Merge pull request #209 from cyberman54/development

v1.6.85
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Verkehrsrot 2018-11-25 18:46:53 +01:00 committed by GitHub
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94 changed files with 6901 additions and 451 deletions

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@ -47,7 +47,7 @@ Depending on board hardware following features are supported:
- Silicon unique ID
- Battery voltage monitoring
- GPS (Generic serial NMEA, or Quectel L76 I2C)
- MEMS sensor (Bosch BME680)
- Environmental sensor (Bosch BME680 I2C)
Target platform must be selected in [platformio.ini](https://github.com/cyberman54/ESP32-Paxcounter/blob/master/platformio.ini).<br>
Hardware dependent settings (pinout etc.) are stored in board files in /hal directory. If you want to use a ESP32 board which is not yet supported, use hal file generic.h and tailor pin mappings to your needs. Pull requests for new boards welcome.<br>
@ -151,7 +151,6 @@ Hereafter described is the default *plain* format, which uses MSB bit numbering.
byte 1-2: Number of unique pax, first seen on Wifi
byte 3-4: Number of unique pax, first seen on Bluetooth [0 if BT disabled]
bytes 5-18: GPS data, format see Port #4 (appended only, if GPS is present and has a fix)
**Port #2:** Device status query result
@ -177,12 +176,12 @@ Hereafter described is the default *plain* format, which uses MSB bit numbering.
byte 13: Wifi antenna switch (0=internal, 1=external) [default 0]
byte 14: Vendorfilter mode (0=disabled, 1=enabled) [default 0]
byte 15: RGB LED luminosity (0..100 %) [default 30]
byte 16: GPS send data mode (1=on, 0=ff) [default 1]
byte 16: Payload filter mask
byte 17: Beacon proximity alarm mode (1=on, 0=off) [default 0]
bytes 18-28: Software version (ASCII format, terminating with zero)
**Port #4:** GPS query result
**Port #4:** GPS query result (device answers only if has GPS and GPS has a fix)
bytes 1-4: Latitude
bytes 5-8: Longitude
@ -199,12 +198,20 @@ Hereafter described is the default *plain* format, which uses MSB bit numbering.
byte 1: Beacon RSSI reception level
byte 2: Beacon identifier (0..255)
**Port #7:** BME680 query result
**Port #7:** Environmental sensor query result
bytes 1-2: Temperature [°C]
bytes 3-4: Pressure [hPa]
bytes 5-6: Humidity [%]
bytes 7-8: Gas resistance [kOhm]
bytes 7-8: Indoor air quality index (0..500), see below
Indoor air quality classification:
0-50 good
51-100 average
101-150 little bad
151-200 bad
201-300 worse
301-500 very bad
# Remote control
@ -306,6 +313,11 @@ Note: all settings are stored in NVRAM and will be reloaded when device starts.
byte 1 = beacon ID (0..255)
bytes 2..7 = beacon MAC with 6 digits (e.g. MAC 80:ab:00:01:02:03 -> 0x80ab00010203)
0x13 set user sensor mode
byte 1 = user sensor number (1..4)
byte 2 = sensor mode (0 = disabled / 1 = enabled [default])
0x80 get device configuration
Device answers with it's current configuration on Port 3.

29
include/bme680mems.h Normal file
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@ -0,0 +1,29 @@
#ifndef _BME680MEMS_H
#define _BME680MEMS_H
#include "globals.h"
#include <Wire.h>
#include "bsec_integration.h"
extern bmeStatus_t
bme_status; // Make struct for storing gps data globally available
extern TaskHandle_t BmeTask;
int bme_init();
void bme_loop(void *pvParameters);
int8_t i2c_read(uint8_t dev_id, uint8_t reg_addr, uint8_t *reg_data,
uint16_t len);
int8_t i2c_write(uint8_t dev_id, uint8_t reg_addr, uint8_t *reg_data,
uint16_t len);
void output_ready(int64_t timestamp, float iaq, uint8_t iaq_accuracy,
float temperature, float humidity, float pressure,
float raw_temperature, float raw_humidity, float gas,
bsec_library_return_t bsec_status, float static_iaq,
float co2_equivalent, float breath_voc_equivalent);
uint32_t state_load(uint8_t *state_buffer, uint32_t n_buffer);
void state_save(const uint8_t *state_buffer, uint32_t length);
uint32_t config_load(uint8_t *config_buffer, uint32_t n_buffer);
void user_delay_ms(uint32_t period);
int64_t get_timestamp_us();
#endif

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@ -1,15 +0,0 @@
#ifndef _HAS_BME
#define _HAS_BME
#include "globals.h"
#include <Wire.h>
#include <Adafruit_Sensor.h>
#include "Adafruit_BME680.h"
extern bmeStatus_t
bme_status; // Make struct for storing gps data globally available
void bme_init();
bool bme_read();
#endif

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@ -9,6 +9,26 @@
#include <array>
#include <algorithm>
// bits in payloadmask for filtering payload data
#define GPS_DATA (0x01)
#define ALARM_DATA (0x02)
#define MEMS_DATA (0x04)
#define COUNT_DATA (0x08)
#define SENSOR1_DATA (0x10)
#define SENSOR2_DATA (0x20)
#define SENSOR3_DATA (0x40)
#define SENSOR4_DATA (0x80)
// bits in configmask for device runmode control
#define GPS_MODE (0x01)
#define ALARM_MODE (0x02)
#define BEACON_MODE (0x04)
#define UPDATE_MODE (0x08)
#define FILTER_MODE (0x10)
#define ANTENNA_MODE (0x20)
#define BLE_MODE (0x40)
#define SCREEN_MODE (0x80)
// Struct holding devices's runtime configuration
typedef struct {
uint8_t lorasf; // 7-12, lora spreadfactor
@ -25,9 +45,9 @@ typedef struct {
uint8_t wifiant; // 0=internal, 1=external (for LoPy/LoPy4)
uint8_t vendorfilter; // 0=disabled, 1=enabled
uint8_t rgblum; // RGB Led luminosity (0..100%)
uint8_t gpsmode; // 0=disabled, 1=enabled
uint8_t monitormode; // 0=disabled, 1=enabled
uint8_t runmode; // 0=normal, 1=update
uint8_t payloadmask; // bitswitches for payload data
char version[10]; // Firmware version
} configData_t;
@ -47,10 +67,14 @@ typedef struct {
} gpsStatus_t;
typedef struct {
float temperature; // Temperature in degrees Centigrade
uint16_t pressure; // Barometic pressure in hecto pascals
float humidity; // Relative humidity in percent
uint16_t gas_resistance; // Resistance in MOhms
float iaq; // IAQ signal
uint8_t iaq_accuracy; // accuracy of IAQ signal
float temperature; // temperature signal
float humidity; // humidity signal
float pressure; // pressure signal
float raw_temperature; // raw temperature signal
float raw_humidity; // raw humidity signal
float gas; // raw gas sensor signal
} bmeStatus_t;
// global variables
@ -75,7 +99,7 @@ extern TaskHandle_t irqHandlerTask, wifiSwitchTask;
#endif
#ifdef HAS_BME
#include "bme680read.h"
#include "bme680mems.h"
#endif
#ifdef HAS_LORA
@ -102,4 +126,8 @@ extern TaskHandle_t irqHandlerTask, wifiSwitchTask;
#include "antenna.h"
#endif
#ifdef HAS_SENSORS
#include "sensor.h"
#endif
#endif

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@ -13,6 +13,7 @@ extern gpsStatus_t
gps_status; // Make struct for storing gps data globally available
extern TaskHandle_t GpsTask;
int gps_init(void);
void gps_read(void);
void gps_loop(void *pvParameters);

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@ -3,6 +3,7 @@
#include "globals.h"
#include "rcommand.h"
#include <TimeLib.h>
// LMIC-Arduino LoRaWAN Stack
#include <lmic.h>

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@ -5,7 +5,8 @@
#include "globals.h"
#include "battery.h"
#include "update.h"
//#include "update.h"
#include <Update.h>
#include <WiFi.h>
#include <WiFiClientSecure.h>
#include <BintrayClient.h>

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@ -47,6 +47,7 @@ public:
void addGPS(gpsStatus_t value);
void addBME(bmeStatus_t value);
void addButton(uint8_t value);
void addSensor(uint8_t[]);
#if PAYLOAD_ENCODER == 1 // format plain

8
include/sensor.h Normal file
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@ -0,0 +1,8 @@
#ifndef _SENSOR_H
#define _SENSOR_H
uint8_t sensor_mask(uint8_t sensor_no);
uint8_t * sensor_read(uint8_t sensor);
void sensor_init(void);
#endif

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@ -1,184 +0,0 @@
#ifndef ESP8266UPDATER_H
#define ESP8266UPDATER_H
#include <Arduino.h>
#include <MD5Builder.h>
#include <functional>
#include "esp_partition.h"
#define UPDATE_ERROR_OK (0)
#define UPDATE_ERROR_WRITE (1)
#define UPDATE_ERROR_ERASE (2)
#define UPDATE_ERROR_READ (3)
#define UPDATE_ERROR_SPACE (4)
#define UPDATE_ERROR_SIZE (5)
#define UPDATE_ERROR_STREAM (6)
#define UPDATE_ERROR_MD5 (7)
#define UPDATE_ERROR_MAGIC_BYTE (8)
#define UPDATE_ERROR_ACTIVATE (9)
#define UPDATE_ERROR_NO_PARTITION (10)
#define UPDATE_ERROR_BAD_ARGUMENT (11)
#define UPDATE_ERROR_ABORT (12)
#define UPDATE_SIZE_UNKNOWN 0xFFFFFFFF
#define U_FLASH 0
#define U_SPIFFS 100
#define U_AUTH 200
class UpdateClass {
public:
typedef std::function<void(size_t, size_t)> THandlerFunction_Progress;
UpdateClass();
/*
This callback will be called when Update is receiving data
*/
UpdateClass& onProgress(THandlerFunction_Progress fn);
/*
Call this to check the space needed for the update
Will return false if there is not enough space
*/
bool begin(size_t size=UPDATE_SIZE_UNKNOWN, int command = U_FLASH, int ledPin = -1, uint8_t ledOn = LOW);
/*
Writes a buffer to the flash and increments the address
Returns the amount written
*/
size_t write(uint8_t *data, size_t len);
/*
Writes the remaining bytes from the Stream to the flash
Uses readBytes() and sets UPDATE_ERROR_STREAM on timeout
Returns the bytes written
Should be equal to the remaining bytes when called
Usable for slow streams like Serial
*/
size_t writeStream(Stream &data);
/*
If all bytes are written
this call will write the config to eboot
and return true
If there is already an update running but is not finished and !evenIfRemainanig
or there is an error
this will clear everything and return false
the last error is available through getError()
evenIfRemaining is helpfull when you update without knowing the final size first
*/
bool end(bool evenIfRemaining = false);
/*
Aborts the running update
*/
void abort();
/*
Prints the last error to an output stream
*/
void printError(Stream &out);
/*
sets the expected MD5 for the firmware (hexString)
*/
bool setMD5(const char * expected_md5);
/*
returns the MD5 String of the sucessfully ended firmware
*/
String md5String(void){ return _md5.toString(); }
/*
populated the result with the md5 bytes of the sucessfully ended firmware
*/
void md5(uint8_t * result){ return _md5.getBytes(result); }
//Helpers
uint8_t getError(){ return _error; }
void clearError(){ _error = UPDATE_ERROR_OK; }
bool hasError(){ return _error != UPDATE_ERROR_OK; }
bool isRunning(){ return _size > 0; }
bool isFinished(){ return _progress == _size; }
size_t size(){ return _size; }
size_t progress(){ return _progress; }
size_t remaining(){ return _size - _progress; }
/*
Template to write from objects that expose
available() and read(uint8_t*, size_t) methods
faster than the writeStream method
writes only what is available
*/
template<typename T>
size_t write(T &data){
size_t written = 0;
if (hasError() || !isRunning())
return 0;
size_t available = data.available();
while(available) {
if(_bufferLen + available > remaining()){
available = remaining() - _bufferLen;
}
if(_bufferLen + available > 4096) {
size_t toBuff = 4096 - _bufferLen;
data.read(_buffer + _bufferLen, toBuff);
_bufferLen += toBuff;
if(!_writeBuffer())
return written;
written += toBuff;
} else {
data.read(_buffer + _bufferLen, available);
_bufferLen += available;
written += available;
if(_bufferLen == remaining()) {
if(!_writeBuffer()) {
return written;
}
}
}
if(remaining() == 0)
return written;
available = data.available();
}
return written;
}
/*
check if there is a firmware on the other OTA partition that you can bootinto
*/
bool canRollBack();
/*
set the other OTA partition as bootable (reboot to enable)
*/
bool rollBack();
private:
void _reset();
void _abort(uint8_t err);
bool _writeBuffer();
bool _verifyHeader(uint8_t data);
bool _verifyEnd();
uint8_t _error;
uint8_t *_buffer;
size_t _bufferLen;
size_t _size;
THandlerFunction_Progress _progress_callback;
uint32_t _progress;
uint32_t _command;
const esp_partition_t* _partition;
String _target_md5;
MD5Builder _md5;
int _ledPin;
uint8_t _ledOn;
};
extern UpdateClass Update;
#endif

39
lib/Bosch-BSEC/LICENSE Normal file
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@ -0,0 +1,39 @@
Copyright (C) 2017 - 2018 Bosch Sensortec GmbH
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:
Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
Neither the name of the copyright holder nor the names of the
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND
CONTRIBUTORS "AS IS" AND ANY EXPRESS OR
IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL COPYRIGHT HOLDER
OR CONTRIBUTORS BE LIABLE FOR ANY
DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,
OR CONSEQUENTIAL DAMAGES(INCLUDING, BUT NOT LIMITED TO,
PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
ANY WAY OUT OF THE USE OF THIS
SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
The information provided is believed to be accurate and reliable.
The copyright holder assumes no responsibility
for the consequences of use
of such information nor for any infringement of patents or
other rights of third parties which may result from its use.
No license is granted by implication or otherwise under any patent or
patent rights of the copyright holder.

282
lib/Bosch-BSEC/README.md Normal file
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@ -0,0 +1,282 @@
# BME680 sensor API
## Introduction
This package contains the Bosch Sensortec's BME680 gas sensor API
The sensor driver package includes bme680.h, bme680.c and bme680_defs.h files
## Version
File | Version | Date
--------------|---------|-------------
bme680.c | 3.5.9 | 19 Jun 2018
bme680.h | 3.5.9 | 19 Jun 2018
bme680_defs.h | 3.5.9 | 19 Jun 2018
## Integration details
* Integrate bme680.h, bme680_defs.h and bme680.c file in to your project.
* Include the bme680.h file in your code like below.
``` c
#include "bme680.h"
```
## File information
* bme680_defs.h : This header file has the constants, macros and datatype declarations.
* bme680.h : This header file contains the declarations of the sensor driver APIs.
* bme680.c : This source file contains the definitions of the sensor driver APIs.
## Supported sensor interfaces
* SPI 4-wire
* I2C
## Usage guide
### Initializing the sensor
To initialize the sensor, you will first need to create a device structure. You
can do this by creating an instance of the structure bme680_dev. Then go on to
fill in the various parameters as shown below
#### Example for SPI 4-Wire
``` c
struct bme680_dev gas_sensor;
/* You may assign a chip select identifier to be handled later */
gas_sensor.dev_id = 0;
gas_sensor.intf = BME680_SPI_INTF;
gas_sensor.read = user_spi_read;
gas_sensor.write = user_spi_write;
gas_sensor.delay_ms = user_delay_ms;
/* amb_temp can be set to 25 prior to configuring the gas sensor
* or by performing a few temperature readings without operating the gas sensor.
*/
gas_sensor.amb_temp = 25;
int8_t rslt = BME680_OK;
rslt = bme680_init(&gas_sensor);
```
#### Example for I2C
``` c
struct bme680_dev gas_sensor;
gas_sensor.dev_id = BME680_I2C_ADDR_PRIMARY;
gas_sensor.intf = BME680_I2C_INTF;
gas_sensor.read = i2c_read;
gas_sensor.write = i2c_write;
gas_sensor.delay_ms = user_delay_ms;
/* amb_temp can be set to 25 prior to configuring the gas sensor
* or by performing a few temperature readings without operating the gas sensor.
*/
gas_sensor.amb_temp = 25;
int8_t rslt = BME680_OK;
rslt = bme680_init(&gas_sensor);
```
Regarding compensation functions for temperature, pressure, humidity and gas we have two implementations.
- Integer version
- floating point version
By default, Integer version is used in the API
If the user needs the floating point version, the user has to un-comment BME680_FLOAT_POINT_COMPENSATION macro
in bme680_defs.h file or to add it in the compiler flags.
### Configuring the sensor
#### Example for configuring the sensor in forced mode
``` c
uint8_t set_required_settings;
/* Set the temperature, pressure and humidity settings */
gas_sensor.tph_sett.os_hum = BME680_OS_2X;
gas_sensor.tph_sett.os_pres = BME680_OS_4X;
gas_sensor.tph_sett.os_temp = BME680_OS_8X;
gas_sensor.tph_sett.filter = BME680_FILTER_SIZE_3;
/* Set the remaining gas sensor settings and link the heating profile */
gas_sensor.gas_sett.run_gas = BME680_ENABLE_GAS_MEAS;
/* Create a ramp heat waveform in 3 steps */
gas_sensor.gas_sett.heatr_temp = 320; /* degree Celsius */
gas_sensor.gas_sett.heatr_dur = 150; /* milliseconds */
/* Select the power mode */
/* Must be set before writing the sensor configuration */
gas_sensor.power_mode = BME680_FORCED_MODE;
/* Set the required sensor settings needed */
set_required_settings = BME680_OST_SEL | BME680_OSP_SEL | BME680_OSH_SEL | BME680_FILTER_SEL
| BME680_GAS_SENSOR_SEL;
/* Set the desired sensor configuration */
rslt = bme680_set_sensor_settings(set_required_settings,&gas_sensor);
/* Set the power mode */
rslt = bme680_set_sensor_mode(&gas_sensor);
```
### Reading sensor data
#### Example for reading all sensor data
``` c
/* Get the total measurement duration so as to sleep or wait till the
* measurement is complete */
uint16_t meas_period;
bme680_get_profile_dur(&meas_period, &gas_sensor);
struct bme680_field_data data;
while(1)
{
user_delay_ms(meas_period); /* Delay till the measurement is ready */
rslt = bme680_get_sensor_data(&data, &gas_sensor);
printf("T: %.2f degC, P: %.2f hPa, H %.2f %%rH ", data.temperature / 100.0f,
data.pressure / 100.0f, data.humidity / 1000.0f );
/* Avoid using measurements from an unstable heating setup */
if(data.status & BME680_GASM_VALID_MSK)
printf(", G: %d ohms", data.gas_resistance);
printf("\r\n");
/* Trigger the next measurement if you would like to read data out continuously */
if (gas_sensor.power_mode == BME680_FORCED_MODE) {
rslt = bme680_set_sensor_mode(&gas_sensor);
}
}
```
### Templates for function pointers
``` c
void user_delay_ms(uint32_t period)
{
/*
* Return control or wait,
* for a period amount of milliseconds
*/
}
int8_t user_spi_read(uint8_t dev_id, uint8_t reg_addr, uint8_t *reg_data, uint16_t len)
{
int8_t rslt = 0; /* Return 0 for Success, non-zero for failure */
/*
* The parameter dev_id can be used as a variable to select which Chip Select pin has
* to be set low to activate the relevant device on the SPI bus
*/
/*
* Data on the bus should be like
* |----------------+---------------------+-------------|
* | MOSI | MISO | Chip Select |
* |----------------+---------------------|-------------|
* | (don't care) | (don't care) | HIGH |
* | (reg_addr) | (don't care) | LOW |
* | (don't care) | (reg_data[0]) | LOW |
* | (....) | (....) | LOW |
* | (don't care) | (reg_data[len - 1]) | LOW |
* | (don't care) | (don't care) | HIGH |
* |----------------+---------------------|-------------|
*/
return rslt;
}
int8_t user_spi_write(uint8_t dev_id, uint8_t reg_addr, uint8_t *reg_data, uint16_t len)
{
int8_t rslt = 0; /* Return 0 for Success, non-zero for failure */
/*
* The parameter dev_id can be used as a variable to select which Chip Select pin has
* to be set low to activate the relevant device on the SPI bus
*/
/*
* Data on the bus should be like
* |---------------------+--------------+-------------|
* | MOSI | MISO | Chip Select |
* |---------------------+--------------|-------------|
* | (don't care) | (don't care) | HIGH |
* | (reg_addr) | (don't care) | LOW |
* | (reg_data[0]) | (don't care) | LOW |
* | (....) | (....) | LOW |
* | (reg_data[len - 1]) | (don't care) | LOW |
* | (don't care) | (don't care) | HIGH |
* |---------------------+--------------|-------------|
*/
return rslt;
}
int8_t i2c_read(uint8_t dev_id, uint8_t reg_addr, uint8_t *reg_data, uint16_t len)
{
int8_t rslt = 0; /* Return 0 for Success, non-zero for failure */
/*
* The parameter dev_id can be used as a variable to store the I2C address of the device
*/
/*
* Data on the bus should be like
* |------------+---------------------|
* | I2C action | Data |
* |------------+---------------------|
* | Start | - |
* | Write | (reg_addr) |
* | Stop | - |
* | Start | - |
* | Read | (reg_data[0]) |
* | Read | (....) |
* | Read | (reg_data[len - 1]) |
* | Stop | - |
* |------------+---------------------|
*/
return rslt;
}
int8_t i2c_write(uint8_t dev_id, uint8_t reg_addr, uint8_t *reg_data, uint16_t len)
{
int8_t rslt = 0; /* Return 0 for Success, non-zero for failure */
/*
* The parameter dev_id can be used as a variable to store the I2C address of the device
*/
/*
* Data on the bus should be like
* |------------+---------------------|
* | I2C action | Data |
* |------------+---------------------|
* | Start | - |
* | Write | (reg_addr) |
* | Write | (reg_data[0]) |
* | Write | (....) |
* | Write | (reg_data[len - 1]) |
* | Stop | - |
* |------------+---------------------|
*/
return rslt;
}
```
## Copyright (C) 2017 - 2018 Bosch Sensortec GmbH

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/**
* Copyright (C) 2017 - 2018 Bosch Sensortec GmbH
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* Neither the name of the copyright holder nor the names of the
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND
* CONTRIBUTORS "AS IS" AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL COPYRIGHT HOLDER
* OR CONTRIBUTORS BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,
* OR CONSEQUENTIAL DAMAGES(INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
* The information provided is believed to be accurate and reliable.
* The copyright holder assumes no responsibility
* for the consequences of use
* of such information nor for any infringement of patents or
* other rights of third parties which may result from its use.
* No license is granted by implication or otherwise under any patent or
* patent rights of the copyright holder.
*
* @file bme680.h
* @date 19 Jun 2018
* @version 3.5.9
* @brief
*
*/
/*! @file bme680.h
@brief Sensor driver for BME680 sensor */
/*!
* @defgroup BME680 SENSOR API
* @{*/
#ifndef BME680_H_
#define BME680_H_
/*! CPP guard */
#ifdef __cplusplus
extern "C"
{
#endif
/* Header includes */
#include "bme680_defs.h"
/* function prototype declarations */
/*!
* @brief This API is the entry point.
* It reads the chip-id and calibration data from the sensor.
*
* @param[in,out] dev : Structure instance of bme680_dev
*
* @return Result of API execution status
* @retval zero -> Success / +ve value -> Warning / -ve value -> Error
*/
int8_t bme680_init(struct bme680_dev *dev);
/*!
* @brief This API writes the given data to the register address
* of the sensor.
*
* @param[in] reg_addr : Register address from where the data to be written.
* @param[in] reg_data : Pointer to data buffer which is to be written
* in the sensor.
* @param[in] len : No of bytes of data to write..
* @param[in] dev : Structure instance of bme680_dev.
*
* @return Result of API execution status
* @retval zero -> Success / +ve value -> Warning / -ve value -> Error
*/
int8_t bme680_set_regs(const uint8_t *reg_addr, const uint8_t *reg_data, uint8_t len, struct bme680_dev *dev);
/*!
* @brief This API reads the data from the given register address of the sensor.
*
* @param[in] reg_addr : Register address from where the data to be read
* @param[out] reg_data : Pointer to data buffer to store the read data.
* @param[in] len : No of bytes of data to be read.
* @param[in] dev : Structure instance of bme680_dev.
*
* @return Result of API execution status
* @retval zero -> Success / +ve value -> Warning / -ve value -> Error
*/
int8_t bme680_get_regs(uint8_t reg_addr, uint8_t *reg_data, uint16_t len, struct bme680_dev *dev);
/*!
* @brief This API performs the soft reset of the sensor.
*
* @param[in] dev : Structure instance of bme680_dev.
*
* @return Result of API execution status
* @retval zero -> Success / +ve value -> Warning / -ve value -> Error.
*/
int8_t bme680_soft_reset(struct bme680_dev *dev);
/*!
* @brief This API is used to set the power mode of the sensor.
*
* @param[in] dev : Structure instance of bme680_dev
* @note : Pass the value to bme680_dev.power_mode structure variable.
*
* value | mode
* -------------|------------------
* 0x00 | BME680_SLEEP_MODE
* 0x01 | BME680_FORCED_MODE
*
* * @return Result of API execution status
* @retval zero -> Success / +ve value -> Warning / -ve value -> Error
*/
int8_t bme680_set_sensor_mode(struct bme680_dev *dev);
/*!
* @brief This API is used to get the power mode of the sensor.
*
* @param[in] dev : Structure instance of bme680_dev
* @note : bme680_dev.power_mode structure variable hold the power mode.
*
* value | mode
* ---------|------------------
* 0x00 | BME680_SLEEP_MODE
* 0x01 | BME680_FORCED_MODE
*
* @return Result of API execution status
* @retval zero -> Success / +ve value -> Warning / -ve value -> Error
*/
int8_t bme680_get_sensor_mode(struct bme680_dev *dev);
/*!
* @brief This API is used to set the profile duration of the sensor.
*
* @param[in] dev : Structure instance of bme680_dev.
* @param[in] duration : Duration of the measurement in ms.
*
* @return Nothing
*/
void bme680_set_profile_dur(uint16_t duration, struct bme680_dev *dev);
/*!
* @brief This API is used to get the profile duration of the sensor.
*
* @param[in] dev : Structure instance of bme680_dev.
* @param[in] duration : Duration of the measurement in ms.
*
* @return Nothing
*/
void bme680_get_profile_dur(uint16_t *duration, const struct bme680_dev *dev);
/*!
* @brief This API reads the pressure, temperature and humidity and gas data
* from the sensor, compensates the data and store it in the bme680_data
* structure instance passed by the user.
*
* @param[out] data: Structure instance to hold the data.
* @param[in] dev : Structure instance of bme680_dev.
*
* @return Result of API execution status
* @retval zero -> Success / +ve value -> Warning / -ve value -> Error
*/
int8_t bme680_get_sensor_data(struct bme680_field_data *data, struct bme680_dev *dev);
/*!
* @brief This API is used to set the oversampling, filter and T,P,H, gas selection
* settings in the sensor.
*
* @param[in] dev : Structure instance of bme680_dev.
* @param[in] desired_settings : Variable used to select the settings which
* are to be set in the sensor.
*
* Macros | Functionality
*---------------------------------|----------------------------------------------
* BME680_OST_SEL | To set temperature oversampling.
* BME680_OSP_SEL | To set pressure oversampling.
* BME680_OSH_SEL | To set humidity oversampling.
* BME680_GAS_MEAS_SEL | To set gas measurement setting.
* BME680_FILTER_SEL | To set filter setting.
* BME680_HCNTRL_SEL | To set humidity control setting.
* BME680_RUN_GAS_SEL | To set run gas setting.
* BME680_NBCONV_SEL | To set NB conversion setting.
* BME680_GAS_SENSOR_SEL | To set all gas sensor related settings
*
* @note : Below are the macros to be used by the user for selecting the
* desired settings. User can do OR operation of these macros for configuring
* multiple settings.
*
* @return Result of API execution status
* @retval zero -> Success / +ve value -> Warning / -ve value -> Error.
*/
int8_t bme680_set_sensor_settings(uint16_t desired_settings, struct bme680_dev *dev);
/*!
* @brief This API is used to get the oversampling, filter and T,P,H, gas selection
* settings in the sensor.
*
* @param[in] dev : Structure instance of bme680_dev.
* @param[in] desired_settings : Variable used to select the settings which
* are to be get from the sensor.
*
* @return Result of API execution status
* @retval zero -> Success / +ve value -> Warning / -ve value -> Error.
*/
int8_t bme680_get_sensor_settings(uint16_t desired_settings, struct bme680_dev *dev);
#ifdef __cplusplus
}
#endif /* End of CPP guard */
#endif /* BME680_H_ */
/** @}*/

