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_P118_CCS811.ino
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_P118_CCS811.ino
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#ifdef USES_P118
//#######################################################################################################
//########################### Plugin 118: CCS811 Air Quality TVOC/eCO2 Sensor ###########################
//#######################################################################################################
/*
Plugin written by Alexander Schwantes
Includes sparkfun library https://github.com/sparkfun/SparkFun_CCS811_Arduino_Library
There are various modes for setting up sensor:
* Interrupt: Requires interrupt pin to signal that a new reading is available. Can read ever 1/10/60 seconds.
* Wake: Requires a wake pin to wake device for reading when required.
* Continuous: Takes a reading every 1/10/60 seconds.
This plugin currently implements just the last continuous method as it requires the least number of connected pins.
The library has provisions for the other modes.
*/
#define PLUGIN_118
#define PLUGIN_ID_118 118
#define PLUGIN_NAME_118 "Air Quality - CCS811 TVOC/eCO2 Sensor"
#define PLUGIN_VALUENAME1_118 "TVOC"
#define PLUGIN_VALUENAME2_118 "eCO2"
// int Plugin_118_WAKE_Pin;
// int Plugin_118_INT_Pin;
// #define Plugin_118_nWAKE 2
// #define Plugin_118_nINT 14
#define Plugin_118_D_AWAKE 20 // microseconds to wait before waking waking (deassert) sensor. min 20 microseconds
#define Plugin_118_T_AWAKE 100 // microseconds to wait after waking sensor. min 50 microseconds
/******************************************************************************
CCS811 Arduino library
Marshall Taylor @ SparkFun Electronics
Nathan Seidle @ SparkFun Electronics
April 4, 2017
https://github.com/sparkfun/CCS811_Air_Quality_Breakout
https://github.com/sparkfun/SparkFun_CCS811_Arduino_Library
Resources:
Uses Wire.h for i2c operation
Development environment specifics:
Arduino IDE 1.8.1
This code is released under the [MIT License](http://opensource.org/licenses/MIT).
Please review the LICENSE.md file included with this example. If you have any questions
or concerns with licensing, please contact [email protected].
Distributed as-is; no warranty is given.
******************************************************************************/
// **************************************************************************/
// CCS811 Library
// **************************************************************************/
#ifndef __CCS811_H__
# define __CCS811_H__
# include "stdint.h"
// Register addresses
# define CSS811_STATUS 0x00
# define CSS811_MEAS_MODE 0x01
# define CSS811_ALG_RESULT_DATA 0x02
# define CSS811_RAW_DATA 0x03
# define CSS811_ENV_DATA 0x05
# define CSS811_NTC 0x06
# define CSS811_THRESHOLDS 0x10
# define CSS811_BASELINE 0x11
# define CSS811_HW_ID 0x20
# define CSS811_HW_VERSION 0x21
# define CSS811_FW_BOOT_VERSION 0x23
# define CSS811_FW_APP_VERSION 0x24
# define CSS811_ERROR_ID 0xE0
# define CSS811_APP_START 0xF4
# define CSS811_SW_RESET 0xFF
// This is the core operational class of the driver.
// CCS811Core contains only read and write operations towards the sensor.
// To use the higher level functions, use the class CCS811 which inherits
// this class.
class CCS811Core
{
public:
// Return values
typedef enum {
SENSOR_SUCCESS,
SENSOR_ID_ERROR,
SENSOR_I2C_ERROR,
SENSOR_INTERNAL_ERROR,
SENSOR_GENERIC_ERROR
// ...
} status;
CCS811Core(uint8_t);
~CCS811Core() = default;
status beginCore(void);
void setAddress(uint8_t);
// ***Reading functions***//
// readRegister reads one 8-bit register
status readRegister(uint8_t offset, uint8_t * outputPointer);
// multiReadRegister takes a uint8 array address as input and performs
// a number of consecutive reads
status multiReadRegister(uint8_t offset, uint8_t * outputPointer, uint8_t length);
// ***Writing functions***//
// Writes an 8-bit byte;
status writeRegister(uint8_t offset, uint8_t dataToWrite);
// multiWriteRegister takes a uint8 array address as input and performs
// a number of consecutive writes
status multiWriteRegister(uint8_t offset, uint8_t * inputPointer, uint8_t length);
protected:
uint8_t I2CAddress;
};
// This is the highest level class of the driver.
