PlantCtrl/esp32/src/main.cpp

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/**
* @file main.cpp
* @author Ollo
* @brief PlantControl
* @version 0.1
* @date 2020-05-01
*
* @copyright Copyright (c) 2020
*
*/
#include "PlantCtrl.h"
#include "ControllerConfiguration.h"
#include "DS18B20.h"
#include <Homie.h>
#include "esp_sleep.h"
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const unsigned long TEMPREADCYCLE = 30000; /**< Check temperature all half minutes */
#define AMOUNT_SENOR_QUERYS 8
#define SENSOR_QUERY_SHIFTS 3
#define SOLAR4SENSORS 6.0f
#define TEMP_INIT_VALUE -999.0f
#define TEMP_MAX_VALUE 85.0f
bool mLoopInited = false;
bool mDeepSleep = false;
int plantSensor1 = 0;
int lipoSenor = -1;
int lipoSensorValues = 0;
int solarSensor = -1;
int solarSensorValues = 0;
int mWaterGone = -1; /**< Amount of centimeter, where no water is seen */
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int readCounter = 0;
int mButtonClicks = 0;
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bool mConfigured = false;
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RTC_DATA_ATTR int gBootCount = 0;
RTC_DATA_ATTR int gCurrentPlant = 0; /**< Value Range: 1 ... 7 (0: no plant needs water) */
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#if (MAX_PLANTS >= 1)
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HomieNode plant0("plant0", "Plant 0", "Plant");
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#endif
#if (MAX_PLANTS >= 2)
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HomieNode plant1("plant1", "Plant 1", "Plant");
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#endif
#if (MAX_PLANTS >= 3)
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HomieNode plant2("plant2", "Plant 2", "Plant");
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#endif
#if (MAX_PLANTS >= 4)
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HomieNode plant3("plant3", "Plant 3", "Plant");
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#endif
#if (MAX_PLANTS >= 5)
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HomieNode plant4("plant4", "Plant 4", "Plant");
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#endif
#if (MAX_PLANTS >= 6)
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HomieNode plant5("plant5", "Plant 5", "Plant");
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#endif
#if (MAX_PLANTS >= 7)
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HomieNode plant6("plant6", "Plant 6", "Plant");
#endif
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HomieNode sensorLipo("lipo", "Battery Status", "Lipo");
HomieNode sensorSolar("solar", "Solar Status", "Solarpanel");
HomieNode sensorWater("water", "WaterSensor", "Water");
HomieNode sensorTemp("temperature", "Temperature", "temperature");
HomieSetting<long> deepSleepTime("deepsleep", "time in milliseconds to sleep (0 deactivats it)");
HomieSetting<long> deepSleepNightTime("nightsleep", "time in milliseconds to sleep (0 usese same setting: deepsleep at night, too)");
HomieSetting<long> wateringDeepSleep("pumpdeepsleep", "time seconds to sleep, while a pump is running");
HomieSetting<long> plantCnt("plants", "amout of plants to control (1 ... 7)");
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#ifdef HC_SR04
HomieSetting<long> waterLevel("watermaxlevel", "Water maximum level in centimeter (50 cm default)");
HomieSetting<long> waterMinPercent("watermin", "Minimum percentage of water, to activate the pumps (default 5%)");
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#endif
HomieSetting<long> plant0SensorTrigger("moist0", "Moist0 sensor value, when pump activates");