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@ -0,0 +1,545 @@
/**
* Copyright (C) 2017 - 2018 Bosch Sensortec GmbH
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* Neither the name of the copyright holder nor the names of the
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND
* CONTRIBUTORS "AS IS" AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL COPYRIGHT HOLDER
* OR CONTRIBUTORS BE LIABLE FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,
* OR CONSEQUENTIAL DAMAGES(INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE
*
* The information provided is believed to be accurate and reliable.
* The copyright holder assumes no responsibility
* for the consequences of use
* of such information nor for any infringement of patents or
* other rights of third parties which may result from its use.
* No license is granted by implication or otherwise under any patent or
* patent rights of the copyright holder.
*
* @file bme680_defs.h
* @date 19 Jun 2018
* @version 3.5.9
* @brief
*
*/
/*! @file bme680_defs.h
@brief Sensor driver for BME680 sensor */
/*!
* @defgroup BME680 SENSOR API
* @brief
* @{*/
#ifndef BME680_DEFS_H_
#define BME680_DEFS_H_
/********************************************************/
/* header includes */
#ifdef __KERNEL__
#include <linux/types.h>
#include <linux/kernel.h>
#else
#include <stdint.h>
#include <stddef.h>
#endif
/******************************************************************************/
/*! @name Common macros */
/******************************************************************************/
#if !defined(UINT8_C) && !defined(INT8_C)
#define INT8_C(x) S8_C(x)
#define UINT8_C(x) U8_C(x)
#endif
#if !defined(UINT16_C) && !defined(INT16_C)
#define INT16_C(x) S16_C(x)
#define UINT16_C(x) U16_C(x)
#endif
#if !defined(INT32_C) && !defined(UINT32_C)
#define INT32_C(x) S32_C(x)
#define UINT32_C(x) U32_C(x)
#endif
#if !defined(INT64_C) && !defined(UINT64_C)
#define INT64_C(x) S64_C(x)
#define UINT64_C(x) U64_C(x)
#endif
/**@}*/
/**\name C standard macros */
#ifndef NULL
#ifdef __cplusplus
#define NULL 0
#else
#define NULL ((void *) 0)
#endif
#endif
/** BME680 configuration macros */
/** Enable or un-comment the macro to provide floating point data output */
#ifndef BME680_FLOAT_POINT_COMPENSATION
/* #define BME680_FLOAT_POINT_COMPENSATION */
#endif
/** BME680 General config */
#define BME680_POLL_PERIOD_MS UINT8_C(10)
/** BME680 I2C addresses */
#define BME680_I2C_ADDR_PRIMARY UINT8_C(0x76)
#define BME680_I2C_ADDR_SECONDARY UINT8_C(0x77)
/** BME680 unique chip identifier */
#define BME680_CHIP_ID UINT8_C(0x61)
/** BME680 coefficients related defines */
#define BME680_COEFF_SIZE UINT8_C(41)
#define BME680_COEFF_ADDR1_LEN UINT8_C(25)
#define BME680_COEFF_ADDR2_LEN UINT8_C(16)
/** BME680 field_x related defines */
#define BME680_FIELD_LENGTH UINT8_C(15)
#define BME680_FIELD_ADDR_OFFSET UINT8_C(17)
/** Soft reset command */
#define BME680_SOFT_RESET_CMD UINT8_C(0xb6)
/** Error code definitions */
#define BME680_OK INT8_C(0)
/* Errors */
#define BME680_E_NULL_PTR INT8_C(-1)
#define BME680_E_COM_FAIL INT8_C(-2)
#define BME680_E_DEV_NOT_FOUND INT8_C(-3)
#define BME680_E_INVALID_LENGTH INT8_C(-4)
/* Warnings */
#define BME680_W_DEFINE_PWR_MODE INT8_C(1)
#define BME680_W_NO_NEW_DATA INT8_C(2)
/* Info's */
#define BME680_I_MIN_CORRECTION UINT8_C(1)
#define BME680_I_MAX_CORRECTION UINT8_C(2)
/** Register map */
/** Other coefficient's address */
#define BME680_ADDR_RES_HEAT_VAL_ADDR UINT8_C(0x00)
#define BME680_ADDR_RES_HEAT_RANGE_ADDR UINT8_C(0x02)
#define BME680_ADDR_RANGE_SW_ERR_ADDR UINT8_C(0x04)
#define BME680_ADDR_SENS_CONF_START UINT8_C(0x5A)
#define BME680_ADDR_GAS_CONF_START UINT8_C(0x64)
/** Field settings */
#define BME680_FIELD0_ADDR UINT8_C(0x1d)
/** Heater settings */
#define BME680_RES_HEAT0_ADDR UINT8_C(0x5a)
#define BME680_GAS_WAIT0_ADDR UINT8_C(0x64)
/** Sensor configuration registers */
#define BME680_CONF_HEAT_CTRL_ADDR UINT8_C(0x70)
#define BME680_CONF_ODR_RUN_GAS_NBC_ADDR UINT8_C(0x71)
#define BME680_CONF_OS_H_ADDR UINT8_C(0x72)
#define BME680_MEM_PAGE_ADDR UINT8_C(0xf3)
#define BME680_CONF_T_P_MODE_ADDR UINT8_C(0x74)
#define BME680_CONF_ODR_FILT_ADDR UINT8_C(0x75)
/** Coefficient's address */
#define BME680_COEFF_ADDR1 UINT8_C(0x89)
#define BME680_COEFF_ADDR2 UINT8_C(0xe1)
/** Chip identifier */
#define BME680_CHIP_ID_ADDR UINT8_C(0xd0)
/** Soft reset register */
#define BME680_SOFT_RESET_ADDR UINT8_C(0xe0)
/** Heater control settings */
#define BME680_ENABLE_HEATER UINT8_C(0x00)
#define BME680_DISABLE_HEATER UINT8_C(0x08)
/** Gas measurement settings */
#define BME680_DISABLE_GAS_MEAS UINT8_C(0x00)
#define BME680_ENABLE_GAS_MEAS UINT8_C(0x01)
/** Over-sampling settings */
#define BME680_OS_NONE UINT8_C(0)
#define BME680_OS_1X UINT8_C(1)
#define BME680_OS_2X UINT8_C(2)
#define BME680_OS_4X UINT8_C(3)
#define BME680_OS_8X UINT8_C(4)
#define BME680_OS_16X UINT8_C(5)
/** IIR filter settings */
#define BME680_FILTER_SIZE_0 UINT8_C(0)
#define BME680_FILTER_SIZE_1 UINT8_C(1)
#define BME680_FILTER_SIZE_3 UINT8_C(2)
#define BME680_FILTER_SIZE_7 UINT8_C(3)
#define BME680_FILTER_SIZE_15 UINT8_C(4)
#define BME680_FILTER_SIZE_31 UINT8_C(5)
#define BME680_FILTER_SIZE_63 UINT8_C(6)
#define BME680_FILTER_SIZE_127 UINT8_C(7)
/** Power mode settings */
#define BME680_SLEEP_MODE UINT8_C(0)
#define BME680_FORCED_MODE UINT8_C(1)
/** Delay related macro declaration */
#define BME680_RESET_PERIOD UINT32_C(10)
/** SPI memory page settings */
#define BME680_MEM_PAGE0 UINT8_C(0x10)
#define BME680_MEM_PAGE1 UINT8_C(0x00)
/** Ambient humidity shift value for compensation */
#define BME680_HUM_REG_SHIFT_VAL UINT8_C(4)
/** Run gas enable and disable settings */
#define BME680_RUN_GAS_DISABLE UINT8_C(0)
#define BME680_RUN_GAS_ENABLE UINT8_C(1)
/** Buffer length macro declaration */
#define BME680_TMP_BUFFER_LENGTH UINT8_C(40)
#define BME680_REG_BUFFER_LENGTH UINT8_C(6)
#define BME680_FIELD_DATA_LENGTH UINT8_C(3)
#define BME680_GAS_REG_BUF_LENGTH UINT8_C(20)
/** Settings selector */
#define BME680_OST_SEL UINT16_C(1)
#define BME680_OSP_SEL UINT16_C(2)
#define BME680_OSH_SEL UINT16_C(4)
#define BME680_GAS_MEAS_SEL UINT16_C(8)
#define BME680_FILTER_SEL UINT16_C(16)
#define BME680_HCNTRL_SEL UINT16_C(32)
#define BME680_RUN_GAS_SEL UINT16_C(64)
#define BME680_NBCONV_SEL UINT16_C(128)
#define BME680_GAS_SENSOR_SEL (BME680_GAS_MEAS_SEL | BME680_RUN_GAS_SEL | BME680_NBCONV_SEL)
/** Number of conversion settings*/
#define BME680_NBCONV_MIN UINT8_C(0)
#define BME680_NBCONV_MAX UINT8_C(10)
/** Mask definitions */
#define BME680_GAS_MEAS_MSK UINT8_C(0x30)
#define BME680_NBCONV_MSK UINT8_C(0X0F)
#define BME680_FILTER_MSK UINT8_C(0X1C)
#define BME680_OST_MSK UINT8_C(0XE0)
#define BME680_OSP_MSK UINT8_C(0X1C)
#define BME680_OSH_MSK UINT8_C(0X07)
#define BME680_HCTRL_MSK UINT8_C(0x08)
#define BME680_RUN_GAS_MSK UINT8_C(0x10)
#define BME680_MODE_MSK UINT8_C(0x03)
#define BME680_RHRANGE_MSK UINT8_C(0x30)
#define BME680_RSERROR_MSK UINT8_C(0xf0)
#define BME680_NEW_DATA_MSK UINT8_C(0x80)
#define BME680_GAS_INDEX_MSK UINT8_C(0x0f)
#define BME680_GAS_RANGE_MSK UINT8_C(0x0f)
#define BME680_GASM_VALID_MSK UINT8_C(0x20)
#define BME680_HEAT_STAB_MSK UINT8_C(0x10)
#define BME680_MEM_PAGE_MSK UINT8_C(0x10)
#define BME680_SPI_RD_MSK UINT8_C(0x80)
#define BME680_SPI_WR_MSK UINT8_C(0x7f)
#define BME680_BIT_H1_DATA_MSK UINT8_C(0x0F)
/** Bit position definitions for sensor settings */
#define BME680_GAS_MEAS_POS UINT8_C(4)
#define BME680_FILTER_POS UINT8_C(2)
#define BME680_OST_POS UINT8_C(5)
#define BME680_OSP_POS UINT8_C(2)
#define BME680_RUN_GAS_POS UINT8_C(4)
/** Array Index to Field data mapping for Calibration Data*/
#define BME680_T2_LSB_REG (1)
#define BME680_T2_MSB_REG (2)
#define BME680_T3_REG (3)
#define BME680_P1_LSB_REG (5)
#define BME680_P1_MSB_REG (6)
#define BME680_P2_LSB_REG (7)
#define BME680_P2_MSB_REG (8)
#define BME680_P3_REG (9)
#define BME680_P4_LSB_REG (11)
#define BME680_P4_MSB_REG (12)
#define BME680_P5_LSB_REG (13)
#define BME680_P5_MSB_REG (14)
#define BME680_P7_REG (15)
#define BME680_P6_REG (16)
#define BME680_P8_LSB_REG (19)
#define BME680_P8_MSB_REG (20)
#define BME680_P9_LSB_REG (21)
#define BME680_P9_MSB_REG (22)
#define BME680_P10_REG (23)
#define BME680_H2_MSB_REG (25)
#define BME680_H2_LSB_REG (26)
#define BME680_H1_LSB_REG (26)
#define BME680_H1_MSB_REG (27)
#define BME680_H3_REG (28)
#define BME680_H4_REG (29)
#define BME680_H5_REG (30)
#define BME680_H6_REG (31)
#define BME680_H7_REG (32)
#define BME680_T1_LSB_REG (33)
#define BME680_T1_MSB_REG (34)
#define BME680_GH2_LSB_REG (35)
#define BME680_GH2_MSB_REG (36)
#define BME680_GH1_REG (37)
#define BME680_GH3_REG (38)
/** BME680 register buffer index settings*/
#define BME680_REG_FILTER_INDEX UINT8_C(5)
#define BME680_REG_TEMP_INDEX UINT8_C(4)
#define BME680_REG_PRES_INDEX UINT8_C(4)
#define BME680_REG_HUM_INDEX UINT8_C(2)
#define BME680_REG_NBCONV_INDEX UINT8_C(1)
#define BME680_REG_RUN_GAS_INDEX UINT8_C(1)
#define BME680_REG_HCTRL_INDEX UINT8_C(0)
/** BME680 pressure calculation macros */
/*! This max value is used to provide precedence to multiplication or division
* in pressure compensation equation to achieve least loss of precision and
* avoiding overflows.
* i.e Comparing value, BME680_MAX_OVERFLOW_VAL = INT32_C(1 << 30)
*/
#define BME680_MAX_OVERFLOW_VAL INT32_C(0x40000000)
/** Macro to combine two 8 bit data's to form a 16 bit data */
#define BME680_CONCAT_BYTES(msb, lsb) (((uint16_t)msb << 8) | (uint16_t)lsb)
/** Macro to SET and GET BITS of a register */
#define BME680_SET_BITS(reg_data, bitname, data) \
((reg_data & ~(bitname##_MSK)) | \
((data << bitname##_POS) & bitname##_MSK))
#define BME680_GET_BITS(reg_data, bitname) ((reg_data & (bitname##_MSK)) >> \
(bitname##_POS))
/** Macro variant to handle the bitname position if it is zero */
#define BME680_SET_BITS_POS_0(reg_data, bitname, data) \
((reg_data & ~(bitname##_MSK)) | \
(data & bitname##_MSK))
#define BME680_GET_BITS_POS_0(reg_data, bitname) (reg_data & (bitname##_MSK))
/** Type definitions */
/*!
* Generic communication function pointer
* @param[in] dev_id: Place holder to store the id of the device structure
* Can be used to store the index of the Chip select or
* I2C address of the device.
* @param[in] reg_addr: Used to select the register the where data needs to
* be read from or written to.
* @param[in/out] reg_data: Data array to read/write
* @param[in] len: Length of the data array
*/
typedef int8_t (*bme680_com_fptr_t)(uint8_t dev_id, uint8_t reg_addr, uint8_t *data, uint16_t len);
/*!
* Delay function pointer
* @param[in] period: Time period in milliseconds
*/
typedef void (*bme680_delay_fptr_t)(uint32_t period);
/*!
* @brief Interface selection Enumerations
*/
enum bme680_intf {
/*! SPI interface */
BME680_SPI_INTF,
/*! I2C interface */
BME680_I2C_INTF
};
/* structure definitions */
/*!
* @brief Sensor field data structure
*/
struct bme680_field_data {
/*! Contains new_data, gasm_valid & heat_stab */
uint8_t status;
/*! The index of the heater profile used */
uint8_t gas_index;
/*! Measurement index to track order */
uint8_t meas_index;
#ifndef BME680_FLOAT_POINT_COMPENSATION
/*! Temperature in degree celsius x100 */
int16_t temperature;
/*! Pressure in Pascal */
uint32_t pressure;
/*! Humidity in % relative humidity x1000 */
uint32_t humidity;
/*! Gas resistance in Ohms */
uint32_t gas_resistance;
#else
/*! Temperature in degree celsius */
float temperature;
/*! Pressure in Pascal */
float pressure;
/*! Humidity in % relative humidity x1000 */
float humidity;
/*! Gas resistance in Ohms */
float gas_resistance;
#endif
};
/*!
* @brief Structure to hold the Calibration data
*/
struct bme680_calib_data {
/*! Variable to store calibrated humidity data */
uint16_t par_h1;
/*! Variable to store calibrated humidity data */
uint16_t par_h2;
/*! Variable to store calibrated humidity data */
int8_t par_h3;
/*! Variable to store calibrated humidity data */
int8_t par_h4;
/*! Variable to store calibrated humidity data */
int8_t par_h5;
/*! Variable to store calibrated humidity data */
uint8_t par_h6;
/*! Variable to store calibrated humidity data */
int8_t par_h7;
/*! Variable to store calibrated gas data */
int8_t par_gh1;
/*! Variable to store calibrated gas data */
int16_t par_gh2;
/*! Variable to store calibrated gas data */
int8_t par_gh3;
/*! Variable to store calibrated temperature data */
uint16_t par_t1;
/*! Variable to store calibrated temperature data */
int16_t par_t2;
/*! Variable to store calibrated temperature data */
int8_t par_t3;
/*! Variable to store calibrated pressure data */
uint16_t par_p1;
/*! Variable to store calibrated pressure data */
int16_t par_p2;
/*! Variable to store calibrated pressure data */
int8_t par_p3;
/*! Variable to store calibrated pressure data */
int16_t par_p4;
/*! Variable to store calibrated pressure data */
int16_t par_p5;
/*! Variable to store calibrated pressure data */
int8_t par_p6;
/*! Variable to store calibrated pressure data */
int8_t par_p7;
/*! Variable to store calibrated pressure data */
int16_t par_p8;
/*! Variable to store calibrated pressure data */
int16_t par_p9;
/*! Variable to store calibrated pressure data */
uint8_t par_p10;
#ifndef BME680_FLOAT_POINT_COMPENSATION
/*! Variable to store t_fine size */
int32_t t_fine;
#else
/*! Variable to store t_fine size */
float t_fine;
#endif
/*! Variable to store heater resistance range */
uint8_t res_heat_range;
/*! Variable to store heater resistance value */
int8_t res_heat_val;
/*! Variable to store error range */
int8_t range_sw_err;
};
/*!
* @brief BME680 sensor settings structure which comprises of ODR,
* over-sampling and filter settings.
*/
struct bme680_tph_sett {
/*! Humidity oversampling */
uint8_t os_hum;
/*! Temperature oversampling */
uint8_t os_temp;
/*! Pressure oversampling */
uint8_t os_pres;
/*! Filter coefficient */
uint8_t filter;
};
/*!
* @brief BME680 gas sensor which comprises of gas settings
* and status parameters
*/
struct bme680_gas_sett {
/*! Variable to store nb conversion */
uint8_t nb_conv;
/*! Variable to store heater control */
uint8_t heatr_ctrl;
/*! Run gas enable value */
uint8_t run_gas;
/*! Heater temperature value */
uint16_t heatr_temp;
/*! Duration profile value */
uint16_t heatr_dur;
};
/*!
* @brief BME680 device structure
*/
struct bme680_dev {
/*! Chip Id */
uint8_t chip_id;
/*! Device Id */
uint8_t dev_id;
/*! SPI/I2C interface */
enum bme680_intf intf;
/*! Memory page used */
uint8_t mem_page;
/*! Ambient temperature in Degree C */
int8_t amb_temp;
/*! Sensor calibration data */
struct bme680_calib_data calib;
/*! Sensor settings */
struct bme680_tph_sett tph_sett;
/*! Gas Sensor settings */
struct bme680_gas_sett gas_sett;
/*! Sensor power modes */
uint8_t power_mode;
/*! New sensor fields */
uint8_t new_fields;
/*! Store the info messages */
uint8_t info_msg;
/*! Bus read function pointer */
bme680_com_fptr_t read;
/*! Bus write function pointer */
bme680_com_fptr_t write;
/*! delay function pointer */
bme680_delay_fptr_t delay_ms;
/*! Communication function result */
int8_t com_rslt;
};
#endif /* BME680_DEFS_H_ */
/** @}*/
/** @}*/

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@ -0,0 +1,488 @@
/*
* Copyright (C) 2015, 2016, 2017 Robert Bosch. All Rights Reserved.
*
* Disclaimer
*
* Common:
* Bosch Sensortec products are developed for the consumer goods industry. They may only be used
* within the parameters of the respective valid product data sheet. Bosch Sensortec products are
* provided with the express understanding that there is no warranty of fitness for a particular purpose.
* They are not fit for use in life-sustaining, safety or security sensitive systems or any system or device
* that may lead to bodily harm or property damage if the system or device malfunctions. In addition,
* Bosch Sensortec products are not fit for use in products which interact with motor vehicle systems.
* The resale and/or use of products are at the purchasers own risk and his own responsibility. The
* examination of fitness for the intended use is the sole responsibility of the Purchaser.
*
* The purchaser shall indemnify Bosch Sensortec from all third party claims, including any claims for
* incidental, or consequential damages, arising from any product use not covered by the parameters of
* the respective valid product data sheet or not approved by Bosch Sensortec and reimburse Bosch
* Sensortec for all costs in connection with such claims.
*
* The purchaser must monitor the market for the purchased products, particularly with regard to
* product safety and inform Bosch Sensortec without delay of all security relevant incidents.
*
* Engineering Samples are marked with an asterisk (*) or (e). Samples may vary from the valid
* technical specifications of the product series. They are therefore not intended or fit for resale to third
* parties or for use in end products. Their sole purpose is internal client testing. The testing of an
* engineering sample may in no way replace the testing of a product series. Bosch Sensortec
* assumes no liability for the use of engineering samples. By accepting the engineering samples, the
* Purchaser agrees to indemnify Bosch Sensortec from all claims arising from the use of engineering
* samples.
*
* Special:
* This software module (hereinafter called "Software") and any information on application-sheets
* (hereinafter called "Information") is provided free of charge for the sole purpose to support your
* application work. The Software and Information is subject to the following terms and conditions:
*
* The Software is specifically designed for the exclusive use for Bosch Sensortec products by
* personnel who have special experience and training. Do not use this Software if you do not have the
* proper experience or training.
*
* This Software package is provided `` as is `` and without any expressed or implied warranties,
* including without limitation, the implied warranties of merchantability and fitness for a particular
* purpose.
*
* Bosch Sensortec and their representatives and agents deny any liability for the functional impairment
* of this Software in terms of fitness, performance and safety. Bosch Sensortec and their
* representatives and agents shall not be liable for any direct or indirect damages or injury, except as
* otherwise stipulated in mandatory applicable law.
*
* The Information provided is believed to be accurate and reliable. Bosch Sensortec assumes no
* responsibility for the consequences of use of such Information nor for any infringement of patents or
* other rights of third parties which may result from its use. No license is granted by implication or
* otherwise under any patent or patent rights of Bosch. Specifications mentioned in the Information are
* subject to change without notice.
*
* It is not allowed to deliver the source code of the Software to any third party without permission of
* Bosch Sensortec.
*
*/
/**
* @file bsec_datatypes.h
*
* @brief
* Contains the data types used by BSEC
*
*/
#ifndef __BSEC_DATATYPES_H__
#define __BSEC_DATATYPES_H__
#ifdef __cplusplus
extern "C"
{
#endif
/*!
* @addtogroup bsec_interface BSEC C Interface
* @{*/
#ifdef __KERNEL__
#include <linux/types.h>
#endif
#include <stdint.h>
#include <stddef.h>
#define BSEC_MAX_WORKBUFFER_SIZE (2048) /*!< Maximum size (in bytes) of the work buffer */
#define BSEC_MAX_PHYSICAL_SENSOR (8) /*!< Number of physical sensors that need allocated space before calling bsec_update_subscription() */
#define BSEC_MAX_PROPERTY_BLOB_SIZE (454) /*!< Maximum size (in bytes) of the data blobs returned by bsec_get_configuration() */
#define BSEC_MAX_STATE_BLOB_SIZE (134) /*!< Maximum size (in bytes) of the data blobs returned by bsec_get_state()*/
#define BSEC_SAMPLE_RATE_DISABLED (65535.0f) /*!< Sample rate of a disabled sensor */
#define BSEC_SAMPLE_RATE_ULP (0.0033333f) /*!< Sample rate in case of Ultra Low Power Mode */
#define BSEC_SAMPLE_RATE_LP (0.33333f) /*!< Sample rate in case of Low Power Mode */
#define BSEC_SAMPLE_RATE_ULP_MEASUREMENT_ON_DEMAND (0.0f) /*!< Input value used to trigger an extra measurment (ULP plus) */
#define BSEC_PROCESS_PRESSURE (1 << (BSEC_INPUT_PRESSURE-1)) /*!< process_data bitfield constant for pressure @sa bsec_bme_settings_t */
#define BSEC_PROCESS_TEMPERATURE (1 << (BSEC_INPUT_TEMPERATURE-1)) /*!< process_data bitfield constant for temperature @sa bsec_bme_settings_t */
#define BSEC_PROCESS_HUMIDITY (1 << (BSEC_INPUT_HUMIDITY-1)) /*!< process_data bitfield constant for humidity @sa bsec_bme_settings_t */
#define BSEC_PROCESS_GAS (1 << (BSEC_INPUT_GASRESISTOR-1)) /*!< process_data bitfield constant for gas sensor @sa bsec_bme_settings_t */
#define BSEC_NUMBER_OUTPUTS (14) /*!< Number of outputs, depending on solution */
#define BSEC_OUTPUT_INCLUDED (1210863) /*!< bitfield that indicates which outputs are included in the solution */
/*!
* @brief Enumeration for input (physical) sensors.
*
* Used to populate bsec_input_t::sensor_id. It is also used in bsec_sensor_configuration_t::sensor_id structs
* returned in the parameter required_sensor_settings of bsec_update_subscription().
*
* @sa bsec_sensor_configuration_t @sa bsec_input_t
*/
typedef enum
{
/**
* @brief Pressure sensor output of BMExxx [Pa]
*/
BSEC_INPUT_PRESSURE = 1,
/**
* @brief Humidity sensor output of BMExxx [%]
*
* @note Relative humidity strongly depends on the temperature (it is measured at). It may require a conversion to
* the temperature outside of the device.
*
* @sa bsec_virtual_sensor_t
*/
BSEC_INPUT_HUMIDITY = 2,
/**
* @brief Temperature sensor output of BMExxx [degrees Celsius]
*
* @note The BME680 is factory trimmed, thus the temperature sensor of the BME680 is very accurate.
* The temperature value is a very local measurement value and can be influenced by external heat sources.
*
* @sa bsec_virtual_sensor_t
*/
BSEC_INPUT_TEMPERATURE = 3,
/**
* @brief Gas sensor resistance output of BMExxx [Ohm]
*
* The resistance value changes due to varying VOC concentrations (the higher the concentration of reducing VOCs,
* the lower the resistance and vice versa).
*/
BSEC_INPUT_GASRESISTOR = 4, /*!< */
/**
* @brief Additional input for device heat compensation
*
* IAQ solution: The value is subtracted from ::BSEC_INPUT_TEMPERATURE to compute
* ::BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_TEMPERATURE.
*
* ALL solution: Generic heat source 1
*
* @sa bsec_virtual_sensor_t
*/
BSEC_INPUT_HEATSOURCE = 14,
/**
* @brief Additional input for device heat compensation 8
*
* Generic heat source 8
*/
/**
* @brief Additional input that disables baseline tracker
*
* 0 - Normal
* 1 - Event 1
* 2 - Event 2
*/
BSEC_INPUT_DISABLE_BASELINE_TRACKER = 23,
} bsec_physical_sensor_t;
/*!
* @brief Enumeration for output (virtual) sensors
*
* Used to populate bsec_output_t::sensor_id. It is also used in bsec_sensor_configuration_t::sensor_id structs
* passed in the parameter requested_virtual_sensors of bsec_update_subscription().
*
* @sa bsec_sensor_configuration_t @sa bsec_output_t
*/
typedef enum
{
/**
* @brief Indoor-air-quality estimate [0-500]
*
* Indoor-air-quality (IAQ) gives an indication of the relative change in ambient TVOCs detected by BME680.
*
* @note The IAQ scale ranges from 0 (clean air) to 500 (heavily polluted air). During operation, algorithms
* automatically calibrate and adapt themselves to the typical environments where the sensor is operated
* (e.g., home, workplace, inside a car, etc.).This automatic background calibration ensures that users experience
* consistent IAQ performance. The calibration process considers the recent measurement history (typ. up to four
* days) to ensure that IAQ=25 corresponds to typical good air and IAQ=250 indicates typical polluted air.
*/
BSEC_OUTPUT_IAQ = 1,
BSEC_OUTPUT_STATIC_IAQ = 2, /*!< Unscaled indoor-air-quality estimate */
BSEC_OUTPUT_CO2_EQUIVALENT = 3, /*!< co2 equivalent estimate [ppm] */
BSEC_OUTPUT_BREATH_VOC_EQUIVALENT = 4, /*!< breath VOC concentration estimate [ppm] */
/**
* @brief Temperature sensor signal [degrees Celsius]
*
* Temperature directly measured by BME680 in degree Celsius.
*
* @note This value is cross-influenced by the sensor heating and device specific heating.
*/
BSEC_OUTPUT_RAW_TEMPERATURE = 6,
/**
* @brief Pressure sensor signal [Pa]
*
* Pressure directly measured by the BME680 in Pa.
*/
BSEC_OUTPUT_RAW_PRESSURE = 7,
/**
* @brief Relative humidity sensor signal [%]
*
* Relative humidity directly measured by the BME680 in %.
*
* @note This value is cross-influenced by the sensor heating and device specific heating.
*/
BSEC_OUTPUT_RAW_HUMIDITY = 8,
/**
* @brief Gas sensor signal [Ohm]
*
* Gas resistance measured directly by the BME680 in Ohm.The resistance value changes due to varying VOC
* concentrations (the higher the concentration of reducing VOCs, the lower the resistance and vice versa).
*/
BSEC_OUTPUT_RAW_GAS = 9,
/**
* @brief Gas sensor stabilization status [boolean]
*
* Indicates initial stabilization status of the gas sensor element: stabilization is ongoing (0) or stabilization
* is finished (1).
*/
BSEC_OUTPUT_STABILIZATION_STATUS = 12,
/**
* @brief Gas sensor run-in status [boolean]
*
* Indicates power-on stabilization status of the gas sensor element: stabilization is ongoing (0) or stabilization
* is finished (1).
*/
BSEC_OUTPUT_RUN_IN_STATUS = 13,
/**
* @brief Sensor heat compensated temperature [degrees Celsius]
*
* Temperature measured by BME680 which is compensated for the influence of sensor (heater) in degree Celsius.
* The self heating introduced by the heater is depending on the sensor operation mode and the sensor supply voltage.
*
*
* @note IAQ solution: In addition, the temperature output can be compensated by an user defined value
* (::BSEC_INPUT_HEATSOURCE in degrees Celsius), which represents the device specific self-heating.
*
* Thus, the value is calculated as follows:
* * IAQ solution: ```BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_TEMPERATURE = ::BSEC_INPUT_TEMPERATURE - function(sensor operation mode, sensor supply voltage) - ::BSEC_INPUT_HEATSOURCE```
* * other solutions: ```::BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_TEMPERATURE = ::BSEC_INPUT_TEMPERATURE - function(sensor operation mode, sensor supply voltage)```
*
* The self-heating in operation mode BSEC_SAMPLE_RATE_ULP is negligible.
* The self-heating in operation mode BSEC_SAMPLE_RATE_LP is supported for 1.8V by default (no config file required). If the BME680 sensor supply voltage is 3.3V, the IoT_LP_3_3V.config shall be used.
*/
BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_TEMPERATURE = 14,
/**
* @brief Sensor heat compensated humidity [%]
*
* Relative measured by BME680 which is compensated for the influence of sensor (heater) in %.
*
* It converts the ::BSEC_INPUT_HUMIDITY from temperature ::BSEC_INPUT_TEMPERATURE to temperature
* ::BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_TEMPERATURE.
*
* @note IAQ solution: If ::BSEC_INPUT_HEATSOURCE is used for device specific temperature compensation, it will be
* effective for ::BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_HUMIDITY too.
*/
BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_HUMIDITY = 15,
BSEC_OUTPUT_COMPENSATED_GAS = 18, /*!< Reserved internal debug output */
BSEC_OUTPUT_GAS_PERCENTAGE = 21 /*!< percentage of min and max filtered gas value [%] */
} bsec_virtual_sensor_t;
/*!
* @brief Enumeration for function return codes
*/
typedef enum
{
BSEC_OK = 0, /*!< Function execution successful */
BSEC_E_DOSTEPS_INVALIDINPUT = -1, /*!< Input (physical) sensor id passed to bsec_do_steps() is not in the valid range or not valid for requested virtual sensor */
BSEC_E_DOSTEPS_VALUELIMITS = -2, /*!< Value of input (physical) sensor signal passed to bsec_do_steps() is not in the valid range */
BSEC_E_DOSTEPS_DUPLICATEINPUT = -6, /*!< Duplicate input (physical) sensor ids passed as input to bsec_do_steps() */
BSEC_I_DOSTEPS_NOOUTPUTSRETURNABLE = 2, /*!< No memory allocated to hold return values from bsec_do_steps(), i.e., n_outputs == 0 */
BSEC_W_DOSTEPS_EXCESSOUTPUTS = 3, /*!< Not enough memory allocated to hold return values from bsec_do_steps(), i.e., n_outputs < maximum number of requested output (virtual) sensors */
BSEC_W_DOSTEPS_TSINTRADIFFOUTOFRANGE = 4, /*!< Duplicate timestamps passed to bsec_do_steps() */
BSEC_E_SU_WRONGDATARATE = -10, /*!< The sample_rate of the requested output (virtual) sensor passed to bsec_update_subscription() is zero */
BSEC_E_SU_SAMPLERATELIMITS = -12, /*!< The sample_rate of the requested output (virtual) sensor passed to bsec_update_subscription() does not match with the sampling rate allowed for that sensor */
BSEC_E_SU_DUPLICATEGATE = -13, /*!< Duplicate output (virtual) sensor ids requested through bsec_update_subscription() */
BSEC_E_SU_INVALIDSAMPLERATE = -14, /*!< The sample_rate of the requested output (virtual) sensor passed to bsec_update_subscription() does not fall within the global minimum and maximum sampling rates */
BSEC_E_SU_GATECOUNTEXCEEDSARRAY = -15, /*!< Not enough memory allocated to hold returned input (physical) sensor data from bsec_update_subscription(), i.e., n_required_sensor_settings < #BSEC_MAX_PHYSICAL_SENSOR */
BSEC_E_SU_SAMPLINTVLINTEGERMULT = -16, /*!< The sample_rate of the requested output (virtual) sensor passed to bsec_update_subscription() is not correct */
BSEC_E_SU_MULTGASSAMPLINTVL = -17, /*!< The sample_rate of the requested output (virtual), which requires the gas sensor, is not equal to the sample_rate that the gas sensor is being operated */
BSEC_E_SU_HIGHHEATERONDURATION = -18, /*!< The duration of one measurement is longer than the requested sampling interval */
BSEC_W_SU_UNKNOWNOUTPUTGATE = 10, /*!< Output (virtual) sensor id passed to bsec_update_subscription() is not in the valid range; e.g., n_requested_virtual_sensors > actual number of output (virtual) sensors requested */
BSEC_W_SU_MODINNOULP = 11, /*!< ULP plus can not be requested in non-ulp mode */ /*MOD_ONLY*/
BSEC_I_SU_SUBSCRIBEDOUTPUTGATES = 12, /*!< No output (virtual) sensor data were requested via bsec_update_subscription() */
BSEC_E_PARSE_SECTIONEXCEEDSWORKBUFFER = -32, /*!< n_work_buffer_size passed to bsec_set_[configuration/state]() not sufficient */
BSEC_E_CONFIG_FAIL = -33, /*!< Configuration failed */
BSEC_E_CONFIG_VERSIONMISMATCH = -34, /*!< Version encoded in serialized_[settings/state] passed to bsec_set_[configuration/state]() does not match with current version */
BSEC_E_CONFIG_FEATUREMISMATCH = -35, /*!< Enabled features encoded in serialized_[settings/state] passed to bsec_set_[configuration/state]() does not match with current library implementation */
BSEC_E_CONFIG_CRCMISMATCH = -36, /*!< serialized_[settings/state] passed to bsec_set_[configuration/state]() is corrupted */
BSEC_E_CONFIG_EMPTY = -37, /*!< n_serialized_[settings/state] passed to bsec_set_[configuration/state]() is to short to be valid */
BSEC_E_CONFIG_INSUFFICIENTWORKBUFFER = -38, /*!< Provided work_buffer is not large enough to hold the desired string */
BSEC_E_CONFIG_INVALIDSTRINGSIZE = -40, /*!< String size encoded in configuration/state strings passed to bsec_set_[configuration/state]() does not match with the actual string size n_serialized_[settings/state] passed to these functions */
BSEC_E_CONFIG_INSUFFICIENTBUFFER = -41, /*!< String buffer insufficient to hold serialized data from BSEC library */
BSEC_E_SET_INVALIDCHANNELIDENTIFIER = -100, /*!< Internal error code, size of work buffer in setConfig must be set to BSEC_MAX_WORKBUFFER_SIZE */
BSEC_E_SET_INVALIDLENGTH = -104, /*!< Internal error code */
BSEC_W_SC_CALL_TIMING_VIOLATION = 100, /*!< Difference between actual and defined sampling intervals of bsec_sensor_control() greater than allowed */
BSEC_W_SC_MODEXCEEDULPTIMELIMIT = 101, /*!< ULP plus is not allowed because an ULP measurement just took or will take place */ /*MOD_ONLY*/
BSEC_W_SC_MODINSUFFICIENTWAITTIME = 102 /*!< ULP plus is not allowed because not sufficient time passed since last ULP plus */ /*MOD_ONLY*/
} bsec_library_return_t;
/*!
* @brief Structure containing the version information
*
* Please note that configuration and state strings are coded to a specific version and will not be accepted by other
* versions of BSEC.
*
*/
typedef struct
{
uint8_t major; /**< @brief Major version */
uint8_t minor; /**< @brief Minor version */
uint8_t major_bugfix; /**< @brief Major bug fix version */
uint8_t minor_bugfix; /**< @brief Minor bug fix version */
} bsec_version_t;
/*!
* @brief Structure describing an input sample to the library
*
* Each input sample is provided to BSEC as an element in a struct array of this type. Timestamps must be provided
* in nanosecond resolution. Moreover, duplicate timestamps for subsequent samples are not allowed and will results in
* an error code being returned from bsec_do_steps().
*
* The meaning unit of the signal field are determined by the bsec_input_t::sensor_id field content. Possible
* bsec_input_t::sensor_id values and and their meaning are described in ::bsec_physical_sensor_t.
*
* @sa bsec_physical_sensor_t
*
*/
typedef struct
{
/**
* @brief Time stamp in nanosecond resolution [ns]
*
* Timestamps must be provided as non-repeating and increasing values. They can have their 0-points at system start or
* at a defined wall-clock time (e.g., 01-Jan-1970 00:00:00)
*/
int64_t time_stamp;
float signal; /*!< @brief Signal sample in the unit defined for the respective sensor_id @sa bsec_physical_sensor_t */
uint8_t signal_dimensions; /*!< @brief Signal dimensions (reserved for future use, shall be set to 1) */
uint8_t sensor_id; /*!< @brief Identifier of physical sensor @sa bsec_physical_sensor_t */
} bsec_input_t;
/*!
* @brief Structure describing an output sample of the library
*
* Each output sample is returned from BSEC by populating the element of a struct array of this type. The contents of
* the signal field is defined by the supplied bsec_output_t::sensor_id. Possible output
* bsec_output_t::sensor_id values are defined in ::bsec_virtual_sensor_t.
*
* @sa bsec_virtual_sensor_t
*/
typedef struct
{
int64_t time_stamp; /*!< @brief Time stamp in nanosecond resolution as provided as input [ns] */
float signal; /*!< @brief Signal sample in the unit defined for the respective bsec_output_t::sensor_id @sa bsec_virtual_sensor_t */
uint8_t signal_dimensions; /*!< @brief Signal dimensions (reserved for future use, shall be set to 1) */
uint8_t sensor_id; /*!< @brief Identifier of virtual sensor @sa bsec_virtual_sensor_t */
/**
* @brief Accuracy status 0-3
*
* Some virtual sensors provide a value in the accuracy field. If this is the case, the meaning of the field is as
* follows:
*
* | Name | Value | Accuracy description |
* |----------------------------|-------|-------------------------------------------------------------|
* | UNRELIABLE | 0 | Sensor data is unreliable, the sensor must be calibrated |
* | LOW_ACCURACY | 1 | Low accuracy, sensor should be calibrated |
* | MEDIUM_ACCURACY | 2 | Medium accuracy, sensor calibration may improve performance |
* | HIGH_ACCURACY | 3 | High accuracy |
*
* For example:
*
* - Ambient temperature accuracy is derived from change in the temperature in 1 minute.
*
* | Virtual sensor | Value | Accuracy description |
* |--------------------- |-------|------------------------------------------------------------------------------|
* | Ambient temperature | 0 | The difference in ambient temperature is greater than 4 degree in one minute |
* | | 1 | The difference in ambient temperature is less than 4 degree in one minute |
* | | 2 | The difference in ambient temperature is less than 3 degree in one minute |
* | | 3 | The difference in ambient temperature is less than 2 degree in one minute |
*
* - IAQ accuracy indicator will notify the user when she/he should initiate a calibration process. Calibration is
* performed automatically in the background if the sensor is exposed to clean and polluted air for approximately
* 30 minutes each.
*
* | Virtual sensor | Value | Accuracy description |
* |----------------------------|-------|-----------------------------------------------------------------|
* | IAQ | 0 | The sensor is not yet stabilized or in a run-in status |
* | | 1 | Calibration required |
* | | 2 | Calibration on-going |
* | | 3 | Calibration is done, now IAQ estimate achieves best performance |
*/
uint8_t accuracy;
} bsec_output_t;
/*!
* @brief Structure describing sample rate of physical/virtual sensors
*
* This structure is used together with bsec_update_subscription() to enable BSEC outputs and to retrieve information
* about the sample rates used for BSEC inputs.
*/
typedef struct
{
/**
* @brief Sample rate of the virtual or physical sensor in Hertz [Hz]
*
* Only supported sample rates are allowed.
*/
float sample_rate;
/**
* @brief Identifier of the virtual or physical sensor
*
* The meaning of this field changes depending on whether the structs are as the requested_virtual_sensors argument
* to bsec_update_subscription() or as the required_sensor_settings argument.
*
* | bsec_update_subscription() argument | sensor_id field interpretation |
* |-------------------------------------|--------------------------------|
* | requested_virtual_sensors | ::bsec_virtual_sensor_t |
* | required_sensor_settings | ::bsec_physical_sensor_t |
*
* @sa bsec_physical_sensor_t
* @sa bsec_virtual_sensor_t
*/
uint8_t sensor_id;
} bsec_sensor_configuration_t;
/*!
* @brief Structure returned by bsec_sensor_control() to configure BMExxx sensor
*
* This structure contains settings that must be used to configure the BMExxx to perform a forced-mode measurement.
* A measurement should only be executed if bsec_bme_settings_t::trigger_measurement is 1. If so, the oversampling
* settings for temperature, humidity, and pressure should be set to the provided settings provided in
* bsec_bme_settings_t::temperature_oversampling, bsec_bme_settings_t::humidity_oversampling, and
* bsec_bme_settings_t::pressure_oversampling, respectively.
*
* In case of bsec_bme_settings_t::run_gas = 1, the gas sensor must be enabled with the provided
* bsec_bme_settings_t::heater_temperature and bsec_bme_settings_t::heating_duration settings.
*/
typedef struct
{
int64_t next_call; /*!< @brief Time stamp of the next call of the sensor_control*/
uint32_t process_data; /*!< @brief Bit field describing which data is to be passed to bsec_do_steps() @sa BSEC_PROCESS_* */
uint16_t heater_temperature; /*!< @brief Heating temperature [degrees Celsius] */
uint16_t heating_duration; /*!< @brief Heating duration [ms] */
uint8_t run_gas; /*!< @brief Enable gas measurements [0/1] */
uint8_t pressure_oversampling; /*!< @brief Pressure oversampling settings [0-5] */
uint8_t temperature_oversampling; /*!< @brief Temperature oversampling settings [0-5] */
uint8_t humidity_oversampling; /*!< @brief Humidity oversampling settings [0-5] */
uint8_t trigger_measurement; /*!< @brief Trigger a forced measurement with these settings now [0/1] */
} bsec_bme_settings_t;
/* internal defines and backward compatibility */
#define BSEC_STRUCT_NAME Bsec /*!< Internal struct name */
/*@}*/
#ifdef __cplusplus
}
#endif
#endif

