Change chanel & kor send & move sensors time

2020-11-20 14:21:39 +03:00
parent a45b73601c
commit 9d5b0bbc22
9 changed files with 176 additions and 281 deletions
--- a/ESP_MidRoom/platformio.ini
+++ b/ESP_MidRoom/platformio.ini
@@ -17,3 +17,5 @@ board_build.ldscript = eagle.flash.1m.ld
 ;board_build.flash_mode = dout
 upload_protocol = espota
 upload_port = 192.168.1.132
 lib_deps = 
  jwrw/ESP_EEPROM @ ^2.0.0
--- a/ESP_MidRoom/src/main.cpp
+++ b/ESP_MidRoom/src/main.cpp
@@ -3,7 +3,7 @@
 #include <Ticker.h>
 #include <AsyncMqttClient.h>
 #include <leds.h>
-#include <EEPROM.h>
+#include <ESP_EEPROM.h>
 #define R_LED (13)
 #define G_LED (12)
@@ -124,9 +124,9 @@ void setup() {
    Serial1.println(p); */
  }  
-  EEPROM.begin(4);
+  EEPROM.begin(16);
-  EEPROM.get(0, mvDelaySet);
+  EEPROM.get(4, mvDelaySet);
-  mvDelaySet = 90;
+  //mvDelaySet = 90;
  mvDelay = -1;
 	connectToWifi();
@@ -143,21 +143,21 @@ void loop() {
  ArduinoOTA.handle();
  g_led.tick();
  //r_led.tick();
-  if((digitalRead(MOV_SENS) > 0) && (mvDelay == -1)){
+  if(digitalRead(MOV_SENS) > 0){
-    //mqttClient.publish("/home/midroom/move", 1, false, "1");
+    if(mvDelay == -1) mqttClient.publish("/home/midroom/move", 1, false, "1");
    mvDelay = mvDelaySet;
  }
-  if (digitalRead(MOV_SENS) != old_mov){
+  /*if (digitalRead(MOV_SENS) != old_mov){
    old_mov = digitalRead(MOV_SENS);
    //Serial1.println(F("Change mov detected"));
    mqttClient.publish("/home/midroom/move", 1, false, old_mov ? "1" : "0");
-  }
+  }*/
  if(cRun + 999 < millis()){
    cRun = millis();
    if(mvDelay == 0) {
-      //mqttClient.publish("/home/midroom/move", 1, false, "0");
+      mqttClient.publish("/home/midroom/move", 1, false, "0");
      mvDelay = -1;
    }
    if(mvDelay > 0) mvDelay--;
@@ -193,10 +193,10 @@ void loop() {
        //r_led.start();
        //Serial1.println("Begin Publish");
        dtostrf(t, 5, 1,v);
-        mqttClient.publish("/home/midroom/temp", 0, false, v);
+        mqttClient.publish("/home/midroom/temp", 1, false, v);
        //Serial1.println("Publish1");
        dtostrf(h, 5, 1,v);
-        mqttClient.publish("/home/midroom/humid", 0, false, v);
+        mqttClient.publish("/home/midroom/humid", 1, false, v);
        //Serial1.println("Publish2");
        if(firstRun){
          stDelay++;
@@ -204,7 +204,7 @@ void loop() {
        }
        if(!firstRun && (mhz19.errorCode == RESULT_OK)){
          itoa(co2, v, 10);
-          mqttClient.publish("/home/midroom/co2", 0, false, v);
+          mqttClient.publish("/home/midroom/co2", 1, false, v);
          //Serial1.println("Publish3");
        }
      }
@@ -258,21 +258,15 @@ void onWifiDisconnect(const WiFiEventStationModeDisconnected& event) {
 }
 void onMqttConnect(bool sessionPresent) {
-/*   Serial1.println(F("Connected to MQTT."));
+  char v[15];
-  Serial1.print(F("Session present: "));
+  sprintf(v, "%u", mvDelaySet);
-  //Serial1.flush();
+  //itoa(mvDelaySet, v, 10);
-  Serial1.println(sessionPresent); */
+  mqttClient.publish("/home/midroom/mvdelay", 1, false, v);
-  //digitalWrite(B_LED, HIGH);
+  mqttClient.subscribe("/home/midroom/mvdelay", 1);
