LSM6DS33 Library

Dependents:   teensyIMU LSM6DS33 ALTIMU_v6

Fork of LSM6DS3 by Sherry Yang

Committer:
5hel2l2y
Date:
Mon Jun 20 19:15:31 2016 +0000
Revision:
1:924c7dea286e
Parent:
0:46630122dec9
Child:
2:ed14e6196255
Modified Library to accept low power mode.

Who changed what in which revision?

UserRevisionLine numberNew contents of line
5hel2l2y 0:46630122dec9 1 #include "LSM6DS3.h"
5hel2l2y 0:46630122dec9 2
5hel2l2y 0:46630122dec9 3 LSM6DS3::LSM6DS3(PinName sda, PinName scl, uint8_t xgAddr) : i2c(sda, scl)
5hel2l2y 0:46630122dec9 4 {
5hel2l2y 0:46630122dec9 5 // xgAddress will store the 7-bit I2C address, if using I2C.
5hel2l2y 0:46630122dec9 6 xgAddress = xgAddr;
5hel2l2y 0:46630122dec9 7 }
5hel2l2y 0:46630122dec9 8
5hel2l2y 0:46630122dec9 9 uint16_t LSM6DS3::begin(gyro_scale gScl, accel_scale aScl,
5hel2l2y 0:46630122dec9 10 gyro_odr gODR, accel_odr aODR)
5hel2l2y 0:46630122dec9 11 {
5hel2l2y 0:46630122dec9 12 // Store the given scales in class variables. These scale variables
5hel2l2y 0:46630122dec9 13 // are used throughout to calculate the actual g's, DPS,and Gs's.
5hel2l2y 0:46630122dec9 14 gScale = gScl;
5hel2l2y 0:46630122dec9 15 aScale = aScl;
5hel2l2y 0:46630122dec9 16
5hel2l2y 0:46630122dec9 17 // Once we have the scale values, we can calculate the resolution
5hel2l2y 0:46630122dec9 18 // of each sensor. That's what these functions are for. One for each sensor
5hel2l2y 0:46630122dec9 19 calcgRes(); // Calculate DPS / ADC tick, stored in gRes variable
5hel2l2y 0:46630122dec9 20 calcaRes(); // Calculate g / ADC tick, stored in aRes variable
5hel2l2y 0:46630122dec9 21
5hel2l2y 0:46630122dec9 22
5hel2l2y 0:46630122dec9 23 // To verify communication, we can read from the WHO_AM_I register of
5hel2l2y 0:46630122dec9 24 // each device. Store those in a variable so we can return them.
5hel2l2y 0:46630122dec9 25 // The start of the addresses we want to read from
5hel2l2y 0:46630122dec9 26 char cmd[2] = {
5hel2l2y 0:46630122dec9 27 WHO_AM_I_REG,
5hel2l2y 0:46630122dec9 28 0
5hel2l2y 0:46630122dec9 29 };
5hel2l2y 0:46630122dec9 30
5hel2l2y 0:46630122dec9 31 // Write the address we are going to read from and don't end the transaction
5hel2l2y 0:46630122dec9 32 i2c.write(xgAddress, cmd, 1, true);
5hel2l2y 0:46630122dec9 33 // Read in all the 8 bits of data
5hel2l2y 0:46630122dec9 34 i2c.read(xgAddress, cmd+1, 1);
5hel2l2y 0:46630122dec9 35 uint8_t xgTest = cmd[1]; // Read the accel/gyro WHO_AM_I
5hel2l2y 0:46630122dec9 36
5hel2l2y 0:46630122dec9 37 // Gyro initialization stuff:
5hel2l2y 0:46630122dec9 38 initGyro(); // This will "turn on" the gyro. Setting up interrupts, etc.
5hel2l2y 0:46630122dec9 39 setGyroODR(gODR); // Set the gyro output data rate and bandwidth.
5hel2l2y 0:46630122dec9 40 setGyroScale(gScale); // Set the gyro range
5hel2l2y 0:46630122dec9 41
5hel2l2y 0:46630122dec9 42 // Accelerometer initialization stuff:
5hel2l2y 0:46630122dec9 43 initAccel(); // "Turn on" all axes of the accel. Set up interrupts, etc.