// class CCS811 inherits the CCS811Core and makes use of the beginCore()
// method through its own begin() method. It also contains user settings/values.
class CCS811 : public CCS811Core
{
public:
CCS811(uint8_t);
// Call to check for errors, start app, and set default mode 1
status begin(void);
status readAlgorithmResults(void);
bool checkForStatusError(void);
bool dataAvailable(void);
bool appValid(void);
uint8_t getErrorRegister(void);
uint16_t getBaseline(void);
status setBaseline(uint16_t);
status enableInterrupts(void);
status disableInterrupts(void);
status setDriveMode(uint8_t mode);
status setEnvironmentalData(float relativeHumidity, float temperature);
void setRefResistance(float);
status readNTC(void);
uint16_t getTVOC(void);
uint16_t getCO2(void);
float getResistance(void);
float getTemperature(void);
String getDriverError(CCS811Core::status);
String getSensorError(void);
private:
// These are the air quality values obtained from the sensor
float refResistance;
float resistance;
uint16_t tVOC;
uint16_t CO2;
uint16_t vrefCounts = 0;
uint16_t ntcCounts = 0;
float temperature;
};
#endif // End of definition check
CCS811 myCCS811(0x5B); // start with default, but will update later on with user settings
boolean Plugin_118(byte function, struct EventStruct * event, String & string)
{
boolean success = false;
switch (function)
{
case PLUGIN_DEVICE_ADD:
{
Device[++deviceCount].Number = PLUGIN_ID_118;
Device[deviceCount].Type = DEVICE_TYPE_I2C;
Device[deviceCount].VType = SENSOR_TYPE_DUAL;
Device[deviceCount].Ports = 0;
Device[deviceCount].PullUpOption = false;
Device[deviceCount].InverseLogicOption = false;
Device[deviceCount].FormulaOption = true;
Device[deviceCount].ValueCount = 2;
Device[deviceCount].SendDataOption = true;
Device[deviceCount].TimerOption = true;
break;
}
case PLUGIN_GET_DEVICENAME:
{
string = F(PLUGIN_NAME_118);
break;
}
case PLUGIN_GET_DEVICEVALUENAMES:
{
strcpy_P(ExtraTaskSettings.TaskDeviceValueNames[0], PSTR(PLUGIN_VALUENAME1_118));
strcpy_P(ExtraTaskSettings.TaskDeviceValueNames[1], PSTR(PLUGIN_VALUENAME2_118));
break;
}
case PLUGIN_WEBFORM_LOAD:
{
// I2C address choice
byte choice = Settings.TaskDevicePluginConfig[event->TaskIndex][0];
String options[2] = {F("0x5A (ADDR pin is LOW)"), F("0x5B (ADDR pin is HIGH)")};
int optionValues[2] = {0x5A, 0x5B};
addFormSelector(F("I2C Address"), F("plugin_118_i2c_address"), 2, options, optionValues, choice);
// read frequency
int frequencyChoice = (int) Settings.TaskDevicePluginConfigLong[event->TaskIndex][0];
String frequencyOptions[3] = {F("1 second"), F("10 seconds"), F("60 seconds")};
int frequencyValues[3] = {1, 2, 3};
addFormSelector(F("Take reading every"), F("plugin_118_read_frequency"), 3, frequencyOptions, frequencyValues, frequencyChoice);
addFormSeparator(2);
// mode
addFormCheckBox(F("Enable temp/humid compensation"), F("plugin_118_enable_compensation"), Settings.TaskDevicePluginConfig[event->TaskIndex][1]);
addFormNote(F("If this is enabled, the Temperature and Humidity values below need to be configured."));
// temperature
addHtml(F("<TR><TD>Temperature:<TD>"));
addTaskSelect(F("plugin_118_temperature_task"), Settings.TaskDevicePluginConfig[event->TaskIndex][2]);
LoadTaskSettings(Settings.TaskDevicePluginConfig[event->TaskIndex][2]); // we need to load the values from another task for selection!