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HomieSetting<long> plant1SensorTrigger("moist1", "Moist1 sensor value, when pump activates");
HomieSetting<long> plant2SensorTrigger("moist2", "Moist2 sensor value, when pump activates");
HomieSetting<long> plant3SensorTrigger("moist3", "Moist3 sensor value, when pump activates");
HomieSetting<long> plant4SensorTrigger("moist4", "Moist4 sensor value, when pump activates");
HomieSetting<long> plant5SensorTrigger("moist5", "Moist5 sensor value, when pump activates");
HomieSetting<long> plant6SensorTrigger("moist6", "Moist6 sensor value, when pump activates");
HomieSetting<long> wateringTime0("plant0MaxPumpTime", "time seconds Pump0 is running (60 is the default)");
HomieSetting<long> wateringTime1("plant1MaxPumpTime", "time seconds Pump1 is running (60 is the default)");
HomieSetting<long> wateringTime2("plant2MaxPumpTime", "time seconds Pump2 is running (60 is the default)");
HomieSetting<long> wateringTime3("plant3MaxPumpTime", "time seconds Pump3 is running (60 is the default)");
HomieSetting<long> wateringTime4("plant4MaxPumpTime", "time seconds Pump4 is running (60 is the default)");
HomieSetting<long> wateringTime5("plant5MaxPumpTime", "time seconds Pump5 is running (60 is the default)");
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HomieSetting<long> wateringTime6("plant6MaxPumpTime", "time seconds Pump6 is running (60 is the default)");
HomieSetting<long> wateringIdleTime0("plant0MinPumpIdle", "time in seconds Pump0 will wait (60 is the default)");
HomieSetting<long> wateringIdleTime1("plant1MinPumpIdle", "time in seconds Pump1 will wait (60 is the default)");
HomieSetting<long> wateringIdleTime2("plant2MinPumpIdle", "time in seconds Pump2 will wait (60 is the default)");
HomieSetting<long> wateringIdleTime3("plant3MinPumpIdle", "time in seconds Pump3 will wait (60 is the default)");
HomieSetting<long> wateringIdleTime4("plant4MinPumpIdle", "time in seconds Pump4 will wait (60 is the default)");
HomieSetting<long> wateringIdleTime5("plant5MinPumpIdle", "time in seconds Pump5 will wait (60 is the default)");
HomieSetting<long> wateringIdleTime6("plant6MinPumpIdle", "time in seconds Pump6 will wait (60 is the default)");
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Ds18B20 dallas(SENSOR_DS18B20);
Plant mPlants[MAX_PLANTS] = {
#if (MAX_PLANTS >= 1)
Plant(SENSOR_PLANT0, OUTPUT_PUMP0, &plant0, &plant0SensorTrigger, &wateringTime0, &wateringIdleTime0),
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#endif
#if (MAX_PLANTS >= 2)
Plant(SENSOR_PLANT1, OUTPUT_PUMP1, &plant1, &plant1SensorTrigger, &wateringTime1, &wateringIdleTime1),
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#endif
#if (MAX_PLANTS >= 3)
Plant(SENSOR_PLANT2, OUTPUT_PUMP2, &plant2, &plant2SensorTrigger, &wateringTime2, &wateringIdleTime2),
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#endif
#if (MAX_PLANTS >= 4)
Plant(SENSOR_PLANT3, OUTPUT_PUMP3, &plant3, &plant3SensorTrigger, &wateringTime3, &wateringIdleTime3),
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#endif
#if (MAX_PLANTS >= 5)
Plant(SENSOR_PLANT4, OUTPUT_PUMP4, &plant4, &plant4SensorTrigger, &wateringTime4, &wateringIdleTime4),
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#endif
#if (MAX_PLANTS >= 6)
Plant(SENSOR_PLANT5, OUTPUT_PUMP5, &plant5, &plant5SensorTrigger, &wateringTime5, &wateringIdleTime5),
#endif
#if (MAX_PLANTS >= 7)
Plant(SENSOR_PLANT6, OUTPUT_PUMP6, &plant6, &plant6SensorTrigger, &wateringTime6, &wateringIdleTime6)
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#endif
};
void readAnalogValues() {
if (readCounter < AMOUNT_SENOR_QUERYS) {
