Resolve STM issues

Dependencies:   mbed

Fork of MPU6050 by Shundo Kishi

Committer:
syundo0730
Date:
Tue Nov 19 19:05:55 2013 +0000
Revision:
3:25e1a5a10e53
Parent:
2:f8bfb37b2e1f
Child:
6:b272bd888e98
first commit

Who changed what in which revision?

UserRevisionLine numberNew contents of line
garfieldsg 0:662207e34fba 1 //ported from arduino library: https://github.com/jrowberg/i2cdevlib/tree/master/Arduino/MPU6050
garfieldsg 0:662207e34fba 2 //written by szymon gaertig (email: szymon@gaertig.com.pl)
garfieldsg 0:662207e34fba 3 //
garfieldsg 0:662207e34fba 4 //Changelog:
garfieldsg 0:662207e34fba 5 //2013-01-08 - first beta release
garfieldsg 0:662207e34fba 6
garfieldsg 0:662207e34fba 7 // I2Cdev library collection - MPU6050 I2C device class
garfieldsg 0:662207e34fba 8 // Based on InvenSense MPU-6050 register map document rev. 2.0, 5/19/2011 (RM-MPU-6000A-00)
garfieldsg 0:662207e34fba 9 // 8/24/2011 by Jeff Rowberg <jeff@rowberg.net>
garfieldsg 0:662207e34fba 10 // Updates should (hopefully) always be available at https://github.com/jrowberg/i2cdevlib
garfieldsg 0:662207e34fba 11 //
garfieldsg 0:662207e34fba 12 // Changelog:
garfieldsg 0:662207e34fba 13 // ... - ongoing debug release
garfieldsg 0:662207e34fba 14
garfieldsg 0:662207e34fba 15 // NOTE: THIS IS ONLY A PARIAL RELEASE. THIS DEVICE CLASS IS CURRENTLY UNDERGOING ACTIVE
garfieldsg 0:662207e34fba 16 // DEVELOPMENT AND IS STILL MISSING SOME IMPORTANT FEATURES. PLEASE KEEP THIS IN MIND IF
garfieldsg 0:662207e34fba 17 // YOU DECIDE TO USE THIS PARTICULAR CODE FOR ANYTHING.
garfieldsg 0:662207e34fba 18
garfieldsg 0:662207e34fba 19 /* ============================================
garfieldsg 0:662207e34fba 20 I2Cdev device library code is placed under the MIT license
garfieldsg 0:662207e34fba 21 Copyright (c) 2012 Jeff Rowberg
garfieldsg 0:662207e34fba 22
garfieldsg 0:662207e34fba 23 Permission is hereby granted, free of charge, to any person obtaining a copy
garfieldsg 0:662207e34fba 24 of this software and associated documentation files (the "Software"), to deal
garfieldsg 0:662207e34fba 25 in the Software without restriction, including without limitation the rights
garfieldsg 0:662207e34fba 26 to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
garfieldsg 0:662207e34fba 27 copies of the Software, and to permit persons to whom the Software is
garfieldsg 0:662207e34fba 28 furnished to do so, subject to the following conditions:
garfieldsg 0:662207e34fba 29
garfieldsg 0:662207e34fba 30 The above copyright notice and this permission notice shall be included in
garfieldsg 0:662207e34fba 31 all copies or substantial portions of the Software.
garfieldsg 0:662207e34fba 32
garfieldsg 0:662207e34fba 33 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
garfieldsg 0:662207e34fba 34 IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
garfieldsg 0:662207e34fba 35 FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
garfieldsg 0:662207e34fba 36 AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
garfieldsg 0:662207e34fba 37 LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
garfieldsg 0:662207e34fba 38 OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
garfieldsg 0:662207e34fba 39 THE SOFTWARE.
garfieldsg 0:662207e34fba 40 ===============================================
garfieldsg 0:662207e34fba 41 */
garfieldsg 0:662207e34fba 42
garfieldsg 0:662207e34fba 43 #include "MPU6050.h"
garfieldsg 0:662207e34fba 44
garfieldsg 0:662207e34fba 45 #define useDebugSerial
garfieldsg 0:662207e34fba 46
garfieldsg 0:662207e34fba 47 //instead of using pgmspace.h
garfieldsg 0:662207e34fba 48 typedef const unsigned char prog_uchar;
syundo0730 3:25e1a5a10e53 49 #define pgm_read_byte_near(x) (*(prog_uchar*)(x))//<- I modified here
syundo0730 3:25e1a5a10e53 50 #define pgm_read_byte(x) (*(prog_uchar*)(x))//<- I modified here
garfieldsg 0:662207e34fba 51
garfieldsg 0:662207e34fba 52 /** Default constructor, uses default I2C address.
garfieldsg 0:662207e34fba 53 * @see MPU6050_DEFAULT_ADDRESS
garfieldsg 0:662207e34fba 54 */
garfieldsg 0:662207e34fba 55 MPU6050::MPU6050() : debugSerial(USBTX, USBRX)
garfieldsg 0:662207e34fba 56 {
garfieldsg 0:662207e34fba 57 devAddr = MPU6050_DEFAULT_ADDRESS;
garfieldsg 0:662207e34fba 58 }
garfieldsg 0:662207e34fba 59
garfieldsg 0:662207e34fba 60 /** Specific address constructor.
garfieldsg 0:662207e34fba 61 * @param address I2C address
garfieldsg 0:662207e34fba 62 * @see MPU6050_DEFAULT_ADDRESS
garfieldsg 0:662207e34fba 63 * @see MPU6050_ADDRESS_AD0_LOW
garfieldsg 0:662207e34fba 64 * @see MPU6050_ADDRESS_AD0_HIGH
garfieldsg 0:662207e34fba 65 */
garfieldsg 0:662207e34fba 66 MPU6050::MPU6050(uint8_t address) : debugSerial(USBTX, USBRX)
garfieldsg 0:662207e34fba 67 {
garfieldsg 0:662207e34fba 68 devAddr = address;
garfieldsg 0:662207e34fba 69 }
garfieldsg 0:662207e34fba 70
garfieldsg 0:662207e34fba 71 /** Power on and prepare for general usage.
garfieldsg 0:662207e34fba 72 * This will activate the device and take it out of sleep mode (which must be done
garfieldsg 0:662207e34fba 73 * after start-up). This function also sets both the accelerometer and the gyroscope
garfieldsg 0:662207e34fba 74 * to their most sensitive settings, namely +/- 2g and +/- 250 degrees/sec, and sets
garfieldsg 0:662207e34fba 75 * the clock source to use the X Gyro for reference, which is slightly better than
garfieldsg 0:662207e34fba 76 * the default internal clock source.
garfieldsg 0:662207e34fba 77 */
garfieldsg 0:662207e34fba 78 void MPU6050::initialize()
garfieldsg 0:662207e34fba 79 {
garfieldsg 0:662207e34fba 80
garfieldsg 0:662207e34fba 81 #ifdef useDebugSerial
garfieldsg 0:662207e34fba 82 debugSerial.printf("MPU6050::initialize start\n");
garfieldsg 0:662207e34fba 83 #endif
garfieldsg 0:662207e34fba 84
garfieldsg 0:662207e34fba 85 setClockSource(MPU6050_CLOCK_PLL_XGYRO);
garfieldsg 0:662207e34fba 86 setFullScaleGyroRange(MPU6050_GYRO_FS_250);
garfieldsg 0:662207e34fba 87 setFullScaleAccelRange(MPU6050_ACCEL_FS_2);
garfieldsg 0:662207e34fba 88 setSleepEnabled(false); // thanks to Jack Elston for pointing this one out!
garfieldsg 0:662207e34fba 89
garfieldsg 0:662207e34fba 90 #ifdef useDebugSerial
garfieldsg 0:662207e34fba 91 debugSerial.printf("MPU6050::initialize end\n");
garfieldsg 0:662207e34fba 92 #endif
garfieldsg 0:662207e34fba 93 }
garfieldsg 0:662207e34fba 94
garfieldsg 0:662207e34fba 95 /** Verify the I2C connection.
garfieldsg 0:662207e34fba 96 * Make sure the device is connected and responds as expected.
garfieldsg 0:662207e34fba 97 * @return True if connection is valid, false otherwise
garfieldsg 0:662207e34fba 98 */
garfieldsg 0:662207e34fba 99 bool MPU6050::testConnection()
garfieldsg 0:662207e34fba 100 {
garfieldsg 0:662207e34fba 101 #ifdef useDebugSerial
garfieldsg 0:662207e34fba 102 debugSerial.printf("MPU6050::testConnection start\n");
garfieldsg 0:662207e34fba 103 #endif
garfieldsg 0:662207e34fba 104 uint8_t deviceId = getDeviceID();
garfieldsg 0:662207e34fba 105 #ifdef useDebugSerial
garfieldsg 0:662207e34fba 106 debugSerial.printf("DeviceId = %d\n",deviceId);
garfieldsg 0:662207e34fba 107 #endif
garfieldsg 0:662207e34fba 108 return deviceId == 0x34;
garfieldsg 0:662207e34fba 109 }
garfieldsg 0:662207e34fba 110
garfieldsg 0:662207e34fba 111 // AUX_VDDIO register (InvenSense demo code calls this RA_*G_OFFS_TC)
garfieldsg 0:662207e34fba 112
garfieldsg 0:662207e34fba 113 /** Get the auxiliary I2C supply voltage level.
garfieldsg 0:662207e34fba 114 * When set to 1, the auxiliary I2C bus high logic level is VDD. When cleared to
garfieldsg 0:662207e34fba 115 * 0, the auxiliary I2C bus high logic level is VLOGIC. This does not apply to
garfieldsg 0:662207e34fba 116 * the MPU-6000, which does not have a VLOGIC pin.
garfieldsg 0:662207e34fba 117 * @return I2C supply voltage level (0=VLOGIC, 1=VDD)
garfieldsg 0:662207e34fba 118 */
garfieldsg 0:662207e34fba 119 uint8_t MPU6050::getAuxVDDIOLevel()
garfieldsg 0:662207e34fba 120 {
garfieldsg 0:662207e34fba 121 i2Cdev.readBit(devAddr, MPU6050_RA_YG_OFFS_TC, MPU6050_TC_PWR_MODE_BIT, buffer);
garfieldsg 0:662207e34fba 122 return buffer[0];
garfieldsg 0:662207e34fba 123 }
garfieldsg 0:662207e34fba 124 /** Set the auxiliary I2C supply voltage level.
garfieldsg 0:662207e34fba 125 * When set to 1, the auxiliary I2C bus high logic level is VDD. When cleared to
garfieldsg 0:662207e34fba 126 * 0, the auxiliary I2C bus high logic level is VLOGIC. This does not apply to
garfieldsg 0:662207e34fba 127 * the MPU-6000, which does not have a VLOGIC pin.
garfieldsg 0:662207e34fba 128 * @param level I2C supply voltage level (0=VLOGIC, 1=VDD)
garfieldsg 0:662207e34fba 129 */
garfieldsg 0:662207e34fba 130 void MPU6050::setAuxVDDIOLevel(uint8_t level)
garfieldsg 0:662207e34fba 131 {
garfieldsg 0:662207e34fba 132 i2Cdev.writeBit(devAddr, MPU6050_RA_YG_OFFS_TC, MPU6050_TC_PWR_MODE_BIT, level);
garfieldsg 0:662207e34fba 133 }
garfieldsg 0:662207e34fba 134
garfieldsg 0:662207e34fba 135 // SMPLRT_DIV register
garfieldsg 0:662207e34fba 136
garfieldsg 0:662207e34fba 137 /** Get gyroscope output rate divider.
garfieldsg 0:662207e34fba 138 * The sensor register output, FIFO output, DMP sampling, Motion detection, Zero
garfieldsg 0:662207e34fba 139 * Motion detection, and Free Fall detection are all based on the Sample Rate.
garfieldsg 0:662207e34fba 140 * The Sample Rate is generated by dividing the gyroscope output rate by
garfieldsg 0:662207e34fba 141 * SMPLRT_DIV:
garfieldsg 0:662207e34fba 142 *
garfieldsg 0:662207e34fba 143 * Sample Rate = Gyroscope Output Rate / (1 + SMPLRT_DIV)
garfieldsg 0:662207e34fba 144 *
garfieldsg 0:662207e34fba 145 * where Gyroscope Output Rate = 8kHz when the DLPF is disabled (DLPF_CFG = 0 or
garfieldsg 0:662207e34fba 146 * 7), and 1kHz when the DLPF is enabled (see Register 26).
garfieldsg 0:662207e34fba 147 *
garfieldsg 0:662207e34fba 148 * Note: The accelerometer output rate is 1kHz. This means that for a Sample
garfieldsg 0:662207e34fba 149 * Rate greater than 1kHz, the same accelerometer sample may be output to the
garfieldsg 0:662207e34fba 150 * FIFO, DMP, and sensor registers more than once.
garfieldsg 0:662207e34fba 151 *
garfieldsg 0:662207e34fba 152 * For a diagram of the gyroscope and accelerometer signal paths, see Section 8
garfieldsg 0:662207e34fba 153 * of the MPU-6000/MPU-6050 Product Specification document.
garfieldsg 0:662207e34fba 154 *
garfieldsg 0:662207e34fba 155 * @return Current sample rate
garfieldsg 0:662207e34fba 156 * @see MPU6050_RA_SMPLRT_DIV
garfieldsg 0:662207e34fba 157 */
garfieldsg 0:662207e34fba 158 uint8_t MPU6050::getRate()
garfieldsg 0:662207e34fba 159 {
garfieldsg 0:662207e34fba 160 i2Cdev.readByte(devAddr, MPU6050_RA_SMPLRT_DIV, buffer);
garfieldsg 0:662207e34fba 161 return buffer[0];
garfieldsg 0:662207e34fba 162 }
garfieldsg 0:662207e34fba 163 /** Set gyroscope sample rate divider.
garfieldsg 0:662207e34fba 164 * @param rate New sample rate divider
garfieldsg 0:662207e34fba 165 * @see getRate()
garfieldsg 0:662207e34fba 166 * @see MPU6050_RA_SMPLRT_DIV
garfieldsg 0:662207e34fba 167 */
garfieldsg 0:662207e34fba 168 void MPU6050::setRate(uint8_t rate)
garfieldsg 0:662207e34fba 169 {
garfieldsg 0:662207e34fba 170 i2Cdev.writeByte(devAddr, MPU6050_RA_SMPLRT_DIV, rate);
garfieldsg 0:662207e34fba 171 }
garfieldsg 0:662207e34fba 172
garfieldsg 0:662207e34fba 173 // CONFIG register
garfieldsg 0:662207e34fba 174
garfieldsg 0:662207e34fba 175 /** Get external FSYNC configuration.
garfieldsg 0:662207e34fba 176 * Configures the external Frame Synchronization (FSYNC) pin sampling. An
garfieldsg 0:662207e34fba 177 * external signal connected to the FSYNC pin can be sampled by configuring
garfieldsg 0:662207e34fba 178 * EXT_SYNC_SET. Signal changes to the FSYNC pin are latched so that short
garfieldsg 0:662207e34fba 179 * strobes may be captured. The latched FSYNC signal will be sampled at the
garfieldsg 0:662207e34fba 180 * Sampling Rate, as defined in register 25. After sampling, the latch will
garfieldsg 0:662207e34fba 181 * reset to the current FSYNC signal state.
garfieldsg 0:662207e34fba 182 *
garfieldsg 0:662207e34fba 183 * The sampled value will be reported in place of the least significant bit in
garfieldsg 0:662207e34fba 184 * a sensor data register determined by the value of EXT_SYNC_SET according to
garfieldsg 0:662207e34fba 185 * the following table.
garfieldsg 0:662207e34fba 186 *
garfieldsg 0:662207e34fba 187 * <pre>
garfieldsg 0:662207e34fba 188 * EXT_SYNC_SET | FSYNC Bit Location
garfieldsg 0:662207e34fba 189 * -------------+-------------------
garfieldsg 0:662207e34fba 190 * 0 | Input disabled
garfieldsg 0:662207e34fba 191 * 1 | TEMP_OUT_L[0]
garfieldsg 0:662207e34fba 192 * 2 | GYRO_XOUT_L[0]
garfieldsg 0:662207e34fba 193 * 3 | GYRO_YOUT_L[0]
garfieldsg 0:662207e34fba 194 * 4 | GYRO_ZOUT_L[0]
garfieldsg 0:662207e34fba 195 * 5 | ACCEL_XOUT_L[0]
garfieldsg 0:662207e34fba 196 * 6 | ACCEL_YOUT_L[0]
garfieldsg 0:662207e34fba 197 * 7 | ACCEL_ZOUT_L[0]
garfieldsg 0:662207e34fba 198 * </pre>
garfieldsg 0:662207e34fba 199 *
garfieldsg 0:662207e34fba 200 * @return FSYNC configuration value
garfieldsg 0:662207e34fba 201 */
garfieldsg 0:662207e34fba 202 uint8_t MPU6050::getExternalFrameSync()
garfieldsg 0:662207e34fba 203 {
garfieldsg 0:662207e34fba 204 i2Cdev.readBits(devAddr, MPU6050_RA_CONFIG, MPU6050_CFG_EXT_SYNC_SET_BIT, MPU6050_CFG_EXT_SYNC_SET_LENGTH, buffer);
garfieldsg 0:662207e34fba 205 return buffer[0];
garfieldsg 0:662207e34fba 206 }
garfieldsg 0:662207e34fba 207 /** Set external FSYNC configuration.
garfieldsg 0:662207e34fba 208 * @see getExternalFrameSync()
garfieldsg 0:662207e34fba 209 * @see MPU6050_RA_CONFIG
garfieldsg 0:662207e34fba 210 * @param sync New FSYNC configuration value
garfieldsg 0:662207e34fba 211 */
garfieldsg 0:662207e34fba 212 void MPU6050::setExternalFrameSync(uint8_t sync)
garfieldsg 0:662207e34fba 213 {
garfieldsg 0:662207e34fba 214 i2Cdev.writeBits(devAddr, MPU6050_RA_CONFIG, MPU6050_CFG_EXT_SYNC_SET_BIT, MPU6050_CFG_EXT_SYNC_SET_LENGTH, sync);
garfieldsg 0:662207e34fba 215 }
garfieldsg 0:662207e34fba 216 /** Get digital low-pass filter configuration.
garfieldsg 0:662207e34fba 217 * The DLPF_CFG parameter sets the digital low pass filter configuration. It
garfieldsg 0:662207e34fba 218 * also determines the internal sampling rate used by the device as shown in
garfieldsg 0:662207e34fba 219 * the table below.
garfieldsg 0:662207e34fba 220 *
garfieldsg 0:662207e34fba 221 * Note: The accelerometer output rate is 1kHz. This means that for a Sample
garfieldsg 0:662207e34fba 222 * Rate greater than 1kHz, the same accelerometer sample may be output to the
garfieldsg 0:662207e34fba 223 * FIFO, DMP, and sensor registers more than once.
garfieldsg 0:662207e34fba 224 *
garfieldsg 0:662207e34fba 225 * <pre>
garfieldsg 0:662207e34fba 226 * | ACCELEROMETER | GYROSCOPE
garfieldsg 0:662207e34fba 227 * DLPF_CFG | Bandwidth | Delay | Bandwidth | Delay | Sample Rate
garfieldsg 0:662207e34fba 228 * ---------+-----------+--------+-----------+--------+-------------
garfieldsg 0:662207e34fba 229 * 0 | 260Hz | 0ms | 256Hz | 0.98ms | 8kHz
garfieldsg 0:662207e34fba 230 * 1 | 184Hz | 2.0ms | 188Hz | 1.9ms | 1kHz
garfieldsg 0:662207e34fba 231 * 2 | 94Hz | 3.0ms | 98Hz | 2.8ms | 1kHz
garfieldsg 0:662207e34fba 232 * 3 | 44Hz | 4.9ms | 42Hz | 4.8ms | 1kHz
garfieldsg 0:662207e34fba 233 * 4 | 21Hz | 8.5ms | 20Hz | 8.3ms | 1kHz
garfieldsg 0:662207e34fba 234 * 5 | 10Hz | 13.8ms | 10Hz | 13.4ms | 1kHz
garfieldsg 0:662207e34fba 235 * 6 | 5Hz | 19.0ms | 5Hz | 18.6ms | 1kHz
garfieldsg 0:662207e34fba 236 * 7 | -- Reserved -- | -- Reserved -- | Reserved
garfieldsg 0:662207e34fba 237 * </pre>
garfieldsg 0:662207e34fba 238 *
garfieldsg 0:662207e34fba 239 * @return DLFP configuration
garfieldsg 0:662207e34fba 240 * @see MPU6050_RA_CONFIG
garfieldsg 0:662207e34fba 241 * @see MPU6050_CFG_DLPF_CFG_BIT
garfieldsg 0:662207e34fba 242 * @see MPU6050_CFG_DLPF_CFG_LENGTH
garfieldsg 0:662207e34fba 243 */
garfieldsg 0:662207e34fba 244 uint8_t MPU6050::getDLPFMode()
garfieldsg 0:662207e34fba 245 {
garfieldsg 0:662207e34fba 246 i2Cdev.readBits(devAddr, MPU6050_RA_CONFIG, MPU6050_CFG_DLPF_CFG_BIT, MPU6050_CFG_DLPF_CFG_LENGTH, buffer);
garfieldsg 0:662207e34fba 247 return buffer[0];
garfieldsg 0:662207e34fba 248 }
garfieldsg 0:662207e34fba 249 /** Set digital low-pass filter configuration.
