Arduino mini pro 3.3 battery optimization code

Tommas

@sundberg84

Oh ok. I have put this in the code, so it is OK, i think. I thought that SLEEP_TIME isnt equal to powerdown, but it seems that i misunderstood.
I use your easypcb board Sundberg.... Is your battery measurement code better than this standard mysensors one?

Thank You again!

Tommas

@gohan

Dear Gohan!

Thank you! I thought that it isnt equal with this: https://www.mysensors.org/download/sensor_api_20#sleeping ....
But perhaps I misunderstood something because you says that it is the same sleep mode...

gohan

SLEEP_TIME is defined as the amount of time the node will sleep, but it is the function sleep() that actually puts the node into low power mode and that usually is at the end of loop

sundberg84

@tommas - "my" batterycode is due to a booster and a voltage divider. Its not possible to compare this to @Yveaux Vcc library which uses the internal vcc to measure battery level. This is not possible to use since you boost your VCC on the arduino. I think my code works great though for a voltage divider setup.

Tommas

Hi All!

Im near to get it work:) .
Someone could write an example openhab2 thing and item for Battery Voltage handling?

Thank you!

ghiglie

@sundberg84 said in Arduino mini pro 3.3 battery optimization code:

@tommas - "my" batterycode is due to a booster and a voltage divider. Its not possible to compare this to @Yveaux Vcc library which uses the internal vcc to measure battery level. This is not possible to use since you boost your VCC on the arduino. I think my code works great though for a voltage divider setup.

Sorry, I'm revisiting a temp/hum sensor running on battery, I lost my code so I'm back to work with this (and signing/encryption, doh!)
I think I have something similar to yours- I'm boosting the arduino and DHT voltage to 3,3v, while the antenna is directly connected. I have a voltage divider where I get the Voltage measure. Can I borrow directly your code, you think?

sundberg84

@ghiglie - you can, as long as you have the same divider... (which is the standard divider found @ mysensors website.)

//=========================
// BATTERY MEASURER
// VOLTAGE DIVIDER SETUP
// 1M, 470K divider across battery and using internal ADC ref of 1.1V
// Sense point is bypassed with 0.1 uF cap to reduce noise at that point
// ((1e6+470e3)/470e3)*1.1 = Vmax = 3.44 Volts
// 3.44/1023 = Volts per bit = 0.003363075
#define VBAT_PER_BITS 0.003363075

If not you need to recalculate,

Tommas

@tommas

Dear All!

Can I use 2xAA 1.6V NiZn battery for 3.3V arduino mini pro?

NeverDie

@tommas said in Arduino mini pro 3.3 battery optimization code:

@tommas

Dear All!

Can I use 2xAA 1.6V NiZn battery for 3.3V arduino mini pro?

Accoding to wikipedia, at 100% SOC each cell would deliver 1.85V, which is a smidge too high if running the pro mini with its voltage regulator removed. Well, actually, the pro mini would tolerate it, just maybe not the radio.

gohan

@tommas get some LiFePo4 AA and you can use a single cell

Tommas

Dear @neverdie ,
Ok, so I wont use these batteries.

Tommas

@tommas

I did a new code, and it seems that it is do the job.
My goal was, that I only send the battery voltage (percent) when:
At least one of sensor value transmission occured + The battery report time is elapsed.

What do you think about my code? IT IS NOT ONLY MY CODE and it is not clear yet Thank for @gohan , @sundberg84 and mysensors for the base.

/**
 * 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) 2013-2015 Sensnology AB
 * Full contributor list: https://github.com/mysensors/Arduino/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.
 *
 *******************************
 *
 * REVISION HISTORY
 * Version 1.0: Henrik EKblad
 * Version 1.1 - 2016-07-20: Converted to MySensors v2.0 and added various improvements - Torben Woltjen (mozzbozz)
 * 
 * DESCRIPTION
 * This sketch provides an example of how to implement a humidity/temperature
 * sensor using a DHT11/DHT-22.
 *  
 * For more information, please visit:
 * http://www.mysensors.org/build/humidity
 * 
 */
#define MY_NODE_ID 6
// Enable debug prints
#define MY_DEBUG

// Enable and select radio type attached 
#define MY_RADIO_NRF24
//#define MY_RADIO_RFM69
//#define MY_RS485

#include <MySensors.h>  
#include <Wire.h>
#include <SI7021.h>
#include <SPI.h>
#include <RunningAverage.h>
#include <BH1750.h> //BH1750
#include <Math.h>
#define DEBUG