addHtml(F("<TR><TD>Temperature Value:<TD>"));
addTaskValueSelect(F("plugin_118_temperature_value"), Settings.TaskDevicePluginConfig[event->TaskIndex][3], Settings.TaskDevicePluginConfig[event->TaskIndex][2]);
// temperature scale
int temperatureScale = Settings.TaskDevicePluginConfig[event->TaskIndex][6];
addHtml(F("<TR><TD>Temperature Scale:<TD>")); // checked
addHtml(F("<input type='radio' id='plugin_118_temperature_c' name='plugin_118_temperature_scale' value='0'"));
addHtml((temperatureScale == 0) ? F(" checked>") : F(">"));
addHtml(F("<label for='plugin_118_temperature_c'> °C</label> "));
addHtml(F("<input type='radio' id='plugin_118_temperature_f' name='plugin_118_temperature_scale' value='1'"));
addHtml((temperatureScale == 1) ? F(" checked>") : F(">"));
addHtml(F("<label for='plugin_118_temperature_f'> °F</label><br>"));
// humidity
addHtml(F("<TR><TD>Humidity:<TD>"));
addTaskSelect(F("plugin_118_humidity_task"), Settings.TaskDevicePluginConfig[event->TaskIndex][4]);
LoadTaskSettings(Settings.TaskDevicePluginConfig[event->TaskIndex][4]); // we need to load the values from another task for selection!
addHtml(F("<TR><TD>Humidity Value:<TD>"));
addTaskValueSelect(F("plugin_118_humidity_value"), Settings.TaskDevicePluginConfig[event->TaskIndex][5], Settings.TaskDevicePluginConfig[event->TaskIndex][4]);
LoadTaskSettings(event->TaskIndex); // we need to restore our original taskvalues!
// addFormSeparator(string);
addFormSeparator(2);
success = true;
break;
}
case PLUGIN_WEBFORM_SAVE:
{
Settings.TaskDevicePluginConfig[event->TaskIndex][0] = getFormItemInt(F("plugin_118_i2c_address"));
Settings.TaskDevicePluginConfig[event->TaskIndex][1] = isFormItemChecked(F("plugin_118_enable_compensation") );
Settings.TaskDevicePluginConfig[event->TaskIndex][2] = getFormItemInt(F("plugin_118_temperature_task"));
Settings.TaskDevicePluginConfig[event->TaskIndex][3] = getFormItemInt(F("plugin_118_temperature_value"));
Settings.TaskDevicePluginConfig[event->TaskIndex][4] = getFormItemInt(F("plugin_118_humidity_task"));
Settings.TaskDevicePluginConfig[event->TaskIndex][5] = getFormItemInt(F("plugin_118_humidity_value"));
Settings.TaskDevicePluginConfig[event->TaskIndex][6] = getFormItemInt(F("plugin_118_temperature_scale"));
Settings.TaskDevicePluginConfigLong[event->TaskIndex][0] = getFormItemInt(F("plugin_118_read_frequency"));
success = true;
break;
}
case PLUGIN_INIT:
{
// Plugin_118_WAKE_Pin = Settings.TaskDevicePin1[event->TaskIndex];
uint8_t Plugin_118_I2C_ADDR = Settings.TaskDevicePluginConfig[event->TaskIndex][0];
myCCS811.setAddress(Plugin_118_I2C_ADDR);
CCS811Core::status returnCode;
returnCode = myCCS811.begin();
String log = F("CCS811 : Begin exited with: ");
log += myCCS811.getDriverError(returnCode);
addLog(LOG_LEVEL_DEBUG, log);
UserVar[event->BaseVarIndex] = NAN;
UserVar[event->BaseVarIndex + 1] = NAN;
// This sets the mode to 1 second reads, and prints returned error status.