garfieldsg 0:662207e34fba 250 * @param mode New DLFP configuration setting
garfieldsg 0:662207e34fba 251 * @see getDLPFBandwidth()
garfieldsg 0:662207e34fba 252 * @see MPU6050_DLPF_BW_256
garfieldsg 0:662207e34fba 253 * @see MPU6050_RA_CONFIG
garfieldsg 0:662207e34fba 254 * @see MPU6050_CFG_DLPF_CFG_BIT
garfieldsg 0:662207e34fba 255 * @see MPU6050_CFG_DLPF_CFG_LENGTH
garfieldsg 0:662207e34fba 256 */
garfieldsg 0:662207e34fba 257 void MPU6050::setDLPFMode(uint8_t mode)
garfieldsg 0:662207e34fba 258 {
garfieldsg 0:662207e34fba 259 i2Cdev.writeBits(devAddr, MPU6050_RA_CONFIG, MPU6050_CFG_DLPF_CFG_BIT, MPU6050_CFG_DLPF_CFG_LENGTH, mode);
garfieldsg 0:662207e34fba 260 }
garfieldsg 0:662207e34fba 261
garfieldsg 0:662207e34fba 262 // GYRO_CONFIG register
garfieldsg 0:662207e34fba 263
garfieldsg 0:662207e34fba 264 /** Get full-scale gyroscope range.
garfieldsg 0:662207e34fba 265 * The FS_SEL parameter allows setting the full-scale range of the gyro sensors,
garfieldsg 0:662207e34fba 266 * as described in the table below.
garfieldsg 0:662207e34fba 267 *
garfieldsg 0:662207e34fba 268 * <pre>
garfieldsg 0:662207e34fba 269 * 0 = +/- 250 degrees/sec
garfieldsg 0:662207e34fba 270 * 1 = +/- 500 degrees/sec
garfieldsg 0:662207e34fba 271 * 2 = +/- 1000 degrees/sec
garfieldsg 0:662207e34fba 272 * 3 = +/- 2000 degrees/sec
garfieldsg 0:662207e34fba 273 * </pre>
garfieldsg 0:662207e34fba 274 *
garfieldsg 0:662207e34fba 275 * @return Current full-scale gyroscope range setting
garfieldsg 0:662207e34fba 276 * @see MPU6050_GYRO_FS_250
garfieldsg 0:662207e34fba 277 * @see MPU6050_RA_GYRO_CONFIG
garfieldsg 0:662207e34fba 278 * @see MPU6050_GCONFIG_FS_SEL_BIT
garfieldsg 0:662207e34fba 279 * @see MPU6050_GCONFIG_FS_SEL_LENGTH
garfieldsg 0:662207e34fba 280 */
garfieldsg 0:662207e34fba 281 uint8_t MPU6050::getFullScaleGyroRange()
garfieldsg 0:662207e34fba 282 {
garfieldsg 0:662207e34fba 283 i2Cdev.readBits(devAddr, MPU6050_RA_GYRO_CONFIG, MPU6050_GCONFIG_FS_SEL_BIT, MPU6050_GCONFIG_FS_SEL_LENGTH, buffer);
garfieldsg 0:662207e34fba 284 return buffer[0];
garfieldsg 0:662207e34fba 285 }
garfieldsg 0:662207e34fba 286 /** Set full-scale gyroscope range.
garfieldsg 0:662207e34fba 287 * @param range New full-scale gyroscope range value
garfieldsg 0:662207e34fba 288 * @see getFullScaleRange()
garfieldsg 0:662207e34fba 289 * @see MPU6050_GYRO_FS_250
garfieldsg 0:662207e34fba 290 * @see MPU6050_RA_GYRO_CONFIG
garfieldsg 0:662207e34fba 291 * @see MPU6050_GCONFIG_FS_SEL_BIT
garfieldsg 0:662207e34fba 292 * @see MPU6050_GCONFIG_FS_SEL_LENGTH
garfieldsg 0:662207e34fba 293 */
garfieldsg 0:662207e34fba 294 void MPU6050::setFullScaleGyroRange(uint8_t range)
garfieldsg 0:662207e34fba 295 {
garfieldsg 0:662207e34fba 296 i2Cdev.writeBits(devAddr, MPU6050_RA_GYRO_CONFIG, MPU6050_GCONFIG_FS_SEL_BIT, MPU6050_GCONFIG_FS_SEL_LENGTH, range);
garfieldsg 0:662207e34fba 297 }
garfieldsg 0:662207e34fba 298
garfieldsg 0:662207e34fba 299 // ACCEL_CONFIG register
garfieldsg 0:662207e34fba 300
garfieldsg 0:662207e34fba 301 /** Get self-test enabled setting for accelerometer X axis.
garfieldsg 0:662207e34fba 302 * @return Self-test enabled value
garfieldsg 0:662207e34fba 303 * @see MPU6050_RA_ACCEL_CONFIG
garfieldsg 0:662207e34fba 304 */
garfieldsg 0:662207e34fba 305 bool MPU6050::getAccelXSelfTest()
garfieldsg 0:662207e34fba 306 {
garfieldsg 0:662207e34fba 307 i2Cdev.readBit(devAddr, MPU6050_RA_ACCEL_CONFIG, MPU6050_ACONFIG_XA_ST_BIT, buffer);
garfieldsg 0:662207e34fba 308 return buffer[0];
garfieldsg 0:662207e34fba 309 }
garfieldsg 0:662207e34fba 310 /** Get self-test enabled setting for accelerometer X axis.
garfieldsg 0:662207e34fba 311 * @param enabled Self-test enabled value
garfieldsg 0:662207e34fba 312 * @see MPU6050_RA_ACCEL_CONFIG
garfieldsg 0:662207e34fba 313 */
garfieldsg 0:662207e34fba 314 void MPU6050::setAccelXSelfTest(bool enabled)
garfieldsg 0:662207e34fba 315 {
garfieldsg 0:662207e34fba 316 i2Cdev.writeBit(devAddr, MPU6050_RA_ACCEL_CONFIG, MPU6050_ACONFIG_XA_ST_BIT, enabled);
garfieldsg 0:662207e34fba 317 }
garfieldsg 0:662207e34fba 318 /** Get self-test enabled value for accelerometer Y axis.
garfieldsg 0:662207e34fba 319 * @return Self-test enabled value
garfieldsg 0:662207e34fba 320 * @see MPU6050_RA_ACCEL_CONFIG
garfieldsg 0:662207e34fba 321 */
garfieldsg 0:662207e34fba 322 bool MPU6050::getAccelYSelfTest()
garfieldsg 0:662207e34fba 323 {
garfieldsg 0:662207e34fba 324 i2Cdev.readBit(devAddr, MPU6050_RA_ACCEL_CONFIG, MPU6050_ACONFIG_YA_ST_BIT, buffer);
garfieldsg 0:662207e34fba 325 return buffer[0];
garfieldsg 0:662207e34fba 326 }
garfieldsg 0:662207e34fba 327 /** Get self-test enabled value for accelerometer Y axis.
garfieldsg 0:662207e34fba 328 * @param enabled Self-test enabled value
garfieldsg 0:662207e34fba 329 * @see MPU6050_RA_ACCEL_CONFIG
garfieldsg 0:662207e34fba 330 */
garfieldsg 0:662207e34fba 331 void MPU6050::setAccelYSelfTest(bool enabled)
garfieldsg 0:662207e34fba 332 {
garfieldsg 0:662207e34fba 333 i2Cdev.writeBit(devAddr, MPU6050_RA_ACCEL_CONFIG, MPU6050_ACONFIG_YA_ST_BIT, enabled);
garfieldsg 0:662207e34fba 334 }
garfieldsg 0:662207e34fba 335 /** Get self-test enabled value for accelerometer Z axis.
garfieldsg 0:662207e34fba 336 * @return Self-test enabled value
garfieldsg 0:662207e34fba 337 * @see MPU6050_RA_ACCEL_CONFIG
garfieldsg 0:662207e34fba 338 */
garfieldsg 0:662207e34fba 339 bool MPU6050::getAccelZSelfTest()
garfieldsg 0:662207e34fba 340 {
garfieldsg 0:662207e34fba 341 i2Cdev.readBit(devAddr, MPU6050_RA_ACCEL_CONFIG, MPU6050_ACONFIG_ZA_ST_BIT, buffer);
garfieldsg 0:662207e34fba 342 return buffer[0];
garfieldsg 0:662207e34fba 343 }
garfieldsg 0:662207e34fba 344 /** Set self-test enabled value for accelerometer Z axis.
garfieldsg 0:662207e34fba 345 * @param enabled Self-test enabled value
garfieldsg 0:662207e34fba 346 * @see MPU6050_RA_ACCEL_CONFIG
garfieldsg 0:662207e34fba 347 */
garfieldsg 0:662207e34fba 348 void MPU6050::setAccelZSelfTest(bool enabled)
garfieldsg 0:662207e34fba 349 {
garfieldsg 0:662207e34fba 350 i2Cdev.writeBit(devAddr, MPU6050_RA_ACCEL_CONFIG, MPU6050_ACONFIG_ZA_ST_BIT, enabled);
garfieldsg 0:662207e34fba 351 }
garfieldsg 0:662207e34fba 352 /** Get full-scale accelerometer range.
garfieldsg 0:662207e34fba 353 * The FS_SEL parameter allows setting the full-scale range of the accelerometer
garfieldsg 0:662207e34fba 354 * sensors, as described in the table below.
garfieldsg 0:662207e34fba 355 *
garfieldsg 0:662207e34fba 356 * <pre>
garfieldsg 0:662207e34fba 357 * 0 = +/- 2g
garfieldsg 0:662207e34fba 358 * 1 = +/- 4g
garfieldsg 0:662207e34fba 359 * 2 = +/- 8g
garfieldsg 0:662207e34fba 360 * 3 = +/- 16g
garfieldsg 0:662207e34fba 361 * </pre>
garfieldsg 0:662207e34fba 362 *
garfieldsg 0:662207e34fba 363 * @return Current full-scale accelerometer range setting
garfieldsg 0:662207e34fba 364 * @see MPU6050_ACCEL_FS_2
garfieldsg 0:662207e34fba 365 * @see MPU6050_RA_ACCEL_CONFIG
garfieldsg 0:662207e34fba 366 * @see MPU6050_ACONFIG_AFS_SEL_BIT
garfieldsg 0:662207e34fba 367 * @see MPU6050_ACONFIG_AFS_SEL_LENGTH
garfieldsg 0:662207e34fba 368 */
garfieldsg 0:662207e34fba 369 uint8_t MPU6050::getFullScaleAccelRange()
garfieldsg 0:662207e34fba 370 {
garfieldsg 0:662207e34fba 371 i2Cdev.readBits(devAddr, MPU6050_RA_ACCEL_CONFIG, MPU6050_ACONFIG_AFS_SEL_BIT, MPU6050_ACONFIG_AFS_SEL_LENGTH, buffer);
garfieldsg 0:662207e34fba 372 return buffer[0];
garfieldsg 0:662207e34fba 373 }
garfieldsg 0:662207e34fba 374 /** Set full-scale accelerometer range.
garfieldsg 0:662207e34fba 375 * @param range New full-scale accelerometer range setting
garfieldsg 0:662207e34fba 376 * @see getFullScaleAccelRange()
garfieldsg 0:662207e34fba 377 */
garfieldsg 0:662207e34fba 378 void MPU6050::setFullScaleAccelRange(uint8_t range)
garfieldsg 0:662207e34fba 379 {
garfieldsg 0:662207e34fba 380 i2Cdev.writeBits(devAddr, MPU6050_RA_ACCEL_CONFIG, MPU6050_ACONFIG_AFS_SEL_BIT, MPU6050_ACONFIG_AFS_SEL_LENGTH, range);
garfieldsg 0:662207e34fba 381 }
garfieldsg 0:662207e34fba 382 /** Get the high-pass filter configuration.
garfieldsg 0:662207e34fba 383 * The DHPF is a filter module in the path leading to motion detectors (Free
garfieldsg 0:662207e34fba 384 * Fall, Motion threshold, and Zero Motion). The high pass filter output is not
garfieldsg 0:662207e34fba 385 * available to the data registers (see Figure in Section 8 of the MPU-6000/
garfieldsg 0:662207e34fba 386 * MPU-6050 Product Specification document).
garfieldsg 0:662207e34fba 387 *
garfieldsg 0:662207e34fba 388 * The high pass filter has three modes:
garfieldsg 0:662207e34fba 389 *
garfieldsg 0:662207e34fba 390 * <pre>
garfieldsg 0:662207e34fba 391 * Reset: The filter output settles to zero within one sample. This
garfieldsg 0:662207e34fba 392 * effectively disables the high pass filter. This mode may be toggled
garfieldsg 0:662207e34fba 393 * to quickly settle the filter.
garfieldsg 0:662207e34fba 394 *
garfieldsg 0:662207e34fba 395 * On: The high pass filter will pass signals above the cut off frequency.
garfieldsg 0:662207e34fba 396 *
garfieldsg 0:662207e34fba 397 * Hold: When triggered, the filter holds the present sample. The filter
garfieldsg 0:662207e34fba 398 * output will be the difference between the input sample and the held
garfieldsg 0:662207e34fba 399 * sample.
garfieldsg 0:662207e34fba 400 * </pre>
garfieldsg 0:662207e34fba 401 *
garfieldsg 0:662207e34fba 402 * <pre>
garfieldsg 0:662207e34fba 403 * ACCEL_HPF | Filter Mode | Cut-off Frequency
garfieldsg 0:662207e34fba 404 * ----------+-------------+------------------
garfieldsg 0:662207e34fba 405 * 0 | Reset | None
garfieldsg 0:662207e34fba 406 * 1 | On | 5Hz
garfieldsg 0:662207e34fba 407 * 2 | On | 2.5Hz
garfieldsg 0:662207e34fba 408 * 3 | On | 1.25Hz
garfieldsg 0:662207e34fba 409 * 4 | On | 0.63Hz
garfieldsg 0:662207e34fba 410 * 7 | Hold | None
garfieldsg 0:662207e34fba 411 * </pre>
garfieldsg 0:662207e34fba 412 *
garfieldsg 0:662207e34fba 413 * @return Current high-pass filter configuration
garfieldsg 0:662207e34fba 414 * @see MPU6050_DHPF_RESET
garfieldsg 0:662207e34fba 415 * @see MPU6050_RA_ACCEL_CONFIG
garfieldsg 0:662207e34fba 416 */
garfieldsg 0:662207e34fba 417 uint8_t MPU6050::getDHPFMode()
garfieldsg 0:662207e34fba 418 {
garfieldsg 0:662207e34fba 419 i2Cdev.readBits(devAddr, MPU6050_RA_ACCEL_CONFIG, MPU6050_ACONFIG_ACCEL_HPF_BIT, MPU6050_ACONFIG_ACCEL_HPF_LENGTH, buffer);
garfieldsg 0:662207e34fba 420 return buffer[0];
garfieldsg 0:662207e34fba 421 }
garfieldsg 0:662207e34fba 422 /** Set the high-pass filter configuration.
garfieldsg 0:662207e34fba 423 * @param bandwidth New high-pass filter configuration
garfieldsg 0:662207e34fba 424 * @see setDHPFMode()
garfieldsg 0:662207e34fba 425 * @see MPU6050_DHPF_RESET
garfieldsg 0:662207e34fba 426 * @see MPU6050_RA_ACCEL_CONFIG
garfieldsg 0:662207e34fba 427 */
garfieldsg 0:662207e34fba 428 void MPU6050::setDHPFMode(uint8_t bandwidth)
garfieldsg 0:662207e34fba 429 {
garfieldsg 0:662207e34fba 430 i2Cdev.writeBits(devAddr, MPU6050_RA_ACCEL_CONFIG, MPU6050_ACONFIG_ACCEL_HPF_BIT, MPU6050_ACONFIG_ACCEL_HPF_LENGTH, bandwidth);
garfieldsg 0:662207e34fba 431 }
garfieldsg 0:662207e34fba 432
garfieldsg 0:662207e34fba 433 // FF_THR register
garfieldsg 0:662207e34fba 434
garfieldsg 0:662207e34fba 435 /** Get free-fall event acceleration threshold.
garfieldsg 0:662207e34fba 436 * This register configures the detection threshold for Free Fall event
garfieldsg 0:662207e34fba 437 * detection. The unit of FF_THR is 1LSB = 2mg. Free Fall is detected when the
garfieldsg 0:662207e34fba 438 * absolute value of the accelerometer measurements for the three axes are each
garfieldsg 0:662207e34fba 439 * less than the detection threshold. This condition increments the Free Fall
garfieldsg 0:662207e34fba 440 * duration counter (Register 30). The Free Fall interrupt is triggered when the
garfieldsg 0:662207e34fba 441 * Free Fall duration counter reaches the time specified in FF_DUR.
garfieldsg 0:662207e34fba 442 *
garfieldsg 0:662207e34fba 443 * For more details on the Free Fall detection interrupt, see Section 8.2 of the
garfieldsg 0:662207e34fba 444 * MPU-6000/MPU-6050 Product Specification document as well as Registers 56 and
garfieldsg 0:662207e34fba 445 * 58 of this document.
garfieldsg 0:662207e34fba 446 *
garfieldsg 0:662207e34fba 447 * @return Current free-fall acceleration threshold value (LSB = 2mg)
garfieldsg 0:662207e34fba 448 * @see MPU6050_RA_FF_THR
garfieldsg 0:662207e34fba 449 */
garfieldsg 0:662207e34fba 450 uint8_t MPU6050::getFreefallDetectionThreshold()
garfieldsg 0:662207e34fba 451 {
garfieldsg 0:662207e34fba 452 i2Cdev.readByte(devAddr, MPU6050_RA_FF_THR, buffer);
garfieldsg 0:662207e34fba 453 return buffer[0];
garfieldsg 0:662207e34fba 454 }
garfieldsg 0:662207e34fba 455 /** Get free-fall event acceleration threshold.
garfieldsg 0:662207e34fba 456 * @param threshold New free-fall acceleration threshold value (LSB = 2mg)
garfieldsg 0:662207e34fba 457 * @see getFreefallDetectionThreshold()
garfieldsg 0:662207e34fba 458 * @see MPU6050_RA_FF_THR
garfieldsg 0:662207e34fba 459 */
garfieldsg 0:662207e34fba 460 void MPU6050::setFreefallDetectionThreshold(uint8_t threshold)
garfieldsg 0:662207e34fba 461 {
garfieldsg 0:662207e34fba 462 i2Cdev.writeByte(devAddr, MPU6050_RA_FF_THR, threshold);
garfieldsg 0:662207e34fba 463 }
garfieldsg 0:662207e34fba 464
garfieldsg 0:662207e34fba 465 // FF_DUR register
garfieldsg 0:662207e34fba 466
garfieldsg 0:662207e34fba 467 /** Get free-fall event duration threshold.
garfieldsg 0:662207e34fba 468 * This register configures the duration counter threshold for Free Fall event
garfieldsg 0:662207e34fba 469 * detection. The duration counter ticks at 1kHz, therefore FF_DUR has a unit
garfieldsg 0:662207e34fba 470 * of 1 LSB = 1 ms.
garfieldsg 0:662207e34fba 471 *
garfieldsg 0:662207e34fba 472 * The Free Fall duration counter increments while the absolute value of the
garfieldsg 0:662207e34fba 473 * accelerometer measurements are each less than the detection threshold
garfieldsg 0:662207e34fba 474 * (Register 29). The Free Fall interrupt is triggered when the Free Fall
garfieldsg 0:662207e34fba 475 * duration counter reaches the time specified in this register.
garfieldsg 0:662207e34fba 476 *
garfieldsg 0:662207e34fba 477 * For more details on the Free Fall detection interrupt, see Section 8.2 of
garfieldsg 0:662207e34fba 478 * the MPU-6000/MPU-6050 Product Specification document as well as Registers 56
garfieldsg 0:662207e34fba 479 * and 58 of this document.
garfieldsg 0:662207e34fba 480 *
garfieldsg 0:662207e34fba 481 * @return Current free-fall duration threshold value (LSB = 1ms)
garfieldsg 0:662207e34fba 482 * @see MPU6050_RA_FF_DUR
garfieldsg 0:662207e34fba 483 */
garfieldsg 0:662207e34fba 484 uint8_t MPU6050::getFreefallDetectionDuration()
garfieldsg 0:662207e34fba 485 {
garfieldsg 0:662207e34fba 486 i2Cdev.readByte(devAddr, MPU6050_RA_FF_DUR, buffer);
garfieldsg 0:662207e34fba 487 return buffer[0];
garfieldsg 0:662207e34fba 488 }
garfieldsg 0:662207e34fba 489 /** Get free-fall event duration threshold.
garfieldsg 0:662207e34fba 490 * @param duration New free-fall duration threshold value (LSB = 1ms)
garfieldsg 0:662207e34fba 491 * @see getFreefallDetectionDuration()
garfieldsg 0:662207e34fba 492 * @see MPU6050_RA_FF_DUR
garfieldsg 0:662207e34fba 493 */
garfieldsg 0:662207e34fba 494 void MPU6050::setFreefallDetectionDuration(uint8_t duration)
garfieldsg 0:662207e34fba 495 {
garfieldsg 0:662207e34fba 496 i2Cdev.writeByte(devAddr, MPU6050_RA_FF_DUR, duration);
garfieldsg 0:662207e34fba 497 }
garfieldsg 0:662207e34fba 498
garfieldsg 0:662207e34fba 499 // MOT_THR register
garfieldsg 0:662207e34fba 500
garfieldsg 0:662207e34fba 501 /** Get motion detection event acceleration threshold.
garfieldsg 0:662207e34fba 502 * This register configures the detection threshold for Motion interrupt
garfieldsg 0:662207e34fba 503 * generation. The unit of MOT_THR is 1LSB = 2mg. Motion is detected when the
garfieldsg 0:662207e34fba 504 * absolute value of any of the accelerometer measurements exceeds this Motion
garfieldsg 0:662207e34fba 505 * detection threshold. This condition increments the Motion detection duration
garfieldsg 0:662207e34fba 506 * counter (Register 32). The Motion detection interrupt is triggered when the
garfieldsg 0:662207e34fba 507 * Motion Detection counter reaches the time count specified in MOT_DUR
garfieldsg 0:662207e34fba 508 * (Register 32).
