cast (char) pour compatibilité OS5
LSM9DS1.cpp@7:e6e3d320eb6c, 2017-06-15 (annotated)
- Committer:
- ChangYuHsuan
- Date:
- Thu Jun 15 08:42:23 2017 +0000
- Revision:
- 7:e6e3d320eb6c
- Parent:
- 6:28c4b3c8b43d
- Child:
- 8:16e88babd42a
revised;
Who changed what in which revision?
User | Revision | Line number | New contents of line |
---|---|---|---|
beanmachine44 | 0:622e8874902e | 1 | #include "LSM9DS1.h" |
beanmachine44 | 0:622e8874902e | 2 | |
beanmachine44 | 0:622e8874902e | 3 | LSM9DS1::LSM9DS1(PinName sda, PinName scl, uint8_t xgAddr, uint8_t mAddr) : i2c(sda, scl) |
beanmachine44 | 0:622e8874902e | 4 | { |
beanmachine44 | 0:622e8874902e | 5 | // xgAddress and mAddress will store the 7-bit I2C address, if using I2C. |
beanmachine44 | 0:622e8874902e | 6 | xgAddress = xgAddr; |
beanmachine44 | 0:622e8874902e | 7 | mAddress = mAddr; |
beanmachine44 | 0:622e8874902e | 8 | } |
beanmachine44 | 0:622e8874902e | 9 | |
beanmachine44 | 0:622e8874902e | 10 | uint16_t LSM9DS1::begin(gyro_scale gScl, accel_scale aScl, mag_scale mScl, |
beanmachine44 | 0:622e8874902e | 11 | gyro_odr gODR, accel_odr aODR, mag_odr mODR) |
beanmachine44 | 0:622e8874902e | 12 | { |
beanmachine44 | 0:622e8874902e | 13 | // Store the given scales in class variables. These scale variables |
beanmachine44 | 0:622e8874902e | 14 | // are used throughout to calculate the actual g's, DPS,and Gs's. |
beanmachine44 | 0:622e8874902e | 15 | gScale = gScl; |
beanmachine44 | 0:622e8874902e | 16 | aScale = aScl; |
beanmachine44 | 0:622e8874902e | 17 | mScale = mScl; |
beanmachine44 | 0:622e8874902e | 18 | |
beanmachine44 | 0:622e8874902e | 19 | // Once we have the scale values, we can calculate the resolution |
beanmachine44 | 0:622e8874902e | 20 | // of each sensor. That's what these functions are for. One for each sensor |
beanmachine44 | 0:622e8874902e | 21 | calcgRes(); // Calculate DPS / ADC tick, stored in gRes variable |
beanmachine44 | 0:622e8874902e | 22 | calcmRes(); // Calculate Gs / ADC tick, stored in mRes variable |
beanmachine44 | 0:622e8874902e | 23 | calcaRes(); // Calculate g / ADC tick, stored in aRes variable |
beanmachine44 | 0:622e8874902e | 24 | |
beanmachine44 | 0:622e8874902e | 25 | |
beanmachine44 | 0:622e8874902e | 26 | // To verify communication, we can read from the WHO_AM_I register of |
beanmachine44 | 0:622e8874902e | 27 | // each device. Store those in a variable so we can return them. |
beanmachine44 | 0:622e8874902e | 28 | // The start of the addresses we want to read from |
beanmachine44 | 0:622e8874902e | 29 | char cmd[2] = { |
beanmachine44 | 0:622e8874902e | 30 | WHO_AM_I_XG, |
beanmachine44 | 0:622e8874902e | 31 | 0 |
beanmachine44 | 0:622e8874902e | 32 | }; |
beanmachine44 | 0:622e8874902e | 33 | |
beanmachine44 | 0:622e8874902e | 34 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 35 | i2c.write(xgAddress, cmd, 1, true); |
beanmachine44 | 0:622e8874902e | 36 | // Read in all the 8 bits of data |
beanmachine44 | 0:622e8874902e | 37 | i2c.read(xgAddress, cmd+1, 1); |
beanmachine44 | 0:622e8874902e | 38 | uint8_t xgTest = cmd[1]; // Read the accel/gyro WHO_AM_I |
beanmachine44 | 0:622e8874902e | 39 | |
beanmachine44 | 0:622e8874902e | 40 | // Reset to the address of the mag who am i |
ChangYuHsuan | 6:28c4b3c8b43d | 41 | cmd[0] = WHO_AM_I_M; |
beanmachine44 | 0:622e8874902e | 42 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 43 | i2c.write(mAddress, cmd, 1, true); |
beanmachine44 | 0:622e8874902e | 44 | // Read in all the 8 bits of data |
beanmachine44 | 0:622e8874902e | 45 | i2c.read(mAddress, cmd+1, 1); |
beanmachine44 | 0:622e8874902e | 46 | uint8_t mTest = cmd[1]; // Read the mag WHO_AM_I |
beanmachine44 | 0:622e8874902e | 47 | |
ChangYuHsuan | 6:28c4b3c8b43d | 48 | for(int ii = 0; ii < 3; ii++) |
ChangYuHsuan | 6:28c4b3c8b43d | 49 | { |
ChangYuHsuan | 6:28c4b3c8b43d | 50 | gBiasRaw[ii] = 0; |
ChangYuHsuan | 6:28c4b3c8b43d | 51 | aBiasRaw[ii] = 0; |
ChangYuHsuan | 6:28c4b3c8b43d | 52 | gBias[ii] = 0; |
ChangYuHsuan | 6:28c4b3c8b43d | 53 | aBias[ii] = 0; |
ChangYuHsuan | 6:28c4b3c8b43d | 54 | autoCalib = false; |
ChangYuHsuan | 6:28c4b3c8b43d | 55 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 56 | |
beanmachine44 | 0:622e8874902e | 57 | // Gyro initialization stuff: |
beanmachine44 | 0:622e8874902e | 58 | initGyro(); // This will "turn on" the gyro. Setting up interrupts, etc. |
beanmachine44 | 0:622e8874902e | 59 | setGyroODR(gODR); // Set the gyro output data rate and bandwidth. |
beanmachine44 | 0:622e8874902e | 60 | setGyroScale(gScale); // Set the gyro range |
beanmachine44 | 0:622e8874902e | 61 | |
beanmachine44 | 0:622e8874902e | 62 | // Accelerometer initialization stuff: |
beanmachine44 | 0:622e8874902e | 63 | initAccel(); // "Turn on" all axes of the accel. Set up interrupts, etc. |
beanmachine44 | 0:622e8874902e | 64 | setAccelODR(aODR); // Set the accel data rate. |
