Adding HCHO magnitude

6 years ago · 7ca3ae5f7d
--- a/code/espurna/config/progmem.h
+++ b/code/espurna/config/progmem.h
@ -60,6 +60,7 @@ PROGMEM const char magnitude_co2_topic[] = "co2";
 PROGMEM const char magnitude_lux_topic[] = "lux";
 PROGMEM const char magnitude_uv_topic[] = "uv";
 PROGMEM const char magnitude_distance_topic[] = "distance";
 PROGMEM const char magnitude_hcho_topic[] = "hcho";

 PROGMEM const char* const magnitude_topics[] = {
    magnitude_unknown_topic, magnitude_temperature_topic, magnitude_humidity_topic,
@ -69,7 +70,7 @@ PROGMEM const char* const magnitude_topics[] = {
    magnitude_analog_topic, magnitude_digital_topic, magnitude_events_topic,
    magnitude_pm1dot0_topic, magnitude_pm2dot5_topic, magnitude_pm10_topic,
    magnitude_co2_topic, magnitude_lux_topic, magnitude_uv_topic,
    magnitude_distance_topic
    magnitude_distance_topic, magnitude_hcho_topic
 };

 PROGMEM const char magnitude_empty[] = "";
@ -97,7 +98,7 @@ PROGMEM const char* const magnitude_units[] = {
    magnitude_empty, magnitude_empty, magnitude_empty,
    magnitude_ugm3, magnitude_ugm3, magnitude_ugm3,
    magnitude_ppm, magnitude_lux, magnitude_uv,
    magnitude_distance
    magnitude_distance, magnitude_empty

 };

--- a/code/espurna/config/sensors.h
+++ b/code/espurna/config/sensors.h
@ -391,14 +391,25 @@
 #endif

 //------------------------------------------------------------------------------
 // Particle Monitor based on Plantower PMSX003
 // Enable support by passing PMSX003_SUPPORT=1 build flag
 // Particle Monitor based on Plantower PMS
 // Enable support by passing PMS_SUPPORT=1 build flag
 //------------------------------------------------------------------------------

 #ifndef PMSX003_SUPPORT
 #define PMSX003_SUPPORT                 0
 #endif

 #ifndef PMS_TYPE
 #define PMS_TYPE                        PMS_TYPE_X003
 #endif

 // You can enable smart sleep (read 6-times then sleep on 24-reading-cycles) to extend PMS sensor's life.
 // Otherwise the default lifetime of PMS sensor is about 8000-hours/1-years.
 // The PMS's fan will stop working on sleeping cycle, and will wake up on reading cycle.
 #ifndef PMS_SMART_SLEEP
 #define PMS_SMART_SLEEP                 0
 #endif

 #ifndef PMS_RX_PIN
 #define PMS_RX_PIN                      13
 #endif
@ -649,7 +660,6 @@

 #if PMSX003_SUPPORT
    #include <SoftwareSerial.h>
    #include <PMS.h>
    #include "../sensors/PMSX003Sensor.h"
 #endif

--- a/code/espurna/config/types.h
+++ b/code/espurna/config/types.h
@ -278,5 +278,6 @@
 #define MAGNITUDE_LUX               19
 #define MAGNITUDE_UV                20
 #define MAGNITUDE_DISTANCE          21
 #define MAGNITUDE_HCHO              22

 #define MAGNITUDE_MAX               22
 #define MAGNITUDE_MAX               23
--- a/code/espurna/data/index.html.gz
+++ b/code/espurna/data/index.html.gz
--- a/code/espurna/sensors/PMSX003Sensor.h
+++ b/code/espurna/sensors/PMSX003Sensor.h
@ -1,5 +1,5 @@
 // -----------------------------------------------------------------------------
 // PMSX003 Dust Sensor
 // PMS Dust Sensor
 // Uses SoftwareSerial library
 // Contribution by Òscar Rovira López
 // Refine to support PMS5003T/PMS5003ST by Yonsm Guo
@ -12,25 +12,16 @@
 #include "Arduino.h"
 #include "BaseSensor.h"