lipoSensorValues += analogRead(SENSOR_LIPO);
solarSensorValues += analogRead(SENSOR_SOLAR);
readCounter++;
} else {
lipoSenor = (lipoSensorValues >> SENSOR_QUERY_SHIFTS);
lipoSensorValues = 0;
solarSensor = (solarSensorValues >> SENSOR_QUERY_SHIFTS);
solarSensorValues = 0;
readCounter = 0;
}
}
/**
* @brief cyclic Homie callback
* All logic, to be done by the controller cyclically
*/
void loopHandler() {
int waterLevelPercent = (100 * mWaterGone) / waterLevel.get();
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/* Move from Setup to this position, because the Settings are only here available */
if (!mLoopInited) {
// Configure Deep Sleep:
if (deepSleepTime.get()) {
Serial << "HOMIE | Setup sleeping for " << deepSleepTime.get() << " ms" << endl;
}
/* Publish default values */
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plant0.setProperty("switch").send(String("OFF"));
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plant1.setProperty("switch").send(String("OFF"));
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plant2.setProperty("switch").send(String("OFF"));
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#if (MAX_PLANTS >= 4)
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plant3.setProperty("switch").send(String("OFF"));
plant4.setProperty("switch").send(String("OFF"));
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plant5.setProperty("switch").send(String("OFF"));
#endif
#if (MAX_PLANTS >= 7)
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plant6.setProperty("switch").send(String("OFF"));
#endif
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for(int i=0; i < plantCnt.get() && i < MAX_PLANTS; i++) {
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mPlants[i].calculateSensorValue(AMOUNT_SENOR_QUERYS);
mPlants[i].setProperty("moist").send(String(100 * mPlants[i].getSensorValue() / 4095 ));
/* the last Plant, that was watered is stored in non volatile memory */
if (gCurrentPlant <= 0 && mPlants[i].isPumpRequired()) {
/* there was no plant activated -> we can store the first one */
gCurrentPlant = i + 1;
} else if (gCurrentPlant > 0 && gCurrentPlant < (i+1) &&
mPlants[(gCurrentPlant - 1)].isPumpRequired() == false) {
/* The last does not need any more some water -> jump to the next one */
gCurrentPlant = i + 1;
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}
}
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sensorWater.setProperty("remaining").send(String(waterLevelPercent));
Serial << "Water : " << mWaterGone << " cm (" << waterLevelPercent << "%)" << endl;
/* Check if a plant needs water */
if (gCurrentPlant > 0) {
int plntIdx = (gCurrentPlant-1);
if (mPlants[plntIdx].isPumpRequired() &&
(waterLevelPercent > waterMinPercent.get()) &&
(digitalRead(mPlants[plntIdx].getPumpPin()) == LOW) ) {
Serial << "Plant" << plntIdx << " needs water" << endl;
mPlants[plntIdx].setProperty("switch").send(String("ON"));
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}
digitalWrite(OUTPUT_PUMP, HIGH);
digitalWrite(mPlants[plntIdx].getPumpPin(), HIGH);
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}
}
mLoopInited = true;
readAnalogValues();
if ((millis() % 1500) == 0) {
sensorLipo.setProperty("percent").send( String(100 * lipoSenor / 4095) );
sensorLipo.setProperty("volt").send( String(ADC_5V_TO_3V3(lipoSenor)) );
sensorSolar.setProperty("percent").send(String((100 * solarSensor ) / 4095));
sensorSolar.setProperty("volt").send( String(SOLAR_VOLT(solarSensor)) );
} else if ((millis() % 1000) == 0) {
float temp[2] = { TEMP_INIT_VALUE, TEMP_INIT_VALUE };
float* pFloat = temp;
int devices = dallas.readAllTemperatures(pFloat, 2);
