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2022-10-05 at 4:04 PM
#17374
I uploaded the “SDI12/b_address_change” sketch and the address of the sensor is correctly assigned at “2”. My sketch is below. I modified the DWRI CitSci code for the ClariVUE. Thanks
I uploaded the “SDI12/b_address_change” sketch and the address of the sensor is correctly assigned at “2”. My sketch is below. I modified the DWRI CitSci code for the ClariVUE. Thanks for taking a look!
Arduino
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/** ========================================================================= * @file DRWI_SIM7080LTE.ino * @brief Example for DRWI CitSci LTE sites. * * This example shows proper settings for the following configuration: * * Mayfly v1.1 board * EnviroDIY SIM7080 LTE module (with Hologram SIM card) * ES2 sensor * Campbell Scientific ClareVUE10 Turbidity sensor * * @author Sara Geleskie Damiano <sdamiano@stroudcenter.org> * @copyright (c) 2017-2022 Stroud Water Research Center (SWRC) * and the EnviroDIY Development Team * This example is published under the BSD-3 license. * * Hardware Platform: EnviroDIY Mayfly Arduino Datalogger * * DISCLAIMER: * THIS CODE IS PROVIDED "AS IS" - NO WARRANTY IS GIVEN. * * CASSI 6 version 2 * ======================================================================= */ // ========================================================================== // Defines for the Arduino IDE // NOTE: These are ONLY needed to compile with the Arduino IDE. // If you use PlatformIO, you should set these build flags in your // platformio.ini // ========================================================================== /** Start [defines] */ #ifndef TINY_GSM_RX_BUFFER #define TINY_GSM_RX_BUFFER 64 #endif #ifndef TINY_GSM_YIELD_MS #define TINY_GSM_YIELD_MS 2 #endif /** End [defines] */ // ========================================================================== // Include the libraries required for any data logger // ========================================================================== /** Start [includes] */ // The Arduino library is needed for every Arduino program. #include <Arduino.h> // EnableInterrupt is used by ModularSensors for external and pin change // interrupts and must be explicitly included in the main program. #include <EnableInterrupt.h> // Include the main header for ModularSensors #include <ModularSensors.h> /** End [includes] */ // ========================================================================== // Data Logging Options // ========================================================================== /** Start [logging_options] */ // The name of this program file const char* sketchName = "CASSI6.ino"; // Logger ID, also becomes the prefix for the name of the data file on SD card const char* LoggerID = "CASSI6"; // How frequently (in minutes) to log data const uint8_t loggingInterval = 3; // Your logger's timezone. const int8_t timeZone = -5; // Eastern Standard Time // NOTE: Daylight savings time will not be applied! Please use standard time! // Set the input and output pins for the logger // NOTE: Use -1 for pins that do not apply const int32_t serialBaud = 57600; // Baud rate for debugging const int8_t greenLED = 8; // Pin for the green LED const int8_t redLED = 9; // Pin for the red LED const int8_t buttonPin = 21; // Pin for debugging mode (ie, button pin) const int8_t wakePin = 31; // MCU interrupt/alarm pin to wake from sleep // Mayfly 0.x D31 = A7 const int8_t sdCardPwrPin = -1; // MCU SD card power pin const int8_t sdCardSSPin = 12; // SD card chip select/slave select pin const int8_t sensorPowerPin = 22; // MCU pin controlling main sensor power /** End [logging_options] */ // ========================================================================== // Wifi/Cellular Modem Options // ========================================================================== /** Start [sim_com_sim7080] */ // For almost anything based on the SIMCom SIM7080G #include <modems/SIMComSIM7080.h> // Create a reference to the serial port for the modem HardwareSerial& modemSerial = Serial1; // Use hardware serial if possible const int32_t modemBaud = 9600; // SIM7080 does auto-bauding by default, but // for simplicity we set to 9600 // Modem Pins - Describe the physical pin connection of your modem to your board // NOTE: Use -1 for pins that do not apply const int8_t modemVccPin = 18; // MCU pin controlling modem power --- Pin 18 is the power enable pin for the // bee socket on Mayfly v1.0, use -1 if using Mayfly 0.5b or if the bee socket // is constantly powered (ie you changed SJ18 on Mayfly 1.x to 3.3v) const int8_t modemStatusPin = 19; // MCU pin used to read modem status const int8_t modemSleepRqPin = 23; // MCU pin for modem sleep/wake request const int8_t modemLEDPin = redLED; // MCU pin connected an LED to show modem // status // Network connection information const char* apn = "hologram"; // APN connection name, typically Hologram unless you have a // different provider's SIM card. Change as needed // Create the modem object SIMComSIM7080 