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PressureSensor-c.ino
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PressureSensor-c.ino
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/*
Arduino Pressure sensor based on BMP085
Requires Lib BMP085 V2
https://github.com/adafruit/Adafruit_BMP085_Unified
https://github.com/adafruit/Adafruit_Sensor
Contribution: epierre
G GND
V VCC 5V/3.3V
SCL A4
SDA A5
*/
#include <MySensor.h>
#include <SPI.h>
#include <Wire.h>
#include <Adafruit_Sensor.h>
#include <Adafruit_BMP085_U.h>
//float seaLevelPressure = 1013;
float myAltitude = 45;
#define LTC4067_CHRG_PIN A1 //analog input A1 on ATmega 328 is /CHRG signal from LTC4067
#define batteryVoltage_PIN A0 //analog input A0 on ATmega328 is battery voltage ( /2)
#define solarVoltage_PIN A2 //analog input A2 is solar cell voltage (/ 2)
#define solarCurrent_PIN A6 //analog input A6 is input current ( I=V/Rclprog x 1000 )
#define batteryChargeCurrent_PIN A7 //analog input A7 is battery charge current ( I=V/Rprog x 1000 )
#define LTC4067_SUSPEND_PIN 9 //digital output D9 - drive it high to put LTC4067 in SUSPEND mode
const float VccMin = 1.0 * 3.5; // Minimum expected Vcc level, in Volts. Example for 1 rechargeable lithium-ion.
const float VccMax = 1.0 * 4.2; // Maximum expected Vcc level, in Volts.
#define CHILD_ID_PRESSURE 0
#define CHILD_ID_TEMP 1
#define CHILD_ID_FORECAST 2
#define BATT_CHILD_ID 10
#define SOLAR_CHILD_ID 11
#define PRESSURE_SENSOR_ANALOG_PIN 0
// PIN Radio
#define RADIO_CE_PIN 7 // radio chip enable
#define RADIO_SS_PIN 8 // CS SS serial select
//float lastBattVoltage;
//float lastBattCurrent;
//float lastSolarVoltage;
//float lastSolarCurrent;
int lastBattPct = 0;
float VccReference = 3.3 ; // voltage reference for measurement, definitive init in setup
unsigned long SLEEP_TIME = 10; // Sleep time between reads (in seconds)
Adafruit_BMP085_Unified bmp = Adafruit_BMP085_Unified(10085); // Digital Pressure Sensor
MySensor gw(RADIO_CE_PIN, RADIO_SS_PIN);
MyMessage batteryVoltageMsg(BATT_CHILD_ID, V_VOLTAGE); // Battery voltage (V)
MyMessage batteryCurrentMsg(BATT_CHILD_ID, V_CURRENT); // Battery current (A)
MyMessage solarVoltageMsg(SOLAR_CHILD_ID, V_VOLTAGE); // Solar voltage (V)
MyMessage solarCurrentMsg(SOLAR_CHILD_ID, V_CURRENT);
MyMessage pressureMsg(CHILD_ID_PRESSURE, V_PRESSURE);
MyMessage tempMsg(CHILD_ID_TEMP, V_TEMP);
MyMessage forecastMsg(CHILD_ID_FORECAST, V_FORECAST);
float lastPressure = -1;
float lastTemp = -1;
int lastForecast = -1;
char *weather[] = {"stable", "sunny", "cloudy", "unstable", "thunderstorm", "unknown"};
int minutes;
float pressureSamples[180];
int minuteCount = 0;
bool firstRound = true;
float pressureAvg[7];
float dP_dt;
boolean metric;
void setup() {
gw.begin();
// Send the sketch version information to the gateway and Controller
gw.sendSketchInfo("Pressure Sensor", "1.0");
gw.present(BATT_CHILD_ID, S_POWER); // Battery parameters
gw.present(SOLAR_CHILD_ID, S_POWER); // Solar parameters
// use VCC (3.3V) reference
analogReference(DEFAULT); // default external reference = 3.3v for Ceech board
VccReference = 3.323 ; // measured Vcc input (on board LDO)
pinMode(LTC4067_SUSPEND_PIN, OUTPUT); // suspend of Lion charger set
digitalWrite(LTC4067_SUSPEND_PIN, LOW);
if (!bmp.begin(BMP085_MODE_ULTRAHIGHRES)) {
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(CHILD_ID_PRESSURE, S_BARO);
gw.present(CHILD_ID_TEMP, S_TEMP);
metric = gw.getConfig().isMetric;
}
void loop() {
sendVoltage();
sensors_event_t event;
bmp.getEvent(&event);
float pressure_raw;
float pressure;
float temperature;
float altitude;
if (event.pressure) {
pressure_raw = event.pressure;
//BMP085 pressure from adafruit gives you absolute pressure, that is NOT the barometric pressure the meteo forecast shows. You have to recalculate it by the above equation into the p0.