if (devices < 2) {
if ((pFloat[0] > TEMP_INIT_VALUE) && (pFloat[0] < TEMP_MAX_VALUE) ) {
sensorTemp.setProperty("control").send( String(pFloat[0]));
}
} else if (devices >= 2) {
if ((pFloat[0] > TEMP_INIT_VALUE) && (pFloat[0] < TEMP_MAX_VALUE) ) {
sensorTemp.setProperty("temp").send( String(pFloat[0]));
}
if ((pFloat[1] > TEMP_INIT_VALUE) && (pFloat[1] < TEMP_MAX_VALUE) ) {
sensorTemp.setProperty("control").send( String(pFloat[1]));
}
}
}
/* Main Loop functionality */
if (waterLevelPercent <= waterMinPercent.get()) {
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/* let the ESP sleep qickly, as nothing must be done */
if ((millis() >= (MIN_TIME_RUNNING * MS_TO_S)) && (deepSleepTime.get() > 0)) {
mDeepSleep = true;
Serial << "No Water for pumps" << endl;
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}
}
/* Always check, that after 5 minutes the device is sleeping */
/* Pump is running, go to sleep after defined time */
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if (millis() >= ((MIN_TIME_RUNNING + 5) &&
(deepSleepTime.get() > 0))) {
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Serial << "No sleeping activated (maximum)" << endl;
mDeepSleep = true;
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} else if ((millis() >= ((MIN_TIME_RUNNING * MS_TO_S) + 0)) &&
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(deepSleepTime.get() > 0)) {
Serial << "Maximum time reached: " << endl;
mDeepSleep = true;
}
}
bool switchGeneralPumpHandler(const int pump, const HomieRange& range, const String& value) {
if (range.isRange) return false; // only one switch is present
switch (pump)
{
#if MAX_PLANTS >= 1
case 0:
#endif
#if MAX_PLANTS >= 2
case 1:
#endif
#if MAX_PLANTS >= 3
#endif
case 2:
#if MAX_PLANTS >= 4
case 3:
#endif
#if MAX_PLANTS >= 5
case 4:
#endif
#if MAX_PLANTS >= 6
case 5:
#endif
if ((value.equals("ON")) || (value.equals("On")) || (value.equals("on")) || (value.equals("true"))) {
digitalWrite(mPlants[pump].getPumpPin(), HIGH);
return true;
} else if ((value.equals("OFF")) || (value.equals("Off")) || (value.equals("off")) || (value.equals("false")) ) {
digitalWrite(mPlants[pump].getPumpPin(), LOW);
return true;
} else {
return false;
}
break;
default:
return false;
}
}
/**
* @brief Handle Mqtt commands for the pumpe, responsible for the first plant
*
* @param range multiple transmitted values (not used for this function)
* @param value single value
* @return true when the command was parsed and executed succuessfully
* @return false on errors when parsing the request
*/
bool switch1Handler(const HomieRange& range, const String& value) {
return switchGeneralPumpHandler(0, range, value);
}
/**
* @brief Handle Mqtt commands for the pumpe, responsible for the second plant
*
* @param range multiple transmitted values (not used for this function)
* @param value single value
* @return true when the command was parsed and executed succuessfully
* @return false on errors when parsing the request
*/
bool switch2Handler(const HomieRange& range, const String& value) {
return switchGeneralPumpHandler(1, range, value);
}
/**
* @brief Handle Mqtt commands for the pumpe, responsible for the third plant
*
* @param range multiple transmitted values (not used for this function)
* @param value single value
* @return true when the command was parsed and executed succuessfully
* @return false on errors when parsing the request
*/
bool switch3Handler(const HomieRange& range, const String& value) {
return switchGeneralPumpHandler(2, range, value);
}
/**
* @brief Sensors, that are connected to GPIOs, mandatory for WIFI.
* These sensors (ADC2) can only be read when no Wifi is used.