garfieldsg 0:662207e34fba 509 *
garfieldsg 0:662207e34fba 510 * The Motion interrupt will indicate the axis and polarity of detected motion
garfieldsg 0:662207e34fba 511 * in MOT_DETECT_STATUS (Register 97).
garfieldsg 0:662207e34fba 512 *
garfieldsg 0:662207e34fba 513 * For more details on the Motion detection interrupt, see Section 8.3 of the
garfieldsg 0:662207e34fba 514 * MPU-6000/MPU-6050 Product Specification document as well as Registers 56 and
garfieldsg 0:662207e34fba 515 * 58 of this document.
garfieldsg 0:662207e34fba 516 *
garfieldsg 0:662207e34fba 517 * @return Current motion detection acceleration threshold value (LSB = 2mg)
garfieldsg 0:662207e34fba 518 * @see MPU6050_RA_MOT_THR
garfieldsg 0:662207e34fba 519 */
garfieldsg 0:662207e34fba 520 uint8_t MPU6050::getMotionDetectionThreshold()
garfieldsg 0:662207e34fba 521 {
garfieldsg 0:662207e34fba 522 i2Cdev.readByte(devAddr, MPU6050_RA_MOT_THR, buffer);
garfieldsg 0:662207e34fba 523 return buffer[0];
garfieldsg 0:662207e34fba 524 }
garfieldsg 0:662207e34fba 525 /** Set free-fall event acceleration threshold.
garfieldsg 0:662207e34fba 526 * @param threshold New motion detection acceleration threshold value (LSB = 2mg)
garfieldsg 0:662207e34fba 527 * @see getMotionDetectionThreshold()
garfieldsg 0:662207e34fba 528 * @see MPU6050_RA_MOT_THR
garfieldsg 0:662207e34fba 529 */
garfieldsg 0:662207e34fba 530 void MPU6050::setMotionDetectionThreshold(uint8_t threshold)
garfieldsg 0:662207e34fba 531 {
garfieldsg 0:662207e34fba 532 i2Cdev.writeByte(devAddr, MPU6050_RA_MOT_THR, threshold);
garfieldsg 0:662207e34fba 533 }
garfieldsg 0:662207e34fba 534
garfieldsg 0:662207e34fba 535 // MOT_DUR register
garfieldsg 0:662207e34fba 536
garfieldsg 0:662207e34fba 537 /** Get motion detection event duration threshold.
garfieldsg 0:662207e34fba 538 * This register configures the duration counter threshold for Motion interrupt
garfieldsg 0:662207e34fba 539 * generation. The duration counter ticks at 1 kHz, therefore MOT_DUR has a unit
garfieldsg 0:662207e34fba 540 * of 1LSB = 1ms. The Motion detection duration counter increments when the
garfieldsg 0:662207e34fba 541 * absolute value of any of the accelerometer measurements exceeds the Motion
garfieldsg 0:662207e34fba 542 * detection threshold (Register 31). The Motion detection interrupt is
garfieldsg 0:662207e34fba 543 * triggered when the Motion detection counter reaches the time count specified
garfieldsg 0:662207e34fba 544 * in this register.
garfieldsg 0:662207e34fba 545 *
garfieldsg 0:662207e34fba 546 * For more details on the Motion detection interrupt, see Section 8.3 of the
garfieldsg 0:662207e34fba 547 * MPU-6000/MPU-6050 Product Specification document.
garfieldsg 0:662207e34fba 548 *
garfieldsg 0:662207e34fba 549 * @return Current motion detection duration threshold value (LSB = 1ms)
garfieldsg 0:662207e34fba 550 * @see MPU6050_RA_MOT_DUR
garfieldsg 0:662207e34fba 551 */
garfieldsg 0:662207e34fba 552 uint8_t MPU6050::getMotionDetectionDuration()
garfieldsg 0:662207e34fba 553 {
garfieldsg 0:662207e34fba 554 i2Cdev.readByte(devAddr, MPU6050_RA_MOT_DUR, buffer);
garfieldsg 0:662207e34fba 555 return buffer[0];
garfieldsg 0:662207e34fba 556 }
garfieldsg 0:662207e34fba 557 /** Set motion detection event duration threshold.
garfieldsg 0:662207e34fba 558 * @param duration New motion detection duration threshold value (LSB = 1ms)
garfieldsg 0:662207e34fba 559 * @see getMotionDetectionDuration()
garfieldsg 0:662207e34fba 560 * @see MPU6050_RA_MOT_DUR
garfieldsg 0:662207e34fba 561 */
garfieldsg 0:662207e34fba 562 void MPU6050::setMotionDetectionDuration(uint8_t duration)
garfieldsg 0:662207e34fba 563 {
garfieldsg 0:662207e34fba 564 i2Cdev.writeByte(devAddr, MPU6050_RA_MOT_DUR, duration);
garfieldsg 0:662207e34fba 565 }
garfieldsg 0:662207e34fba 566
garfieldsg 0:662207e34fba 567 // ZRMOT_THR register
garfieldsg 0:662207e34fba 568
garfieldsg 0:662207e34fba 569 /** Get zero motion detection event acceleration threshold.
garfieldsg 0:662207e34fba 570 * This register configures the detection threshold for Zero Motion interrupt
garfieldsg 0:662207e34fba 571 * generation. The unit of ZRMOT_THR is 1LSB = 2mg. Zero Motion is detected when
garfieldsg 0:662207e34fba 572 * the absolute value of the accelerometer measurements for the 3 axes are each
garfieldsg 0:662207e34fba 573 * less than the detection threshold. This condition increments the Zero Motion
garfieldsg 0:662207e34fba 574 * duration counter (Register 34). The Zero Motion interrupt is triggered when
garfieldsg 0:662207e34fba 575 * the Zero Motion duration counter reaches the time count specified in
garfieldsg 0:662207e34fba 576 * ZRMOT_DUR (Register 34).
garfieldsg 0:662207e34fba 577 *
garfieldsg 0:662207e34fba 578 * Unlike Free Fall or Motion detection, Zero Motion detection triggers an
garfieldsg 0:662207e34fba 579 * interrupt both when Zero Motion is first detected and when Zero Motion is no
garfieldsg 0:662207e34fba 580 * longer detected.
garfieldsg 0:662207e34fba 581 *
garfieldsg 0:662207e34fba 582 * When a zero motion event is detected, a Zero Motion Status will be indicated
garfieldsg 0:662207e34fba 583 * in the MOT_DETECT_STATUS register (Register 97). When a motion-to-zero-motion
garfieldsg 0:662207e34fba 584 * condition is detected, the status bit is set to 1. When a zero-motion-to-
garfieldsg 0:662207e34fba 585 * motion condition is detected, the status bit is set to 0.
garfieldsg 0:662207e34fba 586 *
garfieldsg 0:662207e34fba 587 * For more details on the Zero Motion detection interrupt, see Section 8.4 of
garfieldsg 0:662207e34fba 588 * the MPU-6000/MPU-6050 Product Specification document as well as Registers 56
garfieldsg 0:662207e34fba 589 * and 58 of this document.
garfieldsg 0:662207e34fba 590 *
garfieldsg 0:662207e34fba 591 * @return Current zero motion detection acceleration threshold value (LSB = 2mg)
garfieldsg 0:662207e34fba 592 * @see MPU6050_RA_ZRMOT_THR
garfieldsg 0:662207e34fba 593 */
garfieldsg 0:662207e34fba 594 uint8_t MPU6050::getZeroMotionDetectionThreshold()
garfieldsg 0:662207e34fba 595 {
garfieldsg 0:662207e34fba 596 i2Cdev.readByte(devAddr, MPU6050_RA_ZRMOT_THR, buffer);
garfieldsg 0:662207e34fba 597 return buffer[0];
garfieldsg 0:662207e34fba 598 }
garfieldsg 0:662207e34fba 599 /** Set zero motion detection event acceleration threshold.
garfieldsg 0:662207e34fba 600 * @param threshold New zero motion detection acceleration threshold value (LSB = 2mg)
garfieldsg 0:662207e34fba 601 * @see getZeroMotionDetectionThreshold()
garfieldsg 0:662207e34fba 602 * @see MPU6050_RA_ZRMOT_THR
garfieldsg 0:662207e34fba 603 */
garfieldsg 0:662207e34fba 604 void MPU6050::setZeroMotionDetectionThreshold(uint8_t threshold)
garfieldsg 0:662207e34fba 605 {
garfieldsg 0:662207e34fba 606 i2Cdev.writeByte(devAddr, MPU6050_RA_ZRMOT_THR, threshold);
garfieldsg 0:662207e34fba 607 }
garfieldsg 0:662207e34fba 608
garfieldsg 0:662207e34fba 609 // ZRMOT_DUR register
garfieldsg 0:662207e34fba 610
garfieldsg 0:662207e34fba 611 /** Get zero motion detection event duration threshold.
garfieldsg 0:662207e34fba 612 * This register configures the duration counter threshold for Zero Motion
garfieldsg 0:662207e34fba 613 * interrupt generation. The duration counter ticks at 16 Hz, therefore
garfieldsg 0:662207e34fba 614 * ZRMOT_DUR has a unit of 1 LSB = 64 ms. The Zero Motion duration counter
garfieldsg 0:662207e34fba 615 * increments while the absolute value of the accelerometer measurements are
garfieldsg 0:662207e34fba 616 * each less than the detection threshold (Register 33). The Zero Motion
garfieldsg 0:662207e34fba 617 * interrupt is triggered when the Zero Motion duration counter reaches the time
garfieldsg 0:662207e34fba 618 * count specified in this register.
garfieldsg 0:662207e34fba 619 *
garfieldsg 0:662207e34fba 620 * For more details on the Zero Motion detection interrupt, see Section 8.4 of
garfieldsg 0:662207e34fba 621 * the MPU-6000/MPU-6050 Product Specification document, as well as Registers 56
garfieldsg 0:662207e34fba 622 * and 58 of this document.
garfieldsg 0:662207e34fba 623 *
garfieldsg 0:662207e34fba 624 * @return Current zero motion detection duration threshold value (LSB = 64ms)
garfieldsg 0:662207e34fba 625 * @see MPU6050_RA_ZRMOT_DUR
garfieldsg 0:662207e34fba 626 */
garfieldsg 0:662207e34fba 627 uint8_t MPU6050::getZeroMotionDetectionDuration()
garfieldsg 0:662207e34fba 628 {
garfieldsg 0:662207e34fba 629 i2Cdev.readByte(devAddr, MPU6050_RA_ZRMOT_DUR, buffer);
garfieldsg 0:662207e34fba 630 return buffer[0];
garfieldsg 0:662207e34fba 631 }
garfieldsg 0:662207e34fba 632 /** Set zero motion detection event duration threshold.
garfieldsg 0:662207e34fba 633 * @param duration New zero motion detection duration threshold value (LSB = 1ms)
garfieldsg 0:662207e34fba 634 * @see getZeroMotionDetectionDuration()
garfieldsg 0:662207e34fba 635 * @see MPU6050_RA_ZRMOT_DUR
garfieldsg 0:662207e34fba 636 */
garfieldsg 0:662207e34fba 637 void MPU6050::setZeroMotionDetectionDuration(uint8_t duration)
garfieldsg 0:662207e34fba 638 {
garfieldsg 0:662207e34fba 639 i2Cdev.writeByte(devAddr, MPU6050_RA_ZRMOT_DUR, duration);
garfieldsg 0:662207e34fba 640 }
garfieldsg 0:662207e34fba 641
garfieldsg 0:662207e34fba 642 // FIFO_EN register
garfieldsg 0:662207e34fba 643
garfieldsg 0:662207e34fba 644 /** Get temperature FIFO enabled value.
garfieldsg 0:662207e34fba 645 * When set to 1, this bit enables TEMP_OUT_H and TEMP_OUT_L (Registers 65 and
garfieldsg 0:662207e34fba 646 * 66) to be written into the FIFO buffer.
garfieldsg 0:662207e34fba 647 * @return Current temperature FIFO enabled value
garfieldsg 0:662207e34fba 648 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 649 */
garfieldsg 0:662207e34fba 650 bool MPU6050::getTempFIFOEnabled()
garfieldsg 0:662207e34fba 651 {
garfieldsg 0:662207e34fba 652 i2Cdev.readBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_TEMP_FIFO_EN_BIT, buffer);
garfieldsg 0:662207e34fba 653 return buffer[0];
garfieldsg 0:662207e34fba 654 }
garfieldsg 0:662207e34fba 655 /** Set temperature FIFO enabled value.
garfieldsg 0:662207e34fba 656 * @param enabled New temperature FIFO enabled value
garfieldsg 0:662207e34fba 657 * @see getTempFIFOEnabled()
garfieldsg 0:662207e34fba 658 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 659 */
garfieldsg 0:662207e34fba 660 void MPU6050::setTempFIFOEnabled(bool enabled)
garfieldsg 0:662207e34fba 661 {
garfieldsg 0:662207e34fba 662 i2Cdev.writeBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_TEMP_FIFO_EN_BIT, enabled);
garfieldsg 0:662207e34fba 663 }
garfieldsg 0:662207e34fba 664 /** Get gyroscope X-axis FIFO enabled value.
garfieldsg 0:662207e34fba 665 * When set to 1, this bit enables GYRO_XOUT_H and GYRO_XOUT_L (Registers 67 and
garfieldsg 0:662207e34fba 666 * 68) to be written into the FIFO buffer.
garfieldsg 0:662207e34fba 667 * @return Current gyroscope X-axis FIFO enabled value
garfieldsg 0:662207e34fba 668 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 669 */
garfieldsg 0:662207e34fba 670 bool MPU6050::getXGyroFIFOEnabled()
garfieldsg 0:662207e34fba 671 {
garfieldsg 0:662207e34fba 672 i2Cdev.readBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_XG_FIFO_EN_BIT, buffer);
garfieldsg 0:662207e34fba 673 return buffer[0];
garfieldsg 0:662207e34fba 674 }
garfieldsg 0:662207e34fba 675 /** Set gyroscope X-axis FIFO enabled value.
garfieldsg 0:662207e34fba 676 * @param enabled New gyroscope X-axis FIFO enabled value
garfieldsg 0:662207e34fba 677 * @see getXGyroFIFOEnabled()
garfieldsg 0:662207e34fba 678 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 679 */
garfieldsg 0:662207e34fba 680 void MPU6050::setXGyroFIFOEnabled(bool enabled)
garfieldsg 0:662207e34fba 681 {
garfieldsg 0:662207e34fba 682 i2Cdev.writeBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_XG_FIFO_EN_BIT, enabled);
garfieldsg 0:662207e34fba 683 }
garfieldsg 0:662207e34fba 684 /** Get gyroscope Y-axis FIFO enabled value.
garfieldsg 0:662207e34fba 685 * When set to 1, this bit enables GYRO_YOUT_H and GYRO_YOUT_L (Registers 69 and
garfieldsg 0:662207e34fba 686 * 70) to be written into the FIFO buffer.
garfieldsg 0:662207e34fba 687 * @return Current gyroscope Y-axis FIFO enabled value
garfieldsg 0:662207e34fba 688 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 689 */
garfieldsg 0:662207e34fba 690 bool MPU6050::getYGyroFIFOEnabled()
garfieldsg 0:662207e34fba 691 {
garfieldsg 0:662207e34fba 692 i2Cdev.readBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_YG_FIFO_EN_BIT, buffer);
garfieldsg 0:662207e34fba 693 return buffer[0];
garfieldsg 0:662207e34fba 694 }
garfieldsg 0:662207e34fba 695 /** Set gyroscope Y-axis FIFO enabled value.
garfieldsg 0:662207e34fba 696 * @param enabled New gyroscope Y-axis FIFO enabled value
garfieldsg 0:662207e34fba 697 * @see getYGyroFIFOEnabled()
garfieldsg 0:662207e34fba 698 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 699 */
garfieldsg 0:662207e34fba 700 void MPU6050::setYGyroFIFOEnabled(bool enabled)
garfieldsg 0:662207e34fba 701 {
garfieldsg 0:662207e34fba 702 i2Cdev.writeBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_YG_FIFO_EN_BIT, enabled);
garfieldsg 0:662207e34fba 703 }
garfieldsg 0:662207e34fba 704 /** Get gyroscope Z-axis FIFO enabled value.
garfieldsg 0:662207e34fba 705 * When set to 1, this bit enables GYRO_ZOUT_H and GYRO_ZOUT_L (Registers 71 and
garfieldsg 0:662207e34fba 706 * 72) to be written into the FIFO buffer.
garfieldsg 0:662207e34fba 707 * @return Current gyroscope Z-axis FIFO enabled value
garfieldsg 0:662207e34fba 708 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 709 */
garfieldsg 0:662207e34fba 710 bool MPU6050::getZGyroFIFOEnabled()
garfieldsg 0:662207e34fba 711 {
garfieldsg 0:662207e34fba 712 i2Cdev.readBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_ZG_FIFO_EN_BIT, buffer);
garfieldsg 0:662207e34fba 713 return buffer[0];
garfieldsg 0:662207e34fba 714 }
garfieldsg 0:662207e34fba 715 /** Set gyroscope Z-axis FIFO enabled value.
garfieldsg 0:662207e34fba 716 * @param enabled New gyroscope Z-axis FIFO enabled value
garfieldsg 0:662207e34fba 717 * @see getZGyroFIFOEnabled()
garfieldsg 0:662207e34fba 718 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 719 */
garfieldsg 0:662207e34fba 720 void MPU6050::setZGyroFIFOEnabled(bool enabled)
garfieldsg 0:662207e34fba 721 {
garfieldsg 0:662207e34fba 722 i2Cdev.writeBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_ZG_FIFO_EN_BIT, enabled);
garfieldsg 0:662207e34fba 723 }
garfieldsg 0:662207e34fba 724 /** Get accelerometer FIFO enabled value.
garfieldsg 0:662207e34fba 725 * When set to 1, this bit enables ACCEL_XOUT_H, ACCEL_XOUT_L, ACCEL_YOUT_H,
garfieldsg 0:662207e34fba 726 * ACCEL_YOUT_L, ACCEL_ZOUT_H, and ACCEL_ZOUT_L (Registers 59 to 64) to be
garfieldsg 0:662207e34fba 727 * written into the FIFO buffer.
garfieldsg 0:662207e34fba 728 * @return Current accelerometer FIFO enabled value
garfieldsg 0:662207e34fba 729 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 730 */
garfieldsg 0:662207e34fba 731 bool MPU6050::getAccelFIFOEnabled()
garfieldsg 0:662207e34fba 732 {
garfieldsg 0:662207e34fba 733 i2Cdev.readBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_ACCEL_FIFO_EN_BIT, buffer);
garfieldsg 0:662207e34fba 734 return buffer[0];
garfieldsg 0:662207e34fba 735 }
garfieldsg 0:662207e34fba 736 /** Set accelerometer FIFO enabled value.
garfieldsg 0:662207e34fba 737 * @param enabled New accelerometer FIFO enabled value
garfieldsg 0:662207e34fba 738 * @see getAccelFIFOEnabled()
garfieldsg 0:662207e34fba 739 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 740 */
garfieldsg 0:662207e34fba 741 void MPU6050::setAccelFIFOEnabled(bool enabled)
garfieldsg 0:662207e34fba 742 {
garfieldsg 0:662207e34fba 743 i2Cdev.writeBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_ACCEL_FIFO_EN_BIT, enabled);
garfieldsg 0:662207e34fba 744 }
garfieldsg 0:662207e34fba 745 /** Get Slave 2 FIFO enabled value.
garfieldsg 0:662207e34fba 746 * When set to 1, this bit enables EXT_SENS_DATA registers (Registers 73 to 96)
garfieldsg 0:662207e34fba 747 * associated with Slave 2 to be written into the FIFO buffer.
garfieldsg 0:662207e34fba 748 * @return Current Slave 2 FIFO enabled value
garfieldsg 0:662207e34fba 749 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 750 */
garfieldsg 0:662207e34fba 751 bool MPU6050::getSlave2FIFOEnabled()
garfieldsg 0:662207e34fba 752 {
garfieldsg 0:662207e34fba 753 i2Cdev.readBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_SLV2_FIFO_EN_BIT, buffer);
garfieldsg 0:662207e34fba 754 return buffer[0];
garfieldsg 0:662207e34fba 755 }
garfieldsg 0:662207e34fba 756 /** Set Slave 2 FIFO enabled value.
garfieldsg 0:662207e34fba 757 * @param enabled New Slave 2 FIFO enabled value
garfieldsg 0:662207e34fba 758 * @see getSlave2FIFOEnabled()
garfieldsg 0:662207e34fba 759 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 760 */
garfieldsg 0:662207e34fba 761 void MPU6050::setSlave2FIFOEnabled(bool enabled)
garfieldsg 0:662207e34fba 762 {
garfieldsg 0:662207e34fba 763 i2Cdev.writeBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_SLV2_FIFO_EN_BIT, enabled);
garfieldsg 0:662207e34fba 764 }
garfieldsg 0:662207e34fba 765 /** Get Slave 1 FIFO enabled value.
garfieldsg 0:662207e34fba 766 * When set to 1, this bit enables EXT_SENS_DATA registers (Registers 73 to 96)
garfieldsg 0:662207e34fba 767 * associated with Slave 1 to be written into the FIFO buffer.
garfieldsg 0:662207e34fba 768 * @return Current Slave 1 FIFO enabled value
garfieldsg 0:662207e34fba 769 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 770 */
garfieldsg 0:662207e34fba 771 bool MPU6050::getSlave1FIFOEnabled()
garfieldsg 0:662207e34fba 772 {
garfieldsg 0:662207e34fba 773 i2Cdev.readBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_SLV1_FIFO_EN_BIT, buffer);
garfieldsg 0:662207e34fba 774 return buffer[0];
garfieldsg 0:662207e34fba 775 }
garfieldsg 0:662207e34fba 776 /** Set Slave 1 FIFO enabled value.
