Control of step down

flopp

@AWI
Thanks, looks good.

Will order and test.

flopp

I now have another problem.
Same sketch but different problem.

If a use a digital output, I do not have any resistor connected to the digital pin, to enable/disable TLV.

My problem is when I connect pins for I2C(sda and scl) current for whole project goes up to ~300uA if I disconnect SDA it goes down to ~150uA and disconnect SCL it goes down to ~10uA. 10uA is what I have on other project without I2C

Very strange for me. It tried to put a 10k between GND and Enable pin on TLV, same current.

Any ideas.

Can it help with internal pull-up? I am not home right now so I can't try that right now

AWI

@flopp Sounds like problems with (internal) pull-ups and signal levels. Can you post the sketch and your design?

flopp

@AWI
Lots of code that I don't use, I have not clean up yet.

/**
* 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
* 
* DESCRIPTION
* Pressure sensor example using BMP085 module 
* http://www.mysensors.org/build/pressure
*
*/

#include <SPI.h>
#include <MySensor.h> 
#include <Wire.h>
#include <Adafruit_BMP085.h>
#include <SI7021.h>

#define NODE_ID 3 
#define BARO_CHILD 0
#define TEMP_CHILD 1
#define BATT_CHILD 2
#define HUM_CHILD 3

const float ALTITUDE = 8; // <-- adapt this value to your own location's altitude.

// Sleep time between reads (in seconds). Do not change this value as the forecast algorithm needs a sample every minute.
const unsigned long SLEEP_TIME = 1795000;//1795000=30 min

/*const char *weather[] = { "stable", "sunny", "cloudy", "unstable", "thunderstorm", "unknown" };
enum FORECAST
{
STABLE = 0,	// "Stable Weather Pattern"
SUNNY = 1,	// "Slowly rising Good Weather", "Clear/Sunny "
CLOUDY = 2,	// "Slowly falling L-Pressure ", "Cloudy/Rain "
UNSTABLE = 3,	// "Quickly rising H-Press", "Not Stable"
THUNDERSTORM = 4,	// "Quickly falling L-Press", "Thunderstorm"
UNKNOWN = 5	// "Unknown (More Time needed)
};
*/

Adafruit_BMP085 bmp = Adafruit_BMP085(); // Digital Pressure Sensor 

//int BATTERY_SENSE_PIN = A0; // select the input pin for the battery sense point
//int oldBatteryPcnt = 0;
long result;

MySensor gw;

SI7021 sensor;

int humidity;

//float lastPressure = -1;
//float lastTemp = -1;
//int lastForecast = -1;

//const int LAST_SAMPLES_COUNT = 5;
//float lastPressureSamples[LAST_SAMPLES_COUNT];

float batteryPcnt;
float batteryVolt;
//int cycle=6;

// this CONVERSION_FACTOR is used to convert from Pa to kPa in forecast algorithm
// get kPa/h be dividing hPa by 10 
//#define CONVERSION_FACTOR (1.0/10.0)

//int minuteCount = 0;
//bool firstRound = true;
// average value is used in forecast algorithm.
//float pressureAvg;
// average after 2 hours is used as reference value for the next iteration.
//float pressureAvg2;

float dP_dt;
float temperature;
boolean metric;
MyMessage tempMsg(TEMP_CHILD, V_TEMP);
MyMessage pressureMsg(BARO_CHILD, V_PRESSURE);
//MyMessage forecastMsg(BARO_CHILD, V_FORECAST);
MyMessage battMsg(BATT_CHILD, V_VOLTAGE);
MyMessage humMsg(HUM_CHILD, V_HUM);

void setup() 
{
pinMode(6,OUTPUT);
digitalWrite(6,HIGH);
/*
// use the 1.1 V internal reference
#if defined(__AVR_ATmega2560__)
analogReference(INTERNAL1V1);
#else
analogReference(INTERNAL);
#endif
*/
sensor.begin();
gw.begin(NULL,NODE_ID);

// Send the sketch version information to the gateway and Controller
gw.sendSketchInfo("Mini Weather", "1.0");

if (!bmp.begin()) 
{
Serial.println("Could not find a valid BMP085 sensor, check wiring!");
//while (1) {}
}

// Register sensors to gw (they will be created as child devices)
gw.present(BARO_CHILD, S_BARO);
gw.present(TEMP_CHILD, S_TEMP);
gw.present(BATT_CHILD, S_MULTIMETER);
gw.present(HUM_CHILD, S_HUM);
metric = gw.getConfig().isMetric;


}

void loop() 
{
Serial.println("start");
digitalWrite(6,HIGH);
delay(1000);
gw.begin(NULL,NODE_ID);
/*
// get the battery Voltage
int sensorValue = analogRead(BATTERY_SENSE_PIN);
#ifdef DEBUG
Serial.println(sensorValue);
#endif