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@ -0,0 +1,559 @@
/*
* Copyright (C) 2017 Robert Bosch. All Rights Reserved.
*
* Disclaimer
*
* Common:
* Bosch Sensortec products are developed for the consumer goods industry. They may only be used
* within the parameters of the respective valid product data sheet. Bosch Sensortec products are
* provided with the express understanding that there is no warranty of fitness for a particular purpose.
* They are not fit for use in life-sustaining, safety or security sensitive systems or any system or device
* that may lead to bodily harm or property damage if the system or device malfunctions. In addition,
* Bosch Sensortec products are not fit for use in products which interact with motor vehicle systems.
* The resale and/or use of products are at the purchasers own risk and his own responsibility. The
* examination of fitness for the intended use is the sole responsibility of the Purchaser.
*
* The purchaser shall indemnify Bosch Sensortec from all third party claims, including any claims for
* incidental, or consequential damages, arising from any product use not covered by the parameters of
* the respective valid product data sheet or not approved by Bosch Sensortec and reimburse Bosch
* Sensortec for all costs in connection with such claims.
*
* The purchaser must monitor the market for the purchased products, particularly with regard to
* product safety and inform Bosch Sensortec without delay of all security relevant incidents.
*
* Engineering Samples are marked with an asterisk (*) or (e). Samples may vary from the valid
* technical specifications of the product series. They are therefore not intended or fit for resale to third
* parties or for use in end products. Their sole purpose is internal client testing. The testing of an
* engineering sample may in no way replace the testing of a product series. Bosch Sensortec
* assumes no liability for the use of engineering samples. By accepting the engineering samples, the
* Purchaser agrees to indemnify Bosch Sensortec from all claims arising from the use of engineering
* samples.
*
* Special:
* This software module (hereinafter called "Software") and any information on application-sheets
* (hereinafter called "Information") is provided free of charge for the sole purpose to support your
* application work. The Software and Information is subject to the following terms and conditions:
*
* The Software is specifically designed for the exclusive use for Bosch Sensortec products by
* personnel who have special experience and training. Do not use this Software if you do not have the
* proper experience or training.
*
* This Software package is provided `` as is `` and without any expressed or implied warranties,
* including without limitation, the implied warranties of merchantability and fitness for a particular
* purpose.
*
* Bosch Sensortec and their representatives and agents deny any liability for the functional impairment
* of this Software in terms of fitness, performance and safety. Bosch Sensortec and their
* representatives and agents shall not be liable for any direct or indirect damages or injury, except as
* otherwise stipulated in mandatory applicable law.
*
* The Information provided is believed to be accurate and reliable. Bosch Sensortec assumes no
* responsibility for the consequences of use of such Information nor for any infringement of patents or
* other rights of third parties which may result from its use. No license is granted by implication or
* otherwise under any patent or patent rights of Bosch. Specifications mentioned in the Information are
* subject to change without notice.
*
* It is not allowed to deliver the source code of the Software to any third party without permission of
* Bosch Sensortec.
*
*/
/*!
* @file bsec_integration.c
*
* @brief
* Private part of the example for using of BSEC library.
*/
/*!
* @addtogroup bsec_examples BSEC Examples
* @brief BSEC usage examples
* @{*/
/**********************************************************************************************************************/
/* header files */
/**********************************************************************************************************************/
#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include "bsec_integration.h"
/**********************************************************************************************************************/
/* local macro definitions */
/**********************************************************************************************************************/
#define NUM_USED_OUTPUTS 8
/**********************************************************************************************************************/
/* global variable declarations */
/**********************************************************************************************************************/
/* Global sensor APIs data structure */
static struct bme680_dev bme680_g;
/* Global temperature offset to be subtracted */
static float bme680_temperature_offset_g = 0.0f;
/**********************************************************************************************************************/
/* functions */
/**********************************************************************************************************************/
/*!
* @brief Virtual sensor subscription
* Please call this function before processing of data using bsec_do_steps function
*
* @param[in] sample_rate mode to be used (either BSEC_SAMPLE_RATE_ULP or BSEC_SAMPLE_RATE_LP)
*
* @return subscription result, zero when successful
*/
static bsec_library_return_t bme680_bsec_update_subscription(float sample_rate)
{
bsec_sensor_configuration_t requested_virtual_sensors[NUM_USED_OUTPUTS];
uint8_t n_requested_virtual_sensors = NUM_USED_OUTPUTS;
bsec_sensor_configuration_t required_sensor_settings[BSEC_MAX_PHYSICAL_SENSOR];
uint8_t n_required_sensor_settings = BSEC_MAX_PHYSICAL_SENSOR;
bsec_library_return_t status = BSEC_OK;
/* note: Virtual sensors as desired to be added here */
requested_virtual_sensors[0].sensor_id = BSEC_OUTPUT_IAQ;
requested_virtual_sensors[0].sample_rate = sample_rate;
requested_virtual_sensors[1].sensor_id = BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_TEMPERATURE;
requested_virtual_sensors[1].sample_rate = sample_rate;
requested_virtual_sensors[2].sensor_id = BSEC_OUTPUT_RAW_PRESSURE;
requested_virtual_sensors[2].sample_rate = sample_rate;
requested_virtual_sensors[3].sensor_id = BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_HUMIDITY;
requested_virtual_sensors[3].sample_rate = sample_rate;
requested_virtual_sensors[4].sensor_id = BSEC_OUTPUT_RAW_GAS;
requested_virtual_sensors[4].sample_rate = sample_rate;
requested_virtual_sensors[5].sensor_id = BSEC_OUTPUT_RAW_TEMPERATURE;
requested_virtual_sensors[5].sample_rate = sample_rate;
requested_virtual_sensors[6].sensor_id = BSEC_OUTPUT_RAW_HUMIDITY;
requested_virtual_sensors[6].sample_rate = sample_rate;
requested_virtual_sensors[7].sensor_id = BSEC_OUTPUT_STATIC_IAQ;
requested_virtual_sensors[7].sample_rate = sample_rate;
/* Call bsec_update_subscription() to enable/disable the requested virtual sensors */
status = bsec_update_subscription(requested_virtual_sensors, n_requested_virtual_sensors, required_sensor_settings,
&n_required_sensor_settings);
return status;
}
/*!
* @brief Initialize the BME680 sensor and the BSEC library
*
* @param[in] sample_rate mode to be used (either BSEC_SAMPLE_RATE_ULP or BSEC_SAMPLE_RATE_LP)
* @param[in] temperature_offset device-specific temperature offset (due to self-heating)
* @param[in] bus_write pointer to the bus writing function
* @param[in] bus_read pointer to the bus reading function
* @param[in] sleep pointer to the system specific sleep function
* @param[in] state_load pointer to the system-specific state load function
* @param[in] config_load pointer to the system-specific config load function
*
* @return zero if successful, negative otherwise
*/
return_values_init bsec_iot_init(float sample_rate, float temperature_offset, bme680_com_fptr_t bus_write,
bme680_com_fptr_t bus_read, sleep_fct sleep, state_load_fct state_load, config_load_fct config_load)
{
return_values_init ret = {BME680_OK, BSEC_OK};
bsec_library_return_t bsec_status = BSEC_OK;
uint8_t bsec_state[BSEC_MAX_PROPERTY_BLOB_SIZE] = {0};
uint8_t bsec_config[BSEC_MAX_PROPERTY_BLOB_SIZE] = {0};
uint8_t work_buffer[BSEC_MAX_PROPERTY_BLOB_SIZE] = {0};
int bsec_state_len, bsec_config_len;
/* Fixed I2C configuration */
bme680_g.dev_id = BME680_I2C_ADDR_PRIMARY;
bme680_g.intf = BME680_I2C_INTF;
/* User configurable I2C configuration */
bme680_g.write = bus_write;
bme680_g.read = bus_read;
bme680_g.delay_ms = sleep;
/* Initialize BME680 API */
ret.bme680_status = bme680_init(&bme680_g);
if (ret.bme680_status != BME680_OK)
{
return ret;
}
/* Initialize BSEC library */
ret.bsec_status = bsec_init();
if (ret.bsec_status != BSEC_OK)
{
return ret;
}
/* Load library config, if available */
bsec_config_len = config_load(bsec_config, sizeof(bsec_config));
if (bsec_config_len != 0)
{
ret.bsec_status = bsec_set_configuration(bsec_config, bsec_config_len, work_buffer, sizeof(work_buffer));
if (ret.bsec_status != BSEC_OK)
{
return ret;
}
}
/* Load previous library state, if available */
bsec_state_len = state_load(bsec_state, sizeof(bsec_state));
if (bsec_state_len != 0)
{
ret.bsec_status = bsec_set_state(bsec_state, bsec_state_len, work_buffer, sizeof(work_buffer));
if (ret.bsec_status != BSEC_OK)
{
return ret;
}
}
/* Set temperature offset */
bme680_temperature_offset_g = temperature_offset;
/* Call to the function which sets the library with subscription information */
ret.bsec_status = bme680_bsec_update_subscription(sample_rate);
if (ret.bsec_status != BSEC_OK)
{
return ret;
}
return ret;
}
/*!
* @brief Trigger the measurement based on sensor settings
*
* @param[in] sensor_settings settings of the BME680 sensor adopted by sensor control function
* @param[in] sleep pointer to the system specific sleep function
*
* @return none
*/
static void bme680_bsec_trigger_measurement(bsec_bme_settings_t *sensor_settings, sleep_fct sleep)
{
uint16_t meas_period;
uint8_t set_required_settings;
int8_t bme680_status = BME680_OK;
/* Check if a forced-mode measurement should be triggered now */
if (sensor_settings->trigger_measurement)
{
/* Set sensor configuration */
bme680_g.tph_sett.os_hum = sensor_settings->humidity_oversampling;
bme680_g.tph_sett.os_pres = sensor_settings->pressure_oversampling;
bme680_g.tph_sett.os_temp = sensor_settings->temperature_oversampling;
bme680_g.gas_sett.run_gas = sensor_settings->run_gas;
bme680_g.gas_sett.heatr_temp = sensor_settings->heater_temperature; /* degree Celsius */
bme680_g.gas_sett.heatr_dur = sensor_settings->heating_duration; /* milliseconds */
/* Select the power mode */
/* Must be set before writing the sensor configuration */
bme680_g.power_mode = BME680_FORCED_MODE;
/* Set the required sensor settings needed */
set_required_settings = BME680_OST_SEL | BME680_OSP_SEL | BME680_OSH_SEL | BME680_GAS_SENSOR_SEL;
/* Set the desired sensor configuration */
bme680_status = bme680_set_sensor_settings(set_required_settings, &bme680_g);
/* Set power mode as forced mode and trigger forced mode measurement */
bme680_status = bme680_set_sensor_mode(&bme680_g);
/* Get the total measurement duration so as to sleep or wait till the measurement is complete */
bme680_get_profile_dur(&meas_period, &bme680_g);
/* Delay till the measurement is ready. Timestamp resolution in ms */
sleep((uint32_t)meas_period);
}
/* Call the API to get current operation mode of the sensor */
bme680_status = bme680_get_sensor_mode(&bme680_g);
/* When the measurement is completed and data is ready for reading, the sensor must be in BME680_SLEEP_MODE.
* Read operation mode to check whether measurement is completely done and wait until the sensor is no more
* in BME680_FORCED_MODE. */
while (bme680_g.power_mode == BME680_FORCED_MODE)
{
/* sleep for 5 ms */
sleep(5);
bme680_status = bme680_get_sensor_mode(&bme680_g);
}
}
/*!
* @brief Read the data from registers and populate the inputs structure to be passed to do_steps function
*
* @param[in] time_stamp_trigger settings of the sensor returned from sensor control function
* @param[in] inputs input structure containing the information on sensors to be passed to do_steps
* @param[in] num_bsec_inputs number of inputs to be passed to do_steps
* @param[in] bsec_process_data process data variable returned from sensor_control
*
* @return none
*/
static void bme680_bsec_read_data(int64_t time_stamp_trigger, bsec_input_t *inputs, uint8_t *num_bsec_inputs,
int32_t bsec_process_data)
{
static struct bme680_field_data data;
int8_t bme680_status = BME680_OK;
/* We only have to read data if the previous call the bsec_sensor_control() actually asked for it */
if (bsec_process_data)
{
bme680_status = bme680_get_sensor_data(&data, &bme680_g);
if (data.status & BME680_NEW_DATA_MSK)
{
/* Pressure to be processed by BSEC */
if (bsec_process_data & BSEC_PROCESS_PRESSURE)
{
/* Place presssure sample into input struct */
inputs[*num_bsec_inputs].sensor_id = BSEC_INPUT_PRESSURE;
inputs[*num_bsec_inputs].signal = data.pressure;
inputs[*num_bsec_inputs].time_stamp = time_stamp_trigger;
(*num_bsec_inputs)++;
}
/* Temperature to be processed by BSEC */
if (bsec_process_data & BSEC_PROCESS_TEMPERATURE)
{
/* Place temperature sample into input struct */
inputs[*num_bsec_inputs].sensor_id = BSEC_INPUT_TEMPERATURE;
#ifdef BME680_FLOAT_POINT_COMPENSATION
inputs[*num_bsec_inputs].signal = data.temperature;
#else
inputs[*num_bsec_inputs].signal = data.temperature / 100.0f;
#endif
inputs[*num_bsec_inputs].time_stamp = time_stamp_trigger;
(*num_bsec_inputs)++;
/* Also add optional heatsource input which will be subtracted from the temperature reading to
* compensate for device-specific self-heating (supported in BSEC IAQ solution)*/
inputs[*num_bsec_inputs].sensor_id = BSEC_INPUT_HEATSOURCE;
inputs[*num_bsec_inputs].signal = bme680_temperature_offset_g;
inputs[*num_bsec_inputs].time_stamp = time_stamp_trigger;
(*num_bsec_inputs)++;
}
/* Humidity to be processed by BSEC */
if (bsec_process_data & BSEC_PROCESS_HUMIDITY)
{
/* Place humidity sample into input struct */
inputs[*num_bsec_inputs].sensor_id = BSEC_INPUT_HUMIDITY;
#ifdef BME680_FLOAT_POINT_COMPENSATION
inputs[*num_bsec_inputs].signal = data.humidity;
#else
inputs[*num_bsec_inputs].signal = data.humidity / 1000.0f;
#endif
inputs[*num_bsec_inputs].time_stamp = time_stamp_trigger;
(*num_bsec_inputs)++;
}
/* Gas to be processed by BSEC */
if (bsec_process_data & BSEC_PROCESS_GAS)
{
/* Check whether gas_valid flag is set */
if(data.status & BME680_GASM_VALID_MSK)
{
/* Place sample into input struct */
inputs[*num_bsec_inputs].sensor_id = BSEC_INPUT_GASRESISTOR;
inputs[*num_bsec_inputs].signal = data.gas_resistance;
inputs[*num_bsec_inputs].time_stamp = time_stamp_trigger;
(*num_bsec_inputs)++;
}
}
}
}
}
/*!
* @brief This function is written to process the sensor data for the requested virtual sensors
*
* @param[in] bsec_inputs input structure containing the information on sensors to be passed to do_steps
* @param[in] num_bsec_inputs number of inputs to be passed to do_steps
* @param[in] output_ready pointer to the function processing obtained BSEC outputs
*
* @return none
*/
static void bme680_bsec_process_data(bsec_input_t *bsec_inputs, uint8_t num_bsec_inputs, output_ready_fct output_ready)
{
/* Output buffer set to the maximum virtual sensor outputs supported */
bsec_output_t bsec_outputs[BSEC_NUMBER_OUTPUTS];
uint8_t num_bsec_outputs = 0;
uint8_t index = 0;
bsec_library_return_t bsec_status = BSEC_OK;
int64_t timestamp = 0;
float iaq = 0.0f;
uint8_t iaq_accuracy = 0;
float temp = 0.0f;
float raw_temp = 0.0f;
float raw_pressure = 0.0f;
float humidity = 0.0f;
float raw_humidity = 0.0f;
float raw_gas = 0.0f;
float static_iaq = 0.0f;
uint8_t static_iaq_accuracy = 0;
float co2_equivalent = 0.0f;
uint8_t co2_accuracy = 0;
float breath_voc_equivalent = 0.0f;
uint8_t breath_voc_accuracy = 0;
float comp_gas_value = 0.0f;
uint8_t comp_gas_accuracy = 0;
float gas_percentage = 0.0f;
uint8_t gas_percentage_acccuracy = 0;
/* Check if something should be processed by BSEC */
if (num_bsec_inputs > 0)
{
/* Set number of outputs to the size of the allocated buffer */
/* BSEC_NUMBER_OUTPUTS to be defined */
num_bsec_outputs = BSEC_NUMBER_OUTPUTS;
/* Perform processing of the data by BSEC
Note:
* The number of outputs you get depends on what you asked for during bsec_update_subscription(). This is
handled under bme680_bsec_update_subscription() function in this example file.
* The number of actual outputs that are returned is written to num_bsec_outputs. */
bsec_status = bsec_do_steps(bsec_inputs, num_bsec_inputs, bsec_outputs, &num_bsec_outputs);
/* Iterate through the outputs and extract the relevant ones. */
for (index = 0; index < num_bsec_outputs; index++)
{
switch (bsec_outputs[index].sensor_id)
{
case BSEC_OUTPUT_IAQ:
iaq = bsec_outputs[index].signal;
iaq_accuracy = bsec_outputs[index].accuracy;
break;
case BSEC_OUTPUT_STATIC_IAQ:
static_iaq = bsec_outputs[index].signal;
static_iaq_accuracy = bsec_outputs[index].accuracy;
break;
case BSEC_OUTPUT_CO2_EQUIVALENT:
co2_equivalent = bsec_outputs[index].signal;
co2_accuracy = bsec_outputs[index].accuracy;
break;
case BSEC_OUTPUT_BREATH_VOC_EQUIVALENT:
breath_voc_equivalent = bsec_outputs[index].signal;
breath_voc_accuracy = bsec_outputs[index].accuracy;
break;
case BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_TEMPERATURE:
temp = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_RAW_PRESSURE:
raw_pressure = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_HUMIDITY:
humidity = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_RAW_GAS:
raw_gas = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_RAW_TEMPERATURE:
raw_temp = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_RAW_HUMIDITY:
raw_humidity = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_COMPENSATED_GAS:
comp_gas_value = bsec_outputs[index].signal;
comp_gas_accuracy = bsec_outputs[index].accuracy;
break;
case BSEC_OUTPUT_GAS_PERCENTAGE:
gas_percentage = bsec_outputs[index].signal;
gas_percentage_acccuracy = bsec_outputs[index].accuracy;
break;
default:
continue;
}
/* Assume that all the returned timestamps are the same */
timestamp = bsec_outputs[index].time_stamp;
}
/* Pass the extracted outputs to the user provided output_ready() function. */
output_ready(timestamp, iaq, iaq_accuracy, temp, humidity, raw_pressure, raw_temp,
raw_humidity, raw_gas, bsec_status, static_iaq, co2_equivalent, breath_voc_equivalent);
}
}
/*!
* @brief Runs the main (endless) loop that queries sensor settings, applies them, and processes the measured data
*
* @param[in] sleep pointer to the system specific sleep function
* @param[in] get_timestamp_us pointer to the system specific timestamp derivation function
* @param[in] output_ready pointer to the function processing obtained BSEC outputs
* @param[in] state_save pointer to the system-specific state save function
* @param[in] save_intvl interval at which BSEC state should be saved (in samples)
*
* @return none
*/
void bsec_iot_loop(sleep_fct sleep, get_timestamp_us_fct get_timestamp_us, output_ready_fct output_ready,
state_save_fct state_save, uint32_t save_intvl)
{
/* Timestamp variables */
int64_t time_stamp = 0;
int64_t time_stamp_interval_ms = 0;
/* Allocate enough memory for up to BSEC_MAX_PHYSICAL_SENSOR physical inputs*/
bsec_input_t bsec_inputs[BSEC_MAX_PHYSICAL_SENSOR];
/* Number of inputs to BSEC */
uint8_t num_bsec_inputs = 0;
/* BSEC sensor settings struct */
bsec_bme_settings_t sensor_settings;
/* Save state variables */
uint8_t bsec_state[BSEC_MAX_STATE_BLOB_SIZE];
uint8_t work_buffer[BSEC_MAX_STATE_BLOB_SIZE];
uint32_t bsec_state_len = 0;
uint32_t n_samples = 0;
bsec_library_return_t bsec_status = BSEC_OK;
while (1)
{
/* get the timestamp in nanoseconds before calling bsec_sensor_control() */
time_stamp = get_timestamp_us() * 1000;
/* Retrieve sensor settings to be used in this time instant by calling bsec_sensor_control */
bsec_sensor_control(time_stamp, &sensor_settings);
/* Trigger a measurement if necessary */
bme680_bsec_trigger_measurement(&sensor_settings, sleep);
/* Read data from last measurement */
num_bsec_inputs = 0;
bme680_bsec_read_data(time_stamp, bsec_inputs, &num_bsec_inputs, sensor_settings.process_data);
/* Time to invoke BSEC to perform the actual processing */
bme680_bsec_process_data(bsec_inputs, num_bsec_inputs, output_ready);
/* Increment sample counter */
n_samples++;
/* Retrieve and store state if the passed save_intvl */
if (n_samples >= save_intvl)
{
bsec_status = bsec_get_state(0, bsec_state, sizeof(bsec_state), work_buffer, sizeof(work_buffer), &bsec_state_len);
if (bsec_status == BSEC_OK)
{
state_save(bsec_state, bsec_state_len);
}
n_samples = 0;
}
/* Compute how long we can sleep until we need to call bsec_sensor_control() next */
/* Time_stamp is converted from microseconds to nanoseconds first and then the difference to milliseconds */
time_stamp_interval_ms = (sensor_settings.next_call - get_timestamp_us() * 1000) / 1000000;
if (time_stamp_interval_ms > 0)
{
sleep((uint32_t)time_stamp_interval_ms);
}
}
}
/*! @}*/