-  //digitalWrite(R_LED, LOW);
+  // ultoa(ESP.getFlashChipSize(), v, 10);
-  //uint16_t packetIdSub = 
+  // mqttClient.publish("/home/midroom/chipsize", 1, false, v);
-  // //Serial1.print("Subscribing Lamp1, packetId: ");
+  // ultoa(ESP.getFlashChipRealSize(), v, 10);
-  // //Serial1.println(packetIdSub);
+  // mqttClient.publish("/home/midroom/realchipsize", 1, false, v);
  //packetIdSub = mqttClient.subscribe("/home/kor/lamp2_set", 1);
  ////Serial1.print("Subscribing Lamp2, packetId: ");
  ////Serial1.println(packetIdSub);
  ////Serial1.println("Publishing at Lamp 1");
  //mqttClient.publish("/home/kor/lamp2", 1, false, lStat2 ? "1" : "0");
  ////Serial1.println("Publishing at Lamp 2");
  digitalWrite(B_LED, LOW);  
 }
@@ -302,8 +296,8 @@ void onMqttUnsubscribe(uint16_t packetId) {
 void onMqttMessage(char* topic, char* payload, AsyncMqttClientMessageProperties properties, size_t len, size_t index, size_t total) {
  if(strcmp(topic, "/home/midroom/mvdelay") == 0){
-    mvDelaySet = atol(payload);
+    mvDelaySet = atoi(payload);
-    EEPROM.put(0, mvDelaySet);
+    EEPROM.put(4, mvDelaySet);
    EEPROM.commit();
  }
 }
--- a/ExtSens/src/main.cpp
+++ b/ExtSens/src/main.cpp
@@ -2,6 +2,7 @@
 #define MY_DEBUG
 #define MY_RADIO_RF24
 #define MY_RF24_CHANNEL (105)
 #define MY_RF24_PA_LEVEL RF24_PA_HIGH
 #include <MySensors.h>
 #include <AHT10.h>
@@ -34,30 +35,29 @@ void setup() {
  Serial.print(F("Temperature: ")); Serial.print(myAHT10.readTemperature(AHT10_FORCE_READ_DATA)); Serial.println(F(" +-0.3C"));
  Serial.print(F("Humidity...: ")); Serial.print(myAHT10.readHumidity(AHT10_USE_READ_DATA));      Serial.println(F(" +-2%"));
-  cRun = millis();
+  cRun = 0;
-  send(msgMillis.set(cRun));
+  //send(msgMillis.set(cRun));
 }
 void loop() {
    float temp, hum;
-    //if((cRun + 29999) < millis()){
+    unsigned long t = millis();
      cRun = millis();
    temp = myAHT10.readTemperature(AHT10_FORCE_READ_DATA);
    hum = myAHT10.readHumidity(AHT10_USE_READ_DATA);
-      Serial.print(F("Temperature: ")); Serial.print(temp); Serial.println(F(" +-0.3C"));
+    Serial.print(F("T: ")); Serial.print(temp);// Serial.println(F(" +-0.3C"));
-      Serial.print(F("Humidity...: ")); Serial.print(hum);  Serial.println(F(" +-2%"));
+    Serial.print(F("H: ")); Serial.print(hum);//  Serial.println(F(" +-2%"));
    if (temp < 200){
      send(msgTemp.set(temp, 1));
      send(msgHum.set(hum, 1));
    }
      send(msgMillis.set(cRun));
    sensorValue = analogRead(BATTERY_SENSE_PIN);
    v = sensorValue * 0.004659498;
    batteryPcnt = ((v-3.0) * 100) / 1.2;
    sendBatteryLevel(batteryPcnt);
    send(msgVolts.set(v, 2));
-    //}
+    Serial.println(F("Tm run")); Serial.println(millis() - t);
-    sleep(60000 - (millis() - cRun));
+    send(msgMillis.set(cRun++));
    sleep(60000 - (millis() - t));
 }
 void presentation()
--- a/KorMYS/src/main.cpp
+++ b/KorMYS/src/main.cpp
@@ -1,97 +1,28 @@
 #include <Arduino.h>
 /**
 * The MySensors Arduino library handles the wireless radio link and protocol
 * between your home built sensors/actuators and HA controller of choice.