*/
void readSensors() {
/* activate all sensors */
pinMode(OUTPUT_SENSOR, OUTPUT);
digitalWrite(OUTPUT_SENSOR, HIGH);
delay(100);
/* wait before reading something */
for (int readCnt=0;readCnt < AMOUNT_SENOR_QUERYS; readCnt++) {
for(int i=0; i < MAX_PLANTS; i++) {
mPlants[i].addSenseValue(analogRead(mPlants[i].getSensorPin()));
}
}
#ifdef HC_SR04
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/* Use the Ultrasonic sensor to measure waterLevel */
/* deactivate all sensors and measure the pulse */
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digitalWrite(SENSOR_SR04_TRIG, LOW);
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delayMicroseconds(2);
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digitalWrite(SENSOR_SR04_TRIG, HIGH);
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delayMicroseconds(10);
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digitalWrite(SENSOR_SR04_TRIG, LOW);
float duration = pulseIn(SENSOR_SR04_ECHO, HIGH);
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float distance = (duration*.0343)/2;
mWaterGone = (int) distance;
Serial << "HC_SR04 | Distance : " << String(distance) << " cm" << endl;
#endif
/* deactivate the sensors */
digitalWrite(OUTPUT_SENSOR, LOW);
}
/**
* @brief Startup function
* Is called once, the controller is started
*/
void setup() {
/* Required to read the temperature once */
float temp[2] = {0, 0};
float* pFloat = temp;
/* read button */
pinMode(BUTTON, INPUT);
Serial.begin(115200);
Serial.setTimeout(1000); // Set timeout of 1 second
Serial << endl << endl;
Serial << "Read analog sensors..." << endl;
/* Disable Wifi and bluetooth */
WiFi.mode(WIFI_OFF);
/* now ADC2 can be used */
readSensors();
/* activate Wifi again */
WiFi.mode(WIFI_STA);
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if (HomieInternals::MAX_CONFIG_SETTING_SIZE < MAX_CONFIG_SETTING_ITEMS) {
Serial << "HOMIE | Settings: " << HomieInternals::MAX_CONFIG_SETTING_SIZE << "/" << MAX_CONFIG_SETTING_ITEMS << endl;
Serial << " | Update Limits.hpp : MAX_CONFIG_SETTING_SIZE to " << MAX_CONFIG_SETTING_ITEMS << endl;
}
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Homie_setFirmware("PlantControl", FIRMWARE_VERSION);
Homie.setLoopFunction(loopHandler);
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mConfigured = Homie.isConfigured();
if (mConfigured) {
// Load the settings
deepSleepTime.setDefaultValue(0);
deepSleepNightTime.setDefaultValue(0);
wateringTime0.setDefaultValue(60);
wateringTime1.setDefaultValue(60);
wateringTime2.setDefaultValue(60);
wateringTime3.setDefaultValue(60);
wateringTime4.setDefaultValue(60);
wateringTime5.setDefaultValue(60);
wateringTime6.setDefaultValue(60);
plantCnt.setDefaultValue(0).setValidator([] (long candidate) {
return ((candidate >= 0) && (candidate <= 6) );
});
plant1SensorTrigger.setDefaultValue(0);
plant2SensorTrigger.setDefaultValue(0);
plant3SensorTrigger.setDefaultValue(0);
#if (MAX_PLANTS >= 4)
plant4SensorTrigger.setDefaultValue(0);
plant5SensorTrigger.setDefaultValue(0);
plant6SensorTrigger.setDefaultValue(0);
#endif
#ifdef HC_SR04
waterLevel.setDefaultValue(50);
waterMinPercent.setDefaultValue(5);
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#endif
// Advertise topics
plant1.advertise("switch").setName("Pump 1")
.setDatatype("boolean")
.settable(switch1Handler);
plant1.advertise("moist").setName("Percent")
.setDatatype("number")
.setUnit("%");
plant2.advertise("switch").setName("Pump 2")
.setDatatype("boolean")
.settable(switch2Handler);
plant2.advertise("moist").setName("Percent")
.setDatatype("number")
.setUnit("%");
plant3.advertise("switch").setName("Pump 3")
.setDatatype("boolean")
.settable(switch3Handler);
plant3.advertise("moist").setName("Percent")
.setDatatype("number")