garfieldsg 0:662207e34fba 777 * @param enabled New Slave 1 FIFO enabled value
garfieldsg 0:662207e34fba 778 * @see getSlave1FIFOEnabled()
garfieldsg 0:662207e34fba 779 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 780 */
garfieldsg 0:662207e34fba 781 void MPU6050::setSlave1FIFOEnabled(bool enabled)
garfieldsg 0:662207e34fba 782 {
garfieldsg 0:662207e34fba 783 i2Cdev.writeBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_SLV1_FIFO_EN_BIT, enabled);
garfieldsg 0:662207e34fba 784 }
garfieldsg 0:662207e34fba 785 /** Get Slave 0 FIFO enabled value.
garfieldsg 0:662207e34fba 786 * When set to 1, this bit enables EXT_SENS_DATA registers (Registers 73 to 96)
garfieldsg 0:662207e34fba 787 * associated with Slave 0 to be written into the FIFO buffer.
garfieldsg 0:662207e34fba 788 * @return Current Slave 0 FIFO enabled value
garfieldsg 0:662207e34fba 789 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 790 */
garfieldsg 0:662207e34fba 791 bool MPU6050::getSlave0FIFOEnabled()
garfieldsg 0:662207e34fba 792 {
garfieldsg 0:662207e34fba 793 i2Cdev.readBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_SLV0_FIFO_EN_BIT, buffer);
garfieldsg 0:662207e34fba 794 return buffer[0];
garfieldsg 0:662207e34fba 795 }
garfieldsg 0:662207e34fba 796 /** Set Slave 0 FIFO enabled value.
garfieldsg 0:662207e34fba 797 * @param enabled New Slave 0 FIFO enabled value
garfieldsg 0:662207e34fba 798 * @see getSlave0FIFOEnabled()
garfieldsg 0:662207e34fba 799 * @see MPU6050_RA_FIFO_EN
garfieldsg 0:662207e34fba 800 */
garfieldsg 0:662207e34fba 801 void MPU6050::setSlave0FIFOEnabled(bool enabled)
garfieldsg 0:662207e34fba 802 {
garfieldsg 0:662207e34fba 803 i2Cdev.writeBit(devAddr, MPU6050_RA_FIFO_EN, MPU6050_SLV0_FIFO_EN_BIT, enabled);
garfieldsg 0:662207e34fba 804 }
garfieldsg 0:662207e34fba 805
garfieldsg 0:662207e34fba 806 // I2C_MST_CTRL register
garfieldsg 0:662207e34fba 807
garfieldsg 0:662207e34fba 808 /** Get multi-master enabled value.
garfieldsg 0:662207e34fba 809 * Multi-master capability allows multiple I2C masters to operate on the same
garfieldsg 0:662207e34fba 810 * bus. In circuits where multi-master capability is required, set MULT_MST_EN
garfieldsg 0:662207e34fba 811 * to 1. This will increase current drawn by approximately 30uA.
garfieldsg 0:662207e34fba 812 *
garfieldsg 0:662207e34fba 813 * In circuits where multi-master capability is required, the state of the I2C
garfieldsg 0:662207e34fba 814 * bus must always be monitored by each separate I2C Master. Before an I2C
garfieldsg 0:662207e34fba 815 * Master can assume arbitration of the bus, it must first confirm that no other
garfieldsg 0:662207e34fba 816 * I2C Master has arbitration of the bus. When MULT_MST_EN is set to 1, the
garfieldsg 0:662207e34fba 817 * MPU-60X0's bus arbitration detection logic is turned on, enabling it to
garfieldsg 0:662207e34fba 818 * detect when the bus is available.
garfieldsg 0:662207e34fba 819 *
garfieldsg 0:662207e34fba 820 * @return Current multi-master enabled value
garfieldsg 0:662207e34fba 821 * @see MPU6050_RA_I2C_MST_CTRL
garfieldsg 0:662207e34fba 822 */
garfieldsg 0:662207e34fba 823 bool MPU6050::getMultiMasterEnabled()
garfieldsg 0:662207e34fba 824 {
garfieldsg 0:662207e34fba 825 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_CTRL, MPU6050_MULT_MST_EN_BIT, buffer);
garfieldsg 0:662207e34fba 826 return buffer[0];
garfieldsg 0:662207e34fba 827 }
garfieldsg 0:662207e34fba 828 /** Set multi-master enabled value.
garfieldsg 0:662207e34fba 829 * @param enabled New multi-master enabled value
garfieldsg 0:662207e34fba 830 * @see getMultiMasterEnabled()
garfieldsg 0:662207e34fba 831 * @see MPU6050_RA_I2C_MST_CTRL
garfieldsg 0:662207e34fba 832 */
garfieldsg 0:662207e34fba 833 void MPU6050::setMultiMasterEnabled(bool enabled)
garfieldsg 0:662207e34fba 834 {
garfieldsg 0:662207e34fba 835 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_MST_CTRL, MPU6050_MULT_MST_EN_BIT, enabled);
garfieldsg 0:662207e34fba 836 }
garfieldsg 0:662207e34fba 837 /** Get wait-for-external-sensor-data enabled value.
garfieldsg 0:662207e34fba 838 * When the WAIT_FOR_ES bit is set to 1, the Data Ready interrupt will be
garfieldsg 0:662207e34fba 839 * delayed until External Sensor data from the Slave Devices are loaded into the
garfieldsg 0:662207e34fba 840 * EXT_SENS_DATA registers. This is used to ensure that both the internal sensor
garfieldsg 0:662207e34fba 841 * data (i.e. from gyro and accel) and external sensor data have been loaded to
garfieldsg 0:662207e34fba 842 * their respective data registers (i.e. the data is synced) when the Data Ready
garfieldsg 0:662207e34fba 843 * interrupt is triggered.
garfieldsg 0:662207e34fba 844 *
garfieldsg 0:662207e34fba 845 * @return Current wait-for-external-sensor-data enabled value
garfieldsg 0:662207e34fba 846 * @see MPU6050_RA_I2C_MST_CTRL
garfieldsg 0:662207e34fba 847 */
garfieldsg 0:662207e34fba 848 bool MPU6050::getWaitForExternalSensorEnabled()
garfieldsg 0:662207e34fba 849 {
garfieldsg 0:662207e34fba 850 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_CTRL, MPU6050_WAIT_FOR_ES_BIT, buffer);
garfieldsg 0:662207e34fba 851 return buffer[0];
garfieldsg 0:662207e34fba 852 }
garfieldsg 0:662207e34fba 853 /** Set wait-for-external-sensor-data enabled value.
garfieldsg 0:662207e34fba 854 * @param enabled New wait-for-external-sensor-data enabled value
garfieldsg 0:662207e34fba 855 * @see getWaitForExternalSensorEnabled()
garfieldsg 0:662207e34fba 856 * @see MPU6050_RA_I2C_MST_CTRL
garfieldsg 0:662207e34fba 857 */
garfieldsg 0:662207e34fba 858 void MPU6050::setWaitForExternalSensorEnabled(bool enabled)
garfieldsg 0:662207e34fba 859 {
garfieldsg 0:662207e34fba 860 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_MST_CTRL, MPU6050_WAIT_FOR_ES_BIT, enabled);
garfieldsg 0:662207e34fba 861 }
garfieldsg 0:662207e34fba 862 /** Get Slave 3 FIFO enabled value.
garfieldsg 0:662207e34fba 863 * When set to 1, this bit enables EXT_SENS_DATA registers (Registers 73 to 96)
garfieldsg 0:662207e34fba 864 * associated with Slave 3 to be written into the FIFO buffer.
garfieldsg 0:662207e34fba 865 * @return Current Slave 3 FIFO enabled value
garfieldsg 0:662207e34fba 866 * @see MPU6050_RA_MST_CTRL
garfieldsg 0:662207e34fba 867 */
garfieldsg 0:662207e34fba 868 bool MPU6050::getSlave3FIFOEnabled()
garfieldsg 0:662207e34fba 869 {
garfieldsg 0:662207e34fba 870 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_CTRL, MPU6050_SLV_3_FIFO_EN_BIT, buffer);
garfieldsg 0:662207e34fba 871 return buffer[0];
garfieldsg 0:662207e34fba 872 }
garfieldsg 0:662207e34fba 873 /** Set Slave 3 FIFO enabled value.
garfieldsg 0:662207e34fba 874 * @param enabled New Slave 3 FIFO enabled value
garfieldsg 0:662207e34fba 875 * @see getSlave3FIFOEnabled()
garfieldsg 0:662207e34fba 876 * @see MPU6050_RA_MST_CTRL
garfieldsg 0:662207e34fba 877 */
garfieldsg 0:662207e34fba 878 void MPU6050::setSlave3FIFOEnabled(bool enabled)
garfieldsg 0:662207e34fba 879 {
garfieldsg 0:662207e34fba 880 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_MST_CTRL, MPU6050_SLV_3_FIFO_EN_BIT, enabled);
garfieldsg 0:662207e34fba 881 }
garfieldsg 0:662207e34fba 882 /** Get slave read/write transition enabled value.
garfieldsg 0:662207e34fba 883 * The I2C_MST_P_NSR bit configures the I2C Master's transition from one slave
garfieldsg 0:662207e34fba 884 * read to the next slave read. If the bit equals 0, there will be a restart
garfieldsg 0:662207e34fba 885 * between reads. If the bit equals 1, there will be a stop followed by a start
garfieldsg 0:662207e34fba 886 * of the following read. When a write transaction follows a read transaction,
garfieldsg 0:662207e34fba 887 * the stop followed by a start of the successive write will be always used.
garfieldsg 0:662207e34fba 888 *
garfieldsg 0:662207e34fba 889 * @return Current slave read/write transition enabled value
garfieldsg 0:662207e34fba 890 * @see MPU6050_RA_I2C_MST_CTRL
garfieldsg 0:662207e34fba 891 */
garfieldsg 0:662207e34fba 892 bool MPU6050::getSlaveReadWriteTransitionEnabled()
garfieldsg 0:662207e34fba 893 {
garfieldsg 0:662207e34fba 894 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_CTRL, MPU6050_I2C_MST_P_NSR_BIT, buffer);
garfieldsg 0:662207e34fba 895 return buffer[0];
garfieldsg 0:662207e34fba 896 }
garfieldsg 0:662207e34fba 897 /** Set slave read/write transition enabled value.
garfieldsg 0:662207e34fba 898 * @param enabled New slave read/write transition enabled value
garfieldsg 0:662207e34fba 899 * @see getSlaveReadWriteTransitionEnabled()
garfieldsg 0:662207e34fba 900 * @see MPU6050_RA_I2C_MST_CTRL
garfieldsg 0:662207e34fba 901 */
garfieldsg 0:662207e34fba 902 void MPU6050::setSlaveReadWriteTransitionEnabled(bool enabled)
garfieldsg 0:662207e34fba 903 {
garfieldsg 0:662207e34fba 904 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_MST_CTRL, MPU6050_I2C_MST_P_NSR_BIT, enabled);
garfieldsg 0:662207e34fba 905 }
garfieldsg 0:662207e34fba 906 /** Get I2C master clock speed.
garfieldsg 0:662207e34fba 907 * I2C_MST_CLK is a 4 bit unsigned value which configures a divider on the
garfieldsg 0:662207e34fba 908 * MPU-60X0 internal 8MHz clock. It sets the I2C master clock speed according to
garfieldsg 0:662207e34fba 909 * the following table:
garfieldsg 0:662207e34fba 910 *
garfieldsg 0:662207e34fba 911 * <pre>
garfieldsg 0:662207e34fba 912 * I2C_MST_CLK | I2C Master Clock Speed | 8MHz Clock Divider
garfieldsg 0:662207e34fba 913 * ------------+------------------------+-------------------
garfieldsg 0:662207e34fba 914 * 0 | 348kHz | 23
garfieldsg 0:662207e34fba 915 * 1 | 333kHz | 24
garfieldsg 0:662207e34fba 916 * 2 | 320kHz | 25
garfieldsg 0:662207e34fba 917 * 3 | 308kHz | 26
garfieldsg 0:662207e34fba 918 * 4 | 296kHz | 27
garfieldsg 0:662207e34fba 919 * 5 | 286kHz | 28
garfieldsg 0:662207e34fba 920 * 6 | 276kHz | 29
garfieldsg 0:662207e34fba 921 * 7 | 267kHz | 30
garfieldsg 0:662207e34fba 922 * 8 | 258kHz | 31
garfieldsg 0:662207e34fba 923 * 9 | 500kHz | 16
garfieldsg 0:662207e34fba 924 * 10 | 471kHz | 17
garfieldsg 0:662207e34fba 925 * 11 | 444kHz | 18
garfieldsg 0:662207e34fba 926 * 12 | 421kHz | 19
garfieldsg 0:662207e34fba 927 * 13 | 400kHz | 20
garfieldsg 0:662207e34fba 928 * 14 | 381kHz | 21
garfieldsg 0:662207e34fba 929 * 15 | 364kHz | 22
garfieldsg 0:662207e34fba 930 * </pre>
garfieldsg 0:662207e34fba 931 *
garfieldsg 0:662207e34fba 932 * @return Current I2C master clock speed
garfieldsg 0:662207e34fba 933 * @see MPU6050_RA_I2C_MST_CTRL
garfieldsg 0:662207e34fba 934 */
garfieldsg 0:662207e34fba 935 uint8_t MPU6050::getMasterClockSpeed()
garfieldsg 0:662207e34fba 936 {
garfieldsg 0:662207e34fba 937 i2Cdev.readBits(devAddr, MPU6050_RA_I2C_MST_CTRL, MPU6050_I2C_MST_CLK_BIT, MPU6050_I2C_MST_CLK_LENGTH, buffer);
garfieldsg 0:662207e34fba 938 return buffer[0];
garfieldsg 0:662207e34fba 939 }
garfieldsg 0:662207e34fba 940 /** Set I2C master clock speed.
garfieldsg 0:662207e34fba 941 * @reparam speed Current I2C master clock speed
garfieldsg 0:662207e34fba 942 * @see MPU6050_RA_I2C_MST_CTRL
garfieldsg 0:662207e34fba 943 */
garfieldsg 0:662207e34fba 944 void MPU6050::setMasterClockSpeed(uint8_t speed)
garfieldsg 0:662207e34fba 945 {
garfieldsg 0:662207e34fba 946 i2Cdev.writeBits(devAddr, MPU6050_RA_I2C_MST_CTRL, MPU6050_I2C_MST_CLK_BIT, MPU6050_I2C_MST_CLK_LENGTH, speed);
garfieldsg 0:662207e34fba 947 }
garfieldsg 0:662207e34fba 948
garfieldsg 0:662207e34fba 949 // I2C_SLV* registers (Slave 0-3)
garfieldsg 0:662207e34fba 950
garfieldsg 0:662207e34fba 951 /** Get the I2C address of the specified slave (0-3).
garfieldsg 0:662207e34fba 952 * Note that Bit 7 (MSB) controls read/write mode. If Bit 7 is set, it's a read
garfieldsg 0:662207e34fba 953 * operation, and if it is cleared, then it's a write operation. The remaining
garfieldsg 0:662207e34fba 954 * bits (6-0) are the 7-bit device address of the slave device.
garfieldsg 0:662207e34fba 955 *
garfieldsg 0:662207e34fba 956 * In read mode, the result of the read is placed in the lowest available
garfieldsg 0:662207e34fba 957 * EXT_SENS_DATA register. For further information regarding the allocation of
garfieldsg 0:662207e34fba 958 * read results, please refer to the EXT_SENS_DATA register description
garfieldsg 0:662207e34fba 959 * (Registers 73 - 96).
garfieldsg 0:662207e34fba 960 *
garfieldsg 0:662207e34fba 961 * The MPU-6050 supports a total of five slaves, but Slave 4 has unique
garfieldsg 0:662207e34fba 962 * characteristics, and so it has its own functions (getSlave4* and setSlave4*).
garfieldsg 0:662207e34fba 963 *
garfieldsg 0:662207e34fba 964 * I2C data transactions are performed at the Sample Rate, as defined in
garfieldsg 0:662207e34fba 965 * Register 25. The user is responsible for ensuring that I2C data transactions
garfieldsg 0:662207e34fba 966 * to and from each enabled Slave can be completed within a single period of the
garfieldsg 0:662207e34fba 967 * Sample Rate.
garfieldsg 0:662207e34fba 968 *
garfieldsg 0:662207e34fba 969 * The I2C slave access rate can be reduced relative to the Sample Rate. This
garfieldsg 0:662207e34fba 970 * reduced access rate is determined by I2C_MST_DLY (Register 52). Whether a
garfieldsg 0:662207e34fba 971 * slave's access rate is reduced relative to the Sample Rate is determined by
garfieldsg 0:662207e34fba 972 * I2C_MST_DELAY_CTRL (Register 103).
garfieldsg 0:662207e34fba 973 *
garfieldsg 0:662207e34fba 974 * The processing order for the slaves is fixed. The sequence followed for
garfieldsg 0:662207e34fba 975 * processing the slaves is Slave 0, Slave 1, Slave 2, Slave 3 and Slave 4. If a
garfieldsg 0:662207e34fba 976 * particular Slave is disabled it will be skipped.
garfieldsg 0:662207e34fba 977 *
garfieldsg 0:662207e34fba 978 * Each slave can either be accessed at the sample rate or at a reduced sample
garfieldsg 0:662207e34fba 979 * rate. In a case where some slaves are accessed at the Sample Rate and some
garfieldsg 0:662207e34fba 980 * slaves are accessed at the reduced rate, the sequence of accessing the slaves
garfieldsg 0:662207e34fba 981 * (Slave 0 to Slave 4) is still followed. However, the reduced rate slaves will
garfieldsg 0:662207e34fba 982 * be skipped if their access rate dictates that they should not be accessed
garfieldsg 0:662207e34fba 983 * during that particular cycle. For further information regarding the reduced
garfieldsg 0:662207e34fba 984 * access rate, please refer to Register 52. Whether a slave is accessed at the
garfieldsg 0:662207e34fba 985 * Sample Rate or at the reduced rate is determined by the Delay Enable bits in
garfieldsg 0:662207e34fba 986 * Register 103.
garfieldsg 0:662207e34fba 987 *
garfieldsg 0:662207e34fba 988 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 989 * @return Current address for specified slave
garfieldsg 0:662207e34fba 990 * @see MPU6050_RA_I2C_SLV0_ADDR
garfieldsg 0:662207e34fba 991 */
garfieldsg 0:662207e34fba 992 uint8_t MPU6050::getSlaveAddress(uint8_t num)
garfieldsg 0:662207e34fba 993 {
garfieldsg 0:662207e34fba 994 if (num > 3) return 0;
garfieldsg 0:662207e34fba 995 i2Cdev.readByte(devAddr, MPU6050_RA_I2C_SLV0_ADDR + num*3, buffer);
garfieldsg 0:662207e34fba 996 return buffer[0];
garfieldsg 0:662207e34fba 997 }
garfieldsg 0:662207e34fba 998 /** Set the I2C address of the specified slave (0-3).
garfieldsg 0:662207e34fba 999 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1000 * @param address New address for specified slave
garfieldsg 0:662207e34fba 1001 * @see getSlaveAddress()
garfieldsg 0:662207e34fba 1002 * @see MPU6050_RA_I2C_SLV0_ADDR
garfieldsg 0:662207e34fba 1003 */
garfieldsg 0:662207e34fba 1004 void MPU6050::setSlaveAddress(uint8_t num, uint8_t address)
garfieldsg 0:662207e34fba 1005 {
garfieldsg 0:662207e34fba 1006 if (num > 3) return;
garfieldsg 0:662207e34fba 1007 i2Cdev.writeByte(devAddr, MPU6050_RA_I2C_SLV0_ADDR + num*3, address);
garfieldsg 0:662207e34fba 1008 }
garfieldsg 0:662207e34fba 1009 /** Get the active internal register for the specified slave (0-3).
garfieldsg 0:662207e34fba 1010 * Read/write operations for this slave will be done to whatever internal
garfieldsg 0:662207e34fba 1011 * register address is stored in this MPU register.
garfieldsg 0:662207e34fba 1012 *
garfieldsg 0:662207e34fba 1013 * The MPU-6050 supports a total of five slaves, but Slave 4 has unique
garfieldsg 0:662207e34fba 1014 * characteristics, and so it has its own functions.
garfieldsg 0:662207e34fba 1015 *
garfieldsg 0:662207e34fba 1016 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1017 * @return Current active register for specified slave
garfieldsg 0:662207e34fba 1018 * @see MPU6050_RA_I2C_SLV0_REG
garfieldsg 0:662207e34fba 1019 */
garfieldsg 0:662207e34fba 1020 uint8_t MPU6050::getSlaveRegister(uint8_t num)
garfieldsg 0:662207e34fba 1021 {
garfieldsg 0:662207e34fba 1022 if (num > 3) return 0;
garfieldsg 0:662207e34fba 1023 i2Cdev.readByte(devAddr, MPU6050_RA_I2C_SLV0_REG + num*3, buffer);
garfieldsg 0:662207e34fba 1024 return buffer[0];
garfieldsg 0:662207e34fba 1025 }
garfieldsg 0:662207e34fba 1026 /** Set the active internal register for the specified slave (0-3).
garfieldsg 0:662207e34fba 1027 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1028 * @param reg New active register for specified slave
garfieldsg 0:662207e34fba 1029 * @see getSlaveRegister()
garfieldsg 0:662207e34fba 1030 * @see MPU6050_RA_I2C_SLV0_REG
garfieldsg 0:662207e34fba 1031 */
garfieldsg 0:662207e34fba 1032 void MPU6050::setSlaveRegister(uint8_t num, uint8_t reg)
garfieldsg 0:662207e34fba 1033 {
garfieldsg 0:662207e34fba 1034 if (num > 3) return;
garfieldsg 0:662207e34fba 1035 i2Cdev.writeByte(devAddr, MPU6050_RA_I2C_SLV0_REG + num*3, reg);
garfieldsg 0:662207e34fba 1036 }
garfieldsg 0:662207e34fba 1037 /** Get the enabled value for the specified slave (0-3).