 * The sensors forms a self healing radio network with optional repeaters. Each
 * repeater and gateway builds a routing tables in EEPROM which keeps track of the
 * network topology allowing messages to be routed to nodes.
 *
 * Created by Henrik Ekblad <henrik.ekblad@mysensors.org>
 * Copyright (C) 2013-2019 Sensnology AB
 * Full contributor list: https://github.com/mysensors/MySensors/graphs/contributors
 *
 * Documentation: http://www.mysensors.org
 * Support Forum: http://forum.mysensors.org
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * version 2 as published by the Free Software Foundation.
 *
 *******************************
 *
 * DESCRIPTION
 * The ArduinoGateway prints data received from sensors on the serial link.
 * The gateway accepts input on serial which will be sent out on radio network.
 *
 * The GW code is designed for Arduino Nano 328p / 16MHz
 *
 * Wire connections (OPTIONAL):
 * - Inclusion button should be connected between digital pin 3 and GND
 * - RX/TX/ERR leds need to be connected between +5V (anode) and digital pin 6/5/4 with resistor 270-330R in a series
 *
 * LEDs (OPTIONAL):
 * - To use the feature, uncomment any of the MY_DEFAULT_xx_LED_PINs
 * - RX (green) - blink fast on radio message received. In inclusion mode will blink fast only on presentation received
 * - TX (yellow) - blink fast on radio message transmitted. In inclusion mode will blink slowly
 * - ERR (red) - fast blink on error during transmission error or receive crc error
 *
 */
 // Enable debug prints to serial monitor
 #define MY_DEBUG
 // Enable and select radio type attached
 #define MY_RADIO_RF24
-//#define MY_RADIO_NRF5_ESB
+#define MY_RF24_CHANNEL (105)
 //#define MY_RADIO_RFM69
 //#define MY_RADIO_RFM95
 // Set LOW transmit power level as default, if you have an amplified NRF-module and
 // power your radio separately with a good regulator you can turn up PA level.
 #define MY_RF24_PA_LEVEL RF24_PA_HIGH
 // Enable serial gateway
 //#define MY_GATEWAY_SERIAL
 // Define a lower baud rate for Arduinos running on 8 MHz (Arduino Pro Mini 3.3V & SenseBender)
 #if F_CPU == 8000000L
 #define MY_BAUD_RATE 38400
 #endif
 #define MY_TRANSPORT_WAIT_READY_MS 10000
 // Enable inclusion mode
 //#define MY_INCLUSION_MODE_FEATURE
 // Enable Inclusion mode button on gateway
 //#define MY_INCLUSION_BUTTON_FEATURE
 // Inverses behavior of inclusion button (if using external pullup)
 //#define MY_INCLUSION_BUTTON_EXTERNAL_PULLUP
 // Set inclusion mode duration (in seconds)
 //#define MY_INCLUSION_MODE_DURATION 60
 // Digital pin used for inclusion mode button
 //#define MY_INCLUSION_MODE_BUTTON_PIN  3
 // Set blinking period
 #define MY_DEFAULT_LED_BLINK_PERIOD 300
 // Inverses the behavior of leds
 #define MY_WITH_LEDS_BLINKING_INVERSE
 // Flash leds on rx/tx/err
 // Uncomment to override default HW configurations
 #define MY_DEFAULT_ERR_LED_PIN A3  // Error led pin
 #define MY_DEFAULT_TX_LED_PIN  A4  // the PCB, on board LED
 #define MY_DEFAULT_RX_LED_PIN  A5  // Receive led pin
 #include <MySensors.h>
 //#include <SdsDustSensor.h>
 #include <SDS011.h>
 #include <SoftwareSerial.h>
 unsigned long cRun;
-int cSec, adc, move, oldmov, minLight, minLightDB, LightInt;
