weatherstation/firmware/firmware.ino

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// Standard ESP8266 libs from project folder
#include <ESP8266mDNS.h>
#include <ESP8266HTTPUpdateServer.h>
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#include <ESP8266WiFi.h>
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#include <DNSServer.h>
#include <ESP8266WebServer.h>
#include <ESP8266HTTPClient.h>
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#include <WiFiClient.h> // WiFiClient
#include <WiFiManager.h> // WiFiManager from bib manager
// Project includes
#include "constants.h"
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#include "config.h"
#include "config_user.h"
//*************************************************************************//
// check if some settings are correct
#ifdef HTTP_CALL_ON_WINDSPEED_EXCEED
#if (HTTP_CALL_ON_WINDSPEED_INTERVAL_S < WIND_SENSOR_MEAS_TIME_S)
#error "HTTP_CALL_ON_WINDSPEED_INTERVAL_S < WIND_SENSOR_MEAS_TIME_S"
#endif
#endif
//*************************************************************************//
// constant variables
const uint8_t VALUES = 8;
float currentSensorData[VALUES] = {nanf("no value"), nanf("no value"), nanf("no value"), nanf("no value"), nanf("no value"), nanf("no value"), nanf("no value"), nanf("no value")};
float (*sensors[VALUES])() = {};
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uint16_t update_sensor_cnt = 0;
uint16_t update_webserver_cnt = 0;
uint16_t update_windspeed_exceed_cnt = 0;
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WiFiManager wifiManager;
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//*************************************************************************//
void debug(String x)
{
#ifdef DEBUG
Serial.println(x);
#endif
}
void setup()
{
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#if defined(DEBUG) || defined(SERIAL_FEATURE)
Serial.begin(115200);
#endif
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// Pin settings
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pinMode(BAT_CHARGED_PIN, INPUT);
pinMode(BAT_CHARGING_PIN, INPUT);
pinMode(STATUS_LED_PIN, OUTPUT);
pinMode(ANEMOMETER_PIN, INPUT_PULLUP);
pinMode(A0, INPUT);
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digitalWrite(STATUS_LED_PIN, LOW);
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#ifndef BAT_PINS_D34
debug("D5 D6 used as battery pins");
#else
debug("D3 D4 used as battery pins");
#endif
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#ifdef BATTERY_POWERED
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criticalBatCheck();
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#endif
// Establish WiFi connection
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String wifiName = "oko-weather-" + DEVICE_NAME;
wifiManager.setMinimumSignalQuality(WIFI_MINIMUM_SIGNAL_QUALITY);
// the time in seconds to wait for the known wifi connection
wifiManager.setConnectTimeout(WIFI_AUTOCONNECT_TIMEOUT_S);
// the time in seconds to wait for the user to configure the device
wifiManager.setTimeout(WIFI_CONFIG_PORTAL_TIMEOUT_S);
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while (!wifiManager.autoConnect(wifiName.c_str(), "DEADBEEF"))
{
debug("WiFi connection failed, try again in 5 seconds...");
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// If autoconnect to WLAN failed and no client connected, go to deep sleep
#ifdef SLEEP_IF_NO_WLAN_CONNECTION
ESP.deepSleep(POWERSAVING_SLEEP_S * 1000000, WAKE_RF_DEFAULT);
delay(100);
#endif
#ifndef SLEEP_IF_NO_WLAN_CONNECTION
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// sleep a few seconds and go on trying to connect
delay(5000);
#endif
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}
debug("Connected!");
#ifdef INFLUXDB_FEATURE
influxdb_begin();
#endif
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// Initialize and configure the sensors
#ifdef SENSOR_APDS9930
if (sensor_apds9930_begin()) {
sensors[SENSOR_LIGHT] = &apds9930_light;
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}
#endif
#ifdef SENSOR_APDS9960
if (sensor_apds9960_begin()) {
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sensors[SENSOR_LIGHT] = &apds9960_light;
}
#endif
#ifdef SENSOR_BME280
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//Temperature + pressure
if (sensor_bme280_begin(BME_ADDRESS)) {
sensors[SENSOR_TEMPERATURE] = &bme280_temperature;
sensors[SENSOR_HUMIDITY] = &bme280_humidity;
sensors[SENSOR_PRESSURE] = &bme280_pressure;
}
#endif
#ifdef SENSOR_WIND
sensors[SENSOR_WINDSPEED] = &wind_speed;
#endif
#ifdef SENSOR_BATTERY
sensors[SENSOR_BAT_VOLTAGE] = &battery_voltage;
sensors[SENSOR_BATCHARGESTATE] = &battery_charging;
sensors[SENSOR_ESAVEMODE] = &isEnergySavingMode;
#endif
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#ifdef WEBUPDATER_FEATURE
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#ifndef BATTERY_POWERED
setupWebUpdater(DEVICE_NAME, WiFi.localIP().toString());
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#endif
#endif
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//It's magic! leave in
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delay(100);
#ifdef RESET_ESP_TIMEINTERVAL
// if millis() reached interval (1h) restart ESP
if (millis() >= RESET_ESP_TIME_INTERVAL_MS)
{
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debug("Resetting firmware intentionally");
// Push reset button after flashing once or do a manual power cycle to get the functionality working.