beanmachine44 | 0:622e8874902e | 65 | setAccelScale(aScale); // Set the accel range. |
beanmachine44 | 0:622e8874902e | 66 | |
beanmachine44 | 0:622e8874902e | 67 | // Magnetometer initialization stuff: |
beanmachine44 | 0:622e8874902e | 68 | initMag(); // "Turn on" all axes of the mag. Set up interrupts, etc. |
beanmachine44 | 0:622e8874902e | 69 | setMagODR(mODR); // Set the magnetometer output data rate. |
beanmachine44 | 0:622e8874902e | 70 | setMagScale(mScale); // Set the magnetometer's range. |
beanmachine44 | 0:622e8874902e | 71 | |
5hel2l2y | 4:7ffcb378cfd4 | 72 | // Interrupt initialization stuff |
5hel2l2y | 3:f96b287c0bf7 | 73 | initIntr(); |
5hel2l2y | 3:f96b287c0bf7 | 74 | |
beanmachine44 | 0:622e8874902e | 75 | // Once everything is initialized, return the WHO_AM_I registers we read: |
beanmachine44 | 0:622e8874902e | 76 | return (xgTest << 8) | mTest; |
beanmachine44 | 0:622e8874902e | 77 | } |
beanmachine44 | 0:622e8874902e | 78 | |
beanmachine44 | 0:622e8874902e | 79 | void LSM9DS1::initGyro() |
beanmachine44 | 0:622e8874902e | 80 | { |
beanmachine44 | 0:622e8874902e | 81 | char cmd[4] = { |
beanmachine44 | 0:622e8874902e | 82 | CTRL_REG1_G, |
beanmachine44 | 0:622e8874902e | 83 | gScale | G_ODR_119_BW_14, |
beanmachine44 | 0:622e8874902e | 84 | 0, // Default data out and int out |
beanmachine44 | 0:622e8874902e | 85 | 0 // Default power mode and high pass settings |
beanmachine44 | 0:622e8874902e | 86 | }; |
beanmachine44 | 0:622e8874902e | 87 | |
beanmachine44 | 0:622e8874902e | 88 | // Write the data to the gyro control registers |
beanmachine44 | 0:622e8874902e | 89 | i2c.write(xgAddress, cmd, 4); |
beanmachine44 | 0:622e8874902e | 90 | } |
beanmachine44 | 0:622e8874902e | 91 | |
beanmachine44 | 0:622e8874902e | 92 | void LSM9DS1::initAccel() |
beanmachine44 | 0:622e8874902e | 93 | { |
beanmachine44 | 0:622e8874902e | 94 | char cmd[4] = { |
beanmachine44 | 0:622e8874902e | 95 | CTRL_REG5_XL, |
beanmachine44 | 0:622e8874902e | 96 | 0x38, // Enable all axis and don't decimate data in out Registers |
beanmachine44 | 0:622e8874902e | 97 | (A_ODR_119 << 5) | (aScale << 3) | (A_BW_AUTO_SCALE), // 119 Hz ODR, set scale, and auto BW |
beanmachine44 | 0:622e8874902e | 98 | 0 // Default resolution mode and filtering settings |
beanmachine44 | 0:622e8874902e | 99 | }; |
beanmachine44 | 0:622e8874902e | 100 | |
beanmachine44 | 0:622e8874902e | 101 | // Write the data to the accel control registers |
beanmachine44 | 0:622e8874902e | 102 | i2c.write(xgAddress, cmd, 4); |
beanmachine44 | 0:622e8874902e | 103 | } |
beanmachine44 | 0:622e8874902e | 104 | |
beanmachine44 | 0:622e8874902e | 105 | void LSM9DS1::initMag() |
beanmachine44 | 0:622e8874902e | 106 | { |
beanmachine44 | 0:622e8874902e | 107 | char cmd[4] = { |
beanmachine44 | 0:622e8874902e | 108 | CTRL_REG1_M, |
beanmachine44 | 0:622e8874902e | 109 | 0x10, // Default data rate, xy axes mode, and temp comp |
beanmachine44 | 0:622e8874902e | 110 | mScale << 5, // Set mag scale |
beanmachine44 | 0:622e8874902e | 111 | 0 // Enable I2C, write only SPI, not LP mode, Continuous conversion mode |
beanmachine44 | 0:622e8874902e | 112 | }; |
beanmachine44 | 0:622e8874902e | 113 | |
beanmachine44 | 0:622e8874902e | 114 | // Write the data to the mag control registers |
beanmachine44 | 0:622e8874902e | 115 | i2c.write(mAddress, cmd, 4); |
beanmachine44 | 0:622e8874902e | 116 | } |
beanmachine44 | 0:622e8874902e | 117 | |
5hel2l2y | 3:f96b287c0bf7 | 118 | void LSM9DS1::initIntr() |
5hel2l2y | 3:f96b287c0bf7 | 119 | { |
5hel2l2y | 3:f96b287c0bf7 | 120 | char cmd[2]; |
5hel2l2y | 4:7ffcb378cfd4 | 121 | uint16_t thresholdG = 500; |
5hel2l2y | 4:7ffcb378cfd4 | 122 | uint8_t durationG = 10; |
5hel2l2y | 4:7ffcb378cfd4 | 123 | uint8_t thresholdX = 20; |
5hel2l2y | 4:7ffcb378cfd4 | 124 | uint8_t durationX = 1; |
5hel2l2y | 4:7ffcb378cfd4 | 125 | uint16_t thresholdM = 10000; |
5hel2l2y | 3:f96b287c0bf7 | 126 | |
5hel2l2y | 4:7ffcb378cfd4 | 127 | // 1. Configure the gyro interrupt generator |
5hel2l2y | 3:f96b287c0bf7 | 128 | cmd[0] = INT_GEN_CFG_G; |
5hel2l2y | 3:f96b287c0bf7 | 129 | cmd[1] = (1 << 5); |
5hel2l2y | 3:f96b287c0bf7 | 130 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 4:7ffcb378cfd4 | 131 | // 2. Configure the gyro threshold |
5hel2l2y | 4:7ffcb378cfd4 | 132 | cmd[0] = INT_GEN_THS_ZH_G; |
5hel2l2y | 4:7ffcb378cfd4 | 133 | cmd[1] = (thresholdG & 0x7F00) >> 8; |
5hel2l2y | 3:f96b287c0bf7 | 134 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 4:7ffcb378cfd4 | 135 | cmd[0] = INT_GEN_THS_ZL_G; |
5hel2l2y | 4:7ffcb378cfd4 | 136 | cmd[1] = (thresholdG & 0x00FF); |
5hel2l2y | 3:f96b287c0bf7 | 137 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 3:f96b287c0bf7 | 138 | cmd[0] = INT_GEN_DUR_G; |
5hel2l2y | 4:7ffcb378cfd4 | 139 | cmd[1] = (durationG & 0x7F) | 0x80; |
5hel2l2y | 3:f96b287c0bf7 | 140 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 3:f96b287c0bf7 | 141 | |