5hel2l2y 0:46630122dec9 44 setAccelODR(aODR); // Set the accel data rate.
5hel2l2y 0:46630122dec9 45 setAccelScale(aScale); // Set the accel range.
5hel2l2y 0:46630122dec9 46
5hel2l2y 0:46630122dec9 47 // Once everything is initialized, return the WHO_AM_I registers we read:
5hel2l2y 0:46630122dec9 48 return xgTest;
5hel2l2y 0:46630122dec9 49 }
5hel2l2y 0:46630122dec9 50
5hel2l2y 0:46630122dec9 51 void LSM6DS3::initGyro()
5hel2l2y 0:46630122dec9 52 {
5hel2l2y 0:46630122dec9 53 char cmd[4] = {
5hel2l2y 0:46630122dec9 54 CTRL2_G,
5hel2l2y 1:924c7dea286e 55 gScale | G_ODR_104,
5hel2l2y 0:46630122dec9 56 0, // Default data out and int out
5hel2l2y 0:46630122dec9 57 0 // Default power mode and high pass settings
5hel2l2y 0:46630122dec9 58 };
5hel2l2y 0:46630122dec9 59
5hel2l2y 0:46630122dec9 60 // Write the data to the gyro control registers
5hel2l2y 0:46630122dec9 61 i2c.write(xgAddress, cmd, 4);
5hel2l2y 0:46630122dec9 62 }
5hel2l2y 0:46630122dec9 63
5hel2l2y 0:46630122dec9 64 void LSM6DS3::initAccel()
5hel2l2y 0:46630122dec9 65 {
5hel2l2y 0:46630122dec9 66 char cmd[4] = {
5hel2l2y 0:46630122dec9 67 CTRL1_XL,
5hel2l2y 0:46630122dec9 68 0x38, // Enable all axis and don't decimate data in out Registers
5hel2l2y 1:924c7dea286e 69 (A_ODR_104 << 5) | (aScale << 3) | (A_BW_AUTO_SCALE), // 119 Hz ODR, set scale, and auto BW
5hel2l2y 0:46630122dec9 70 0 // Default resolution mode and filtering settings
5hel2l2y 0:46630122dec9 71 };
5hel2l2y 0:46630122dec9 72
5hel2l2y 0:46630122dec9 73 // Write the data to the accel control registers
5hel2l2y 0:46630122dec9 74 i2c.write(xgAddress, cmd, 4);
5hel2l2y 0:46630122dec9 75 }
5hel2l2y 0:46630122dec9 76
5hel2l2y 0:46630122dec9 77 void LSM6DS3::readAccel()
5hel2l2y 0:46630122dec9 78 {
5hel2l2y 0:46630122dec9 79 // The data we are going to read from the accel
5hel2l2y 0:46630122dec9 80 char data[6];
5hel2l2y 0:46630122dec9 81
5hel2l2y 0:46630122dec9 82 // Set addresses
5hel2l2y 0:46630122dec9 83 char subAddressXL = OUTX_L_XL;
5hel2l2y 0:46630122dec9 84 char subAddressXH = OUTX_H_XL;
5hel2l2y 0:46630122dec9 85 char subAddressYL = OUTY_L_XL;
5hel2l2y 0:46630122dec9 86 char subAddressYH = OUTY_H_XL;
5hel2l2y 0:46630122dec9 87 char subAddressZL = OUTZ_L_XL;
5hel2l2y 0:46630122dec9 88 char subAddressZH = OUTZ_H_XL;
5hel2l2y 0:46630122dec9 89
5hel2l2y 0:46630122dec9 90 // Write the address we are going to read from and don't end the transaction
5hel2l2y 0:46630122dec9 91 i2c.write(xgAddress, &subAddressXL, 1, true);
5hel2l2y 0:46630122dec9 92 // Read in register containing the axes data and alocated to the correct index
5hel2l2y 0:46630122dec9 93 i2c.read(xgAddress, data, 1);