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@ -0,0 +1,165 @@
/*
* Copyright (C) 2017 Robert Bosch. All Rights Reserved.
*
* Disclaimer
*
* Common:
* Bosch Sensortec products are developed for the consumer goods industry. They may only be used
* within the parameters of the respective valid product data sheet. Bosch Sensortec products are
* provided with the express understanding that there is no warranty of fitness for a particular purpose.
* They are not fit for use in life-sustaining, safety or security sensitive systems or any system or device
* that may lead to bodily harm or property damage if the system or device malfunctions. In addition,
* Bosch Sensortec products are not fit for use in products which interact with motor vehicle systems.
* The resale and/or use of products are at the purchasers own risk and his own responsibility. The
* examination of fitness for the intended use is the sole responsibility of the Purchaser.
*
* The purchaser shall indemnify Bosch Sensortec from all third party claims, including any claims for
* incidental, or consequential damages, arising from any product use not covered by the parameters of
* the respective valid product data sheet or not approved by Bosch Sensortec and reimburse Bosch
* Sensortec for all costs in connection with such claims.
*
* The purchaser must monitor the market for the purchased products, particularly with regard to
* product safety and inform Bosch Sensortec without delay of all security relevant incidents.
*
* Engineering Samples are marked with an asterisk (*) or (e). Samples may vary from the valid
* technical specifications of the product series. They are therefore not intended or fit for resale to third
* parties or for use in end products. Their sole purpose is internal client testing. The testing of an
* engineering sample may in no way replace the testing of a product series. Bosch Sensortec
* assumes no liability for the use of engineering samples. By accepting the engineering samples, the
* Purchaser agrees to indemnify Bosch Sensortec from all claims arising from the use of engineering
* samples.
*
* Special:
* This software module (hereinafter called "Software") and any information on application-sheets
* (hereinafter called "Information") is provided free of charge for the sole purpose to support your
* application work. The Software and Information is subject to the following terms and conditions:
*
* The Software is specifically designed for the exclusive use for Bosch Sensortec products by
* personnel who have special experience and training. Do not use this Software if you do not have the
* proper experience or training.
*
* This Software package is provided `` as is `` and without any expressed or implied warranties,
* including without limitation, the implied warranties of merchantability and fitness for a particular
* purpose.
*
* Bosch Sensortec and their representatives and agents deny any liability for the functional impairment
* of this Software in terms of fitness, performance and safety. Bosch Sensortec and their
* representatives and agents shall not be liable for any direct or indirect damages or injury, except as
* otherwise stipulated in mandatory applicable law.
*
* The Information provided is believed to be accurate and reliable. Bosch Sensortec assumes no
* responsibility for the consequences of use of such Information nor for any infringement of patents or
* other rights of third parties which may result from its use. No license is granted by implication or
* otherwise under any patent or patent rights of Bosch. Specifications mentioned in the Information are
* subject to change without notice.
*
* It is not allowed to deliver the source code of the Software to any third party without permission of
* Bosch Sensortec.
*
*/
/*!
* @file bsec_integration.h
*
* @brief
* Contains BSEC integration API
*/
/*!
* @addtogroup bsec_examples BSEC Examples
* @brief BSEC usage examples
* @{*/
#ifndef __BSEC_INTEGRATION_H__
#define __BSEC_INTEGRATION_H__
#ifdef __cplusplus
extern "C"
{
#endif
/**********************************************************************************************************************/
/* header files */
/**********************************************************************************************************************/
/* Use the following bme680 driver: https://github.com/BoschSensortec/BME680_driver/releases/tag/bme680_v3.5.1 */
#include "bme680.h"
/* BSEC header files are available in the inc/ folder of the release package */
#include "bsec_interface.h"
#include "bsec_datatypes.h"
/**********************************************************************************************************************/
/* type definitions */
/**********************************************************************************************************************/
/* function pointer to the system specific sleep function */
typedef void (*sleep_fct)(uint32_t t_ms);
/* function pointer to the system specific timestamp derivation function */
typedef int64_t (*get_timestamp_us_fct)();
/* function pointer to the function processing obtained BSEC outputs */
typedef void (*output_ready_fct)(int64_t timestamp, float iaq, uint8_t iaq_accuracy, float temperature, float humidity,
float pressure, float raw_temperature, float raw_humidity, float gas, bsec_library_return_t bsec_status,
float static_iaq, float co2_equivalent, float breath_voc_equivalent);
/* function pointer to the function loading a previous BSEC state from NVM */
typedef uint32_t (*state_load_fct)(uint8_t *state_buffer, uint32_t n_buffer);
/* function pointer to the function saving BSEC state to NVM */
typedef void (*state_save_fct)(const uint8_t *state_buffer, uint32_t length);
/* function pointer to the function loading the BSEC configuration string from NVM */
typedef uint32_t (*config_load_fct)(uint8_t *state_buffer, uint32_t n_buffer);
/* structure definitions */
/* Structure with the return value from bsec_iot_init() */
typedef struct{
/*! Result of API execution status */
int8_t bme680_status;
/*! Result of BSEC library */
bsec_library_return_t bsec_status;
}return_values_init;
/**********************************************************************************************************************/
/* function declarations */
/**********************************************************************************************************************/
/*!
* @brief Initialize the BME680 sensor and the BSEC library
*
* @param[in] sample_rate mode to be used (either BSEC_SAMPLE_RATE_ULP or BSEC_SAMPLE_RATE_LP)
* @param[in] temperature_offset device-specific temperature offset (due to self-heating)
* @param[in] bus_write pointer to the bus writing function
* @param[in] bus_read pointer to the bus reading function
* @param[in] sleep pointer to the system-specific sleep function
* @param[in] state_load pointer to the system-specific state load function
*
* @return zero if successful, negative otherwise
*/
return_values_init bsec_iot_init(float sample_rate, float temperature_offset, bme680_com_fptr_t bus_write, bme680_com_fptr_t bus_read,
sleep_fct sleep, state_load_fct state_load, config_load_fct config_load);
/*!
* @brief Runs the main (endless) loop that queries sensor settings, applies them, and processes the measured data
*
* @param[in] sleep pointer to the system-specific sleep function
* @param[in] get_timestamp_us pointer to the system-specific timestamp derivation function
* @param[in] output_ready pointer to the function processing obtained BSEC outputs
* @param[in] state_save pointer to the system-specific state save function
* @param[in] save_intvl interval at which BSEC state should be saved (in samples)
*
* @return return_values_init struct with the result of the API and the BSEC library
*/
void bsec_iot_loop(sleep_fct sleep, get_timestamp_us_fct get_timestamp_us, output_ready_fct output_ready,
state_save_fct state_save, uint32_t save_intvl);
#ifdef __cplusplus
}
#endif
#endif /* __BSEC_INTEGRATION_H__ */
/*! @}*/

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/*
* Copyright (C) 2015, 2016, 2017 Robert Bosch. All Rights Reserved.
*
* Disclaimer
*
* Common:
* Bosch Sensortec products are developed for the consumer goods industry. They may only be used
* within the parameters of the respective valid product data sheet. Bosch Sensortec products are
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/*!
*
* @file bsec_interface.h
*
* @brief
* Contains the API for BSEC
*
*/
#ifndef __BSEC_INTERFACE_H__
#define __BSEC_INTERFACE_H__
#include "bsec_datatypes.h"
#ifdef __cplusplus
extern "C" {
#endif
/*! @addtogroup bsec_interface BSEC C Interface
* @brief Interfaces of BSEC signal processing library
*
* ### Interface usage
*
* The following provides a short overview on the typical operation sequence for BSEC.
*
* - Initialization of the library
*
* | Steps | Function |
* |---------------------------------------------------------------------|--------------------------|
* | Initialization of library | bsec_init() |
* | Update configuration settings (optional) | bsec_set_configuration() |
* | Restore the state of the library (optional) | bsec_set_state() |
*
*
* - The following function is called to enable output signals and define their sampling rate / operation mode.
*
* | Steps | Function |
* |---------------------------------------------|----------------------------|
* | Enable library outputs with specified mode | bsec_update_subscription() |
*
*
* - This table describes the main processing loop.
*
* | Steps | Function |
* |-------------------------------------------|----------------------------------|
* | Retrieve sensor settings to be used | bsec_sensor_control() |
* | Configure sensor and trigger measurement | See BME680 API and example codes |
* | Read results from sensor | See BME680 API and example codes |
* | Perform signal processing | bsec_do_steps() |
*
*
* - Before shutting down the system, the current state of BSEC can be retrieved and can then be used during
* re-initialization to continue processing.
*
* | Steps | Function |
* |----------------------------------------|-------------------|
* | To retrieve the current library state | bsec_get_state() |
*
*
*
* ### Configuration and state
*
* Values of variables belonging to a BSEC instance are divided into two groups:
* - Values **not updated by processing** of signals belong to the **configuration group**. If available, BSEC can be
* configured before use with a customer specific configuration string.
* - Values **updated during processing** are member of the **state group**. Saving and restoring of the state of BSEC
* is necessary to maintain previously estimated sensor models and baseline information which is important for best
* performance of the gas sensor outputs.
*
* @note BSEC library consists of adaptive algorithms which models the gas sensor which improves its performance over
* the time. These will be lost if library is initialized due to system reset. In order to avoid this situation
* library state shall be stored in non volatile memory so that it can be loaded after system reset.
*
*
* @{
*/
/*!
* @brief Return the version information of BSEC library
*
* @param [out] bsec_version_p pointer to struct which is to be populated with the version information
*
* @return Zero if successful, otherwise an error code
*
* See also: bsec_version_t
*
\code{.c}
// Example //
bsec_version_t version;
bsec_get_version(&version);
printf("BSEC version: %d.%d.%d.%d",version.major, version.minor, version.major_bugfix, version.minor_bugfix);
\endcode
*/
bsec_library_return_t bsec_get_version(bsec_version_t * bsec_version_p);
/*!
* @brief Initialize the library
*
* Initialization and reset of BSEC is performed by calling bsec_init(). Calling this function sets up the relation
* among all internal modules, initializes run-time dependent library states and resets the configuration and state
* of all BSEC signal processing modules to defaults.
*
* Before any further use, the library must be initialized. This ensure that all memory and states are in defined
* conditions prior to processing any data.
*
* @return Zero if successful, otherwise an error code
*
\code{.c}
// Initialize BSEC library before further use
bsec_init();
\endcode
*/
bsec_library_return_t bsec_init(void);
/*!
* @brief Subscribe to library virtual sensors outputs
*
* Use bsec_update_subscription() to instruct BSEC which of the processed output signals are requested at which sample rates.
* See ::bsec_virtual_sensor_t for available library outputs.
*
* Based on the requested virtual sensors outputs, BSEC will provide information about the required physical sensor input signals
* (see ::bsec_physical_sensor_t) with corresponding sample rates. This information is purely informational as bsec_sensor_control()
* will ensure the sensor is operated in the required manner. To disable a virtual sensor, set the sample rate to BSEC_SAMPLE_RATE_DISABLED.
*
* The subscription update using bsec_update_subscription() is apart from the signal processing one of the the most
* important functions. It allows to enable the desired library outputs. The function determines which physical input
* sensor signals are required at which sample rate to produce the virtual output sensor signals requested by the user.
* When this function returns with success, the requested outputs are called subscribed. A very important feature is the
* retaining of already subscribed outputs. Further outputs can be requested or disabled both individually and
* group-wise in addition to already subscribed outputs without changing them unless a change of already subscribed
* outputs is requested.
*
* @note The state of the library concerning the subscribed outputs cannot be retained among reboots.
*
* The interface of bsec_update_subscription() requires the usage of arrays of sensor configuration structures.
* Such a structure has the fields sensor identifier and sample rate. These fields have the properties:
* - Output signals of virtual sensors must be requested using unique identifiers (Member of ::bsec_virtual_sensor_t)
* - Different sets of identifiers are available for inputs of physical sensors and outputs of virtual sensors
* - Identifiers are unique values defined by the library, not from external
* - Sample rates must be provided as value of
* - An allowed sample rate for continuously sampled signals
* - 65535.0f (BSEC_SAMPLE_RATE_DISABLED) to turn off outputs and identify disabled inputs
*
* @note The same sensor identifiers are also used within the functions bsec_do_steps().
*
* The usage principles of bsec_update_subscription() are:
* - Differential updates (i.e., only asking for outputs that the user would like to change) is supported.
* - Invalid requests of outputs are ignored. Also if one of the requested outputs is unavailable, all the requests
* are ignored. At the same time, a warning is returned.
* - To disable BSEC, all outputs shall be turned off. Only enabled (subscribed) outputs have to be disabled while
* already disabled outputs do not have to be disabled explicitly.
*
* @param[in] requested_virtual_sensors Pointer to array of requested virtual sensor (output) configurations for the library
* @param[in] n_requested_virtual_sensors Number of virtual sensor structs pointed by requested_virtual_sensors
* @param[out] required_sensor_settings Pointer to array of required physical sensor configurations for the library
* @param[in,out] n_required_sensor_settings [in] Size of allocated required_sensor_settings array, [out] number of sensor configurations returned
*
* @return Zero when successful, otherwise an error code
*
* @sa bsec_sensor_configuration_t
* @sa bsec_physical_sensor_t
* @sa bsec_virtual_sensor_t
*
\code{.c}
// Example //
// Change 3 virtual sensors (switch IAQ and raw temperature -> on / pressure -> off)
bsec_sensor_configuration_t requested_virtual_sensors[3];
uint8_t n_requested_virtual_sensors = 3;
requested_virtual_sensors[0].sensor_id = BSEC_OUTPUT_IAQ;
requested_virtual_sensors[0].sample_rate = BSEC_SAMPLE_RATE_ULP;
requested_virtual_sensors[1].sensor_id = BSEC_OUTPUT_RAW_TEMPERATURE;
requested_virtual_sensors[1].sample_rate = BSEC_SAMPLE_RATE_ULP;
requested_virtual_sensors[2].sensor_id = BSEC_OUTPUT_RAW_PRESSURE;
requested_virtual_sensors[2].sample_rate = BSEC_SAMPLE_RATE_DISABLED;
// Allocate a struct for the returned physical sensor settings
bsec_sensor_configuration_t required_sensor_settings[BSEC_MAX_PHYSICAL_SENSOR];
uint8_t n_required_sensor_settings = BSEC_MAX_PHYSICAL_SENSOR;
// Call bsec_update_subscription() to enable/disable the requested virtual sensors
bsec_update_subscription(requested_virtual_sensors, n_requested_virtual_sensors, required_sensor_settings, &n_required_sensor_settings);
\endcode
*
*/
bsec_library_return_t bsec_update_subscription(const bsec_sensor_configuration_t * const requested_virtual_sensors,
const uint8_t n_requested_virtual_sensors, bsec_sensor_configuration_t * required_sensor_settings,
uint8_t * n_required_sensor_settings);
/*!
* @brief Main signal processing function of BSEC
*
*
* Processing of the input signals and returning of output samples is performed by bsec_do_steps().
* - The samples of all library inputs must be passed with unique identifiers representing the input signals from
* physical sensors where the order of these inputs can be chosen arbitrary. However, all input have to be provided
* within the same time period as they are read. A sequential provision to the library might result in undefined
* behavior.
* - The samples of all library outputs are returned with unique identifiers corresponding to the output signals of
* virtual sensors where the order of the returned outputs may be arbitrary.
* - The samples of all input as well as output signals of physical as well as virtual sensors use the same
* representation in memory with the following fields:
* - Sensor identifier:
* - For inputs: required to identify the input signal from a physical sensor
* - For output: overwritten by bsec_do_steps() to identify the returned signal from a virtual sensor
* - Time stamp of the sample
*
* Calling bsec_do_steps() requires the samples of the input signals to be provided along with their time stamp when
* they are recorded and only when they are acquired. Repetition of samples with the same time stamp are ignored and
* result in a warning. Repetition of values of samples which are not acquired anew by a sensor result in deviations
* of the computed output signals. Concerning the returned output samples, an important feature is, that a value is
* returned for an output only when a new occurrence has been computed. A sample of an output signal is returned only
* once.
*
*
* @param[in] inputs Array of input data samples. Each array element represents a sample of a different physical sensor.
* @param[in] n_inputs Number of passed input data structs.
* @param[out] outputs Array of output data samples. Each array element represents a sample of a different virtual sensor.
* @param[in,out] n_outputs [in] Number of allocated output structs, [out] number of outputs returned
*
* @return Zero when successful, otherwise an error code
*
\code{.c}
// Example //
// Allocate input and output memory
bsec_input_t input[3];
uint8_t n_input = 3;
bsec_output_t output[2];
uint8_t n_output=2;
bsec_library_return_t status;
// Populate the input structs, assuming the we have timestamp (ts),
// gas sensor resistance (R), temperature (T), and humidity (rH) available
// as input variables
input[0].sensor_id = BSEC_INPUT_GASRESISTOR;
input[0].signal = R;
input[0].time_stamp= ts;
input[1].sensor_id = BSEC_INPUT_TEMPERATURE;
input[1].signal = T;
input[1].time_stamp= ts;
input[2].sensor_id = BSEC_INPUT_HUMIDITY;
input[2].signal = rH;
input[2].time_stamp= ts;
// Invoke main processing BSEC function
status = bsec_do_steps( input, n_input, output, &n_output );
// Iterate through the BSEC output data, if the call succeeded
if(status == BSEC_OK)
{
for(int i = 0; i < n_output; i++)
{
switch(output[i].sensor_id)
{
case BSEC_OUTPUT_IAQ:
// Retrieve the IAQ results from output[i].signal
// and do something with the data
break;
case BSEC_OUTPUT_AMBIENT_TEMPERATURE:
// Retrieve the ambient temperature results from output[i].signal
// and do something with the data
break;
}
}
}
\endcode
*/
bsec_library_return_t bsec_do_steps(const bsec_input_t * const inputs, const uint8_t n_inputs, bsec_output_t * outputs, uint8_t * n_outputs);
/*!
* @brief Reset a particular virtual sensor output
*
* This function allows specific virtual sensor outputs to be reset. The meaning of "reset" depends on the specific
* output. In case of the IAQ output, reset means zeroing the output to the current ambient conditions.
*
* @param[in] sensor_id Virtual sensor to be reset
*
* @return Zero when successful, otherwise an error code
*
*
\code{.c}
// Example //
bsec_reset_output(BSEC_OUTPUT_IAQ);
\endcode
*/
bsec_library_return_t bsec_reset_output(uint8_t sensor_id);
/*!
* @brief Update algorithm configuration parameters
*
* BSEC uses a default configuration for the modules and common settings. The initial configuration can be customized
* by bsec_set_configuration(). This is an optional step.
*
* @note A work buffer with sufficient size is required and has to be provided by the function caller to decompose
* the serialization and apply it to the library and its modules. Please use #BSEC_MAX_PROPERTY_BLOB_SIZE for allotting
* the required size.
*
* @param[in] serialized_settings Settings serialized to a binary blob
* @param[in] n_serialized_settings Size of the settings blob
* @param[in,out] work_buffer Work buffer used to parse the blob
* @param[in] n_work_buffer_size Length of the work buffer available for parsing the blob
*
* @return Zero when successful, otherwise an error code
*
\code{.c}
// Example //
// Allocate variables
uint8_t serialized_settings[BSEC_MAX_PROPERTY_BLOB_SIZE];
uint32_t n_serialized_settings_max = BSEC_MAX_PROPERTY_BLOB_SIZE;
uint8_t work_buffer[BSEC_MAX_PROPERTY_BLOB_SIZE];
uint32_t n_work_buffer = BSEC_MAX_PROPERTY_BLOB_SIZE;
// Here we will load a provided config string into serialized_settings
// Apply the configuration
bsec_set_configuration(serialized_settings, n_serialized_settings_max, work_buffer, n_work_buffer);
\endcode
*/
bsec_library_return_t bsec_set_configuration(const uint8_t * const serialized_settings,
const uint32_t n_serialized_settings, uint8_t * work_buffer,
const uint32_t n_work_buffer_size);
/*!
* @brief Restore the internal state of the library
*
* BSEC uses a default state for all signal processing modules and the BSEC module. To ensure optimal performance,
* especially of the gas sensor functionality, it is recommended to retrieve the state using bsec_get_state()
* before unloading the library, storing it in some form of non-volatile memory, and setting it using bsec_set_state()
* before resuming further operation of the library.
*
* @note A work buffer with sufficient size is required and has to be provided by the function caller to decompose the
* serialization and apply it to the library and its modules. Please use #BSEC_MAX_PROPERTY_BLOB_SIZE for allotting the
* required size.
*
* @param[in] serialized_state States serialized to a binary blob
* @param[in] n_serialized_state Size of the state blob
* @param[in,out] work_buffer Work buffer used to parse the blob
* @param[in] n_work_buffer_size Length of the work buffer available for parsing the blob
*
* @return Zero when successful, otherwise an error code
*
\code{.c}
// Example //
// Allocate variables
uint8_t serialized_state[BSEC_MAX_PROPERTY_BLOB_SIZE];
uint32_t n_serialized_state = BSEC_MAX_PROPERTY_BLOB_SIZE;
uint8_t work_buffer_state[BSEC_MAX_PROPERTY_BLOB_SIZE];
uint32_t n_work_buffer_size = BSEC_MAX_PROPERTY_BLOB_SIZE;
// Here we will load a state string from a previous use of BSEC
// Apply the previous state to the current BSEC session
bsec_set_state(serialized_state, n_serialized_state, work_buffer_state, n_work_buffer_size);
\endcode
*/
bsec_library_return_t bsec_set_state(const uint8_t * const serialized_state, const uint32_t n_serialized_state,
uint8_t * work_buffer, const uint32_t n_work_buffer_size);
/*!
* @brief Retrieve the current library configuration
*
* BSEC allows to retrieve the current configuration using bsec_get_configuration(). Returns a binary blob encoding
* the current configuration parameters of the library in a format compatible with bsec_set_configuration().
*
* @note The function bsec_get_configuration() is required to be used for debugging purposes only.
* @note A work buffer with sufficient size is required and has to be provided by the function caller to decompose the
* serialization and apply it to the library and its modules. Please use #BSEC_MAX_PROPERTY_BLOB_SIZE for allotting the
* required size.
*
*
* @param[in] config_id Identifier for a specific set of configuration settings to be returned;
* shall be zero to retrieve all configuration settings.
* @param[out] serialized_settings Buffer to hold the serialized config blob
* @param[in] n_serialized_settings_max Maximum available size for the serialized settings
* @param[in,out] work_buffer Work buffer used to parse the binary blob
* @param[in] n_work_buffer Length of the work buffer available for parsing the blob
* @param[out] n_serialized_settings Actual size of the returned serialized configuration blob
*
* @return Zero when successful, otherwise an error code
*
\code{.c}
// Example //
// Allocate variables
uint8_t serialized_settings[BSEC_MAX_PROPERTY_BLOB_SIZE];
uint32_t n_serialized_settings_max = BSEC_MAX_PROPERTY_BLOB_SIZE;
uint8_t work_buffer[BSEC_MAX_PROPERTY_BLOB_SIZE];
uint32_t n_work_buffer = BSEC_MAX_PROPERTY_BLOB_SIZE;
uint32_t n_serialized_settings = 0;
// Configuration of BSEC algorithm is stored in 'serialized_settings'
bsec_get_configuration(0, serialized_settings, n_serialized_settings_max, work_buffer, n_work_buffer, &n_serialized_settings);
\endcode
*/
bsec_library_return_t bsec_get_configuration(const uint8_t config_id, uint8_t * serialized_settings, const uint32_t n_serialized_settings_max,
uint8_t * work_buffer, const uint32_t n_work_buffer, uint32_t * n_serialized_settings);
/*!
*@brief Retrieve the current internal library state
*
* BSEC allows to retrieve the current states of all signal processing modules and the BSEC module using
* bsec_get_state(). This allows a restart of the processing after a reboot of the system by calling bsec_set_state().
*
* @note A work buffer with sufficient size is required and has to be provided by the function caller to decompose the
* serialization and apply it to the library and its modules. Please use #BSEC_MAX_STATE_BLOB_SIZE for allotting the
* required size.
*
*
* @param[in] state_set_id Identifier for a specific set of states to be returned; shall be
* zero to retrieve all states.
* @param[out] serialized_state Buffer to hold the serialized config blob
* @param[in] n_serialized_state_max Maximum available size for the serialized states
* @param[in,out] work_buffer Work buffer used to parse the blob
* @param[in] n_work_buffer Length of the work buffer available for parsing the blob
* @param[out] n_serialized_state Actual size of the returned serialized blob
*
* @return Zero when successful, otherwise an error code
*
\code{.c}
// Example //
// Allocate variables
uint8_t serialized_state[BSEC_MAX_STATE_BLOB_SIZE];
uint32_t n_serialized_state_max = BSEC_MAX_STATE_BLOB_SIZE;
uint32_t n_serialized_state = BSEC_MAX_STATE_BLOB_SIZE;
uint8_t work_buffer_state[BSEC_MAX_STATE_BLOB_SIZE];
uint32_t n_work_buffer_size = BSEC_MAX_STATE_BLOB_SIZE;
// Algorithm state is stored in 'serialized_state'
bsec_get_state(0, serialized_state, n_serialized_state_max, work_buffer_state, n_work_buffer_size, &n_serialized_state);
\endcode
*/
bsec_library_return_t bsec_get_state(const uint8_t state_set_id, uint8_t * serialized_state,
const uint32_t n_serialized_state_max, uint8_t * work_buffer, const uint32_t n_work_buffer,
uint32_t * n_serialized_state);
/*!
* @brief Retrieve BMExxx sensor instructions
*
* The bsec_sensor_control() interface is a key feature of BSEC, as it allows an easy way for the signal processing
* library to control the operation of the BME sensor. This is important since gas sensor behaviour is mainly
* determined by how the integrated heater is configured. To ensure an easy integration of BSEC into any system,
* bsec_sensor_control() will provide the caller with information about the current sensor configuration that is
* necessary to fulfill the input requirements derived from the current outputs requested via
* bsec_update_subscription().
*
* In practice the use of this function shall be as follows:
* - Call bsec_sensor_control() which returns a bsec_bme_settings_t struct.
* - Based on the information contained in this struct, the sensor is configured and a forced-mode measurement is
* triggered if requested by bsec_sensor_control().
* - Once this forced-mode measurement is complete, the signals specified in this struct shall be passed to
* bsec_do_steps() to perform the signal processing.
* - After processing, the process should sleep until the bsec_bme_settings_t::next_call timestamp is reached.
*
*
* @param [in] time_stamp Current timestamp in [ns]
* @param[out] sensor_settings Settings to be passed to API to operate sensor at this time instance
*
* @return Zero when successful, otherwise an error code
*/
bsec_library_return_t bsec_sensor_control(const int64_t time_stamp, bsec_bme_settings_t *sensor_settings);
/*@}*/ //BSEC Interface
#ifdef __cplusplus
}
#endif
#endif /* __BSEC_INTERFACE_H__ */

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454,1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,168,19,73,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,7,240,150,61,0,0,0,0,0,0,0,0,28,124,225,61,52,128,215,63,0,0,160,64,0,0,0,0,0,0,0,0,205,204,12,62,103,213,39,62,230,63,76,192,0,0,0,0,0,0,0,0,145,237,60,191,251,58,64,63,177,80,131,64,0,0,0,0,0,0,0,0,93,254,227,62,54,60,133,191,0,0,64,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,48,117,0,0,0,0,30,235,0,0
1 454 1 7 4 1 61 0 0 0 0 0 0 0 174 1 0 0 48 0 1 0 137 65 0 63 205 204 204 62 0 0 64 63 205 204 204 62 0 0 225 68 0 168 19 73 64 49 119 76 0 0 0 0 0 80 5 95 0 0 0 0 0 0 0 0 28 0 2 0 0 244 1 225 0 25 0 0 128 64 0 0 32 65 144 1 0 0 112 65 0 0 0 63 16 0 3 0 10 215 163 60 10 215 35 59 10 215 35 59 9 0 5 0 0 0 0 0 1 88 0 9 0 7 240 150 61 0 0 0 0 0 0 0 0 28 124 225 61 52 128 215 63 0 0 160 64 0 0 0 0 0 0 0 0 205 204 12 62 103 213 39 62 230 63 76 192 0 0 0 0 0 0 0 0 145 237 60 191 251 58 64 63 177 80 131 64 0 0 0 0 0 0 0 0 93 254 227 62 54 60 133 191 0 0 64 64 12 0 10 0 0 0 0 0 0 0 0 0 229 0 254 0 2 1 5 48 117 100 0 44 1 112 23 151 7 132 3 197 0 92 4 144 1 64 1 64 1 144 1 48 117 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 48 117 48 117 100 0 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 100 0 100 0 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 255 255 255 255 255 255 255 255 220 5 220 5 220 5 255 255 255 255 255 255 220 5 220 5 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 48 117 0 0 0 0 30 235 0 0

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#include "bsec_serialized_configurations_iaq.h"
const uint8_t bsec_config_iaq[454] =
{1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,168,19,73,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,7,240,150,61,0,0,0,0,0,0,0,0,28,124,225,61,52,128,215,63,0,0,160,64,0,0,0,0,0,0,0,0,205,204,12,62,103,213,39,62,230,63,76,192,0,0,0,0,0,0,0,0,145,237,60,191,251,58,64,63,177,80,131,64,0,0,0,0,0,0,0,0,93,254,227,62,54,60,133,191,0,0,64,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,48,117,0,0,0,0,30,235,0,0};

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#include <stdint.h>
extern const uint8_t bsec_config_iaq[454];

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454,1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,192,168,71,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,7,240,150,61,0,0,0,0,0,0,0,0,28,124,225,61,52,128,215,63,0,0,160,64,0,0,0,0,0,0,0,0,205,204,12,62,103,213,39,62,230,63,76,192,0,0,0,0,0,0,0,0,145,237,60,191,251,58,64,63,177,80,131,64,0,0,0,0,0,0,0,0,93,254,227,62,54,60,133,191,0,0,64,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,48,117,0,0,0,0,195,255,0,0
1 454 1 7 4 1 61 0 0 0 0 0 0 0 174 1 0 0 48 0 1 0 137 65 0 63 205 204 204 62 0 0 64 63 205 204 204 62 0 0 225 68 0 192 168 71 64 49 119 76 0 0 0 0 0 80 5 95 0 0 0 0 0 0 0 0 28 0 2 0 0 244 1 225 0 25 0 0 128 64 0 0 32 65 144 1 0 0 112 65 0 0 0 63 16 0 3 0 10 215 163 60 10 215 35 59 10 215 35 59 9 0 5 0 0 0 0 0 1 88 0 9 0 7 240 150 61 0 0 0 0 0 0 0 0 28 124 225 61 52 128 215 63 0 0 160 64 0 0 0 0 0 0 0 0 205 204 12 62 103 213 39 62 230 63 76 192 0 0 0 0 0 0 0 0 145 237 60 191 251 58 64 63 177 80 131 64 0 0 0 0 0 0 0 0 93 254 227 62 54 60 133 191 0 0 64 64 12 0 10 0 0 0 0 0 0 0 0 0 229 0 254 0 2 1 5 48 117 100 0 44 1 112 23 151 7 132 3 197 0 92 4 144 1 64 1 64 1 144 1 48 117 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 48 117 48 117 100 0 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 100 0 100 0 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 255 255 255 255 255 255 255 255 220 5 220 5 220 5 255 255 255 255 255 255 220 5 220 5 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 48 117 0 0 0 0 195 255 0 0

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#include "bsec_serialized_configurations_iaq.h"
const uint8_t bsec_config_iaq[454] =
{1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,192,168,71,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,7,240,150,61,0,0,0,0,0,0,0,0,28,124,225,61,52,128,215,63,0,0,160,64,0,0,0,0,0,0,0,0,205,204,12,62,103,213,39,62,230,63,76,192,0,0,0,0,0,0,0,0,145,237,60,191,251,58,64,63,177,80,131,64,0,0,0,0,0,0,0,0,93,254,227,62,54,60,133,191,0,0,64,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,48,117,0,0,0,0,195,255,0,0};

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#include <stdint.h>
extern const uint8_t bsec_config_iaq[454];

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454,1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,168,19,73,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,7,240,150,61,0,0,0,0,0,0,0,0,28,124,225,61,52,128,215,63,0,0,160,64,0,0,0,0,0,0,0,0,205,204,12,62,103,213,39,62,230,63,76,192,0,0,0,0,0,0,0,0,145,237,60,191,251,58,64,63,177,80,131,64,0,0,0,0,0,0,0,0,93,254,227,62,54,60,133,191,0,0,64,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,44,1,0,0,0,0,140,226,0,0
1 454 1 7 4 1 61 0 0 0 0 0 0 0 174 1 0 0 48 0 1 0 137 65 0 63 205 204 204 62 0 0 64 63 205 204 204 62 0 0 225 68 0 168 19 73 64 49 119 76 0 0 0 0 0 80 5 95 0 0 0 0 0 0 0 0 28 0 2 0 0 244 1 225 0 25 0 0 128 64 0 0 32 65 144 1 0 0 112 65 0 0 0 63 16 0 3 0 10 215 163 60 10 215 35 59 10 215 35 59 9 0 5 0 0 0 0 0 1 88 0 9 0 7 240 150 61 0 0 0 0 0 0 0 0 28 124 225 61 52 128 215 63 0 0 160 64 0 0 0 0 0 0 0 0 205 204 12 62 103 213 39 62 230 63 76 192 0 0 0 0 0 0 0 0 145 237 60 191 251 58 64 63 177 80 131 64 0 0 0 0 0 0 0 0 93 254 227 62 54 60 133 191 0 0 64 64 12 0 10 0 0 0 0 0 0 0 0 0 229 0 254 0 2 1 5 48 117 100 0 44 1 112 23 151 7 132 3 197 0 92 4 144 1 64 1 64 1 144 1 48 117 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 48 117 48 117 100 0 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 100 0 100 0 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 255 255 255 255 255 255 255 255 220 5 220 5 220 5 255 255 255 255 255 255 220 5 220 5 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 44 1 0 0 0 0 140 226 0 0

