Rain Guage
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@petewill said:
I have been testing the code for the last couple of days and I think this is working but another set of eyes would be good. I added functionality to set the "calibrateFactor" to a decimal. I also updated the save/load EEPROM to work with the MySensors standard. It seems to be working in my testing but I'm no programmer.
Pete,
I had a whack of combining your desire to use floats, and my desire not to use floats!
Essentially we are storing in hundredths of a mm or hundredths of an inch, and dividing the values down when we transmit to Vera.
you set the calibration in hundredths of a unit per tip here:
#define CALIBRATE_FACTOR 5 // e.g. 5 is .05mm (or 5 hundredths of an inch if imperial) per tip
Take a look at this and let me know if you like it, note it is untested and I still have to test the circular buffer storing ints instead of bytes.
/* Arduino Tipping Bucket Rain Gauge April 26, 2015 Version 1.02b for MySensors version 1.4.1 Arduino Tipping Bucket Rain Gauge Utilizing a tipping bucket sensor, your Vera home automation controller and the MySensors.org gateway you can measure and sense local rain. This sketch will create two devices on your Vera controller. One will display your total precipitation for the last 24, 48, 72, 96 and 120 hours. The other, a sensor that changes state if there is recent rain (up to last 120 hours) above a threshold. Both these settings are user definable. This sketch features the following: * Allows you to set the rain threshold in mm * Allows you to determine the interval window up to 120 hours. * Displays the last 24, 48, 72, 96 and 120 hours total rain in Variable1 through Variable5 of the Rain Sensor device * Configuration changes to Sensor device updated every hour * SHould run on any Arduino * Will retain Tripped/Not Tripped status and data in a power outage, saving small ammount of data to EEPROM (Circular Buffer to maximize life of EEPROM) * There is a unique setup requirement necessary in order to properly present the Vera device variables. The details are outlined in the sketch below. * LED status indicator by @BulldogLowell and @PeteWill for free public use */ #include <SPI.h> #include <MySensor.h> #include <math.h> #define NODE_ID 24 #define SKETCH_NAME "Rain Gauge" #define SKETCH_VERSION "1.02b" #define DEBUG_ON // comment out this line to disable serial debug #define CHILD_ID_RAIN 3 #define CHILD_ID_TRIPPED_RAIN 4 #define STATE_LOCATION 0 // location to save state to EEPROM #define EEPROM_BUFFER 1 // location of the EEPROM circular buffer #define BUFFER_LENGTH 121 // buffer plus the current hour #define CALIBRATE_FACTOR 100 // e.g. 5 is .05mm (or 5 hundredths of an inch if imperial) per tip #ifdef DEBUG_ON #define DEBUG_PRINT(x) Serial.print(x) #define DEBUG_PRINTLN(x) Serial.println(x) #define SERIAL_START(x) Serial.begin(x) #else #define DEBUG_PRINT(x) #define DEBUG_PRINTLN(x) #define SERIAL_START(x) #endif // MySensor gw; // MyMessage msgRainRate(CHILD_ID_RAIN, V_RAINRATE); MyMessage msgRain(CHILD_ID_RAIN, V_RAIN); MyMessage msgRainVAR1(CHILD_ID_RAIN, V_VAR1); MyMessage msgRainVAR2(CHILD_ID_RAIN, V_VAR2); MyMessage msgRainVAR3(CHILD_ID_RAIN, V_VAR3); MyMessage msgRainVAR4(CHILD_ID_RAIN, V_VAR4); MyMessage msgRainVAR5(CHILD_ID_RAIN, V_VAR5); // MyMessage msgTripped(CHILD_ID_TRIPPED_RAIN, V_TRIPPED); MyMessage msgTrippedVar1(CHILD_ID_TRIPPED_RAIN, V_VAR1); MyMessage msgTrippedVar2(CHILD_ID_TRIPPED_RAIN, V_VAR2); // boolean metric = true; // int eepromIndex; int tipSensorPin = 3; // Must be interrupt capable pin int ledPin = 5; // PWM capable pin required unsigned long dataMillis; unsigned long serialInterval = 10000UL; const unsigned long oneHour = 3600000UL; unsigned long lastTipTime; unsigned long lastBucketInterval; unsigned long startMillis; unsigned int rainBucket [120] ; /* 120 hours = 5 days of data */ unsigned int rainRate = 0; volatile int tipBuffer = 0; byte rainWindow = 72; //default rain window in hours int rainSensorThreshold = 50; //default rain sensor sensitivity in hundredths. Will be overwritten with msgTrippedVar2. byte state = 0; byte oldState = -1; // void setup() { SERIAL_START(115200); gw.begin(getVariables, NODE_ID); pinMode(tipSensorPin, INPUT_PULLUP); attachInterrupt (1, sensorTipped, FALLING); // depending on location of the hall effect sensor may need CHANGE pinMode(ledPin, OUTPUT); digitalWrite(ledPin, HIGH); gw.sendSketchInfo(SKETCH_NAME, SKETCH_VERSION); gw.present(CHILD_ID_RAIN, S_RAIN); gw.present(CHILD_ID_TRIPPED_RAIN, S_MOTION); DEBUG_PRINTLN(F("Sensor Presentation Complete")); state = gw.loadState(STATE_LOCATION); //retreive prior state from EEPROM DEBUG_PRINT(F("Previous Tripped State (from EEPROM): ")); DEBUG_PRINTLN(state ? "Tripped" : "Not Tripped"); // gw.send(msgTripped.set(state)); delay(250); // recharge the capacitor // boolean isDataOnEeprom = false; for (int i = 0; i < BUFFER_LENGTH; i++) { byte locator = gw.loadState(EEPROM_BUFFER + 2 * i); //<<<<<<<<<<< if (locator == 0xFF) // found the EEPROM circular buffer index { eepromIndex = EEPROM_BUFFER + 2 * i; //Now that we have the buffer index let's populate the rainBucket with data from eeprom loadRainArray(eepromIndex); isDataOnEeprom = true; DEBUG_PRINT("EEPROM Index "); DEBUG_PRINTLN(eepromIndex); isDataOnEeprom = true; break; } } if (!isDataOnEeprom) // Added for the first time it is run on a new arduino { eepromIndex = 1; gw.saveState(eepromIndex, 0xFF); gw.saveState(eepromIndex + 1, 0x00); } // reset the timers dataMillis = millis(); startMillis = millis(); lastTipTime = millis() - oneHour; gw.request(CHILD_ID_TRIPPED_RAIN, V_VAR1); //Get rainWindow from controller (Vera) delay(250); gw.request(CHILD_ID_TRIPPED_RAIN, V_VAR2); //Get rainSensorThreshold from controller (Vera) delay(250); DEBUG_PRINTLN(F("Radio Setup Complete!")); } // void loop() { gw.process(); if (state) { prettyFade(); // breath if tripped } else { slowFlash(); // blink if not tripped } // // let's constantly check to see if the rain in the past rainWindow hours is greater than rainSensorThreshold // int measure = 0; // Check to see if we need to show sensor tripped in this block for (int i = 0; i < rainWindow; i++) { measure += rainBucket [i]; DEBUG_PRINT(F("measure value (total rainBucket within rainWindow): ")); DEBUG_PRINTLN(measure); } // state = (measure >= rainSensorThreshold); if (state != oldState) { gw.send(msgTripped.set(state)); delay(250); gw.saveState(STATE_LOCATION, state); //New Code DEBUG_PRINT(F("State Changed. Tripped State: ")); DEBUG_PRINTLN(state); oldState = state; } // // Now lets reset the rainRate to zero if no tips in the last hour // if (millis() - lastTipTime >= oneHour)// timeout for rain rate { if (rainRate != 0) { rainRate = 0; gw.send(msgRainRate.set(0)); delay(250); } } #ifdef DEBUG_ON if ( (millis() - dataMillis) >= serialInterval) { for (int i = 24; i <= 120; i = i + 24) { updateSerialData(i); } dataMillis = millis(); } #endif // if (tipBuffer > 0) { DEBUG_PRINTLN(F("Sensor Tipped")); DEBUG_PRINT(F("rainBucket [0] value: ")); DEBUG_PRINTLN(rainBucket [0]); // int dayTotal = 0; for (int i = 0; i < 24; i++) { dayTotal = dayTotal + rainBucket [i]; } // DEBUG_PRINT(F("dayTotal value: ")); DEBUG_PRINTLN(dayTotal); gw.send(msgRain.set(dayTotal, 1)); delay(250); // unsigned long tipDelay = millis() - lastTipTime; if (tipDelay <= oneHour) { rainRate = ((oneHour) / tipDelay); gw.send(msgRainRate.set(rainRate, 1)); DEBUG_PRINT(F("RainRate= ")); DEBUG_PRINTLN(rainRate); } // //If this is the first trip in an hour send .1 // else { gw.send(msgRainRate.set( (float) CALIBRATE_FACTOR / 100.0, 1));//<<<<<<<<<<<<<<calibrate? } lastTipTime = millis(); tipBuffer--; } // if (millis() - startMillis >= oneHour) { DEBUG_PRINTLN(F("One hour elapsed.")); //EEPROM write last value gw.saveState(eepromIndex, highByte(rainBucket[0])); gw.saveState(eepromIndex + 1, lowByte(rainBucket[0])); eepromIndex++; if (eepromIndex > EEPROM_BUFFER + BUFFER_LENGTH) eepromIndex = EEPROM_BUFFER; DEBUG_PRINT(F("Writing to EEPROM. Index: ")); DEBUG_PRINTLN(eepromIndex); gw.saveState(eepromIndex, 0xFF); gw.saveState(eepromIndex + 1, 0x00); // for (int i = BUFFER_LENGTH - 1; i >= 0; i--)//cascade an hour of values { rainBucket [i + 1] = rainBucket [i]; } rainBucket[0] = 0; gw.send(msgRain.set(tipCounter(24), 1)); // send 24hr tips delay(250); transmitRainData(); // send all of the 5 buckets of data to controller delay(250); gw.request(CHILD_ID_TRIPPED_RAIN, V_VAR1); delay(250); gw.request(CHILD_ID_TRIPPED_RAIN, V_VAR2); startMillis = millis(); } } // void sensorTipped() { static unsigned long last_interrupt_time = 0; unsigned long interrupt_time = millis(); if (interrupt_time - last_interrupt_time > 200) { rainBucket[0] += CALIBRATE_FACTOR; // adds CALIBRATE_FACTOR hundredths of unit each tip } last_interrupt_time = interrupt_time; } // float tipCounter(int hours) { float tipCount = 0; for ( int i = 0; i < hours; i++) { tipCount = tipCount + rainBucket [i]; } return tipCount; } // void updateSerialData(int x) { DEBUG_PRINT(F("Tips last ")); DEBUG_PRINT(x); DEBUG_PRINTLN(F(" hours: ")); int tipCount = 0; for (int i = 0; i < x; i++) { tipCount = tipCount + rainBucket [i]; } DEBUG_PRINTLN(tipCount); } void loadRainArray(int value) { for (int i = 0; i < BUFFER_LENGTH - 1; i++) { value--; DEBUG_PRINT("EEPROM location: "); DEBUG_PRINTLN(value); if (value < EEPROM_BUFFER) { value = EEPROM_BUFFER + BUFFER_LENGTH; } byte rainValueHigh = gw.loadState(value); byte rainValueLow = gw.loadState(value + 1); int rainValue = (rainValueHigh << 8) & rainValueLow; rainBucket[i] = rainValue; // DEBUG_PRINT(F("rainBucket[ value: ")); DEBUG_PRINT(i); DEBUG_PRINT(F("] value: ")); DEBUG_PRINTLN(rainBucket[i]); } } void transmitRainData(void) { int rainUpdateTotal = 0; for (int i = 0; i < 24; i++) { rainUpdateTotal += rainBucket[i]; } gw.send(msgRainVAR1.set(( float) rainUpdateTotal / 100.0 , 1)); delay(250); for (int i = 24; i < 48; i++) { rainUpdateTotal += rainBucket[i]; } gw.send(msgRainVAR2.set( (float) rainUpdateTotal / 100.0 , 1)); delay(250); for (int i = 48; i < 72; i++) { rainUpdateTotal += rainBucket[i]; } gw.send(msgRainVAR3.set( (float) rainUpdateTotal / 100.0 , 1)); delay(250); for (int i = 72; i < 96; i++) { rainUpdateTotal += rainBucket[i]; } gw.send(msgRainVAR4.set( (float) rainUpdateTotal / 100.0 , 1)); delay(250); for (int i = 96; i < 120; i++) { rainUpdateTotal += rainBucket[i]; } gw.send(msgRainVAR5.set( (float) rainUpdateTotal / 100.0 , 1)); delay(250); } void getVariables(const MyMessage &message) { if (message.sensor == CHILD_ID_RAIN) { // nothing to do here } else if (message.sensor == CHILD_ID_TRIPPED_RAIN) { if (message.type == V_VAR1) { rainWindow = atoi(message.data); if (rainWindow > 120) { rainWindow = 120; } else if (rainWindow < 1) { rainWindow = 1; } if (rainWindow != atoi(message.data)) // if I changed the value back inside the boundries, push that number back to Vera { gw.send(msgTrippedVar1.set(rainWindow)); } } else if (message.type == V_VAR2) { rainSensorThreshold = atoi(message.data); if (rainSensorThreshold > 10000) { rainSensorThreshold = 10000; } else if (rainSensorThreshold < 1) { rainSensorThreshold = 1; } if (rainSensorThreshold != atoi(message.data)) // if I changed the value back inside the boundries, push that number back to Vera { gw.send(msgTrippedVar2.set(rainSensorThreshold)); } } } } // void prettyFade(void) { float val = (exp(sin(millis() / 2000.0 * PI)) - 0.36787944) * 108.0; analogWrite(ledPin, val); } void slowFlash(void) { static boolean ledState = true; static unsigned long pulseStart = millis(); if (millis() - pulseStart < 100UL) { digitalWrite(ledPin, !ledState); pulseStart = millis(); } }
EDIT, modified some serial.print()s that needed editing for the debug toggle
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@BulldogLowell
Thanks for the comments and sorry for the delayed response. It was a busy weekend and I didn't get much time in front of the computer.I had a whack of combining your desire to use floats, and my desire not to use floats!
