Project #28 – Sensors – LSM9DS1 – Mk11
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#DonLucElectronics #DonLuc #Sensors #LSM9DS1 #IMU #GPSReceiver #Adafruit #SparkFun #Arduino #Project #Fritzing #Programming #Electronics #Microcontrollers #Consultant
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SparkFun 9DoF IMU Breakout – LSM9DS1
The SparkFun LSM9DS1 Breakout is a versatile, motion-sensing System-In-A-Chip. It houses a 3-axis accelerometer, 3-axis gyroscope, and 3-axis magnetometer, nine degrees of freedom (9DOF) on a single board. The LSM9DS1 from STMicroelectronics is equipped with a digital interface, but even that is flexible. This IMU-In-A-Chip is so cool we put it on the quarter-sized breakout board you are currently viewing.
The LSM9DS1 is one of only a handful of IC’s that can measure three key properties of movement, angular velocity, acceleration, and heading, in a single IC. By measuring these three properties, you can gain a great deal of knowledge about an object’s movement and orientation. The LSM9DS1 measures each of these movement properties in three dimensions. That means it produces nine pieces of data: acceleration in x/y/z, angular rotation in x/y/z, and magnetic force in x/y/z. The LSM9DS1 Breakout has labels indicating the accelerometer and gyroscope axis orientations, which share a right-hand rule relationship with each other.
DL2309Mk05
1 x SparkFun Thing Plus – ESP32 WROOM
1 x DS3231 Precision RTC FeatherWing
1 x GPS Receiver – GP-20U7 (56 Channel)
1 x SparkFun 9DoF IMU Breakout – LSM9DS1
1 x Rocker Switch – SPST
1 x Resistor 10K Ohm
1 x CR1220 3V Lithium Coin Cell Battery
1 x 1 x Lithium Ion Battery – 1000mAh
1 x Terminal Block Breakout FeatherWing
1 x SparkFun Cerberus USB Cable
SparkFun Thing Plus – ESP32 WROOM
LED – LED_BUILTIN
SDA – Digital 23
SCL – Digital 22
SW1 – Digital 21
GPT – Digital 17
GPR – Digital 16
VIN – +3.3V
GND – GND
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DL2309Mk05p.ino
/****** Don Luc Electronics © ****** Software Version Information Project #28 - Sensors - LSM9DS1 - Mk11 28-11 DL2309Mk05p.ino 1 x SparkFun Thing Plus - ESP32 WROOM 1 x DS3231 Precision RTC FeatherWing 1 x GPS Receiver - GP-20U7 (56 Channel) 1 x SparkFun 9DoF IMU Breakout - LSM9DS1 1 x Rocker Switch - SPST 1 x Resistor 10K Ohm 1 x Lithium Ion Battery - 1000mAh 1 x CR1220 3V Lithium Coin Cell Battery 1 x Terminal Block Breakout FeatherWing 1 x SparkFun Cerberus USB Cable */ // Include the Library Code // Bluetooth LE keyboard #include <BleKeyboard.h> // Two Wire Interface (TWI/I2C) #include <Wire.h> // Serial Peripheral Interface #include <SPI.h> // DS3231 Precision RTC #include <RTClib.h> // GPS Receiver #include <TinyGPS++.h> // ESP32 Hardware Serial #include <HardwareSerial.h> // LSM9DS1 9DOF Sensor #include <SparkFunLSM9DS1.h> // Bluetooth LE Keyboard BleKeyboard bleKeyboard; String sKeyboard = ""; // Send Size byte sendSize = 0; // DS3231 Precision RTC RTC_DS3231 rtc; String dateRTC = ""; String timeRTC = ""; // GPS Receiver #define gpsRXPIN 16 // This one is unused and doesnt have a conection #define gpsTXPIN 17 // The TinyGPS++ object TinyGPSPlus gps; // Latitude float TargetLat; // Longitude float TargetLon; // GPS Date, Time // GPS Date String TargetDat; // GPS Time String TargetTim; // GPS Status String GPSSt = ""; // ESP32 HardwareSerial HardwareSerial tGPS(2); // LSM9DS1 9DOF Sensor LSM9DS1 imu; #define PRINT_CALCULATED // Earth's magnetic field varies by location. Add or subtract // a declination to get a more accurate heading. Calculate // your's here: http://www.ngdc.noaa.gov/geomag-web/#declination // Declination (degrees) in El Centro, CA #define