// Mode 0 = Idle (not used)
// Mode 1 = read every 1s
// Mode 2 = every 10s
// Mode 3 = every 60s
// Mode 4 = RAW mode (not used)
returnCode = myCCS811.setDriveMode(Settings.TaskDevicePluginConfigLong[event->TaskIndex][0]);
log = F("CCS811 : Mode request exited with: ");
log += myCCS811.getDriverError(returnCode);
addLog(LOG_LEVEL_DEBUG, log);
success = true;
break;
}
case PLUGIN_READ:
{
String log;
// if CCS811 is compensated with temperature and humidity
if (Settings.TaskDevicePluginConfig[event->TaskIndex][1])
{
// we're checking a var from another task, so calculate that basevar
byte TaskIndex = Settings.TaskDevicePluginConfig[event->TaskIndex][2];
byte BaseVarIndex = TaskIndex * VARS_PER_TASK + Settings.TaskDevicePluginConfig[event->TaskIndex][3];
float temperature = UserVar[BaseVarIndex]; // in degrees C
// convert to celsius if required
int temperature_in_fahrenheit = Settings.TaskDevicePluginConfig[event->TaskIndex][6];
String temp = F("°C");
if (temperature_in_fahrenheit)
{
temperature = (temperature - 32) * 5 / 9;
temp = F("°F");
}
byte TaskIndex2 = Settings.TaskDevicePluginConfig[event->TaskIndex][4];
byte BaseVarIndex2 = TaskIndex2 * VARS_PER_TASK + Settings.TaskDevicePluginConfig[event->TaskIndex][5];
float humidity = UserVar[BaseVarIndex2]; // in % relative
log = F("CCS811 : Compensating for Temperature: ");
log += String(temperature) + temp + F(" & Humidity: ") + String(humidity) + F("%");
addLog(LOG_LEVEL_DEBUG, log);
myCCS811.setEnvironmentalData(humidity, temperature);
// myCCS811.readAlgorithmResults(); //Dump a reading and wait
delay(100);
}
if (myCCS811.dataAvailable() )
{
// Calling readAlgorithmResults() function updates the global tVOC and CO2 variables
CCS811Core::status readstatus = myCCS811.readAlgorithmResults();
if (readstatus == 0)
{
UserVar[event->BaseVarIndex] = myCCS811.getTVOC();
UserVar[event->BaseVarIndex + 1] = myCCS811.getCO2();
success = true;
log = F("CCS811 : tVOC: ");
log += myCCS811.getTVOC();
log += F(", eCO2: ");
log += myCCS811.getCO2();
addLog(LOG_LEVEL_INFO, log);
}
else
{
log = F("CCS811 : Error reading values : ");
log += readstatus;
addLog(LOG_LEVEL_ERROR, log);
}
}
else if (myCCS811.checkForStatusError() )
{
// If the CCS811 found an internal error, print it.
log = F("CCS811 : Error: ");
log += myCCS811.getSensorError();
addLog(LOG_LEVEL_ERROR, log);
}
else
{
log = F("CCS811 : No values found.");
addLog(LOG_LEVEL_ERROR, log);
}
if(!success)
{
UserVar[event->BaseVarIndex] = NAN;
UserVar[event->BaseVarIndex + 1] = NAN;
}
break;
}
} // switch
return success;
} // Plugin_118
// ****************************************************************************//
//
// LIS3DHCore functions
//
// For I2C, construct LIS3DHCore myIMU(<address>);
//
// Default <address> is 0x5B.