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#include "bsec_serialized_configurations_iaq.h"
const uint8_t bsec_config_iaq[454] =
{1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,168,19,73,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,7,240,150,61,0,0,0,0,0,0,0,0,28,124,225,61,52,128,215,63,0,0,160,64,0,0,0,0,0,0,0,0,205,204,12,62,103,213,39,62,230,63,76,192,0,0,0,0,0,0,0,0,145,237,60,191,251,58,64,63,177,80,131,64,0,0,0,0,0,0,0,0,93,254,227,62,54,60,133,191,0,0,64,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,44,1,0,0,0,0,140,226,0,0};

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#include <stdint.h>
extern const uint8_t bsec_config_iaq[454];

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@ -0,0 +1 @@
454,1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,192,168,71,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,7,240,150,61,0,0,0,0,0,0,0,0,28,124,225,61,52,128,215,63,0,0,160,64,0,0,0,0,0,0,0,0,205,204,12,62,103,213,39,62,230,63,76,192,0,0,0,0,0,0,0,0,145,237,60,191,251,58,64,63,177,80,131,64,0,0,0,0,0,0,0,0,93,254,227,62,54,60,133,191,0,0,64,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,44,1,0,0,0,0,81,246,0,0
1 454 1 7 4 1 61 0 0 0 0 0 0 0 174 1 0 0 48 0 1 0 137 65 0 63 205 204 204 62 0 0 64 63 205 204 204 62 0 0 225 68 0 192 168 71 64 49 119 76 0 0 0 0 0 80 5 95 0 0 0 0 0 0 0 0 28 0 2 0 0 244 1 225 0 25 0 0 128 64 0 0 32 65 144 1 0 0 112 65 0 0 0 63 16 0 3 0 10 215 163 60 10 215 35 59 10 215 35 59 9 0 5 0 0 0 0 0 1 88 0 9 0 7 240 150 61 0 0 0 0 0 0 0 0 28 124 225 61 52 128 215 63 0 0 160 64 0 0 0 0 0 0 0 0 205 204 12 62 103 213 39 62 230 63 76 192 0 0 0 0 0 0 0 0 145 237 60 191 251 58 64 63 177 80 131 64 0 0 0 0 0 0 0 0 93 254 227 62 54 60 133 191 0 0 64 64 12 0 10 0 0 0 0 0 0 0 0 0 229 0 254 0 2 1 5 48 117 100 0 44 1 112 23 151 7 132 3 197 0 92 4 144 1 64 1 64 1 144 1 48 117 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 48 117 48 117 100 0 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 100 0 100 0 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 255 255 255 255 255 255 255 255 220 5 220 5 220 5 255 255 255 255 255 255 220 5 220 5 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 44 1 0 0 0 0 81 246 0 0

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#include "bsec_serialized_configurations_iaq.h"
const uint8_t bsec_config_iaq[454] =
{1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,192,168,71,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,7,240,150,61,0,0,0,0,0,0,0,0,28,124,225,61,52,128,215,63,0,0,160,64,0,0,0,0,0,0,0,0,205,204,12,62,103,213,39,62,230,63,76,192,0,0,0,0,0,0,0,0,145,237,60,191,251,58,64,63,177,80,131,64,0,0,0,0,0,0,0,0,93,254,227,62,54,60,133,191,0,0,64,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,44,1,0,0,0,0,81,246,0,0};

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#include <stdint.h>
extern const uint8_t bsec_config_iaq[454];

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454,1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,168,19,73,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,229,208,34,62,0,0,0,0,0,0,0,0,218,27,156,62,225,11,67,64,0,0,160,64,0,0,0,0,0,0,0,0,94,75,72,189,93,254,159,64,66,62,160,191,0,0,0,0,0,0,0,0,33,31,180,190,138,176,97,64,65,241,99,190,0,0,0,0,0,0,0,0,167,121,71,61,165,189,41,192,184,30,189,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,48,117,0,0,0,0,160,82,0,0
1 454 1 7 4 1 61 0 0 0 0 0 0 0 174 1 0 0 48 0 1 0 137 65 0 63 205 204 204 62 0 0 64 63 205 204 204 62 0 0 225 68 0 168 19 73 64 49 119 76 0 0 0 0 0 80 5 95 0 0 0 0 0 0 0 0 28 0 2 0 0 244 1 225 0 25 0 0 128 64 0 0 32 65 144 1 0 0 112 65 0 0 0 63 16 0 3 0 10 215 163 60 10 215 35 59 10 215 35 59 9 0 5 0 0 0 0 0 1 88 0 9 0 229 208 34 62 0 0 0 0 0 0 0 0 218 27 156 62 225 11 67 64 0 0 160 64 0 0 0 0 0 0 0 0 94 75 72 189 93 254 159 64 66 62 160 191 0 0 0 0 0 0 0 0 33 31 180 190 138 176 97 64 65 241 99 190 0 0 0 0 0 0 0 0 167 121 71 61 165 189 41 192 184 30 189 64 12 0 10 0 0 0 0 0 0 0 0 0 229 0 254 0 2 1 5 48 117 100 0 44 1 112 23 151 7 132 3 197 0 92 4 144 1 64 1 64 1 144 1 48 117 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 48 117 48 117 100 0 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 100 0 100 0 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 255 255 255 255 255 255 255 255 220 5 220 5 220 5 255 255 255 255 255 255 220 5 220 5 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 48 117 0 0 0 0 160 82 0 0

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#include "bsec_serialized_configurations_iaq.h"
const uint8_t bsec_config_iaq[454] =
{1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,168,19,73,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,229,208,34,62,0,0,0,0,0,0,0,0,218,27,156,62,225,11,67,64,0,0,160,64,0,0,0,0,0,0,0,0,94,75,72,189,93,254,159,64,66,62,160,191,0,0,0,0,0,0,0,0,33,31,180,190,138,176,97,64,65,241,99,190,0,0,0,0,0,0,0,0,167,121,71,61,165,189,41,192,184,30,189,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,48,117,0,0,0,0,160,82,0,0};

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#include <stdint.h>
extern const uint8_t bsec_config_iaq[454];

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454,1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,192,168,71,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,229,208,34,62,0,0,0,0,0,0,0,0,218,27,156,62,225,11,67,64,0,0,160,64,0,0,0,0,0,0,0,0,94,75,72,189,93,254,159,64,66,62,160,191,0,0,0,0,0,0,0,0,33,31,180,190,138,176,97,64,65,241,99,190,0,0,0,0,0,0,0,0,167,121,71,61,165,189,41,192,184,30,189,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,48,117,0,0,0,0,125,70,0,0
1 454 1 7 4 1 61 0 0 0 0 0 0 0 174 1 0 0 48 0 1 0 137 65 0 63 205 204 204 62 0 0 64 63 205 204 204 62 0 0 225 68 0 192 168 71 64 49 119 76 0 0 0 0 0 80 5 95 0 0 0 0 0 0 0 0 28 0 2 0 0 244 1 225 0 25 0 0 128 64 0 0 32 65 144 1 0 0 112 65 0 0 0 63 16 0 3 0 10 215 163 60 10 215 35 59 10 215 35 59 9 0 5 0 0 0 0 0 1 88 0 9 0 229 208 34 62 0 0 0 0 0 0 0 0 218 27 156 62 225 11 67 64 0 0 160 64 0 0 0 0 0 0 0 0 94 75 72 189 93 254 159 64 66 62 160 191 0 0 0 0 0 0 0 0 33 31 180 190 138 176 97 64 65 241 99 190 0 0 0 0 0 0 0 0 167 121 71 61 165 189 41 192 184 30 189 64 12 0 10 0 0 0 0 0 0 0 0 0 229 0 254 0 2 1 5 48 117 100 0 44 1 112 23 151 7 132 3 197 0 92 4 144 1 64 1 64 1 144 1 48 117 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 48 117 48 117 100 0 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 100 0 100 0 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 255 255 255 255 255 255 255 255 220 5 220 5 220 5 255 255 255 255 255 255 220 5 220 5 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 48 117 0 0 0 0 125 70 0 0

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#include "bsec_serialized_configurations_iaq.h"
const uint8_t bsec_config_iaq[454] =
{1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,192,168,71,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,229,208,34,62,0,0,0,0,0,0,0,0,218,27,156,62,225,11,67,64,0,0,160,64,0,0,0,0,0,0,0,0,94,75,72,189,93,254,159,64,66,62,160,191,0,0,0,0,0,0,0,0,33,31,180,190,138,176,97,64,65,241,99,190,0,0,0,0,0,0,0,0,167,121,71,61,165,189,41,192,184,30,189,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,48,117,0,0,0,0,125,70,0,0};

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#include <stdint.h>
extern const uint8_t bsec_config_iaq[454];

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@ -0,0 +1 @@
454,1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,168,19,73,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,229,208,34,62,0,0,0,0,0,0,0,0,218,27,156,62,225,11,67,64,0,0,160,64,0,0,0,0,0,0,0,0,94,75,72,189,93,254,159,64,66,62,160,191,0,0,0,0,0,0,0,0,33,31,180,190,138,176,97,64,65,241,99,190,0,0,0,0,0,0,0,0,167,121,71,61,165,189,41,192,184,30,189,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,44,1,0,0,0,0,50,91,0,0
1 454 1 7 4 1 61 0 0 0 0 0 0 0 174 1 0 0 48 0 1 0 137 65 0 63 205 204 204 62 0 0 64 63 205 204 204 62 0 0 225 68 0 168 19 73 64 49 119 76 0 0 0 0 0 80 5 95 0 0 0 0 0 0 0 0 28 0 2 0 0 244 1 225 0 25 0 0 128 64 0 0 32 65 144 1 0 0 112 65 0 0 0 63 16 0 3 0 10 215 163 60 10 215 35 59 10 215 35 59 9 0 5 0 0 0 0 0 1 88 0 9 0 229 208 34 62 0 0 0 0 0 0 0 0 218 27 156 62 225 11 67 64 0 0 160 64 0 0 0 0 0 0 0 0 94 75 72 189 93 254 159 64 66 62 160 191 0 0 0 0 0 0 0 0 33 31 180 190 138 176 97 64 65 241 99 190 0 0 0 0 0 0 0 0 167 121 71 61 165 189 41 192 184 30 189 64 12 0 10 0 0 0 0 0 0 0 0 0 229 0 254 0 2 1 5 48 117 100 0 44 1 112 23 151 7 132 3 197 0 92 4 144 1 64 1 64 1 144 1 48 117 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 48 117 48 117 100 0 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 100 0 100 0 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 255 255 255 255 255 255 255 255 220 5 220 5 220 5 255 255 255 255 255 255 220 5 220 5 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 44 1 0 0 0 0 50 91 0 0

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#include "bsec_serialized_configurations_iaq.h"
const uint8_t bsec_config_iaq[454] =
{1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,168,19,73,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,229,208,34,62,0,0,0,0,0,0,0,0,218,27,156,62,225,11,67,64,0,0,160,64,0,0,0,0,0,0,0,0,94,75,72,189,93,254,159,64,66,62,160,191,0,0,0,0,0,0,0,0,33,31,180,190,138,176,97,64,65,241,99,190,0,0,0,0,0,0,0,0,167,121,71,61,165,189,41,192,184,30,189,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,44,1,0,0,0,0,50,91,0,0};

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#include <stdint.h>
extern const uint8_t bsec_config_iaq[454];

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454,1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,192,168,71,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,229,208,34,62,0,0,0,0,0,0,0,0,218,27,156,62,225,11,67,64,0,0,160,64,0,0,0,0,0,0,0,0,94,75,72,189,93,254,159,64,66,62,160,191,0,0,0,0,0,0,0,0,33,31,180,190,138,176,97,64,65,241,99,190,0,0,0,0,0,0,0,0,167,121,71,61,165,189,41,192,184,30,189,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,44,1,0,0,0,0,239,79,0,0
1 454 1 7 4 1 61 0 0 0 0 0 0 0 174 1 0 0 48 0 1 0 137 65 0 63 205 204 204 62 0 0 64 63 205 204 204 62 0 0 225 68 0 192 168 71 64 49 119 76 0 0 0 0 0 80 5 95 0 0 0 0 0 0 0 0 28 0 2 0 0 244 1 225 0 25 0 0 128 64 0 0 32 65 144 1 0 0 112 65 0 0 0 63 16 0 3 0 10 215 163 60 10 215 35 59 10 215 35 59 9 0 5 0 0 0 0 0 1 88 0 9 0 229 208 34 62 0 0 0 0 0 0 0 0 218 27 156 62 225 11 67 64 0 0 160 64 0 0 0 0 0 0 0 0 94 75 72 189 93 254 159 64 66 62 160 191 0 0 0 0 0 0 0 0 33 31 180 190 138 176 97 64 65 241 99 190 0 0 0 0 0 0 0 0 167 121 71 61 165 189 41 192 184 30 189 64 12 0 10 0 0 0 0 0 0 0 0 0 229 0 254 0 2 1 5 48 117 100 0 44 1 112 23 151 7 132 3 197 0 92 4 144 1 64 1 64 1 144 1 48 117 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 48 117 48 117 100 0 100 0 100 0 100 0 48 117 48 117 48 117 100 0 100 0 100 0 48 117 48 117 100 0 100 0 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 44 1 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 8 7 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 112 23 255 255 255 255 255 255 255 255 220 5 220 5 220 5 255 255 255 255 255 255 220 5 220 5 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 255 44 1 0 0 0 0 239 79 0 0

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#include "bsec_serialized_configurations_iaq.h"
const uint8_t bsec_config_iaq[454] =
{1,7,4,1,61,0,0,0,0,0,0,0,174,1,0,0,48,0,1,0,137,65,0,63,205,204,204,62,0,0,64,63,205,204,204,62,0,0,225,68,0,192,168,71,64,49,119,76,0,0,0,0,0,80,5,95,0,0,0,0,0,0,0,0,28,0,2,0,0,244,1,225,0,25,0,0,128,64,0,0,32,65,144,1,0,0,112,65,0,0,0,63,16,0,3,0,10,215,163,60,10,215,35,59,10,215,35,59,9,0,5,0,0,0,0,0,1,88,0,9,0,229,208,34,62,0,0,0,0,0,0,0,0,218,27,156,62,225,11,67,64,0,0,160,64,0,0,0,0,0,0,0,0,94,75,72,189,93,254,159,64,66,62,160,191,0,0,0,0,0,0,0,0,33,31,180,190,138,176,97,64,65,241,99,190,0,0,0,0,0,0,0,0,167,121,71,61,165,189,41,192,184,30,189,64,12,0,10,0,0,0,0,0,0,0,0,0,229,0,254,0,2,1,5,48,117,100,0,44,1,112,23,151,7,132,3,197,0,92,4,144,1,64,1,64,1,144,1,48,117,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,48,117,48,117,100,0,100,0,100,0,100,0,48,117,48,117,48,117,100,0,100,0,100,0,48,117,48,117,100,0,100,0,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,44,1,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,8,7,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,112,23,255,255,255,255,255,255,255,255,220,5,220,5,220,5,255,255,255,255,255,255,220,5,220,5,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,44,1,0,0,0,0,239,79,0,0};

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#include <stdint.h>
extern const uint8_t bsec_config_iaq[454];

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/*
* Copyright (C) 2017 Robert Bosch. All Rights Reserved.
*
* Disclaimer
*
* Common:
* Bosch Sensortec products are developed for the consumer goods industry. They may only be used
* within the parameters of the respective valid product data sheet. Bosch Sensortec products are
* provided with the express understanding that there is no warranty of fitness for a particular purpose.
* They are not fit for use in life-sustaining, safety or security sensitive systems or any system or device
* that may lead to bodily harm or property damage if the system or device malfunctions. In addition,
* Bosch Sensortec products are not fit for use in products which interact with motor vehicle systems.
* The resale and/or use of products are at the purchasers own risk and his own responsibility. The
* examination of fitness for the intended use is the sole responsibility of the Purchaser.
*
* The purchaser shall indemnify Bosch Sensortec from all third party claims, including any claims for
* incidental, or consequential damages, arising from any product use not covered by the parameters of
* the respective valid product data sheet or not approved by Bosch Sensortec and reimburse Bosch
* Sensortec for all costs in connection with such claims.
*
* The purchaser must monitor the market for the purchased products, particularly with regard to
* product safety and inform Bosch Sensortec without delay of all security relevant incidents.
*
* Engineering Samples are marked with an asterisk (*) or (e). Samples may vary from the valid
* technical specifications of the product series. They are therefore not intended or fit for resale to third
* parties or for use in end products. Their sole purpose is internal client testing. The testing of an
* engineering sample may in no way replace the testing of a product series. Bosch Sensortec
* assumes no liability for the use of engineering samples. By accepting the engineering samples, the
* Purchaser agrees to indemnify Bosch Sensortec from all claims arising from the use of engineering
* samples.
*
* Special:
* This software module (hereinafter called "Software") and any information on application-sheets
* (hereinafter called "Information") is provided free of charge for the sole purpose to support your
* application work. The Software and Information is subject to the following terms and conditions:
*
* The Software is specifically designed for the exclusive use for Bosch Sensortec products by
* personnel who have special experience and training. Do not use this Software if you do not have the
* proper experience or training.
*
* This Software package is provided `` as is `` and without any expressed or implied warranties,
* including without limitation, the implied warranties of merchantability and fitness for a particular
* purpose.
*
* Bosch Sensortec and their representatives and agents deny any liability for the functional impairment
* of this Software in terms of fitness, performance and safety. Bosch Sensortec and their
* representatives and agents shall not be liable for any direct or indirect damages or injury, except as
* otherwise stipulated in mandatory applicable law.
*
* The Information provided is believed to be accurate and reliable. Bosch Sensortec assumes no
* responsibility for the consequences of use of such Information nor for any infringement of patents or
* other rights of third parties which may result from its use. No license is granted by implication or
* otherwise under any patent or patent rights of Bosch. Specifications mentioned in the Information are
* subject to change without notice.
*
* It is not allowed to deliver the source code of the Software to any third party without permission of
* Bosch Sensortec.
*
*/
/*!
* @file bsec_integration.c
*
* @brief
* Private part of the example for using of BSEC library.
*/
/*!
* @addtogroup bsec_examples BSEC Examples
* @brief BSEC usage examples
* @{*/
/**********************************************************************************************************************/
/* header files */
/**********************************************************************************************************************/
#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include "bsec_integration.h"
/**********************************************************************************************************************/
/* local macro definitions */
/**********************************************************************************************************************/
#define NUM_USED_OUTPUTS 8
/**********************************************************************************************************************/
/* global variable declarations */
/**********************************************************************************************************************/
/* Global sensor APIs data structure */
static struct bme680_dev bme680_g;
/* Global temperature offset to be subtracted */
static float bme680_temperature_offset_g = 0.0f;
/**********************************************************************************************************************/
/* functions */
/**********************************************************************************************************************/
/*!
* @brief Virtual sensor subscription
* Please call this function before processing of data using bsec_do_steps function
*
* @param[in] sample_rate mode to be used (either BSEC_SAMPLE_RATE_ULP or BSEC_SAMPLE_RATE_LP)
*
* @return subscription result, zero when successful
*/
static bsec_library_return_t bme680_bsec_update_subscription(float sample_rate)
{
bsec_sensor_configuration_t requested_virtual_sensors[NUM_USED_OUTPUTS];
uint8_t n_requested_virtual_sensors = NUM_USED_OUTPUTS;
bsec_sensor_configuration_t required_sensor_settings[BSEC_MAX_PHYSICAL_SENSOR];
uint8_t n_required_sensor_settings = BSEC_MAX_PHYSICAL_SENSOR;
bsec_library_return_t status = BSEC_OK;
/* note: Virtual sensors as desired to be added here */
requested_virtual_sensors[0].sensor_id = BSEC_OUTPUT_IAQ;
requested_virtual_sensors[0].sample_rate = sample_rate;
requested_virtual_sensors[1].sensor_id = BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_TEMPERATURE;
requested_virtual_sensors[1].sample_rate = sample_rate;
requested_virtual_sensors[2].sensor_id = BSEC_OUTPUT_RAW_PRESSURE;
requested_virtual_sensors[2].sample_rate = sample_rate;
requested_virtual_sensors[3].sensor_id = BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_HUMIDITY;
requested_virtual_sensors[3].sample_rate = sample_rate;
requested_virtual_sensors[4].sensor_id = BSEC_OUTPUT_RAW_GAS;
requested_virtual_sensors[4].sample_rate = sample_rate;
requested_virtual_sensors[5].sensor_id = BSEC_OUTPUT_RAW_TEMPERATURE;
requested_virtual_sensors[5].sample_rate = sample_rate;
requested_virtual_sensors[6].sensor_id = BSEC_OUTPUT_RAW_HUMIDITY;
requested_virtual_sensors[6].sample_rate = sample_rate;
requested_virtual_sensors[7].sensor_id = BSEC_OUTPUT_STATIC_IAQ;
requested_virtual_sensors[7].sample_rate = sample_rate;
/* Call bsec_update_subscription() to enable/disable the requested virtual sensors */
status = bsec_update_subscription(requested_virtual_sensors, n_requested_virtual_sensors, required_sensor_settings,
&n_required_sensor_settings);
return status;
}
/*!
* @brief Initialize the BME680 sensor and the BSEC library
*
* @param[in] sample_rate mode to be used (either BSEC_SAMPLE_RATE_ULP or BSEC_SAMPLE_RATE_LP)
* @param[in] temperature_offset device-specific temperature offset (due to self-heating)
* @param[in] bus_write pointer to the bus writing function
* @param[in] bus_read pointer to the bus reading function
* @param[in] sleep pointer to the system specific sleep function
* @param[in] state_load pointer to the system-specific state load function
* @param[in] config_load pointer to the system-specific config load function
*
* @return zero if successful, negative otherwise
*/
return_values_init bsec_iot_init(float sample_rate, float temperature_offset, bme680_com_fptr_t bus_write,
bme680_com_fptr_t bus_read, sleep_fct sleep, state_load_fct state_load, config_load_fct config_load)
{
return_values_init ret = {BME680_OK, BSEC_OK};
bsec_library_return_t bsec_status = BSEC_OK;
uint8_t bsec_state[BSEC_MAX_PROPERTY_BLOB_SIZE] = {0};
uint8_t bsec_config[BSEC_MAX_PROPERTY_BLOB_SIZE] = {0};
uint8_t work_buffer[BSEC_MAX_PROPERTY_BLOB_SIZE] = {0};
int bsec_state_len, bsec_config_len;
/* Fixed I2C configuration */
bme680_g.dev_id = BME680_I2C_ADDR_PRIMARY;
bme680_g.intf = BME680_I2C_INTF;
/* User configurable I2C configuration */
bme680_g.write = bus_write;
bme680_g.read = bus_read;
bme680_g.delay_ms = sleep;
/* Initialize BME680 API */
ret.bme680_status = bme680_init(&bme680_g);
if (ret.bme680_status != BME680_OK)
{
return ret;
}
/* Initialize BSEC library */
ret.bsec_status = bsec_init();
if (ret.bsec_status != BSEC_OK)
{
return ret;
}
/* Load library config, if available */
bsec_config_len = config_load(bsec_config, sizeof(bsec_config));
if (bsec_config_len != 0)
{
ret.bsec_status = bsec_set_configuration(bsec_config, bsec_config_len, work_buffer, sizeof(work_buffer));
if (ret.bsec_status != BSEC_OK)
{
return ret;
}
}
/* Load previous library state, if available */
bsec_state_len = state_load(bsec_state, sizeof(bsec_state));
if (bsec_state_len != 0)
{
ret.bsec_status = bsec_set_state(bsec_state, bsec_state_len, work_buffer, sizeof(work_buffer));
if (ret.bsec_status != BSEC_OK)
{
return ret;
}
}
/* Set temperature offset */
bme680_temperature_offset_g = temperature_offset;
/* Call to the function which sets the library with subscription information */
ret.bsec_status = bme680_bsec_update_subscription(sample_rate);
if (ret.bsec_status != BSEC_OK)
{
return ret;
}
return ret;
}
/*!
* @brief Trigger the measurement based on sensor settings
*
* @param[in] sensor_settings settings of the BME680 sensor adopted by sensor control function
* @param[in] sleep pointer to the system specific sleep function
*
* @return none
*/
static void bme680_bsec_trigger_measurement(bsec_bme_settings_t *sensor_settings, sleep_fct sleep)
{
uint16_t meas_period;
uint8_t set_required_settings;
int8_t bme680_status = BME680_OK;
/* Check if a forced-mode measurement should be triggered now */
if (sensor_settings->trigger_measurement)
{
/* Set sensor configuration */
bme680_g.tph_sett.os_hum = sensor_settings->humidity_oversampling;
bme680_g.tph_sett.os_pres = sensor_settings->pressure_oversampling;
bme680_g.tph_sett.os_temp = sensor_settings->temperature_oversampling;
bme680_g.gas_sett.run_gas = sensor_settings->run_gas;
bme680_g.gas_sett.heatr_temp = sensor_settings->heater_temperature; /* degree Celsius */
bme680_g.gas_sett.heatr_dur = sensor_settings->heating_duration; /* milliseconds */
/* Select the power mode */
/* Must be set before writing the sensor configuration */
bme680_g.power_mode = BME680_FORCED_MODE;
/* Set the required sensor settings needed */
set_required_settings = BME680_OST_SEL | BME680_OSP_SEL | BME680_OSH_SEL | BME680_GAS_SENSOR_SEL;
/* Set the desired sensor configuration */
bme680_status = bme680_set_sensor_settings(set_required_settings, &bme680_g);
/* Set power mode as forced mode and trigger forced mode measurement */
bme680_status = bme680_set_sensor_mode(&bme680_g);
/* Get the total measurement duration so as to sleep or wait till the measurement is complete */
bme680_get_profile_dur(&meas_period, &bme680_g);
/* Delay till the measurement is ready. Timestamp resolution in ms */
sleep((uint32_t)meas_period);
}
/* Call the API to get current operation mode of the sensor */
bme680_status = bme680_get_sensor_mode(&bme680_g);
/* When the measurement is completed and data is ready for reading, the sensor must be in BME680_SLEEP_MODE.
* Read operation mode to check whether measurement is completely done and wait until the sensor is no more
* in BME680_FORCED_MODE. */
while (bme680_g.power_mode == BME680_FORCED_MODE)
{
/* sleep for 5 ms */
sleep(5);
bme680_status = bme680_get_sensor_mode(&bme680_g);
}
}
/*!
* @brief Read the data from registers and populate the inputs structure to be passed to do_steps function
*
* @param[in] time_stamp_trigger settings of the sensor returned from sensor control function
* @param[in] inputs input structure containing the information on sensors to be passed to do_steps
* @param[in] num_bsec_inputs number of inputs to be passed to do_steps
* @param[in] bsec_process_data process data variable returned from sensor_control
*
* @return none
*/
static void bme680_bsec_read_data(int64_t time_stamp_trigger, bsec_input_t *inputs, uint8_t *num_bsec_inputs,
int32_t bsec_process_data)
{
static struct bme680_field_data data;
int8_t bme680_status = BME680_OK;
/* We only have to read data if the previous call the bsec_sensor_control() actually asked for it */
if (bsec_process_data)
{
bme680_status = bme680_get_sensor_data(&data, &bme680_g);
if (data.status & BME680_NEW_DATA_MSK)
{
/* Pressure to be processed by BSEC */
if (bsec_process_data & BSEC_PROCESS_PRESSURE)
{
/* Place presssure sample into input struct */
inputs[*num_bsec_inputs].sensor_id = BSEC_INPUT_PRESSURE;
inputs[*num_bsec_inputs].signal = data.pressure;
inputs[*num_bsec_inputs].time_stamp = time_stamp_trigger;
(*num_bsec_inputs)++;
}
/* Temperature to be processed by BSEC */
if (bsec_process_data & BSEC_PROCESS_TEMPERATURE)
{
/* Place temperature sample into input struct */
inputs[*num_bsec_inputs].sensor_id = BSEC_INPUT_TEMPERATURE;
#ifdef BME680_FLOAT_POINT_COMPENSATION
inputs[*num_bsec_inputs].signal = data.temperature;
#else
inputs[*num_bsec_inputs].signal = data.temperature / 100.0f;
#endif
inputs[*num_bsec_inputs].time_stamp = time_stamp_trigger;
(*num_bsec_inputs)++;
/* Also add optional heatsource input which will be subtracted from the temperature reading to
* compensate for device-specific self-heating (supported in BSEC IAQ solution)*/
inputs[*num_bsec_inputs].sensor_id = BSEC_INPUT_HEATSOURCE;
inputs[*num_bsec_inputs].signal = bme680_temperature_offset_g;
inputs[*num_bsec_inputs].time_stamp = time_stamp_trigger;
(*num_bsec_inputs)++;
}
/* Humidity to be processed by BSEC */
if (bsec_process_data & BSEC_PROCESS_HUMIDITY)
{
/* Place humidity sample into input struct */
inputs[*num_bsec_inputs].sensor_id = BSEC_INPUT_HUMIDITY;
#ifdef BME680_FLOAT_POINT_COMPENSATION
inputs[*num_bsec_inputs].signal = data.humidity;
#else
inputs[*num_bsec_inputs].signal = data.humidity / 1000.0f;
#endif
inputs[*num_bsec_inputs].time_stamp = time_stamp_trigger;
(*num_bsec_inputs)++;
}
/* Gas to be processed by BSEC */
if (bsec_process_data & BSEC_PROCESS_GAS)
{
/* Check whether gas_valid flag is set */
if(data.status & BME680_GASM_VALID_MSK)
{
/* Place sample into input struct */
inputs[*num_bsec_inputs].sensor_id = BSEC_INPUT_GASRESISTOR;
inputs[*num_bsec_inputs].signal = data.gas_resistance;
inputs[*num_bsec_inputs].time_stamp = time_stamp_trigger;
(*num_bsec_inputs)++;
}
}
}
}
}
/*!
* @brief This function is written to process the sensor data for the requested virtual sensors
*
* @param[in] bsec_inputs input structure containing the information on sensors to be passed to do_steps
* @param[in] num_bsec_inputs number of inputs to be passed to do_steps
* @param[in] output_ready pointer to the function processing obtained BSEC outputs
*
* @return none
*/
static void bme680_bsec_process_data(bsec_input_t *bsec_inputs, uint8_t num_bsec_inputs, output_ready_fct output_ready)
{
/* Output buffer set to the maximum virtual sensor outputs supported */
bsec_output_t bsec_outputs[BSEC_NUMBER_OUTPUTS];
uint8_t num_bsec_outputs = 0;
uint8_t index = 0;
bsec_library_return_t bsec_status = BSEC_OK;
int64_t timestamp = 0;
float iaq = 0.0f;
uint8_t iaq_accuracy = 0;
float temp = 0.0f;
float raw_temp = 0.0f;
float raw_pressure = 0.0f;
float humidity = 0.0f;
float raw_humidity = 0.0f;
float raw_gas = 0.0f;
float static_iaq = 0.0f;
uint8_t static_iaq_accuracy = 0;
float co2_equivalent = 0.0f;
uint8_t co2_accuracy = 0;
float breath_voc_equivalent = 0.0f;
uint8_t breath_voc_accuracy = 0;
float comp_gas_value = 0.0f;
uint8_t comp_gas_accuracy = 0;
float gas_percentage = 0.0f;
uint8_t gas_percentage_acccuracy = 0;
/* Check if something should be processed by BSEC */
if (num_bsec_inputs > 0)
{
/* Set number of outputs to the size of the allocated buffer */
/* BSEC_NUMBER_OUTPUTS to be defined */
num_bsec_outputs = BSEC_NUMBER_OUTPUTS;
/* Perform processing of the data by BSEC
Note:
* The number of outputs you get depends on what you asked for during bsec_update_subscription(). This is
handled under bme680_bsec_update_subscription() function in this example file.
* The number of actual outputs that are returned is written to num_bsec_outputs. */
bsec_status = bsec_do_steps(bsec_inputs, num_bsec_inputs, bsec_outputs, &num_bsec_outputs);
/* Iterate through the outputs and extract the relevant ones. */
for (index = 0; index < num_bsec_outputs; index++)
{
switch (bsec_outputs[index].sensor_id)
{
case BSEC_OUTPUT_IAQ:
iaq = bsec_outputs[index].signal;
iaq_accuracy = bsec_outputs[index].accuracy;
break;
case BSEC_OUTPUT_STATIC_IAQ:
static_iaq = bsec_outputs[index].signal;
static_iaq_accuracy = bsec_outputs[index].accuracy;
break;
case BSEC_OUTPUT_CO2_EQUIVALENT:
co2_equivalent = bsec_outputs[index].signal;
co2_accuracy = bsec_outputs[index].accuracy;
break;
case BSEC_OUTPUT_BREATH_VOC_EQUIVALENT:
breath_voc_equivalent = bsec_outputs[index].signal;
breath_voc_accuracy = bsec_outputs[index].accuracy;
break;
case BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_TEMPERATURE:
temp = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_RAW_PRESSURE:
raw_pressure = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_SENSOR_HEAT_COMPENSATED_HUMIDITY:
humidity = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_RAW_GAS:
raw_gas = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_RAW_TEMPERATURE:
raw_temp = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_RAW_HUMIDITY:
raw_humidity = bsec_outputs[index].signal;
break;
case BSEC_OUTPUT_COMPENSATED_GAS:
comp_gas_value = bsec_outputs[index].signal;
comp_gas_accuracy = bsec_outputs[index].accuracy;
break;
case BSEC_OUTPUT_GAS_PERCENTAGE:
gas_percentage = bsec_outputs[index].signal;
gas_percentage_acccuracy = bsec_outputs[index].accuracy;
break;
default:
continue;
}
/* Assume that all the returned timestamps are the same */
timestamp = bsec_outputs[index].time_stamp;
}
/* Pass the extracted outputs to the user provided output_ready() function. */
output_ready(timestamp, iaq, iaq_accuracy, temp, humidity, raw_pressure, raw_temp,
raw_humidity, raw_gas, bsec_status, static_iaq, co2_equivalent, breath_voc_equivalent);
}
}
/*!
* @brief Runs the main (endless) loop that queries sensor settings, applies them, and processes the measured data
*
* @param[in] sleep pointer to the system specific sleep function
* @param[in] get_timestamp_us pointer to the system specific timestamp derivation function
* @param[in] output_ready pointer to the function processing obtained BSEC outputs
* @param[in] state_save pointer to the system-specific state save function
* @param[in] save_intvl interval at which BSEC state should be saved (in samples)
*
* @return none
*/
void bsec_iot_loop(sleep_fct sleep, get_timestamp_us_fct get_timestamp_us, output_ready_fct output_ready,
state_save_fct state_save, uint32_t save_intvl)
{
/* Timestamp variables */
int64_t time_stamp = 0;
int64_t time_stamp_interval_ms = 0;
/* Allocate enough memory for up to BSEC_MAX_PHYSICAL_SENSOR physical inputs*/
bsec_input_t bsec_inputs[BSEC_MAX_PHYSICAL_SENSOR];
/* Number of inputs to BSEC */
uint8_t num_bsec_inputs = 0;
/* BSEC sensor settings struct */
bsec_bme_settings_t sensor_settings;
/* Save state variables */
uint8_t bsec_state[BSEC_MAX_STATE_BLOB_SIZE];
uint8_t work_buffer[BSEC_MAX_STATE_BLOB_SIZE];
uint32_t bsec_state_len = 0;
uint32_t n_samples = 0;
bsec_library_return_t bsec_status = BSEC_OK;
while (1)
{
/* get the timestamp in nanoseconds before calling bsec_sensor_control() */
time_stamp = get_timestamp_us() * 1000;
/* Retrieve sensor settings to be used in this time instant by calling bsec_sensor_control */
bsec_sensor_control(time_stamp, &sensor_settings);
/* Trigger a measurement if necessary */
bme680_bsec_trigger_measurement(&sensor_settings, sleep);
/* Read data from last measurement */
num_bsec_inputs = 0;
bme680_bsec_read_data(time_stamp, bsec_inputs, &num_bsec_inputs, sensor_settings.process_data);
/* Time to invoke BSEC to perform the actual processing */
bme680_bsec_process_data(bsec_inputs, num_bsec_inputs, output_ready);
/* Increment sample counter */
n_samples++;
/* Retrieve and store state if the passed save_intvl */
if (n_samples >= save_intvl)
{
bsec_status = bsec_get_state(0, bsec_state, sizeof(bsec_state), work_buffer, sizeof(work_buffer), &bsec_state_len);
if (bsec_status == BSEC_OK)
{
state_save(bsec_state, bsec_state_len);
}
n_samples = 0;
}
/* Compute how long we can sleep until we need to call bsec_sensor_control() next */
/* Time_stamp is converted from microseconds to nanoseconds first and then the difference to milliseconds */
time_stamp_interval_ms = (sensor_settings.next_call - get_timestamp_us() * 1000) / 1000000;
if (time_stamp_interval_ms > 0)
{
sleep((uint32_t)time_stamp_interval_ms);
}
}
}
/*! @}*/