 #include <PMS.h>
 #include <SoftwareSerial.h>

 //
 #define PMS_TYPE_X003    0
 #define PMS_TYPE_X003_9  1
 #define PMS_TYPE_5003T   2
 #define PMS_TYPE_5003ST  3
 // Type of sensor
 #define PMS_TYPE_X003       0
 #define PMS_TYPE_X003_9     1
 #define PMS_TYPE_5003T      2
 #define PMS_TYPE_5003ST     3

 #ifndef PMS_TYPE
 #define PMS_TYPE PMS_TYPE_X003
 #endif

 // You can enable smart sleep (read 6-times then sleep on 24-reading-cycles) to extend PMS sensor's life.
 // Otherwise the default lifetime of PMS sensor is about 8000-hours/1-years.
 // The PMS's fan will stop working on sleeping cycle, and will wake up on reading cycle.
 #ifndef PMS_SMART_SLEEP
 #define PMS_SMART_SLEEP 0
 #endif
 // These should not be static, instead a setType method should be used to
 // dinamically choose the type of sensor...

 // [MAGIC][LEN][DATA9|13|17][SUM]
 #if PMS_TYPE == PMS_TYPE_5003ST
@ -38,7 +29,7 @@
 #define PMS_DATA_COUNT 17
 #define PMS_SLOT_COUNT 4
 #define PMS_SLOT_NAMES {"PM2.5", "TEMP", "HUMI", "HCHO"}
 #define PMS_SLOT_TYPES {MAGNITUDE_PM2dot5, MAGNITUDE_TEMPERATURE, MAGNITUDE_HUMIDITY, MAGNITUDE_ANALOG}
 #define PMS_SLOT_TYPES {MAGNITUDE_PM2dot5, MAGNITUDE_TEMPERATURE, MAGNITUDE_HUMIDITY, MAGNITUDE_HCHO}
 #elif PMS_TYPE == PMS_TYPE_5003T
 #define PMS_TYPE_NAME "PMS5003T"
 #define PMS_DATA_COUNT 13
@ -63,107 +54,112 @@
 #define PMS_PAYLOAD_SIZE (PMS_DATA_COUNT * 2 + 2)


 // PMSX003 sensor utils
 // PMS sensor utils
 // Command functions copied from: https://github.com/fu-hsi/PMS/blob/master/src/PMS.cpp
 // Reading function is rewrited to support flexible reading for PMS5003T/PMS5003ST
 class PMSX003 {
 protected:
    SoftwareSerial *_serial = NULL; // Should initialized by child class

 public:
    // Standby mode. For low power consumption and prolong the life of the sensor.
    inline void sleep() {
        uint8_t command[] = { 0x42, 0x4D, 0xE4, 0x00, 0x00, 0x01, 0x73 };
        _serial->write(command, sizeof(command));
    }

    // Operating mode. Stable data should be got at least 30 seconds after the sensor wakeup from the sleep mode because of the fan's performance.
    inline void wakeUp() {
        uint8_t command[] = { 0x42, 0x4D, 0xE4, 0x00, 0x01, 0x01, 0x74 };
        _serial->write(command, sizeof(command));
    }

    // Active mode. Default mode after power up. In this mode sensor would send serial data to the host automatically.
    inline void activeMode() {
        uint8_t command[] = { 0x42, 0x4D, 0xE1, 0x00, 0x01, 0x01, 0x71 };
        _serial->write(command, sizeof(command));
    }

    // Passive mode. In this mode, sensor would send serial data to the host only for request.
    inline void passiveMode() {
        uint8_t command[] = { 0x42, 0x4D, 0xE1, 0x00, 0x00, 0x01, 0x70 };
        _serial->write(command, sizeof(command));
    }