//
// ****************************************************************************//
CCS811Core::CCS811Core(uint8_t inputArg) : I2CAddress(inputArg)
{
}
void CCS811Core::setAddress(uint8_t address)
{
I2CAddress = address;
}
CCS811Core::status CCS811Core::beginCore(void)
{
CCS811Core::status returnError = SENSOR_SUCCESS;
// Wire.begin(); // not necessary
#ifdef __AVR__
#else
#endif
#ifdef __MK20DX256__
#else
#endif
#ifdef ARDUINO_ARCH_ESP8266
#else
#endif
// Spin for a few ms
volatile uint8_t temp = 0;
for (uint16_t i = 0; i < 10000; i++)
{
temp++;
}
while (Wire.available() ) // Clear wire as a precaution
{
Wire.read();
}
// Check the ID register to determine if the operation was a success.
uint8_t readCheck;
readCheck = 0;
returnError = readRegister(CSS811_HW_ID, &readCheck);
if (returnError != SENSOR_SUCCESS)
{
return returnError;
}
if (readCheck != 0x81)
{
returnError = SENSOR_ID_ERROR;
}
return returnError;
} // CCS811Core::beginCore
// ****************************************************************************//
//
// ReadRegister
//
// Parameters:
// offset -- register to read
// *outputPointer -- Pass &variable (address of) to save read data to
//
// ****************************************************************************//
CCS811Core::status CCS811Core::readRegister(uint8_t offset, uint8_t * outputPointer)
{
// Return value
uint8_t result;
uint8_t numBytes = 1;
CCS811Core::status returnError = SENSOR_SUCCESS;
Wire.beginTransmission(I2CAddress);
Wire.write(offset);
if (Wire.endTransmission() != 0)
{
returnError = SENSOR_I2C_ERROR;
}
Wire.requestFrom(I2CAddress, numBytes);
while (Wire.available() ) // slave may send less than requested
{
result = Wire.read(); // receive a byte as a proper uint8_t
}
*outputPointer = result;
return returnError;
}
// ****************************************************************************//
//
// multiReadRegister
//
// Parameters:
// offset -- register to read
// *outputPointer -- Pass &variable (base address of) to save read data to
// length -- number of bytes to read
//
// Note: Does not know if the target memory space is an array or not, or
// if there is the array is big enough. if the variable passed is only
// two bytes long and 3 bytes are requested, this will over-write some
// other memory!
//
// ****************************************************************************//
CCS811Core::status CCS811Core::multiReadRegister(uint8_t offset, uint8_t * outputPointer, uint8_t length)
{
CCS811Core::status returnError = SENSOR_SUCCESS;
// define pointer that will point to the external space
uint8_t i = 0;
uint8_t c = 0;
// Set the address
Wire.beginTransmission(I2CAddress);
Wire.write(offset);
if (Wire.endTransmission() != 0)
{
returnError = SENSOR_I2C_ERROR;
}
else // OK, all worked, keep going
{ // request 6 bytes from slave device
Wire.requestFrom(I2CAddress, length);
while ( ( Wire.available() ) && (i < length) ) // slave may send less than requested
{
c = Wire.read(); // receive a byte as character
*outputPointer = c;
outputPointer++;
i++;
}
// dump extra
while (Wire.available() )
{
Wire.read();
}
}
return returnError;
} // CCS811Core::multiReadRegister
// ****************************************************************************//
//
// writeRegister
//
// Parameters:
// offset -- register to write
// dataToWrite -- 8 bit data to write to register
//
// ****************************************************************************//
CCS811Core::status CCS811Core::writeRegister(uint8_t offset, uint8_t dataToWrite)
{
CCS811Core::status returnError = SENSOR_SUCCESS;
Wire.beginTransmission(I2CAddress);
Wire.write(offset);
Wire.write(dataToWrite);
if (Wire.endTransmission() != 0)
{
returnError = SENSOR_I2C_ERROR;
}
return returnError;
}
// ****************************************************************************//
//
// multiReadRegister
//
// Parameters:
// offset -- register to read
// *inputPointer -- Pass &variable (base address of) to save read data to
// length -- number of bytes to read
//
// Note: Does not know if the target memory space is an array or not, or
// if there is the array is big enough. if the variable passed is only
// two bytes long and 3 bytes are requested, this will over-write some
// other memory!