+int cSec, adc, move, oldmov, minLight, minLightDB, LightInt, timeDelay, curDelay;
 uint8_t sdsPeriod;
 bool lamp;
 //float avgL;
@@ -108,7 +39,9 @@ MyMessage msgLightLevSet(3, V_VAR1);
 MyMessage msgMillis(3, V_VAR4);
 MyMessage msgMove(4, V_TRIPPED);
 MyMessage msgLamp(5, V_VAR1);
-
+void sendData(MyMessage msg, int status);
 void sendData(MyMessage msg, float status);
 void sendData(MyMessage msg, bool status);
 void SDS011workmode(byte mode, SoftwareSerial *ser);
 void setup()
@@ -132,6 +65,13 @@ void setup()
 	minLightDB = (loadState(2) << 8) + loadState(3);
 	LightInt = (loadState(4) << 8) + loadState(5);
 	sdsPeriod = loadState(6);
 	timeDelay = (loadState(8) << 8) + loadState(9);
 	curDelay = -1;
 	Serial.print(F("Min Light"));Serial.println(minLight);
 	Serial.print(F("Min LightDB"));Serial.println(minLightDB);
 	Serial.print(F("LightInt"));Serial.println(LightInt);
 	Serial.print(F("SDS Period"));Serial.println(sdsPeriod);
 	Serial.print(F("Time Delay"));Serial.println(timeDelay);
  SDS011workmode(sdsPeriod, &sSerial);
 //	if(minLight == 0) minLight = 5;
 	//adc = analogRead(A0);
@@ -155,56 +95,73 @@ void presentation()
 void loop()
 {
 	float p25, p10;
-	move = digitalRead(A1);
+	//move = digitalRead(A1);
-	if(move != oldmov){
+
-		oldmov = move;
+  if(digitalRead(A1) > 0){
-		send(msgMove.set(move));
+    if(curDelay == -1) sendData(msgMove, true);
 		move = true;
    curDelay = timeDelay;
  }
 	// if(move != oldmov){
 	// 	oldmov = move;
 	// 	sendData(msgMove, move);
 	// 	//send(msgMove.set(move));
 	// }
 	adc = analogRead(A0);
 	//avgL += ((float)(adc) - avgL) * 0.1f;
 	if ((adc <= minLight) && (move == 1)){
 		analogWrite(LAMP_OUT, LightInt);
 		//digitalWrite(6, HIGH);
 		if(lamp == false){
 			Serial.println("Lamp ON");
 			Serial.print("ADC: ");Serial.print(adc);
 			Serial.print(", Move: ");Serial.println(move);
-			send(msgLightLev.set(adc, 2));
+			sendData(msgLightLev, adc);
 			//send(msgLightLev.set(adc, 2));
 			wait(50);
-			send(msgLamp.set(true));
+			sendData(msgLamp, true);
 			//send(msgLamp.set(true));
 			lamp = true;
 		}
 	}
 	else if((adc > (minLight + minLightDB)) || (move == 0)){
 		analogWrite(LAMP_OUT, 0);
 		//digitalWrite(6, LOW);
 		if(lamp == true){
 			Serial.println("Lamp OFF");
 			Serial.print("ADC: ");Serial.print(adc);
 			Serial.print(", Move: ");Serial.println(move);
-			send(msgLightLev.set(adc, 2));
+			sendData(msgLightLev, adc);
 			//send(msgLightLev.set(adc, 2));
 			wait(50);
-			send(msgLamp.set(false));
+			sendData(msgLamp, false);
 			//send(msgLamp.set(false));
 			lamp = false;
 		}
 	}
 	if(cRun + 999 < millis()){
 		cRun = millis();
    if(curDelay == 0) {
      sendData(msgMove, false);
 			move = false;
      curDelay = -1;
    }
    if(curDelay > 0) curDelay--;
 		int error = sds.read(&p25, &p10);
 		//Serial.print("ADC: ");Serial.print(adc);Serial.print(", Move: ");Serial.println(move);
 		if (!error) {
 			Serial.println(millis()/1000);
 			Serial.println("P2.5: " + String(p25));
 			Serial.println("P10:  " + String(p10));
-			send(msgHum25.set(p25, 1));
+			sendData(msgHum25, p25);
 			//send(msgHum25.set(p25, 1));
 			wait(100);
-			send(msgHum10.set(p10, 1));
+			sendData(msgHum10, p10);
 			//send(msgHum10.set(p10, 1));