// 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
// ((305400+100000)/100000)*1.1 = Vmax = 4.46 Volts
// 3.44/1023 = Volts per bit = 0.003363075
// 4.46/1023 = Volts per bit = 0.0043591398
//float batteryV = sensorValue * 0.004359140;
float batteryV = sensorValue * 4.2 / 1023;
int batteryPcnt = sensorValue / 10;

#ifdef DEBUG
Serial.print("Battery Voltage: ");
Serial.print(batteryV);
Serial.println(" V");

Serial.print("Battery percent: ");
Serial.print(batteryPcnt);
Serial.println(" %");
#endif
*/ 
int pressure = bmp.readSealevelPressure(ALTITUDE) / 100.0;
//	float temperature = bmp.readTemperature();



//	int forecast = sample(pressure);

//	Serial.print("Temperature = ");
//	Serial.print(temperature);
//	Serial.println(metric ? " *C" : " *F");

//Serial.print("Forecast = ");
//Serial.println(weather[forecast]);

si7021_thc data = sensor.getTempAndRH();

temperature = data.celsiusHundredths/100.0;

humidity = data.humidityPercent;

Serial.print("humidity:");
Serial.print(humidity);
Serial.println("%");
Serial.print("Pressure = ");
Serial.print(pressure);
Serial.println(" hPa");
Serial.print("temperature:");
Serial.print(temperature);
Serial.println("°");


/*if (temperature != lastTemp) 
{
gw.send(tempMsg.set(temperature, 1));
lastTemp = temperature;
delay(100);
}

if (pressure != lastPressure) 
{
gw.send(pressureMsg.set(pressure, 0));
lastPressure = pressure;
delay(100);
}

/*if (forecast != lastForecast)
{
gw.send(forecastMsg.set(weather[forecast]));
lastForecast = forecast;
delay(100);
}
*/
readVcc();
gw.sendBatteryLevel(batteryPcnt);
gw.send(battMsg.set(batteryVolt, 3));

gw.send(tempMsg.set(temperature, 1));
//lastTemp = temperature;

gw.send(pressureMsg.set(pressure, 0));
//lastPressure = pressure;

//gw.send(forecastMsg.set(weather[forecast]));
//lastForecast = forecast;

gw.send(humMsg.set(humidity, 0));

delay(100);
//cycle=0;

digitalWrite(6,LOW);
Serial.println("sleep");
delay(1000);
//cycle++;
gw.sleep(SLEEP_TIME);
}

/*float getLastPressureSamplesAverage()
{
float lastPressureSamplesAverage = 0;
for (int i = 0; i < LAST_SAMPLES_COUNT; i++)
{
lastPressureSamplesAverage += lastPressureSamples[i];
}
lastPressureSamplesAverage /= LAST_SAMPLES_COUNT;

return lastPressureSamplesAverage;
}



// Algorithm found here
// http://www.freescale.com/files/sensors/doc/app_note/AN3914.pdf
// Pressure in hPa --> forecast done by calculating kPa/h
int sample(float pressure)
{
// Calculate the average of the last n minutes.
int index = minuteCount % LAST_SAMPLES_COUNT;
lastPressureSamples[index] = pressure;