garfieldsg 0:662207e34fba 1038 * When set to 1, this bit enables Slave 0 for data transfer operations. When
garfieldsg 0:662207e34fba 1039 * cleared to 0, this bit disables Slave 0 from data transfer operations.
garfieldsg 0:662207e34fba 1040 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1041 * @return Current enabled value for specified slave
garfieldsg 0:662207e34fba 1042 * @see MPU6050_RA_I2C_SLV0_CTRL
garfieldsg 0:662207e34fba 1043 */
garfieldsg 0:662207e34fba 1044 bool MPU6050::getSlaveEnabled(uint8_t num)
garfieldsg 0:662207e34fba 1045 {
garfieldsg 0:662207e34fba 1046 if (num > 3) return 0;
garfieldsg 0:662207e34fba 1047 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_SLV0_CTRL + num*3, MPU6050_I2C_SLV_EN_BIT, buffer);
garfieldsg 0:662207e34fba 1048 return buffer[0];
garfieldsg 0:662207e34fba 1049 }
garfieldsg 0:662207e34fba 1050 /** Set the enabled value for the specified slave (0-3).
garfieldsg 0:662207e34fba 1051 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1052 * @param enabled New enabled value for specified slave
garfieldsg 0:662207e34fba 1053 * @see getSlaveEnabled()
garfieldsg 0:662207e34fba 1054 * @see MPU6050_RA_I2C_SLV0_CTRL
garfieldsg 0:662207e34fba 1055 */
garfieldsg 0:662207e34fba 1056 void MPU6050::setSlaveEnabled(uint8_t num, bool enabled)
garfieldsg 0:662207e34fba 1057 {
garfieldsg 0:662207e34fba 1058 if (num > 3) return;
garfieldsg 0:662207e34fba 1059 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_SLV0_CTRL + num*3, MPU6050_I2C_SLV_EN_BIT, enabled);
garfieldsg 0:662207e34fba 1060 }
garfieldsg 0:662207e34fba 1061 /** Get word pair byte-swapping enabled for the specified slave (0-3).
garfieldsg 0:662207e34fba 1062 * When set to 1, this bit enables byte swapping. When byte swapping is enabled,
garfieldsg 0:662207e34fba 1063 * the high and low bytes of a word pair are swapped. Please refer to
garfieldsg 0:662207e34fba 1064 * I2C_SLV0_GRP for the pairing convention of the word pairs. When cleared to 0,
garfieldsg 0:662207e34fba 1065 * bytes transferred to and from Slave 0 will be written to EXT_SENS_DATA
garfieldsg 0:662207e34fba 1066 * registers in the order they were transferred.
garfieldsg 0:662207e34fba 1067 *
garfieldsg 0:662207e34fba 1068 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1069 * @return Current word pair byte-swapping enabled value for specified slave
garfieldsg 0:662207e34fba 1070 * @see MPU6050_RA_I2C_SLV0_CTRL
garfieldsg 0:662207e34fba 1071 */
garfieldsg 0:662207e34fba 1072 bool MPU6050::getSlaveWordByteSwap(uint8_t num)
garfieldsg 0:662207e34fba 1073 {
garfieldsg 0:662207e34fba 1074 if (num > 3) return 0;
garfieldsg 0:662207e34fba 1075 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_SLV0_CTRL + num*3, MPU6050_I2C_SLV_BYTE_SW_BIT, buffer);
garfieldsg 0:662207e34fba 1076 return buffer[0];
garfieldsg 0:662207e34fba 1077 }
garfieldsg 0:662207e34fba 1078 /** Set word pair byte-swapping enabled for the specified slave (0-3).
garfieldsg 0:662207e34fba 1079 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1080 * @param enabled New word pair byte-swapping enabled value for specified slave
garfieldsg 0:662207e34fba 1081 * @see getSlaveWordByteSwap()
garfieldsg 0:662207e34fba 1082 * @see MPU6050_RA_I2C_SLV0_CTRL
garfieldsg 0:662207e34fba 1083 */
garfieldsg 0:662207e34fba 1084 void MPU6050::setSlaveWordByteSwap(uint8_t num, bool enabled)
garfieldsg 0:662207e34fba 1085 {
garfieldsg 0:662207e34fba 1086 if (num > 3) return;
garfieldsg 0:662207e34fba 1087 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_SLV0_CTRL + num*3, MPU6050_I2C_SLV_BYTE_SW_BIT, enabled);
garfieldsg 0:662207e34fba 1088 }
garfieldsg 0:662207e34fba 1089 /** Get write mode for the specified slave (0-3).
garfieldsg 0:662207e34fba 1090 * When set to 1, the transaction will read or write data only. When cleared to
garfieldsg 0:662207e34fba 1091 * 0, the transaction will write a register address prior to reading or writing
garfieldsg 0:662207e34fba 1092 * data. This should equal 0 when specifying the register address within the
garfieldsg 0:662207e34fba 1093 * Slave device to/from which the ensuing data transaction will take place.
garfieldsg 0:662207e34fba 1094 *
garfieldsg 0:662207e34fba 1095 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1096 * @return Current write mode for specified slave (0 = register address + data, 1 = data only)
garfieldsg 0:662207e34fba 1097 * @see MPU6050_RA_I2C_SLV0_CTRL
garfieldsg 0:662207e34fba 1098 */
garfieldsg 0:662207e34fba 1099 bool MPU6050::getSlaveWriteMode(uint8_t num)
garfieldsg 0:662207e34fba 1100 {
garfieldsg 0:662207e34fba 1101 if (num > 3) return 0;
garfieldsg 0:662207e34fba 1102 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_SLV0_CTRL + num*3, MPU6050_I2C_SLV_REG_DIS_BIT, buffer);
garfieldsg 0:662207e34fba 1103 return buffer[0];
garfieldsg 0:662207e34fba 1104 }
garfieldsg 0:662207e34fba 1105 /** Set write mode for the specified slave (0-3).
garfieldsg 0:662207e34fba 1106 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1107 * @param mode New write mode for specified slave (0 = register address + data, 1 = data only)
garfieldsg 0:662207e34fba 1108 * @see getSlaveWriteMode()
garfieldsg 0:662207e34fba 1109 * @see MPU6050_RA_I2C_SLV0_CTRL
garfieldsg 0:662207e34fba 1110 */
garfieldsg 0:662207e34fba 1111 void MPU6050::setSlaveWriteMode(uint8_t num, bool mode)
garfieldsg 0:662207e34fba 1112 {
garfieldsg 0:662207e34fba 1113 if (num > 3) return;
garfieldsg 0:662207e34fba 1114 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_SLV0_CTRL + num*3, MPU6050_I2C_SLV_REG_DIS_BIT, mode);
garfieldsg 0:662207e34fba 1115 }
garfieldsg 0:662207e34fba 1116 /** Get word pair grouping order offset for the specified slave (0-3).
garfieldsg 0:662207e34fba 1117 * This sets specifies the grouping order of word pairs received from registers.
garfieldsg 0:662207e34fba 1118 * When cleared to 0, bytes from register addresses 0 and 1, 2 and 3, etc (even,
garfieldsg 0:662207e34fba 1119 * then odd register addresses) are paired to form a word. When set to 1, bytes
garfieldsg 0:662207e34fba 1120 * from register addresses are paired 1 and 2, 3 and 4, etc. (odd, then even
garfieldsg 0:662207e34fba 1121 * register addresses) are paired to form a word.
garfieldsg 0:662207e34fba 1122 *
garfieldsg 0:662207e34fba 1123 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1124 * @return Current word pair grouping order offset for specified slave
garfieldsg 0:662207e34fba 1125 * @see MPU6050_RA_I2C_SLV0_CTRL
garfieldsg 0:662207e34fba 1126 */
garfieldsg 0:662207e34fba 1127 bool MPU6050::getSlaveWordGroupOffset(uint8_t num)
garfieldsg 0:662207e34fba 1128 {
garfieldsg 0:662207e34fba 1129 if (num > 3) return 0;
garfieldsg 0:662207e34fba 1130 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_SLV0_CTRL + num*3, MPU6050_I2C_SLV_GRP_BIT, buffer);
garfieldsg 0:662207e34fba 1131 return buffer[0];
garfieldsg 0:662207e34fba 1132 }
garfieldsg 0:662207e34fba 1133 /** Set word pair grouping order offset for the specified slave (0-3).
garfieldsg 0:662207e34fba 1134 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1135 * @param enabled New word pair grouping order offset for specified slave
garfieldsg 0:662207e34fba 1136 * @see getSlaveWordGroupOffset()
garfieldsg 0:662207e34fba 1137 * @see MPU6050_RA_I2C_SLV0_CTRL
garfieldsg 0:662207e34fba 1138 */
garfieldsg 0:662207e34fba 1139 void MPU6050::setSlaveWordGroupOffset(uint8_t num, bool enabled)
garfieldsg 0:662207e34fba 1140 {
garfieldsg 0:662207e34fba 1141 if (num > 3) return;
garfieldsg 0:662207e34fba 1142 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_SLV0_CTRL + num*3, MPU6050_I2C_SLV_GRP_BIT, enabled);
garfieldsg 0:662207e34fba 1143 }
garfieldsg 0:662207e34fba 1144 /** Get number of bytes to read for the specified slave (0-3).
garfieldsg 0:662207e34fba 1145 * Specifies the number of bytes transferred to and from Slave 0. Clearing this
garfieldsg 0:662207e34fba 1146 * bit to 0 is equivalent to disabling the register by writing 0 to I2C_SLV0_EN.
garfieldsg 0:662207e34fba 1147 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1148 * @return Number of bytes to read for specified slave
garfieldsg 0:662207e34fba 1149 * @see MPU6050_RA_I2C_SLV0_CTRL
garfieldsg 0:662207e34fba 1150 */
garfieldsg 0:662207e34fba 1151 uint8_t MPU6050::getSlaveDataLength(uint8_t num)
garfieldsg 0:662207e34fba 1152 {
garfieldsg 0:662207e34fba 1153 if (num > 3) return 0;
garfieldsg 0:662207e34fba 1154 i2Cdev.readBits(devAddr, MPU6050_RA_I2C_SLV0_CTRL + num*3, MPU6050_I2C_SLV_LEN_BIT, MPU6050_I2C_SLV_LEN_LENGTH, buffer);
garfieldsg 0:662207e34fba 1155 return buffer[0];
garfieldsg 0:662207e34fba 1156 }
garfieldsg 0:662207e34fba 1157 /** Set number of bytes to read for the specified slave (0-3).
garfieldsg 0:662207e34fba 1158 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 1159 * @param length Number of bytes to read for specified slave
garfieldsg 0:662207e34fba 1160 * @see getSlaveDataLength()
garfieldsg 0:662207e34fba 1161 * @see MPU6050_RA_I2C_SLV0_CTRL
garfieldsg 0:662207e34fba 1162 */
garfieldsg 0:662207e34fba 1163 void MPU6050::setSlaveDataLength(uint8_t num, uint8_t length)
garfieldsg 0:662207e34fba 1164 {
garfieldsg 0:662207e34fba 1165 if (num > 3) return;
garfieldsg 0:662207e34fba 1166 i2Cdev.writeBits(devAddr, MPU6050_RA_I2C_SLV0_CTRL + num*3, MPU6050_I2C_SLV_LEN_BIT, MPU6050_I2C_SLV_LEN_LENGTH, length);
garfieldsg 0:662207e34fba 1167 }
garfieldsg 0:662207e34fba 1168
garfieldsg 0:662207e34fba 1169 // I2C_SLV* registers (Slave 4)
garfieldsg 0:662207e34fba 1170
garfieldsg 0:662207e34fba 1171 /** Get the I2C address of Slave 4.
garfieldsg 0:662207e34fba 1172 * Note that Bit 7 (MSB) controls read/write mode. If Bit 7 is set, it's a read
garfieldsg 0:662207e34fba 1173 * operation, and if it is cleared, then it's a write operation. The remaining
garfieldsg 0:662207e34fba 1174 * bits (6-0) are the 7-bit device address of the slave device.
garfieldsg 0:662207e34fba 1175 *
garfieldsg 0:662207e34fba 1176 * @return Current address for Slave 4
garfieldsg 0:662207e34fba 1177 * @see getSlaveAddress()
garfieldsg 0:662207e34fba 1178 * @see MPU6050_RA_I2C_SLV4_ADDR
garfieldsg 0:662207e34fba 1179 */
garfieldsg 0:662207e34fba 1180 uint8_t MPU6050::getSlave4Address()
garfieldsg 0:662207e34fba 1181 {
garfieldsg 0:662207e34fba 1182 i2Cdev.readByte(devAddr, MPU6050_RA_I2C_SLV4_ADDR, buffer);
garfieldsg 0:662207e34fba 1183 return buffer[0];
garfieldsg 0:662207e34fba 1184 }
garfieldsg 0:662207e34fba 1185 /** Set the I2C address of Slave 4.
garfieldsg 0:662207e34fba 1186 * @param address New address for Slave 4
garfieldsg 0:662207e34fba 1187 * @see getSlave4Address()
garfieldsg 0:662207e34fba 1188 * @see MPU6050_RA_I2C_SLV4_ADDR
garfieldsg 0:662207e34fba 1189 */
garfieldsg 0:662207e34fba 1190 void MPU6050::setSlave4Address(uint8_t address)
garfieldsg 0:662207e34fba 1191 {
garfieldsg 0:662207e34fba 1192 i2Cdev.writeByte(devAddr, MPU6050_RA_I2C_SLV4_ADDR, address);
garfieldsg 0:662207e34fba 1193 }
garfieldsg 0:662207e34fba 1194 /** Get the active internal register for the Slave 4.
garfieldsg 0:662207e34fba 1195 * Read/write operations for this slave will be done to whatever internal
garfieldsg 0:662207e34fba 1196 * register address is stored in this MPU register.
garfieldsg 0:662207e34fba 1197 *
garfieldsg 0:662207e34fba 1198 * @return Current active register for Slave 4
garfieldsg 0:662207e34fba 1199 * @see MPU6050_RA_I2C_SLV4_REG
garfieldsg 0:662207e34fba 1200 */
garfieldsg 0:662207e34fba 1201 uint8_t MPU6050::getSlave4Register()
garfieldsg 0:662207e34fba 1202 {
garfieldsg 0:662207e34fba 1203 i2Cdev.readByte(devAddr, MPU6050_RA_I2C_SLV4_REG, buffer);
garfieldsg 0:662207e34fba 1204 return buffer[0];
garfieldsg 0:662207e34fba 1205 }
garfieldsg 0:662207e34fba 1206 /** Set the active internal register for Slave 4.
garfieldsg 0:662207e34fba 1207 * @param reg New active register for Slave 4
garfieldsg 0:662207e34fba 1208 * @see getSlave4Register()
garfieldsg 0:662207e34fba 1209 * @see MPU6050_RA_I2C_SLV4_REG
garfieldsg 0:662207e34fba 1210 */
garfieldsg 0:662207e34fba 1211 void MPU6050::setSlave4Register(uint8_t reg)
garfieldsg 0:662207e34fba 1212 {
garfieldsg 0:662207e34fba 1213 i2Cdev.writeByte(devAddr, MPU6050_RA_I2C_SLV4_REG, reg);
garfieldsg 0:662207e34fba 1214 }
garfieldsg 0:662207e34fba 1215 /** Set new byte to write to Slave 4.
garfieldsg 0:662207e34fba 1216 * This register stores the data to be written into the Slave 4. If I2C_SLV4_RW
garfieldsg 0:662207e34fba 1217 * is set 1 (set to read), this register has no effect.
garfieldsg 0:662207e34fba 1218 * @param data New byte to write to Slave 4
garfieldsg 0:662207e34fba 1219 * @see MPU6050_RA_I2C_SLV4_DO
garfieldsg 0:662207e34fba 1220 */
garfieldsg 0:662207e34fba 1221 void MPU6050::setSlave4OutputByte(uint8_t data)
garfieldsg 0:662207e34fba 1222 {
garfieldsg 0:662207e34fba 1223 i2Cdev.writeByte(devAddr, MPU6050_RA_I2C_SLV4_DO, data);
garfieldsg 0:662207e34fba 1224 }
garfieldsg 0:662207e34fba 1225 /** Get the enabled value for the Slave 4.
garfieldsg 0:662207e34fba 1226 * When set to 1, this bit enables Slave 4 for data transfer operations. When
garfieldsg 0:662207e34fba 1227 * cleared to 0, this bit disables Slave 4 from data transfer operations.
garfieldsg 0:662207e34fba 1228 * @return Current enabled value for Slave 4
garfieldsg 0:662207e34fba 1229 * @see MPU6050_RA_I2C_SLV4_CTRL
garfieldsg 0:662207e34fba 1230 */
garfieldsg 0:662207e34fba 1231 bool MPU6050::getSlave4Enabled()
garfieldsg 0:662207e34fba 1232 {
garfieldsg 0:662207e34fba 1233 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_SLV4_CTRL, MPU6050_I2C_SLV4_EN_BIT, buffer);
garfieldsg 0:662207e34fba 1234 return buffer[0];
garfieldsg 0:662207e34fba 1235 }
garfieldsg 0:662207e34fba 1236 /** Set the enabled value for Slave 4.
garfieldsg 0:662207e34fba 1237 * @param enabled New enabled value for Slave 4
garfieldsg 0:662207e34fba 1238 * @see getSlave4Enabled()
garfieldsg 0:662207e34fba 1239 * @see MPU6050_RA_I2C_SLV4_CTRL
garfieldsg 0:662207e34fba 1240 */
garfieldsg 0:662207e34fba 1241 void MPU6050::setSlave4Enabled(bool enabled)
garfieldsg 0:662207e34fba 1242 {
garfieldsg 0:662207e34fba 1243 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_SLV4_CTRL, MPU6050_I2C_SLV4_EN_BIT, enabled);
garfieldsg 0:662207e34fba 1244 }
garfieldsg 0:662207e34fba 1245 /** Get the enabled value for Slave 4 transaction interrupts.
garfieldsg 0:662207e34fba 1246 * When set to 1, this bit enables the generation of an interrupt signal upon
garfieldsg 0:662207e34fba 1247 * completion of a Slave 4 transaction. When cleared to 0, this bit disables the
garfieldsg 0:662207e34fba 1248 * generation of an interrupt signal upon completion of a Slave 4 transaction.
garfieldsg 0:662207e34fba 1249 * The interrupt status can be observed in Register 54.
garfieldsg 0:662207e34fba 1250 *
garfieldsg 0:662207e34fba 1251 * @return Current enabled value for Slave 4 transaction interrupts.
garfieldsg 0:662207e34fba 1252 * @see MPU6050_RA_I2C_SLV4_CTRL
garfieldsg 0:662207e34fba 1253 */
garfieldsg 0:662207e34fba 1254 bool MPU6050::getSlave4InterruptEnabled()
garfieldsg 0:662207e34fba 1255 {
garfieldsg 0:662207e34fba 1256 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_SLV4_CTRL, MPU6050_I2C_SLV4_INT_EN_BIT, buffer);
garfieldsg 0:662207e34fba 1257 return buffer[0];
garfieldsg 0:662207e34fba 1258 }
garfieldsg 0:662207e34fba 1259 /** Set the enabled value for Slave 4 transaction interrupts.
garfieldsg 0:662207e34fba 1260 * @param enabled New enabled value for Slave 4 transaction interrupts.
garfieldsg 0:662207e34fba 1261 * @see getSlave4InterruptEnabled()
garfieldsg 0:662207e34fba 1262 * @see MPU6050_RA_I2C_SLV4_CTRL
garfieldsg 0:662207e34fba 1263 */
garfieldsg 0:662207e34fba 1264 void MPU6050::setSlave4InterruptEnabled(bool enabled)
garfieldsg 0:662207e34fba 1265 {
garfieldsg 0:662207e34fba 1266 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_SLV4_CTRL, MPU6050_I2C_SLV4_INT_EN_BIT, enabled);
garfieldsg 0:662207e34fba 1267 }
garfieldsg 0:662207e34fba 1268 /** Get write mode for Slave 4.
garfieldsg 0:662207e34fba 1269 * When set to 1, the transaction will read or write data only. When cleared to
garfieldsg 0:662207e34fba 1270 * 0, the transaction will write a register address prior to reading or writing
garfieldsg 0:662207e34fba 1271 * data. This should equal 0 when specifying the register address within the
garfieldsg 0:662207e34fba 1272 * Slave device to/from which the ensuing data transaction will take place.
garfieldsg 0:662207e34fba 1273 *
garfieldsg 0:662207e34fba 1274 * @return Current write mode for Slave 4 (0 = register address + data, 1 = data only)
garfieldsg 0:662207e34fba 1275 * @see MPU6050_RA_I2C_SLV4_CTRL
garfieldsg 0:662207e34fba 1276 */
garfieldsg 0:662207e34fba 1277 bool MPU6050::getSlave4WriteMode()
garfieldsg 0:662207e34fba 1278 {
garfieldsg 0:662207e34fba 1279 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_SLV4_CTRL, MPU6050_I2C_SLV4_REG_DIS_BIT, buffer);
garfieldsg 0:662207e34fba 1280 return buffer[0];
garfieldsg 0:662207e34fba 1281 }
garfieldsg 0:662207e34fba 1282 /** Set write mode for the Slave 4.