 		}
 		if (++cSec > 19){
 			cSec = 0;
 			//sendHeartbeat();
 			wait(100);
-			send(msgLightLev.set(adc));
+			sendData(msgLightLev, adc);
 			//send(msgLightLev.set(adc));
 			wait(100);
 			uint32_t ms = millis();
 			send(msgMillis.set(ms));
@@ -240,12 +197,18 @@ void receive(const MyMessage &message)
    sdsPeriod = message.getInt();
 		saveState(6, sdsPeriod);
    Serial.print("Sds period:");
    Serial.println(sdsPeriod);
  }
  if((message.sensor == 5) && (message.type == V_VAR2)){
    timeDelay = message.getInt();
 		saveState(8, (timeDelay>>8) & 0xFF);
 		saveState(9, timeDelay & 0xFF);
    Serial.print("time period:");
    Serial.println(timeDelay);
  }
 }
 //////////////////  sends work mode command to SDS011  //////////////////////
 void SDS011workmode(byte mode, SoftwareSerial *ser)
 {
  byte cs = 7 + mode;
@@ -255,3 +218,46 @@ void SDS011workmode(byte mode, SoftwareSerial *ser)
    ser->write(sleep_command[i]);
  }
 }
 void sendData(MyMessage msg, bool status)
 {
  bool send_data = false;
  uint8_t count = 0;
  while(send_data == false){
    count++;
    send_data = send(msg.set(status));
    wait(1000, C_SET, V_STATUS);
    if ((count ==  3 )&&(send_data == 0)){                   // Если сделано 3 попытки и нет подтверждения отправки
      count = 0;                                             // Обнуляем счётчик
      send_data = 1;                                         // Выходим из цикла
    }
  }
 }
 void sendData(MyMessage msg, float status)
 {
  bool send_data = false;
  uint8_t count = 0;
  while(send_data == false){
    count++;
    send_data = send(msg.set(status, 1));
    wait(1000, C_SET, V_STATUS);
    if ((count ==  3 )&&(send_data == 0)){                   // Если сделано 3 попытки и нет подтверждения отправки
      count = 0;                                             // Обнуляем счётчик
      send_data = 1;                                         // Выходим из цикла
    }
  }
 }
 void sendData(MyMessage msg, int status)
 {
  bool send_data = false;
  uint8_t count = 0;
  while(send_data == false){
    count++;
    send_data = send(msg.set(status));
    wait(1000, C_SET, V_STATUS);
    if ((count ==  3 )&&(send_data == 0)){                   // Если сделано 3 попытки и нет подтверждения отправки
      count = 0;                                             // Обнуляем счётчик
      send_data = 1;                                         // Выходим из цикла
    }
  }
 }
--- a/MainDoorMyS/src/main.cpp
+++ b/MainDoorMyS/src/main.cpp
@@ -4,6 +4,7 @@
 // Enable and select radio type attached
 #define MY_RF24_PA_LEVEL RF24_PA_HIGH
 #define MY_RADIO_RF24
 #define MY_RF24_CHANNEL (105)
 #if F_CPU == 8000000L
 #define MY_BAUD_RATE 38400
 #endif
--- a/MidRoomNLight/src/main.cpp
+++ b/MidRoomNLight/src/main.cpp
@@ -4,6 +4,7 @@
 // Enable and select radio type attached
 #define MY_RADIO_RF24
 #define MY_RF24_CHANNEL (105)
 #include <MySensors.h>
 #define RELAY_PIN 3  // Arduino Digital I/O pin number for first relay (second on pin+1 etc)
@@ -20,7 +21,6 @@ void before()
 void setup()
 {
 }
 void presentation()
@@ -30,10 +30,8 @@ void presentation()
    present(0, S_DIMMER, "Dimmer");
 }
 void loop()
 {
 }
 void receive(const MyMessage &message)