5hel2l2y 0:46630122dec9 94
5hel2l2y 0:46630122dec9 95 i2c.write(xgAddress, &subAddressXH, 1, true);
5hel2l2y 0:46630122dec9 96 i2c.read(xgAddress, (data + 1), 1);
5hel2l2y 0:46630122dec9 97 i2c.write(xgAddress, &subAddressYL, 1, true);
5hel2l2y 0:46630122dec9 98 i2c.read(xgAddress, (data + 2), 1);
5hel2l2y 0:46630122dec9 99 i2c.write(xgAddress, &subAddressYH, 1, true);
5hel2l2y 0:46630122dec9 100 i2c.read(xgAddress, (data + 3), 1);
5hel2l2y 0:46630122dec9 101 i2c.write(xgAddress, &subAddressZL, 1, true);
5hel2l2y 0:46630122dec9 102 i2c.read(xgAddress, (data + 4), 1);
5hel2l2y 0:46630122dec9 103 i2c.write(xgAddress, &subAddressZH, 1, true);
5hel2l2y 0:46630122dec9 104 i2c.read(xgAddress, (data + 5), 1);
5hel2l2y 0:46630122dec9 105
5hel2l2y 0:46630122dec9 106 // Reassemble the data and convert to g
5hel2l2y 0:46630122dec9 107 ax_raw = data[0] | (data[1] << 8);
5hel2l2y 0:46630122dec9 108 ay_raw = data[2] | (data[3] << 8);
5hel2l2y 0:46630122dec9 109 az_raw = data[4] | (data[5] << 8);
5hel2l2y 0:46630122dec9 110 ax = ax_raw * aRes;
5hel2l2y 0:46630122dec9 111 ay = ay_raw * aRes;
5hel2l2y 0:46630122dec9 112 az = az_raw * aRes;
5hel2l2y 0:46630122dec9 113 }
5hel2l2y 0:46630122dec9 114
5hel2l2y 0:46630122dec9 115 void LSM6DS3::readTemp()
5hel2l2y 0:46630122dec9 116 {
5hel2l2y 0:46630122dec9 117 // The data we are going to read from the temp
5hel2l2y 0:46630122dec9 118 char data[2];
5hel2l2y 0:46630122dec9 119
5hel2l2y 0:46630122dec9 120 // Set addresses
5hel2l2y 0:46630122dec9 121 char subAddressL = OUT_TEMP_L;
5hel2l2y 0:46630122dec9 122 char subAddressH = OUT_TEMP_H;
5hel2l2y 0:46630122dec9 123
5hel2l2y 0:46630122dec9 124 // Write the address we are going to read from and don't end the transaction
5hel2l2y 0:46630122dec9 125 i2c.write(xgAddress, &subAddressL, 1, true);
5hel2l2y 0:46630122dec9 126 // Read in register containing the temperature data and alocated to the correct index
5hel2l2y 0:46630122dec9 127 i2c.read(xgAddress, data, 1);
5hel2l2y 0:46630122dec9 128
5hel2l2y 0:46630122dec9 129 i2c.write(xgAddress, &subAddressH, 1, true);
5hel2l2y 0:46630122dec9 130 i2c.read(xgAddress, (data + 1), 1);
5hel2l2y 0:46630122dec9 131
5hel2l2y 0:46630122dec9 132 // Temperature is a 12-bit signed integer
5hel2l2y 0:46630122dec9 133 temperature_raw = data[0] | (data[1] << 8);
5hel2l2y 0:46630122dec9 134
5hel2l2y 0:46630122dec9 135 temperature_c = (float)temperature_raw / 16.0 + 25.0;
5hel2l2y 0:46630122dec9 136 temperature_f = temperature_c * 1.8 + 32.0;
5hel2l2y 0:46630122dec9 137 }
5hel2l2y 0:46630122dec9 138
5hel2l2y 0:46630122dec9 139
5hel2l2y 0:46630122dec9 140 void LSM6DS3::readGyro()
5hel2l2y 0:46630122dec9 141 {