5hel2l2y | 4:7ffcb378cfd4 | 142 | // 3. Configure accelerometer interrupt generator |
5hel2l2y | 3:f96b287c0bf7 | 143 | cmd[0] = INT_GEN_CFG_XL; |
5hel2l2y | 3:f96b287c0bf7 | 144 | cmd[1] = (1 << 1); |
5hel2l2y | 3:f96b287c0bf7 | 145 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 4:7ffcb378cfd4 | 146 | // 4. Configure accelerometer threshold |
5hel2l2y | 4:7ffcb378cfd4 | 147 | cmd[0] = INT_GEN_THS_X_XL; |
5hel2l2y | 4:7ffcb378cfd4 | 148 | cmd[1] = thresholdX; |
5hel2l2y | 3:f96b287c0bf7 | 149 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 3:f96b287c0bf7 | 150 | cmd[0] = INT_GEN_DUR_XL; |
5hel2l2y | 4:7ffcb378cfd4 | 151 | cmd[1] = (durationX & 0x7F); |
5hel2l2y | 3:f96b287c0bf7 | 152 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 3:f96b287c0bf7 | 153 | |
5hel2l2y | 4:7ffcb378cfd4 | 154 | // 5. Configure INT1 - assign it to gyro interrupt |
5hel2l2y | 3:f96b287c0bf7 | 155 | cmd[0] = INT1_CTRL; |
5hel2l2y | 4:7ffcb378cfd4 | 156 | // cmd[1] = 0xC0; |
5hel2l2y | 3:f96b287c0bf7 | 157 | cmd[1] = (1 << 7) | (1 << 6); |
5hel2l2y | 3:f96b287c0bf7 | 158 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 3:f96b287c0bf7 | 159 | cmd[0] = CTRL_REG8; |
5hel2l2y | 4:7ffcb378cfd4 | 160 | // cmd[1] = 0x04; |
5hel2l2y | 4:7ffcb378cfd4 | 161 | cmd[1] = (1 << 2) | (1 << 5) | (1 << 4); |
5hel2l2y | 3:f96b287c0bf7 | 162 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 3:f96b287c0bf7 | 163 | |
5hel2l2y | 4:7ffcb378cfd4 | 164 | // Configure interrupt 2 to fire whenever new accelerometer |
5hel2l2y | 4:7ffcb378cfd4 | 165 | // or gyroscope data is available. |
5hel2l2y | 3:f96b287c0bf7 | 166 | cmd[0] = INT2_CTRL; |
5hel2l2y | 3:f96b287c0bf7 | 167 | cmd[1] = (1 << 0) | (1 << 1); |
5hel2l2y | 3:f96b287c0bf7 | 168 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 3:f96b287c0bf7 | 169 | cmd[0] = CTRL_REG8; |
5hel2l2y | 4:7ffcb378cfd4 | 170 | cmd[1] = (1 << 2) | (1 << 5) | (1 << 4); |
5hel2l2y | 3:f96b287c0bf7 | 171 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 3:f96b287c0bf7 | 172 | |
5hel2l2y | 4:7ffcb378cfd4 | 173 | // Configure magnetometer interrupt |
5hel2l2y | 3:f96b287c0bf7 | 174 | cmd[0] = INT_CFG_M; |
5hel2l2y | 4:7ffcb378cfd4 | 175 | cmd[1] = (1 << 7) | (1 << 0); |
5hel2l2y | 3:f96b287c0bf7 | 176 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 3:f96b287c0bf7 | 177 | |
5hel2l2y | 4:7ffcb378cfd4 | 178 | // Configure magnetometer threshold |
5hel2l2y | 3:f96b287c0bf7 | 179 | cmd[0] = INT_THS_H_M; |
5hel2l2y | 4:7ffcb378cfd4 | 180 | cmd[1] = uint8_t((thresholdM & 0x7F00) >> 8); |
5hel2l2y | 3:f96b287c0bf7 | 181 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 3:f96b287c0bf7 | 182 | cmd[0] = INT_THS_L_M; |
5hel2l2y | 4:7ffcb378cfd4 | 183 | cmd[1] = uint8_t(thresholdM & 0x00FF); |
5hel2l2y | 3:f96b287c0bf7 | 184 | i2c.write(xgAddress, cmd, 2); |
5hel2l2y | 3:f96b287c0bf7 | 185 | } |
5hel2l2y | 3:f96b287c0bf7 | 186 | |
ChangYuHsuan | 6:28c4b3c8b43d | 187 | void LSM9DS1::calibration() |
ChangYuHsuan | 6:28c4b3c8b43d | 188 | { |
ChangYuHsuan | 6:28c4b3c8b43d | 189 | |
ChangYuHsuan | 6:28c4b3c8b43d | 190 | uint16_t samples = 0; |
ChangYuHsuan | 6:28c4b3c8b43d | 191 | int32_t aBiasRawTemp[3] = {0, 0, 0}; |
ChangYuHsuan | 6:28c4b3c8b43d | 192 | int32_t gBiasRawTemp[3] = {0, 0, 0}; |
ChangYuHsuan | 6:28c4b3c8b43d | 193 | /* |
ChangYuHsuan | 6:28c4b3c8b43d | 194 | // Turn on FIFO and set threshold to 32 samples |
ChangYuHsuan | 6:28c4b3c8b43d | 195 | enableXgFIFO(true); |
ChangYuHsuan | 6:28c4b3c8b43d | 196 | setXgFIFO( 1, 0x1F); |
ChangYuHsuan | 6:28c4b3c8b43d | 197 | while (samples < 0x1F) |
ChangYuHsuan | 6:28c4b3c8b43d | 198 | { |
ChangYuHsuan | 6:28c4b3c8b43d | 199 | samples = (i2c.read(FIFO_SRC) & 0x3F); // Read number of stored samples |
ChangYuHsuan | 6:28c4b3c8b43d | 200 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 201 | for(int ii = 0; ii < samples ; ii++) |
ChangYuHsuan | 6:28c4b3c8b43d | 202 | { // Read the gyro data stored in the FIFO |
ChangYuHsuan | 6:28c4b3c8b43d | 203 | readGyro(); |
ChangYuHsuan | 6:28c4b3c8b43d | 204 | gBiasRawTemp[0] += gx_raw; |
ChangYuHsuan | 6:28c4b3c8b43d | 205 | gBiasRawTemp[1] += gy_raw; |
ChangYuHsuan | 6:28c4b3c8b43d | 206 | gBiasRawTemp[2] += gz_raw; |
ChangYuHsuan | 6:28c4b3c8b43d | 207 | readAccel(); |
ChangYuHsuan | 6:28c4b3c8b43d | 208 | aBiasRawTemp[0] += ax_raw; |
ChangYuHsuan | 6:28c4b3c8b43d | 209 | aBiasRawTemp[1] += ay_raw; |
ChangYuHsuan | 6:28c4b3c8b43d | 210 | aBiasRawTemp[2] += az_raw - (int16_t)(1./aRes); // Assumes sensor facing up! |
ChangYuHsuan | 6:28c4b3c8b43d | 211 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 212 | for (int ii = 0; ii < 3; ii++) |
ChangYuHsuan | 6:28c4b3c8b43d | 213 | { |
ChangYuHsuan | 6:28c4b3c8b43d | 214 | gBias_raw[ii] = gBiasRawTemp[ii] / samples; |
ChangYuHsuan | 6:28c4b3c8b43d | 215 | gBias[ii] = gBias_raw[ii] * gRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 216 | aBias_raw[ii] = aBiasRawTemp[ii] / samples; |