Haha! I only used floats because I don't know any better. I'm curious, why the dislike of floats?
Once you get it done, let's take @hek 's idea and put it into github.
Is this something you would like me to do since you made it way better I'm happy to do it but I don't want to overstep. I consider this your handy work that I'm just happy to use.
Take a look at this and let me know if you like it, note it is untested and I still have to test the circular buffer storing ints instead of bytes.
Great! I will take a look some time this week. I mounted my gauge on the house today because we were supposed to get some rain and I wanted to see how it worked in real life. Unfortunately we didn't get any... Hopefully we will get some in the next couple of days before I pull it off to do some more testing.
we also need to create image files for the Sensor, but for now, if you want to do the tutorial, I say go for it!
I was thinking of going through how I made my gauge by using an existing rain gauge. I'd go over how to do the calculations for the tipping bucket calibration, uploading the files to Vera and how I added the MySensors stuff to the existing gauge. I will definitely mention the 3d printing option as well
Thanks for your help!.
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@petewill said:
why the dislike of floats?
their four-byte size on arduino make for a huge eeprom storage buffer that we really don't need, we will never have negative rain and we'd never be interested in precision below 0.01 inches or milimeters.
@petewill said:
I mounted my gauge on the house today
terrific, glad to see it make its way into the real world!
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@BulldogLowell said:
their four-byte size on arduino make for a huge eeprom storage buffer that we really don't need
Good to know! I still have a lot to learn about all this stuff. It's definitely fun.
terrific, glad to see it make its way into the real world!
Yes, me too! I'm happy to report it's working. It rained 6.4mm last night. SO COOL!
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big thumbs up!
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how about adding windspeed to the device?
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@BulldogLowell said:
how about adding windspeed to the device?
Cool device. Haven't seen that one before.
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@BulldogLowell Cool! Do you think it detects wind from all directions? Would this be better than the traditional spinning cup design?
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electronics box:
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@BulldogLowell this looks great once you complete it I will print it. Only problem our raining session is over till Dec. But I can start the build so long :).
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Nice. But I'm a bit worried about water finding its way into the electronics. Would it be possible to make a cavity for the electronics box in the bottom plate?
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@hek
recessing the electronics into the bottom would be tough in this design. I was taking advantage on the two parts to use the smooth plate of the printer, and then make a gasket or even use silicone. lemme think about it. I could add a couple of deflectors on the bottom plate to glue on around where the weep holes are...PS enough room for 2 C sized cells
bottom view:
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@BulldogLowell Awesome!
I kind of wish I didn't have mine built already
I may have missed it but did you have any mounting holes (for the side of a building or pole) What is your vision for that?
It would also be cool to see some place to add a DHT22 in there. On mine I added one of those as well as a BH1750 for light. I'm not sure how long that will hold up though.
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@petewill said:
It would also be cool to see some place to add a DHT22 in there. On mine I added one of those as well as a BH1750 for light. I'm not sure how long that will hold up though.
I'll try to fit that in, if I can, but I'm really focusing on sealing up the electronics. A skirt around the electronics housing may be enough...
I was thinking of a female 'flange-like' option for the unit to sit at the top of some galvanized pipe. It could be mounted that way on the side of a house, a fence or just a pole (back of your basketball backboard!). So, the yellow-brown part will be of two options to print.
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@BulldogLowell said:
I was taking advantage on the two parts to use the smooth plate of the printer
Of course, didn't think that long.
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If you add a little edge around the holes, the water cannt flow into the electronic box.
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@BulldogLowell Awesome. I would love to get a 3d printer. Someday.
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As it happens, I am sort of turning the code on its head for this update. Do you want to use accumulated rain over X days as the trigger?
I was thinking about storing the time on EEPROM and retrieving the stored rain values from VERA for each of the last 5 days after a power-up/restart. This saves from having to create too much EEPROM management, plus we can observe how much time has passed in the event of a power-off. That is, if the unit starts up, we test EEPROM to see what was the last day of rain recorded. If it hasn't been more than one, then we retrieve the values from VERA that were previously sent up. Sound OK to you?
I would save an epoch timestamp once each day at midnight when we total today's rain and cascade the values back a day.
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@BulldogLowell said:
Do you want to use accumulated rain over X days as the trigger?
As opposed to hours? I don't have too strong of an opinion either way. I think whatever is easier works. If they are both the same then maybe hours so we have a little more granular control?
I was thinking about storing the time on EEPROM and retrieving the stored rain values from VERA for each of the last 5 days after a power-up/restart.
I like that it will simplify the EEPROM more and potentially prolong the life of the device (since it's not using as much EEPROM). One thought though, if there is a communication error between Vera and the rain gauge when it is first started is there a way to prevent the rain gauge from subsequently overwriting the values in Vera? I don't know too much about the "ack" portion of the communication but maybe that would make it so it's not an issue?
I'm excited to see the new code. Keep up the good work!
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@petewill said:
As opposed to hours? I don't have too strong of an opinion either way. I think whatever is easier works. If they are both the same then maybe hours so we have a little more granular control?
that's where we were with the 120 hour framework, so let's leave that. I'm not worried about EEPROM life, you get 100,000 writes and that is your lifetime++ using the circular buffer. I did the math on it but can't recall the exact number.
So, we won't change EEPROM data, actually may need to add another 24hours. We just send to VERA the total of each of the past 5 days instead of the total accumulated rainfall over the past 24, 48, 72, 96 and 120 hours. This will be calendar days, we will verify by getting the time from VERA, and synchronize that a few times daily. the days will rollover at midnight, and the daily accumulation will be cascaded back accordingly.
trigger for the sensor will still be total accumulation over so many hours.
Yes?
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@BulldogLowell That sounds GREAT to me! This is your baby though (and you have much more experience with this stuff) so I trust what direction you go.
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here is some (untested) mods to update the 5 day rainfall history once per day at midnight. Take a look, let me know what you think (any problems issues). It turns out I was overthinking the problem and it really only needed minor mods...
/* Arduino Tipping Bucket Rain Gauge April 26, 2015 Version 1.4.1 alpha Arduino Tipping Bucket Rain Gauge Utilizing a tipping bucket sensor, your Vera home automation controller and the MySensors.org gateway you can measure and sense local rain. This sketch will create two devices on your Vera controller. One will display your total precipitation for the last 24, 48, 72, 96 and 120 hours. The other, a sensor that changes state if there is recent rain (up to last 120 hours) above a threshold. Both these settings are user definable. This sketch features the following: * Allows you to set the rain threshold in mm * Allows you to determine the interval window up to 120 hours. * Displays the last 5 days of rain in Variable1 through Variable5 of the Rain Sensor device * Configuration changes to Sensor device updated every hour * SHould run on any Arduino * Will retain Tripped/Not Tripped status and data in a power interruption, saving small ammount of data to EEPROM (Circular Buffer to maximize life of EEPROM) * LED status indicator by @BulldogLowell and @PeteWill for free public use */ #include <SPI.h> #include <MySensor.h> #include <math.h> #include <Time.h> #define NODE_ID 24 #define SKETCH_NAME "Rain Gauge" #define SKETCH_VERSION "1.4.1a" #define DWELL_TIME 125 // this allows for radio to come back to power after a transmission, ideally 0 #define DEBUG_ON // comment out this line to disable serial debug #define CHILD_ID_RAIN_LOG 3 // Keeps track of accumulated rainfall #define CHILD_ID_TRIPPED_INDICATOR 4 // Indicates Tripped when rain detected #define EEPROM_STATE_LOCATION 0 // location to save state to EEPROM #define EEPROM_BUFFER_LOCATION 1 // location of the EEPROM circular buffer #define BUFFER_LENGTH 121 #define CALIBRATE_FACTOR 100 // e.g. 5 is .05mm (or 5 hundredths of an inch if imperial) per tip #ifdef DEBUG_ON #define DEBUG_PRINT(x) Serial.print(x) #define DEBUG_PRINTLN(x) Serial.println(x) #define SERIAL_START(x) Serial.begin(x) #else #define DEBUG_PRINT(x) #define DEBUG_PRINTLN(x) #define SERIAL_START(x) #endif // MySensor gw; // MyMessage msgRainRate(CHILD_ID_RAIN_LOG, V_RAINRATE); MyMessage msgRain(CHILD_ID_RAIN_LOG, V_RAIN); // MyMessage msgRainVAR1(CHILD_ID_RAIN_LOG, V_VAR1); MyMessage msgRainVAR2(CHILD_ID_RAIN_LOG, V_VAR2); MyMessage msgRainVAR3(CHILD_ID_RAIN_LOG, V_VAR3); MyMessage msgRainVAR4(CHILD_ID_RAIN_LOG, V_VAR4); MyMessage msgRainVAR5(CHILD_ID_RAIN_LOG, V_VAR5); // MyMessage msgTripped(CHILD_ID_TRIPPED_INDICATOR, V_TRIPPED); MyMessage msgTrippedVar1(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); MyMessage msgTrippedVar2(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); // boolean metric = true; int eepromIndex; int tipSensorPin = 3; // Must be interrupt capable pin int ledPin = 5; // PWM capable pin required unsigned long dataMillis; const unsigned long serialInterval = 10000UL; const unsigned long oneHour = 3600000UL; unsigned long lastTipTime; unsigned long startMillis; unsigned int rainBucket [24] ; /* 24 hours = 1 day of data */ unsigned int rainRate = 0; volatile int wasTippedBuffer = 0; byte rainWindow = 72; //default rain window in hours int rainSensorThreshold = 50; //default rain sensor sensitivity in hundredths. Will be overwritten with msgTrippedVar2. byte state = 0; byte oldState = -1; int lastRainRate = 0; int lastMeasure = 0; boolean gotTime = false; byte lastHour; void setup() { SERIAL_START(115200); // // Set up the IO pinMode(tipSensorPin, INPUT_PULLUP); attachInterrupt (1, sensorTipped, FALLING); // depending on location of the hall effect sensor may need CHANGE pinMode(ledPin, OUTPUT); digitalWrite(ledPin, HIGH); // //Let's get the controller talking to the Arduino gw.begin(getVariables, NODE_ID); gw.sendSketchInfo(SKETCH_NAME, SKETCH_VERSION); delay(DWELL_TIME); gw.present(CHILD_ID_RAIN_LOG, S_RAIN); delay(DWELL_TIME); gw.present(CHILD_ID_TRIPPED_INDICATOR, S_MOTION); delay(DWELL_TIME); DEBUG_PRINTLN(F("Sensor Presentation Complete")); state = gw.loadState(EEPROM_STATE_LOCATION); //retreive prior state from EEPROM DEBUG_PRINT(F("Previous Tripped State (from EEPROM): ")); DEBUG_PRINTLN(state ? "Tripped" : "Not Tripped"); // gw.send(msgTripped.set(state)); delay(DWELL_TIME); // //Sync time with the server, this will be called hourly in order to keep time from creeping with the crystal // while(timeStatus() == timeNotSet) { gw.process(); gw.requestTime(receiveTime); Serial.println("getting Time"); delay(1000); // call once per second Serial.print("."); } // //retrieve from EEPROM stored values on a power cycle. // boolean isDataOnEeprom = false; for (int i = 0; i < BUFFER_LENGTH; i++) { byte locator = gw.loadState(EEPROM_BUFFER_LOCATION + 2 * i); //<<<<<<<<<<< if (locator == 0xFF) // found the EEPROM circular buffer index { eepromIndex = EEPROM_BUFFER_LOCATION + 2 * i; //Now that we have the buffer index let's populate the rainBucket[] with data from eeprom loadRainArray(eepromIndex); isDataOnEeprom = true; DEBUG_PRINT("EEPROM Index "); DEBUG_PRINTLN(eepromIndex); isDataOnEeprom = true; break; } } if (!isDataOnEeprom) // Added for the first time it is run on a new arduino { eepromIndex = 1; gw.saveState(eepromIndex, 0xFF); // store the EEPROM index marker... gw.saveState(eepromIndex + 1, 0xFF); } dataMillis = millis(); startMillis = millis(); lastTipTime = millis() - oneHour; // //Get sensor time window and threshold from controller gw.request(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); delay(DWELL_TIME); gw.request(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); delay(DWELL_TIME); DEBUG_PRINTLN(F("Radio Setup Complete!")); } void loop() { gw.process(); if (state) { prettyFade(); // breathe if tripped } else { slowFlash(); // blink if not tripped } #ifdef DEBUG_ON // Serial Debug Block if ( (millis() - dataMillis) >= serialInterval) { for (int i = 24; i <= 120; i = i + 24) { updateSerialData(i); } dataMillis = millis(); } #endif // // let's constantly check to see if the rain in the past rainWindow hours is greater than rainSensorThreshold // int measure = 0; // Check to see if