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@ -0,0 +1,165 @@
/*
* Copyright (C) 2017 Robert Bosch. All Rights Reserved.
*
* Disclaimer
*
* Common:
* Bosch Sensortec products are developed for the consumer goods industry. They may only be used
* within the parameters of the respective valid product data sheet. Bosch Sensortec products are
* provided with the express understanding that there is no warranty of fitness for a particular purpose.
* They are not fit for use in life-sustaining, safety or security sensitive systems or any system or device
* that may lead to bodily harm or property damage if the system or device malfunctions. In addition,
* Bosch Sensortec products are not fit for use in products which interact with motor vehicle systems.
* The resale and/or use of products are at the purchasers own risk and his own responsibility. The
* examination of fitness for the intended use is the sole responsibility of the Purchaser.
*
* The purchaser shall indemnify Bosch Sensortec from all third party claims, including any claims for
* incidental, or consequential damages, arising from any product use not covered by the parameters of
* the respective valid product data sheet or not approved by Bosch Sensortec and reimburse Bosch
* Sensortec for all costs in connection with such claims.
*
* The purchaser must monitor the market for the purchased products, particularly with regard to
* product safety and inform Bosch Sensortec without delay of all security relevant incidents.
*
* Engineering Samples are marked with an asterisk (*) or (e). Samples may vary from the valid
* technical specifications of the product series. They are therefore not intended or fit for resale to third
* parties or for use in end products. Their sole purpose is internal client testing. The testing of an
* engineering sample may in no way replace the testing of a product series. Bosch Sensortec
* assumes no liability for the use of engineering samples. By accepting the engineering samples, the
* Purchaser agrees to indemnify Bosch Sensortec from all claims arising from the use of engineering
* samples.
*
* Special:
* This software module (hereinafter called "Software") and any information on application-sheets
* (hereinafter called "Information") is provided free of charge for the sole purpose to support your
* application work. The Software and Information is subject to the following terms and conditions:
*
* The Software is specifically designed for the exclusive use for Bosch Sensortec products by
* personnel who have special experience and training. Do not use this Software if you do not have the
* proper experience or training.
*
* This Software package is provided `` as is `` and without any expressed or implied warranties,
* including without limitation, the implied warranties of merchantability and fitness for a particular
* purpose.
*
* Bosch Sensortec and their representatives and agents deny any liability for the functional impairment
* of this Software in terms of fitness, performance and safety. Bosch Sensortec and their
* representatives and agents shall not be liable for any direct or indirect damages or injury, except as
* otherwise stipulated in mandatory applicable law.
*
* The Information provided is believed to be accurate and reliable. Bosch Sensortec assumes no
* responsibility for the consequences of use of such Information nor for any infringement of patents or
* other rights of third parties which may result from its use. No license is granted by implication or
* otherwise under any patent or patent rights of Bosch. Specifications mentioned in the Information are
* subject to change without notice.
*
* It is not allowed to deliver the source code of the Software to any third party without permission of
* Bosch Sensortec.
*
*/
/*!
* @file bsec_integration.h
*
* @brief
* Contains BSEC integration API
*/
/*!
* @addtogroup bsec_examples BSEC Examples
* @brief BSEC usage examples
* @{*/
#ifndef __BSEC_INTEGRATION_H__
#define __BSEC_INTEGRATION_H__
#ifdef __cplusplus
extern "C"
{
#endif
/**********************************************************************************************************************/
/* header files */
/**********************************************************************************************************************/
/* Use the following bme680 driver: https://github.com/BoschSensortec/BME680_driver/releases/tag/bme680_v3.5.1 */
#include "bme680.h"
/* BSEC header files are available in the inc/ folder of the release package */
#include "bsec_interface.h"
#include "bsec_datatypes.h"
/**********************************************************************************************************************/
/* type definitions */
/**********************************************************************************************************************/
/* function pointer to the system specific sleep function */
typedef void (*sleep_fct)(uint32_t t_ms);
/* function pointer to the system specific timestamp derivation function */
typedef int64_t (*get_timestamp_us_fct)();
/* function pointer to the function processing obtained BSEC outputs */
typedef void (*output_ready_fct)(int64_t timestamp, float iaq, uint8_t iaq_accuracy, float temperature, float humidity,
float pressure, float raw_temperature, float raw_humidity, float gas, bsec_library_return_t bsec_status,
float static_iaq, float co2_equivalent, float breath_voc_equivalent);
/* function pointer to the function loading a previous BSEC state from NVM */
typedef uint32_t (*state_load_fct)(uint8_t *state_buffer, uint32_t n_buffer);
/* function pointer to the function saving BSEC state to NVM */
typedef void (*state_save_fct)(const uint8_t *state_buffer, uint32_t length);
/* function pointer to the function loading the BSEC configuration string from NVM */
typedef uint32_t (*config_load_fct)(uint8_t *state_buffer, uint32_t n_buffer);
/* structure definitions */
/* Structure with the return value from bsec_iot_init() */
typedef struct{
/*! Result of API execution status */
int8_t bme680_status;
/*! Result of BSEC library */
bsec_library_return_t bsec_status;
}return_values_init;
/**********************************************************************************************************************/
/* function declarations */
/**********************************************************************************************************************/
/*!
* @brief Initialize the BME680 sensor and the BSEC library
*
* @param[in] sample_rate mode to be used (either BSEC_SAMPLE_RATE_ULP or BSEC_SAMPLE_RATE_LP)
* @param[in] temperature_offset device-specific temperature offset (due to self-heating)
* @param[in] bus_write pointer to the bus writing function
* @param[in] bus_read pointer to the bus reading function
* @param[in] sleep pointer to the system-specific sleep function
* @param[in] state_load pointer to the system-specific state load function
*
* @return zero if successful, negative otherwise
*/
return_values_init bsec_iot_init(float sample_rate, float temperature_offset, bme680_com_fptr_t bus_write, bme680_com_fptr_t bus_read,
sleep_fct sleep, state_load_fct state_load, config_load_fct config_load);
/*!
* @brief Runs the main (endless) loop that queries sensor settings, applies them, and processes the measured data
*
* @param[in] sleep pointer to the system-specific sleep function
* @param[in] get_timestamp_us pointer to the system-specific timestamp derivation function
* @param[in] output_ready pointer to the function processing obtained BSEC outputs
* @param[in] state_save pointer to the system-specific state save function
* @param[in] save_intvl interval at which BSEC state should be saved (in samples)
*
* @return return_values_init struct with the result of the API and the BSEC library
*/
void bsec_iot_loop(sleep_fct sleep, get_timestamp_us_fct get_timestamp_us, output_ready_fct output_ready,
state_save_fct state_save, uint32_t save_intvl);
#ifdef __cplusplus
}
#endif
#endif /* __BSEC_INTEGRATION_H__ */
/*! @}*/

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@ -0,0 +1,258 @@
/*
* Copyright (C) 2017 Robert Bosch. All Rights Reserved.
*
* Disclaimer
*
* Common:
* Bosch Sensortec products are developed for the consumer goods industry. They may only be used
* within the parameters of the respective valid product data sheet. Bosch Sensortec products are
* provided with the express understanding that there is no warranty of fitness for a particular purpose.
* They are not fit for use in life-sustaining, safety or security sensitive systems or any system or device
* that may lead to bodily harm or property damage if the system or device malfunctions. In addition,
* Bosch Sensortec products are not fit for use in products which interact with motor vehicle systems.
* The resale and/or use of products are at the purchasers own risk and his own responsibility. The
* examination of fitness for the intended use is the sole responsibility of the Purchaser.
*
* The purchaser shall indemnify Bosch Sensortec from all third party claims, including any claims for
* incidental, or consequential damages, arising from any product use not covered by the parameters of
* the respective valid product data sheet or not approved by Bosch Sensortec and reimburse Bosch
* Sensortec for all costs in connection with such claims.
*
* The purchaser must monitor the market for the purchased products, particularly with regard to
* product safety and inform Bosch Sensortec without delay of all security relevant incidents.
*
* Engineering Samples are marked with an asterisk (*) or (e). Samples may vary from the valid
* technical specifications of the product series. They are therefore not intended or fit for resale to third
* parties or for use in end products. Their sole purpose is internal client testing. The testing of an
* engineering sample may in no way replace the testing of a product series. Bosch Sensortec
* assumes no liability for the use of engineering samples. By accepting the engineering samples, the
* Purchaser agrees to indemnify Bosch Sensortec from all claims arising from the use of engineering
* samples.
*
* Special:
* This software module (hereinafter called "Software") and any information on application-sheets
* (hereinafter called "Information") is provided free of charge for the sole purpose to support your
* application work. The Software and Information is subject to the following terms and conditions:
*
* The Software is specifically designed for the exclusive use for Bosch Sensortec products by
* personnel who have special experience and training. Do not use this Software if you do not have the
* proper experience or training.
*
* This Software package is provided `` as is `` and without any expressed or implied warranties,
* including without limitation, the implied warranties of merchantability and fitness for a particular
* purpose.
*
* Bosch Sensortec and their representatives and agents deny any liability for the functional impairment
* of this Software in terms of fitness, performance and safety. Bosch Sensortec and their
* representatives and agents shall not be liable for any direct or indirect damages or injury, except as
* otherwise stipulated in mandatory applicable law.
*
* The Information provided is believed to be accurate and reliable. Bosch Sensortec assumes no
* responsibility for the consequences of use of such Information nor for any infringement of patents or
* other rights of third parties which may result from its use. No license is granted by implication or
* otherwise under any patent or patent rights of Bosch. Specifications mentioned in the Information are
* subject to change without notice.
*
* It is not allowed to deliver the source code of the Software to any third party without permission of
* Bosch Sensortec.
*
*/
/*!
* @file bsec_iot_example.c
*
* @brief
* Example for using of BSEC library in a fixed configuration with the BME680 sensor.
* This works by running an endless loop in the bsec_iot_loop() function.
*/
/*!
* @addtogroup bsec_examples BSEC Examples
* @brief BSEC usage examples
* @{*/
/**********************************************************************************************************************/
/* header files */
/**********************************************************************************************************************/
#include "bsec_integration.h"
/**********************************************************************************************************************/
/* functions */
/**********************************************************************************************************************/
/*!
* @brief Write operation in either I2C or SPI
*
* param[in] dev_addr I2C or SPI device address
* param[in] reg_addr register address
* param[in] reg_data_ptr pointer to the data to be written
* param[in] data_len number of bytes to be written
*
* @return result of the bus communication function
*/
int8_t bus_write(uint8_t dev_addr, uint8_t reg_addr, uint8_t *reg_data_ptr, uint16_t data_len)
{
// ...
// Please insert system specific function to write to the bus where BME680 is connected
// ...
return 0;
}
/*!
* @brief Read operation in either I2C or SPI
*
* param[in] dev_addr I2C or SPI device address
* param[in] reg_addr register address
* param[out] reg_data_ptr pointer to the memory to be used to store the read data
* param[in] data_len number of bytes to be read
*
* @return result of the bus communication function
*/
int8_t bus_read(uint8_t dev_addr, uint8_t reg_addr, uint8_t *reg_data_ptr, uint16_t data_len)
{
// ...
// Please insert system specific function to read from bus where BME680 is connected
// ...
return 0;
}
/*!
* @brief System specific implementation of sleep function
*
* @param[in] t_ms time in milliseconds
*
* @return none
*/
void sleep(uint32_t t_ms)
{
// ...
// Please insert system specific function sleep or delay for t_ms milliseconds
// ...
}
/*!
* @brief Capture the system time in microseconds
*
* @return system_current_time current system timestamp in microseconds
*/
int64_t get_timestamp_us()
{
int64_t system_current_time = 0;
// ...
// Please insert system specific function to retrieve a timestamp (in microseconds)
// ...
return system_current_time;
}
/*!
* @brief Handling of the ready outputs
*
* @param[in] timestamp time in nanoseconds
* @param[in] iaq IAQ signal
* @param[in] iaq_accuracy accuracy of IAQ signal
* @param[in] temperature temperature signal
* @param[in] humidity humidity signal
* @param[in] pressure pressure signal
* @param[in] raw_temperature raw temperature signal
* @param[in] raw_humidity raw humidity signal
* @param[in] gas raw gas sensor signal
* @param[in] bsec_status value returned by the bsec_do_steps() call
*
* @return none
*/
void output_ready(int64_t timestamp, float iaq, uint8_t iaq_accuracy, float temperature, float humidity,
float pressure, float raw_temperature, float raw_humidity, float gas, bsec_library_return_t bsec_status,
float static_iaq, float co2_equivalent, float breath_voc_equivalent)
{
// ...
// Please insert system specific code to further process or display the BSEC outputs
// ...
}
/*!
* @brief Load previous library state from non-volatile memory
*
* @param[in,out] state_buffer buffer to hold the loaded state string
* @param[in] n_buffer size of the allocated state buffer
*
* @return number of bytes copied to state_buffer
*/
uint32_t state_load(uint8_t *state_buffer, uint32_t n_buffer)
{
// ...
// Load a previous library state from non-volatile memory, if available.
//
// Return zero if loading was unsuccessful or no state was available,
// otherwise return length of loaded state string.
// ...
return 0;
}
/*!
* @brief Save library state to non-volatile memory
*
* @param[in] state_buffer buffer holding the state to be stored
* @param[in] length length of the state string to be stored
*
* @return none
*/
void state_save(const uint8_t *state_buffer, uint32_t length)
{
// ...
// Save the string some form of non-volatile memory, if possible.
// ...
}
/*!
* @brief Load library config from non-volatile memory
*
* @param[in,out] config_buffer buffer to hold the loaded state string
* @param[in] n_buffer size of the allocated state buffer
*
* @return number of bytes copied to config_buffer
*/
uint32_t config_load(uint8_t *config_buffer, uint32_t n_buffer)
{
// ...
// Load a library config from non-volatile memory, if available.
//
// Return zero if loading was unsuccessful or no config was available,
// otherwise return length of loaded config string.
// ...
return 0;
}
/*!
* @brief Main function which configures BSEC library and then reads and processes the data from sensor based
* on timer ticks
*
* @return result of the processing
*/
int main()
{
return_values_init ret;
/* Call to the function which initializes the BSEC library
* Switch on low-power mode and provide no temperature offset */
ret = bsec_iot_init(BSEC_SAMPLE_RATE_LP, 0.0f, bus_write, bus_read, sleep, state_load, config_load);
if (ret.bme680_status)
{
/* Could not intialize BME680 */
return (int)ret.bme680_status;
}
else if (ret.bsec_status)
{
/* Could not intialize BSEC library */
return (int)ret.bsec_status;
}
/* Call to endless loop function which reads and processes data based on sensor settings */
/* State is saved every 10.000 samples, which means every 10.000 * 3 secs = 500 minutes */
bsec_iot_loop(sleep, get_timestamp_us, output_ready, state_save, 10000);
return 0;
}
/*! @}*/

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@ -0,0 +1,291 @@
/*
* Copyright (C) 2017 Robert Bosch. All Rights Reserved.
*
* Disclaimer
*
* Common:
* Bosch Sensortec products are developed for the consumer goods industry. They may only be used
* within the parameters of the respective valid product data sheet. Bosch Sensortec products are
* provided with the express understanding that there is no warranty of fitness for a particular purpose.
* They are not fit for use in life-sustaining, safety or security sensitive systems or any system or device
* that may lead to bodily harm or property damage if the system or device malfunctions. In addition,
* Bosch Sensortec products are not fit for use in products which interact with motor vehicle systems.
* The resale and/or use of products are at the purchasers own risk and his own responsibility. The
* examination of fitness for the intended use is the sole responsibility of the Purchaser.
*
* The purchaser shall indemnify Bosch Sensortec from all third party claims, including any claims for
* incidental, or consequential damages, arising from any product use not covered by the parameters of
* the respective valid product data sheet or not approved by Bosch Sensortec and reimburse Bosch
* Sensortec for all costs in connection with such claims.
*
* The purchaser must monitor the market for the purchased products, particularly with regard to
* product safety and inform Bosch Sensortec without delay of all security relevant incidents.
*
* Engineering Samples are marked with an asterisk (*) or (e). Samples may vary from the valid
* technical specifications of the product series. They are therefore not intended or fit for resale to third
* parties or for use in end products. Their sole purpose is internal client testing. The testing of an
* engineering sample may in no way replace the testing of a product series. Bosch Sensortec
* assumes no liability for the use of engineering samples. By accepting the engineering samples, the
* Purchaser agrees to indemnify Bosch Sensortec from all claims arising from the use of engineering
* samples.
*
* Special:
* This software module (hereinafter called "Software") and any information on application-sheets
* (hereinafter called "Information") is provided free of charge for the sole purpose to support your
* application work. The Software and Information is subject to the following terms and conditions:
*
* The Software is specifically designed for the exclusive use for Bosch Sensortec products by
* personnel who have special experience and training. Do not use this Software if you do not have the
* proper experience or training.
*
* This Software package is provided `` as is `` and without any expressed or implied warranties,
* including without limitation, the implied warranties of merchantability and fitness for a particular
* purpose.
*
* Bosch Sensortec and their representatives and agents deny any liability for the functional impairment
* of this Software in terms of fitness, performance and safety. Bosch Sensortec and their
* representatives and agents shall not be liable for any direct or indirect damages or injury, except as
* otherwise stipulated in mandatory applicable law.
*
* The Information provided is believed to be accurate and reliable. Bosch Sensortec assumes no
* responsibility for the consequences of use of such Information nor for any infringement of patents or
* other rights of third parties which may result from its use. No license is granted by implication or
* otherwise under any patent or patent rights of Bosch. Specifications mentioned in the Information are
* subject to change without notice.
*
* It is not allowed to deliver the source code of the Software to any third party without permission of
* Bosch Sensortec.
*
*/
/*!
* @file bsec_iot_example.ino
*
* @brief
* Example for using of BSEC library in a fixed configuration with the BME680 sensor.
* This works by running an endless loop in the bsec_iot_loop() function.
*/
/*!
* @addtogroup bsec_examples BSEC Examples
* @brief BSEC usage examples
* @{*/
/**********************************************************************************************************************/
/* header files */
/**********************************************************************************************************************/
#include "bsec_integration.h"
#include <Wire.h>
/**********************************************************************************************************************/
/* functions */
/**********************************************************************************************************************/
/*!
* @brief Write operation in either Wire or SPI
*
* param[in] dev_addr Wire or SPI device address
* param[in] reg_addr register address
* param[in] reg_data_ptr pointer to the data to be written
* param[in] data_len number of bytes to be written
*
* @return result of the bus communication function
*/
int8_t bus_write(uint8_t dev_addr, uint8_t reg_addr, uint8_t *reg_data_ptr, uint16_t data_len)
{
Wire.beginTransmission(dev_addr);
Wire.write(reg_addr); /* Set register address to start writing to */
/* Write the data */
for (int index = 0; index < data_len; index++) {
Wire.write(reg_data_ptr[index]);
}
return (int8_t)Wire.endTransmission();
}
/*!
* @brief Read operation in either Wire or SPI
*
* param[in] dev_addr Wire or SPI device address
* param[in] reg_addr register address
* param[out] reg_data_ptr pointer to the memory to be used to store the read data
* param[in] data_len number of bytes to be read
*
* @return result of the bus communication function
*/
int8_t bus_read(uint8_t dev_addr, uint8_t reg_addr, uint8_t *reg_data_ptr, uint16_t data_len)
{
int8_t comResult = 0;
Wire.beginTransmission(dev_addr);
Wire.write(reg_addr); /* Set register address to start reading from */
comResult = Wire.endTransmission();
delayMicroseconds(150); /* Precautionary response delay */
Wire.requestFrom(dev_addr, (uint8_t)data_len); /* Request data */
int index = 0;
while (Wire.available()) /* The slave device may send less than requested (burst read) */
{
reg_data_ptr[index] = Wire.read();
index++;
}
return comResult;
}
/*!
* @brief System specific implementation of sleep function
*
* @param[in] t_ms time in milliseconds
*
* @return none
*/
void sleep(uint32_t t_ms)
{
delay(t_ms);
}
/*!
* @brief Capture the system time in microseconds
*
* @return system_current_time current system timestamp in microseconds
*/
int64_t get_timestamp_us()
{
return (int64_t) millis() * 1000;
}
/*!
* @brief Handling of the ready outputs
*
* @param[in] timestamp time in nanoseconds
* @param[in] iaq IAQ signal
* @param[in] iaq_accuracy accuracy of IAQ signal
* @param[in] temperature temperature signal
* @param[in] humidity humidity signal
* @param[in] pressure pressure signal
* @param[in] raw_temperature raw temperature signal
* @param[in] raw_humidity raw humidity signal
* @param[in] gas raw gas sensor signal
* @param[in] bsec_status value returned by the bsec_do_steps() call
*
* @return none
*/
void output_ready(int64_t timestamp, float iaq, uint8_t iaq_accuracy, float temperature, float humidity,
float pressure, float raw_temperature, float raw_humidity, float gas, bsec_library_return_t bsec_status,
float static_iaq, float co2_equivalent, float breath_voc_equivalent)
{
Serial.print("[");
Serial.print(timestamp/1e6);
Serial.print("] T: ");
Serial.print(temperature);
Serial.print("| rH: ");
Serial.print(humidity);
Serial.print("| IAQ: ");
Serial.print(iaq);
Serial.print(" (");
Serial.print(iaq_accuracy);
Serial.print("| Static IAQ: ");
Serial.print(static_iaq);
Serial.print("| CO2e: ");
Serial.print(co2_equivalent);
Serial.print("| bVOC: ");
Serial.println(breath_voc_equivalent);
}
/*!
* @brief Load previous library state from non-volatile memory
*
* @param[in,out] state_buffer buffer to hold the loaded state string
* @param[in] n_buffer size of the allocated state buffer
*
* @return number of bytes copied to state_buffer
*/
uint32_t state_load(uint8_t *state_buffer, uint32_t n_buffer)
{
// ...
// Load a previous library state from non-volatile memory, if available.
//
// Return zero if loading was unsuccessful or no state was available,
// otherwise return length of loaded state string.
// ...
return 0;
}
/*!
* @brief Save library state to non-volatile memory
*
* @param[in] state_buffer buffer holding the state to be stored
* @param[in] length length of the state string to be stored
*
* @return none
*/
void state_save(const uint8_t *state_buffer, uint32_t length)
{
// ...
// Save the string some form of non-volatile memory, if possible.
// ...
}
/*!
* @brief Load library config from non-volatile memory
*
* @param[in,out] config_buffer buffer to hold the loaded state string
* @param[in] n_buffer size of the allocated state buffer
*
* @return number of bytes copied to config_buffer
*/
uint32_t config_load(uint8_t *config_buffer, uint32_t n_buffer)
{
// ...
// Load a library config from non-volatile memory, if available.
//
// Return zero if loading was unsuccessful or no config was available,
// otherwise return length of loaded config string.
// ...
return 0;
}
/*!
* @brief Main function which configures BSEC library and then reads and processes the data from sensor based
* on timer ticks
*
* @return result of the processing
*/
void setup()
{
return_values_init ret;
/* Init I2C and serial communication */
Wire.begin();
Serial.begin(115200);
/* Call to the function which initializes the BSEC library
* Switch on low-power mode and provide no temperature offset */
ret = bsec_iot_init(BSEC_SAMPLE_RATE_LP, 5.0f, bus_write, bus_read, sleep, state_load, config_load);
if (ret.bme680_status)
{
/* Could not intialize BME680 */
Serial.println("Error while initializing BME680");
return;
}
else if (ret.bsec_status)
{
/* Could not intialize BSEC library */
Serial.println("Error while initializing BSEC library");
return;
}
/* Call to endless loop function which reads and processes data based on sensor settings */
/* State is saved every 10.000 samples, which means every 10.000 * 3 secs = 500 minutes */
bsec_iot_loop(sleep, get_timestamp_us, output_ready, state_save, 10000);
}
void loop()
{
}
/*! @}*/