5hel2l2y 0:46630122dec9 142 // The data we are going to read from the gyro
5hel2l2y 0:46630122dec9 143 char data[6];
5hel2l2y 0:46630122dec9 144
5hel2l2y 0:46630122dec9 145 // Set addresses
5hel2l2y 0:46630122dec9 146 char subAddressXL = OUTX_L_G;
5hel2l2y 0:46630122dec9 147 char subAddressXH = OUTX_H_G;
5hel2l2y 0:46630122dec9 148 char subAddressYL = OUTY_L_G;
5hel2l2y 0:46630122dec9 149 char subAddressYH = OUTY_H_G;
5hel2l2y 0:46630122dec9 150 char subAddressZL = OUTZ_L_G;
5hel2l2y 0:46630122dec9 151 char subAddressZH = OUTZ_H_G;
5hel2l2y 0:46630122dec9 152
5hel2l2y 0:46630122dec9 153 // Write the address we are going to read from and don't end the transaction
5hel2l2y 0:46630122dec9 154 i2c.write(xgAddress, &subAddressXL, 1, true);
5hel2l2y 0:46630122dec9 155 // Read in register containing the axes data and alocated to the correct index
5hel2l2y 0:46630122dec9 156 i2c.read(xgAddress, data, 1);
5hel2l2y 0:46630122dec9 157
5hel2l2y 0:46630122dec9 158 i2c.write(xgAddress, &subAddressXH, 1, true);
5hel2l2y 0:46630122dec9 159 i2c.read(xgAddress, (data + 1), 1);
5hel2l2y 0:46630122dec9 160 i2c.write(xgAddress, &subAddressYL, 1, true);
5hel2l2y 0:46630122dec9 161 i2c.read(xgAddress, (data + 2), 1);
5hel2l2y 0:46630122dec9 162 i2c.write(xgAddress, &subAddressYH, 1, true);
5hel2l2y 0:46630122dec9 163 i2c.read(xgAddress, (data + 3), 1);
5hel2l2y 0:46630122dec9 164 i2c.write(xgAddress, &subAddressZL, 1, true);
5hel2l2y 0:46630122dec9 165 i2c.read(xgAddress, (data + 4), 1);
5hel2l2y 0:46630122dec9 166 i2c.write(xgAddress, &subAddressZH, 1, true);
5hel2l2y 0:46630122dec9 167 i2c.read(xgAddress, (data + 5), 1);
5hel2l2y 0:46630122dec9 168
5hel2l2y 0:46630122dec9 169 // Reassemble the data and convert to degrees/sec
5hel2l2y 0:46630122dec9 170 gx_raw = data[0] | (data[1] << 8);
5hel2l2y 0:46630122dec9 171 gy_raw = data[2] | (data[3] << 8);
5hel2l2y 0:46630122dec9 172 gz_raw = data[4] | (data[5] << 8);
5hel2l2y 0:46630122dec9 173 gx = gx_raw * gRes;
5hel2l2y 0:46630122dec9 174 gy = gy_raw * gRes;
5hel2l2y 0:46630122dec9 175 gz = gz_raw * gRes;
5hel2l2y 0:46630122dec9 176 }
5hel2l2y 0:46630122dec9 177
5hel2l2y 0:46630122dec9 178 void LSM6DS3::setGyroScale(gyro_scale gScl)
5hel2l2y 0:46630122dec9 179 {
5hel2l2y 0:46630122dec9 180 // The start of the addresses we want to read from
5hel2l2y 0:46630122dec9 181 char cmd[2] = {
5hel2l2y 0:46630122dec9 182 CTRL2_G,
5hel2l2y 0:46630122dec9 183 0
5hel2l2y 0:46630122dec9 184 };
5hel2l2y 0:46630122dec9 185
5hel2l2y 0:46630122dec9 186 // Write the address we are going to read from and don't end the transaction
5hel2l2y 0:46630122dec9 187 i2c.write(xgAddress, cmd, 1, true);