modem7080(&modemSerial, modemVccPin, modemStatusPin, modemSleepRqPin, apn); // Create an extra reference to the modem by a generic name SIMComSIM7080 modem = modem7080; /** End [sim_com_sim7080] */ // ========================================================================== // Using the Processor as a Sensor // ========================================================================== /** Start [processor_sensor] */ #include <sensors/ProcessorStats.h> // Create the main processor chip "sensor" - for general metadata const char* mcuBoardVersion = "v1.1"; ProcessorStats mcuBoard(mcuBoardVersion); /** End [processor_sensor] */ // ========================================================================== // Maxim DS3231 RTC (Real Time Clock) // ========================================================================== /** Start [ds3231] */ #include <sensors/MaximDS3231.h> // Create a DS3231 sensor object MaximDS3231 ds3231(1); /** End [ds3231] */ // \ // ========================================================================== // Decagon ES2 Conductivity and Temperature Sensor // ========================================================================== /** Start [es2] */ #include <sensors/DecagonES2.h> // NOTE: Use -1 for any pins that don't apply or aren't being used. const char* ES2SDI12address = "1"; // The SDI-12 Address of the ES2 const int8_t ES2Power = sensorPowerPin; // Power pin const int8_t ES2Data = 7; // The SDI12 data pin const uint8_t ES2NumberReadings = 5; // Create a Decagon ES2 sensor object DecagonES2 es2(*ES2SDI12address, ES2Power, ES2Data, ES2NumberReadings); \ /** End [es2] */ \ // ========================================================================== // Campbell ClariVUE Turbidity Sensor // ========================================================================== /** Start [clarivue] */ #include <sensors/CampbellClariVUE10.h> const char* ClariVUESDI12address = "2"; // The SDI-12 Address of the ClariVUE10 const int8_t ClariVUEPower = sensorPowerPin; // Power pin (-1 if unconnected) const int8_t ClariVUEData = 7; // The SDI12 data pin // NOTE: you should NOT take more than one readings. THe sensor already takes // and averages 8 by default. // Create a Campbell ClariVUE10 sensor object CampbellClariVUE10 clarivue(*ClariVUESDI12address, ClariVUEPower, ClariVUEData); \ // ========================================================================== // Creating the Variable Array[s] and Filling with Variable Objects // ========================================================================== /** Start [variable_arrays] */ Variable* variableList[] = { new DecagonES2_Cond (&es2), new DecagonES2_Temp (&es2), new CampbellClariVUE10_Turbidity(&clarivue, "", "Turbidity"), new MaximDS3231_Temp(&ds3231), new ProcessorStats_Battery(&mcuBoard), new Modem_SignalPercent(&modem), }; // All UUID's, device registration, and sampling feature information can be // pasted directly from Monitor My Watershed. // To get the list, click the "View token UUID list" button on the upper right // of the site page. // *** CAUTION --- CAUTION --- CAUTION --- CAUTION --- CAUTION *** // Check the order of your variables in the variable list!!! // Be VERY certain that they match the order of your UUID's! // Rearrange the variables in the variable list ABOVE if necessary to match! // Do not change the order of the variables in the section below. // *** CAUTION --- CAUTION --- CAUTION --- CAUTION --- CAUTION *** // Replace all of the text in the following section with the UUID array from // MonitorMyWatershed /* clang-format off */ // --------------------- Beginning of Token UUID List --------------------- const char *UUIDs[] = // UUID array for device sensors { "abcdefghijklmnopqrstuvwxyz", // Electrical conductivity (Decagon_ES-2_Cond) "abcdefghijklmnopqrstuvwxyz", // Temperature (Decagon_ES-2_Temp) "abcdefghijklmnopqrstuvwxyz", // Turbidity (Campbell_OBS3_Turb) "abcdefghijklmnopqrstuvwxyz", // Temperature (Maxim_DS3231_Temp) "abcdefghijklmnopqrstuvwxyz", // Battery voltage (EnviroDIY_Mayfly_Batt) "abcdefghijklmnopqrstuvwxyz" // Percent full scale (EnviroDIY_LTEB_SignalPercent) }; const char *registrationToken = "abcdefghijklmnopqrstuvwxyz"; // Device registration token const char *samplingFeature = "abcdefghijklmnopqrstuvwxyz"; // Sampling feature UUID // ----------------------- End of Token UUID List ----------------------- /* clang-format on */ // Count up the number of pointers in the array int variableCount = sizeof(variableList) / sizeof(variableList[6]); // Create the VariableArray object VariableArray varArray(variableCount, variableList, UUIDs); /** End [variable_arrays] */ // ========================================================================== // The Logger Object[s] // ========================================================================== /** Start [loggers] */ // Create a new logger instance Logger dataLogger(LoggerID, loggingInterval, &varArray); /** End [loggers] */ // ========================================================================== // Creating Data