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@ -0,0 +1,290 @@
/*
* Copyright (C) 2017 Robert Bosch. All Rights Reserved.
*
* Disclaimer
*
* Common:
* Bosch Sensortec products are developed for the consumer goods industry. They may only be used
* within the parameters of the respective valid product data sheet. Bosch Sensortec products are
* provided with the express understanding that there is no warranty of fitness for a particular purpose.
* They are not fit for use in life-sustaining, safety or security sensitive systems or any system or device
* that may lead to bodily harm or property damage if the system or device malfunctions. In addition,
* Bosch Sensortec products are not fit for use in products which interact with motor vehicle systems.
* The resale and/or use of products are at the purchasers own risk and his own responsibility. The
* examination of fitness for the intended use is the sole responsibility of the Purchaser.
*
* The purchaser shall indemnify Bosch Sensortec from all third party claims, including any claims for
* incidental, or consequential damages, arising from any product use not covered by the parameters of
* the respective valid product data sheet or not approved by Bosch Sensortec and reimburse Bosch
* Sensortec for all costs in connection with such claims.
*
* The purchaser must monitor the market for the purchased products, particularly with regard to
* product safety and inform Bosch Sensortec without delay of all security relevant incidents.
*
* Engineering Samples are marked with an asterisk (*) or (e). Samples may vary from the valid
* technical specifications of the product series. They are therefore not intended or fit for resale to third
* parties or for use in end products. Their sole purpose is internal client testing. The testing of an
* engineering sample may in no way replace the testing of a product series. Bosch Sensortec
* assumes no liability for the use of engineering samples. By accepting the engineering samples, the
* Purchaser agrees to indemnify Bosch Sensortec from all claims arising from the use of engineering
* samples.
*
* Special:
* This software module (hereinafter called "Software") and any information on application-sheets
* (hereinafter called "Information") is provided free of charge for the sole purpose to support your
* application work. The Software and Information is subject to the following terms and conditions:
*
* The Software is specifically designed for the exclusive use for Bosch Sensortec products by
* personnel who have special experience and training. Do not use this Software if you do not have the
* proper experience or training.
*
* This Software package is provided `` as is `` and without any expressed or implied warranties,
* including without limitation, the implied warranties of merchantability and fitness for a particular
* purpose.
*
* Bosch Sensortec and their representatives and agents deny any liability for the functional impairment
* of this Software in terms of fitness, performance and safety. Bosch Sensortec and their
* representatives and agents shall not be liable for any direct or indirect damages or injury, except as
* otherwise stipulated in mandatory applicable law.
*
* The Information provided is believed to be accurate and reliable. Bosch Sensortec assumes no
* responsibility for the consequences of use of such Information nor for any infringement of patents or
* other rights of third parties which may result from its use. No license is granted by implication or
* otherwise under any patent or patent rights of Bosch. Specifications mentioned in the Information are
* subject to change without notice.
*
* It is not allowed to deliver the source code of the Software to any third party without permission of
* Bosch Sensortec.
*
*/
/*!
* @file bsec_iot_ulp_plus_example.c
*
* @brief
* Example for using of BSEC library in a fixed configuration with the BME680 sensor.
* This works by running an endless loop in the bsec_iot_loop() function.
*/
/*!
* @addtogroup bsec_examples BSEC Examples
* @brief BSEC usage examples
* @{*/
/**********************************************************************************************************************/
/* header files */
/**********************************************************************************************************************/
/* BSEC configuration files are available in the config/ folder of the release package. Please chose a configuration file with 3s maximum time between `bsec_sensor_control()` calls */
#include "bsec_integration.h"
/**********************************************************************************************************************/
/* functions */
/**********************************************************************************************************************/
/*!
* @brief Write operation in either I2C or SPI
*
* param[in] dev_addr I2C or SPI device address
* param[in] reg_addr register address
* param[in] reg_data_ptr pointer to the data to be written
* param[in] data_len number of bytes to be written
*
* @return result of the bus communication function
*/
int8_t bus_write(uint8_t dev_addr, uint8_t reg_addr, uint8_t *reg_data_ptr, uint16_t data_len)
{
// ...
// Please insert system specific function to write to the bus where BME680 is connected
// ...
return 0;
}
/*!
* @brief Read operation in either I2C or SPI
*
* param[in] dev_addr I2C or SPI device address
* param[in] reg_addr register address
* param[out] reg_data_ptr pointer to the memory to be used to store the read data
* param[in] data_len number of bytes to be read
*
* @return result of the bus communication function
*/
int8_t bus_read(uint8_t dev_addr, uint8_t reg_addr, uint8_t *reg_data_ptr, uint16_t data_len)
{
// ...
// Please insert system specific function to read from bus where BME680 is connected
// ...
return 0;
}
/*!
* @brief System specific implementation of sleep function
*
* @param[in] t_ms time in milliseconds
*
* @return none
*/
void sleep(uint32_t t_ms)
{
// ...
// Please insert system specific function sleep or delay for t_ms milliseconds
// ...
}
/*!
* @brief Capture the system time in microseconds
*
* @return system_current_time current system timestamp in microseconds
*/
int64_t get_timestamp_us()
{
int64_t system_current_time = 0;
// ...
// Please insert system specific function to retrieve a timestamp (in microseconds)
// ...
return system_current_time;
}
/*!
* @brief Handling of the ready outputs
*
* @param[in] timestamp time in nanoseconds
* @param[in] iaq IAQ signal
* @param[in] iaq_accuracy accuracy of IAQ signal
* @param[in] temperature temperature signal
* @param[in] humidity humidity signal
* @param[in] pressure pressure signal
* @param[in] raw_temperature raw temperature signal
* @param[in] raw_humidity raw humidity signal
* @param[in] gas raw gas sensor signal
* @param[in] bsec_status value returned by the bsec_do_steps() call
*
* @return none
*/
void output_ready(int64_t timestamp, float iaq, uint8_t iaq_accuracy, float temperature, float humidity,
float pressure, float raw_temperature, float raw_humidity, float gas, bsec_library_return_t bsec_status,
float static_iaq, float co2_equivalent, float breath_voc_equivalent)
{
// ...
// Please insert system specific code to further process or display the BSEC outputs
// ...
}
/*!
* @brief Load previous library state from non-volatile memory
*
* @param[in,out] state_buffer buffer to hold the loaded state string
* @param[in] n_buffer size of the allocated state buffer
*
* @return number of bytes copied to state_buffer
*/
uint32_t state_load(uint8_t *state_buffer, uint32_t n_buffer)
{
// ...
// Load a previous library state from non-volatile memory, if available.
//
// Return zero if loading was unsuccessful or no state was available,
// otherwise return length of loaded state string.
// ...
return 0;
}
/*!
* @brief Save library state to non-volatile memory
*
* @param[in] state_buffer buffer holding the state to be stored
* @param[in] length length of the state string to be stored
*
* @return none
*/
void state_save(const uint8_t *state_buffer, uint32_t length)
{
// ...
// Save the string some form of non-volatile memory, if possible.
// ...
}
/*!
* @brief Load library config from non-volatile memory
*
* @param[in,out] config_buffer buffer to hold the loaded state string
* @param[in] n_buffer size of the allocated state buffer
*
* @return number of bytes copied to config_buffer
*/
uint32_t config_load(uint8_t *config_buffer, uint32_t n_buffer)
{
// ...
// Load a library config from non-volatile memory, if available.
//
// Return zero if loading was unsuccessful or no config was available,
// otherwise return length of loaded config string.
// ...
return 0;
}
/*!
* @brief Interrupt handler for press of a ULP plus button
*
* @return none
*/
void ulp_plus_button_press()
{
/* We call bsec_update_subscription() in order to instruct BSEC to perform an extra measurement at the next
* possible time slot
*/
bsec_sensor_configuration_t requested_virtual_sensors[1];
uint8_t n_requested_virtual_sensors = 1;
bsec_sensor_configuration_t required_sensor_settings[BSEC_MAX_PHYSICAL_SENSOR];
uint8_t n_required_sensor_settings = BSEC_MAX_PHYSICAL_SENSOR;
bsec_library_return_t status = BSEC_OK;
/* To trigger a ULP plus, we request the IAQ virtual sensor with a specific sample rate code */
requested_virtual_sensors[0].sensor_id = BSEC_OUTPUT_IAQ;
requested_virtual_sensors[0].sample_rate = BSEC_SAMPLE_RATE_ULP_MEASUREMENT_ON_DEMAND;
/* Call bsec_update_subscription() to enable/disable the requested virtual sensors */
status = bsec_update_subscription(requested_virtual_sensors, n_requested_virtual_sensors, required_sensor_settings,
&n_required_sensor_settings);
/* The status code would tell is if the request was accepted. It will be rejected if the sensor is not already in
* ULP mode, or if the time difference between requests is too short, for example. */
}
/*!
* @brief Main function which configures BSEC library and then reads and processes the data from sensor based
* on timer ticks
*
* @return result of the processing
*/
int main()
{
return_values_init ret;
// ...
// Attach a button (or other) interrupt here to the ulp_plus_button_press() handler function to
// enable this interrupt to trigger a ULP plus
// ...
/* Call to the function which initializes the BSEC library
* Switch on ultra_low-power mode and provide no temperature offset */
ret = bsec_iot_init(BSEC_SAMPLE_RATE_ULP, 0.0f, bus_write, bus_read, sleep, state_load, config_load);
if (ret.bme680_status)
{
/* Could not intialize BME680 or BSEC library */
return (int)ret.bme680_status;
}
else if (ret.bsec_status)
{
/* Could not intialize BSEC library */
return (int)ret.bsec_status;
}
/* Call to endless loop function which reads and processes data based on sensor settings */
/* State is saved every 10.000 samples, which means every 100 * 300 secs = 500 minutes */
bsec_iot_loop(sleep, get_timestamp_us, output_ready, state_save, 100);
return 0;
}
/*! @}*/

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@ -0,0 +1,342 @@
/*
* Copyright (C) 2017 Robert Bosch. All Rights Reserved.
*
* Disclaimer
*
* Common:
* Bosch Sensortec products are developed for the consumer goods industry. They may only be used
* within the parameters of the respective valid product data sheet. Bosch Sensortec products are
* provided with the express understanding that there is no warranty of fitness for a particular purpose.
* They are not fit for use in life-sustaining, safety or security sensitive systems or any system or device
* that may lead to bodily harm or property damage if the system or device malfunctions. In addition,
* Bosch Sensortec products are not fit for use in products which interact with motor vehicle systems.
* The resale and/or use of products are at the purchasers own risk and his own responsibility. The
* examination of fitness for the intended use is the sole responsibility of the Purchaser.
*
* The purchaser shall indemnify Bosch Sensortec from all third party claims, including any claims for
* incidental, or consequential damages, arising from any product use not covered by the parameters of
* the respective valid product data sheet or not approved by Bosch Sensortec and reimburse Bosch
* Sensortec for all costs in connection with such claims.
*
* The purchaser must monitor the market for the purchased products, particularly with regard to
* product safety and inform Bosch Sensortec without delay of all security relevant incidents.
*
* Engineering Samples are marked with an asterisk (*) or (e). Samples may vary from the valid
* technical specifications of the product series. They are therefore not intended or fit for resale to third
* parties or for use in end products. Their sole purpose is internal client testing. The testing of an
* engineering sample may in no way replace the testing of a product series. Bosch Sensortec
* assumes no liability for the use of engineering samples. By accepting the engineering samples, the
* Purchaser agrees to indemnify Bosch Sensortec from all claims arising from the use of engineering
* samples.
*
* Special:
* This software module (hereinafter called "Software") and any information on application-sheets
* (hereinafter called "Information") is provided free of charge for the sole purpose to support your
* application work. The Software and Information is subject to the following terms and conditions:
*
* The Software is specifically designed for the exclusive use for Bosch Sensortec products by
* personnel who have special experience and training. Do not use this Software if you do not have the
* proper experience or training.
*
* This Software package is provided `` as is `` and without any expressed or implied warranties,
* including without limitation, the implied warranties of merchantability and fitness for a particular
* purpose.
*
* Bosch Sensortec and their representatives and agents deny any liability for the functional impairment
* of this Software in terms of fitness, performance and safety. Bosch Sensortec and their
* representatives and agents shall not be liable for any direct or indirect damages or injury, except as
* otherwise stipulated in mandatory applicable law.
*
* The Information provided is believed to be accurate and reliable. Bosch Sensortec assumes no
* responsibility for the consequences of use of such Information nor for any infringement of patents or
* other rights of third parties which may result from its use. No license is granted by implication or
* otherwise under any patent or patent rights of Bosch. Specifications mentioned in the Information are
* subject to change without notice.
*
* It is not allowed to deliver the source code of the Software to any third party without permission of
* Bosch Sensortec.
*
*/
/*!
* @file bsec_iot_ulp_plus_example.ino
*
* @brief
* Example for using of BSEC library in a fixed configuration with the BME680 sensor.
* This works by running an endless loop in the bsec_iot_loop() function.
*/
/*!
* @addtogroup bsec_examples BSEC Examples
* @brief BSEC usage examples
* @{*/
/**********************************************************************************************************************/
/* header files */
/**********************************************************************************************************************/
#include "bsec_integration.h"
#include "bsec_serialized_configurations_iaq.h"
#include <Wire.h>
/**********************************************************************************************************************/
/* functions */
/**********************************************************************************************************************/
/*!
* @brief Write operation in either Wire or SPI
*
* param[in] dev_addr Wire or SPI device address
* param[in] reg_addr register address
* param[in] reg_data_ptr pointer to the data to be written
* param[in] data_len number of bytes to be written
*
* @return result of the bus communication function
*/
int8_t bus_write(uint8_t dev_addr, uint8_t reg_addr, uint8_t *reg_data_ptr, uint16_t data_len)
{
Wire.beginTransmission(dev_addr);
Wire.write(reg_addr); /* Set register address to start writing to */
/* Write the data */
for (int index = 0; index < data_len; index++) {
Wire.write(reg_data_ptr[index]);
}
return (int8_t)Wire.endTransmission();
}
/*!
* @brief Read operation in either Wire or SPI
*
* param[in] dev_addr Wire or SPI device address
* param[in] reg_addr register address
* param[out] reg_data_ptr pointer to the memory to be used to store the read data
* param[in] data_len number of bytes to be read
*
* @return result of the bus communication function
*/
int8_t bus_read(uint8_t dev_addr, uint8_t reg_addr, uint8_t *reg_data_ptr, uint16_t data_len)
{
int8_t comResult = 0;
Wire.beginTransmission(dev_addr);
Wire.write(reg_addr); /* Set register address to start reading from */
comResult = Wire.endTransmission();
delayMicroseconds(150); /* Precautionary response delay */
Wire.requestFrom(dev_addr, (uint8_t)data_len); /* Request data */
int index = 0;
while (Wire.available()) /* The slave device may send less than requested (burst read) */
{
reg_data_ptr[index] = Wire.read();
index++;
}
return comResult;
}
/*!
* @brief System specific implementation of sleep function
*
* @param[in] t_ms time in milliseconds
*
* @return none
*/
void sleep(uint32_t t_ms)
{
delay(t_ms);
}
/*!
* @brief Capture the system time in microseconds
*
* @return system_current_time current system timestamp in microseconds
*/
int64_t get_timestamp_us()
{
return (int64_t) millis() * 1000;
}
/*!
* @brief Handling of the ready outputs
*
* @param[in] timestamp time in nanoseconds
* @param[in] iaq IAQ signal
* @param[in] iaq_accuracy accuracy of IAQ signal
* @param[in] temperature temperature signal
* @param[in] humidity humidity signal
* @param[in] pressure pressure signal
* @param[in] raw_temperature raw temperature signal
* @param[in] raw_humidity raw humidity signal
* @param[in] gas raw gas sensor signal
* @param[in] bsec_status value returned by the bsec_do_steps() call
*
* @return none
*/
void output_ready(int64_t timestamp, float iaq, uint8_t iaq_accuracy, float temperature, float humidity,
float pressure, float raw_temperature, float raw_humidity, float gas, bsec_library_return_t bsec_status,
float static_iaq, float co2_equivalent, float breath_voc_equivalent)
{
Serial.print("[");
Serial.print(timestamp/1e6);
Serial.print("] T: ");
Serial.print(temperature);
Serial.print("| rH: ");
Serial.print(humidity);
Serial.print("| IAQ: ");
Serial.print(iaq);
Serial.print(" (");
Serial.print(iaq_accuracy);
Serial.println(")");
}
/*!
* @brief Load previous library state from non-volatile memory
*
* @param[in,out] state_buffer buffer to hold the loaded state string
* @param[in] n_buffer size of the allocated state buffer
*
* @return number of bytes copied to state_buffer
*/
uint32_t state_load(uint8_t *state_buffer, uint32_t n_buffer)
{
// ...
// Load a previous library state from non-volatile memory, if available.
//
// Return zero if loading was unsuccessful or no state was available,
// otherwise return length of loaded state string.
// ...
return 0;
}
/*!
* @brief Save library state to non-volatile memory
*
* @param[in] state_buffer buffer holding the state to be stored
* @param[in] length length of the state string to be stored
*
* @return none
*/
void state_save(const uint8_t *state_buffer, uint32_t length)
{
// ...
// Save the string some form of non-volatile memory, if possible.
// ...
}
/*!
* @brief Load library config from non-volatile memory
*
* @param[in,out] config_buffer buffer to hold the loaded state string
* @param[in] n_buffer size of the allocated state buffer
*
* @return number of bytes copied to config_buffer
*/
uint32_t config_load(uint8_t *config_buffer, uint32_t n_buffer)
{
// ...
// Load a library config from non-volatile memory, if available.
//
// Return zero if loading was unsuccessful or no config was available,
// otherwise return length of loaded config string.
// ...
memcpy(config_buffer, bsec_config_iaq, sizeof(bsec_config_iaq));
return sizeof(bsec_config_iaq);
}
/*!
* @brief Interrupt handler for press of a ULP plus button
*
* @return none
*/
void ulp_plus_button_press()
{
/* We call bsec_update_subscription() in order to instruct BSEC to perform an extra measurement at the next
* possible time slot
*/
bsec_sensor_configuration_t requested_virtual_sensors[1];
uint8_t n_requested_virtual_sensors = 1;
bsec_sensor_configuration_t required_sensor_settings[BSEC_MAX_PHYSICAL_SENSOR];
uint8_t n_required_sensor_settings = BSEC_MAX_PHYSICAL_SENSOR;
bsec_library_return_t status = BSEC_OK;
/* To trigger a ULP plus, we request the IAQ virtual sensor with a specific sample rate code */
requested_virtual_sensors[0].sensor_id = BSEC_OUTPUT_IAQ_ESTIMATE;
requested_virtual_sensors[0].sample_rate = BSEC_SAMPLE_RATE_ULP_MEASUREMENT_ON_DEMAND;
/* Call bsec_update_subscription() to enable/disable the requested virtual sensors */
status = bsec_update_subscription(requested_virtual_sensors, n_requested_virtual_sensors, required_sensor_settings,
&n_required_sensor_settings);
/* The status code would tell is if the request was accepted. It will be rejected if the sensor is not already in
* ULP mode, or if the time difference between requests is too short, for example. */
if (status == BSEC_OK)
{
Serial.println("ULP plus triggered sucessfully.");
}
else
{
Serial.print("ULP plus request rejected. ");
switch (status)
{
case BSEC_W_SC_MODEXCEEDULPTIMELIMIT:
Serial.println("Request came within 20 s of a previous measurement.");
break;
case BSEC_W_SC_MODINSUFFICIENTWAITTIME:
Serial.println("Request came within 20 s of a ULP plus.");
break;
case BSEC_W_SU_MODINNOULP:
Serial.println("Sensor not in ULP mode.");
break;
}
}
}
/*!
* @brief Main function which configures BSEC library and then reads and processes the data from sensor based
* on timer ticks
*
* @return result of the processing
*/
void setup()
{
return_values_init ret;
/* Init I2C and serial communication */
Wire.begin();
Serial.begin(115200);
/* Setup button interrupt to trigger ULP plus */
pinMode(2, INPUT_PULLUP);
attachInterrupt(digitalPinToInterrupt(2), ulp_plus_button_press, FALLING);
/* Call to the function which initializes the BSEC library
* Switch on ultra_low-power mode and provide no temperature offset */
ret = bsec_iot_init(BSEC_SAMPLE_RATE_ULP, 5.0f, bus_write, bus_read, sleep, state_load, config_load);
if (ret.bme680_status)
{
/* Could not intialize BME680 */
Serial.println("Error while initializing BME680");
return;
}
else if (ret.bsec_status)
{
/* Could not intialize BSEC library */
Serial.println("Error while initializing BSEC library");
return;
}
/* Call to endless loop function which reads and processes data based on sensor settings */
/* State is saved every 10.000 samples, which means every 100 * 300 secs = 500 minutes */
bsec_iot_loop(sleep, get_timestamp_us, output_ready, state_save, 100);
}
void loop()
{
}
/*! @}*/

Binary file not shown.

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@ -0,0 +1,2 @@
text data bss dec hex filename
23795 0 1120 24915 6153 (TOTALS)

View File

@ -23,7 +23,7 @@ function Decoder(bytes, port) {
if (port === 3) {
// device config data
return decode(bytes, [uint8, uint8, uint16, uint8, uint8, uint8, uint8, bitmap, version], ['lorasf', 'txpower', 'rssilimit', 'sendcycle', 'wifichancycle', 'blescantime', 'rgblum', 'flags', 'version']);
return decode(bytes, [uint8, uint8, uint16, uint8, uint8, uint8, uint8, bitmap, bitmap, version], ['lorasf', 'txpower', 'rssilimit', 'sendcycle', 'wifichancycle', 'blescantime', 'rgblum', 'flags', 'payloadmask', 'version']);
}
if (port === 4) {
@ -157,7 +157,7 @@ var bitmap = function (byte) {
}
var i = bytesToInt(byte);
var bm = ('00000000' + Number(i).toString(2)).substr(-8).split('').map(Number).map(Boolean);
return ['adr', 'screensaver', 'screen', 'countermode', 'blescan', 'antenna', 'filter', 'gpsmode']
return ['adr', 'screensaver', 'screen', 'countermode', 'blescan', 'antenna', 'filter', 'alarm']
.reduce(function (obj, pos, index) {
obj[pos] = +bm[index];
return obj;

153
src/bme680mems.cpp Normal file
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@ -0,0 +1,153 @@
#ifdef HAS_BME
#include "bme680mems.h"
// Local logging tag
static const char TAG[] = "main";
bmeStatus_t bme_status;
TaskHandle_t BmeTask;
// initialize BME680 sensor
int bme_init(void) {
// struct bme680_dev gas_sensor;
Wire.begin(HAS_BME, 400000); // I2C connect to BME680 sensor with 400 KHz
// Call to the function which initializes the BSEC library
// Switch on low-power mode and provide no temperature offset
return_values_init ret =
bsec_iot_init(BSEC_SAMPLE_RATE_LP, 0.0f, i2c_write, i2c_read,
user_delay_ms, state_load, config_load);
if ((int)ret.bme680_status) {
ESP_LOGE(TAG, "Could not initialize BME680, error %d", (int)ret.bme680_status);
} else if ((int)ret.bsec_status) {
ESP_LOGE(TAG, "Could not initialize BSEC library, error %d", (int)ret.bsec_status);
} else {
ESP_LOGI(TAG, "BME680 sensor found and initialized");
return 1;
}
return 0;
}
void output_ready(int64_t timestamp, float iaq, uint8_t iaq_accuracy,
float temperature, float humidity, float pressure,
float raw_temperature, float raw_humidity, float gas,
bsec_library_return_t bsec_status, float static_iaq,
float co2_equivalent, float breath_voc_equivalent) {
bme_status.temperature = temperature;
bme_status.humidity = humidity;
bme_status.pressure = pressure;
bme_status.iaq = iaq;
}
// loop function which reads and processes data based on sensor settings
void bme_loop(void *pvParameters) {
configASSERT(((uint32_t)pvParameters) == 1); // FreeRTOS check
#ifdef HAS_BME
// State is saved every 10.000 samples, which means every 10.000 * 3 secs =
// 500 minutes
bsec_iot_loop(user_delay_ms, get_timestamp_us, output_ready, state_save,
10000);
#endif
vTaskDelete(BmeTask); // should never be reached
} // bme_loop()
int8_t i2c_read(uint8_t dev_id, uint8_t reg_addr, uint8_t *reg_data,
uint16_t len) {
int8_t rslt = 0; /* Return 0 for Success, non-zero for failure */
uint16_t i;
Wire.beginTransmission(dev_id);
Wire.write(reg_addr);
rslt = Wire.endTransmission();
Wire.requestFrom((int)dev_id, (int)len);
for (i = 0; (i < len) && Wire.available(); i++) {
reg_data[i] = Wire.read();
}
return rslt;
}
int8_t i2c_write(uint8_t dev_id, uint8_t reg_addr, uint8_t *reg_data,
uint16_t len) {
int8_t rslt = 0; /* Return 0 for Success, non-zero for failure */
uint16_t i;
Wire.beginTransmission(dev_id);
Wire.write(reg_addr);
for (i = 0; i < len; i++) {
Wire.write(reg_data[i]);
}
rslt = Wire.endTransmission();
return rslt;
}
/*!
* @brief Load previous library state from non-volatile memory
*
* @param[in,out] state_buffer buffer to hold the loaded state string
* @param[in] n_buffer size of the allocated state buffer
*
* @return number of bytes copied to state_buffer
*/
uint32_t state_load(uint8_t *state_buffer, uint32_t n_buffer) {
// ...
// Load a previous library state from non-volatile memory, if available.
//
// Return zero if loading was unsuccessful or no state was available,
// otherwise return length of loaded state string.
// ...
return 0;
}
/*!
* @brief Save library state to non-volatile memory
*
* @param[in] state_buffer buffer holding the state to be stored
* @param[in] length length of the state string to be stored
*
* @return none
*/
void state_save(const uint8_t *state_buffer, uint32_t length) {
// ...
// Save the string some form of non-volatile memory, if possible.
// ...
}
/*!
* @brief Load library config from non-volatile memory
*
* @param[in,out] config_buffer buffer to hold the loaded state string
* @param[in] n_buffer size of the allocated state buffer
*
* @return number of bytes copied to config_buffer
*/
uint32_t config_load(uint8_t *config_buffer, uint32_t n_buffer) {
// ...
// Load a library config from non-volatile memory, if available.
//
// Return zero if loading was unsuccessful or no config was available,
// otherwise return length of loaded config string.
// ...
return 0;
}
/*!
* @brief Interrupt handler for press of a ULP plus button
*
* @return none
*/
void user_delay_ms(uint32_t period) { vTaskDelay(period / portTICK_PERIOD_MS); }
int64_t get_timestamp_us() { return (int64_t)millis() * 1000; }
#endif // HAS_BME

View File

@ -1,44 +0,0 @@
#ifdef HAS_BME
#include "bme680read.h"
// Local logging tag
static const char TAG[] = "main";
#define SEALEVELPRESSURE_HPA (1013.25)
// I2C Bus interface
Adafruit_BME680 bme;
bmeStatus_t bme_status;
void bme_init(void) {
// initialize BME680 sensor using default i2c address 0x77
if (bme.begin(HAS_BME)) {
// Set up oversampling and filter initialization
bme.setTemperatureOversampling(BME680_OS_8X);
bme.setHumidityOversampling(BME680_OS_2X);
bme.setPressureOversampling(BME680_OS_4X);
bme.setIIRFilterSize(BME680_FILTER_SIZE_3);
bme.setGasHeater(320, 150); // 320*C for 150 ms
ESP_LOGI(TAG, "BME680 chip found and initialized");
} else
ESP_LOGE(TAG, "BME680 chip not found on i2c bus");
}
bool bme_read(void) {
bool ret = bme.performReading();
if (ret) {
// read current BME data and buffer in global struct
bme_status.temperature = bme.temperature;
bme_status.pressure = (uint16_t)(bme.pressure / 100.0); // convert Pa -> hPa
bme_status.humidity = bme.humidity;
bme_status.gas_resistance = (uint16_t)(bme.gas_resistance / 1000.0); // convert Ohm -> kOhm
ESP_LOGI(TAG, "BME680 sensor data read success");
} else {
ESP_LOGI(TAG, "BME680 sensor read error");
}
return ret;
}
#endif // HAS_BME

View File

@ -29,9 +29,9 @@ void defaultConfig() {
cfg.wifiant = 0; // 0=internal, 1=external (for LoPy/LoPy4)
cfg.vendorfilter = 1; // 0=disabled, 1=enabled
cfg.rgblum = RGBLUMINOSITY; // RGB Led luminosity (0..100%)
cfg.gpsmode = 1; // 0=disabled, 1=enabled
cfg.monitormode = 0; // 0=disabled, 1=enabled
cfg.runmode = 0; // 0=normal, 1=update
cfg.payloadmask = 0xFF; // all payload switched on
strncpy(cfg.version, PROGVERSION, sizeof(cfg.version) - 1);
}
@ -136,9 +136,9 @@ void saveConfig() {
flash8 != cfg.rgblum)
nvs_set_i8(my_handle, "rgblum", cfg.rgblum);
if (nvs_get_i8(my_handle, "gpsmode", &flash8) != ESP_OK ||
flash8 != cfg.gpsmode)
nvs_set_i8(my_handle, "gpsmode", cfg.gpsmode);
if (nvs_get_i8(my_handle, "payloadmask", &flash8) != ESP_OK ||
flash8 != cfg.payloadmask)
nvs_set_i8(my_handle, "payloadmask", cfg.payloadmask);
if (nvs_get_i8(my_handle, "monitormode", &flash8) != ESP_OK ||
flash8 != cfg.monitormode)
@ -315,11 +315,11 @@ void loadConfig() {
saveConfig();
}
if (nvs_get_i8(my_handle, "gpsmode", &flash8) == ESP_OK) {
cfg.gpsmode = flash8;
ESP_LOGI(TAG, "GPS mode = %d", flash8);
if (nvs_get_i8(my_handle, "payloadmask", &flash8) == ESP_OK) {
cfg.payloadmask = flash8;
ESP_LOGI(TAG, "payloadmask = %u", flash8);
} else {
ESP_LOGI(TAG, "GPS mode set to default %d", cfg.gpsmode);
ESP_LOGI(TAG, "payloadmask set to default %u", cfg.payloadmask);
saveConfig();
}

View File

@ -32,11 +32,6 @@ void doHousekeeping() {
}
#endif
#ifdef HAS_BME
// read BME280 sensor if present
bme_read();
#endif
// task storage debugging //
ESP_LOGD(TAG, "Wifiloop %d bytes left",
uxTaskGetStackHighWaterMark(wifiSwitchTask));
@ -45,6 +40,9 @@ void doHousekeeping() {
#ifdef HAS_GPS
ESP_LOGD(TAG, "Gpsloop %d bytes left", uxTaskGetStackHighWaterMark(GpsTask));
#endif
#ifdef HAS_BME
ESP_LOGD(TAG, "Bmeloop %d bytes left", uxTaskGetStackHighWaterMark(BmeTask));
#endif
#if (HAS_LED != NOT_A_PIN) || defined(HAS_RGB_LED)
ESP_LOGD(TAG, "LEDloop %d bytes left",

View File

@ -9,27 +9,19 @@ TinyGPSPlus gps;
gpsStatus_t gps_status;
TaskHandle_t GpsTask;
// read GPS data and cast to global struct
void gps_read() {
gps_status.latitude = (int32_t)(gps.location.lat() * 1e6);
gps_status.longitude = (int32_t)(gps.location.lng() * 1e6);
gps_status.satellites = (uint8_t)gps.satellites.value();
gps_status.hdop = (uint16_t)gps.hdop.value();
gps_status.altitude = (int16_t)gps.altitude.meters();
}
#ifdef GPS_SERIAL
HardwareSerial GPS_Serial(1);
#endif
// GPS serial feed FreeRTos Task
void gps_loop(void *pvParameters) {
// initialize and configure GPS
int gps_init(void) {
configASSERT(((uint32_t)pvParameters) == 1); // FreeRTOS check
int ret = 1;
// initialize and, if needed, configure, GPS
#if defined GPS_SERIAL
HardwareSerial GPS_Serial(1);
GPS_Serial.begin(GPS_SERIAL);
ESP_LOGI(TAG, "Using serial GPS");
#elif defined GPS_I2C
uint8_t ret;
Wire.begin(GPS_I2C, 400000); // I2C connect to GPS device with 400 KHz
Wire.beginTransmission(GPS_ADDR);
Wire.write(0x00); // dummy write
@ -40,16 +32,35 @@ void gps_loop(void *pvParameters) {
"Quectel L76 GPS chip not found on i2c bus, bus error %d. "
"Stopping GPS-Task.",
ret);
vTaskDelete(GpsTask);
ret = 0;
} else {
ESP_LOGI(TAG, "Quectel L76 GPS chip found.");
ESP_LOGI(TAG, "Quectel L76 GPS chip found");
}
#endif
return ret;
} // gps_init()
// read GPS data and cast to global struct
void gps_read() {
gps_status.latitude = (int32_t)(gps.location.lat() * 1e6);
gps_status.longitude = (int32_t)(gps.location.lng() * 1e6);
gps_status.satellites = (uint8_t)gps.satellites.value();
gps_status.hdop = (uint16_t)gps.hdop.value();
gps_status.altitude = (int16_t)gps.altitude.meters();
// show NMEA data in debug mode, useful for debugging GPS
ESP_LOGD(TAG, "GPS NMEA data: passed %d / failed: %d / with fix: %d",
gps.passedChecksum(), gps.failedChecksum(), gps.sentencesWithFix());
}
// GPS serial feed FreeRTos Task
void gps_loop(void *pvParameters) {
configASSERT(((uint32_t)pvParameters) == 1); // FreeRTOS check
while (1) {
if (cfg.gpsmode) {
if (cfg.payloadmask && GPS_DATA) {
#if defined GPS_SERIAL
// feed GPS decoder with serial NMEA data from GPS device
while (GPS_Serial.available()) {
@ -62,13 +73,13 @@ void gps_loop(void *pvParameters) {
vTaskDelay(2 / portTICK_PERIOD_MS); // 2ms delay according L76 datasheet
}
#endif
} // if (cfg.gpsmode)
} // if
vTaskDelay(2 / portTICK_PERIOD_MS); // yield to CPU
} // end of infinite loop
vTaskDelete(NULL); // shoud never be reached
vTaskDelete(GpsTask); // shoud never be reached
} // gps_loop()

View File

@ -1,3 +1,5 @@
// clang-format off
#ifndef _EBOX_H
#define _EBOX_H
@ -18,7 +20,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
#define LORA_IRQ (26)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN

View File

@ -1,3 +1,5 @@
// clang-format off
#ifndef _EBOXTUBE_H
#define _EBOXTUBE_H
@ -19,7 +21,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
#define LORA_IRQ (26)
#define LORA_IO1 (33)
#define LORA_IO2 (32)

View File

@ -1,3 +1,5 @@
// clang-format off
#ifndef _FIPY_H
#define _FIPY_H
@ -18,7 +20,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST LMIC_UNUSED_PIN
#define LORA_IO0 (23) // LoRa IRQ
#define LORA_IRQ (23) // LoRa IRQ
#define LORA_IO1 (23) // Pin tied via diode to DIO0
#define LORA_IO2 LMIC_UNUSED_PIN