5hel2l2y 0:46630122dec9 188 // Read in all the 8 bits of data
5hel2l2y 0:46630122dec9 189 i2c.read(xgAddress, cmd+1, 1);
5hel2l2y 0:46630122dec9 190
5hel2l2y 0:46630122dec9 191 // Then mask out the gyro scale bits:
5hel2l2y 0:46630122dec9 192 cmd[1] &= 0xFF^(0x3 << 3);
5hel2l2y 0:46630122dec9 193 // Then shift in our new scale bits:
5hel2l2y 0:46630122dec9 194 cmd[1] |= gScl << 3;
5hel2l2y 0:46630122dec9 195
5hel2l2y 0:46630122dec9 196 // Write the gyroscale out to the gyro
5hel2l2y 0:46630122dec9 197 i2c.write(xgAddress, cmd, 2);
5hel2l2y 0:46630122dec9 198
5hel2l2y 0:46630122dec9 199 // We've updated the sensor, but we also need to update our class variables
5hel2l2y 0:46630122dec9 200 // First update gScale:
5hel2l2y 0:46630122dec9 201 gScale = gScl;
5hel2l2y 0:46630122dec9 202 // Then calculate a new gRes, which relies on gScale being set correctly:
5hel2l2y 0:46630122dec9 203 calcgRes();
5hel2l2y 0:46630122dec9 204 }
5hel2l2y 0:46630122dec9 205
5hel2l2y 0:46630122dec9 206 void LSM6DS3::setAccelScale(accel_scale aScl)
5hel2l2y 0:46630122dec9 207 {
5hel2l2y 0:46630122dec9 208 // The start of the addresses we want to read from
5hel2l2y 0:46630122dec9 209 char cmd[2] = {
5hel2l2y 0:46630122dec9 210 CTRL1_XL,
5hel2l2y 0:46630122dec9 211 0
5hel2l2y 0:46630122dec9 212 };
5hel2l2y 0:46630122dec9 213
5hel2l2y 0:46630122dec9 214 // Write the address we are going to read from and don't end the transaction
5hel2l2y 0:46630122dec9 215 i2c.write(xgAddress, cmd, 1, true);
5hel2l2y 0:46630122dec9 216 // Read in all the 8 bits of data
5hel2l2y 0:46630122dec9 217 i2c.read(xgAddress, cmd+1, 1);
5hel2l2y 0:46630122dec9 218
5hel2l2y 0:46630122dec9 219 // Then mask out the accel scale bits:
5hel2l2y 0:46630122dec9 220 cmd[1] &= 0xFF^(0x3 << 3);
5hel2l2y 0:46630122dec9 221 // Then shift in our new scale bits:
5hel2l2y 0:46630122dec9 222 cmd[1] |= aScl << 3;
5hel2l2y 0:46630122dec9 223
5hel2l2y 0:46630122dec9 224 // Write the accelscale out to the accel
5hel2l2y 0:46630122dec9 225 i2c.write(xgAddress, cmd, 2);
5hel2l2y 0:46630122dec9 226
5hel2l2y 0:46630122dec9 227 // We've updated the sensor, but we also need to update our class variables
5hel2l2y 0:46630122dec9 228 // First update aScale:
5hel2l2y 0:46630122dec9 229 aScale = aScl;
5hel2l2y 0:46630122dec9 230 // Then calculate a new aRes, which relies on aScale being set correctly:
5hel2l2y 0:46630122dec9 231 calcaRes();
5hel2l2y 0:46630122dec9 232 }
5hel2l2y 0:46630122dec9 233
5hel2l2y 0:46630122dec9 234 void LSM6DS3::setGyroODR(gyro_odr gRate)
5hel2l2y 0:46630122dec9 235 {
5hel2l2y 0:46630122dec9 236 // The start of the addresses we want to read from
5hel2l2y 0:46630122dec9 237 char cmd[2] = {
