/** * * @license MIT License * * Copyright (c) 2026 lewis he * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in all * copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. * * @file QMC6310_CalibrateExample.ino * @author Lewis He (lewishe@outlook.com) * @date 2026-01-26 * */ #include #include #include #include "SensorQMC6310.hpp" #define ARDUINO_T_BEAM_S3_SUPREME #ifdef ARDUINO_T_BEAM_S3_SUPREME #include //PMU Library https://github.com/lewisxhe/XPowersLib.git #endif #ifndef SENSOR_SDA #define SENSOR_SDA 17 #endif #ifndef SENSOR_SCL #define SENSOR_SCL 18 #endif SensorQMC6310 magnetometer; void beginPower() { #if defined(ARDUINO_T_BEAM_S3_SUPREME) XPowersAXP2101 power; power.begin(Wire1, AXP2101_SLAVE_ADDRESS, 42, 41); power.disableALDO1(); power.disableALDO2(); delay(250); power.setALDO1Voltage(3300); power.enableALDO1(); power.setALDO2Voltage(3300); power.enableALDO2(); #endif } void calibrate() { if (!magnetometer.setOutputDataRate(200.0f)) { Serial.println("Failed to set output data rate"); return ; } Serial.println("========================================"); Serial.println("Calibration Instructions:"); Serial.println("1. Rotate sensor in FIGURE-8 pattern"); Serial.println("2. Cover all axes (X, Y, Z directions)"); Serial.println("3. Rotate slowly and completely"); Serial.println("4. Wait for progress bar to complete"); Serial.println("5. Expected: Magnetic Strength ~25-65 uT"); Serial.println("========================================"); Serial.println(); Serial.println("Place the sensor on the plane and slowly rotate the sensor..."); Serial.println("Rotate in FIGURE-8 pattern to cover all directions!"); Serial.println(); int32_t x_min = 65535; int32_t x_max = -65535; int32_t y_min = 65535; int32_t y_max = -65535; int32_t z_min = 65535; int32_t z_max = -65535; int32_t range = 1000; int32_t i = 0; int32_t x = 0, y = 0, z = 0;; int16_t x_offset = 0; int16_t y_offset = 0; int16_t z_offset = 0; MagnetometerData data; while (i < range) { i += 1; if (magnetometer.isDataReady()) { magnetometer.readData(data); x = (data.raw.x + x) / 2; y = (data.raw.y + y) / 2; z = (data.raw.z + z) / 2; if (x < x_min) { x_min = x; i = 0; } if (x > x_max) { x_max = x; i = 0; } if (y < y_min) { y_min = y; i = 0; } if (y > y_max) { y_max = y; i = 0; } if (z < z_min) { z_min = z; i = 0; } if (z > z_max) { z_max = z; i = 0; } int j = round(10 * i / range); Serial.print("["); for (int k = 0; k < j; ++k) { Serial.print("*"); } Serial.println("]"); } delay(5); } x_offset = (x_max + x_min) / 2; y_offset = (y_max + y_min) / 2; z_offset = (z_max + z_min) / 2; Serial.print("x_min:"); Serial.println(x_min); Serial.print("x_max:"); Serial.println(x_max); Serial.print("y_min:"); Serial.println(y_min); Serial.print("y_max:"); Serial.println(y_max); Serial.print("z_min:"); Serial.println(z_min); Serial.print("z_max:"); Serial.println(z_max); Serial.print("x_offset:"); Serial.println(x_offset); Serial.print("y_offset:"); Serial.println(y_offset); Serial.print("z_offset:"); Serial.println(z_offset); // Set the calibration value and the user calculates the deviation magnetometer.setOffset(x_offset, y_offset, z_offset); Serial.println(); Serial.println("Calibration complete!"); Serial.println("Check if Magnetic Strength is ~25-65 uT"); Serial.println("If too low, repeat calibration with better rotation"); } void setup() { Serial.begin(115200); while (!Serial); // LilyGo T-Beam-Supreme sensor requires a power source to function. beginPower(); /** * Supports QMC6310U and QMC6310N; simply pass the corresponding device address * during initialization. * - QMC6310U_SLAVE_ADDRESS * - QMC6310N_SLAVE_ADDRESS */ uint8_t address = QMC6310U_SLAVE_ADDRESS; // uint8_t address = QMC6310N_SLAVE_ADDRESS; if (!magnetometer.begin(Wire, address, SENSOR_SDA, SENSOR_SCL)) { while (1) { Serial.println("Failed to find QMC6310 - check your wiring!"); delay(1000); } } // The desired output data rate in Hz. Allowed values are 10.0, 50.0, 100.0 and 200.0HZ. float data_rate_hz = 200.0f; // op_mode: Allowed values are SUSPEND, NORMAL, SINGLE_MEASUREMENT, CONTINUOUS_MEASUREMENT OperationMode op_mode = OperationMode::CONTINUOUS_MEASUREMENT; // full_scale: Allowed values are FS_2G, FS_8G, FS_12G ,FS_30G MagFullScaleRange full_scale = MagFullScaleRange::FS_8G; // over_sample_ratio: Allowed values are OSR_1, OSR_2, OSR_4, OSR_8 MagOverSampleRatio over_sample_ratio = MagOverSampleRatio::OSR_1; // down_sample_ratio: Allowed values are DSR_1, DSR_2, DSR_4, DSR_8 MagDownSampleRatio down_sample_ratio = MagDownSampleRatio::DSR_1; /* Config Magnetometer */ if (magnetometer.configMagnetometer( op_mode, full_scale, data_rate_hz, over_sample_ratio, down_sample_ratio)) { Serial.println("Magnetometer configured successfully."); } else { Serial.println("Magnetometer configuration failed."); while (1); } // Calibration algorithm reference from // https://github.com/CoreElectronics/CE-PiicoDev-QMC6310-MicroPython-Module calibrate(); Serial.println("Calibration done."); delay(5000); SensorInfo info = magnetometer.getSensorInfo(); Serial.print("Manufacturer: "); Serial.println(info.manufacturer); Serial.print("Model: "); Serial.println(info.model); Serial.print("I2C Address: 0x"); Serial.println(info.i2c_address, HEX); Serial.print("Version: "); Serial.println(info.version); Serial.print("UID: 0x"); Serial.println(info.uid); Serial.print("Type: "); Serial.println(SensorUtils::typeToString(info.type)); SensorConfig cfg = magnetometer.getConfig(); Serial.print("DataRate: "); Serial.println(cfg.sample_rate); Serial.print("FullScaleRange: "); Serial.println(cfg.range); Serial.print("Mode: "); Serial.println((uint8_t)cfg.mode); Serial.println(); //Find the magnetic declination : https://www.magnetic-declination.com/ float declination_deg = MagnetometerUtils::dmsToDecimalDegrees(-3, 20); // -3.3333 magnetometer.setDeclination(declination_deg); Serial.print(" Magnetic Declination: "); Serial.print(declination_deg, 2); Serial.println("°"); Serial.print(" Sensitivity: "); Serial.print(magnetometer.getSensitivity(), 6); Serial.println(" Gauss/LSB"); delay(3000); Serial.println("Read data now..."); } void loop() { MagnetometerData data; if (magnetometer.readData(data)) { // Gauss to μT float x = MagnetometerUtils::gaussToMicroTesla(data.magnetic_field.x); float y = MagnetometerUtils::gaussToMicroTesla(data.magnetic_field.y); float z = MagnetometerUtils::gaussToMicroTesla(data.magnetic_field.z); Serial.print("Mag:"); Serial.print(" X:"); Serial.print(x); Serial.print(" Y:"); Serial.print(y); Serial.print(" Z:"); Serial.print(z); Serial.print(" μT"); Serial.print(" Sensitivity: "); Serial.print(magnetometer.getSensitivity(), 6); Serial.print(" Gauss/LSB"); Serial.print(" Metadata:"); Serial.print(" X:"); Serial.print(data.raw.x); Serial.print(" Y:"); Serial.print(data.raw.y); Serial.print(" Z:"); Serial.print(data.raw.z); Serial.print(" Heading (rad): "); Serial.print(data.heading, 6); Serial.print(" rad"); Serial.print(" Heading (deg): "); Serial.print(data.heading_degrees, 2); Serial.print("°"); float strength = MagnetometerUtils::calculateMagneticStrength(data); strength = MagnetometerUtils::gaussToMicroTesla(strength); Serial.print(" Magnetic Strength: "); Serial.print(strength, 2); Serial.println(" μT"); if (data.overflow) { Serial.println("\tWarning: Data Overflow occurred!"); } } delay(10); }