//
// ****************************************************************************//
CCS811Core::status CCS811Core::multiWriteRegister(uint8_t offset, uint8_t * inputPointer, uint8_t length)
{
CCS811Core::status returnError = SENSOR_SUCCESS;
// define pointer that will point to the external space
uint8_t i = 0;
// Set the address
Wire.beginTransmission(I2CAddress);
Wire.write(offset);
while (i < length) // send data bytes
{
Wire.write(*inputPointer); // receive a byte as character
inputPointer++;
i++;
}
if (Wire.endTransmission() != 0)
{
returnError = SENSOR_I2C_ERROR;
}
return returnError;
}
// ****************************************************************************//
//
// Main user class -- wrapper for the core class + maths
//
// Construct with same rules as the core ( uint8_t busType, uint8_t inputArg )
//
// ****************************************************************************//
CCS811::CCS811(uint8_t inputArg) : CCS811Core(inputArg)
{
refResistance = 10000;
resistance = 0;
temperature = 0;
tVOC = 0;
CO2 = 0;
}
// ****************************************************************************//
//
// Begin
//
// This starts the lower level begin, then applies settings
//
// ****************************************************************************//
CCS811Core::status CCS811::begin(void)
{
uint8_t data[4] = { 0x11, 0xE5, 0x72, 0x8A }; // Reset key
CCS811Core::status returnError = SENSOR_SUCCESS; // Default error state
// restart the core
returnError = beginCore();
if (returnError != SENSOR_SUCCESS)
{
return returnError;
}
// Reset the device
multiWriteRegister(CSS811_SW_RESET, data, 4);
// Tclk = 1/16MHz = 0x0000000625
// 0.001 s / tclk = 16000 counts
volatile uint8_t temp = 0;
#ifdef ARDUINO_ARCH_ESP8266
for (uint32_t i = 0; i < 80000; i++) // This waits > 1ms @ 80MHz clock
{
temp++;
}
#elif __AVR__
for (uint16_t i = 0; i < 16000; i++) // This waits > 1ms @ 16MHz clock
{
temp++;
}
#else // ifdef ARDUINO_ARCH_ESP8266
for (uint32_t i = 0; i < 200000; i++) // Spin for a good while
{
temp++;
}
#endif // ifdef ARDUINO_ARCH_ESP8266
if (checkForStatusError() == true)
{
return SENSOR_INTERNAL_ERROR;
}
if (appValid() == false)
{
return SENSOR_INTERNAL_ERROR;
}
// Write 0 bytes to this register to start app
Wire.beginTransmission(I2CAddress);
Wire.write(CSS811_APP_START);
if (Wire.endTransmission() != 0)
{
return SENSOR_I2C_ERROR;
}
delay(200);
// returnError = setDriveMode(1); //Read every second
Serial.println();
return returnError;
} // CCS811::begin
// ****************************************************************************//
//
// Sensor functions
//
// ****************************************************************************//
// Updates the total voltatile organic compounds (TVOC) in parts per billion (PPB)
// and the CO2 value
// Returns nothing
CCS811Core::status CCS811::readAlgorithmResults(void)
{
uint8_t data[4];
CCS811Core::status returnError = multiReadRegister(CSS811_ALG_RESULT_DATA, data, 4);
if (returnError != SENSOR_SUCCESS)
{
return returnError;
}
// Data ordered:
// co2MSB, co2LSB, tvocMSB, tvocLSB
CO2 = ( (uint16_t) data[0] << 8 ) | data[1];
tVOC = ( (uint16_t) data[2] << 8 ) | data[3];
return SENSOR_SUCCESS;
}
// Checks to see if error bit is set
bool CCS811::checkForStatusError(void)