5hel2l2y 0:46630122dec9 238 CTRL2_G,
5hel2l2y 0:46630122dec9 239 0
5hel2l2y 0:46630122dec9 240 };
5hel2l2y 1:924c7dea286e 241
5hel2l2y 1:924c7dea286e 242 // Set low power based on ODR, else keep sensor on high performance
5hel2l2y 1:924c7dea286e 243 if(gRate == G_ODR_13_BW_0 | gRate == G_ODR_26_BW_2 | gRate == G_ODR_52_BW_16) {
5hel2l2y 1:924c7dea286e 244 char cmdLow[2] ={
5hel2l2y 1:924c7dea286e 245 CTRL7_G,
5hel2l2y 1:924c7dea286e 246 1
5hel2l2y 1:924c7dea286e 247 };
5hel2l2y 1:924c7dea286e 248
5hel2l2y 1:924c7dea286e 249 i2c.write(xgAddress, cmdLow, 2);
5hel2l2y 1:924c7dea286e 250 }
5hel2l2y 1:924c7dea286e 251 else {
5hel2l2y 1:924c7dea286e 252 char cmdLow[2] ={
5hel2l2y 1:924c7dea286e 253 CTRL7_G,
5hel2l2y 1:924c7dea286e 254 0
5hel2l2y 1:924c7dea286e 255 };
5hel2l2y 1:924c7dea286e 256
5hel2l2y 1:924c7dea286e 257 i2c.write(xgAddress, cmdLow, 2);
5hel2l2y 1:924c7dea286e 258 }
5hel2l2y 0:46630122dec9 259
5hel2l2y 0:46630122dec9 260 // Write the address we are going to read from and don't end the transaction
5hel2l2y 0:46630122dec9 261 i2c.write(xgAddress, cmd, 1, true);
5hel2l2y 0:46630122dec9 262 // Read in all the 8 bits of data
5hel2l2y 0:46630122dec9 263 i2c.read(xgAddress, cmd+1, 1);
5hel2l2y 0:46630122dec9 264
5hel2l2y 0:46630122dec9 265 // Then mask out the gyro odr bits:
5hel2l2y 0:46630122dec9 266 cmd[1] &= (0x3 << 3);
5hel2l2y 0:46630122dec9 267 // Then shift in our new odr bits:
5hel2l2y 0:46630122dec9 268 cmd[1] |= gRate;
5hel2l2y 0:46630122dec9 269
5hel2l2y 0:46630122dec9 270 // Write the gyroodr out to the gyro
5hel2l2y 0:46630122dec9 271 i2c.write(xgAddress, cmd, 2);
5hel2l2y 0:46630122dec9 272 }
5hel2l2y 0:46630122dec9 273
5hel2l2y 0:46630122dec9 274 void LSM6DS3::setAccelODR(accel_odr aRate)
5hel2l2y 0:46630122dec9 275 {
5hel2l2y 0:46630122dec9 276 // The start of the addresses we want to read from
5hel2l2y 0:46630122dec9 277 char cmd[2] = {
5hel2l2y 0:46630122dec9 278 CTRL1_XL,
5hel2l2y 0:46630122dec9 279 0
5hel2l2y 0:46630122dec9 280 };
5hel2l2y 1:924c7dea286e 281
5hel2l2y 1:924c7dea286e 282 // Set low power based on ODR, else keep sensor on high performance
5hel2l2y 1:924c7dea286e 283 if(aRate == A_ODR_13 | aRate == A_ODR_26 | aRate == A_ODR_52) {
5hel2l2y 1:924c7dea286e 284 char cmdLow[2] ={
5hel2l2y 1:924c7dea286e 285 CTRL6_C,
5hel2l2y 1:924c7dea286e 286 1
5hel2l2y 1:924c7dea286e 287 };
5hel2l2y 1:924c7dea286e 288
5hel2l2y 1:924c7dea286e 289 i2c.write(xgAddress, cmdLow, 2);
5hel2l2y 1:924c7dea286e 290 }
5hel2l2y 1:924c7dea286e 291 else {
5hel2l2y 1:924c7dea286e 292 char cmdLow[2] ={
5hel2l2y 1:924c7dea286e 293 CTRL6_C,
5hel2l2y 1:924c7dea286e 294 0
5hel2l2y 1:924c7dea286e 295 };