garfieldsg 0:662207e34fba 1283 * @param mode New write mode for Slave 4 (0 = register address + data, 1 = data only)
garfieldsg 0:662207e34fba 1284 * @see getSlave4WriteMode()
garfieldsg 0:662207e34fba 1285 * @see MPU6050_RA_I2C_SLV4_CTRL
garfieldsg 0:662207e34fba 1286 */
garfieldsg 0:662207e34fba 1287 void MPU6050::setSlave4WriteMode(bool mode)
garfieldsg 0:662207e34fba 1288 {
garfieldsg 0:662207e34fba 1289 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_SLV4_CTRL, MPU6050_I2C_SLV4_REG_DIS_BIT, mode);
garfieldsg 0:662207e34fba 1290 }
garfieldsg 0:662207e34fba 1291 /** Get Slave 4 master delay value.
garfieldsg 0:662207e34fba 1292 * This configures the reduced access rate of I2C slaves relative to the Sample
garfieldsg 0:662207e34fba 1293 * Rate. When a slave's access rate is decreased relative to the Sample Rate,
garfieldsg 0:662207e34fba 1294 * the slave is accessed every:
garfieldsg 0:662207e34fba 1295 *
garfieldsg 0:662207e34fba 1296 * 1 / (1 + I2C_MST_DLY) samples
garfieldsg 0:662207e34fba 1297 *
garfieldsg 0:662207e34fba 1298 * This base Sample Rate in turn is determined by SMPLRT_DIV (register 25) and
garfieldsg 0:662207e34fba 1299 * DLPF_CFG (register 26). Whether a slave's access rate is reduced relative to
garfieldsg 0:662207e34fba 1300 * the Sample Rate is determined by I2C_MST_DELAY_CTRL (register 103). For
garfieldsg 0:662207e34fba 1301 * further information regarding the Sample Rate, please refer to register 25.
garfieldsg 0:662207e34fba 1302 *
garfieldsg 0:662207e34fba 1303 * @return Current Slave 4 master delay value
garfieldsg 0:662207e34fba 1304 * @see MPU6050_RA_I2C_SLV4_CTRL
garfieldsg 0:662207e34fba 1305 */
garfieldsg 0:662207e34fba 1306 uint8_t MPU6050::getSlave4MasterDelay()
garfieldsg 0:662207e34fba 1307 {
garfieldsg 0:662207e34fba 1308 i2Cdev.readBits(devAddr, MPU6050_RA_I2C_SLV4_CTRL, MPU6050_I2C_SLV4_MST_DLY_BIT, MPU6050_I2C_SLV4_MST_DLY_LENGTH, buffer);
garfieldsg 0:662207e34fba 1309 return buffer[0];
garfieldsg 0:662207e34fba 1310 }
garfieldsg 0:662207e34fba 1311 /** Set Slave 4 master delay value.
garfieldsg 0:662207e34fba 1312 * @param delay New Slave 4 master delay value
garfieldsg 0:662207e34fba 1313 * @see getSlave4MasterDelay()
garfieldsg 0:662207e34fba 1314 * @see MPU6050_RA_I2C_SLV4_CTRL
garfieldsg 0:662207e34fba 1315 */
garfieldsg 0:662207e34fba 1316 void MPU6050::setSlave4MasterDelay(uint8_t delay)
garfieldsg 0:662207e34fba 1317 {
garfieldsg 0:662207e34fba 1318 i2Cdev.writeBits(devAddr, MPU6050_RA_I2C_SLV4_CTRL, MPU6050_I2C_SLV4_MST_DLY_BIT, MPU6050_I2C_SLV4_MST_DLY_LENGTH, delay);
garfieldsg 0:662207e34fba 1319 }
garfieldsg 0:662207e34fba 1320 /** Get last available byte read from Slave 4.
garfieldsg 0:662207e34fba 1321 * This register stores the data read from Slave 4. This field is populated
garfieldsg 0:662207e34fba 1322 * after a read transaction.
garfieldsg 0:662207e34fba 1323 * @return Last available byte read from to Slave 4
garfieldsg 0:662207e34fba 1324 * @see MPU6050_RA_I2C_SLV4_DI
garfieldsg 0:662207e34fba 1325 */
garfieldsg 0:662207e34fba 1326 uint8_t MPU6050::getSlate4InputByte()
garfieldsg 0:662207e34fba 1327 {
garfieldsg 0:662207e34fba 1328 i2Cdev.readByte(devAddr, MPU6050_RA_I2C_SLV4_DI, buffer);
garfieldsg 0:662207e34fba 1329 return buffer[0];
garfieldsg 0:662207e34fba 1330 }
garfieldsg 0:662207e34fba 1331
garfieldsg 0:662207e34fba 1332 // I2C_MST_STATUS register
garfieldsg 0:662207e34fba 1333
garfieldsg 0:662207e34fba 1334 /** Get FSYNC interrupt status.
garfieldsg 0:662207e34fba 1335 * This bit reflects the status of the FSYNC interrupt from an external device
garfieldsg 0:662207e34fba 1336 * into the MPU-60X0. This is used as a way to pass an external interrupt
garfieldsg 0:662207e34fba 1337 * through the MPU-60X0 to the host application processor. When set to 1, this
garfieldsg 0:662207e34fba 1338 * bit will cause an interrupt if FSYNC_INT_EN is asserted in INT_PIN_CFG
garfieldsg 0:662207e34fba 1339 * (Register 55).
garfieldsg 0:662207e34fba 1340 * @return FSYNC interrupt status
garfieldsg 0:662207e34fba 1341 * @see MPU6050_RA_I2C_MST_STATUS
garfieldsg 0:662207e34fba 1342 */
garfieldsg 0:662207e34fba 1343 bool MPU6050::getPassthroughStatus()
garfieldsg 0:662207e34fba 1344 {
garfieldsg 0:662207e34fba 1345 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_STATUS, MPU6050_MST_PASS_THROUGH_BIT, buffer);
garfieldsg 0:662207e34fba 1346 return buffer[0];
garfieldsg 0:662207e34fba 1347 }
garfieldsg 0:662207e34fba 1348 /** Get Slave 4 transaction done status.
garfieldsg 0:662207e34fba 1349 * Automatically sets to 1 when a Slave 4 transaction has completed. This
garfieldsg 0:662207e34fba 1350 * triggers an interrupt if the I2C_MST_INT_EN bit in the INT_ENABLE register
garfieldsg 0:662207e34fba 1351 * (Register 56) is asserted and if the SLV_4_DONE_INT bit is asserted in the
garfieldsg 0:662207e34fba 1352 * I2C_SLV4_CTRL register (Register 52).
garfieldsg 0:662207e34fba 1353 * @return Slave 4 transaction done status
garfieldsg 0:662207e34fba 1354 * @see MPU6050_RA_I2C_MST_STATUS
garfieldsg 0:662207e34fba 1355 */
garfieldsg 0:662207e34fba 1356 bool MPU6050::getSlave4IsDone()
garfieldsg 0:662207e34fba 1357 {
garfieldsg 0:662207e34fba 1358 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_STATUS, MPU6050_MST_I2C_SLV4_DONE_BIT, buffer);
garfieldsg 0:662207e34fba 1359 return buffer[0];
garfieldsg 0:662207e34fba 1360 }
garfieldsg 0:662207e34fba 1361 /** Get master arbitration lost status.
garfieldsg 0:662207e34fba 1362 * This bit automatically sets to 1 when the I2C Master has lost arbitration of
garfieldsg 0:662207e34fba 1363 * the auxiliary I2C bus (an error condition). This triggers an interrupt if the
garfieldsg 0:662207e34fba 1364 * I2C_MST_INT_EN bit in the INT_ENABLE register (Register 56) is asserted.
garfieldsg 0:662207e34fba 1365 * @return Master arbitration lost status
garfieldsg 0:662207e34fba 1366 * @see MPU6050_RA_I2C_MST_STATUS
garfieldsg 0:662207e34fba 1367 */
garfieldsg 0:662207e34fba 1368 bool MPU6050::getLostArbitration()
garfieldsg 0:662207e34fba 1369 {
garfieldsg 0:662207e34fba 1370 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_STATUS, MPU6050_MST_I2C_LOST_ARB_BIT, buffer);
garfieldsg 0:662207e34fba 1371 return buffer[0];
garfieldsg 0:662207e34fba 1372 }
garfieldsg 0:662207e34fba 1373 /** Get Slave 4 NACK status.
garfieldsg 0:662207e34fba 1374 * This bit automatically sets to 1 when the I2C Master receives a NACK in a
garfieldsg 0:662207e34fba 1375 * transaction with Slave 4. This triggers an interrupt if the I2C_MST_INT_EN
garfieldsg 0:662207e34fba 1376 * bit in the INT_ENABLE register (Register 56) is asserted.
garfieldsg 0:662207e34fba 1377 * @return Slave 4 NACK interrupt status
garfieldsg 0:662207e34fba 1378 * @see MPU6050_RA_I2C_MST_STATUS
garfieldsg 0:662207e34fba 1379 */
garfieldsg 0:662207e34fba 1380 bool MPU6050::getSlave4Nack()
garfieldsg 0:662207e34fba 1381 {
garfieldsg 0:662207e34fba 1382 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_STATUS, MPU6050_MST_I2C_SLV4_NACK_BIT, buffer);
garfieldsg 0:662207e34fba 1383 return buffer[0];
garfieldsg 0:662207e34fba 1384 }
garfieldsg 0:662207e34fba 1385 /** Get Slave 3 NACK status.
garfieldsg 0:662207e34fba 1386 * This bit automatically sets to 1 when the I2C Master receives a NACK in a
garfieldsg 0:662207e34fba 1387 * transaction with Slave 3. This triggers an interrupt if the I2C_MST_INT_EN
garfieldsg 0:662207e34fba 1388 * bit in the INT_ENABLE register (Register 56) is asserted.
garfieldsg 0:662207e34fba 1389 * @return Slave 3 NACK interrupt status
garfieldsg 0:662207e34fba 1390 * @see MPU6050_RA_I2C_MST_STATUS
garfieldsg 0:662207e34fba 1391 */
garfieldsg 0:662207e34fba 1392 bool MPU6050::getSlave3Nack()
garfieldsg 0:662207e34fba 1393 {
garfieldsg 0:662207e34fba 1394 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_STATUS, MPU6050_MST_I2C_SLV3_NACK_BIT, buffer);
garfieldsg 0:662207e34fba 1395 return buffer[0];
garfieldsg 0:662207e34fba 1396 }
garfieldsg 0:662207e34fba 1397 /** Get Slave 2 NACK status.
garfieldsg 0:662207e34fba 1398 * This bit automatically sets to 1 when the I2C Master receives a NACK in a
garfieldsg 0:662207e34fba 1399 * transaction with Slave 2. This triggers an interrupt if the I2C_MST_INT_EN
garfieldsg 0:662207e34fba 1400 * bit in the INT_ENABLE register (Register 56) is asserted.
garfieldsg 0:662207e34fba 1401 * @return Slave 2 NACK interrupt status
garfieldsg 0:662207e34fba 1402 * @see MPU6050_RA_I2C_MST_STATUS
garfieldsg 0:662207e34fba 1403 */
garfieldsg 0:662207e34fba 1404 bool MPU6050::getSlave2Nack()
garfieldsg 0:662207e34fba 1405 {
garfieldsg 0:662207e34fba 1406 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_STATUS, MPU6050_MST_I2C_SLV2_NACK_BIT, buffer);
garfieldsg 0:662207e34fba 1407 return buffer[0];
garfieldsg 0:662207e34fba 1408 }
garfieldsg 0:662207e34fba 1409 /** Get Slave 1 NACK status.
garfieldsg 0:662207e34fba 1410 * This bit automatically sets to 1 when the I2C Master receives a NACK in a
garfieldsg 0:662207e34fba 1411 * transaction with Slave 1. This triggers an interrupt if the I2C_MST_INT_EN
garfieldsg 0:662207e34fba 1412 * bit in the INT_ENABLE register (Register 56) is asserted.
garfieldsg 0:662207e34fba 1413 * @return Slave 1 NACK interrupt status
garfieldsg 0:662207e34fba 1414 * @see MPU6050_RA_I2C_MST_STATUS
garfieldsg 0:662207e34fba 1415 */
garfieldsg 0:662207e34fba 1416 bool MPU6050::getSlave1Nack()
garfieldsg 0:662207e34fba 1417 {
garfieldsg 0:662207e34fba 1418 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_STATUS, MPU6050_MST_I2C_SLV1_NACK_BIT, buffer);
garfieldsg 0:662207e34fba 1419 return buffer[0];
garfieldsg 0:662207e34fba 1420 }
garfieldsg 0:662207e34fba 1421 /** Get Slave 0 NACK status.
garfieldsg 0:662207e34fba 1422 * This bit automatically sets to 1 when the I2C Master receives a NACK in a
garfieldsg 0:662207e34fba 1423 * transaction with Slave 0. This triggers an interrupt if the I2C_MST_INT_EN
garfieldsg 0:662207e34fba 1424 * bit in the INT_ENABLE register (Register 56) is asserted.
garfieldsg 0:662207e34fba 1425 * @return Slave 0 NACK interrupt status
garfieldsg 0:662207e34fba 1426 * @see MPU6050_RA_I2C_MST_STATUS
garfieldsg 0:662207e34fba 1427 */
garfieldsg 0:662207e34fba 1428 bool MPU6050::getSlave0Nack()
garfieldsg 0:662207e34fba 1429 {
garfieldsg 0:662207e34fba 1430 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_STATUS, MPU6050_MST_I2C_SLV0_NACK_BIT, buffer);
garfieldsg 0:662207e34fba 1431 return buffer[0];
garfieldsg 0:662207e34fba 1432 }
garfieldsg 0:662207e34fba 1433
garfieldsg 0:662207e34fba 1434 // INT_PIN_CFG register
garfieldsg 0:662207e34fba 1435
garfieldsg 0:662207e34fba 1436 /** Get interrupt logic level mode.
garfieldsg 0:662207e34fba 1437 * Will be set 0 for active-high, 1 for active-low.
garfieldsg 0:662207e34fba 1438 * @return Current interrupt mode (0=active-high, 1=active-low)
garfieldsg 0:662207e34fba 1439 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1440 * @see MPU6050_INTCFG_INT_LEVEL_BIT
garfieldsg 0:662207e34fba 1441 */
garfieldsg 0:662207e34fba 1442 bool MPU6050::getInterruptMode()
garfieldsg 0:662207e34fba 1443 {
garfieldsg 0:662207e34fba 1444 i2Cdev.readBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_INT_LEVEL_BIT, buffer);
garfieldsg 0:662207e34fba 1445 return buffer[0];
garfieldsg 0:662207e34fba 1446 }
garfieldsg 0:662207e34fba 1447 /** Set interrupt logic level mode.
garfieldsg 0:662207e34fba 1448 * @param mode New interrupt mode (0=active-high, 1=active-low)
garfieldsg 0:662207e34fba 1449 * @see getInterruptMode()
garfieldsg 0:662207e34fba 1450 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1451 * @see MPU6050_INTCFG_INT_LEVEL_BIT
garfieldsg 0:662207e34fba 1452 */
garfieldsg 0:662207e34fba 1453 void MPU6050::setInterruptMode(bool mode)
garfieldsg 0:662207e34fba 1454 {
garfieldsg 0:662207e34fba 1455 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_INT_LEVEL_BIT, mode);
garfieldsg 0:662207e34fba 1456 }
garfieldsg 0:662207e34fba 1457 /** Get interrupt drive mode.
garfieldsg 0:662207e34fba 1458 * Will be set 0 for push-pull, 1 for open-drain.
garfieldsg 0:662207e34fba 1459 * @return Current interrupt drive mode (0=push-pull, 1=open-drain)
garfieldsg 0:662207e34fba 1460 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1461 * @see MPU6050_INTCFG_INT_OPEN_BIT
garfieldsg 0:662207e34fba 1462 */
garfieldsg 0:662207e34fba 1463 bool MPU6050::getInterruptDrive()
garfieldsg 0:662207e34fba 1464 {
garfieldsg 0:662207e34fba 1465 i2Cdev.readBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_INT_OPEN_BIT, buffer);
garfieldsg 0:662207e34fba 1466 return buffer[0];
garfieldsg 0:662207e34fba 1467 }
garfieldsg 0:662207e34fba 1468 /** Set interrupt drive mode.
garfieldsg 0:662207e34fba 1469 * @param drive New interrupt drive mode (0=push-pull, 1=open-drain)
garfieldsg 0:662207e34fba 1470 * @see getInterruptDrive()
garfieldsg 0:662207e34fba 1471 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1472 * @see MPU6050_INTCFG_INT_OPEN_BIT
garfieldsg 0:662207e34fba 1473 */
garfieldsg 0:662207e34fba 1474 void MPU6050::setInterruptDrive(bool drive)
garfieldsg 0:662207e34fba 1475 {
garfieldsg 0:662207e34fba 1476 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_INT_OPEN_BIT, drive);
garfieldsg 0:662207e34fba 1477 }
garfieldsg 0:662207e34fba 1478 /** Get interrupt latch mode.
garfieldsg 0:662207e34fba 1479 * Will be set 0 for 50us-pulse, 1 for latch-until-int-cleared.
garfieldsg 0:662207e34fba 1480 * @return Current latch mode (0=50us-pulse, 1=latch-until-int-cleared)
garfieldsg 0:662207e34fba 1481 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1482 * @see MPU6050_INTCFG_LATCH_INT_EN_BIT
garfieldsg 0:662207e34fba 1483 */
garfieldsg 0:662207e34fba 1484 bool MPU6050::getInterruptLatch()
garfieldsg 0:662207e34fba 1485 {
garfieldsg 0:662207e34fba 1486 i2Cdev.readBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_LATCH_INT_EN_BIT, buffer);
garfieldsg 0:662207e34fba 1487 return buffer[0];
garfieldsg 0:662207e34fba 1488 }
garfieldsg 0:662207e34fba 1489 /** Set interrupt latch mode.
garfieldsg 0:662207e34fba 1490 * @param latch New latch mode (0=50us-pulse, 1=latch-until-int-cleared)
garfieldsg 0:662207e34fba 1491 * @see getInterruptLatch()
garfieldsg 0:662207e34fba 1492 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1493 * @see MPU6050_INTCFG_LATCH_INT_EN_BIT
garfieldsg 0:662207e34fba 1494 */
garfieldsg 0:662207e34fba 1495 void MPU6050::setInterruptLatch(bool latch)
garfieldsg 0:662207e34fba 1496 {
garfieldsg 0:662207e34fba 1497 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_LATCH_INT_EN_BIT, latch);
garfieldsg 0:662207e34fba 1498 }
garfieldsg 0:662207e34fba 1499 /** Get interrupt latch clear mode.
garfieldsg 0:662207e34fba 1500 * Will be set 0 for status-read-only, 1 for any-register-read.
garfieldsg 0:662207e34fba 1501 * @return Current latch clear mode (0=status-read-only, 1=any-register-read)
garfieldsg 0:662207e34fba 1502 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1503 * @see MPU6050_INTCFG_INT_RD_CLEAR_BIT
garfieldsg 0:662207e34fba 1504 */
garfieldsg 0:662207e34fba 1505 bool MPU6050::getInterruptLatchClear()
garfieldsg 0:662207e34fba 1506 {
garfieldsg 0:662207e34fba 1507 i2Cdev.readBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_INT_RD_CLEAR_BIT, buffer);
garfieldsg 0:662207e34fba 1508 return buffer[0];
garfieldsg 0:662207e34fba 1509 }
garfieldsg 0:662207e34fba 1510 /** Set interrupt latch clear mode.
garfieldsg 0:662207e34fba 1511 * @param clear New latch clear mode (0=status-read-only, 1=any-register-read)
garfieldsg 0:662207e34fba 1512 * @see getInterruptLatchClear()
garfieldsg 0:662207e34fba 1513 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1514 * @see MPU6050_INTCFG_INT_RD_CLEAR_BIT
garfieldsg 0:662207e34fba 1515 */
garfieldsg 0:662207e34fba 1516 void MPU6050::setInterruptLatchClear(bool clear)
garfieldsg 0:662207e34fba 1517 {
garfieldsg 0:662207e34fba 1518 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_INT_RD_CLEAR_BIT, clear);
garfieldsg 0:662207e34fba 1519 }
garfieldsg 0:662207e34fba 1520 /** Get FSYNC interrupt logic level mode.
garfieldsg 0:662207e34fba 1521 * @return Current FSYNC interrupt mode (0=active-high, 1=active-low)
garfieldsg 0:662207e34fba 1522 * @see getFSyncInterruptMode()
garfieldsg 0:662207e34fba 1523 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1524 * @see MPU6050_INTCFG_FSYNC_INT_LEVEL_BIT
garfieldsg 0:662207e34fba 1525 */
garfieldsg 0:662207e34fba 1526 bool MPU6050::getFSyncInterruptLevel()
garfieldsg 0:662207e34fba 1527 {
garfieldsg 0:662207e34fba 1528 i2Cdev.readBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_FSYNC_INT_LEVEL_BIT, buffer);
garfieldsg 0:662207e34fba 1529 return buffer[0];
garfieldsg 0:662207e34fba 1530 }
garfieldsg 0:662207e34fba 1531 /** Set FSYNC interrupt logic level mode.
garfieldsg 0:662207e34fba 1532 * @param mode New FSYNC interrupt mode (0=active-high, 1=active-low)
garfieldsg 0:662207e34fba 1533 * @see getFSyncInterruptMode()
garfieldsg 0:662207e34fba 1534 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1535 * @see MPU6050_INTCFG_FSYNC_INT_LEVEL_BIT
garfieldsg 0:662207e34fba 1536 */
garfieldsg 0:662207e34fba 1537 void MPU6050::setFSyncInterruptLevel(bool level)
garfieldsg 0:662207e34fba 1538 {
garfieldsg 0:662207e34fba 1539 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_FSYNC_INT_LEVEL_BIT, level);
garfieldsg 0:662207e34fba 1540 }
garfieldsg 0:662207e34fba 1541 /** Get FSYNC pin interrupt enabled setting.
garfieldsg 0:662207e34fba 1542 * Will be set 0 for disabled, 1 for enabled.