.setUnit("%");
#if (MAX_PLANTS >= 4)
plant4.advertise("moist").setName("Percent")
.setDatatype("number")
.setUnit("%");
plant5.advertise("moist").setName("Percent")
.setDatatype("number")
.setUnit("%");
plant6.advertise("moist").setName("Percent")
.setDatatype("number")
.setUnit("%");
plant0.advertise("moist").setName("Percent")
.setDatatype("number")
.setUnit("%");
#endif
sensorTemp.advertise("control")
.setName("Temperature")
.setDatatype("number")
.setUnit("°C");
sensorTemp.advertise("temp")
.setName("Temperature")
.setDatatype("number")
.setUnit("°C");
sensorLipo.advertise("percent")
.setName("Percent")
.setDatatype("number")
.setUnit("%");
sensorLipo.advertise("volt")
.setName("Volt")
.setDatatype("number")
.setUnit("V");
sensorSolar.advertise("percent")
.setName("Percent")
.setDatatype("number")
.setUnit("%");
sensorSolar.advertise("volt")
.setName("Volt")
.setDatatype("number")
.setUnit("V");
sensorWater.advertise("remaining").setDatatype("number").setUnit("%");
}
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Homie.setup();
/* Intialize inputs and outputs */
for(int i=0; i < plantCnt.get(); i++) {
pinMode(mPlants[i].getPumpPin(), OUTPUT);
pinMode(mPlants[i].getSensorPin(), ANALOG);
digitalWrite(mPlants[i].getPumpPin(), LOW);
}
/* Setup Solar and Lipo measurement */
pinMode(SENSOR_LIPO, ANALOG);
pinMode(SENSOR_SOLAR, ANALOG);
/* Read analog values at the start */
do {
readAnalogValues();
} while (readCounter != 0);
// Configure Deep Sleep:
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if (mConfigured && (deepSleepNightTime.get() > 0) &&
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( SOLAR_VOLT(solarSensor) < MINIMUM_SOLAR_VOLT)) {
Serial << "HOMIE | Setup sleeping for " << deepSleepNightTime.get() << " ms as sun is at " << SOLAR_VOLT(solarSensor) << "V" << endl;
uint64_t usSleepTime = deepSleepNightTime.get() * 1000U;
esp_sleep_enable_timer_wakeup(usSleepTime);
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}else if (mConfigured && deepSleepTime.get()) {
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Serial << "HOMIE | Setup sleeping for " << deepSleepTime.get() << " ms" << endl;
uint64_t usSleepTime = deepSleepTime.get() * 1000U;
esp_sleep_enable_timer_wakeup(usSleepTime);
}
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if (mConfigured && (ADC_5V_TO_3V3(lipoSenor) < MINIMUM_LIPO_VOLT) && (deepSleepTime.get()) ) {
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long sleepEmptyLipo = (deepSleepTime.get() * EMPTY_LIPO_MULTIPL);
Serial << "HOMIE | Change sleeping to " << sleepEmptyLipo << " ms as lipo is at " << ADC_5V_TO_3V3(lipoSenor) << "V" << endl;
esp_sleep_enable_timer_wakeup(sleepEmptyLipo * 1000U);
mDeepSleep = true;
}
esp_sleep_pd_config(ESP_PD_DOMAIN_RTC_PERIPH, ESP_PD_OPTION_OFF);
esp_sleep_pd_config(ESP_PD_DOMAIN_RTC_SLOW_MEM, ESP_PD_OPTION_ON);
esp_sleep_pd_config(ESP_PD_DOMAIN_RTC_FAST_MEM, ESP_PD_OPTION_OFF);
esp_sleep_pd_config(ESP_PD_DOMAIN_XTAL,ESP_PD_OPTION_ON);
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Serial << "DS18B20 | Initialization " << endl;
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/* Read the temperature sensors once, as first time 85 degree is returned */
Serial << "DS18B20 | sensors: " << String(dallas.readDevices()) << endl;
delay(200);
if (dallas.readAllTemperatures(pFloat, 2) > 0) {
Serial << "DS18B20 | Temperature 1: " << String(temp[0]) << endl;
Serial << "DS18B20 | Temperature 2: " << String(temp[1]) << endl;
}
delay(200);
if (dallas.readAllTemperatures(pFloat, 2) > 0) {
Serial << "Temperature 1: " << String(temp[0]) << endl;
Serial << "Temperature 2: " << String(temp[1]) << endl;
}
}
/**
* @brief Cyclic call
* Executs the Homie base functionallity or triggers sleeping, if requested.