we need to show sensor tripped in this block for (int i = 0; i < rainWindow; i++) { measure += rainBucket [i]; if (measure != lastMeasure) { DEBUG_PRINT(F("measure value (total rainBucket within rainWindow): ")); DEBUG_PRINTLN(measure); lastMeasure = measure; } } // state = (measure >= rainSensorThreshold); if (state != oldState) { gw.send(msgTripped.set(state)); delay(DWELL_TIME); gw.saveState(EEPROM_STATE_LOCATION, state); //New Code DEBUG_PRINT(F("New Sensor State... Sensor: ")); DEBUG_PRINTLN(state? "Tripped" : "Not Tripped"); oldState = state; } // unsigned long tipDelay = millis() - lastTipTime; if (wasTippedBuffer) // if was tipped, then update the 24hour total and transmit to Vera { DEBUG_PRINTLN(F("Sensor Tipped")); DEBUG_PRINT(F("rainBucket [0] value: ")); DEBUG_PRINTLN(rainBucket [0]); // int dayTotal = 0; for (int i = 0; i < 24; i++) { dayTotal = dayTotal + rainBucket [i]; } // DEBUG_PRINT(F("dayTotal value: ")); DEBUG_PRINTLN(dayTotal); gw.send(msgRain.set(dayTotal, 1)); delay(DWELL_TIME); wasTippedBuffer--; rainRate = ((oneHour) / tipDelay); if (rainRate != lastRainRate) { gw.send(msgRainRate.set(rainRate, 1)); delay(DWELL_TIME); DEBUG_PRINT(F("RainRate= ")); DEBUG_PRINTLN(rainRate); lastRainRate = rainRate; } } if (tipDelay > oneHour) { rainRate = 0; gw.send(msgRainRate.set(rainRate, 1)); } // if (millis() - startMillis >= oneHour) { DEBUG_PRINTLN(F("One hour elapsed.")); for (int i = BUFFER_LENGTH - 1; i >= 0; i--)//cascade an hour of values back into the array { rainBucket [i + 1] = rainBucket [i]; } rainBucket[0] = 0; gw.send(msgRain.set(rainTotal(24), 1)); // send 24hr tips delay(DWELL_TIME); gw.request(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); delay(DWELL_TIME); gw.request(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); delay(DWELL_TIME); gw.saveState(eepromIndex, highByte(rainBucket[0])); gw.saveState(eepromIndex + 1, lowByte(rainBucket[0])); eepromIndex++; if (eepromIndex > EEPROM_BUFFER_LOCATION + BUFFER_LENGTH) eepromIndex = EEPROM_BUFFER_LOCATION; DEBUG_PRINT(F("Writing to EEPROM. Index: ")); DEBUG_PRINTLN(eepromIndex); gw.saveState(eepromIndex, 0xFF); gw.saveState(eepromIndex + 1, 0xFF); gw.requestTime(receiveTime); // sync the time every hour delay(DWELL_TIME); startMillis = millis(); } if (hour() == 0 and lastHour == 23) { transmitRainData(); } lastHour = hour(); } void sensorTipped() { unsigned long thisTipTime = millis(); if (thisTipTime - lastTipTime > 100UL) { rainBucket[0] += CALIBRATE_FACTOR; // adds CALIBRATE_FACTOR hundredths of unit each tip wasTippedBuffer++; } lastTipTime = thisTipTime; } // int rainTotal(int hours) { int total = 0; for ( int i = 0; i < hours; i++) { total += rainBucket [i]; } return total; } void updateSerialData(int x) { DEBUG_PRINT(F("Tips last ")); DEBUG_PRINT(x); DEBUG_PRINTLN(F(" hours: ")); int tipCount = 0; for (int i = 0; i < x; i++) { tipCount = tipCount + rainBucket [i]; } DEBUG_PRINTLN(tipCount); } void loadRainArray(int value) // load stored rain array from EEPROM on powerup { for (int i = 0; i < BUFFER_LENGTH - 1; i++) { value--; DEBUG_PRINT("EEPROM location: "); DEBUG_PRINTLN(value); if (value < EEPROM_BUFFER_LOCATION) { value = EEPROM_BUFFER_LOCATION + BUFFER_LENGTH; } byte rainValueHigh = gw.loadState(value); byte rainValueLow = gw.loadState(value + 1); int rainValue = (rainValueHigh << 8) & rainValueLow; rainBucket[i] = rainValue; // DEBUG_PRINT(F("rainBucket[ value: ")); DEBUG_PRINT(i); DEBUG_PRINT(F("] value: ")); DEBUG_PRINTLN(rainBucket[i]); } } void transmitRainData(void) { int rainUpdateTotal = 0; for (int i = 0; i < 24; i++) { rainUpdateTotal += rainBucket[i]; } gw.send(msgRainVAR1.set(( float) rainUpdateTotal / 100.0 , 1)); delay(DWELL_TIME); rainUpdateTotal = 0; for (int i = 24; i < 48; i++) { rainUpdateTotal += rainBucket[i]; } gw.send(msgRainVAR2.set( (float) rainUpdateTotal / 100.0 , 1)); delay(DWELL_TIME); rainUpdateTotal = 0; for (int i = 48; i < 72; i++) { rainUpdateTotal += rainBucket[i]; } gw.send(msgRainVAR3.set( (float) rainUpdateTotal / 100.0 , 1)); delay(DWELL_TIME); rainUpdateTotal = 0; for (int i = 72; i < 96; i++) { rainUpdateTotal += rainBucket[i]; } gw.send(msgRainVAR4.set( (float) rainUpdateTotal / 100.0 , 1)); delay(DWELL_TIME); rainUpdateTotal = 0; for (int i = 96; i < 120; i++) { rainUpdateTotal += rainBucket[i]; } gw.send(msgRainVAR5.set( (float) rainUpdateTotal / 100.0 , 1)); delay(DWELL_TIME); } void getVariables(const MyMessage &message) { if (message.sensor == CHILD_ID_RAIN_LOG) { // nothing to do here } else if (message.sensor == CHILD_ID_TRIPPED_INDICATOR) { if (message.type == V_VAR1) { rainWindow = atoi(message.data); if (rainWindow > 120) { rainWindow = 120; } else if (rainWindow < 1) { rainWindow = 1; } if (rainWindow != atoi(message.data)) // if I changed the value back inside the boundries, push that number back to Vera { gw.send(msgTrippedVar1.set(rainWindow)); } } else if (message.type == V_VAR2) { rainSensorThreshold = atoi(message.data); if (rainSensorThreshold > 10000) { rainSensorThreshold = 10000; } else if (rainSensorThreshold < 1) { rainSensorThreshold = 1; } if (rainSensorThreshold != atoi(message.data)) // if I changed the value back inside the boundries, push that number back to Vera { gw.send(msgTrippedVar2.set(rainSensorThreshold)); } } } } void prettyFade(void) { float val = (exp(sin(millis() / 2000.0 * PI)) - 0.36787944) * 108.0; analogWrite(ledPin, val); } void slowFlash(void) { static boolean ledState = true; static unsigned long pulseStart = millis(); if (millis() - pulseStart < 100UL) { digitalWrite(ledPin, !ledState); pulseStart = millis(); } } void receiveTime(unsigned long time) { DEBUG_PRINTLN(F("Time received from controller...")); setTime(time); char theTime[26]; sprintf(theTime, "The current time is %d:%2d", hour(), minute()); DEBUG_PRINTLN(theTime); }
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Wow, just wow man.... that is a thing of beauty!!
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@ServiceXp
waiting for the 3D prints from China, I'll post when I get them!
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I would love to see the .stl files for this.
It has turned into something really amazing imho.
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@marceltrapman said:
I would love to see the .stl files for this.
It has turned into something really amazing imho.I'll post, but I wanted to print and check first...
@marceltrapman here you go...
Posted to GoogleDrive
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@BulldogLowell this has been quite a project to watch unfold and develop into just the greatest project. I am learning more just following you programing wizards, than I learn surfing . Thanks for the project and the inside tracks on programming etc.
I have got my tripping gage back from my local 3d hub shop and the job looks good I hope to have it running hardware and soft before I return to and take it to Florida this fall.
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A page for your new creation has been deployed here:
http://www.mysensors.org/build/rainPlease let me know if I missed something or spelling needs to be corrected.
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@hek Looks great! Thanks!
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@petewill - another outstanding tutorial video.
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@blacey Thanks! Couldn't have done it without @BulldogLowell and @hek
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Received my off the shelf tipping bucket sensor today. http://www.ebay.com/itm/331525977548?rmvSB=true
To my surprise it contained a dummy 2xAAA battery compartment. It might be possible to squeeze in a sensebender and nrf-radio (with some slight modification).
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@hek Cool! Looks like you may even have some room on the other side if you can figure out a way to waterproof it?
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@hek said:
Received my off the shelf tipping bucket sensor today. http://www.ebay.com/itm/331525977548?rmvSB=true
To my surprise it contained a dummy 2xAAA battery compartment. It might be possible to squeeze in a sensebender and nrf-radio (with some slight modification).
@hek
Did you ever wire this up with sensebender & radio squeezed in?
I have this same guage I want to use with sensebender
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No, never had time to finish my rain gauge this summer.
But it should be doable. But the big pcb in there has to be modified, or even better is probably to move the reed switch directly to the sensebender.
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@hek said:
No, never had time to finish my rain gauge this summer.
But it should be doable. But the big pcb in there has to be modified, or even better is probably to move the reed switch directly to the sensebender.
ok thanks
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Hi.
i'm having some trouble whit my rain gauge...My rain gauge is a Aercus KW9015, using the code provided i'm getting rain count every hour whit no rain at all.
I don't know what to do to fix this.Over the rain gauge i have 4 connections.
1 - GND
2 - TX1 --- Temperature sensor
3 - TX2 --- Rain sensor
4 - VCCWhy i'm i getting reads of rain ever 1h when there is no rain ?
Can anyone help me whit this problem ?
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@mrc-core
Are you actually getting a rain value or is it just sending 0? The code is designed to send an update to your gateway every hour with the total rain for the day whether there is rain or not.
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Some times i do get value 0 but other times i get rain value a big rain value for example values above 10mm of rain.
The update is made every hour. Yesterday the rain value was 148mm when there was no rain at all. It doesn't rain for the last month.Ill try today reassembling the arduino, clear cd rom and flash again the rain gauge code.
But i don't understand why i get this values.
I even beleaved that the sensor was sendind data because off the wind... but it's not the problem.
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how is it connected electronically?
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At the rain gauge i have an arduino nano conneting PIN "d3" to TX2 over the rain gauge circuit, the arduino is powered at pins VIN and GND.
The rain gauge gets its power from the 3.3V over the arduino.im posting two images from the rain gauge circuit:
Starting to believe i had connect someting rong like for example had switched TX1 and TX2 at the rain gauge
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Looking over the IMG_2 should i connect arduino pin d3 to T1 just above the reed switch?
Or i'm i correct using the TX2 connection.
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No PULLUP or PULLDOWN resistor?
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no i cant find any pullup or pulldown resistor.
You can see the images from de interior of the rain gauge hi have.
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Which resistor do i pu between the 5v and the D3 pin ???
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if you don't pull up/down the signal, you may get floating voltages and spurious interrupts occurring.
try to use the internal pullup
pinMode(yourInterruptPin, INPUT_PULLUP);
if that does not work try an external 10kOhm resistor to pull it up/down for your switch.
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Going to put the 10kOhm resistor. the internall pullup did not work.
One question. the resistor i put it between de 5v and the D3 pin
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to PULL UP, yes.
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Thanks going to try it now. And today is a good day since its raining.
No luck... now i'm getting only "0"
What i have done until now:
Put a resistor 10kOhm between the GND and D3 Pin from arduino and connect it to TX2 over rthe rain gauge.
And connected the 5V from arduino to the VCC over the rain gauge.But i'm only getting 0 ...
send: 4-4-0-0 s=3,c=1,t=28,pt=7,l=5,sg=0,st=fail:-0.2
read: 5-5-255 s=255,c=3,t=7,pt=0,l=0,sg=0:
send: 4-4-0-0 s=4,c=1,t=16,pt=1,l=1,sg=0,st=ok:0
New Sensor State... Sensor: Not Tripped
read: 3-3-0 s=0,c=1,t=38,pt=7,l=5,sg=0:4.748
read: 0-0-4 s=4,c=2,t=24,pt=0,l=1,sg=0:1
read: 5-5-255 s=255,c=3,t=7,pt=0,l=0,sg=0:
read: 5-5-255 s=255,c=3,t=7,pt=0,l=0,sg=0:
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I guess I'd need to see a schematic or a good photo.
can you generate a simple interrupt with a pushbutton and a resistor?
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Hi. yesterday i disassembled the rain gauge circuit removed from it the reed switch and created a new circuit.
I have connnected the reed switch to GND and PIN3 whit 10kOhm resistor.
I'll post an image tonight.Up until now the values i'me getting from this new circuit is:
Values i'm getting from serial port:
Rain last 24 hours:
1.80
Rain last 48 hours:
12481.94
Rain last 72 hours:
28210.34
Rain last 96 hours:
43938.74
Rain last 120 hours:
59667.14
read and drop: 6-6-255 s=255,c=3,t=7,pt=0,l=0,sg=0:
read and drop: 6-6-255 s=255,c=3,t=7,pt=0,l=0,sg=0:
read and drop: 5-5-255 s=255,c=3,t=7,pt=0,l=0,sg=0:
read and drop: 6-6-255 s=255,c=3,t=7,pt=0,l=0,sg=0:Seeing the graphic and this values it seems the problem i was having is fixed...
But tonight i'm going do spread some water over the bucket to see if i get any values and not just 0
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MI-SOL Rain Guage has CALIBRATE_FACTOR = 36
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Sensor manufacturer has sent information about the sensor. 0.3 mm to 1 tick
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@Ivan-Z Thanks for the info.
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Hey guys,
Sorry if this is a stupid question but how does the Arduino interact with the tipping bucket to detect rain?
Thanks!
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@Theekshana There is a magnet on the tipping bucket and a reed switch that detects the magnet each time it passes by. So each time the bucket tips it will trigger to the Arduino and it can count from there.