garfieldsg 0:662207e34fba 1543 * @return Current interrupt enabled setting
garfieldsg 0:662207e34fba 1544 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1545 * @see MPU6050_INTCFG_FSYNC_INT_EN_BIT
garfieldsg 0:662207e34fba 1546 */
garfieldsg 0:662207e34fba 1547 bool MPU6050::getFSyncInterruptEnabled()
garfieldsg 0:662207e34fba 1548 {
garfieldsg 0:662207e34fba 1549 i2Cdev.readBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_FSYNC_INT_EN_BIT, buffer);
garfieldsg 0:662207e34fba 1550 return buffer[0];
garfieldsg 0:662207e34fba 1551 }
garfieldsg 0:662207e34fba 1552 /** Set FSYNC pin interrupt enabled setting.
garfieldsg 0:662207e34fba 1553 * @param enabled New FSYNC pin interrupt enabled setting
garfieldsg 0:662207e34fba 1554 * @see getFSyncInterruptEnabled()
garfieldsg 0:662207e34fba 1555 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1556 * @see MPU6050_INTCFG_FSYNC_INT_EN_BIT
garfieldsg 0:662207e34fba 1557 */
garfieldsg 0:662207e34fba 1558 void MPU6050::setFSyncInterruptEnabled(bool enabled)
garfieldsg 0:662207e34fba 1559 {
garfieldsg 0:662207e34fba 1560 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_FSYNC_INT_EN_BIT, enabled);
garfieldsg 0:662207e34fba 1561 }
garfieldsg 0:662207e34fba 1562 /** Get I2C bypass enabled status.
garfieldsg 0:662207e34fba 1563 * When this bit is equal to 1 and I2C_MST_EN (Register 106 bit[5]) is equal to
garfieldsg 0:662207e34fba 1564 * 0, the host application processor will be able to directly access the
garfieldsg 0:662207e34fba 1565 * auxiliary I2C bus of the MPU-60X0. When this bit is equal to 0, the host
garfieldsg 0:662207e34fba 1566 * application processor will not be able to directly access the auxiliary I2C
garfieldsg 0:662207e34fba 1567 * bus of the MPU-60X0 regardless of the state of I2C_MST_EN (Register 106
garfieldsg 0:662207e34fba 1568 * bit[5]).
garfieldsg 0:662207e34fba 1569 * @return Current I2C bypass enabled status
garfieldsg 0:662207e34fba 1570 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1571 * @see MPU6050_INTCFG_I2C_BYPASS_EN_BIT
garfieldsg 0:662207e34fba 1572 */
garfieldsg 0:662207e34fba 1573 bool MPU6050::getI2CBypassEnabled()
garfieldsg 0:662207e34fba 1574 {
garfieldsg 0:662207e34fba 1575 i2Cdev.readBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_I2C_BYPASS_EN_BIT, buffer);
garfieldsg 0:662207e34fba 1576 return buffer[0];
garfieldsg 0:662207e34fba 1577 }
garfieldsg 0:662207e34fba 1578 /** Set I2C bypass enabled status.
garfieldsg 0:662207e34fba 1579 * When this bit is equal to 1 and I2C_MST_EN (Register 106 bit[5]) is equal to
garfieldsg 0:662207e34fba 1580 * 0, the host application processor will be able to directly access the
garfieldsg 0:662207e34fba 1581 * auxiliary I2C bus of the MPU-60X0. When this bit is equal to 0, the host
garfieldsg 0:662207e34fba 1582 * application processor will not be able to directly access the auxiliary I2C
garfieldsg 0:662207e34fba 1583 * bus of the MPU-60X0 regardless of the state of I2C_MST_EN (Register 106
garfieldsg 0:662207e34fba 1584 * bit[5]).
garfieldsg 0:662207e34fba 1585 * @param enabled New I2C bypass enabled status
garfieldsg 0:662207e34fba 1586 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1587 * @see MPU6050_INTCFG_I2C_BYPASS_EN_BIT
garfieldsg 0:662207e34fba 1588 */
garfieldsg 0:662207e34fba 1589 void MPU6050::setI2CBypassEnabled(bool enabled)
garfieldsg 0:662207e34fba 1590 {
garfieldsg 0:662207e34fba 1591 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_I2C_BYPASS_EN_BIT, enabled);
garfieldsg 0:662207e34fba 1592 }
garfieldsg 0:662207e34fba 1593 /** Get reference clock output enabled status.
garfieldsg 0:662207e34fba 1594 * When this bit is equal to 1, a reference clock output is provided at the
garfieldsg 0:662207e34fba 1595 * CLKOUT pin. When this bit is equal to 0, the clock output is disabled. For
garfieldsg 0:662207e34fba 1596 * further information regarding CLKOUT, please refer to the MPU-60X0 Product
garfieldsg 0:662207e34fba 1597 * Specification document.
garfieldsg 0:662207e34fba 1598 * @return Current reference clock output enabled status
garfieldsg 0:662207e34fba 1599 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1600 * @see MPU6050_INTCFG_CLKOUT_EN_BIT
garfieldsg 0:662207e34fba 1601 */
garfieldsg 0:662207e34fba 1602 bool MPU6050::getClockOutputEnabled()
garfieldsg 0:662207e34fba 1603 {
garfieldsg 0:662207e34fba 1604 i2Cdev.readBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_CLKOUT_EN_BIT, buffer);
garfieldsg 0:662207e34fba 1605 return buffer[0];
garfieldsg 0:662207e34fba 1606 }
garfieldsg 0:662207e34fba 1607 /** Set reference clock output enabled status.
garfieldsg 0:662207e34fba 1608 * When this bit is equal to 1, a reference clock output is provided at the
garfieldsg 0:662207e34fba 1609 * CLKOUT pin. When this bit is equal to 0, the clock output is disabled. For
garfieldsg 0:662207e34fba 1610 * further information regarding CLKOUT, please refer to the MPU-60X0 Product
garfieldsg 0:662207e34fba 1611 * Specification document.
garfieldsg 0:662207e34fba 1612 * @param enabled New reference clock output enabled status
garfieldsg 0:662207e34fba 1613 * @see MPU6050_RA_INT_PIN_CFG
garfieldsg 0:662207e34fba 1614 * @see MPU6050_INTCFG_CLKOUT_EN_BIT
garfieldsg 0:662207e34fba 1615 */
garfieldsg 0:662207e34fba 1616 void MPU6050::setClockOutputEnabled(bool enabled)
garfieldsg 0:662207e34fba 1617 {
garfieldsg 0:662207e34fba 1618 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_PIN_CFG, MPU6050_INTCFG_CLKOUT_EN_BIT, enabled);
garfieldsg 0:662207e34fba 1619 }
garfieldsg 0:662207e34fba 1620
garfieldsg 0:662207e34fba 1621 // INT_ENABLE register
garfieldsg 0:662207e34fba 1622
garfieldsg 0:662207e34fba 1623 /** Get full interrupt enabled status.
garfieldsg 0:662207e34fba 1624 * Full register byte for all interrupts, for quick reading. Each bit will be
garfieldsg 0:662207e34fba 1625 * set 0 for disabled, 1 for enabled.
garfieldsg 0:662207e34fba 1626 * @return Current interrupt enabled status
garfieldsg 0:662207e34fba 1627 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1628 * @see MPU6050_INTERRUPT_FF_BIT
garfieldsg 0:662207e34fba 1629 **/
garfieldsg 0:662207e34fba 1630 uint8_t MPU6050::getIntEnabled()
garfieldsg 0:662207e34fba 1631 {
garfieldsg 0:662207e34fba 1632 i2Cdev.readByte(devAddr, MPU6050_RA_INT_ENABLE, buffer);
garfieldsg 0:662207e34fba 1633 return buffer[0];
garfieldsg 0:662207e34fba 1634 }
garfieldsg 0:662207e34fba 1635 /** Set full interrupt enabled status.
garfieldsg 0:662207e34fba 1636 * Full register byte for all interrupts, for quick reading. Each bit should be
garfieldsg 0:662207e34fba 1637 * set 0 for disabled, 1 for enabled.
garfieldsg 0:662207e34fba 1638 * @param enabled New interrupt enabled status
garfieldsg 0:662207e34fba 1639 * @see getIntFreefallEnabled()
garfieldsg 0:662207e34fba 1640 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1641 * @see MPU6050_INTERRUPT_FF_BIT
garfieldsg 0:662207e34fba 1642 **/
garfieldsg 0:662207e34fba 1643 void MPU6050::setIntEnabled(uint8_t enabled)
garfieldsg 0:662207e34fba 1644 {
garfieldsg 0:662207e34fba 1645 i2Cdev.writeByte(devAddr, MPU6050_RA_INT_ENABLE, enabled);
garfieldsg 0:662207e34fba 1646 }
garfieldsg 0:662207e34fba 1647 /** Get Free Fall interrupt enabled status.
garfieldsg 0:662207e34fba 1648 * Will be set 0 for disabled, 1 for enabled.
garfieldsg 0:662207e34fba 1649 * @return Current interrupt enabled status
garfieldsg 0:662207e34fba 1650 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1651 * @see MPU6050_INTERRUPT_FF_BIT
garfieldsg 0:662207e34fba 1652 **/
garfieldsg 0:662207e34fba 1653 bool MPU6050::getIntFreefallEnabled()
garfieldsg 0:662207e34fba 1654 {
garfieldsg 0:662207e34fba 1655 i2Cdev.readBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_FF_BIT, buffer);
garfieldsg 0:662207e34fba 1656 return buffer[0];
garfieldsg 0:662207e34fba 1657 }
garfieldsg 0:662207e34fba 1658 /** Set Free Fall interrupt enabled status.
garfieldsg 0:662207e34fba 1659 * @param enabled New interrupt enabled status
garfieldsg 0:662207e34fba 1660 * @see getIntFreefallEnabled()
garfieldsg 0:662207e34fba 1661 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1662 * @see MPU6050_INTERRUPT_FF_BIT
garfieldsg 0:662207e34fba 1663 **/
garfieldsg 0:662207e34fba 1664 void MPU6050::setIntFreefallEnabled(bool enabled)
garfieldsg 0:662207e34fba 1665 {
garfieldsg 0:662207e34fba 1666 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_FF_BIT, enabled);
garfieldsg 0:662207e34fba 1667 }
garfieldsg 0:662207e34fba 1668 /** Get Motion Detection interrupt enabled status.
garfieldsg 0:662207e34fba 1669 * Will be set 0 for disabled, 1 for enabled.
garfieldsg 0:662207e34fba 1670 * @return Current interrupt enabled status
garfieldsg 0:662207e34fba 1671 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1672 * @see MPU6050_INTERRUPT_MOT_BIT
garfieldsg 0:662207e34fba 1673 **/
garfieldsg 0:662207e34fba 1674 bool MPU6050::getIntMotionEnabled()
garfieldsg 0:662207e34fba 1675 {
garfieldsg 0:662207e34fba 1676 i2Cdev.readBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_MOT_BIT, buffer);
garfieldsg 0:662207e34fba 1677 return buffer[0];
garfieldsg 0:662207e34fba 1678 }
garfieldsg 0:662207e34fba 1679 /** Set Motion Detection interrupt enabled status.
garfieldsg 0:662207e34fba 1680 * @param enabled New interrupt enabled status
garfieldsg 0:662207e34fba 1681 * @see getIntMotionEnabled()
garfieldsg 0:662207e34fba 1682 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1683 * @see MPU6050_INTERRUPT_MOT_BIT
garfieldsg 0:662207e34fba 1684 **/
garfieldsg 0:662207e34fba 1685 void MPU6050::setIntMotionEnabled(bool enabled)
garfieldsg 0:662207e34fba 1686 {
garfieldsg 0:662207e34fba 1687 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_MOT_BIT, enabled);
garfieldsg 0:662207e34fba 1688 }
garfieldsg 0:662207e34fba 1689 /** Get Zero Motion Detection interrupt enabled status.
garfieldsg 0:662207e34fba 1690 * Will be set 0 for disabled, 1 for enabled.
garfieldsg 0:662207e34fba 1691 * @return Current interrupt enabled status
garfieldsg 0:662207e34fba 1692 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1693 * @see MPU6050_INTERRUPT_ZMOT_BIT
garfieldsg 0:662207e34fba 1694 **/
garfieldsg 0:662207e34fba 1695 bool MPU6050::getIntZeroMotionEnabled()
garfieldsg 0:662207e34fba 1696 {
garfieldsg 0:662207e34fba 1697 i2Cdev.readBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_ZMOT_BIT, buffer);
garfieldsg 0:662207e34fba 1698 return buffer[0];
garfieldsg 0:662207e34fba 1699 }
garfieldsg 0:662207e34fba 1700 /** Set Zero Motion Detection interrupt enabled status.
garfieldsg 0:662207e34fba 1701 * @param enabled New interrupt enabled status
garfieldsg 0:662207e34fba 1702 * @see getIntZeroMotionEnabled()
garfieldsg 0:662207e34fba 1703 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1704 * @see MPU6050_INTERRUPT_ZMOT_BIT
garfieldsg 0:662207e34fba 1705 **/
garfieldsg 0:662207e34fba 1706 void MPU6050::setIntZeroMotionEnabled(bool enabled)
garfieldsg 0:662207e34fba 1707 {
garfieldsg 0:662207e34fba 1708 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_ZMOT_BIT, enabled);
garfieldsg 0:662207e34fba 1709 }
garfieldsg 0:662207e34fba 1710 /** Get FIFO Buffer Overflow interrupt enabled status.
garfieldsg 0:662207e34fba 1711 * Will be set 0 for disabled, 1 for enabled.
garfieldsg 0:662207e34fba 1712 * @return Current interrupt enabled status
garfieldsg 0:662207e34fba 1713 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1714 * @see MPU6050_INTERRUPT_FIFO_OFLOW_BIT
garfieldsg 0:662207e34fba 1715 **/
garfieldsg 0:662207e34fba 1716 bool MPU6050::getIntFIFOBufferOverflowEnabled()
garfieldsg 0:662207e34fba 1717 {
garfieldsg 0:662207e34fba 1718 i2Cdev.readBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_FIFO_OFLOW_BIT, buffer);
garfieldsg 0:662207e34fba 1719 return buffer[0];
garfieldsg 0:662207e34fba 1720 }
garfieldsg 0:662207e34fba 1721 /** Set FIFO Buffer Overflow interrupt enabled status.
garfieldsg 0:662207e34fba 1722 * @param enabled New interrupt enabled status
garfieldsg 0:662207e34fba 1723 * @see getIntFIFOBufferOverflowEnabled()
garfieldsg 0:662207e34fba 1724 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1725 * @see MPU6050_INTERRUPT_FIFO_OFLOW_BIT
garfieldsg 0:662207e34fba 1726 **/
garfieldsg 0:662207e34fba 1727 void MPU6050::setIntFIFOBufferOverflowEnabled(bool enabled)
garfieldsg 0:662207e34fba 1728 {
garfieldsg 0:662207e34fba 1729 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_FIFO_OFLOW_BIT, enabled);
garfieldsg 0:662207e34fba 1730 }
garfieldsg 0:662207e34fba 1731 /** Get I2C Master interrupt enabled status.
garfieldsg 0:662207e34fba 1732 * This enables any of the I2C Master interrupt sources to generate an
garfieldsg 0:662207e34fba 1733 * interrupt. Will be set 0 for disabled, 1 for enabled.
garfieldsg 0:662207e34fba 1734 * @return Current interrupt enabled status
garfieldsg 0:662207e34fba 1735 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1736 * @see MPU6050_INTERRUPT_I2C_MST_INT_BIT
garfieldsg 0:662207e34fba 1737 **/
garfieldsg 0:662207e34fba 1738 bool MPU6050::getIntI2CMasterEnabled()
garfieldsg 0:662207e34fba 1739 {
garfieldsg 0:662207e34fba 1740 i2Cdev.readBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_I2C_MST_INT_BIT, buffer);
garfieldsg 0:662207e34fba 1741 return buffer[0];
garfieldsg 0:662207e34fba 1742 }
garfieldsg 0:662207e34fba 1743 /** Set I2C Master interrupt enabled status.
garfieldsg 0:662207e34fba 1744 * @param enabled New interrupt enabled status
garfieldsg 0:662207e34fba 1745 * @see getIntI2CMasterEnabled()
garfieldsg 0:662207e34fba 1746 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1747 * @see MPU6050_INTERRUPT_I2C_MST_INT_BIT
garfieldsg 0:662207e34fba 1748 **/
garfieldsg 0:662207e34fba 1749 void MPU6050::setIntI2CMasterEnabled(bool enabled)
garfieldsg 0:662207e34fba 1750 {
garfieldsg 0:662207e34fba 1751 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_I2C_MST_INT_BIT, enabled);
garfieldsg 0:662207e34fba 1752 }
garfieldsg 0:662207e34fba 1753 /** Get Data Ready interrupt enabled setting.
garfieldsg 0:662207e34fba 1754 * This event occurs each time a write operation to all of the sensor registers
garfieldsg 0:662207e34fba 1755 * has been completed. Will be set 0 for disabled, 1 for enabled.
garfieldsg 0:662207e34fba 1756 * @return Current interrupt enabled status
garfieldsg 0:662207e34fba 1757 * @see MPU6050_RA_INT_ENABLE
garfieldsg 0:662207e34fba 1758 * @see MPU6050_INTERRUPT_DATA_RDY_BIT
garfieldsg 0:662207e34fba 1759 */
garfieldsg 0:662207e34fba 1760 bool MPU6050::getIntDataReadyEnabled()
garfieldsg 0:662207e34fba 1761 {
garfieldsg 0:662207e34fba 1762 i2Cdev.readBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_DATA_RDY_BIT, buffer);
garfieldsg 0:662207e34fba 1763 return buffer[0];
garfieldsg 0:662207e34fba 1764 }
garfieldsg 0:662207e34fba 1765 /** Set Data Ready interrupt enabled status.
garfieldsg 0:662207e34fba 1766 * @param enabled New interrupt enabled status
garfieldsg 0:662207e34fba 1767 * @see getIntDataReadyEnabled()
garfieldsg 0:662207e34fba 1768 * @see MPU6050_RA_INT_CFG
garfieldsg 0:662207e34fba 1769 * @see MPU6050_INTERRUPT_DATA_RDY_BIT
garfieldsg 0:662207e34fba 1770 */
garfieldsg 0:662207e34fba 1771 void MPU6050::setIntDataReadyEnabled(bool enabled)
garfieldsg 0:662207e34fba 1772 {
garfieldsg 0:662207e34fba 1773 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_DATA_RDY_BIT, enabled);
garfieldsg 0:662207e34fba 1774 }
garfieldsg 0:662207e34fba 1775
garfieldsg 0:662207e34fba 1776 // INT_STATUS register
garfieldsg 0:662207e34fba 1777
garfieldsg 0:662207e34fba 1778 /** Get full set of interrupt status bits.
garfieldsg 0:662207e34fba 1779 * These bits clear to 0 after the register has been read. Very useful
garfieldsg 0:662207e34fba 1780 * for getting multiple INT statuses, since each single bit read clears
garfieldsg 0:662207e34fba 1781 * all of them because it has to read the whole byte.
garfieldsg 0:662207e34fba 1782 * @return Current interrupt status
garfieldsg 0:662207e34fba 1783 * @see MPU6050_RA_INT_STATUS
garfieldsg 0:662207e34fba 1784 */
garfieldsg 0:662207e34fba 1785 uint8_t MPU6050::getIntStatus()
garfieldsg 0:662207e34fba 1786 {
garfieldsg 0:662207e34fba 1787 i2Cdev.readByte(devAddr, MPU6050_RA_INT_STATUS, buffer);
garfieldsg 0:662207e34fba 1788 return buffer[0];
garfieldsg 0:662207e34fba 1789 }
garfieldsg 0:662207e34fba 1790 /** Get Free Fall interrupt status.
garfieldsg 0:662207e34fba 1791 * This bit automatically sets to 1 when a Free Fall interrupt has been
garfieldsg 0:662207e34fba 1792 * generated. The bit clears to 0 after the register has been read.
garfieldsg 0:662207e34fba 1793 * @return Current interrupt status
garfieldsg 0:662207e34fba 1794 * @see MPU6050_RA_INT_STATUS
garfieldsg 0:662207e34fba 1795 * @see MPU6050_INTERRUPT_FF_BIT
garfieldsg 0:662207e34fba 1796 */
garfieldsg 0:662207e34fba 1797 bool MPU6050::getIntFreefallStatus()
garfieldsg 0:662207e34fba 1798 {
garfieldsg 0:662207e34fba 1799 i2Cdev.readBit(devAddr, MPU6050_RA_INT_STATUS, MPU6050_INTERRUPT_FF_BIT, buffer);
garfieldsg 0:662207e34fba 1800 return buffer[0];
garfieldsg 0:662207e34fba 1801 }
garfieldsg 0:662207e34fba 1802 /** Get Motion Detection interrupt status.
garfieldsg 0:662207e34fba 1803 * This bit automatically sets to 1 when a Motion Detection interrupt has been
garfieldsg 0:662207e34fba 1804 * generated. The bit clears to 0 after the register has been read.
garfieldsg 0:662207e34fba 1805 * @return Current interrupt status
garfieldsg 0:662207e34fba 1806 * @see MPU6050_RA_INT_STATUS
garfieldsg 0:662207e34fba 1807 * @see MPU6050_INTERRUPT_MOT_BIT
garfieldsg 0:662207e34fba 1808 */
garfieldsg 0:662207e34fba 1809 bool MPU6050::getIntMotionStatus()
garfieldsg 0:662207e34fba 1810 {
garfieldsg 0:662207e34fba 1811 i2Cdev.readBit(devAddr, MPU6050_RA_INT_STATUS, MPU6050_INTERRUPT_MOT_BIT, buffer);
garfieldsg 0:662207e34fba 1812 return buffer[0];
garfieldsg 0:662207e34fba 1813 }
garfieldsg 0:662207e34fba 1814 /** Get Zero Motion Detection interrupt status.