DECLINATION 10.4 // Gyro float fGyroX; float fGyroY; float fGyroZ; // Accel float fAccelX; float fAccelY; float fAccelZ; // Mag float fMagX; float fMagY; float fMagZ; // Attitude float fRoll; float fPitch; float fHeading; // The number of the Rocker Switch pin int iSwitch = 21; // Variable for reading the button status int SwitchState = 0; // Software Version Information String sver = "28-11"; void loop() { // Date and Time RTC isRTC (); // isGPS isGPS(); // GPS Keyboard isGPSKeyboard(); // Gyro isGyro(); // Accel isAccel(); // Mag isMag(); // Attitude isAttitude(); // Read the state of the Switch value: SwitchState = digitalRead(iSwitch); // Check if the button is pressed. If it is, the SwitchState is HIGH: if (SwitchState == HIGH) { // Bluetooth LE Keyboard isBluetooth(); } // Delay 1 Second delay(1000); }
getBleKeyboard.ino
// Ble Keyboard // Bluetooth // isBluetooth void isBluetooth() { // ESP32 BLE Keyboard if(bleKeyboard.isConnected()) { // Send Size Length sendSize = sKeyboard.length(); // Send Size, charAt for(byte i = 0; i < sendSize+1; i++){ // Write bleKeyboard.write(sKeyboard.charAt(i)); delay(50); } bleKeyboard.write(KEY_RETURN); } }
getGPS.ino
// GPS Receiver // Setup GPS void setupGPS() { // Setup GPS //tGPS.begin( 9600 ); // Setup GPS tGPS.begin( 9600 , SERIAL_8N1 , gpsRXPIN , gpsTXPIN ); } // isGPS void isGPS(){ // Receives NEMA data from GPS receiver // This sketch displays information every time a new sentence is correctly encoded while ( tGPS.available() > 0) if (gps.encode( tGPS.read() )) { // GPS Vector Pointer Target displayInfo(); // GPS Date, Time displayDTS(); } if (millis() > 5000 && gps.charsProcessed() < 10) { while(true); } } // GPS Vector Pointer Target void displayInfo(){ // Location if (gps.location.isValid()) { // Latitude TargetLat = gps.location.lat(); // Longitude TargetLon = gps.location.lng(); // GPS Status 2 GPSSt = "Yes"; } else { // GPS Status 0 GPSSt = "No"; TargetLat = 0; TargetLon = 0; } } // GPS Date, Time void displayDTS(){ // Date TargetDat = ""; if (gps.date.isValid()) { // Date // Year TargetDat += String(gps.date.year(), DEC); TargetDat += "/"; // Month TargetDat += String(gps.date.month(), DEC); TargetDat += "/"; // Day TargetDat += String(gps.date.day(), DEC); } // Time TargetTim = ""; if (gps.time.isValid()) { // Time // Hour TargetTim += String(gps.time.hour(), DEC); TargetTim += ":"; // Minute TargetTim += String(gps.time.minute(), DEC); TargetTim += ":"; // Secound TargetTim += String(gps.time.second(), DEC); } } // GPS Keyboard void isGPSKeyboard(){ // GPS Keyboard // bleKeyboard // GPS Vector Pointer Target sKeyboard = sKeyboard + GPSSt + "|" + String(TargetLat) + "|" + String(TargetLon) + "|"; // bleKeyboard // GPS Date, Time sKeyboard = sKeyboard + TargetDat + "|" + TargetTim + "|"; }
getLSM9DS1.ino
// LSM9DS1 9DOF Sensor // Gyro void isGyro(){ // Update the sensor values whenever new data is available if ( imu.gyroAvailable() ) { // To read from the gyroscope, first call the // readGyro() function. When it exits, it'll update the // gx, gy, and gz variables with the most current data. imu.readGyro(); // If you want to print calculated values, you can use the // calcGyro helper function to convert a raw ADC value to // DPS. Give the function the value that you want to convert. fGyroX = imu.calcGyro(imu.gx); fGyroY = imu.calcGyro(imu.gy); fGyroZ = imu.calcGyro(imu.gz); // bleKeyboard // Gyro sKeyboard = sKeyboard + String(fGyroX) + "|" + String(fGyroY) + "|" + String(fGyroZ) + "|"; } } // Accel void isAccel(){ // Update the sensor values whenever new data is available if ( imu.accelAvailable() ) { // To read from the accelerometer, first call the // readAccel() function. When it exits, it'll update the // ax, ay, and az variables with the most current data. imu.readAccel(); // If you want to print calculated values, you can use the // calcAccel helper function to convert a raw ADC value to // g's. Give the function the value that you want to convert. fAccelX = imu.calcAccel(imu.ax); fAccelY = imu.calcAccel(imu.ay); fAccelZ = imu.calcAccel(imu.az); // bleKeyboard // Accel sKeyboard = sKeyboard + String(fAccelX) + "|" + String(fAccelY) + "|" + String(fAccelZ) + "|"; } } // Mag void isMag(){ // Update the sensor values whenever new data is available if ( imu.magAvailable() ) { // To read from the magnetometer, first call the // readMag() function. When it exits, it'll update the // mx, my, and mz variables with the most current data. imu.readMag(); // If you want to print calculated values, you can use the // calcMag helper function to convert a raw ADC value to // Gauss. Give the function the value that you want to convert. fMagX = imu.calcMag(imu.mx); fMagY = imu.calcMag(imu.my); fMagZ = imu.calcMag(imu.mz); // bleKeyboard // Mag sKeyboard = sKeyboard + String(fMagX) + "|" + String(fMagY) + "|" + String(fMagZ) + "|"; } } // Attitude void isAttitude(){ // Attitude // Roll fRoll = atan2(fAccelY, fAccelZ); // Pitch fPitch = atan2(-fAccelX, sqrt(fAccelY * fAccelY + fAccelZ * fAccelZ)); // Heading if (fMagY == 0) { fHeading = (fMagX < 0) ? PI : 0; } else { fHeading = atan2(fMagX, fMagY); } fHeading -= DECLINATION * PI / 180; if (fHeading > PI) fHeading -= (2 * PI); else if (fHeading < -PI) fHeading += (2 * PI); // Convert everything from radians to degrees: fHeading *= 180.0 / PI; fPitch *= 180.0 / PI; fRoll *= 180.0 / PI; // bleKeyboard // Attitude sKeyboard = sKeyboard + String(fHeading) + "|" + String(fPitch) + "|" + String(fRoll) + "|*"; }
getRTC.ino
// Date & Time // DS3231 Precision RTC void setupRTC() { // DS3231 Precision RTC if (! rtc.begin()) { //Serial.println("Couldn't find RTC"); //Serial.flush(); while (1) delay(10); } if (rtc.lostPower()) { //Serial.println("RTC lost power, let's set the time!"); // When time needs to be set on a new device, or after a power loss, the // following line sets the RTC to the date & time this sketch was compiled rtc.adjust(DateTime(F(__DATE__), F(__TIME__))); // This line sets the RTC with an explicit date & time, for example to set // January 21, 2014 at 3am you would call: //rtc.adjust(DateTime(2023, 8, 10, 11, 0, 0)); } } // Date and Time RTC void isRTC () { // Date and Time dateRTC = ""; timeRTC = ""; DateTime now = rtc.now(); // Date dateRTC = now.year(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.month(), DEC; dateRTC = dateRTC + "/"; dateRTC = dateRTC + now.day(), DEC; // Time timeRTC = now.hour(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.minute(), DEC; timeRTC = timeRTC + ":"; timeRTC = timeRTC + now.second(), DEC; // bleKeyboard sKeyboard = "SEN|" + sver + "|" + String(dateRTC) + "|" + String(timeRTC) + "|"; }
setup.ino
// Setup void setup() { // Give display time to power on delay(100); // Bluetooth LE keyboard bleKeyboard.begin(); // Wire - Inialize I2C Hardware Wire.begin(); // Give display time to power on delay(100); // Date & Time RTC // DS3231 Precision RTC setupRTC(); // Give display time to power on delay(100); // GPS Receiver // Setup GPS setupGPS(); // LSM9DS1 9DOF Sensor imu.begin(); // Initialize the Switch pin as an input pinMode(iSwitch, INPUT); // Initialize digital pin LED_BUILTIN as an output pinMode(LED_BUILTIN, OUTPUT); // Turn the LED on HIGH digitalWrite(LED_BUILTIN, HIGH); // Delay 5 Second delay( 5000 ); }
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