pressure = pressure_raw/pow((1.0 - ( myAltitude/44330.0 )), 5.255);
bmp.getTemperature(&temperature);
// altitude = bmp.pressureToAltitude(seaLevelPressure,
// event.pressure
// );
}
if (!metric) {
// Convert to fahrenheit
temperature = temperature * 9.0 / 5.0 + 32.0;
}
int forecast = sample(pressure);
Serial.print("Temperature = ");
Serial.print(temperature);
Serial.println(metric ? " *C" : " *F");
Serial.print("Pressure = ");
Serial.print(pressure);
Serial.println(" hPa");
Serial.println(weather[forecast]);
//Serial.print("Altitude = ");
//Serial.print(altitude);
if (ceil(temperature) != ceil(lastTemp)) {
gw.send(tempMsg.set(temperature, 1));
lastTemp = temperature;
}
if (ceil(pressure) != ceil(lastPressure)) {
gw.send(pressureMsg.set(pressure, 1));
lastPressure = pressure;
}
if (forecast != lastForecast) {
gw.send(forecastMsg.set(weather[forecast]));
lastForecast = forecast;
}
/*
DP/Dt explanation
0 = "Stable Weather Pattern"
1 = "Slowly rising Good Weather", "Clear/Sunny "
2 = "Slowly falling L-Pressure ", "Cloudy/Rain "
3 = "Quickly rising H-Press", "Not Stable"
4 = "Quickly falling L-Press", "Thunderstorm"
5 = "Unknown (More Time needed)
*/
// Power down the radio. Note that the radio will get powered back up
// on the next write() call.
delay(1000); //delay to allow serial to fully print before sleep
gw.sleep(SLEEP_TIME * 1000); // sleep to conserve power
}
int sample(float pressure) {
// Algorithm found here
// http://www.freescale.com/files/sensors/doc/app_note/AN3914.pdf
if (minuteCount > 180)
minuteCount = 6;
pressureSamples[minuteCount] = pressure;
minuteCount++;
if (minuteCount == 5) {
// Avg pressure in first 5 min, value averaged from 0 to 5 min.
pressureAvg[0] = ((pressureSamples[1] + pressureSamples[2]
+ pressureSamples[3] + pressureSamples[4] + pressureSamples[5])
/ 5);
} else if (minuteCount == 35) {
// Avg pressure in 30 min, value averaged from 0 to 5 min.
pressureAvg[1] = ((pressureSamples[30] + pressureSamples[31]
+ pressureSamples[32] + pressureSamples[33]
+ pressureSamples[34]) / 5);
float change = (pressureAvg[1] - pressureAvg[0]);
if (firstRound) // first time initial 3 hour
dP_dt = ((65.0 / 1023.0) * 2 * change); // note this is for t = 0.5hour
else
dP_dt = (((65.0 / 1023.0) * change) / 1.5); // divide by 1.5 as this is the difference in time from 0 value.
} else if (minuteCount == 60) {
// Avg pressure at end of the hour, value averaged from 0 to 5 min.
pressureAvg[2] = ((pressureSamples[55] + pressureSamples[56]
+ pressureSamples[57] + pressureSamples[58]
+ pressureSamples[59]) / 5);
float change = (pressureAvg[2] - pressureAvg[0]);
if (firstRound) //first time initial 3 hour
dP_dt = ((65.0 / 1023.0) * change); //note this is for t = 1 hour
else
dP_dt = (((65.0 / 1023.0) * change) / 2); //divide by 2 as this is the difference in time from 0 value
} else if (minuteCount == 95) {
// Avg pressure at end of the hour, value averaged from 0 to 5 min.
pressureAvg[3] = ((pressureSamples[90] + pressureSamples[91]
+ pressureSamples[92] + pressureSamples[93]
+ pressureSamples[94]) / 5);
float change = (pressureAvg[3] - pressureAvg[0]);
if (firstRound) // first time initial 3 hour
dP_dt = (((65.0 / 1023.0) * change) / 1.5); // note this is for t = 1.5 hour
else
dP_dt = (((65.0 / 1023.0) * change) / 2.5); // divide by 2.5 as this is the difference in time from 0 value
} else if (minuteCount == 120) {
// Avg pressure at end of the hour, value averaged from 0 to 5 min.