{
uint8_t value;
// return the status bit
readRegister(CSS811_STATUS, &value);
return (value & 1 << 0);
}
// Checks to see if DATA_READ flag is set in the status register
bool CCS811::dataAvailable(void)
{
uint8_t value;
CCS811Core::status returnError = readRegister(CSS811_STATUS, &value);
if (returnError != SENSOR_SUCCESS)
{
return 0;
}
else
{
return (value & 1 << 3);
}
}
// Checks to see if APP_VALID flag is set in the status register
bool CCS811::appValid(void)
{
uint8_t value;
CCS811Core::status returnError = readRegister(CSS811_STATUS, &value);
if (returnError != SENSOR_SUCCESS)
{
return 0;
}
else
{
return (value & 1 << 4);
}
}
uint8_t CCS811::getErrorRegister(void)
{
uint8_t value;
CCS811Core::status returnError = readRegister(CSS811_ERROR_ID, &value);
if (returnError != SENSOR_SUCCESS)
{
return 0xFF;
}
else
{
return value; // Send all errors in the event of communication error
}
}
// Returns the baseline value
// Used for telling sensor what 'clean' air is
// You must put the sensor in clean air and record this value
uint16_t CCS811::getBaseline(void)
{
uint8_t data[2];
CCS811Core::status returnError = multiReadRegister(CSS811_BASELINE, data, 2);
unsigned int baseline = ( (uint16_t) data[0] << 8 ) | data[1];
if (returnError != SENSOR_SUCCESS)
{
return 0;
}
else
{
return (baseline);
}
}
CCS811Core::status CCS811::setBaseline(uint16_t input)
{
uint8_t data[2];
data[0] = (input >> 8) & 0x00FF;
data[1] = input & 0x00FF;
CCS811Core::status returnError = multiWriteRegister(CSS811_BASELINE, data, 2);
return returnError;
}
// Enable the nINT signal
CCS811Core::status CCS811::enableInterrupts(void)
{
uint8_t value;
CCS811Core::status returnError = readRegister(CSS811_MEAS_MODE, &value); // Read what's currently there
if (returnError != SENSOR_SUCCESS)
{
return returnError;
}
Serial.println(value, HEX);
value |= (1 << 3); // Set INTERRUPT bit
writeRegister(CSS811_MEAS_MODE, value);
Serial.println(value, HEX);
return returnError;
}
// Disable the nINT signal
CCS811Core::status CCS811::disableInterrupts(void)
{
uint8_t value;
CCS811Core::status returnError = readRegister(CSS811_MEAS_MODE, &value); // Read what's currently there
if (returnError != SENSOR_SUCCESS)
{
return returnError;
}
value &= ~(1 << 3); // Clear INTERRUPT bit
returnError = writeRegister(CSS811_MEAS_MODE, value);
return returnError;
}
// Mode 0 = Idle
// Mode 1 = read every 1s
// Mode 2 = every 10s
// Mode 3 = every 60s
// Mode 4 = RAW mode
CCS811Core::status CCS811::setDriveMode(uint8_t mode)
{
if (mode > 4)
{
mode = 4; // sanitize input
}
uint8_t value;
CCS811Core::status returnError = readRegister(CSS811_MEAS_MODE, &value); // Read what's currently there
if (returnError != SENSOR_SUCCESS)
{
return returnError;
}
value &= ~(0b00000111 << 4); // Clear DRIVE_MODE bits
value |= (mode << 4); // Mask in mode
returnError = writeRegister(CSS811_MEAS_MODE, value);
return returnError;
}
// Given a temp and humidity, write this data to the CSS811 for better compensation
// This function expects the humidity and temp to come in as floats
CCS811Core::status CCS811::setEnvironmentalData(float relativeHumidity, float temperature)
{
// Check for invalid temperatures
if ( (temperature < -25) || (temperature > 50) )
{
return SENSOR_GENERIC_ERROR;
}