#ifdef DEBUG
#define DEBUG_SERIAL(x) Serial.begin(x)
#define DEBUG_PRINT(x) Serial.print(x)
#define DEBUG_PRINTLN(x) Serial.println(x)
#else
#define DEBUG_SERIAL(x)
#define DEBUG_PRINT(x) 
#define DEBUG_PRINTLN(x) 
#endif

#define NODE_ID 6             // <<<<<<<<<<<<<<<<<<<<<<<<<<<   Enter Node_ID
#define CHILD_ID_TEMP 0
#define CHILD_ID_HUM 1
#define CHILD_ID_LIGHT 2 //BH1750
#define CHILD_ID_VBAT 254

/*BATTERY*/
// BATTERY MEASURER
// VOLTAGE DIVIDER SETUP
// 1M, 470K divider across battery and using internal ADC ref of 1.1V
// Sense point is bypassed with 0.1 uF cap to reduce noise at that point
// ((1e6+470e3)/470e3)*1.1 = Vmax = 3.44 Volts
// 3.44/1023 = Volts per bit = 0.003363075
#define VBAT_PER_BITS 0.003363075
#define VMIN 2.1                                  //  Vmin (radio Min Volt)=1.9V (564v)
#define VMAX 3.1                                  //  Vmax = (2xAA bat)=3.0V (892v)
int batteryPcnt = 0;                              // Calc value for battery %
int battAveragePcnt;
int battSumPcnt = 0; 
int BATTERY_SENSE_PIN = A0;                       // select the input pin for the battery sense point
float VbatAverage=0;
float VbatSum=0;
//=========================
/*BATTERY*/

//#define SLEEP_TIME 180000   // 3 min
//#define FORCE_TRANSMIT_CYCLE 10  // SLEEP_TIME*FORCE_TRANSMIT_CYCLE=Mindenképp küldi az értéket (Temp+HUM), különben akkor ha HUMI_TRANSMIT_THRESHOLD vagy TEMP_TRANSMIT_THRESHOLD igaz, 
//#define BATT_MEASURE_CYCLE 10   // SLEEP_TIME/1000*BATTERY_Measure_CYCLE=Ennyi időnként Veszünk mintát (BATTERY)
//#define BATT_REPORT_CYCLE 15   // SLEEP_TIME/1000*BATTERY_REPORT_CYCLE=Ennyi időnként küldi az értéket (BATTERY)
#define SLEEP_TIME 300000   // 15sec
#define FORCE_TRANSMIT_CYCLE 24  // 30sec SLEEP_TIME*FORCE_TRANSMIT_CYCLE=Mindenképp küldi az értéket (Temp+HUM), különben akkor ha HUMI_TRANSMIT_THRESHOLD vagy TEMP_TRANSMIT_THRESHOLD igaz, 
#define BATT_MEASURE_CYCLE 2   // Hányszor vegyünk mintát a küldés előtt
#define BATT_REPORT_CYCLE 60     // SLEEP_TIME/1000*BATTERY_REPORT_CYCLE*2=Ennyi időnként küldi az értéket (BATTERY)
#define HUMI_TRANSMIT_THRESHOLD 3.0  // THRESHOLD tells how much the value should have changed since last time it was transmitted.
#define TEMP_TRANSMIT_THRESHOLD 0.5
#define LUX_TRANSMIT_THRESHOLD 10
#define AVERAGES 2

int measureCount = 0;
int battreportCount=-2;
float lastTemperature = -100;
int lastHumidity = -100;
int lastLux = 0; //BH1750
boolean transmission_occured = false;
RunningAverage raHum(AVERAGES);
SI7021 humiditySensor;
BH1750 lightSensor;