--- a/SerialGateWayMyS/.vscode/tasks.json
+++ b/SerialGateWayMyS/.vscode/tasks.json
@@ -0,0 +1,28 @@
 {
  "tasks": [
    {
      "type": "cppbuild",
      "label": "C/C++: avr-gcc.exe build active file",
      "command": "C:/Users/lexa-/.platformio/packages/toolchain-atmelavr@1.50400.190710/bin/avr-gcc.exe",
      "args": [
        "-g",
        "${file}",
        "-o",
        "${fileDirname}\\${fileBasenameNoExtension}.exe",
        "-mmcu=atmega328p"
      ],
      "options": {
        "cwd": "C:/Users/lexa-/.platformio/packages/toolchain-atmelavr@1.50400.190710/bin"
      },
      "problemMatcher": [
        "$gcc"
      ],
      "group": {
        "kind": "build",
        "isDefault": true
      },
      "detail": "Generated task by Debugger"
    }
  ],
  "version": "2.0.0"
 }
--- a/SerialGateWayMyS/platformio.ini
+++ b/SerialGateWayMyS/platformio.ini
@@ -10,8 +10,8 @@
 [env:nanoatmega328]
 platform = atmelavr
-;board = nanoatmega328
+board = nanoatmega328
-board = uno
+;board = uno
 framework = arduino
 monitor_speed = 115200
 lib_deps = featherfly/SoftwareSerial @ ^1.0
--- a/SerialGateWayMyS/src/main.cpp
+++ b/SerialGateWayMyS/src/main.cpp
@@ -1,167 +1,33 @@
 #include <Arduino.h>
 /**
 * The MySensors Arduino library handles the wireless radio link and protocol
 * between your home built sensors/actuators and HA controller of choice.
 * The sensors forms a self healing radio network with optional repeaters. Each
 * repeater and gateway builds a routing tables in EEPROM which keeps track of the
 * network topology allowing messages to be routed to nodes.
 *
 * Created by Henrik Ekblad <henrik.ekblad@mysensors.org>
 * Copyright (C) 2013-2019 Sensnology AB
 * Full contributor list: https://github.com/mysensors/MySensors/graphs/contributors
 *
 * Documentation: http://www.mysensors.org
 * Support Forum: http://forum.mysensors.org
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * version 2 as published by the Free Software Foundation.
 *
 *******************************
 *
 * DESCRIPTION
 * The ArduinoGateway prints data received from sensors on the serial link.
 * The gateway accepts input on serial which will be sent out on radio network.
 *
 * The GW code is designed for Arduino Nano 328p / 16MHz
 *
 * Wire connections (OPTIONAL):
 * - Inclusion button should be connected between digital pin 3 and GND
 * - RX/TX/ERR leds need to be connected between +5V (anode) and digital pin 6/5/4 with resistor 270-330R in a series
 *
 * LEDs (OPTIONAL):
 * - To use the feature, uncomment any of the MY_DEFAULT_xx_LED_PINs
 * - RX (green) - blink fast on radio message received. In inclusion mode will blink fast only on presentation received
 * - TX (yellow) - blink fast on radio message transmitted. In inclusion mode will blink slowly
 * - ERR (red) - fast blink on error during transmission error or receive crc error
 *
 */
 // Enable debug prints to serial monitor
 #define MY_DEBUG
 // Enable and select radio type attached
 #define MY_RADIO_RF24
 //#define MY_RADIO_NRF5_ESB
 //#define MY_RADIO_RFM69
 //#define MY_RADIO_RFM95
 // Set LOW transmit power level as default, if you have an amplified NRF-module and
 // power your radio separately with a good regulator you can turn up PA level.