ChangYuHsuan | 6:28c4b3c8b43d | 217 | aBias[ii] = aBias_raw[ii] * aRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 218 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 219 | |
ChangYuHsuan | 6:28c4b3c8b43d | 220 | |
ChangYuHsuan | 6:28c4b3c8b43d | 221 | |
ChangYuHsuan | 6:28c4b3c8b43d | 222 | enableXgFIFO(false); |
ChangYuHsuan | 6:28c4b3c8b43d | 223 | setXgFIFO(0, 0x00); |
ChangYuHsuan | 6:28c4b3c8b43d | 224 | */ |
ChangYuHsuan | 6:28c4b3c8b43d | 225 | while(samples < 300) |
ChangYuHsuan | 6:28c4b3c8b43d | 226 | { |
ChangYuHsuan | 6:28c4b3c8b43d | 227 | readGyro(); |
ChangYuHsuan | 6:28c4b3c8b43d | 228 | gBiasRawTemp[0] += gx_raw; |
ChangYuHsuan | 6:28c4b3c8b43d | 229 | gBiasRawTemp[1] += gy_raw; |
ChangYuHsuan | 6:28c4b3c8b43d | 230 | gBiasRawTemp[2] += gz_raw; |
ChangYuHsuan | 6:28c4b3c8b43d | 231 | readAccel(); |
ChangYuHsuan | 6:28c4b3c8b43d | 232 | aBiasRawTemp[0] += ax_raw; |
ChangYuHsuan | 6:28c4b3c8b43d | 233 | aBiasRawTemp[1] += ay_raw; |
ChangYuHsuan | 6:28c4b3c8b43d | 234 | aBiasRawTemp[2] += az_raw; |
ChangYuHsuan | 6:28c4b3c8b43d | 235 | wait_us(1000); |
ChangYuHsuan | 6:28c4b3c8b43d | 236 | samples++; |
ChangYuHsuan | 6:28c4b3c8b43d | 237 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 238 | |
ChangYuHsuan | 6:28c4b3c8b43d | 239 | for(int ii = 0; ii < 3; ii++) |
ChangYuHsuan | 6:28c4b3c8b43d | 240 | { |
ChangYuHsuan | 6:28c4b3c8b43d | 241 | gBiasRaw[ii] = gBiasRawTemp[ii] / samples; |
ChangYuHsuan | 6:28c4b3c8b43d | 242 | aBiasRaw[ii] = aBiasRawTemp[ii] / samples; |
ChangYuHsuan | 6:28c4b3c8b43d | 243 | |
ChangYuHsuan | 6:28c4b3c8b43d | 244 | gBias[ii] = gBiasRaw[ii] * gRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 245 | aBias[ii] = aBiasRaw[ii] * aRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 246 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 247 | |
ChangYuHsuan | 6:28c4b3c8b43d | 248 | autoCalib = true; |
ChangYuHsuan | 6:28c4b3c8b43d | 249 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 250 | |
beanmachine44 | 0:622e8874902e | 251 | void LSM9DS1::readAccel() |
beanmachine44 | 0:622e8874902e | 252 | { |
beanmachine44 | 0:622e8874902e | 253 | // The data we are going to read from the accel |
beanmachine44 | 0:622e8874902e | 254 | char data[6]; |
beanmachine44 | 0:622e8874902e | 255 | |
beanmachine44 | 0:622e8874902e | 256 | // The start of the addresses we want to read from |
beanmachine44 | 0:622e8874902e | 257 | char subAddress = OUT_X_L_XL; |
beanmachine44 | 0:622e8874902e | 258 | |
beanmachine44 | 0:622e8874902e | 259 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 260 | i2c.write(xgAddress, &subAddress, 1, true); |
beanmachine44 | 0:622e8874902e | 261 | // Read in all 8 bit registers containing the axes data |
beanmachine44 | 0:622e8874902e | 262 | i2c.read(xgAddress, data, 6); |
beanmachine44 | 0:622e8874902e | 263 | |
beanmachine44 | 0:622e8874902e | 264 | // Reassemble the data and convert to g |
beanmachine44 | 0:622e8874902e | 265 | ax_raw = data[0] | (data[1] << 8); |
beanmachine44 | 0:622e8874902e | 266 | ay_raw = data[2] | (data[3] << 8); |
beanmachine44 | 0:622e8874902e | 267 | az_raw = data[4] | (data[5] << 8); |
beanmachine44 | 0:622e8874902e | 268 | ax = ax_raw * aRes; |
beanmachine44 | 0:622e8874902e | 269 | ay = ay_raw * aRes; |
beanmachine44 | 0:622e8874902e | 270 | az = az_raw * aRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 271 | |
ChangYuHsuan | 6:28c4b3c8b43d | 272 | if(autoCalib == true) |
ChangYuHsuan | 6:28c4b3c8b43d | 273 | { |
ChangYuHsuan | 6:28c4b3c8b43d | 274 | ax_raw -= aBiasRaw[0]; |
ChangYuHsuan | 6:28c4b3c8b43d | 275 | ay_raw -= aBiasRaw[1]; |
ChangYuHsuan | 6:28c4b3c8b43d | 276 | az_raw -= aBiasRaw[2]; |
ChangYuHsuan | 6:28c4b3c8b43d | 277 | |
ChangYuHsuan | 6:28c4b3c8b43d | 278 | ax = ax_raw * aRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 279 | ay = ay_raw * aRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 280 | az = az_raw * aRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 281 | } |
beanmachine44 | 0:622e8874902e | 282 | } |
beanmachine44 | 0:622e8874902e | 283 | |
beanmachine44 | 0:622e8874902e | 284 | void LSM9DS1::readMag() |
beanmachine44 | 0:622e8874902e | 285 | { |
beanmachine44 | 0:622e8874902e | 286 | // The data we are going to read from the mag |
beanmachine44 | 0:622e8874902e | 287 | char data[6]; |
beanmachine44 | 0:622e8874902e | 288 | |
beanmachine44 | 0:622e8874902e | 289 | // The start of the addresses we want to read from |
beanmachine44 | 0:622e8874902e | 290 | char subAddress = OUT_X_L_M; |
beanmachine44 | 0:622e8874902e | 291 | |
beanmachine44 | 0:622e8874902e | 292 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 293 | i2c.write(mAddress, &subAddress, 1, true); |
beanmachine44 | 0:622e8874902e | 294 | // Read in all 8 bit registers containing the axes data |
beanmachine44 | 0:622e8874902e | 295 | i2c.read(mAddress, data, 6); |
beanmachine44 | 0:622e8874902e | 296 | |