    // Request read, ONLY needed in Passive Mode!!
    inline void requestRead() {
        uint8_t command[] = { 0x42, 0x4D, 0xE2, 0x00, 0x00, 0x01, 0x71 };
        _serial->write(command, sizeof(command));
    }

    // Read sensor's data
    bool readData(uint16_t data[PMS_DATA_COUNT]) {
        do
        {
            int avail = _serial->available();
            #if SENSOR_DEBUG
                //debugSend("[SENSOR] %s: Packet available = %d\n", PMS_TYPE_NAME, avail);
            #endif
            if (avail < PMS_PACKET_SIZE)
                break;

            if (_serial->read() == 0x42 && _serial->read() == 0x4D)
            {
                uint16_t sum = 0x42 + 0x4D;
                uint16_t size = read16(sum);
    protected:
        SoftwareSerial *_serial = NULL; // Should initialized by child class

    public:

        // Standby mode. For low power consumption and prolong the life of the sensor.
        inline void sleep() {
            uint8_t command[] = { 0x42, 0x4D, 0xE4, 0x00, 0x00, 0x01, 0x73 };
            _serial->write(command, sizeof(command));
        }

        // Operating mode. Stable data should be got at least 30 seconds after the sensor wakeup from the sleep mode because of the fan's performance.
        inline void wakeUp() {
            uint8_t command[] = { 0x42, 0x4D, 0xE4, 0x00, 0x01, 0x01, 0x74 };
            _serial->write(command, sizeof(command));
        }

        // Active mode. Default mode after power up. In this mode sensor would send serial data to the host automatically.
        inline void activeMode() {
            uint8_t command[] = { 0x42, 0x4D, 0xE1, 0x00, 0x01, 0x01, 0x71 };
            _serial->write(command, sizeof(command));
        }

        // Passive mode. In this mode, sensor would send serial data to the host only for request.
        inline void passiveMode() {
            uint8_t command[] = { 0x42, 0x4D, 0xE1, 0x00, 0x00, 0x01, 0x70 };
            _serial->write(command, sizeof(command));
        }

        // Request read, ONLY needed in Passive Mode!!
        inline void requestRead() {
            uint8_t command[] = { 0x42, 0x4D, 0xE2, 0x00, 0x00, 0x01, 0x71 };
            _serial->write(command, sizeof(command));
        }

        // Read sensor's data
        bool readData(uint16_t data[PMS_DATA_COUNT]) {

            do {

                int avail = _serial->available();
                #if SENSOR_DEBUG
                    debugSend("[SENSOR] %s: Payload size = %d\n", PMS_TYPE_NAME, size);
                    //debugSend("[SENSOR] %s: Packet available = %d\n", PMS_TYPE_NAME, avail);
                #endif
                if (size != PMS_PAYLOAD_SIZE)
                {
                    #if SENSOR_DEBUG
                        debugSend(("[SENSOR] %s: Payload size != %d \n"), PMS_TYPE_NAME, PMS_PAYLOAD_SIZE);
                    #endif
                if (avail < PMS_PACKET_SIZE) {
                    break;
                }

                for (int i = 0; i < PMS_DATA_COUNT; i++)
                {
                    data[i] = read16(sum);
                if (_serial->read() == 0x42 && _serial->read() == 0x4D) {

                    uint16_t sum = 0x42 + 0x4D;
                    uint16_t size = read16(sum);
                    #if SENSOR_DEBUG
                        //debugSend(("[SENSOR] %s:   data[%d] = %d\n"), PMS_TYPE_NAME, i, data[i]);
                        debugSend("[SENSOR] %s: Payload size = %d\n", PMS_TYPE_NAME, size);
                    #endif
                }
                    if (size != PMS_PAYLOAD_SIZE) {
                        #if SENSOR_DEBUG
                            debugSend(("[SENSOR] %s: Payload size != %d \n"), PMS_TYPE_NAME, PMS_PAYLOAD_SIZE);
                        #endif
                        break;
                    }