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Has anyone converted this sketch to Mysensors 2.0 already? I've tried but received following error when compiling:
Rain-gauge.ino: In function 'void setup()': Rain-gauge.ino:151:28: error: too many arguments to function 'void requestTime()' In file included from D:\Programs\Arduino\Sketchbook\libraries\libraries\MySensors/MySensors.h:293:0, from Rain-gauge.ino:71: D:\Programs\Arduino\Sketchbook\libraries\libraries\MySensors/core/MySensorsCore.cpp:296:6: note: declared here void requestTime() { ^ Rain-gauge.ino: In function 'void loop()': Rain-gauge.ino:323:28: error: too many arguments to function 'void requestTime()' In file included from D:\Programs\Arduino\Sketchbook\libraries\libraries\MySensors/MySensors.h:293:0, from Rain-gauge.ino:71: D:\Programs\Arduino\Sketchbook\libraries\libraries\MySensors/core/MySensorsCore.cpp:296:6: note: declared here void requestTime() { ^ too many arguments to function 'void requestTime()'
Modified sketch below:
/* Arduino Tipping Bucket Rain Gauge April 26, 2015 Version 1.4.1 alpha Arduino Tipping Bucket Rain Gauge Utilizing a tipping bucket sensor, your Vera home automation controller and the MySensors.org gateway you can measure and sense local rain. This sketch will create two devices on your Vera controller. One will display your total precipitation for the last 5 days. The other, a sensor that changes state if there is recent rain (up to last 120 hours) above a threshold. Both these settings are user definable. There is a build overview video here: https://youtu.be/1eMfKQaLROo This sketch features the following: * Allows you to set the rain threshold in mm * Allows you to determine the tripped indicator window up to 120 hours. * Displays the last 5 days of rain in Variable1 through Variable5 of the Rain Sensor device * Configuration changes to Sensor device updated every hour * Should run on any Arduino * Will retain Tripped/Not Tripped status and data in a power interruption, saving small amount of data to EEPROM (Circular Buffer to maximize life of EEPROM) * LED status indicator * Optional Temp/Humidity (DHT-22 or DHT-11) and Light LUX (BH1750) sensors. To use, uncomment #define DHT_ON and/or #define LUX_ON * Optionally send total accumulation of each day's rainfall or send only individual days rainfall totals. Comment out #define USE_DAILY to display individual daily rainfall. by @BulldogLowell and @PeteWill for free public use */ #include <SPI.h> #include <math.h> #include <Time.h> //#define NODE_ID AUTO //or AUTO to let controller assign #define SKETCH_NAME "Rain Gauge" #define SKETCH_VERSION "1.4.1a" #define MY_RADIO_NRF24 #define DWELL_TIME 125 // this allows for radio to come back to power after a transmission, ideally 0 //#define DEBUG_ON // comment out this line to disable serial debug //#define DHT_ON // uncomment out this line to enable DHT sensor //#define LUX_ON // uncomment out this line to enable BH1750 sensor //#define USE_DAILY // displays each time segment as an accumulation of prior periods inclusive. Comment out to display individual daily rainfall totals in the variables sent to your controller. #define CALIBRATE_FACTOR 60 // amount of rain per rain bucket tip e.g. 5 is .05mm #define DHT_LUX_DELAY 300000 //Delay in milliseconds that the DHT and LUX sensors will wait before sending data #define CHILD_ID_RAIN_LOG 3 // Keeps track of accumulated rainfall #define CHILD_ID_TRIPPED_INDICATOR 4 // Indicates Tripped when rain detected #define EEPROM_BUFFER_LOCATION 0 // location of the EEPROM circular buffer #define E_BUFFER_LENGTH 240 #define RAIN_BUCKET_SIZE 120 #ifdef DEBUG_ON #define DEBUG_PRINT(x) Serial.print(x) #define DEBUG_PRINTLN(x) Serial.println(x) #define SERIAL_START(x) Serial.begin(x) #else #define DEBUG_PRINT(x) #define DEBUG_PRINTLN(x) #define SERIAL_START(x) #endif #include <MySensors.h> // MyMessage msgRainRate(CHILD_ID_RAIN_LOG, V_RAINRATE); MyMessage msgRain(CHILD_ID_RAIN_LOG, V_RAIN); // MyMessage msgRainVAR1(CHILD_ID_RAIN_LOG, V_VAR1); MyMessage msgRainVAR2(CHILD_ID_RAIN_LOG, V_VAR2); MyMessage msgRainVAR3(CHILD_ID_RAIN_LOG, V_VAR3); MyMessage msgRainVAR4(CHILD_ID_RAIN_LOG, V_VAR4); MyMessage msgRainVAR5(CHILD_ID_RAIN_LOG, V_VAR5); // MyMessage msgTripped(CHILD_ID_TRIPPED_INDICATOR, V_TRIPPED); MyMessage msgTrippedVar1(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); MyMessage msgTrippedVar2(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); // #ifdef DHT_ON #include <DHT.h> #define CHILD_ID_HUM 0 #define CHILD_ID_TEMP 1 #define HUMIDITY_SENSOR_DIGITAL_PIN 8 DHT dht; float lastTemp; float lastHum; boolean metric = true; MyMessage msgHum(CHILD_ID_HUM, V_HUM); MyMessage msgTemp(CHILD_ID_TEMP, V_TEMP); #endif // #ifdef LUX_ON //BH1750 is connected to SCL (analog input A5) and SDA (analog input A4) #include <BH1750.h> #include <Wire.h> #define CHILD_ID_LIGHT 2 BH1750 lightSensor; MyMessage msg(CHILD_ID_LIGHT, V_LIGHT_LEVEL); unsigned int lastlux; byte heartbeat = 10; //Used to send the light lux to gateway as soon as the device is restarted and after the DHT_LUX_DELAY has happened 10 times #endif unsigned long sensorPreviousMillis; int eepromIndex; int tipSensorPin = 3; // Pin the tipping bucket is connected to. Must be interrupt capable pin int ledPin = 5; // Pin the LED is connected to. PWM capable pin required unsigned long dataMillis; unsigned long serialInterval = 600000UL; const unsigned long oneHour = 3600000UL; unsigned long lastTipTime; unsigned long lastRainTime; //Used for rainRate calculation unsigned int rainBucket [RAIN_BUCKET_SIZE] ; /* 24 hours x 5 Days = 120 hours */ unsigned int rainRate = 0; byte rainWindow = 72; //default rain window in hours. Will be overwritten with msgTrippedVar1. volatile int wasTippedBuffer = 0; int rainSensorThreshold = 50; //default rain sensor sensitivity in hundredths. Will be overwritten with msgTrippedVar2. byte state = 0; byte oldState = -1; int lastRainRate = 0; int lastMeasure = 0; boolean gotTime = false; byte lastHour; byte currentHour; // void setup() { SERIAL_START(115200); // // Set up the IO pinMode(tipSensorPin, INPUT_PULLUP); attachInterrupt (1, sensorTipped, FALLING); // depending on location of the hall effect sensor may need CHANGE pinMode(ledPin, OUTPUT); digitalWrite(ledPin, HIGH); // //Let's get the controller talking to the Arduino //begin(getVariables, NODE_ID); // //Sync time with the server, this will be called hourly in order to keep time from creeping with the crystal // unsigned long functionTimeout = millis(); while (timeStatus() == timeNotSet && millis() - functionTimeout < 30000UL) { // process(); requestTime(receiveTime); DEBUG_PRINTLN(F("Getting Time")); wait(1000); // call once per second DEBUG_PRINTLN(F(".")); } currentHour = hour(); lastHour = hour(); // //retrieve from EEPROM stored values on a power cycle. // boolean isDataOnEeprom = false; for (int i = 0; i < E_BUFFER_LENGTH; i++) { byte locator = loadState(EEPROM_BUFFER_LOCATION + i); if (locator == 0xFE) // found the EEPROM circular buffer index { eepromIndex = EEPROM_BUFFER_LOCATION + i; DEBUG_PRINT(F("EEPROM Index ")); DEBUG_PRINTLN(eepromIndex); //Now that we have the buffer index let's populate the rainBucket[] with data from eeprom loadRainArray(eepromIndex); isDataOnEeprom = true; break; } } // if (!isDataOnEeprom) // Added for the first time it is run on a new Arduino { DEBUG_PRINTLN(F("I didn't find valid EEPROM Index, so I'm writing one to location 0")); eepromIndex = EEPROM_BUFFER_LOCATION; saveState(eepromIndex, 0xFE); saveState(eepromIndex + 1, 0xFE); //then I will clear out any bad data for (int i = 2; i <= E_BUFFER_LENGTH; i++) { saveState(i, 0x00); } } dataMillis = millis(); lastTipTime = millis() - oneHour; //why is this -oneHour?? Doesn't millis() start at 0 when first powered on? // request(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); wait(DWELL_TIME); request(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); wait(DWELL_TIME); // #ifdef DHT_ON dht.setup(HUMIDITY_SENSOR_DIGITAL_PIN); // Register all sensors to gw (they will be created as child devices) present(CHILD_ID_HUM, S_HUM); wait(DWELL_TIME); present(CHILD_ID_TEMP, S_TEMP); wait(DWELL_TIME); metric = getConfig().isMetric; .wait(DWELL_TIME); #endif // #ifdef LUX_ON present(CHILD_ID_LIGHT, S_LIGHT_LEVEL); wait(DWELL_TIME); lightSensor.begin(); #endif // DEBUG_PRINTLN(F("Radio Setup Complete!")); transmitRainData(); } void presentation() { sendSketchInfo(SKETCH_NAME, SKETCH_VERSION); wait(DWELL_TIME); present(CHILD_ID_RAIN_LOG, S_RAIN); wait(DWELL_TIME); present(CHILD_ID_TRIPPED_INDICATOR, S_MOTION); wait(DWELL_TIME); DEBUG_PRINTLN(F("Sensor Presentation Complete")); } // void loop() { // process(); if (state) { prettyFade(); // breathe if tripped } else { slowFlash(); // blink if not tripped } #ifdef DEBUG_ON // Serial Debug Block if ( (millis() - dataMillis) >= serialInterval) { for (int i = 24; i <= 120; i = i + 24) { updateSerialData(i); } dataMillis = millis(); } #endif // // let's constantly check to see if the rain in the past rainWindow hours is greater than rainSensorThreshold // int measure = 0; // Check to see if we need to show sensor tripped in this block for (int i = 0; i < rainWindow; i++) { measure += rainBucket [i]; if (measure != lastMeasure) { // DEBUG_PRINT(F("measure value (total rainBucket within rainWindow): ")); // DEBUG_PRINTLN(measure); lastMeasure = measure; } } // state = (measure >= (rainSensorThreshold * 100)); if (state != oldState) { send(msgTripped.set(state)); wait(DWELL_TIME); DEBUG_PRINT(F("New Sensor State... Sensor: ")); DEBUG_PRINTLN(state ? "Tripped" : "Not Tripped"); oldState = state; } // unsigned long tipDelay = millis() - lastRainTime; if (wasTippedBuffer) // if was tipped, then update the 24hour total and transmit to Vera { DEBUG_PRINTLN(F("Sensor Tipped")); DEBUG_PRINT(F("rainBucket [0] value: ")); DEBUG_PRINTLN(rainBucket [0]); send(msgRain.set((float)rainTotal(currentHour) / 100, 1)); //Calculate the total rain for the day wait(DWELL_TIME); wasTippedBuffer--; rainRate = ((oneHour) / tipDelay); if (rainRate != lastRainRate) { send(msgRainRate.set(rainRate, 1)); wait(DWELL_TIME); DEBUG_PRINT(F("RainRate= ")); DEBUG_PRINTLN(rainRate); lastRainRate = rainRate; } lastRainTime = lastTipTime; } // currentHour = hour(); if (currentHour != lastHour) { DEBUG_PRINTLN(F("One hour elapsed.")); send(msgRain.set((float)rainTotal(currentHour) / 100, 1)); // send today's rainfall wait(DWELL_TIME); saveState(eepromIndex, highByte(rainBucket[0])); saveState(eepromIndex + 1, lowByte(rainBucket[0])); DEBUG_PRINT(F("Saving rainBucket[0] to eeprom. rainBucket[0] = ")); DEBUG_PRINTLN(rainBucket[0]); for (int i = RAIN_BUCKET_SIZE - 1; i >= 0; i--)//cascade an hour of values back into the array { rainBucket [i + 1] = rainBucket [i]; } request(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); wait(DWELL_TIME); request(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); wait(DWELL_TIME); rainBucket[0] = 0; eepromIndex = eepromIndex + 2; if (eepromIndex > EEPROM_BUFFER_LOCATION + E_BUFFER_LENGTH) { eepromIndex = EEPROM_BUFFER_LOCATION; } DEBUG_PRINT(F("Writing to EEPROM. Index: ")); DEBUG_PRINTLN(eepromIndex); saveState(eepromIndex, 0xFE); saveState(eepromIndex + 1, 0xFE); requestTime(receiveTime); // sync the time every hour wait(DWELL_TIME); transmitRainData(); rainRate = 0; send(msgRainRate.set(rainRate, 1)); wait(DWELL_TIME); DEBUG_PRINTLN(F("Sending rainRate is 0 to controller")); lastHour = currentHour; } if (millis() - sensorPreviousMillis > DHT_LUX_DELAY) { #ifdef DHT_ON //DHT Code doDHT(); #endif #ifdef LUX_ON doLUX(); #endif sensorPreviousMillis = millis(); } } // #ifdef DHT_ON void doDHT(void) { float temperature = dht.getTemperature(); if (isnan(temperature)) { DEBUG_PRINTLN(F("Failed reading temperature from DHT")); } else if (temperature != lastTemp) { lastTemp = temperature; if (!metric) { temperature = dht.toFahrenheit(temperature); } gw.send(msgTemp.set(temperature, 1)); gw.wait(DWELL_TIME); DEBUG_PRINT(F("Temperature is: ")); DEBUG_PRINTLN(temperature); } float humidity = dht.getHumidity();; if (isnan(humidity)) { DEBUG_PRINTLN(F("Failed reading humidity from DHT")); } else if (humidity != lastHum) { lastHum = humidity; gw.send(msgHum.set(humidity, 1)); gw.wait(DWELL_TIME); DEBUG_PRINT(F("Humidity is: ")); DEBUG_PRINTLN(humidity); } } #endif // #ifdef LUX_ON void doLUX(void) { unsigned int lux = lightSensor.readLightLevel();// Get Lux value DEBUG_PRINT(F("Current LUX Level: ")); DEBUG_PRINTLN(lux); heartbeat++; if (lux != lastlux || heartbeat > 10) { gw.send(msg.set(lux)); lastlux = lux; } if (heartbeat > 10) { heartbeat = 0; } } #endif // void sensorTipped() { unsigned long thisTipTime = millis(); if (thisTipTime - lastTipTime > 100UL) { rainBucket[0] += CALIBRATE_FACTOR; // adds CALIBRATE_FACTOR hundredths of unit each tip wasTippedBuffer++; } lastTipTime = thisTipTime; } // int rainTotal(int hours) { int total = 0; for ( int i = 0; i <= hours; i++) { total += rainBucket [i]; } return total; } void updateSerialData(int x) { DEBUG_PRINT(F("Rain last ")); DEBUG_PRINT(x); DEBUG_PRINTLN(F(" hours: ")); float tipCount = 0; for (int i = 0; i < x; i++) { tipCount = tipCount + rainBucket [i]; } tipCount = tipCount / 100; DEBUG_PRINTLN(tipCount); } void loadRainArray(int value) // retrieve stored rain array from EEPROM on powerup { for (int i = 0; i < RAIN_BUCKET_SIZE; i++) { value = value - 2; if (value < EEPROM_BUFFER_LOCATION) { value = EEPROM_BUFFER_LOCATION + E_BUFFER_LENGTH; } DEBUG_PRINT(F("EEPROM location: ")); DEBUG_PRINTLN(value); byte rainValueHigh = loadState(value); byte rainValueLow = loadState(value + 1); unsigned int rainValue = rainValueHigh << 8; rainValue |= rainValueLow; rainBucket[i + 1] = rainValue; // DEBUG_PRINT(F("rainBucket[ value: ")); DEBUG_PRINT(i + 1); DEBUG_PRINT(F("] value: ")); DEBUG_PRINTLN(rainBucket[i + 1]); } } void transmitRainData(void) { DEBUG_PRINT(F("In transmitRainData. currentHour = ")); DEBUG_PRINTLN(currentHour); int rainUpdateTotal = 0; for (int i = currentHour; i >= 0; i--) { rainUpdateTotal += rainBucket[i]; DEBUG_PRINT(F("Adding rainBucket[")); DEBUG_PRINT(i); DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } DEBUG_PRINT(F("TX Day 1: rainUpdateTotal = ")); DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR1.set((float)rainUpdateTotal / 100.0, 1)); //Send current day rain totals (resets at midnight) wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 24; i > currentHour; i--) { rainUpdateTotal += rainBucket[i]; DEBUG_PRINT(F("Adding rainBucket[")); DEBUG_PRINT(i); DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } DEBUG_PRINT(F("TX Day 2: rainUpdateTotal = ")); DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR2.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 48; i > currentHour + 24; i--) { rainUpdateTotal += rainBucket[i]; DEBUG_PRINT(F("Adding rainBucket[")); DEBUG_PRINT(i); DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } DEBUG_PRINT(F("TX Day 3: rainUpdateTotal = ")); DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR3.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 72; i > currentHour + 48; i--) { rainUpdateTotal += rainBucket[i]; DEBUG_PRINT(F("Adding rainBucket[")); DEBUG_PRINT(i); DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } DEBUG_PRINT(F("TX Day 4: rainUpdateTotal = ")); DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR4.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 96; i > currentHour + 72; i--) { rainUpdateTotal += rainBucket[i]; DEBUG_PRINT(F("Adding rainBucket[")); DEBUG_PRINT(i); DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } DEBUG_PRINT(F("TX Day 5: rainUpdateTotal = ")); DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR5.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); } void getVariables(const MyMessage &message) { if (message.sensor == CHILD_ID_RAIN_LOG) { // nothing to do here } else if (message.sensor == CHILD_ID_TRIPPED_INDICATOR) { if (message.type == V_VAR1) { rainWindow = atoi(message.data); if (rainWindow > 120) { rainWindow = 120; } else if (rainWindow < 1) { rainWindow = 1; } if (rainWindow != atoi(message.data)) // if I changed the value back inside the boundries, push that number back to Vera { send(msgTrippedVar1.set(rainWindow)); } } else if (message.type == V_VAR2) { rainSensorThreshold = atoi(message.data); if (rainSensorThreshold > 10000) { rainSensorThreshold = 10000; } else if (rainSensorThreshold < 1) { rainSensorThreshold = 1; } if (rainSensorThreshold != atoi(message.data)) // if I changed the value back inside the boundries, push that number back to Vera { send(msgTrippedVar2.set(rainSensorThreshold)); } } } } void prettyFade(void) { float val = (exp(sin(millis() / 2000.0 * PI)) - 0.36787944) * 108.0; analogWrite(ledPin, val); } void slowFlash(void) { static boolean ledState = true; static unsigned long pulseStart = millis(); if (millis() - pulseStart < 100UL) { digitalWrite(ledPin, !ledState); pulseStart = millis(); } } void receiveTime(unsigned long time) { DEBUG_PRINTLN(F("Time received...")); setTime(time); char theTime[6]; sprintf(theTime, "%d:%2d", hour(), minute()); DEBUG_PRINTLN(theTime); }
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@niccodemi syntax for time functions is:
requestTime(); // Request latest time from controller // This is called when a new time value was received void receiveTime(unsigned long controllerTime) { }
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@AWI thank you. Sketch compiles now but after uploading it still doesn't work - serial monitor is blank (debug on).
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Using the new code for version 2.0.0 i'm getting this errors:
C:\Users\marco\Documents\Arduino\Nova pasta\RainGauge\RainGauge.ino: In function 'void setup()':
RainGauge:145: error: 'timeStatus' was not declared in this scope
while (timeStatus() == timeNotSet && millis() - functionTimeout < 30000UL)
RainGauge:145: error: 'timeNotSet' was not declared in this scope
while (timeStatus() == timeNotSet && millis() - functionTimeout < 30000UL)
RainGauge:152: error: 'hour' was not declared in this scope
currentHour = hour();
C:\Users\marco\Documents\Arduino\Nova pasta\RainGauge\RainGauge.ino: In function 'void loop()':
RainGauge:299: error: 'hour' was not declared in this scope
currentHour = hour();
C:\Users\marco\Documents\Arduino\Nova pasta\RainGauge\RainGauge.ino: In function 'void receiveTime(long unsigned int)':
RainGauge:597: error: 'setTime' was not declared in this scope
setTime(time);
RainGauge:599: error: 'hour' was not declared in this scope
sprintf(theTime, "%d:%2d", hour(), minute());
RainGauge:599: error: 'minute' was not declared in this scope
sprintf(theTime, "%d:%2d", hour(), minute());
Using library MySensors at version 2.0.0 in folder: C:\Users\marco\Documents\Arduino\libraries\MySensors
Using library SPI at version 1.0 in folder: C:\Users\marco\AppData\Local\Arduino15\packages\arduino\hardware\avr\1.6.13\libraries\SPI
Using library Wire at version 1.0 in folder: C:\Users\marco\AppData\Local\Arduino15\packages\arduino\hardware\avr\1.6.13\libraries\Wire
exit status 1
'timeStatus' was not declared in this scopeDoes anyone now how to fix this ??
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@mrc-core is this the sketch you are using?
/* Arduino Tipping Bucket Rain Gauge April 26, 2015 Version 1.4.1 alpha Arduino Tipping Bucket Rain Gauge Utilizing a tipping bucket sensor, your Vera home automation controller and the MySensors.org gateway you can measure and sense local rain. This sketch will create two devices on your Vera controller. One will display your total precipitation for the last 5 days. The other, a sensor that changes state if there is recent rain (up to last 120 hours) above a threshold. Both these settings are user definable. There is a build overview video here: https://youtu.be/1eMfKQaLROo This sketch features the following: * Allows you to set the rain threshold in mm * Allows you to determine the tripped indicator window up to 120 hours. * Displays the last 5 days of rain in Variable1 through Variable5 of the Rain Sensor device * Configuration changes to Sensor device updated every hour * Should run on any Arduino * Will retain Tripped/Not Tripped status and data in a power interruption, saving small amount of data to EEPROM (Circular Buffer to maximize life of EEPROM) * LED status indicator * Optional Temp/Humidity (DHT-22 or DHT-11) and Light LUX (BH1750) sensors. To use, uncomment #define DHT_ON and/or #define LUX_ON * Optionally send total accumulation of each day's rainfall or send only individual days rainfall totals. Comment out #define USE_DAILY to display individual daily rainfall. by @BulldogLowell and @PeteWill for free public use */ // Enable debug prints to serial monitor #define MY_DEBUG // Enable and select radio type attached #define MY_RADIO_NRF24 //#define MY_RADIO_RFM69 //#define MY_NODE_ID 7 #include <SPI.h> #include <MySensors.h> #include <math.h> #include <Time.h> #define SKETCH_NAME "Rain Gauge" #define SKETCH_VERSION "1.4.1a" #define DWELL_TIME 125 // this allows for radio to come back to power after a transmission, ideally 0 //#define DEBUG_ON // comment out this line to disable serial debug #define DHT_ON // uncomment out this line to enable DHT sensor #define LUX_ON // uncomment out this line to enable BH1750 sensor //#define USE_DAILY // displays each time segment as an accumulation of prior periods inclusive. Comment out to display individual daily rainfall totals in the variables sent to your controller. #define TIP_SENSOR_PIN 3 #define CALIBRATE_FACTOR 60 // amount of rain per rain bucket tip e.g. 5 is .05mm #define DHT_LUX_DELAY 300000 //Delay in milliseconds that the DHT and LUX sensors will wait before sending data #define CHILD_ID_RAIN_LOG 3 // Keeps track of accumulated rainfall #define CHILD_ID_TRIPPED_INDICATOR 4 // Indicates Tripped when rain detected #define EEPROM_BUFFER_LOCATION 0 // location of the EEPROM circular buffer #define E_BUFFER_LENGTH 240 #define RAIN_BUCKET_SIZE 120 #ifdef DEBUG_ON #define DEBUG_PRINT(x) Serial.print(x) #define DEBUG_PRINTLN(x) Serial.println(x) #define SERIAL_START(x) Serial.begin(x) #else #define DEBUG_PRINT(x) #define DEBUG_PRINTLN(x) #define SERIAL_START(x) #endif // MyMessage msgRainRate(CHILD_ID_RAIN_LOG, V_RAINRATE); MyMessage msgRain(CHILD_ID_RAIN_LOG, V_RAIN); // MyMessage msgRainVAR1(CHILD_ID_RAIN_LOG, V_VAR1); MyMessage msgRainVAR2(CHILD_ID_RAIN_LOG, V_VAR2); MyMessage msgRainVAR3(CHILD_ID_RAIN_LOG, V_VAR3); MyMessage msgRainVAR4(CHILD_ID_RAIN_LOG, V_VAR4); MyMessage msgRainVAR5(CHILD_ID_RAIN_LOG, V_VAR5); // MyMessage msgTripped(CHILD_ID_TRIPPED_INDICATOR, V_TRIPPED); MyMessage msgTrippedVar1(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); MyMessage msgTrippedVar2(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); // #ifdef DHT_ON #include <DHT.h> #define CHILD_ID_HUM 0 #define CHILD_ID_TEMP 1 #define HUMIDITY_SENSOR_DIGITAL_PIN 8 DHT dht; float lastTemp; float lastHum; boolean metric = true; MyMessage msgHum(CHILD_ID_HUM, V_HUM); MyMessage msgTemp(CHILD_ID_TEMP, V_TEMP); #endif // #ifdef LUX_ON //BH1750 is connected to SCL (analog input A5) and SDA (analog input A4) #include <BH1750.h> #include <Wire.h> #define CHILD_ID_LIGHT 2 BH1750 lightSensor; MyMessage msg(CHILD_ID_LIGHT, V_LIGHT_LEVEL); unsigned int lastlux; byte heartbeat = 10; //Used to send the light lux to gateway as soon as the device is restarted and after the DHT_LUX_DELAY has happened 10 times #endif unsigned long sensorPreviousMillis; int eepromIndex; int ledPin = 5; // Pin the LED is connected to. PWM capable pin required unsigned long dataMillis; unsigned long serialInterval = 