5hel2l2y 1:924c7dea286e 296
5hel2l2y 1:924c7dea286e 297 i2c.write(xgAddress, cmdLow, 2);
5hel2l2y 1:924c7dea286e 298 }
5hel2l2y 0:46630122dec9 299
5hel2l2y 0:46630122dec9 300 // Write the address we are going to read from and don't end the transaction
5hel2l2y 0:46630122dec9 301 i2c.write(xgAddress, cmd, 1, true);
5hel2l2y 0:46630122dec9 302 // Read in all the 8 bits of data
5hel2l2y 0:46630122dec9 303 i2c.read(xgAddress, cmd+1, 1);
5hel2l2y 0:46630122dec9 304
5hel2l2y 0:46630122dec9 305 // Then mask out the accel odr bits:
5hel2l2y 0:46630122dec9 306 cmd[1] &= 0xFF^(0x7 << 5);
5hel2l2y 0:46630122dec9 307 // Then shift in our new odr bits:
5hel2l2y 0:46630122dec9 308 cmd[1] |= aRate << 5;
5hel2l2y 0:46630122dec9 309
5hel2l2y 0:46630122dec9 310 // Write the accelodr out to the accel
5hel2l2y 0:46630122dec9 311 i2c.write(xgAddress, cmd, 2);
5hel2l2y 0:46630122dec9 312 }
5hel2l2y 0:46630122dec9 313
5hel2l2y 0:46630122dec9 314 void LSM6DS3::calcgRes()
5hel2l2y 0:46630122dec9 315 {
5hel2l2y 0:46630122dec9 316 // Possible gyro scales (and their register bit settings) are:
5hel2l2y 0:46630122dec9 317 // 245 DPS (00), 500 DPS (01), 2000 DPS (10).
5hel2l2y 0:46630122dec9 318 switch (gScale)
5hel2l2y 0:46630122dec9 319 {
5hel2l2y 0:46630122dec9 320 case G_SCALE_245DPS:
5hel2l2y 0:46630122dec9 321 gRes = 245.0 / 32768.0;
5hel2l2y 0:46630122dec9 322 break;
5hel2l2y 0:46630122dec9 323 case G_SCALE_500DPS:
5hel2l2y 0:46630122dec9 324 gRes = 500.0 / 32768.0;
5hel2l2y 0:46630122dec9 325 break;
5hel2l2y 0:46630122dec9 326 case G_SCALE_2000DPS:
5hel2l2y 0:46630122dec9 327 gRes = 2000.0 / 32768.0;
5hel2l2y 0:46630122dec9 328 break;
5hel2l2y 0:46630122dec9 329 }
5hel2l2y 0:46630122dec9 330 }
5hel2l2y 0:46630122dec9 331
5hel2l2y 0:46630122dec9 332 void LSM6DS3::calcaRes()
5hel2l2y 0:46630122dec9 333 {
5hel2l2y 0:46630122dec9 334 // Possible accelerometer scales (and their register bit settings) are:
5hel2l2y 0:46630122dec9 335 // 2 g (000), 4g (001), 6g (010) 8g (011), 16g (100).
5hel2l2y 0:46630122dec9 336 switch (aScale)
5hel2l2y 0:46630122dec9 337 {
5hel2l2y 0:46630122dec9 338 case A_SCALE_2G:
5hel2l2y 0:46630122dec9 339 aRes = 2.0 / 32768.0;
5hel2l2y 0:46630122dec9 340 break;
5hel2l2y 0:46630122dec9 341 case A_SCALE_4G:
5hel2l2y 0:46630122dec9 342 aRes = 4.0 / 32768.0;
5hel2l2y 0:46630122dec9 343 break;
5hel2l2y 0:46630122dec9 344 case A_SCALE_8G:
5hel2l2y 0:46630122dec9 345 aRes = 8.0 / 32768.0;
5hel2l2y 0:46630122dec9 346 break;
5hel2l2y 0:46630122dec9 347 case A_SCALE_16G:
5hel2l2y 0:46630122dec9 348 aRes = 16.0 / 32768.0;
5hel2l2y 0:46630122dec9 349 break;
5hel2l2y 0:46630122dec9 350 }
5hel2l2y 0:46630122dec9 351 }