//MySensor gw;
MyMessage msgTemp(CHILD_ID_TEMP,V_TEMP); // Initialize temperature message
MyMessage msgHum(CHILD_ID_HUM,V_HUM);
MyMessage msgLight(CHILD_ID_LIGHT, V_LIGHT_LEVEL); //BH1750
MyMessage msgVBat(CHILD_ID_VBAT, V_VOLTAGE); //BH1750


void presentation(){

sendSketchInfo("Node 6, Temp,Hum,Light", "1.1"); 
  present(CHILD_ID_TEMP, S_TEMP);   // Present sensor to controller
  present(CHILD_ID_HUM, S_HUM);
  present(CHILD_ID_LIGHT, S_LIGHT_LEVEL); //BH1750
  present(CHILD_ID_VBAT, S_MULTIMETER); //BH1750
}


void setup() {

  DEBUG_SERIAL(115200);    
  DEBUG_PRINTLN("Serial started");

  delay(500); // Allow time for radio if power useed as reset
  
  raHum.clear();
  lightSensor.begin(); //BH1750

  
  /*BATTERY*/
   //=========================
  // BATTERY MEASURER
  //Set internal ref to internal to be able to measure bat 0-1v
  //Make sure this fits other sensors using analogRead()! 
  //If you have a sensor reporting 0-5v you need to change analogReference() before reading that sensor.
  
  analogReference(INTERNAL);
  //DEFAULT: the default analog reference of 5 volts (on 5V Arduino boards) or 3.3 volts (on 3.3V Arduino boards)
  //INTERNAL: an built-in reference, equal to 1.1 volts on the ATmega168 or ATmega328 and 2.56 volts on the ATmega8 (not available on the Arduino Mega)
  //EXTERNAL: the voltage applied to the AREF pin (0 to 5V only) is used as the reference.
  
  //Battery inital calc
  Serial.print("With Battery VMax (100%) = "); Serial.print(VMAX); Serial.print("volts and Vmin (0%) = "); Serial.print(VMIN); Serial.println(" volts");
  Serial.print("Battert Percent 25%/50%/75% should be: "); Serial.print(((VMAX - VMIN) / 4) + VMIN); Serial.print("/"); Serial.print(((VMAX - VMIN) / 2) + VMIN); Serial.print("/"); Serial.println(VMAX - ((VMAX - VMIN) / 4));
  delay(500);
  int sensorValue = analogRead(BATTERY_SENSE_PIN);
  delay(50);
  float Vbat  = sensorValue * VBAT_PER_BITS;
  int batteryPcnt = static_cast<int>(((Vbat - VMIN) / (VMAX - VMIN)) * 100.);
  Serial.print("Current battery are measured to (please confirm!): "); Serial.print(batteryPcnt); Serial.print(" % - Or "); Serial.print(Vbat); Serial.println(" Volts");
  //=========================
  /*BATTERY*/
}

void loop() {
  DEBUG_PRINTLN("Loop started"); 
  boolean forceTransmit = false;
  transmission_occured = false;
  battreportCount ++;
  measureCount ++;
  forceTransmit = false;
  
  if (measureCount == FORCE_TRANSMIT_CYCLE) {
  forceTransmit = true;
  measureCount = 0;
  }
  
  sendTempHumidityMeasurements(forceTransmit);
  sendLightMeasurements(forceTransmit);

  Serial.print("battreportCount");Serial.println(battreportCount);
    /*BATTERY*/
    //=========================
    // BATTERY MEASURER
    if(((transmission_occured) && (battreportCount>=BATT_REPORT_CYCLE)) || (battreportCount == -1)){
            Serial.print("----BATTERY SEND/Measure CYCLE---- ");
            MeasureBattery();
            send(msgVBat.set(VbatAverage, 3));
            sendBatteryLevel(battAveragePcnt);
            Serial.print("Battery Average (Send): "); Serial.print(battAveragePcnt); Serial.println(" %");
            Serial.print("Battery Average Voltage (Send): "); Serial.print(VbatAverage); Serial.println(" V");
            battreportCount=0; 
            battAveragePcnt=0;
            VbatAverage=0;
            VbatSum=0;
            battSumPcnt=0;
            measureCount=0;
            }
  //=========================
  /*BATTERY*/
  
  DEBUG_PRINTLN("Loop ended");
  sleep(SLEEP_TIME);
}
/*********************************************
 * * Sends temperature and humidity from Si7021 sensor
 * Parameters
 * - force : Forces transmission of a value (even if it's the same as previous measurement)
 *********************************************/
void sendTempHumidityMeasurements(bool force) {
  bool tx = force;
  DEBUG_PRINTLN("Send TEMP and HUM started"); 
  si7021_env data = humiditySensor.getHumidityAndTemperature();
  float temperature = data.celsiusHundredths / 100.0;
  DEBUG_PRINT("T: ");DEBUG_PRINTLN(temperature);
  float diffTemp = abs(lastTemperature - temperature);
  DEBUG_PRINT(F("TempDiff :"));DEBUG_PRINTLN(diffTemp);
  if (diffTemp > TEMP_TRANSMIT_THRESHOLD || tx) {
    send(msgTemp.set(temperature, 1));
    lastTemperature = temperature;
    DEBUG_PRINTLN("TEMP sent!");
    transmission_occured = true;
   