600000UL; const unsigned long oneHour = 3600000UL; unsigned long lastTipTime; unsigned long lastRainTime; //Used for rainRate calculation unsigned int rainBucket [RAIN_BUCKET_SIZE] ; /* 24 hours x 5 Days = 120 hours */ unsigned int rainRate = 0; byte rainWindow = 72; //default rain window in hours. Will be overwritten with msgTrippedVar1. volatile int wasTippedBuffer = 0; int rainSensorThreshold = 50; //default rain sensor sensitivity in hundredths. Will be overwritten with msgTrippedVar2. byte state = 0; byte oldState = -1; unsigned int lastRainRate = 0; int lastMeasure = 0; boolean gotTime = false; byte lastHour; byte currentHour; // void setup() { SERIAL_START(115200); // // Set up the IO pinMode(TIP_SENSOR_PIN, INPUT_PULLUP); attachInterrupt (digitalPinToInterrupt(TIP_SENSOR_PIN), sensorTipped, FALLING); // depending on location of the hall effect sensor may need CHANGE pinMode(ledPin, OUTPUT); digitalWrite(ledPin, HIGH); // //Sync time with the server, this will be called hourly in order to keep time from creeping with the crystal // unsigned long functionTimeout = millis(); while (timeStatus() == timeNotSet && millis() - functionTimeout < 30000UL) { requestTime(); DEBUG_PRINTLN(F("Getting Time")); wait(1000); // call once per second DEBUG_PRINTLN(F(".")); } currentHour = hour(); lastHour = hour(); // //retrieve from EEPROM stored values on a power cycle. // boolean isDataOnEeprom = false; for (int i = 0; i < E_BUFFER_LENGTH; i++) { byte locator = loadState(EEPROM_BUFFER_LOCATION + i); if (locator == 0xFE) // found the EEPROM circular buffer index { eepromIndex = EEPROM_BUFFER_LOCATION + i; DEBUG_PRINT(F("EEPROM Index ")); DEBUG_PRINTLN(eepromIndex); //Now that we have the buffer index let's populate the rainBucket[] with data from eeprom loadRainArray(eepromIndex); isDataOnEeprom = true; break; } } // if (!isDataOnEeprom) // Added for the first time it is run on a new Arduino { DEBUG_PRINTLN(F("I didn't find valid EEPROM Index, so I'm writing one to location 0")); eepromIndex = EEPROM_BUFFER_LOCATION; saveState(eepromIndex, 0xFE); saveState(eepromIndex + 1, 0xFE); //then I will clear out any bad data for (int i = 2; i <= E_BUFFER_LENGTH; i++) { saveState(i, 0x00); } } dataMillis = millis(); lastTipTime = millis() - oneHour; //why is this -oneHour?? Doesn't millis() start at 0 when first powered on? // request(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); wait(DWELL_TIME); request(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); wait(DWELL_TIME); // #ifdef DHT_ON dht.setup(HUMIDITY_SENSOR_DIGITAL_PIN); wait(DWELL_TIME); metric = getConfig().isMetric; #endif // #ifdef LUX_ON wait(DWELL_TIME); lightSensor.begin(); #endif // DEBUG_PRINTLN(F("Radio Setup Complete!")); transmitRainData(); } void presentation() { // Register all sensors to gw (they will be created as child devices) sendSketchInfo(SKETCH_NAME, SKETCH_VERSION); wait(DWELL_TIME); present(CHILD_ID_RAIN_LOG, S_RAIN); wait(DWELL_TIME); present(CHILD_ID_TRIPPED_INDICATOR, S_MOTION); wait(DWELL_TIME); #ifdef DHT_ON present(CHILD_ID_HUM, S_HUM); wait(DWELL_TIME); present(CHILD_ID_TEMP, S_TEMP); wait(DWELL_TIME); #endif #ifdef LUX_ON present(CHILD_ID_LIGHT, S_LIGHT_LEVEL); #endif DEBUG_PRINTLN(F("Sensor Presentation Complete")); } void loop() { if (state) { prettyFade(); // breathe if tripped } else { slowFlash(); // blink if not tripped } #ifdef DEBUG_ON // Serial Debug Block if ( (millis() - dataMillis) >= serialInterval) { for (int i = 24; i <= 120; i = i + 24) { updateSerialData(i); } dataMillis = millis(); } #endif // // let's constantly check to see if the rain in the past rainWindow hours is greater than rainSensorThreshold // int measure = 0; // Check to see if we need to show sensor tripped in this block for (int i = 0; i < rainWindow; i++) { measure += rainBucket [i]; if (measure != lastMeasure) { // DEBUG_PRINT(F("measure value (total rainBucket within rainWindow): ")); // DEBUG_PRINTLN(measure); lastMeasure = measure; } } // state = (measure >= (rainSensorThreshold * 100)); if (state != oldState) { send(msgTripped.set(state)); wait(DWELL_TIME); DEBUG_PRINT(F("New Sensor State... Sensor: ")); DEBUG_PRINTLN(state ? "Tripped" : "Not Tripped"); oldState = state; } // unsigned long tipDelay = millis() - lastRainTime; if (wasTippedBuffer) // if was tipped, then update the 24hour total and transmit to Vera { DEBUG_PRINTLN(F("Sensor Tipped")); DEBUG_PRINT(F("rainBucket [0] value: ")); DEBUG_PRINTLN(rainBucket [0]); send(msgRain.set((float)rainTotal(currentHour) / 100, 1)); //Calculate the total rain for the day wait(DWELL_TIME); wasTippedBuffer--; rainRate = ((oneHour) / tipDelay); if (rainRate != lastRainRate) { send(msgRainRate.set(rainRate, 1)); wait(DWELL_TIME); DEBUG_PRINT(F("RainRate= ")); DEBUG_PRINTLN(rainRate); lastRainRate = rainRate; } lastRainTime = lastTipTime; } // currentHour = hour(); if (currentHour != lastHour) { DEBUG_PRINTLN(F("One hour elapsed.")); send(msgRain.set((float)rainTotal(currentHour) / 100, 1)); // send today's rainfall wait(DWELL_TIME); saveState(eepromIndex, highByte(rainBucket[0])); saveState(eepromIndex + 1, lowByte(rainBucket[0])); DEBUG_PRINT(F("Saving rainBucket[0] to eeprom. rainBucket[0] = ")); DEBUG_PRINTLN(rainBucket[0]); for (int i = RAIN_BUCKET_SIZE - 1; i >= 0; i--)//cascade an hour of values back into the array { rainBucket [i + 1] = rainBucket [i]; } request(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); wait(DWELL_TIME); request(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); wait(DWELL_TIME); rainBucket[0] = 0; eepromIndex = eepromIndex + 2; if (eepromIndex > EEPROM_BUFFER_LOCATION + E_BUFFER_LENGTH) { eepromIndex = EEPROM_BUFFER_LOCATION; } DEBUG_PRINT(F("Writing to EEPROM. Index: ")); DEBUG_PRINTLN(eepromIndex); saveState(eepromIndex, 0xFE); saveState(eepromIndex + 1, 0xFE); requestTime(); // sync the time every hour wait(DWELL_TIME); transmitRainData(); rainRate = 0; send(msgRainRate.set(rainRate, 1)); wait(DWELL_TIME); DEBUG_PRINTLN(F("Sending rainRate is 0 to controller")); lastHour = currentHour; } if (millis() - sensorPreviousMillis > DHT_LUX_DELAY) { #ifdef DHT_ON //DHT Code doDHT(); #endif #ifdef LUX_ON doLUX(); #endif sensorPreviousMillis = millis(); } } // #ifdef DHT_ON void doDHT(void) { float temperature = dht.getTemperature(); if (isnan(temperature)) { DEBUG_PRINTLN(F("Failed reading temperature from DHT")); } else if (temperature != lastTemp) { lastTemp = temperature; if (!metric) { temperature = dht.toFahrenheit(temperature); } send(msgTemp.set(temperature, 1)); wait(DWELL_TIME); DEBUG_PRINT(F("Temperature is: ")); DEBUG_PRINTLN(temperature); } float humidity = dht.getHumidity();; if (isnan(humidity)) { DEBUG_PRINTLN(F("Failed reading humidity from DHT")); } else if (humidity != lastHum) { lastHum = humidity; send(msgHum.set(humidity, 1)); wait(DWELL_TIME); DEBUG_PRINT(F("Humidity is: ")); DEBUG_PRINTLN(humidity); } } #endif // #ifdef LUX_ON void doLUX(void) { unsigned int lux = lightSensor.readLightLevel();// Get Lux value DEBUG_PRINT(F("Current LUX Level: ")); DEBUG_PRINTLN(lux); heartbeat++; if (lux != lastlux || heartbeat > 10) { send(msg.set(lux)); lastlux = lux; } if (heartbeat > 10) { heartbeat = 0; } } #endif // void sensorTipped() { unsigned long thisTipTime = millis(); if (thisTipTime - lastTipTime > 100UL) { rainBucket[0] += CALIBRATE_FACTOR; // adds CALIBRATE_FACTOR hundredths of unit each tip wasTippedBuffer++; } lastTipTime = thisTipTime; } // int rainTotal(int hours) { int total = 0; for ( int i = 0; i <= hours; i++) { total += rainBucket [i]; } return total; } void updateSerialData(int x) { DEBUG_PRINT(F("Rain last ")); DEBUG_PRINT(x); DEBUG_PRINTLN(F(" hours: ")); float tipCount = 0; for (int i = 0; i < x; i++) { tipCount = tipCount + rainBucket [i]; } tipCount = tipCount / 100; DEBUG_PRINTLN(tipCount); } void loadRainArray(int value) // retrieve stored rain array from EEPROM on powerup { for (int i = 0; i < RAIN_BUCKET_SIZE; i++) { value = value - 2; if (value < EEPROM_BUFFER_LOCATION) { value = EEPROM_BUFFER_LOCATION + E_BUFFER_LENGTH; } DEBUG_PRINT(F("EEPROM location: ")); DEBUG_PRINTLN(value); byte rainValueHigh = loadState(value); byte rainValueLow = loadState(value + 1); unsigned int rainValue = rainValueHigh << 8; rainValue |= rainValueLow; rainBucket[i + 1] = rainValue; // DEBUG_PRINT(F("rainBucket[ value: ")); DEBUG_PRINT(i + 1); DEBUG_PRINT(F("] value: ")); DEBUG_PRINTLN(rainBucket[i + 1]); } } void transmitRainData(void) { DEBUG_PRINT(F("In transmitRainData. currentHour = ")); DEBUG_PRINTLN(currentHour); int rainUpdateTotal = 0; for (int i = currentHour; i >= 0; i--) { rainUpdateTotal += rainBucket[i]; DEBUG_PRINT(F("Adding rainBucket[")); DEBUG_PRINT(i); DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } DEBUG_PRINT(F("TX Day 1: rainUpdateTotal = ")); DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR1.set((float)rainUpdateTotal / 100.0, 1)); //Send current day rain totals (resets at midnight) wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 24; i > currentHour; i--) { rainUpdateTotal += rainBucket[i]; DEBUG_PRINT(F("Adding rainBucket[")); DEBUG_PRINT(i); DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } DEBUG_PRINT(F("TX Day 2: rainUpdateTotal = ")); DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR2.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 48; i > currentHour + 24; i--) { rainUpdateTotal += rainBucket[i]; DEBUG_PRINT(F("Adding rainBucket[")); DEBUG_PRINT(i); DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } DEBUG_PRINT(F("TX Day 3: rainUpdateTotal = ")); DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR3.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 72; i > currentHour + 48; i--) { rainUpdateTotal += rainBucket[i]; DEBUG_PRINT(F("Adding rainBucket[")); DEBUG_PRINT(i); DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } DEBUG_PRINT(F("TX Day 4: rainUpdateTotal = ")); DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR4.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 96; i > currentHour + 72; i--) { rainUpdateTotal += rainBucket[i]; DEBUG_PRINT(F("Adding rainBucket[")); DEBUG_PRINT(i); DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } DEBUG_PRINT(F("TX Day 5: rainUpdateTotal = ")); DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR5.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); } void receive(const MyMessage &message) { if (message.sensor == CHILD_ID_RAIN_LOG) { // nothing to do here } else if (message.sensor == CHILD_ID_TRIPPED_INDICATOR) { if (message.type == V_VAR1) { rainWindow = atoi(message.data); if (rainWindow > 120) { rainWindow = 120; } else if (rainWindow < 1) { rainWindow = 1; } if (rainWindow != atoi(message.data)) // if I changed the value back inside the boundries, push that number back to Vera { send(msgTrippedVar1.set(rainWindow)); } } else if (message.type == V_VAR2) { rainSensorThreshold = atoi(message.data); if (rainSensorThreshold > 10000) { rainSensorThreshold = 10000; } else if (rainSensorThreshold < 1) { rainSensorThreshold = 1; } if (rainSensorThreshold != atoi(message.data)) // if I changed the value back inside the boundries, push that number back to Vera { send(msgTrippedVar2.set(rainSensorThreshold)); } } } } void prettyFade(void) { float val = (exp(sin(millis() / 2000.0 * PI)) - 0.36787944) * 108.0; analogWrite(ledPin, val); } void slowFlash(void) { static boolean ledState = true; static unsigned long pulseStart = millis(); if (millis() - pulseStart < 100UL) { digitalWrite(ledPin, !ledState); pulseStart = millis(); } } void receiveTime(unsigned long time) { DEBUG_PRINTLN(F("Time received...")); setTime(time); char theTime[6]; sprintf(theTime, "%d:%2d", hour(), minute()); DEBUG_PRINTLN(theTime); }
It compiles fine with Arduino IDE 1.6.5, Mysensors 2.0.0 and libraries (Time, BH1750).
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Yes that's the one.