View File

@ -1,3 +1,5 @@
// clang-format off
#ifndef _GENERIC_H
#define _GENERIC_H
@ -13,7 +15,13 @@
#define SPI_SCLK GPIO_NUM_18
#define SPI_CS GPIO_NUM_5
#define HAS_BME 0x77 // BME680 sensor on I2C bus (SDA=4/SCL=15); comment out if not present
// enable only if device has these sensors, otherwise comment these lines
// BME680 sensor on I2C bus
// don't forget to connect SDIO of BME680 to GND for selecting i2c addr 0x76
#define HAS_BME GPIO_NUM_21, GPIO_NUM_22 // SDA, SCL
// user defined sensors
//#define HAS_SENSORS 1 // comment out if device has user defined sensors
#define CFG_sx1276_radio 1 // select LoRa chip
//#define CFG_sx1272_radio 1 // select LoRa chip
@ -45,7 +53,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
#define LORA_IRQ (26)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN

View File

@ -1,30 +1,28 @@
// clang-format off
#ifndef _HELTEC_H
#define _HELTEC_H
#include <stdint.h>
//#define HAS_BME 0x77 // BME680 sensor on I2C bus (SDI=21/SCL=22); comment out if not present
//#define HAS_BME 0x77 // BME680 sensor on I2C bus (SDI=21/SCL=22); comment out
//if not present
// Hardware related definitions for Heltec LoRa-32 Board
#define HAS_LORA 1 // comment out if device shall not send data via LoRa
#define HAS_LORA 1 // comment out if device shall not send data via LoRa
#define CFG_sx1276_radio 1
#define HAS_DISPLAY U8X8_SSD1306_128X64_NONAME_HW_I2C // OLED-Display on board
#define HAS_LED (25) // white LED on board
#define HAS_BUTTON (0) // button "PROG" on board
#define HAS_LED (25) // white LED on board
#define HAS_BUTTON (0) // button "PROG" on board
// Pins for I2C interface of OLED Display
#define MY_OLED_SDA (4)
#define MY_OLED_SCL (15)
#define MY_OLED_RST (16)
// Pins for LORA chip SPI interface, reset line and interrupt lines
#define LORA_SCK (5)
#define LORA_CS (18)
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN
// Pins for LORA chip SPI interface come from board file, we need some
// additional definitions for LMIC
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN
#endif

View File

@ -1,3 +1,5 @@
// clang-format off
#ifndef _HELTECV2_H
#define _HELTECV2_H
@ -5,6 +7,9 @@
// Hardware related definitions for Heltec V2 LoRa-32 Board
//#define HAS_BME 0x77 // BME680 sensor on I2C bus (SDI=21/SCL=22); comment out
//if not present
#define HAS_LORA 1 // comment out if device shall not send data via LoRa
#define CFG_sx1276_radio 1
@ -17,13 +22,8 @@
#define OLED_SCL (15)
#define OLED_RST (16)
// Pins for LORA chip SPI interface, reset line and interrupt lines
#define LORA_SCK (5)
#define LORA_CS (18)
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
// Pins for LORA chip SPI interface come from board file, we need some
// additional definitions for LMIC
#define LORA_IO1 (35)
#define LORA_IO2 (34)

View File

@ -1,3 +1,5 @@
// clang-format off
#ifndef _LOLINLITE_H
#define _LOLINLITE_H

View File

@ -1,3 +1,5 @@
// clang-format off
#ifndef _LOLINLITELORA_H
#define _LOLINLITELORA_H
@ -26,7 +28,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST (25)
#define LORA_IO0 (27)
#define LORA_IRQ (27)
#define LORA_IO1 (26)
#define LORA_IO2 LMIC_UNUSED_PIN

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@ -1,3 +1,5 @@
// clang-format off
#ifndef _LOLINLORA_H
#define _LOLINLORA_H
@ -27,7 +29,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST (25)
#define LORA_IO0 (27)
#define LORA_IRQ (27)
#define LORA_IO1 (26)
#define LORA_IO2 LMIC_UNUSED_PIN
#define LORA_IO5 LMIC_UNUSED_PIN

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@ -1,3 +1,5 @@
// clang-format off
#ifndef _LOPY_H
#define _LOPY_H
@ -10,13 +12,8 @@
#define HAS_LED NOT_A_PIN // LoPy4 has no on board mono LED, we use on board RGB LED
#define HAS_RGB_LED (0) // WS2812B RGB LED on GPIO0
// Pins for LORA chip SPI interface, reset line and interrupt lines
#define LORA_SCK (5) // GPIO5 - SX1276 SCK
#define LORA_CS (17) // GPIO17 - SX1276 CS
#define LORA_MISO (19) // GPIO19 - SX1276 MISO
#define LORA_MOSI (27) // GPIO27 - SX1276 MOSI
#define LORA_RST (18) // GPIO18 - SX1276 RESET
#define LORA_IO0 (23) // LoRa IRQ
// Pins for LORA chip SPI interface come from board file, we need some
// additional definitions for LMIC
#define LORA_IO1 (23) // Pin tied via diode to DIO0
#define LORA_IO2 (23) // Pin tied via diode to DIO0

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@ -1,3 +1,5 @@
// clang-format off
#ifndef _LOPY4_H
#define _LOPY4_H
@ -19,13 +21,8 @@
#define HAS_RGB_LED (0) // WS2812B RGB LED on GPIO0 (P2)
#define BOARD_HAS_PSRAM // use extra 4MB extern RAM
// Pins for LORA chip SPI interface, reset line and interrupt lines
#define LORA_SCK (5)
#define LORA_CS (18)
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST LMIC_UNUSED_PIN
#define LORA_IO0 (23) // LoRa IRQ
// Pins for LORA chip SPI interface come from board file, we need some
// additional definitions for LMIC
#define LORA_IO1 (23) // Pin tied via diode to DIO0
#define LORA_IO2 (23) // Pin tied via diode to DIO0

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@ -1,3 +1,5 @@
// clang-format off
#ifndef _OCTOPUS_H
#define _OCTOPUS_H
@ -10,7 +12,13 @@
// disable brownout detection (avoid unexpected reset on some boards)
#define DISABLE_BROWNOUT 1 // comment out if you want to keep brownout feature
#define HAS_BME 0x76 // BME680 sensor on I2C bus; comment out if not present
// enable only if device has these sensors, otherwise comment these lines
// BME680 sensor on I2C bus
// don't forget to connect SDIO of BME680 to GND for selecting i2c addr 0x76
#define HAS_BME GPIO_NUM_21, GPIO_NUM_22 // SDA, SCL
// user defined sensors
//#define HAS_SENSORS 1 // comment out if device has user defined sensors
#define HAS_LED 13 // ESP32 GPIO12 (pin22) On Board LED
#define LED_ACTIVE_LOW 1 // Onboard LED is active when pin is LOW
@ -27,7 +35,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (18)
#define LORA_RST LMIC_UNUSED_PIN
#define LORA_IO0 (33)
#define LORA_IRQ (33)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN

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@ -1,3 +1,5 @@
// clang-format off
#ifndef _TTGOBEAM_H
#define _TTGOBEAM_H
@ -5,11 +7,21 @@
// Hardware related definitions for TTGO T-Beam board
// enable only if device has these sensors, otherwise comment these lines
// BME680 sensor on I2C bus
// attention: Pin21 is also LED! set HAS_LED to NOT_A_PIN if using BME280
// don't forget to connect SDIO of BME680 to GND for selecting i2c addr 0x76
#define HAS_BME GPIO_NUM_21, GPIO_NUM_22 // SDA, SCL
#define HAS_LED NOT_A_PIN // on board green LED
// user defined sensors
//#define HAS_SENSORS 1 // comment out if device has user defined sensors
#define HAS_LORA 1 // comment out if device shall not send data via LoRa
#define CFG_sx1276_radio 1 // HPD13A LoRa SoC
#define BOARD_HAS_PSRAM // use extra 4MB external RAM
#define HAS_LED GPIO_NUM_21 // on board green LED
//#define HAS_LED GPIO_NUM_21 // on board green LED
#define HAS_BUTTON GPIO_NUM_39 // on board button "BOOT" (next to reset button)
@ -24,7 +36,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST LMIC_UNUSED_PIN
#define LORA_IO0 (26)
#define LORA_IRQ (26)
#define LORA_IO1 (32) // !! NEEDS EXTERNAL WIRING !!
//#define LORA_IO1 (33) // for T-Beam T22_V05 and T22_V07, other versions may need external wiring
#define LORA_IO2 LMIC_UNUSED_PIN

View File

@ -1,3 +1,5 @@
// clang-format off
#ifndef _TTGOV1_H
#define _TTGOV1_H
@ -25,7 +27,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST (14)
#define LORA_IO0 (26)
#define LORA_IRQ (26)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN

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@ -1,3 +1,5 @@
// clang-format off
#ifndef _TTGOV2_H
#define _TTGOV2_H
@ -26,7 +28,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST LMIC_UNUSED_PIN
#define LORA_IO0 (26)
#define LORA_IRQ (26)
#define LORA_IO1 (33)
#define LORA_IO2 LMIC_UNUSED_PIN

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@ -1,3 +1,5 @@
// clang-format off
#ifndef _TTGOV21NEW_H
#define _TTGOV21NEW_H
@ -8,8 +10,6 @@
// This settings are for boards labeled v1.6 on pcb, NOT for v1.5 or older
*/
#define HAS_BME 0x77 // BME680 sensor on I2C bus (SDI=21/SCL=22); comment out if not present
#define HAS_LORA 1 // comment out if device shall not send data via LoRa
#define CFG_sx1276_radio 1 // HPD13A LoRa SoC
@ -29,7 +29,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST (23)
#define LORA_IO0 (26)
#define LORA_IRQ (26)
#define LORA_IO1 (33)
#define LORA_IO2 (32)

View File

@ -1,3 +1,5 @@
// clang-format off
#ifndef _TTGOV21OLD_H
#define _TTGOV21OLD_H
@ -30,7 +32,7 @@
#define LORA_MISO (19)
#define LORA_MOSI (27)
#define LORA_RST LMIC_UNUSED_PIN
#define LORA_IO0 (26)
#define LORA_IRQ (26)
#define LORA_IO1 (33)
#define LORA_IO2 (32)

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@ -107,15 +107,17 @@ void switch_LED(uint8_t state) {
#endif
}
#if (HAS_LED != NOT_A_PIN) || defined(HAS_RGB_LED)
void blink_LED(uint16_t set_color, uint16_t set_blinkduration) {
#if (HAS_LED != NOT_A_PIN) || defined(HAS_RGB_LED)
LEDColor = set_color; // set color for RGB LED
LEDBlinkDuration = set_blinkduration; // duration
LEDBlinkStarted = millis(); // Time Start here
LEDState = LED_ON; // Let main set LED on
#endif
}
#if (HAS_LED != NOT_A_PIN) || defined(HAS_RGB_LED)
void ledLoop(void *parameter) {
while (1) {
// Custom blink running always have priority other LoRaWAN led
@ -189,8 +191,8 @@ void ledLoop(void *parameter) {
}
// give yield to CPU
vTaskDelay(2 / portTICK_PERIOD_MS);
} // while(1)
vTaskDelete(NULL); // shoud never be reached
}; // ledloop()
} // while(1)
vTaskDelete(ledLoopTask); // shoud never be reached
}; // ledloop()
#endif // #if (HAS_LED != NOT_A_PIN) || defined(HAS_RGB_LED)

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@ -14,7 +14,7 @@ const lmic_pinmap lmic_pins = {
.nss = LORA_CS,
.rxtx = LMIC_UNUSED_PIN,
.rst = LORA_RST,
.dio = {LORA_IO0, LORA_IO1, LORA_IO2},
.dio = {LORA_IRQ, LORA_IO1, LORA_IO2},
.mosi = LORA_MOSI,
.miso = LORA_MISO,
.sck = LORA_SCK

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@ -34,7 +34,8 @@ IDLE 0 0 ESP32 arduino scheduler -> runs wifi sniffer
looptask 1 1 arduino core -> runs the LMIC LoRa stack
irqhandler 1 1 executes tasks triggered by irq
gpsloop 1 2 reads data from GPS over serial or i2c
gpsloop 1 2 reads data from GPS via serial or i2c
bmeloop 1 2 reads data from BME sensor via i2c
IDLE 1 0 ESP32 arduino scheduler
ESP32 hardware timers
@ -90,6 +91,29 @@ void setup() {
esp_log_set_vprintf(redirect_log);
#endif
ESP_LOGI(TAG, "Starting %s v%s", PRODUCTNAME, PROGVERSION);
// print chip information on startup if in verbose mode
#ifdef VERBOSE
esp_chip_info_t chip_info;
esp_chip_info(&chip_info);
ESP_LOGI(TAG,
"This is ESP32 chip with %d CPU cores, WiFi%s%s, silicon revision "
"%d, %dMB %s Flash",
chip_info.cores, (chip_info.features & CHIP_FEATURE_BT) ? "/BT" : "",
(chip_info.features & CHIP_FEATURE_BLE) ? "/BLE" : "",
chip_info.revision, spi_flash_get_chip_size() / (1024 * 1024),
(chip_info.features & CHIP_FEATURE_EMB_FLASH) ? "embedded"
: "external");
ESP_LOGI(TAG, "ESP32 SDK: %s", ESP.getSdkVersion());
ESP_LOGI(TAG, "Free RAM: %d bytes", ESP.getFreeHeap());
#ifdef HAS_GPS
ESP_LOGI(TAG, "TinyGPS+ v%s", TinyGPSPlus::libraryVersion());
#endif
#endif // verbose
// read (and initialize on first run) runtime settings from NVRAM
loadConfig(); // includes initialize if necessary
@ -100,12 +124,21 @@ void setup() {
// switch on power LED if we have 2 LEDs, else use it for status
#ifdef HAS_RGB_LED
switch_LED(LED_ON);
strcat_P(features, " RGB");
rgb_set_color(COLOR_PINK);
#endif
#endif
#ifdef HAS_RGB_LED
rgb_set_color(COLOR_PINK);
strcat_P(features, " RGB");
#if (HAS_LED != NOT_A_PIN) || defined(HAS_RGB_LED)
// start led loop
ESP_LOGI(TAG, "Starting LEDloop...");
xTaskCreatePinnedToCore(ledLoop, // task function
"ledloop", // name of task
1024, // stack size of task
(void *)1, // parameter of the task
3, // priority of the task
&ledLoopTask, // task handle
0); // CPU core
#endif
// initialize wifi antenna
@ -156,12 +189,37 @@ void setup() {
// initialize gps
#ifdef HAS_GPS
strcat_P(features, " GPS");
if (gps_init()) {
ESP_LOGI(TAG, "Starting GPSloop...");
xTaskCreatePinnedToCore(gps_loop, // task function
"gpsloop", // name of task
2048, // stack size of task
(void *)1, // parameter of the task
2, // priority of the task
&GpsTask, // task handle
1); // CPU core
}
#endif
// initialize gps
// initialize bme
#ifdef HAS_BME
strcat_P(features, " BME");
bme_init();
if (bme_init()) {
ESP_LOGI(TAG, "Starting BMEloop...");
xTaskCreatePinnedToCore(bme_loop, // task function
"bmeloop", // name of task
4096, // stack size of task
(void *)1, // parameter of the task
2, // priority of the task
&BmeTask, // task handle
1); // CPU core
}
#endif
// initialize sensors
#ifdef HAS_SENSORS
strcat_P(features, " SENS");
sensor_init();
#endif
// initialize LoRa
@ -180,29 +238,6 @@ void setup() {
strcat_P(features, " OUIFLT");
#endif
ESP_LOGI(TAG, "Starting %s v%s", PRODUCTNAME, PROGVERSION);
// print chip information on startup if in verbose mode
#ifdef VERBOSE
esp_chip_info_t chip_info;
esp_chip_info(&chip_info);
ESP_LOGI(TAG,
"This is ESP32 chip with %d CPU cores, WiFi%s%s, silicon revision "
"%d, %dMB %s Flash",
chip_info.cores, (chip_info.features & CHIP_FEATURE_BT) ? "/BT" : "",
(chip_info.features & CHIP_FEATURE_BLE) ? "/BLE" : "",
chip_info.revision, spi_flash_get_chip_size() / (1024 * 1024),
(chip_info.features & CHIP_FEATURE_EMB_FLASH) ? "embedded"
: "external");
ESP_LOGI(TAG, "ESP32 SDK: %s", ESP.getSdkVersion());
ESP_LOGI(TAG, "Free RAM: %d bytes", ESP.getFreeHeap());
#ifdef HAS_GPS
ESP_LOGI(TAG, "TinyGPS+ v%s", TinyGPSPlus::libraryVersion());
#endif
#endif // verbose
// initialize display
#ifdef HAS_DISPLAY
strcat_P(features, " OLED");
@ -271,17 +306,6 @@ void setup() {
// function gets it's seed from RF noise
get_salt(); // get new 16bit for salting hashes
#ifdef HAS_GPS
ESP_LOGI(TAG, "Starting GPSloop...");
xTaskCreatePinnedToCore(gps_loop, // task function
"gpsloop", // name of task
2048, // stack size of task
(void *)1, // parameter of the task
2, // priority of the task
&GpsTask, // task handle
1); // CPU core
#endif
// start state machine
ESP_LOGI(TAG, "Starting IRQ Handler...");
xTaskCreatePinnedToCore(irqHandler, // task function
@ -292,18 +316,6 @@ void setup() {
&irqHandlerTask, // task handle
1); // CPU core
#if (HAS_LED != NOT_A_PIN) || defined(HAS_RGB_LED)
// start led loop
ESP_LOGI(TAG, "Starting LEDloop...");
xTaskCreatePinnedToCore(ledLoop, // task function
"ledloop", // name of task
1024, // stack size of task
(void *)1, // parameter of the task
3, // priority of the task
&ledLoopTask, // task handle
0); // CPU core
#endif
// start wifi channel rotation task
ESP_LOGI(TAG, "Starting Wifi Channel rotation...");
xTaskCreatePinnedToCore(switchWifiChannel, // task function

View File

@ -118,6 +118,10 @@ int do_ota_update() {
// Fetch the latest firmware version
ESP_LOGI(TAG, "Checking latest firmware version on server");
display(2, "**", "checking version");
if (WiFi.status() != WL_CONNECTED)
return 1;
const String latest = bintray.getLatestVersion();
if (latest.length() == 0) {
@ -133,6 +137,8 @@ int do_ota_update() {
display(2, "OK", latest.c_str());
display(3, "**", "");
if (WiFi.status() != WL_CONNECTED)
return 1;
String firmwarePath = bintray.getBinaryPath(latest);
if (!firmwarePath.endsWith(".bin")) {
ESP_LOGI(TAG, "Unsupported binary format");
@ -146,9 +152,7 @@ int do_ota_update() {
WiFiClientSecure client;
client.setCACert(bintray.getCertificate(currentHost));
// client.setTimeout(RESPONSE_TIMEOUT_MS);
// --> causing error [E][WiFiClient.cpp:236] setSocketOption(): 1006 : 9
// so we unfortunately need patched update.cpp which sets the stream timeout
client.setTimeout(RESPONSE_TIMEOUT_MS);
if (!client.connect(currentHost.c_str(), port)) {
ESP_LOGI(TAG, "Cannot connect to %s", currentHost.c_str());

View File

@ -11,7 +11,7 @@
// Payload send cycle and encoding
#define SEND_SECS 30 // payload send cycle [seconds/2] -> 60 sec.
#define PAYLOAD_ENCODER 2 // payload encoder: 1=Plain, 2=Packed, 3=CayenneLPP dynamic, 4=CayenneLPP packed
#define PAYLOAD_ENCODER 3 // payload encoder: 1=Plain, 2=Packed, 3=CayenneLPP dynamic, 4=CayenneLPP packed
// Set this to include BLE counting and vendor filter functions
#define VENDORFILTER 1 // comment out if you want to count things, not people
@ -60,6 +60,10 @@
#define LPP2PORT 2 // Port for Cayenne LPP 2.0 packed sensor encoding
#define BEACONPORT 6 // Port on which device sends beacon alarms
#define BMEPORT 7 // Port on which device sends BME680 sensor data
#define SENSOR1PORT 10 // Port on which device sends User sensor #1 data
#define SENSOR2PORT 11 // Port on which device sends User sensor #2 data
#define SENSOR3PORT 12 // Port on which device sends User sensor #3 data
#define SENSOR4PORT 13 // Port on which device sends User sensor #4 data
// Some hardware settings
#define RGBLUMINOSITY 30 // RGB LED luminosity [default = 30%]

View File

@ -1,4 +1,3 @@
#include "globals.h"
#include "payload.h"
@ -47,7 +46,7 @@ void PayloadConvert::addConfig(configData_t value) {
buffer[cursor++] = value.wifiant;
buffer[cursor++] = value.vendorfilter;
buffer[cursor++] = value.rgblum;
buffer[cursor++] = value.gpsmode;
buffer[cursor++] = value.payloadmask;
buffer[cursor++] = value.monitormode;
memcpy(buffer + cursor, value.version, 10);
cursor += 10;
@ -93,18 +92,27 @@ void PayloadConvert::addGPS(gpsStatus_t value) {
#endif
}
void PayloadConvert::addSensor(uint8_t buf[]) {
#ifdef HAS_SENSORS
uint8_t length = buf[0];
memcpy(buffer, buf + 1, length);
cursor += length; // length of buffer
#endif
}
void PayloadConvert::addBME(bmeStatus_t value) {
#ifdef HAS_BME
int16_t temperature = (int16_t)(value.temperature); // float -> int
uint16_t humidity = (uint16_t)(value.humidity); // float -> int
uint16_t iaq = (uint16_t)(value.iaq); // float -> int
buffer[cursor++] = highByte(temperature);
buffer[cursor++] = lowByte(temperature);
buffer[cursor++] = highByte(value.pressure);
buffer[cursor++] = lowByte(value.pressure);
buffer[cursor++] = highByte(humidity);
buffer[cursor++] = lowByte(humidity);
buffer[cursor++] = highByte(value.gas_resistance);
buffer[cursor++] = lowByte(value.gas_resistance);
buffer[cursor++] = highByte(value.iaq);
buffer[cursor++] = lowByte(value.iaq);
#endif
}
@ -142,7 +150,16 @@ void PayloadConvert::addConfig(configData_t value) {
writeBitmap(value.adrmode ? true : false, value.screensaver ? true : false,
value.screenon ? true : false, value.countermode ? true : false,
value.blescan ? true : false, value.wifiant ? true : false,
value.vendorfilter ? true : false, value.gpsmode ? true : false);
value.vendorfilter ? true : false,
value.monitormode ? true : false);
writeBitmap(value.payloadmask && GPS_DATA ? true : false,
value.payloadmask && ALARM_DATA ? true : false,
value.payloadmask && MEMS_DATA ? true : false,
value.payloadmask && COUNT_DATA ? true : false,
value.payloadmask && SENSOR1_DATA ? true : false,
value.payloadmask && SENSOR2_DATA ? true : false,
value.payloadmask && SENSOR3_DATA ? true : false,
value.payloadmask && SENSOR4_DATA ? true : false);
writeVersion(value.version);
}
@ -165,12 +182,20 @@ void PayloadConvert::addGPS(gpsStatus_t value) {
#endif
}
void PayloadConvert::addSensor(uint8_t buf[]) {
#ifdef HAS_SENSORS
uint8_t length = buf[0];
memcpy(buffer, buf + 1, length);
cursor += length; // length of buffer
#endif
}
void PayloadConvert::addBME(bmeStatus_t value) {
#ifdef HAS_BME
writeTemperature(value.temperature);
writeUint16(value.pressure);
writeHumidity(value.humidity);
writeUint16(value.gas_resistance);
writeUint16(value.iaq);
#endif
}
@ -328,6 +353,17 @@ void PayloadConvert::addGPS(gpsStatus_t value) {
#endif // HAS_GPS
}
void PayloadConvert::addSensor(uint8_t buf[]) {
#ifdef HAS_SENSORS
// to come
/*
uint8_t length = buf[0];
memcpy(buffer, buf+1, length);
cursor += length; // length of buffer
*/
#endif
}
void PayloadConvert::addBME(bmeStatus_t value) {
#ifdef HAS_BME
@ -338,8 +374,8 @@ void PayloadConvert::addBME(bmeStatus_t value) {
uint16_t pressure = value.pressure * 10;
// 0.5% per bit => 0 .. 128 %C
uint8_t humidity = (uint8_t)(value.humidity * 2.0);
// 0.01 Ohm per bit => 0 .. 655,36 Ohm
uint16_t gas = value.gas_resistance * 100;
// 0.01 IAQ per bit => 0 .. 655,36 IAQ
uint16_t iaq = (uint16_t) value.iaq * 100;
#if (PAYLOAD_ENCODER == 3)
buffer[cursor++] = LPP_TEMPERATURE_CHANNEL;
@ -362,8 +398,8 @@ void PayloadConvert::addBME(bmeStatus_t value) {
buffer[cursor++] = LPP_GAS_CHANNEL;
#endif
buffer[cursor++] = LPP_ANALOG_INPUT; // 2 bytes 0.01 Signed
buffer[cursor++] = highByte(gas);
buffer[cursor++] = lowByte(gas);
buffer[cursor++] = highByte(iaq);
buffer[cursor++] = lowByte(iaq);
#endif // HAS_BME
}

View File

@ -8,8 +8,6 @@ static const char TAG[] = "main";
// helper function
void do_reset() {
ESP_LOGI(TAG, "Remote command: restart device");
if (irqHandlerTask != NULL)
vTaskDelete(irqHandlerTask);
LMIC_shutdown();
vTaskDelay(3000 / portTICK_PERIOD_MS);
esp_restart();
@ -127,7 +125,36 @@ void set_display(uint8_t val[]) {
void set_gps(uint8_t val[]) {
ESP_LOGI(TAG, "Remote command: set GPS mode to %s", val[0] ? "on" : "off");
cfg.gpsmode = val[0] ? 1 : 0;
if (val[0]) {
cfg.payloadmask |= (uint8_t)GPS_DATA; // set bit in mask
} else {
cfg.payloadmask &= ~(uint8_t)GPS_DATA; // clear bit in mask
}
}
void set_sensor(uint8_t val[]) {
#ifdef HAS_SENSORS
switch (val[0]) { // check if valid sensor number 1...4
case 1:
case 2:
case 3:
case 4:
break; // valid sensor number -> continue
default:
ESP_LOGW(
TAG,
"Remote command set sensor mode called with invalid sensor number");
return; // invalid sensor number -> exit
}
ESP_LOGI(TAG, "Remote command: set sensor #%d mode to %s", val[0],
val[1] ? "on" : "off");
if (val[1])
cfg.payloadmask |= sensor_mask(val[0]); // set bit
else
cfg.payloadmask &= ~sensor_mask(val[0]); // clear bit
#endif
}
void set_beacon(uint8_t val[]) {
@ -265,8 +292,9 @@ cmd_t table[] = {
{0x0d, set_vendorfilter, 1, false}, {0x0e, set_blescan, 1, true},
{0x0f, set_wifiant, 1, true}, {0x10, set_rgblum, 1, true},
{0x11, set_monitor, 1, true}, {0x12, set_beacon, 7, false},
{0x80, get_config, 0, false}, {0x81, get_status, 0, false},
{0x84, get_gps, 0, false}, {0x85, get_bme, 0, false},
{0x13, set_sensor, 2, true}, {0x80, get_config, 0, false},
{0x81, get_status, 0, false}, {0x84, get_gps, 0, false},
{0x85, get_bme, 0, false},
};
const uint8_t cmdtablesize =

View File

@ -21,44 +21,78 @@ void SendPayload(uint8_t port) {
// interrupt triggered function to prepare payload to send
void sendCounter() {
// append counter data to payload
payload.reset();
payload.addCount(macs_wifi, cfg.blescan ? macs_ble : 0);
// append GPS data, if present
uint8_t bitmask = cfg.payloadmask;
uint8_t mask = 1;
// clear counter if not in cumulative counter mode
if (cfg.countermode != 1) {
reset_counters(); // clear macs container and reset all counters
get_salt(); // get new salt for salting hashes
ESP_LOGI(TAG, "Counter cleared");
}
while (bitmask) {
switch (bitmask & mask) {
case COUNT_DATA:
payload.reset();
payload.addCount(macs_wifi, cfg.blescan ? macs_ble : 0);
SendPayload(COUNTERPORT);
// clear counter if not in cumulative counter mode
if (cfg.countermode != 1) {
reset_counters(); // clear macs container and reset all counters
get_salt(); // get new salt for salting hashes
ESP_LOGI(TAG, "Counter cleared");
}
break;
#ifdef HAS_BME
case MEMS_DATA:
payload.reset();
payload.addBME(bme_status);
SendPayload(BMEPORT);
break;
#endif
#ifdef HAS_GPS
// show NMEA data in debug mode, useful for debugging GPS on board
// connection
ESP_LOGD(TAG, "GPS NMEA data: passed %d / failed: %d / with fix: %d",
gps.passedChecksum(), gps.failedChecksum(), gps.sentencesWithFix());
// log GPS position if we have a fix and gps data mode is enabled
if ((cfg.gpsmode) && (gps.location.isValid())) {
gps_read();
payload.addGPS(gps_status);
ESP_LOGD(TAG, "lat=%.6f | lon=%.6f | %u Sats | HDOP=%.1f | Altitude=%um",
gps_status.latitude / (float)1e6,
gps_status.longitude / (float)1e6, gps_status.satellites,
gps_status.hdop / (float)100, gps_status.altitude);
} else {
ESP_LOGD(TAG, "No valid GPS position or GPS data mode disabled");
}
case GPS_DATA:
// send GPS position only if we have a fix
if (gps.location.isValid()) {
gps_read();
payload.reset();
payload.addGPS(gps_status);
SendPayload(GPSPORT);
} else
ESP_LOGD(TAG, "No valid GPS position");
break;
#endif
SendPayload(COUNTERPORT);
// if we have MEMS sensor, send sensor data in separate frame
#ifdef HAS_BME
payload.reset();
payload.addBME(bme_status);
SendPayload(BMEPORT);
#ifdef HAS_SENSORS
case SENSOR1_DATA:
payload.reset();
payload.addSensor(sensor_read(1));
SendPayload(SENSOR1PORT);
break;
case SENSOR2_DATA:
payload.reset();
payload.addSensor(sensor_read(2));
SendPayload(SENSOR2PORT);
break;
case SENSOR3_DATA:
payload.reset();
payload.addSensor(sensor_read(3));
SendPayload(SENSOR3PORT);
break;
case SENSOR4_DATA:
payload.reset();
payload.addSensor(sensor_read(4));
SendPayload(SENSOR4PORT);
break;
#endif
} // switch
bitmask &= ~mask;
mask <<= 1;
} // while (bitmask)
} // sendCounter()
void flushQueues() {

70
src/sensor.cpp Normal file
View File

@ -0,0 +1,70 @@
// Basic Config
#include "globals.h"
// Local logging tag
static const char TAG[] = "main";
#define SENSORBUFFER 10 // max. size of user sensor data buffer in bytes [default=20]
void sensor_init(void) {
// this function is called dureing device startup
// put your sensor initialization routines here
}
uint8_t sensor_mask(uint8_t sensor_no) {
switch (sensor_no) {
case 1:
return (uint8_t)SENSOR1_DATA;
case 2:
return (uint8_t)SENSOR2_DATA;
break;
case 3:
return (uint8_t)SENSOR3_DATA;
case 4:
return (uint8_t)SENSOR4_DATA;
}
}
uint8_t *sensor_read(uint8_t sensor) {
static uint8_t buf[SENSORBUFFER] = {0};
uint8_t length = 3;
switch (sensor) {
case 1:
buf[0] = length;
buf[1] = 0xff;
buf[2] = 0xa0;
buf[3] = 0x01;
break;
case 2:
buf[0] = length;
buf[1] = 0xff;
buf[2] = 0xa0;
buf[3] = 0x02;
break;
case 3:
buf[0] = length;
buf[1] = 0xff;
buf[2] = 0xa0;
buf[3] = 0x03;
break;
case 4:
buf[0] = length;
buf[1] = 0xff;
buf[2] = 0xa0;
buf[3] = 0x04;
break;
}
return buf;
}

View File

@ -27,6 +27,7 @@ typedef struct {
// using IRAM_:ATTR here to speed up callback function
IRAM_ATTR void wifi_sniffer_packet_handler(void *buff,
wifi_promiscuous_pkt_type_t type) {
const wifi_promiscuous_pkt_t *ppkt = (wifi_promiscuous_pkt_t *)buff;
const wifi_ieee80211_packet_t *ipkt =
(wifi_ieee80211_packet_t *)ppkt->payload;