beanmachine44 | 0:622e8874902e | 297 | // Reassemble the data and convert to degrees |
beanmachine44 | 0:622e8874902e | 298 | mx_raw = data[0] | (data[1] << 8); |
beanmachine44 | 0:622e8874902e | 299 | my_raw = data[2] | (data[3] << 8); |
beanmachine44 | 0:622e8874902e | 300 | mz_raw = data[4] | (data[5] << 8); |
beanmachine44 | 0:622e8874902e | 301 | mx = mx_raw * mRes; |
beanmachine44 | 0:622e8874902e | 302 | my = my_raw * mRes; |
beanmachine44 | 0:622e8874902e | 303 | mz = mz_raw * mRes; |
beanmachine44 | 0:622e8874902e | 304 | } |
beanmachine44 | 0:622e8874902e | 305 | |
5hel2l2y | 3:f96b287c0bf7 | 306 | void LSM9DS1::readIntr() |
5hel2l2y | 3:f96b287c0bf7 | 307 | { |
5hel2l2y | 3:f96b287c0bf7 | 308 | char data[1]; |
5hel2l2y | 3:f96b287c0bf7 | 309 | char subAddress = INT_GEN_SRC_G; |
5hel2l2y | 3:f96b287c0bf7 | 310 | |
5hel2l2y | 3:f96b287c0bf7 | 311 | i2c.write(xgAddress, &subAddress, 1, true); |
5hel2l2y | 3:f96b287c0bf7 | 312 | i2c.read(xgAddress, data, 1); |
5hel2l2y | 3:f96b287c0bf7 | 313 | |
5hel2l2y | 3:f96b287c0bf7 | 314 | intr = (float)data[0]; |
5hel2l2y | 3:f96b287c0bf7 | 315 | } |
5hel2l2y | 3:f96b287c0bf7 | 316 | |
beanmachine44 | 0:622e8874902e | 317 | void LSM9DS1::readTemp() |
beanmachine44 | 0:622e8874902e | 318 | { |
beanmachine44 | 0:622e8874902e | 319 | // The data we are going to read from the temp |
beanmachine44 | 0:622e8874902e | 320 | char data[2]; |
beanmachine44 | 0:622e8874902e | 321 | |
beanmachine44 | 0:622e8874902e | 322 | // The start of the addresses we want to read from |
beanmachine44 | 0:622e8874902e | 323 | char subAddress = OUT_TEMP_L; |
beanmachine44 | 0:622e8874902e | 324 | |
beanmachine44 | 0:622e8874902e | 325 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 326 | i2c.write(xgAddress, &subAddress, 1, true); |
beanmachine44 | 0:622e8874902e | 327 | // Read in all 8 bit registers containing the axes data |
beanmachine44 | 0:622e8874902e | 328 | i2c.read(xgAddress, data, 2); |
beanmachine44 | 0:622e8874902e | 329 | |
beanmachine44 | 0:622e8874902e | 330 | // Temperature is a 12-bit signed integer |
beanmachine44 | 0:622e8874902e | 331 | temperature_raw = data[0] | (data[1] << 8); |
beanmachine44 | 0:622e8874902e | 332 | |
beanmachine44 | 0:622e8874902e | 333 | temperature_c = (float)temperature_raw / 8.0 + 25; |
beanmachine44 | 0:622e8874902e | 334 | temperature_f = temperature_c * 1.8 + 32; |
beanmachine44 | 0:622e8874902e | 335 | } |
beanmachine44 | 0:622e8874902e | 336 | |
beanmachine44 | 0:622e8874902e | 337 | void LSM9DS1::readGyro() |
beanmachine44 | 0:622e8874902e | 338 | { |
beanmachine44 | 0:622e8874902e | 339 | // The data we are going to read from the gyro |
beanmachine44 | 0:622e8874902e | 340 | char data[6]; |
beanmachine44 | 0:622e8874902e | 341 | |
beanmachine44 | 0:622e8874902e | 342 | // The start of the addresses we want to read from |
beanmachine44 | 0:622e8874902e | 343 | char subAddress = OUT_X_L_G; |
beanmachine44 | 0:622e8874902e | 344 | |
beanmachine44 | 0:622e8874902e | 345 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 346 | i2c.write(xgAddress, &subAddress, 1, true); |
ChangYuHsuan | 7:e6e3d320eb6c | 347 | // i2c.write(xgAddress, &subAddress, 1); |
beanmachine44 | 0:622e8874902e | 348 | // Read in all 8 bit registers containing the axes data |
beanmachine44 | 0:622e8874902e | 349 | i2c.read(xgAddress, data, 6); |
beanmachine44 | 0:622e8874902e | 350 | |
beanmachine44 | 0:622e8874902e | 351 | // Reassemble the data and convert to degrees/sec |
beanmachine44 | 0:622e8874902e | 352 | gx_raw = data[0] | (data[1] << 8); |
beanmachine44 | 0:622e8874902e | 353 | gy_raw = data[2] | (data[3] << 8); |
beanmachine44 | 0:622e8874902e | 354 | gz_raw = data[4] | (data[5] << 8); |
beanmachine44 | 0:622e8874902e | 355 | gx = gx_raw * gRes; |
beanmachine44 | 0:622e8874902e | 356 | gy = gy_raw * gRes; |
beanmachine44 | 0:622e8874902e | 357 | gz = gz_raw * gRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 358 | |
ChangYuHsuan | 6:28c4b3c8b43d | 359 | if(autoCalib == true) |
ChangYuHsuan | 6:28c4b3c8b43d | 360 | { |
ChangYuHsuan | 6:28c4b3c8b43d | 361 | gx_raw -= gBiasRaw[0]; |
ChangYuHsuan | 6:28c4b3c8b43d | 362 | gy_raw -= gBiasRaw[1]; |
ChangYuHsuan | 6:28c4b3c8b43d | 363 | gz_raw -= gBiasRaw[2]; |
ChangYuHsuan | 6:28c4b3c8b43d | 364 | |
ChangYuHsuan | 6:28c4b3c8b43d | 365 | gx = gx_raw * gRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 366 | gy = gy_raw * gRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 367 | gz = gz_raw * gRes; |
ChangYuHsuan | 6:28c4b3c8b43d | 368 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 369 | |
beanmachine44 | 0:622e8874902e | 370 | } |
beanmachine44 | 0:622e8874902e | 371 | |
beanmachine44 | 0:622e8874902e | 372 | void LSM9DS1::setGyroScale(gyro_scale gScl) |
beanmachine44 | 0:622e8874902e | 373 | { |
beanmachine44 | 0:622e8874902e | 374 | // The start of the addresses we want to read from |
beanmachine44 | 0:622e8874902e | 375 | char cmd[2] = { |
