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CO2_Gadget_Battery.h
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CO2_Gadget_Battery.h
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#ifndef CO2_Gadget_Battery_h
#define CO2_Gadget_Battery_h
// clang-format off
/*****************************************************************************************************/
/********* *********/
/********* SETUP BATTERY FUNCTIONALITY *********/
/********* Uses Library https://github.com/rlogiacco/BatterySense *********/
/********* *********/
/*****************************************************************************************************/
// clang-format on
float lastBatteryVoltage = 0;
uint16_t timeBetweenBatteryRead = 1;
uint64_t lastTimeBatteryRead = 0; // Time of last battery reading
const uint8_t batterySamples = 3; // Number of samples to average for battery voltage.
// Battery info (percent charge).
const uint32_t voltageDividerR1Ohms = 100000; // Resistance of "R1" for voltage divider.
const uint32_t voltageDividerR2Ohms = 100000; // Resistance of "R2" for voltage divider.
// Voltage divider ratio for battery sense must be (R1 + R2) / R2
const float voltageDividerRatio = (voltageDividerR1Ohms + voltageDividerR2Ohms) / voltageDividerR2Ohms;
#include <Battery.h>
Battery battery(batteryDischargedMillivolts, batteryFullyChargedMillivolts, ADC_BATTERY_PIN);
void initBattery() {
battery.onDemand(battery.ON_DEMAND_DISABLE, LOW);
battery.begin(vRef, voltageDividerRatio, &asigmoidal);
// Serial.println("-->[BATT***] Battery initialized with vRef: " + String(vRef) + " and voltage divider ratio: " + String(voltageDividerRatio));
}
void readBatteryVoltage() {
float batteryVoltageNow = 0;
if ((millis() - lastTimeBatteryRead >= timeBetweenBatteryRead * 1000) || (lastTimeBatteryRead == 0)) {
for (uint8_t i = 0; i < batterySamples; i++) {
batteryVoltageNow += float(battery.voltage(20)) / 1000;
delay(5);
}
batteryVoltageNow /= 3;
batteryVoltage = batteryVoltageNow;
batteryLevel = battery.level(batteryVoltage * 1000);
lastTimeBatteryRead = millis();
// If battery voltage is more than 6% of the fully charged battery voltage (~4.45V) or if battery voltage is less
// than 1V (no battery connected to sense pin), then assume that the device is working on external power.
const float workingOnExternalPowerThreshold = batteryFullyChargedMillivolts * 1.06 / 1000;
workingOnExternalPower = ((batteryVoltageNow) > workingOnExternalPowerThreshold) || (batteryVoltageNow < 1);
// workingOnExternalPower = (batteryVoltageNow * 1000 > batteryFullyChargedMillivolts + (batteryFullyChargedMillivolts * 6 / 100)) || (batteryVoltageNow < 1);
// publishMQTTLogData("-->[TFT ] Battery Level: " + String(batteryLevel) + "% Battery voltage: " + String(batteryVoltageNow) + "V External power: " + String(workingOnExternalPower));
// if (!inMenu) {
// Serial.println("-->[TFT ] Battery Level: " + String(batteryLevel) + "% Battery voltage: " + String(batteryVoltage) + "V External power: " + String(workingOnExternalPower) + " workingOnExternalPowerThreshold: " + String(workingOnExternalPowerThreshold));
// delay(20);
// }
// publishMQTTLogData("-->[TFT ] Battery Level: " + String(batteryLevel) + "% Battery voltage: " + String(batteryVoltageNow) + "V External power: " + String(workingOnExternalPower) + " workingOnExternalPowerThreshold: " + String(workingOnExternalPowerThreshold));
}
}
void batteryLoop() {
if (isDownloadingBLE) return;
readBatteryVoltage();
if (!inMenu) {
if (abs(lastBatteryVoltage - batteryVoltage) >= 0.1) { // If battery voltage changed by at least 0.1V, update battery level
// Serial.printf("-->[BATT] Battery Level: %d%%. Battery voltage changed from: %.4fV to %.4fV\n", batteryLevel, lastBatteryVoltage, batteryVoltage);
lastBatteryVoltage = batteryVoltage;
}
}
}
#endif // CO2_Gadget_Battery_h