minuteCount++;
if (minuteCount > 185)
{
minuteCount = 6;
}

if (minuteCount == 5)
{
pressureAvg = getLastPressureSamplesAverage();
}
else if (minuteCount == 35)
{
float lastPressureAvg = getLastPressureSamplesAverage();
float change = (lastPressureAvg - pressureAvg) * CONVERSION_FACTOR;
if (firstRound) // first time initial 3 hour
{
dP_dt = change * 2; // note this is for t = 0.5hour
}
else
{
dP_dt = change / 1.5; // divide by 1.5 as this is the difference in time from 0 value.
}
}
else if (minuteCount == 65)
{
float lastPressureAvg = getLastPressureSamplesAverage();
float change = (lastPressureAvg - pressureAvg) * CONVERSION_FACTOR;
if (firstRound) //first time initial 3 hour
{
dP_dt = change; //note this is for t = 1 hour
}
else
{
dP_dt = change / 2; //divide by 2 as this is the difference in time from 0 value
}
}
else if (minuteCount == 95)
{
float lastPressureAvg = getLastPressureSamplesAverage();
float change = (lastPressureAvg - pressureAvg) * CONVERSION_FACTOR;
if (firstRound) // first time initial 3 hour
{
dP_dt = change / 1.5; // note this is for t = 1.5 hour
}
else
{
dP_dt = change / 2.5; // divide by 2.5 as this is the difference in time from 0 value
}
}
else if (minuteCount == 125)
{
float lastPressureAvg = getLastPressureSamplesAverage();
pressureAvg2 = lastPressureAvg; // store for later use.
float change = (lastPressureAvg - pressureAvg) * CONVERSION_FACTOR;
if (firstRound) // first time initial 3 hour
{
dP_dt = change / 2; // note this is for t = 2 hour
}
else
{
dP_dt = change / 3; // divide by 3 as this is the difference in time from 0 value
}
}
else if (minuteCount == 155)
{
float lastPressureAvg = getLastPressureSamplesAverage();
float change = (lastPressureAvg - pressureAvg) * CONVERSION_FACTOR;
if (firstRound) // first time initial 3 hour
{
dP_dt = change / 2.5; // note this is for t = 2.5 hour
}
else
{
dP_dt = change / 3.5; // divide by 3.5 as this is the difference in time from 0 value
}
}
else if (minuteCount == 185)
{
float lastPressureAvg = getLastPressureSamplesAverage();
float change = (lastPressureAvg - pressureAvg) * CONVERSION_FACTOR;
if (firstRound) // first time initial 3 hour
{
dP_dt = change / 3; // note this is for t = 3 hour
}
else
{
dP_dt = change / 4; // divide by 4 as this is the difference in time from 0 value
}
pressureAvg = pressureAvg2; // Equating the pressure at 0 to the pressure at 2 hour after 3 hours have past.
firstRound = false; // flag to let you know that this is on the past 3 hour mark. Initialized to 0 outside main loop.
}

int forecast = UNKNOWN;
if (minuteCount < 35 && firstRound) //if time is less than 35 min on the first 3 hour interval.
{
forecast = UNKNOWN;
}
else if (dP_dt < (-0.25))
{
forecast = THUNDERSTORM;
}
else if (dP_dt > 0.25)
{
forecast = UNSTABLE;
}
else if ((dP_dt > (-0.25)) && (dP_dt < (-0.05)))
{
forecast = CLOUDY;
}
else if ((dP_dt > 0.05) && (dP_dt < 0.25))
{
forecast = SUNNY;
}
else if ((dP_dt >(-0.05)) && (dP_dt < 0.05))
{
forecast = STABLE;
}
else
{
forecast = UNKNOWN;
}

// uncomment when debugging
//Serial.print(F("Forecast at minute "));
//Serial.print(minuteCount);
//Serial.print(F(" dP/dt = "));
//Serial.print(dP_dt);
//Serial.print(F("kPa/h --> "));
//Serial.println(weather[forecast]);

return forecast;
}
*/
long readVcc() {

// Read 1.1V reference against AVcc
ADMUX = _BV(REFS0) | _BV(MUX3) | _BV(MUX2) | _BV(MUX1);
delay(2); // Wait for Vref to settle
ADCSRA |= _BV(ADSC); // Convert
while (bit_is_set(ADCSRA,ADSC));
result = ADCL;
result |= ADCH<<8;
result = 1126400L / result; // Back-calculate AVcc in mV
//return result;
batteryPcnt = (result - 3300) * 0.111111;
batteryVolt = result/1000.000;
/*Serial.print("battery volt:");
Serial.println(batteryVolt, 3);
Serial.print("battery percent:");
Serial.println(batteryPcnt);
*/
}```

AWI

@flopp and your circuit? Which are your I2C devices and do you power them down while sleeping?

flopp

@AWI

mysensorsboard_nocharge.pdf

BMP180 and Si7021. Yes, I set LOW on digital 6, so TLV is powered down, right before SLEEP

flopp

@AWI
Added PDF

AWI

@flopp I cannot find it in the datasheets but I can imagine that the BMP180 and/or si7021 kind of "short" their inputs to ground when power drops to down to Grnd. This would connect the pullups to grn explaining the rise in consumption. Both these sensors take around 0.1 uA in standby so I don't see a need to power them down.

flopp

@AWI

Thanks for you time.
I have also NRF connected to TLV, so I power down that one also.

If I don't power down my project draw ~60 uA, which I can live with but when power down it will be ~10 uA, that is 1/6.
I run on battery so that is something I want to be able to do.

I will try to have only BMP180 and also test to only have Si7021.

AWI

@flopp One of my nodes, equipped with the same sensors (si7021/ bmp180 and nrf) including the electronics (LDO level conversion etc.) on the sensor boards is consuming around 12uA during sleep. The sensors are all powered from the same LDO (662k).

flopp

@AWI
Thank again.

I found one 662K at home.

Now it draws ~19uA with everything connected: arduino pro mini(clone), NRF, si7021 and bmp180(without 662k) This is good enough.