                uint16_t checksum = read16();
                #if SENSOR_DEBUG
                    debugSend(("[SENSOR] %s:   Sum=%04X, Checksum=%04X\n"), PMS_TYPE_NAME, sum, checksum);
                #endif
                if (sum == checksum)
                {
                    return true;
                    for (int i = 0; i < PMS_DATA_COUNT; i++) {
                        data[i] = read16(sum);
                        #if SENSOR_DEBUG
                            //debugSend(("[SENSOR] %s:   data[%d] = %d\n"), PMS_TYPE_NAME, i, data[i]);
                        #endif
                    }

                    uint16_t checksum = read16();
                    #if SENSOR_DEBUG
                        debugSend(("[SENSOR] %s:   Sum=%04X, Checksum=%04X\n"), PMS_TYPE_NAME, sum, checksum);
                    #endif
                    if (sum == checksum) {
                        return true;
                    }
                    break;
                }
                break;
            }

            } while (true);

            return false;

        }

    private:

        // Read 16-bit
        inline uint16_t read16() {
            return ((uint16_t) _serial->read()) << 8 | _serial->read();
        }

        // Read 16-bit and calculate checksum
        uint16_t read16(uint16_t &checksum) {
            uint8_t high = _serial->read();
            uint8_t low = _serial->read();
            checksum += high;
            checksum += low;
            return ((uint16_t) high) << 8 | low;
        }
        while (true);
        return false;
    }

 private:
    // Read 16-bit
    inline uint16_t read16() {
        return ((uint16_t) _serial->read()) << 8 | _serial->read();
    }

    // Read 16-bit and calculate checksum
    uint16_t read16(uint16_t &checksum) {
        uint8_t high = _serial->read();
        uint8_t low = _serial->read();
        checksum += high;
        checksum += low;
        return ((uint16_t) high) << 8 | low;
    }    

 };

 class PMSX003Sensor : public BaseSensor, PMSX003 {
@ -313,6 +309,7 @@ class PMSX003Sensor : public BaseSensor, PMSX003 {
            #endif

            requestRead();
            
        }

        // Current value for slot # index
@ -326,9 +323,10 @@ class PMSX003Sensor : public BaseSensor, PMSX003 {
        unsigned long _startTime;
        double _slot_values[PMS_SLOT_COUNT] = {0};

 #if PMS_SMART_SLEEP
        unsigned int _readCount = 0;
 #endif
        #if PMS_SMART_SLEEP
            unsigned int _readCount = 0;
        #endif

 };

 #endif // SENSOR_SUPPORT && PMSX003_SUPPORT
 #endif // SENSOR_SUPPORT && PMS_SUPPORT
--- a/code/espurna/static/index.html.gz.h
+++ b/code/espurna/static/index.html.gz.h
--- a/code/html/custom.js
+++ b/code/html/custom.js
@ -39,7 +39,7 @@ function sensorName(id) {
        "HLW8012", "V9261F", "ECH1560", "Analog", "Digital",
        "Events", "PMSX003", "BMX280", "MHZ19", "SI7021",
        "SHT3X I2C", "BH1750", "PZEM004T", "AM2320 I2C", "GUVAS12SD",
        "TMP3X", "HC-SR04"
        "TMP3X", "HC-SR04", "SenseAir"
    ];
    if (1 <= id && id <= names.length) {
        return names[id - 1];
@ -53,7 +53,7 @@ function magnitudeType(type) {
        "Current", "Voltage", "Active Power", "Apparent Power",
        "Reactive Power", "Power Factor", "Energy", "Energy (delta)",
        "Analog", "Digital", "Events",
        "PM1.0", "PM2.5", "PM10", "CO2", "Lux", "UV", "Distance"
        "PM1.0", "PM2.5", "PM10", "CO2", "Lux", "UV", "Distance" , "HCHO"
    ];
    if (1 <= type && type <= types.length) {
        return types[type - 1];