beanmachine44 | 0:622e8874902e | 376 | CTRL_REG1_G, |
beanmachine44 | 0:622e8874902e | 377 | 0 |
beanmachine44 | 0:622e8874902e | 378 | }; |
beanmachine44 | 0:622e8874902e | 379 | |
beanmachine44 | 0:622e8874902e | 380 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 381 | i2c.write(xgAddress, cmd, 1, true); |
beanmachine44 | 0:622e8874902e | 382 | // Read in all the 8 bits of data |
beanmachine44 | 0:622e8874902e | 383 | i2c.read(xgAddress, cmd+1, 1); |
beanmachine44 | 0:622e8874902e | 384 | |
beanmachine44 | 0:622e8874902e | 385 | // Then mask out the gyro scale bits: |
beanmachine44 | 0:622e8874902e | 386 | cmd[1] &= 0xFF^(0x3 << 3); |
beanmachine44 | 0:622e8874902e | 387 | // Then shift in our new scale bits: |
beanmachine44 | 0:622e8874902e | 388 | cmd[1] |= gScl << 3; |
beanmachine44 | 0:622e8874902e | 389 | |
beanmachine44 | 0:622e8874902e | 390 | // Write the gyroscale out to the gyro |
beanmachine44 | 0:622e8874902e | 391 | i2c.write(xgAddress, cmd, 2); |
beanmachine44 | 0:622e8874902e | 392 | |
beanmachine44 | 0:622e8874902e | 393 | // We've updated the sensor, but we also need to update our class variables |
beanmachine44 | 0:622e8874902e | 394 | // First update gScale: |
beanmachine44 | 0:622e8874902e | 395 | gScale = gScl; |
beanmachine44 | 0:622e8874902e | 396 | // Then calculate a new gRes, which relies on gScale being set correctly: |
beanmachine44 | 0:622e8874902e | 397 | calcgRes(); |
beanmachine44 | 0:622e8874902e | 398 | } |
beanmachine44 | 0:622e8874902e | 399 | |
beanmachine44 | 0:622e8874902e | 400 | void LSM9DS1::setAccelScale(accel_scale aScl) |
beanmachine44 | 0:622e8874902e | 401 | { |
beanmachine44 | 0:622e8874902e | 402 | // The start of the addresses we want to read from |
beanmachine44 | 0:622e8874902e | 403 | char cmd[2] = { |
beanmachine44 | 0:622e8874902e | 404 | CTRL_REG6_XL, |
beanmachine44 | 0:622e8874902e | 405 | 0 |
beanmachine44 | 0:622e8874902e | 406 | }; |
beanmachine44 | 0:622e8874902e | 407 | |
beanmachine44 | 0:622e8874902e | 408 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 409 | i2c.write(xgAddress, cmd, 1, true); |
beanmachine44 | 0:622e8874902e | 410 | // Read in all the 8 bits of data |
beanmachine44 | 0:622e8874902e | 411 | i2c.read(xgAddress, cmd+1, 1); |
beanmachine44 | 0:622e8874902e | 412 | |
beanmachine44 | 0:622e8874902e | 413 | // Then mask out the accel scale bits: |
beanmachine44 | 0:622e8874902e | 414 | cmd[1] &= 0xFF^(0x3 << 3); |
beanmachine44 | 0:622e8874902e | 415 | // Then shift in our new scale bits: |
beanmachine44 | 0:622e8874902e | 416 | cmd[1] |= aScl << 3; |
beanmachine44 | 0:622e8874902e | 417 | |
beanmachine44 | 0:622e8874902e | 418 | // Write the accelscale out to the accel |
beanmachine44 | 0:622e8874902e | 419 | i2c.write(xgAddress, cmd, 2); |
beanmachine44 | 0:622e8874902e | 420 | |
beanmachine44 | 0:622e8874902e | 421 | // We've updated the sensor, but we also need to update our class variables |
beanmachine44 | 0:622e8874902e | 422 | // First update aScale: |
beanmachine44 | 0:622e8874902e | 423 | aScale = aScl; |
beanmachine44 | 0:622e8874902e | 424 | // Then calculate a new aRes, which relies on aScale being set correctly: |
beanmachine44 | 0:622e8874902e | 425 | calcaRes(); |
beanmachine44 | 0:622e8874902e | 426 | } |
beanmachine44 | 0:622e8874902e | 427 | |
beanmachine44 | 0:622e8874902e | 428 | void LSM9DS1::setMagScale(mag_scale mScl) |
beanmachine44 | 0:622e8874902e | 429 | { |
beanmachine44 | 0:622e8874902e | 430 | // The start of the addresses we want to read from |
beanmachine44 | 0:622e8874902e | 431 | char cmd[2] = { |
beanmachine44 | 0:622e8874902e | 432 | CTRL_REG2_M, |
beanmachine44 | 0:622e8874902e | 433 | 0 |
beanmachine44 | 0:622e8874902e | 434 | }; |
beanmachine44 | 0:622e8874902e | 435 | |
beanmachine44 | 0:622e8874902e | 436 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 437 | i2c.write(mAddress, cmd, 1, true); |
beanmachine44 | 0:622e8874902e | 438 | // Read in all the 8 bits of data |
beanmachine44 | 0:622e8874902e | 439 | i2c.read(mAddress, cmd+1, 1); |
beanmachine44 | 0:622e8874902e | 440 | |
beanmachine44 | 0:622e8874902e | 441 | // Then mask out the mag scale bits: |
beanmachine44 | 0:622e8874902e | 442 | cmd[1] &= 0xFF^(0x3 << 5); |
beanmachine44 | 0:622e8874902e | 443 | // Then shift in our new scale bits: |
beanmachine44 | 0:622e8874902e | 444 | cmd[1] |= mScl << 5; |
beanmachine44 | 0:622e8874902e | 445 | |
beanmachine44 | 0:622e8874902e | 446 | // Write the magscale out to the mag |
beanmachine44 | 0:622e8874902e | 447 | i2c.write(mAddress, cmd, 2); |
beanmachine44 | 0:622e8874902e | 448 | |
beanmachine44 | 0:622e8874902e | 449 | // We've updated the sensor, but we also need to update our class variables |
beanmachine44 | 0:622e8874902e | 450 | // First update mScale: |
beanmachine44 | 0:622e8874902e | 451 | mScale = mScl; |