*/
void loop() {
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if (!mDeepSleep || !mConfigured) {
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if (Serial.available() > 0) {
// read the incoming byte:
int incomingByte = Serial.read();
switch ((char) incomingByte)
{
case 'P':
Serial << "Activate Sensor OUTPUT " << endl;
pinMode(OUTPUT_SENSOR, OUTPUT);
digitalWrite(OUTPUT_SENSOR, HIGH);
break;
case 'p':
Serial << "Deactivate Sensor OUTPUT " << endl;
pinMode(OUTPUT_SENSOR, OUTPUT);
digitalWrite(OUTPUT_SENSOR, LOW);
break;
default:
break;
}
}
if ((digitalRead(BUTTON) == LOW) && (mButtonClicks % 2) == 0) {
float temp[2] = {0, 0};
float* pFloat = temp;
mButtonClicks++;
Serial << "SELF TEST (clicks: " << String(mButtonClicks) << ")" << endl;
Serial << "DS18B20 sensors: " << String(dallas.readDevices()) << endl;
delay(200);
if (dallas.readAllTemperatures(pFloat, 2) > 0) {
Serial << "Temperature 1: " << String(temp[0]) << endl;
Serial << "Temperature 2: " << String(temp[1]) << endl;
}
switch(mButtonClicks) {
case 1:
case 3:
case 5:
if (mButtonClicks > 1) {
Serial << "Read analog sensors..." << endl;
/* Disable Wifi and bluetooth */
WiFi.mode(WIFI_OFF);
delay(50);
/* now ADC2 can be used */
readSensors();
}
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Serial << "Water gone: " << String(mWaterGone) << " cm" << endl;
for(int i=0; i < MAX_PLANTS; i++) {
mPlants[i].calculateSensorValue(AMOUNT_SENOR_QUERYS);
Serial << "Moist Sensor " << (i+1) << ": " << String(mPlants[i].getSensorValue()) << " Volt: " << String(ADC_5V_TO_3V3(mPlants[i].getSensorValue())) << endl;
}
/* Read enough values */
do {
readAnalogValues();
Serial << "Read Analog (" << String(readCounter) << ")" << endl;;
} while (readCounter != 0);
Serial << "Lipo Sensor - Raw: " << String(lipoSenor) << " Volt: " << String(ADC_5V_TO_3V3(lipoSenor)) << endl;
Serial << "Solar Sensor - Raw: " << String(solarSensor) << " Volt: " << String(SOLAR_VOLT(solarSensor)) << endl;
break;
case 7:
Serial << "Activate Sensor OUTPUT " << endl;
pinMode(OUTPUT_SENSOR, OUTPUT);
digitalWrite(OUTPUT_SENSOR, HIGH);
break;
case 9:
Serial << "Activate Pump1 GPIO" << String(mPlants[0].getPumpPin()) << endl;
digitalWrite(mPlants[0].getPumpPin(), HIGH);
break;
case 11:
Serial << "Activate Pump2 GPIO" << String(mPlants[1].getPumpPin()) << endl;
digitalWrite(mPlants[1].getPumpPin(), HIGH);
break;
case 13:
Serial << "Activate Pump3 GPIO" << String(mPlants[2].getPumpPin()) << endl;
digitalWrite(mPlants[2].getPumpPin(), HIGH);
break;
case 15:
Serial << "Activate Pump4/Sensor GPIO" << String(OUTPUT_PUMP4) << endl;
digitalWrite(OUTPUT_PUMP4, HIGH);
break;
default:
Serial << "No further tests! Please reboot" << endl;
}
Serial.flush();
}else if (mButtonClicks > 0 && (digitalRead(BUTTON) == HIGH) && (mButtonClicks % 2) == 1) {
Serial << "Self Test Ended" << endl;
mButtonClicks++;
/* Always reset all outputs */
digitalWrite(OUTPUT_SENSOR, LOW);
for(int i=0; i < MAX_PLANTS; i++) {
digitalWrite(mPlants[i].getPumpPin(), LOW);
}
digitalWrite(OUTPUT_PUMP4, LOW);
} else if (mButtonClicks == 0) {
Homie.loop();
}
} else {
Serial << (millis()/ 1000) << "s running; sleeeping ..." << endl;
Serial.flush();
esp_deep_sleep_start();
}
}