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Using IDE 1.6.5 i get this:
In file included from C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:10:0:
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:18:18: error: variable 'monthStr1' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr1[] PROGMEM = "January";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:19:18: error: variable 'monthStr2' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr2[] PROGMEM = "February";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:20:18: error: variable 'monthStr3' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr3[] PROGMEM = "March";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:21:18: error: variable 'monthStr4' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr4[] PROGMEM = "April";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:22:18: error: variable 'monthStr5' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr5[] PROGMEM = "May";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:23:18: error: variable 'monthStr6' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr6[] PROGMEM = "June";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:24:18: error: variable 'monthStr7' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr7[] PROGMEM = "July";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:25:18: error: variable 'monthStr8' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr8[] PROGMEM = "August";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:26:18: error: variable 'monthStr9' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr9[] PROGMEM = "September";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:27:19: error: variable 'monthStr10' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr10[] PROGMEM = "October";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:28:19: error: variable 'monthStr11' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr11[] PROGMEM = "November";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:29:19: error: variable 'monthStr12' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthStr12[] PROGMEM = "December";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:31:22: error: variable 'monthNames_P' must be const in order to be put into read-only section by means of 'attribute((progmem))'
PGM_P monthNames_P[] PROGMEM =
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:37:26: error: variable 'monthShortNames_P' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char monthShortNames_P[] PROGMEM = "ErrJanFebMarAprMayJunJulAugSepOctNovDec";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:39:16: error: variable 'dayStr0' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char dayStr0[] PROGMEM = "Err";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:40:16: error: variable 'dayStr1' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char dayStr1[] PROGMEM = "Sunday";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:41:16: error: variable 'dayStr2' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char dayStr2[] PROGMEM = "Monday";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:42:16: error: variable 'dayStr3' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char dayStr3[] PROGMEM = "Tuesday";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:43:16: error: variable 'dayStr4' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char dayStr4[] PROGMEM = "Wednesday";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:44:16: error: variable 'dayStr5' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char dayStr5[] PROGMEM = "Thursday";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:45:16: error: variable 'dayStr6' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char dayStr6[] PROGMEM = "Friday";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:46:16: error: variable 'dayStr7' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char dayStr7[] PROGMEM = "Saturday";
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:48:20: error: variable 'dayNames_P' must be const in order to be put into read-only section by means of 'attribute((progmem))'
PGM_P dayNames_P[] PROGMEM = { dayStr0,dayStr1,dayStr2,dayStr3,dayStr4,dayStr5,dayStr6,dayStr7};
^
C:\Users\marco\Documents\Arduino\libraries\Time\DateStrings.cpp:49:24: error: variable 'dayShortNames_P' must be const in order to be put into read-only section by means of 'attribute((progmem))'
char dayShortNames_P[] PROGMEM = "ErrSunMonTueWedThrFriSat";
^
Erro ao compilar.
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@mrc-core Remove folder "Time" from your libraries folder, then download the "MySensorsArduinoExamples" zip from this link and extract Time library to your libraries folder. Restart Arduino IDE and try again.
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Hi All,
Can you run this of 2 x AA batteries, does it go into sleep? It seems to fade the LED al the time, so I guess it will drain the batteries quick quickly? Does anyone have experience in powering this?
Regards
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@esawyja No, currently this example is written to be powered by external power so it wouldn't work well with batteries.
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Hi friends,
here is my replica of Rain Guage MySensors project
photos:
https://goo.gl/photos/4kA7T4d8SsDBRrrS7The sketch is adopted for 'Adafruit Unified Sensor by Adafruit' + 'DHT sensor library' just uncomment both DHT_ON and DHT_ADAFRUIT and Yes, I'm using rfm69hw radio with encryption enabled
3d bucket model: proposal to split it on a 3 part (i split on 2 parts now and have some troubles)#define MY_RFM69_ENABLE_ENCRYPTION /* Arduino Tipping Bucket Rain Gauge April 26, 2015 Version 2.0 Arduino Tipping Bucket Rain Gauge Utilizing a tipping bucket sensor, your Vera home automation controller and the MySensors.org gateway you can measure and sense local rain. This sketch will create two devices on your Vera controller. One will display your total precipitation for the last 5 days. The other, a sensor that changes state if there is recent rain (up to last 120 hours) above a threshold. Both these settings are user definable. There is a build overview video here: https://youtu.be/1eMfKQaLROo This sketch features the following: * Allows you to set the rain threshold in mm * Allows you to determine the tripped indicator window up to 120 hours. * Displays the last 5 days of rain in Variable1 through Variable5 of the Rain Sensor device * Configuration changes to Sensor device updated every hour * Should run on any Arduino * Will retain Tripped/Not Tripped status and data in a power interruption, saving small amount of data to EEPROM (Circular Buffer to maximize life of EEPROM) * LED status indicator * Optional Temp/Humidity (DHT-22 or DHT-11) and Light LUX (BH1750) sensors. To use, uncomment #define DHT_ON and/or #define LUX_ON * Optionally send total accumulation of each day's rainfall or send only individual days rainfall totals. Uncomment #define USE_DAILY to display individual daily rainfall. If it is commented out it will display a cumulative total rainfall (day4 = day1+day2+day3+day4 etc) by @BulldogLowell and @PeteWill for free public use */ // Enable debug prints to serial monitor //#define MY_DEBUG //#define MY_DEBUG_VERBOSE #define MY_NODE_ID AUTO // Enable and select radio type attached //#define MY_RADIO_NRF24 #define MY_RADIO_RFM69 #define MY_IS_RFM69HW #define MY_RFM69_FREQUENCY RF69_433MHZ #define MY_RFM69_NETWORKID 100 #define MY_RFM69_TX_POWER 31 #include <math.h> #include <TimeLib.h> #include <MySensors.h> #define SKETCH_NAME "Rain Gauge" #define SKETCH_VERSION "2.0" #define DWELL_TIME 40 // this allows for radio to come back to power after a transmission, ideally 0 //#define DEBUG_ON // Rain gauge specific debug messages. #define DHT_ON // uncomment out this line to enable DHT sensor // 20170621 by Enfeet #define DHT_ADAFRUIT // uncomment out this line to enable DHT with 'Adafruit Unified Sensor by Adafruit' + 'DHT sensor library' //#define DHTTYPE DHT11 // DHT 11 #define DHTTYPE DHT22 // DHT 22 (AM2302) //#define DHTTYPE DHT21 // DHT 21 (AM2301) // /20170621 by Enfeet //#define LUX_ON // uncomment out this line to enable BH1750 sensor //#define USE_DAILY // Uncomment to display individual daily rainfall totals in the variables sent to your controller. If it's commented it will add each day to the next for a cumulative total. #define TIP_SENSOR_PIN 3 //d=112 mm //11689.863832 mm2 = 116,89863832 cm2 //42,77209787776081 mm //88 89 91 91 90 = 89,8 //0,4763039852757329 #define CALIBRATE_FACTOR 48 // amount of rain per rain bucket tip e.g. 5 is .05mm #define DHT_LUX_DELAY 300000 //Delay in milliseconds that the DHT and LUX sensors will wait before sending data #define CHILD_ID_RAIN_LOG 3 // Keeps track of accumulated rainfall #define CHILD_ID_TRIPPED_INDICATOR 4 // Indicates Tripped when rain detected #define EEPROM_BUFFER_LOCATION 0 // location of the EEPROM circular buffer #define E_BUFFER_LENGTH 240 #define RAIN_BUCKET_SIZE 120 #ifdef DEBUG_ON #define M_DEBUG_PRINT(x) Serial.print(x) #define M_DEBUG_PRINTLN(x) Serial.println(x) #define SERIAL_START(x) Serial.begin(x) #else #define M_DEBUG_PRINT(x) #define M_DEBUG_PRINTLN(x) #define SERIAL_START(x) #endif // MyMessage msgRainRate(CHILD_ID_RAIN_LOG, V_RAINRATE); MyMessage msgRain(CHILD_ID_RAIN_LOG, V_RAIN); // MyMessage msgRainVAR1(CHILD_ID_RAIN_LOG, V_VAR1); MyMessage msgRainVAR2(CHILD_ID_RAIN_LOG, V_VAR2); MyMessage msgRainVAR3(CHILD_ID_RAIN_LOG, V_VAR3); MyMessage msgRainVAR4(CHILD_ID_RAIN_LOG, V_VAR4); MyMessage msgRainVAR5(CHILD_ID_RAIN_LOG, V_VAR5); // MyMessage msgTripped(CHILD_ID_TRIPPED_INDICATOR, V_TRIPPED); MyMessage msgTrippedVar1(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); MyMessage msgTrippedVar2(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); // #ifdef DHT_ON // 20170621 by Enfeet #ifdef DHT_ADAFRUIT #include <Adafruit_Sensor.h> #include <DHT_U.h> #endif // /20170621 by Enfeet #include <DHT.h> #define CHILD_ID_HUM 0 #define CHILD_ID_TEMP 1 #define HUMIDITY_SENSOR_DIGITAL_PIN 8 #ifndef DHT_ADAFRUIT // 20170621 by Enfeet DHT dht; #else DHT_Unified dht(HUMIDITY_SENSOR_DIGITAL_PIN, DHTTYPE); sensors_event_t event; #endif // /20170621 by Enfeet float lastTemp; float lastHum; bool metric = true; MyMessage msgHum(CHILD_ID_HUM, V_HUM); MyMessage msgTemp(CHILD_ID_TEMP, V_TEMP); #endif // #ifdef LUX_ON //BH1750 is connected to SCL (analog input A5) and SDA (analog input A4) #include <BH1750.h> #include <Wire.h> #define CHILD_ID_LIGHT 2 BH1750 lightSensor; MyMessage msg(CHILD_ID_LIGHT, V_LIGHT_LEVEL); unsigned int lastlux; uint8_t heartbeat = 10; //Used to send the light lux to gateway as soon as the device is restarted and after the DHT_LUX_DELAY has happened 10 times #endif unsigned long sensorPreviousMillis; int eepromIndex; int tipSensorPin = 3; // Pin the tipping bucket is connected to. Must be interrupt capable pin int ledPin = 5; // Pin the LED is connected to. PWM capable pin required #ifdef DEBUG_ON unsigned long dataMillis; unsigned long serialInterval = 600000UL; #endif const unsigned long oneHour = 3600000UL; unsigned long lastTipTime; unsigned long lastRainTime; //Used for rainRate calculation unsigned int rainBucket [RAIN_BUCKET_SIZE] ; /* 24 hours x 5 Days = 120 hours */ unsigned int rainRate = 0; uint8_t rainWindow = 72; //default rain window in hours. Will be overwritten with msgTrippedVar1. volatile int wasTippedBuffer = 0; int rainSensorThreshold = 50; //default rain sensor sensitivity in hundredths. Will be overwritten with msgTrippedVar2. uint8_t state = 0; uint8_t oldState = 2; //Setting the default to something other than 1 or 0 unsigned int lastRainRate = 0; int lastMeasure = 0; bool gotTime = false; uint8_t lastHour; uint8_t currentHour; // void presentation() { // Register all sensors to gw (they will be created as child devices) sendSketchInfo(SKETCH_NAME, SKETCH_VERSION); wait(DWELL_TIME); present(CHILD_ID_RAIN_LOG, S_RAIN); wait(DWELL_TIME); present(CHILD_ID_TRIPPED_INDICATOR, S_MOTION); wait(DWELL_TIME); #ifdef DHT_ON present(CHILD_ID_HUM, S_HUM); wait(DWELL_TIME); present(CHILD_ID_TEMP, S_TEMP); wait(DWELL_TIME); #endif #ifdef LUX_ON present(CHILD_ID_LIGHT, S_LIGHT_LEVEL); #endif M_DEBUG_PRINTLN(F("Sensor Presentation Complete")); } void setup() { #ifndef MY_DEBUG SERIAL_START(115200); //Start serial if MySensors debugging isn't enabled #endif // // Set up the IO pinMode(TIP_SENSOR_PIN, INPUT); attachInterrupt (digitalPinToInterrupt(TIP_SENSOR_PIN), sensorTipped, FALLING); // depending on location of the hall effect sensor may need CHANGE pinMode(ledPin, OUTPUT); digitalWrite(ledPin, HIGH); // //Sync time with the server // unsigned long functionTimeout = millis(); while (timeStatus() == timeNotSet && millis() - functionTimeout < 30000UL) { requestTime(); M_DEBUG_PRINTLN(F("Getting Time")); wait(1000); // call once per second M_DEBUG_PRINTLN(F(".")); } currentHour = hour(); lastHour = hour(); // //retrieve from EEPROM stored values on a power cycle. // bool isDataOnEeprom = false; for (int i = 0; i < E_BUFFER_LENGTH; i++) { uint8_t locator = loadState(EEPROM_BUFFER_LOCATION + i); if (locator == 0xFE) // found the EEPROM