beanmachine44 | 0:622e8874902e | 452 | // Then calculate a new mRes, which relies on mScale being set correctly: |
beanmachine44 | 0:622e8874902e | 453 | calcmRes(); |
beanmachine44 | 0:622e8874902e | 454 | } |
beanmachine44 | 0:622e8874902e | 455 | |
beanmachine44 | 0:622e8874902e | 456 | void LSM9DS1::setGyroODR(gyro_odr gRate) |
beanmachine44 | 0:622e8874902e | 457 | { |
5hel2l2y | 2:ac3b69ccd3dd | 458 | char cmd[2]; |
5hel2l2y | 2:ac3b69ccd3dd | 459 | char cmdLow[2]; |
5hel2l2y | 2:ac3b69ccd3dd | 460 | |
5hel2l2y | 2:ac3b69ccd3dd | 461 | if(gRate == G_ODR_15_BW_0 | gRate == G_ODR_60_BW_16 | gRate == G_ODR_119_BW_14 | gRate == G_ODR_119_BW_31) { |
5hel2l2y | 2:ac3b69ccd3dd | 462 | cmdLow[0] = CTRL_REG3_G; |
5hel2l2y | 2:ac3b69ccd3dd | 463 | cmdLow[1] = 1; |
5hel2l2y | 2:ac3b69ccd3dd | 464 | |
5hel2l2y | 2:ac3b69ccd3dd | 465 | i2c.write(xgAddress, cmdLow, 2); |
5hel2l2y | 2:ac3b69ccd3dd | 466 | } |
5hel2l2y | 2:ac3b69ccd3dd | 467 | |
beanmachine44 | 0:622e8874902e | 468 | // The start of the addresses we want to read from |
5hel2l2y | 2:ac3b69ccd3dd | 469 | cmd[0] = CTRL_REG1_G; |
5hel2l2y | 2:ac3b69ccd3dd | 470 | cmd[1] = 0; |
beanmachine44 | 0:622e8874902e | 471 | |
beanmachine44 | 0:622e8874902e | 472 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 473 | i2c.write(xgAddress, cmd, 1, true); |
beanmachine44 | 0:622e8874902e | 474 | // Read in all the 8 bits of data |
beanmachine44 | 0:622e8874902e | 475 | i2c.read(xgAddress, cmd+1, 1); |
beanmachine44 | 0:622e8874902e | 476 | |
beanmachine44 | 0:622e8874902e | 477 | // Then mask out the gyro odr bits: |
beanmachine44 | 0:622e8874902e | 478 | cmd[1] &= (0x3 << 3); |
beanmachine44 | 0:622e8874902e | 479 | // Then shift in our new odr bits: |
beanmachine44 | 0:622e8874902e | 480 | cmd[1] |= gRate; |
beanmachine44 | 0:622e8874902e | 481 | |
beanmachine44 | 0:622e8874902e | 482 | // Write the gyroodr out to the gyro |
beanmachine44 | 0:622e8874902e | 483 | i2c.write(xgAddress, cmd, 2); |
beanmachine44 | 0:622e8874902e | 484 | } |
beanmachine44 | 0:622e8874902e | 485 | |
beanmachine44 | 0:622e8874902e | 486 | void LSM9DS1::setAccelODR(accel_odr aRate) |
beanmachine44 | 0:622e8874902e | 487 | { |
beanmachine44 | 0:622e8874902e | 488 | // The start of the addresses we want to read from |
beanmachine44 | 0:622e8874902e | 489 | char cmd[2] = { |
beanmachine44 | 0:622e8874902e | 490 | CTRL_REG6_XL, |
beanmachine44 | 0:622e8874902e | 491 | 0 |
beanmachine44 | 0:622e8874902e | 492 | }; |
beanmachine44 | 0:622e8874902e | 493 | |
beanmachine44 | 0:622e8874902e | 494 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 495 | i2c.write(xgAddress, cmd, 1, true); |
beanmachine44 | 0:622e8874902e | 496 | // Read in all the 8 bits of data |
beanmachine44 | 0:622e8874902e | 497 | i2c.read(xgAddress, cmd+1, 1); |
beanmachine44 | 0:622e8874902e | 498 | |
beanmachine44 | 0:622e8874902e | 499 | // Then mask out the accel odr bits: |
beanmachine44 | 0:622e8874902e | 500 | cmd[1] &= 0xFF^(0x7 << 5); |
beanmachine44 | 0:622e8874902e | 501 | // Then shift in our new odr bits: |
beanmachine44 | 0:622e8874902e | 502 | cmd[1] |= aRate << 5; |
beanmachine44 | 0:622e8874902e | 503 | |
beanmachine44 | 0:622e8874902e | 504 | // Write the accelodr out to the accel |
beanmachine44 | 0:622e8874902e | 505 | i2c.write(xgAddress, cmd, 2); |
beanmachine44 | 0:622e8874902e | 506 | } |
beanmachine44 | 0:622e8874902e | 507 | |
beanmachine44 | 0:622e8874902e | 508 | void LSM9DS1::setMagODR(mag_odr mRate) |
beanmachine44 | 0:622e8874902e | 509 | { |
beanmachine44 | 0:622e8874902e | 510 | // The start of the addresses we want to read from |
beanmachine44 | 0:622e8874902e | 511 | char cmd[2] = { |
beanmachine44 | 0:622e8874902e | 512 | CTRL_REG1_M, |
beanmachine44 | 0:622e8874902e | 513 | 0 |
beanmachine44 | 0:622e8874902e | 514 | }; |
beanmachine44 | 0:622e8874902e | 515 | |
beanmachine44 | 0:622e8874902e | 516 | // Write the address we are going to read from and don't end the transaction |
beanmachine44 | 0:622e8874902e | 517 | i2c.write(mAddress, cmd, 1, true); |
beanmachine44 | 0:622e8874902e | 518 | // Read in all the 8 bits of data |
beanmachine44 | 0:622e8874902e | 519 | i2c.read(mAddress, cmd+1, 1); |
beanmachine44 | 0:622e8874902e | 520 | |
beanmachine44 | 0:622e8874902e | 521 | // Then mask out the mag odr bits: |
beanmachine44 | 0:622e8874902e | 522 | cmd[1] &= 0xFF^(0x7 << 2); |
beanmachine44 | 0:622e8874902e | 523 | // Then shift in our new odr bits: |
beanmachine44 | 0:622e8874902e | 524 | cmd[1] |= mRate << 2; |
beanmachine44 | 0:622e8874902e | 525 | |
beanmachine44 | 0:622e8874902e | 526 | // Write the magodr out to the mag |
beanmachine44 | 0:622e8874902e | 527 | i2c.write(mAddress, cmd, 2); |
beanmachine44 | 0:622e8874902e | 528 | } |
beanmachine44 | 0:622e8874902e | 529 | |
beanmachine44 | 0:622e8874902e | 530 | void LSM9DS1::calcgRes() |
beanmachine44 | 0:622e8874902e | 531 | { |
beanmachine44 | 0:622e8874902e | 532 | // Possible gyro scales (and their register bit settings) are: |