    }
  
  int humidity = data.humidityPercent;
  DEBUG_PRINT("H: ");DEBUG_PRINTLN(humidity);
  raHum.addValue(humidity);
  humidity = raHum.getAverage();  // MA sample imply reasonable fast sample frequency
  float diffHum = abs(lastHumidity - humidity);  
  DEBUG_PRINT(F("HumDiff  :"));DEBUG_PRINTLN(diffHum); 
  if (diffHum > HUMI_TRANSMIT_THRESHOLD || tx) {
    send(msgHum.set(humidity, 1));
    lastHumidity = humidity;
    DEBUG_PRINTLN("HUM sent!");
    transmission_occured = true;
    
    }

}

//BH1750
void sendLightMeasurements(bool force){
    bool tx = force;
    int lux = lightSensor.readLightLevel();// Get Lux value
    float diffLux = abs(lastLux - lux);
    //Serial.println(lux);
    DEBUG_PRINT("LUX: ");DEBUG_PRINTLN(lux);
    DEBUG_PRINT("LuxDiff: ");DEBUG_PRINTLN(diffLux);
    if (diffLux > LUX_TRANSMIT_THRESHOLD || tx) {
      send(msgLight.set(lux));
      lastLux = lux;
      DEBUG_PRINTLN("LUX sent!");
      transmission_occured = true;
      }
}
//BH1750

/*BATTERY*/
//=========================
// BATTERY MEASURER
void MeasureBattery() //The battery calculations
{
  
  
  
 if (batteryPcnt > 100) {
     batteryPcnt = 100;
    }
      for (int i = 1 ; i <= BATT_MEASURE_CYCLE; i++)
      {
        delay(500);
        // Battery monitoring reading
        int sensorValue = analogRead(BATTERY_SENSE_PIN);
        delay(500);
        // Calculate the battery in %
        float Vbat  = sensorValue * VBAT_PER_BITS;
        int batteryPcnt = static_cast<int>(((Vbat - VMIN) / (VMAX - VMIN)) * 100.);
        Serial.print("I: ");Serial.println(i);
        Serial.print("Battery percent: "); Serial.print(batteryPcnt); Serial.print(" %"); Serial.print("Battery Voltage: "); Serial.print(Vbat); Serial.println(" Volts");
        battSumPcnt += batteryPcnt;
        Serial.print("battSumPcnt:::");Serial.println(battSumPcnt);
        battAveragePcnt = battSumPcnt / i;
        VbatSum += Vbat;
        VbatAverage = VbatSum / i;
        Serial.print("battAveragePcnt Calculated: ");Serial.println(battAveragePcnt);
        
      }
    }
//=========================
/*BATTERY*/

Tommas

@tommas

Should I use any other sleep "code"? How I know that the nrf24L01 go to sleep?

Tommas

@gohan said in Arduino mini pro 3.3 battery optimization code:

LiFePo4 AA

THank You! I will try!

gohan

@tommas said in Arduino mini pro 3.3 battery optimization code:

@tommas

Should I use any other sleep "code"? How I know that the nrf24L01 go to sleep?

If you measure current while the node is sleeping, if it is in the range 6 to 20 uA you are good

Tommas

@gohan said in Arduino mini pro 3.3 battery optimization code:

loop

What kind of sleep is it? There are parameters out there. ADC_OFF and some and some... Is this sleep turn off adc?

gohan

Just use the sleep () function, that's it

Tommas

@gohan

Ok! After the "loop ended " the node should go to sleep. On the console I see these lines:
Loop ended
62763 MCO:SLP:MS=300000,SMS=0,I1=255,M1=255,I2=255,M2=255
62773 MCO:SLP:TPD

What does it mean?

korttoma

@tommas said in Arduino mini pro 3.3 battery optimization code:

@gohan

Ok! After the "loop ended " the node should go to sleep. On the console I see these lines:
Loop ended
62763 MCO:SLP:MS=300000,SMS=0,I1=255,M1=255,I2=255,M2=255
62773 MCO:SLP:TPD

What does it mean?

Log Parser is your friend ;)

Tommas

@korttoma

Thank you very much, and sorry....