circular buffer index { eepromIndex = EEPROM_BUFFER_LOCATION + i; M_DEBUG_PRINT(F("EEPROM Index ")); M_DEBUG_PRINTLN(eepromIndex); //Now that we have the buffer index let's populate the rainBucket[] with data from eeprom loadRainArray(eepromIndex); isDataOnEeprom = true; break; } } // if (!isDataOnEeprom) // Added for the first time it is run on a new Arduino { M_DEBUG_PRINTLN(F("I didn't find valid EEPROM Index, so I'm writing one to location 0")); eepromIndex = EEPROM_BUFFER_LOCATION; saveState(eepromIndex, 0xFE); saveState(eepromIndex + 1, 0xFE); //then I will clear out any bad data for (int i = 2; i <= E_BUFFER_LENGTH; i++) { saveState(i, 0x00); } } #ifdef DEBUG_ON dataMillis = millis(); #endif lastTipTime = millis(); // request(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); wait(DWELL_TIME); request(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); wait(DWELL_TIME); // #ifdef DHT_ON // 20170621 by Enfeet #ifndef DHT_ADAFRUIT dht.setup(HUMIDITY_SENSOR_DIGITAL_PIN); #else dht.begin(); #endif metric = getControllerConfig().isMetric; wait(DWELL_TIME); #endif // #ifdef LUX_ON lightSensor.begin(); #endif // transmitRainData(); //Setup complete send any data loaded from eeprom to gateway } void loop() { if (state) { prettyFade(); // breathe if tripped } else { slowFlash(); // blink if not tripped } #ifdef DEBUG_ON // Serial Debug Block if ( (millis() - dataMillis) >= serialInterval) { for (int i = 24; i <= 120; i = i + 24) { updateSerialData(i); } dataMillis = millis(); } #endif // // let's constantly check to see if the rain in the past rainWindow hours is greater than rainSensorThreshold // int measure = 0; // Check to see if we need to show sensor tripped in this block for (int i = 0; i < rainWindow; i++) { measure += rainBucket [i]; if (measure != lastMeasure) { // M_DEBUG_PRINT(F("measure value (total rainBucket within rainWindow): ")); // M_DEBUG_PRINTLN(measure); lastMeasure = measure; } } // state = (measure >= (rainSensorThreshold * 100)); if (state != oldState) { send(msgTripped.set(state)); wait(DWELL_TIME); M_DEBUG_PRINT(F("New Sensor State... Sensor: ")); M_DEBUG_PRINTLN(state ? "Tripped" : "Not Tripped"); oldState = state; } // unsigned long tipDelay = millis() - lastRainTime; if (wasTippedBuffer) // if was tipped, then update the 24hour total and transmit to Vera { M_DEBUG_PRINTLN(F("Sensor Tipped")); M_DEBUG_PRINT(F("rainBucket [0] value: ")); M_DEBUG_PRINTLN(rainBucket [0]); send(msgRain.set((float)rainTotal(currentHour) / 100, 1)); //Calculate the total rain for the day wait(DWELL_TIME); wasTippedBuffer--; rainRate = ((oneHour) / tipDelay); if (rainRate != lastRainRate) { send(msgRainRate.set(rainRate, 1)); wait(DWELL_TIME); M_DEBUG_PRINT(F("RainRate= ")); M_DEBUG_PRINTLN(rainRate); lastRainRate = rainRate; } lastRainTime = lastTipTime; } // currentHour = hour(); if (currentHour != lastHour) { M_DEBUG_PRINTLN(F("One hour elapsed.")); send(msgRain.set((float)rainTotal(currentHour) / 100, 1)); // send today's rainfall wait(DWELL_TIME); saveState(eepromIndex, highByte(rainBucket[0])); saveState(eepromIndex + 1, lowByte(rainBucket[0])); M_DEBUG_PRINT(F("Saving rainBucket[0] to eeprom. rainBucket[0] = ")); M_DEBUG_PRINTLN(rainBucket[0]); for (int i = RAIN_BUCKET_SIZE - 1; i >= 0; i--)//cascade an hour of values back into the array { rainBucket [i + 1] = rainBucket [i]; } request(CHILD_ID_TRIPPED_INDICATOR, V_VAR1); wait(DWELL_TIME); request(CHILD_ID_TRIPPED_INDICATOR, V_VAR2); wait(DWELL_TIME); rainBucket[0] = 0; eepromIndex = eepromIndex + 2; if (eepromIndex > EEPROM_BUFFER_LOCATION + E_BUFFER_LENGTH) { eepromIndex = EEPROM_BUFFER_LOCATION; } M_DEBUG_PRINT(F("Writing to EEPROM. Index: ")); M_DEBUG_PRINTLN(eepromIndex); saveState(eepromIndex, 0xFE); saveState(eepromIndex + 1, 0xFE); requestTime(); // sync the time every hour wait(DWELL_TIME); transmitRainData(); rainRate = 0; send(msgRainRate.set(rainRate, 1)); wait(DWELL_TIME); M_DEBUG_PRINTLN(F("Sending rainRate is 0 to controller")); lastHour = hour(); } if (millis() - sensorPreviousMillis > DHT_LUX_DELAY) { #ifdef DHT_ON //DHT Code doDHT(); #endif #ifdef LUX_ON doLUX(); #endif sensorPreviousMillis = millis(); } } // #ifdef DHT_ON void doDHT(void) { // 20170621 by Enfeet #ifndef DHT_ADAFRUIT float temperature = dht.getTemperature(); if (isnan(temperature)) #else dht.temperature().getEvent(&event); float temperature = event.temperature; if (isnan(event.temperature)) #endif // /20170621 by Enfeet { M_DEBUG_PRINTLN(F("Failed reading temperature from DHT")); } else if (temperature != lastTemp) { lastTemp = temperature; #ifndef DHT_ADAFRUIT if (!metric) { temperature = dht.toFahrenheit(temperature); } #endif send(msgTemp.set(temperature, 1)); wait(DWELL_TIME); M_DEBUG_PRINT(F("Temperature is: ")); M_DEBUG_PRINTLN(temperature); } // 20170621 by Enfeet #ifndef DHT_ADAFRUIT float humidity = dht.getHumidity();; if (isnan(humidity)) #else dht.humidity().getEvent(&event); float humidity = event.relative_humidity; if (isnan(event.relative_humidity)) #endif // /20170621 by Enfeet { M_DEBUG_PRINTLN(F("Failed reading humidity from DHT")); } else if (humidity != lastHum) { lastHum = humidity; send(msgHum.set(humidity, 1)); wait(DWELL_TIME); M_DEBUG_PRINT(F("Humidity is: ")); M_DEBUG_PRINTLN(humidity); } } #endif // #ifdef LUX_ON void doLUX(void) { unsigned int lux = lightSensor.readLightLevel();// Get Lux value M_DEBUG_PRINT(F("Current LUX Level: ")); M_DEBUG_PRINTLN(lux); heartbeat++; if (lux != lastlux || heartbeat > 10) { send(msg.set(lux)); lastlux = lux; } if (heartbeat > 10) { heartbeat = 0; } } #endif // void sensorTipped() { unsigned long thisTipTime = millis(); if (thisTipTime - lastTipTime > 100UL) { rainBucket[0] += CALIBRATE_FACTOR; // adds CALIBRATE_FACTOR hundredths of unit each tip wasTippedBuffer++; } lastTipTime = thisTipTime; } // int rainTotal(int hours) { int total = 0; for ( int i = 0; i <= hours; i++) { total += rainBucket [i]; } return total; } #ifdef DEBUG_ON void updateSerialData(int x) { M_DEBUG_PRINT(F("Rain last ")); M_DEBUG_PRINT(x); M_DEBUG_PRINTLN(F(" hours: ")); float tipCount = 0; for (int i = 0; i < x; i++) { tipCount = tipCount + rainBucket [i]; } tipCount = tipCount / 100; M_DEBUG_PRINTLN(tipCount); } #endif void loadRainArray(int eValue) // retrieve stored rain array from EEPROM on powerup { for (int i = 1; i < RAIN_BUCKET_SIZE; i++) { eValue = eValue - 2; if (eValue < EEPROM_BUFFER_LOCATION) { eValue = EEPROM_BUFFER_LOCATION + E_BUFFER_LENGTH; } M_DEBUG_PRINT(F("EEPROM location: ")); M_DEBUG_PRINTLN(eValue); uint8_t rainValueHigh = loadState(eValue); uint8_t rainValueLow = loadState(eValue + 1); unsigned int rainValue = rainValueHigh << 8; rainValue |= rainValueLow; rainBucket[i] = rainValue; // M_DEBUG_PRINT(F("rainBucket[ value: ")); M_DEBUG_PRINT(i); M_DEBUG_PRINT(F("] value: ")); M_DEBUG_PRINTLN(rainBucket[i]); } } void transmitRainData(void) { M_DEBUG_PRINT(F("In transmitRainData. currentHour = ")); M_DEBUG_PRINTLN(currentHour); int rainUpdateTotal = 0; for (int i = currentHour; i >= 0; i--) { rainUpdateTotal += rainBucket[i]; M_DEBUG_PRINT(F("Adding rainBucket[")); M_DEBUG_PRINT(i); M_DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } M_DEBUG_PRINT(F("TX Day 1: rainUpdateTotal = ")); M_DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR1.set((float)rainUpdateTotal / 100.0, 1)); //Send current day rain totals (resets at midnight) wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 24; i > currentHour; i--) { rainUpdateTotal += rainBucket[i]; M_DEBUG_PRINT(F("Adding rainBucket[")); M_DEBUG_PRINT(i); M_DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } M_DEBUG_PRINT(F("TX Day 2: rainUpdateTotal = ")); M_DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR2.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 48; i > currentHour + 24; i--) { rainUpdateTotal += rainBucket[i]; M_DEBUG_PRINT(F("Adding rainBucket[")); M_DEBUG_PRINT(i); M_DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } M_DEBUG_PRINT(F("TX Day 3: rainUpdateTotal = ")); M_DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR3.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 72; i > currentHour + 48; i--) { rainUpdateTotal += rainBucket[i]; M_DEBUG_PRINT(F("Adding rainBucket[")); M_DEBUG_PRINT(i); M_DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } M_DEBUG_PRINT(F("TX Day 4: rainUpdateTotal = ")); M_DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR4.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); #ifdef USE_DAILY rainUpdateTotal = 0; #endif for (int i = currentHour + 96; i > currentHour + 72; i--) { rainUpdateTotal += rainBucket[i]; M_DEBUG_PRINT(F("Adding rainBucket[")); M_DEBUG_PRINT(i); M_DEBUG_PRINTLN(F("] to rainUpdateTotal.")); } M_DEBUG_PRINT(F("TX Day 5: rainUpdateTotal = ")); M_DEBUG_PRINTLN((float)rainUpdateTotal / 100.0); send(msgRainVAR5.set((float)rainUpdateTotal / 100.0, 1)); wait(DWELL_TIME); } void receive(const MyMessage &message) { if (message.sensor == CHILD_ID_RAIN_LOG) { // nothing to do here } else if (message.sensor == CHILD_ID_TRIPPED_INDICATOR) { if (message.type == V_VAR1) { rainWindow = atoi(message.data); if (rainWindow > 120) { rainWindow = 120; } else if (rainWindow < 1) { rainWindow = 1; } if (rainWindow != atoi(message.data)) // if I changed the value back inside the boundries, push that number back to Vera { send(msgTrippedVar1.set(rainWindow)); } } else if (message.type == V_VAR2) { rainSensorThreshold = atoi(message.data); if (rainSensorThreshold > 10000) { rainSensorThreshold = 10000; } else if (rainSensorThreshold < 1) { rainSensorThreshold = 1; } if (rainSensorThreshold != atoi(message.data)) // if I changed the value back inside the boundries, push that number back to Vera { send(msgTrippedVar2.set(rainSensorThreshold)); } } } } void prettyFade(void) { float val = (exp(sin(millis() / 2000.0 * PI)) - 0.36787944) * 108.0; analogWrite(ledPin, val); } void slowFlash(void) { static bool ledState = true; static unsigned long pulseStart = millis(); if (millis() - pulseStart < 100UL) { digitalWrite(ledPin, !ledState); pulseStart = millis(); } } void receiveTime(unsigned long newTime) { M_DEBUG_PRINTLN(F("Time received...")); setTime(newTime); char theTime[6]; sprintf(theTime, "%d:%2d", hour(), minute()); M_DEBUG_PRINTLN(theTime); }
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SY
Enfeet
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@Enfeet I am interested in checking out your code (have not looked through it yet). I am to the point with my rain gauge design that I am ready to do the code for the sensor. Out of curiosity, what type of sensor did you use for your tipping bucket? I am using a magnetic reed switch. I had originally done a bucket design like the one you have, actually when I started my project, I modeled my original one off of that one. This is my modified design:
The magnet fits in the recessed hole in the side, no need to glue it in. The big difference is that the center divider is angled out to help better with the tipping action.Here is the rest of the sensor:
I just got the OpenSCAD file for the project cleaned up and I will be posting it to thingiverse later today.
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@dbemowsk , i take an original .stl files from the link provided: https://drive.google.com/drive/folders/0B3KGTJHUgpw1fkwtM3RreEF2QWg4eUdsUHdSQjl6UWx2Q3dPS19WSGdqd0pZQ3hhQk1TMkE
but in order to save a support material recreate and split it a little
The result are visible on photos (link in my previous post)
here is an .scad code of my modifications on top of original files, also i print them up side down
$fn=300; difference(){ translate([35,0,0]) import("Can.stl"); cube([210,150,150],center=true); } translate([62,0,0]) rotate([0,90,0]) difference(){ cylinder(d=10,h=3,center=true); cylinder(d=4,h=6,center=true); } difference(){ translate([-88,0,0]) sphere(d=300); translate([-90,0,0]) sphere(d=300); translate([61,0,0]) rotate([0,90,0]) cylinder(d=4,h=4,center=true); rotate([0,90,0]) difference(){ cylinder(d=310,h=208,center=true); cylinder(d=122.5+4,h=310,center=true); } } translate([54,0,0]) rotate([0,90,0]) difference(){ cylinder(d=122.5+4,h=108,center=true); cylinder(d=122.5,h=310,center=true); }
$fn=300; /* difference(){ translate([35,0,0]) import("Can.stl"); cube([210,150,150],center=true); } translate([62,0,0]) rotate([0,90,0]) difference(){ cylinder(d=10,h=3,center=true); cylinder(d=4,h=6,center=true); } difference(){ translate([-88,0,0]) sphere(d=300); translate([-90,0,0]) sphere(d=300); translate([61,0,0]) rotate([0,90,0]) cylinder(d=4,h=4,center=true); rotate([0,90,0]) difference(){ cylinder(d=310,h=208,center=true); cylinder(d=122.5+4,h=310,center=true); } } */ translate([54,0,0]) rotate([0,90,0]) difference(){ cylinder(d=122.5+4,h=40 ,center=true); cylinder(d=122.5,h=310,center=true); } translate([32,0,0]) rotate([0,90,0]) difference(){ cylinder(d=122.5+4+4,h=8 ,center=true); cylinder(d=122.5+4,h=9,center=true); }
The arduino code is also from original project (https://www.mysensors.org/build/rain) but i adopt it to Adafruit Unified Sensors Library and last version of Arduino IDE 1.8.3
SY
Enfeet
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Lets continue in correct topic https://forum.mysensors.org/topic/4821/rain-gauge/35