beanmachine44 | 0:622e8874902e | 533 | // 245 DPS (00), 500 DPS (01), 2000 DPS (10). |
beanmachine44 | 0:622e8874902e | 534 | switch (gScale) |
beanmachine44 | 0:622e8874902e | 535 | { |
beanmachine44 | 0:622e8874902e | 536 | case G_SCALE_245DPS: |
beanmachine44 | 0:622e8874902e | 537 | gRes = 245.0 / 32768.0; |
beanmachine44 | 0:622e8874902e | 538 | break; |
beanmachine44 | 0:622e8874902e | 539 | case G_SCALE_500DPS: |
beanmachine44 | 0:622e8874902e | 540 | gRes = 500.0 / 32768.0; |
beanmachine44 | 0:622e8874902e | 541 | break; |
beanmachine44 | 0:622e8874902e | 542 | case G_SCALE_2000DPS: |
beanmachine44 | 0:622e8874902e | 543 | gRes = 2000.0 / 32768.0; |
beanmachine44 | 0:622e8874902e | 544 | break; |
beanmachine44 | 0:622e8874902e | 545 | } |
beanmachine44 | 0:622e8874902e | 546 | } |
beanmachine44 | 0:622e8874902e | 547 | |
beanmachine44 | 0:622e8874902e | 548 | void LSM9DS1::calcaRes() |
beanmachine44 | 0:622e8874902e | 549 | { |
beanmachine44 | 0:622e8874902e | 550 | // Possible accelerometer scales (and their register bit settings) are: |
beanmachine44 | 0:622e8874902e | 551 | // 2 g (000), 4g (001), 6g (010) 8g (011), 16g (100). |
beanmachine44 | 0:622e8874902e | 552 | switch (aScale) |
beanmachine44 | 0:622e8874902e | 553 | { |
beanmachine44 | 0:622e8874902e | 554 | case A_SCALE_2G: |
beanmachine44 | 0:622e8874902e | 555 | aRes = 2.0 / 32768.0; |
beanmachine44 | 0:622e8874902e | 556 | break; |
beanmachine44 | 0:622e8874902e | 557 | case A_SCALE_4G: |
beanmachine44 | 0:622e8874902e | 558 | aRes = 4.0 / 32768.0; |
beanmachine44 | 0:622e8874902e | 559 | break; |
beanmachine44 | 0:622e8874902e | 560 | case A_SCALE_8G: |
beanmachine44 | 0:622e8874902e | 561 | aRes = 8.0 / 32768.0; |
beanmachine44 | 0:622e8874902e | 562 | break; |
beanmachine44 | 0:622e8874902e | 563 | case A_SCALE_16G: |
beanmachine44 | 0:622e8874902e | 564 | aRes = 16.0 / 32768.0; |
beanmachine44 | 0:622e8874902e | 565 | break; |
beanmachine44 | 0:622e8874902e | 566 | } |
beanmachine44 | 0:622e8874902e | 567 | } |
beanmachine44 | 0:622e8874902e | 568 | |
beanmachine44 | 0:622e8874902e | 569 | void LSM9DS1::calcmRes() |
beanmachine44 | 0:622e8874902e | 570 | { |
beanmachine44 | 0:622e8874902e | 571 | // Possible magnetometer scales (and their register bit settings) are: |
beanmachine44 | 0:622e8874902e | 572 | // 2 Gs (00), 4 Gs (01), 8 Gs (10) 12 Gs (11). |
beanmachine44 | 0:622e8874902e | 573 | switch (mScale) |
beanmachine44 | 0:622e8874902e | 574 | { |
beanmachine44 | 0:622e8874902e | 575 | case M_SCALE_4GS: |
beanmachine44 | 0:622e8874902e | 576 | mRes = 4.0 / 32768.0; |
beanmachine44 | 0:622e8874902e | 577 | break; |
beanmachine44 | 0:622e8874902e | 578 | case M_SCALE_8GS: |
beanmachine44 | 0:622e8874902e | 579 | mRes = 8.0 / 32768.0; |
beanmachine44 | 0:622e8874902e | 580 | break; |
beanmachine44 | 0:622e8874902e | 581 | case M_SCALE_12GS: |
beanmachine44 | 0:622e8874902e | 582 | mRes = 12.0 / 32768.0; |
beanmachine44 | 0:622e8874902e | 583 | break; |
beanmachine44 | 0:622e8874902e | 584 | case M_SCALE_16GS: |
beanmachine44 | 0:622e8874902e | 585 | mRes = 16.0 / 32768.0; |
beanmachine44 | 0:622e8874902e | 586 | break; |
beanmachine44 | 0:622e8874902e | 587 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 588 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 589 | |
ChangYuHsuan | 6:28c4b3c8b43d | 590 | |
ChangYuHsuan | 6:28c4b3c8b43d | 591 | /* |
ChangYuHsuan | 6:28c4b3c8b43d | 592 | void LSM9DS1::enableXgFIFO(bool enable) |
ChangYuHsuan | 6:28c4b3c8b43d | 593 | { |
ChangYuHsuan | 6:28c4b3c8b43d | 594 | char cmd[2] = {CTRL_REG9, 0}; |
ChangYuHsuan | 6:28c4b3c8b43d | 595 | |
ChangYuHsuan | 6:28c4b3c8b43d | 596 | i2c.write(xgAddress, cmd, 1); |
ChangYuHsuan | 6:28c4b3c8b43d | 597 | cmd[1] = i2c.read(CTRL_REG9); |
ChangYuHsuan | 6:28c4b3c8b43d | 598 | |
ChangYuHsuan | 6:28c4b3c8b43d | 599 | if (enable) cmd[1] |= (1<<1); |
ChangYuHsuan | 6:28c4b3c8b43d | 600 | else cmd[1] &= ~(1<<1); |
ChangYuHsuan | 6:28c4b3c8b43d | 601 | |
ChangYuHsuan | 6:28c4b3c8b43d | 602 | i2c.write(xgAddress, cmd, 2); |
ChangYuHsuan | 6:28c4b3c8b43d | 603 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 604 | |
ChangYuHsuan | 6:28c4b3c8b43d | 605 | void LSM9DS1::setXgFIFO(uint8_t fifoMode, uint8_t fifoThs) |
ChangYuHsuan | 6:28c4b3c8b43d | 606 | { |
ChangYuHsuan | 6:28c4b3c8b43d | 607 | // Limit threshold - 0x1F (31) is the maximum. If more than that was asked |
ChangYuHsuan | 6:28c4b3c8b43d | 608 | // limit it to the maximum. |
ChangYuHsuan | 6:28c4b3c8b43d | 609 | char cmd[2] = {FIFO_CTRL, 0}; |
ChangYuHsuan | 6:28c4b3c8b43d | 610 | uint8_t threshold = fifoThs <= 0x1F ? fifoThs : 0x1F; |
ChangYuHsuan | 6:28c4b3c8b43d | 611 | cmd[1] = ((fifoMode & 0x7) << 5) | (threshold & 0x1F); |
ChangYuHsuan | 6:28c4b3c8b43d | 612 | i2c.write(xgAddress, cmd, 2); |
ChangYuHsuan | 6:28c4b3c8b43d | 613 | } |
ChangYuHsuan | 6:28c4b3c8b43d | 614 | */ |