Publisher[s] // ========================================================================== /** Start [publishers] */ // Create a data publisher for the Monitor My Watershed/EnviroDIY POST endpoint #include <publishers/EnviroDIYPublisher.h> EnviroDIYPublisher EnviroDIYPOST(dataLogger, &modem.gsmClient, registrationToken, samplingFeature); /** End [publishers] */ // ========================================================================== // Working Functions // ========================================================================== /** Start [working_functions] */ // Flashes the LED's on the primary board void greenredflash(uint8_t numFlash = 4, uint8_t rate = 75) { for (uint8_t i = 0; i < numFlash; i++) { digitalWrite(greenLED, HIGH); digitalWrite(redLED, LOW); delay(rate); digitalWrite(greenLED, LOW); digitalWrite(redLED, HIGH); delay(rate); } digitalWrite(redLED, LOW); } // Reads the battery voltage // NOTE: This will actually return the battery level from the previous update! float getBatteryVoltage() { if (mcuBoard.sensorValues[0] == -9999) mcuBoard.update(); return mcuBoard.sensorValues[0]; } // ========================================================================== // Arduino Setup Function // ========================================================================== /** Start [setup] */ void setup() { // Start the primary serial connection Serial.begin(serialBaud); // Print a start-up note to the first serial port Serial.print(F("Now running ")); Serial.print(sketchName); Serial.print(F(" on Logger ")); Serial.println(LoggerID); Serial.println(); Serial.print(F("Using ModularSensors Library version ")); Serial.println(MODULAR_SENSORS_VERSION); Serial.print(F("TinyGSM Library version ")); Serial.println(TINYGSM_VERSION); Serial.println(); // Start the serial connection with the modem modemSerial.begin(modemBaud); // Set up pins for the LED's pinMode(greenLED, OUTPUT); digitalWrite(greenLED, LOW); pinMode(redLED, OUTPUT); digitalWrite(redLED, LOW); // Blink the LEDs to show the board is on and starting up greenredflash(); pinMode(20, OUTPUT); // for proper operation of the onboard flash memory // chip's ChipSelect (Mayfly v1.0 and later) // Set the timezones for the logger/data and the RTC // Logging in the given time zone Logger::setLoggerTimeZone(timeZone); // It is STRONGLY RECOMMENDED that you set the RTC to be in UTC (UTC+0) Logger::setRTCTimeZone(0); // Attach the modem and information pins to the logger dataLogger.attachModem(modem); modem.setModemLED(modemLEDPin); dataLogger.setLoggerPins(wakePin, sdCardSSPin, sdCardPwrPin, buttonPin, greenLED); // Begin the logger dataLogger.begin(); // Note: Please change these battery voltages to match your battery // Set up the sensors, except at lowest battery level if (getBatteryVoltage() > 3.4) { Serial.println(F("Setting up sensors...")); varArray.setupSensors(); } /** Start [setup_sim7080] */ modem.setModemWakeLevel(HIGH); // ModuleFun Bee inverts the signal modem.setModemResetLevel(HIGH); // ModuleFun Bee inverts the signal Serial.println(F("Waking modem and setting Cellular Carrier Options...")); modem.modemWake(); // NOTE: This will also set up the modem modem.gsmModem.setBaud(modemBaud); // Make sure we're *NOT* auto-bauding! modem.gsmModem.setNetworkMode(38); // set to LTE only // 2 Automatic // 13 GSM only // 38 LTE only // 51 GSM and LTE only modem.gsmModem.setPreferredMode(1); // set to CAT-M // 1 CAT-M // 2 NB-IoT // 3 CAT-M and NB-IoT /** End [setup_sim7080] */ // Sync the clock if it isn't valid or we have battery to spare if (getBatteryVoltage() > 3.55 || !dataLogger.isRTCSane()) { // Synchronize the RTC with NIST // This will also set up the modem dataLogger.syncRTC(); } // Create the log file, adding the default header to it // Do this last so we have the best chance of getting the time correct and // all sensor names correct // Writing to the SD card can be power intensive, so if we're skipping // the sensor setup we'll skip this too. if (getBatteryVoltage() > 3.4) { Serial.println(F("Setting up file on SD card")); dataLogger.turnOnSDcard( true); // true = wait for card to settle after power up dataLogger.createLogFile(true); // true = write a new header dataLogger.turnOffSDcard( true); // true = wait for internal housekeeping after write } // Call the processor sleep Serial.println(F("Putting processor to sleep\n")); dataLogger.systemSleep(); } /** End [setup] */ // ========================================================================== // Arduino Loop Function // ========================================================================== /** Start [loop] */ // Use this short loop for simple data logging and sending void loop() { // Note: Please change these battery voltages to match your battery // At very low battery, just go back to sleep if (getBatteryVoltage() < 3.4) { dataLogger.systemSleep(); } // At moderate voltage, log data but don't send it over the modem else if (getBatteryVoltage() < 3.55) { dataLogger.logData(); } // If the battery is good, send the data to the world else { dataLogger.logDataAndPublish(); } } /** End [loop] */ |