ESP.restart();
}
#endif
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#ifdef BATTERY_POWERED
debug("battery powered");
_loop();
digitalWrite(STATUS_LED_PIN, LOW);
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criticalBatCheck();
WiFi.mode(WIFI_OFF);
WiFi.forceSleepBegin();
debug("deep sleep");
// the ESP.deepSleep requires microseconds as input, after the sleep the system will run into the setup routine
ESP.deepSleep(POWERSAVING_SLEEP_S * 1000000, WAKE_RF_DEFAULT);
delay(100);
#endif
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}
//*************************************************************************//
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#ifdef BATTERY_POWERED
void criticalBatCheck()
{
float volt = battery_voltage();
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if (volt <= BAT_EMERGENCY_DEEPSLEEP_VOLTAGE) {
debug("Bat Voltage: " + String(volt) + " V");
debug("Low battery, going into deep sleep.");
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// Casting to an unsigned int, so it fits into the integer range
ESP.deepSleep(1U * EMERGENCY_SLEEP_S * 1000000); // battery low, shutting down
delay(100);
}
}
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#endif
void loop()
{
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#ifdef BATTERY_POWERED
delay(50);
return;
#endif
// call sub loop function
_loop();
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//Needed to give WIFI time to function properly
delay(DELAY_LOOP_MS);
update_sensor_cnt++;
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#ifdef WEBUPDATER_FEATURE
update_webserver_cnt++;
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#endif
#ifdef HTTP_CALL_ON_WINDSPEED_EXCEED
update_windspeed_exceed_cnt++;
#endif
}
void _loop() {
#ifdef WEBUPDATER_FEATURE
if (UPDATE_WEBSERVER_INTVERVAL_S * 1000 / DELAY_LOOP_MS <= update_webserver_cnt)
{
update_webserver_cnt = 0;
doWebUpdater();
}
#endif
#ifdef HTTP_CALL_ON_WINDSPEED_EXCEED
if (HTTP_CALL_ON_WINDSPEED_INTERVAL_S * 1000 / DELAY_LOOP_MS <= update_windspeed_exceed_cnt)
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{
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debug("Reading wind sensor because of exceed call functionality");
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if (sensors[SENSOR_WINDSPEED])
{
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// read from windspeed sensorSTATUS_LED_PIN
digitalWrite(STATUS_LED_PIN, HIGH);
currentSensorData[SENSOR_WINDSPEED] = sensors[SENSOR_WINDSPEED]();
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digitalWrite(STATUS_LED_PIN, LOW);
if (currentSensorData[SENSOR_WINDSPEED] >= HTTP_CALL_ON_WINDSPEED_EXCEED_MPS)
{
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digitalWrite(STATUS_LED_PIN, HIGH);
// call the url HTTP_CALL_ON_WINDSPEED_URL
WiFiClient client;
HTTPClient http;
http.begin(client, String(HTTP_CALL_ON_WINDSPEED_URL).c_str());
// Send HTTP GET request
int httpResponseCode = http.GET();
if (httpResponseCode > 0) {
String response = http.getString();
#ifdef DEBUG
Serial.println("http response code: " + String(httpResponseCode) + " = " + response);
#endif
// TODO handle response
}
http.end();
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debug("Called windspeed exceed callout");
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digitalWrite(STATUS_LED_PIN, LOW);
}
} else {
currentSensorData[SENSOR_WINDSPEED] = nan("no value");
}
update_windspeed_exceed_cnt = 0;
}
#endif
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#ifndef BATTERY_POWERED
if (UPDATE_SENSOR_INTERVAL_S * 1000 / DELAY_LOOP_MS > update_sensor_cnt) {
return;
}
#endif
#ifdef defined(BATTERY_POWERED) && defined(SENSOR_WIND)
if (energySavingMode() == 1) {
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// Disable expensive tasks
sensors[SENSOR_WINDSPEED] = 0;
} else {
sensors[SENSOR_WINDSPEED] = &wind_speed;
}
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#endif
update_sensor_cnt = 0;
for (uint8_t i = 0; i < VALUES; i++) {
if (sensors[i]) {
currentSensorData[i] = sensors[i]();
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} else {
currentSensorData[i] = nan("no value");
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}
}
#ifdef SERIAL_FEATURE
logToSerial(currentSensorData);
#endif
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delay(100);
#ifdef INFLUXDB_FEATURE
pushToInfluxDB(DEVICE_NAME, currentSensorData);
#endif
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#ifdef WEBUPDATER_FEATURE
setSensorData(currentSensorData);
#endif
}
void logToSerial(float sensorValues[]) {
Serial.println("");
Serial.println("Current readings:");
Serial.println("Temperature: " + String(sensorValues[SENSOR_TEMPERATURE]) + " °C");
Serial.println("Humidity: " + String(sensorValues[SENSOR_HUMIDITY]) + " %");
Serial.println("Light: " + String(sensorValues[SENSOR_LIGHT]) + " Lux");
Serial.println("Windspeed: " + String(sensorValues[SENSOR_WINDSPEED]) + " km/h");
Serial.println("Pressure: " + String(sensorValues[SENSOR_PRESSURE]) + " hPa");
Serial.println("Bat Voltage: " + String(sensorValues[SENSOR_BAT_VOLTAGE]) + " V");
Serial.println("Bat charge state: " + String(sensorValues[SENSOR_BATCHARGESTATE]));
Serial.println("Energy saving: " + String(sensorValues[SENSOR_ESAVEMODE]));
}