 #define MY_RF24_PA_LEVEL RF24_PA_HIGH
 // Enable serial gateway
 #define MY_GATEWAY_SERIAL
-
+#define MY_RF24_CHANNEL (105)
 // Define a lower baud rate for Arduinos running on 8 MHz (Arduino Pro Mini 3.3V & SenseBender)
 #if F_CPU == 8000000L
 #define MY_BAUD_RATE 38400
 #endif
 // Enable inclusion mode
 //#define MY_INCLUSION_MODE_FEATURE
 // Enable Inclusion mode button on gateway
 //#define MY_INCLUSION_BUTTON_FEATURE
 // Inverses behavior of inclusion button (if using external pullup)
 //#define MY_INCLUSION_BUTTON_EXTERNAL_PULLUP
 // Set inclusion mode duration (in seconds)
 //#define MY_INCLUSION_MODE_DURATION 60
 // Digital pin used for inclusion mode button
 //#define MY_INCLUSION_MODE_BUTTON_PIN  3
 // Set blinking period
 #define MY_DEFAULT_LED_BLINK_PERIOD 300
 // Inverses the behavior of leds
 #define MY_WITH_LEDS_BLINKING_INVERSE
 // Flash leds on rx/tx/err
 // Uncomment to override default HW configurations
 #define MY_DEFAULT_ERR_LED_PIN 4  // Error led pin
 #define MY_DEFAULT_RX_LED_PIN  6  // Receive led pin
 #define MY_DEFAULT_TX_LED_PIN  5  // the PCB, on board LED
 #include <MySensors.h>
 //#include <SdsDustSensor.h>
 #include <SDS011.h>
 #include <SoftwareSerial.h>
 unsigned long cRun;
 int cSec;
 #define RX_PIN 2
 #define TX_PIN 3
 SoftwareSerial sSerial(RX_PIN, TX_PIN);
 SDS011 sds;
 //SdsDustSensor sds(sSerial);
 MyMessage msgHum25(0, V_LEVEL);
 MyMessage msgHum25_UN(0, V_UNIT_PREFIX);
 MyMessage msgHum10(1, V_LEVEL);
 MyMessage msgHum10_UN(1, V_UNIT_PREFIX);
 void set_per(uint8_t per, SoftwareSerial *ser);
 void setup()
 {
 	Serial.begin(115200);
 	sSerial.begin(9600);
 	set_per(2, &sSerial);
  sds.begin(&sSerial);
 	Serial.println("Begin");
  //Serial.println(sds.queryFirmwareVersion().toString()); // prints firmware version
  //Serial.println(sds.setActiveReportingMode().toString()); // ensures sensor is in 'active' reporting mode
  //Serial.println(sds.setCustomWorkingPeriod(3).toString()); // sensor sends data every 3 minutes
  //sds.setActiveReportingMode();
  //sds.setCustomWorkingPeriod(1);
 	cRun = millis();
 	cSec = 0;
 }
 void presentation()
 {
 	present(0, S_DUST, "pm2.5");
 	present(1, S_DUST, "pm10");
 }
 void loop()
 {
 	float p25, p10;
 	if(cRun + 999 < millis()){
 		cRun = millis();
 		int error = sds.read(&p25, &p10);
 		if (!error) {
 			Serial.println(millis()/1000);
 			Serial.println("P2.5: " + String(p25));
 			Serial.println("P10:  " + String(p10));
 		}
 /*		PmResult pm = sds.readPm();
 		if (pm.isOk()) {
 			send(msgHum25.set(pm.pm25, 2));
 			wait(100);
 			send(msgHum10.set(pm.pm10, 2));
 		}
 		if(++cSec == 60){
 			wait(100);
 			send(msgHum25_UN.set("pm2.5"));
 			wait(100);
 			send(msgHum10_UN.set("pm10"));
 		}*/
 	}
 }
 void set_per(uint8_t per, SoftwareSerial *ser)
 {
 	ser->write(0xAA);
 	ser->write(0xB4);
 	ser->write(0x08);
 	ser->write(0xAA);
 	ser->write(0x01);
 	for(int i = 0; i < 10; i++) ser->print(0x00);
 	ser->write(0xFF);
 	ser->write(0xFF);
 	uint8_t crc = 0x07 + per;
 	ser->write(crc);
 	ser->write(0xAB);
 }