pressureAvg[4] = ((pressureSamples[115] + pressureSamples[116]
+ pressureSamples[117] + pressureSamples[118]
+ pressureSamples[119]) / 5);
float change = (pressureAvg[4] - pressureAvg[0]);
if (firstRound) // first time initial 3 hour
dP_dt = (((65.0 / 1023.0) * change) / 2); // note this is for t = 2 hour
else
dP_dt = (((65.0 / 1023.0) * change) / 3); // divide by 3 as this is the difference in time from 0 value
} else if (minuteCount == 155) {
// Avg pressure at end of the hour, value averaged from 0 to 5 min.
pressureAvg[5] = ((pressureSamples[150] + pressureSamples[151]
+ pressureSamples[152] + pressureSamples[153]
+ pressureSamples[154]) / 5);
float change = (pressureAvg[5] - pressureAvg[0]);
if (firstRound) // first time initial 3 hour
dP_dt = (((65.0 / 1023.0) * change) / 2.5); // note this is for t = 2.5 hour
else
dP_dt = (((65.0 / 1023.0) * change) / 3.5); // divide by 3.5 as this is the difference in time from 0 value
} else if (minuteCount == 180) {
// Avg pressure at end of the hour, value averaged from 0 to 5 min.
pressureAvg[6] = ((pressureSamples[175] + pressureSamples[176]
+ pressureSamples[177] + pressureSamples[178]
+ pressureSamples[179]) / 5);
float change = (pressureAvg[6] - pressureAvg[0]);
if (firstRound) // first time initial 3 hour
dP_dt = (((65.0 / 1023.0) * change) / 3); // note this is for t = 3 hour
else
dP_dt = (((65.0 / 1023.0) * change) / 4); // divide by 4 as this is the difference in time from 0 value
pressureAvg[0] = pressureAvg[5]; // 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.
}
if (minuteCount < 35 && firstRound) //if time is less than 35 min on the first 3 hour interval.
return 5; // Unknown, more time needed
else if (dP_dt < (-0.25))
return 4; // Quickly falling LP, Thunderstorm, not stable
else if (dP_dt > 0.25)
return 3; // Quickly rising HP, not stable weather
else if ((dP_dt > (-0.25)) && (dP_dt < (-0.05)))
return 2; // Slowly falling Low Pressure System, stable rainy weather
else if ((dP_dt > 0.05) && (dP_dt < 0.25))
return 1; // Slowly rising HP stable good weather
else if ((dP_dt > (-0.05)) && (dP_dt < 0.05))
return 0; // Stable weather
else
return 5; // Unknown
}
void sendVoltage(void)
// battery and charging values
{
// get Battery Voltage & charge current
float batteryVoltage = ((float)analogRead(batteryVoltage_PIN) * VccReference / 1024) * 2; // actual voltage is double
Serial.print("Batt: ");
Serial.print(batteryVoltage);
Serial.print("V ; ");
float batteryChargeCurrent = ((float)analogRead(batteryChargeCurrent_PIN) * VccReference / 1024) / 2.5 ; // current(A) = V/Rprog(kohm)
Serial.print(batteryChargeCurrent);
Serial.println("A ");
// get Solar Voltage & charge current
float solarVoltage = ((float)analogRead(solarVoltage_PIN) / 1024 * VccReference) * 2 ; // actual voltage is double
Serial.print("Solar: ");
Serial.print(solarVoltage);
Serial.print("V ; ");
// get Solar Current
float solarCurrent = ((float)analogRead(solarCurrent_PIN) / 1024 * VccReference) / 2.5; // current(A) = V/Rclprog(kohm)
Serial.print(solarCurrent);
Serial.print(" A; charge: ");
Serial.println(digitalRead(LTC4067_CHRG_PIN) ? "No" : "Yes");
// send battery percentage for node
int battPct = 1 ;
if (batteryVoltage > VccMin) {
battPct = 100.0 * (batteryVoltage - VccMin) / (VccMax - VccMin);
}
Serial.print("BattPct: ");
Serial.print(battPct);
Serial.println("% ");
if (lastBattPct != battPct) {
gw.send(batteryVoltageMsg.set(batteryVoltage, 3)); // Send (V)
gw.send(batteryCurrentMsg.set(batteryChargeCurrent, 6)); // Send (Amps)
gw.send(solarVoltageMsg.set(solarVoltage, 3)); // Send (V)
gw.send(solarCurrentMsg.set(solarCurrent, 6)); // Send (Amps)
gw.sendBatteryLevel(battPct);
lastBattPct = battPct;
}
}