// Check for invalid humidity
if ( (relativeHumidity < 0) || (relativeHumidity > 100) )
{
return SENSOR_GENERIC_ERROR;
}
uint32_t rH = relativeHumidity * 1000; // 42.348 becomes 42348
uint32_t temp = temperature * 1000; // 23.2 becomes 23200
byte envData[4];
// Split value into 7-bit integer and 9-bit fractional
envData[0] = ( (rH % 1000) / 100 ) > 7 ? (rH / 1000 + 1) << 1 : (rH / 1000) << 1;
envData[1] = 0; // CCS811 only supports increments of 0.5 so bits 7-0 will always be zero
if ( ( (rH % 1000) / 100 ) > 2 && ( ( (rH % 1000) / 100 ) < 8 ) )
{
envData[0] |= 1; // Set 9th bit of fractional to indicate 0.5%
}
temp += 25000; // Add the 25C offset
// Split value into 7-bit integer and 9-bit fractional
envData[2] = ( (temp % 1000) / 100 ) > 7 ? (temp / 1000 + 1) << 1 : (temp / 1000) << 1;
envData[3] = 0;
if ( ( (temp % 1000) / 100 ) > 2 && ( ( (temp % 1000) / 100 ) < 8 ) )
{
envData[2] |= 1; // Set 9th bit of fractional to indicate 0.5C
}
CCS811Core::status returnError = multiWriteRegister(CSS811_ENV_DATA, envData, 4);
return returnError;
} // CCS811::setEnvironmentalData
void CCS811::setRefResistance(float input)
{
refResistance = input;
}
CCS811Core::status CCS811::readNTC(void)
{
uint8_t data[4];
CCS811Core::status returnError = multiReadRegister(CSS811_NTC, data, 4);
vrefCounts = ( (uint16_t) data[0] << 8 ) | data[1];
// Serial.print("vrefCounts: ");
// Serial.println(vrefCounts);
ntcCounts = ( (uint16_t) data[2] << 8 ) | data[3];
// Serial.print("ntcCounts: ");
// Serial.println(ntcCounts);
// Serial.print("sum: ");
// Serial.println(ntcCounts + vrefCounts);
resistance = ( (float) ntcCounts * refResistance / (float) vrefCounts );
// Code from Milan Malesevic and Zoran Stupic, 2011,
// Modified by Max Mayfield,
temperature = log( (long) resistance);
temperature = 1 / ( 0.001129148 + (0.000234125 * temperature) + (0.0000000876741 * temperature * temperature * temperature) );
temperature = temperature - 273.15; // Convert Kelvin to Celsius
return returnError;
}
uint16_t CCS811::getTVOC(void)
{
return tVOC;
}
uint16_t CCS811::getCO2(void)
{
return CO2;
}
float CCS811::getResistance(void)
{
return resistance;
}
float CCS811::getTemperature(void)
{
return temperature;
}
// getDriverError decodes the CCS811Core::status type and prints the
// type of error to the serial terminal.
//
// Save the return value of any function of type CCS811Core::status, then pass
// to this function to see what the output was.
String CCS811::getDriverError(CCS811Core::status errorCode)
{
switch (errorCode)
{
case CCS811Core::SENSOR_SUCCESS:
return "SUCCESS";
case CCS811Core::SENSOR_ID_ERROR:
return "ID_ERROR";
case CCS811Core::SENSOR_I2C_ERROR:
return "I2C_ERROR";
case CCS811Core::SENSOR_INTERNAL_ERROR:
return "INTERNAL_ERROR";
case CCS811Core::SENSOR_GENERIC_ERROR:
return "GENERIC_ERROR";
default:
return "Unspecified error.";
}
}
// getSensorError gets, clears, then prints the errors
// saved within the error register.
String CCS811::getSensorError()
{
uint8_t error = getErrorRegister();
if (error == 0xFF)
{
return "Failed to get ERROR_ID register.";
}
else
{
if (error & 1 << 5)
{
return "HeaterSupply";
}
if (error & 1 << 4)
{
return "HeaterFault";
}
if (error & 1 << 3)
{
return "MaxResistance";
}
if (error & 1 << 2)
{
return "MeasModeInvalid";
}