garfieldsg 0:662207e34fba 1815 * This bit automatically sets to 1 when a Zero Motion Detection interrupt has
garfieldsg 0:662207e34fba 1816 * been generated. The bit clears to 0 after the register has been read.
garfieldsg 0:662207e34fba 1817 * @return Current interrupt status
garfieldsg 0:662207e34fba 1818 * @see MPU6050_RA_INT_STATUS
garfieldsg 0:662207e34fba 1819 * @see MPU6050_INTERRUPT_ZMOT_BIT
garfieldsg 0:662207e34fba 1820 */
garfieldsg 0:662207e34fba 1821 bool MPU6050::getIntZeroMotionStatus()
garfieldsg 0:662207e34fba 1822 {
garfieldsg 0:662207e34fba 1823 i2Cdev.readBit(devAddr, MPU6050_RA_INT_STATUS, MPU6050_INTERRUPT_ZMOT_BIT, buffer);
garfieldsg 0:662207e34fba 1824 return buffer[0];
garfieldsg 0:662207e34fba 1825 }
garfieldsg 0:662207e34fba 1826 /** Get FIFO Buffer Overflow interrupt status.
garfieldsg 0:662207e34fba 1827 * This bit automatically sets to 1 when a Free Fall interrupt has been
garfieldsg 0:662207e34fba 1828 * generated. The bit clears to 0 after the register has been read.
garfieldsg 0:662207e34fba 1829 * @return Current interrupt status
garfieldsg 0:662207e34fba 1830 * @see MPU6050_RA_INT_STATUS
garfieldsg 0:662207e34fba 1831 * @see MPU6050_INTERRUPT_FIFO_OFLOW_BIT
garfieldsg 0:662207e34fba 1832 */
garfieldsg 0:662207e34fba 1833 bool MPU6050::getIntFIFOBufferOverflowStatus()
garfieldsg 0:662207e34fba 1834 {
garfieldsg 0:662207e34fba 1835 i2Cdev.readBit(devAddr, MPU6050_RA_INT_STATUS, MPU6050_INTERRUPT_FIFO_OFLOW_BIT, buffer);
garfieldsg 0:662207e34fba 1836 return buffer[0];
garfieldsg 0:662207e34fba 1837 }
garfieldsg 0:662207e34fba 1838 /** Get I2C Master interrupt status.
garfieldsg 0:662207e34fba 1839 * This bit automatically sets to 1 when an I2C Master interrupt has been
garfieldsg 0:662207e34fba 1840 * generated. For a list of I2C Master interrupts, please refer to Register 54.
garfieldsg 0:662207e34fba 1841 * The bit clears to 0 after the register has been read.
garfieldsg 0:662207e34fba 1842 * @return Current interrupt status
garfieldsg 0:662207e34fba 1843 * @see MPU6050_RA_INT_STATUS
garfieldsg 0:662207e34fba 1844 * @see MPU6050_INTERRUPT_I2C_MST_INT_BIT
garfieldsg 0:662207e34fba 1845 */
garfieldsg 0:662207e34fba 1846 bool MPU6050::getIntI2CMasterStatus()
garfieldsg 0:662207e34fba 1847 {
garfieldsg 0:662207e34fba 1848 i2Cdev.readBit(devAddr, MPU6050_RA_INT_STATUS, MPU6050_INTERRUPT_I2C_MST_INT_BIT, buffer);
garfieldsg 0:662207e34fba 1849 return buffer[0];
garfieldsg 0:662207e34fba 1850 }
garfieldsg 0:662207e34fba 1851 /** Get Data Ready interrupt status.
garfieldsg 0:662207e34fba 1852 * This bit automatically sets to 1 when a Data Ready interrupt has been
garfieldsg 0:662207e34fba 1853 * generated. The bit clears to 0 after the register has been read.
garfieldsg 0:662207e34fba 1854 * @return Current interrupt status
garfieldsg 0:662207e34fba 1855 * @see MPU6050_RA_INT_STATUS
garfieldsg 0:662207e34fba 1856 * @see MPU6050_INTERRUPT_DATA_RDY_BIT
garfieldsg 0:662207e34fba 1857 */
garfieldsg 0:662207e34fba 1858 bool MPU6050::getIntDataReadyStatus()
garfieldsg 0:662207e34fba 1859 {
garfieldsg 0:662207e34fba 1860 i2Cdev.readBit(devAddr, MPU6050_RA_INT_STATUS, MPU6050_INTERRUPT_DATA_RDY_BIT, buffer);
garfieldsg 0:662207e34fba 1861 return buffer[0];
garfieldsg 0:662207e34fba 1862 }
garfieldsg 0:662207e34fba 1863
garfieldsg 0:662207e34fba 1864 // ACCEL_*OUT_* registers
garfieldsg 0:662207e34fba 1865
garfieldsg 0:662207e34fba 1866 /** Get raw 9-axis motion sensor readings (accel/gyro/compass).
garfieldsg 0:662207e34fba 1867 * FUNCTION NOT FULLY IMPLEMENTED YET.
garfieldsg 0:662207e34fba 1868 * @param ax 16-bit signed integer container for accelerometer X-axis value
garfieldsg 0:662207e34fba 1869 * @param ay 16-bit signed integer container for accelerometer Y-axis value
garfieldsg 0:662207e34fba 1870 * @param az 16-bit signed integer container for accelerometer Z-axis value
garfieldsg 0:662207e34fba 1871 * @param gx 16-bit signed integer container for gyroscope X-axis value
garfieldsg 0:662207e34fba 1872 * @param gy 16-bit signed integer container for gyroscope Y-axis value
garfieldsg 0:662207e34fba 1873 * @param gz 16-bit signed integer container for gyroscope Z-axis value
garfieldsg 0:662207e34fba 1874 * @param mx 16-bit signed integer container for magnetometer X-axis value
garfieldsg 0:662207e34fba 1875 * @param my 16-bit signed integer container for magnetometer Y-axis value
garfieldsg 0:662207e34fba 1876 * @param mz 16-bit signed integer container for magnetometer Z-axis value
garfieldsg 0:662207e34fba 1877 * @see getMotion6()
garfieldsg 0:662207e34fba 1878 * @see getAcceleration()
garfieldsg 0:662207e34fba 1879 * @see getRotation()
garfieldsg 0:662207e34fba 1880 * @see MPU6050_RA_ACCEL_XOUT_H
garfieldsg 0:662207e34fba 1881 */
garfieldsg 0:662207e34fba 1882 void MPU6050::getMotion9(int16_t* ax, int16_t* ay, int16_t* az, int16_t* gx, int16_t* gy, int16_t* gz, int16_t* mx, int16_t* my, int16_t* mz)
garfieldsg 0:662207e34fba 1883 {
garfieldsg 0:662207e34fba 1884 getMotion6(ax, ay, az, gx, gy, gz);
akode 2:f8bfb37b2e1f 1885
akode 2:f8bfb37b2e1f 1886 // magnetometer reading
akode 2:f8bfb37b2e1f 1887 i2Cdev.writeByte(devAddr, MPU6050_RA_INT_PIN_CFG, 0x02); //set i2c bypass enable pin to true to access magnetometer
akode 2:f8bfb37b2e1f 1888 wait_ms(10); // necessary wait >=6ms
akode 2:f8bfb37b2e1f 1889 i2Cdev.writeByte(MPU9150_RA_MAG_ADDRESS, 0x0A, 0x01); // enable the magnetometer
akode 2:f8bfb37b2e1f 1890 wait_ms(10); // necessary wait >=6ms
akode 2:f8bfb37b2e1f 1891 i2Cdev.readBytes(MPU9150_RA_MAG_ADDRESS, MPU9150_RA_MAG_XOUT_L, 6, buffer);
akode 2:f8bfb37b2e1f 1892 *mx = (((int16_t)buffer[0]) << 8) | buffer[1];
akode 2:f8bfb37b2e1f 1893 *my = (((int16_t)buffer[2]) << 8) | buffer[3];
akode 2:f8bfb37b2e1f 1894 *mz = (((int16_t)buffer[4]) << 8) | buffer[5];
garfieldsg 0:662207e34fba 1895 }
garfieldsg 0:662207e34fba 1896 /** Get raw 6-axis motion sensor readings (accel/gyro).
garfieldsg 0:662207e34fba 1897 * Retrieves all currently available motion sensor values.
garfieldsg 0:662207e34fba 1898 * @param ax 16-bit signed integer container for accelerometer X-axis value
garfieldsg 0:662207e34fba 1899 * @param ay 16-bit signed integer container for accelerometer Y-axis value
garfieldsg 0:662207e34fba 1900 * @param az 16-bit signed integer container for accelerometer Z-axis value
garfieldsg 0:662207e34fba 1901 * @param gx 16-bit signed integer container for gyroscope X-axis value
garfieldsg 0:662207e34fba 1902 * @param gy 16-bit signed integer container for gyroscope Y-axis value
garfieldsg 0:662207e34fba 1903 * @param gz 16-bit signed integer container for gyroscope Z-axis value
garfieldsg 0:662207e34fba 1904 * @see getAcceleration()
garfieldsg 0:662207e34fba 1905 * @see getRotation()
garfieldsg 0:662207e34fba 1906 * @see MPU6050_RA_ACCEL_XOUT_H
garfieldsg 0:662207e34fba 1907 */
garfieldsg 0:662207e34fba 1908 void MPU6050::getMotion6(int16_t* ax, int16_t* ay, int16_t* az, int16_t* gx, int16_t* gy, int16_t* gz)
garfieldsg 0:662207e34fba 1909 {
garfieldsg 0:662207e34fba 1910 i2Cdev.readBytes(devAddr, MPU6050_RA_ACCEL_XOUT_H, 14, buffer);
garfieldsg 0:662207e34fba 1911 *ax = (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 1912 *ay = (((int16_t)buffer[2]) << 8) | buffer[3];
garfieldsg 0:662207e34fba 1913 *az = (((int16_t)buffer[4]) << 8) | buffer[5];
garfieldsg 0:662207e34fba 1914 *gx = (((int16_t)buffer[8]) << 8) | buffer[9];
garfieldsg 0:662207e34fba 1915 *gy = (((int16_t)buffer[10]) << 8) | buffer[11];
garfieldsg 0:662207e34fba 1916 *gz = (((int16_t)buffer[12]) << 8) | buffer[13];
garfieldsg 0:662207e34fba 1917 }
garfieldsg 0:662207e34fba 1918 /** Get 3-axis accelerometer readings.
garfieldsg 0:662207e34fba 1919 * These registers store the most recent accelerometer measurements.
garfieldsg 0:662207e34fba 1920 * Accelerometer measurements are written to these registers at the Sample Rate
garfieldsg 0:662207e34fba 1921 * as defined in Register 25.
garfieldsg 0:662207e34fba 1922 *
garfieldsg 0:662207e34fba 1923 * The accelerometer measurement registers, along with the temperature
garfieldsg 0:662207e34fba 1924 * measurement registers, gyroscope measurement registers, and external sensor
garfieldsg 0:662207e34fba 1925 * data registers, are composed of two sets of registers: an internal register
garfieldsg 0:662207e34fba 1926 * set and a user-facing read register set.
garfieldsg 0:662207e34fba 1927 *
garfieldsg 0:662207e34fba 1928 * The data within the accelerometer sensors' internal register set is always
garfieldsg 0:662207e34fba 1929 * updated at the Sample Rate. Meanwhile, the user-facing read register set
garfieldsg 0:662207e34fba 1930 * duplicates the internal register set's data values whenever the serial
garfieldsg 0:662207e34fba 1931 * interface is idle. This guarantees that a burst read of sensor registers will
garfieldsg 0:662207e34fba 1932 * read measurements from the same sampling instant. Note that if burst reads
garfieldsg 0:662207e34fba 1933 * are not used, the user is responsible for ensuring a set of single byte reads
garfieldsg 0:662207e34fba 1934 * correspond to a single sampling instant by checking the Data Ready interrupt.
garfieldsg 0:662207e34fba 1935 *
garfieldsg 0:662207e34fba 1936 * Each 16-bit accelerometer measurement has a full scale defined in ACCEL_FS
garfieldsg 0:662207e34fba 1937 * (Register 28). For each full scale setting, the accelerometers' sensitivity
garfieldsg 0:662207e34fba 1938 * per LSB in ACCEL_xOUT is shown in the table below:
garfieldsg 0:662207e34fba 1939 *
garfieldsg 0:662207e34fba 1940 * <pre>
garfieldsg 0:662207e34fba 1941 * AFS_SEL | Full Scale Range | LSB Sensitivity
garfieldsg 0:662207e34fba 1942 * --------+------------------+----------------
garfieldsg 0:662207e34fba 1943 * 0 | +/- 2g | 8192 LSB/mg
garfieldsg 0:662207e34fba 1944 * 1 | +/- 4g | 4096 LSB/mg
garfieldsg 0:662207e34fba 1945 * 2 | +/- 8g | 2048 LSB/mg
garfieldsg 0:662207e34fba 1946 * 3 | +/- 16g | 1024 LSB/mg
garfieldsg 0:662207e34fba 1947 * </pre>
garfieldsg 0:662207e34fba 1948 *
garfieldsg 0:662207e34fba 1949 * @param x 16-bit signed integer container for X-axis acceleration
garfieldsg 0:662207e34fba 1950 * @param y 16-bit signed integer container for Y-axis acceleration
garfieldsg 0:662207e34fba 1951 * @param z 16-bit signed integer container for Z-axis acceleration
garfieldsg 0:662207e34fba 1952 * @see MPU6050_RA_GYRO_XOUT_H
garfieldsg 0:662207e34fba 1953 */
garfieldsg 0:662207e34fba 1954 void MPU6050::getAcceleration(int16_t* x, int16_t* y, int16_t* z)
garfieldsg 0:662207e34fba 1955 {
garfieldsg 0:662207e34fba 1956 i2Cdev.readBytes(devAddr, MPU6050_RA_ACCEL_XOUT_H, 6, buffer);
garfieldsg 0:662207e34fba 1957 *x = (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 1958 *y = (((int16_t)buffer[2]) << 8) | buffer[3];
garfieldsg 0:662207e34fba 1959 *z = (((int16_t)buffer[4]) << 8) | buffer[5];
garfieldsg 0:662207e34fba 1960 }
garfieldsg 0:662207e34fba 1961 /** Get X-axis accelerometer reading.
garfieldsg 0:662207e34fba 1962 * @return X-axis acceleration measurement in 16-bit 2's complement format
garfieldsg 0:662207e34fba 1963 * @see getMotion6()
garfieldsg 0:662207e34fba 1964 * @see MPU6050_RA_ACCEL_XOUT_H
garfieldsg 0:662207e34fba 1965 */
garfieldsg 0:662207e34fba 1966 int16_t MPU6050::getAccelerationX()
garfieldsg 0:662207e34fba 1967 {
garfieldsg 0:662207e34fba 1968 i2Cdev.readBytes(devAddr, MPU6050_RA_ACCEL_XOUT_H, 2, buffer);
garfieldsg 0:662207e34fba 1969 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 1970 }
garfieldsg 0:662207e34fba 1971 /** Get Y-axis accelerometer reading.
garfieldsg 0:662207e34fba 1972 * @return Y-axis acceleration measurement in 16-bit 2's complement format
garfieldsg 0:662207e34fba 1973 * @see getMotion6()
garfieldsg 0:662207e34fba 1974 * @see MPU6050_RA_ACCEL_YOUT_H
garfieldsg 0:662207e34fba 1975 */
garfieldsg 0:662207e34fba 1976 int16_t MPU6050::getAccelerationY()
garfieldsg 0:662207e34fba 1977 {
garfieldsg 0:662207e34fba 1978 i2Cdev.readBytes(devAddr, MPU6050_RA_ACCEL_YOUT_H, 2, buffer);
garfieldsg 0:662207e34fba 1979 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 1980 }
garfieldsg 0:662207e34fba 1981 /** Get Z-axis accelerometer reading.
garfieldsg 0:662207e34fba 1982 * @return Z-axis acceleration measurement in 16-bit 2's complement format
garfieldsg 0:662207e34fba 1983 * @see getMotion6()
garfieldsg 0:662207e34fba 1984 * @see MPU6050_RA_ACCEL_ZOUT_H
garfieldsg 0:662207e34fba 1985 */
garfieldsg 0:662207e34fba 1986 int16_t MPU6050::getAccelerationZ()
garfieldsg 0:662207e34fba 1987 {
garfieldsg 0:662207e34fba 1988 i2Cdev.readBytes(devAddr, MPU6050_RA_ACCEL_ZOUT_H, 2, buffer);
garfieldsg 0:662207e34fba 1989 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 1990 }
garfieldsg 0:662207e34fba 1991
garfieldsg 0:662207e34fba 1992 // TEMP_OUT_* registers
garfieldsg 0:662207e34fba 1993
garfieldsg 0:662207e34fba 1994 /** Get current internal temperature.
garfieldsg 0:662207e34fba 1995 * @return Temperature reading in 16-bit 2's complement format
garfieldsg 0:662207e34fba 1996 * @see MPU6050_RA_TEMP_OUT_H
garfieldsg 0:662207e34fba 1997 */
garfieldsg 0:662207e34fba 1998 int16_t MPU6050::getTemperature()
garfieldsg 0:662207e34fba 1999 {
garfieldsg 0:662207e34fba 2000 i2Cdev.readBytes(devAddr, MPU6050_RA_TEMP_OUT_H, 2, buffer);
garfieldsg 0:662207e34fba 2001 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 2002 }
garfieldsg 0:662207e34fba 2003
garfieldsg 0:662207e34fba 2004 // GYRO_*OUT_* registers
garfieldsg 0:662207e34fba 2005
garfieldsg 0:662207e34fba 2006 /** Get 3-axis gyroscope readings.
garfieldsg 0:662207e34fba 2007 * These gyroscope measurement registers, along with the accelerometer
garfieldsg 0:662207e34fba 2008 * measurement registers, temperature measurement registers, and external sensor
garfieldsg 0:662207e34fba 2009 * data registers, are composed of two sets of registers: an internal register
garfieldsg 0:662207e34fba 2010 * set and a user-facing read register set.
garfieldsg 0:662207e34fba 2011 * The data within the gyroscope sensors' internal register set is always
garfieldsg 0:662207e34fba 2012 * updated at the Sample Rate. Meanwhile, the user-facing read register set
garfieldsg 0:662207e34fba 2013 * duplicates the internal register set's data values whenever the serial
garfieldsg 0:662207e34fba 2014 * interface is idle. This guarantees that a burst read of sensor registers will
garfieldsg 0:662207e34fba 2015 * read measurements from the same sampling instant. Note that if burst reads
garfieldsg 0:662207e34fba 2016 * are not used, the user is responsible for ensuring a set of single byte reads
garfieldsg 0:662207e34fba 2017 * correspond to a single sampling instant by checking the Data Ready interrupt.
garfieldsg 0:662207e34fba 2018 *
garfieldsg 0:662207e34fba 2019 * Each 16-bit gyroscope measurement has a full scale defined in FS_SEL
garfieldsg 0:662207e34fba 2020 * (Register 27). For each full scale setting, the gyroscopes' sensitivity per
garfieldsg 0:662207e34fba 2021 * LSB in GYRO_xOUT is shown in the table below:
garfieldsg 0:662207e34fba 2022 *
garfieldsg 0:662207e34fba 2023 * <pre>
garfieldsg 0:662207e34fba 2024 * FS_SEL | Full Scale Range | LSB Sensitivity
garfieldsg 0:662207e34fba 2025 * -------+--------------------+----------------
garfieldsg 0:662207e34fba 2026 * 0 | +/- 250 degrees/s | 131 LSB/deg/s
garfieldsg 0:662207e34fba 2027 * 1 | +/- 500 degrees/s | 65.5 LSB/deg/s
garfieldsg 0:662207e34fba 2028 * 2 | +/- 1000 degrees/s | 32.8 LSB/deg/s
garfieldsg 0:662207e34fba 2029 * 3 | +/- 2000 degrees/s | 16.4 LSB/deg/s
garfieldsg 0:662207e34fba 2030 * </pre>
garfieldsg 0:662207e34fba 2031 *
garfieldsg 0:662207e34fba 2032 * @param x 16-bit signed integer container for X-axis rotation
garfieldsg 0:662207e34fba 2033 * @param y 16-bit signed integer container for Y-axis rotation
garfieldsg 0:662207e34fba 2034 * @param z 16-bit signed integer container for Z-axis rotation
garfieldsg 0:662207e34fba 2035 * @see getMotion6()
garfieldsg 0:662207e34fba 2036 * @see MPU6050_RA_GYRO_XOUT_H
garfieldsg 0:662207e34fba 2037 */
garfieldsg 0:662207e34fba 2038 void MPU6050::getRotation(int16_t* x, int16_t* y, int16_t* z)
garfieldsg 0:662207e34fba 2039 {
garfieldsg 0:662207e34fba 2040 i2Cdev.readBytes(devAddr, MPU6050_RA_GYRO_XOUT_H, 6, buffer);
garfieldsg 0:662207e34fba 2041 *x = (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 2042 *y = (((int16_t)buffer[2]) << 8) | buffer[3];
garfieldsg 0:662207e34fba 2043 *z = (((int16_t)buffer[4]) << 8) | buffer[5];
garfieldsg 0:662207e34fba 2044 }
garfieldsg 0:662207e34fba 2045 /** Get X-axis gyroscope reading.
garfieldsg 0:662207e34fba 2046 * @return X-axis rotation measurement in 16-bit 2's complement format
garfieldsg 0:662207e34fba 2047 * @see getMotion6()
garfieldsg 0:662207e34fba 2048 * @see MPU6050_RA_GYRO_XOUT_H
garfieldsg 0:662207e34fba 2049 */
garfieldsg 0:662207e34fba 2050 int16_t MPU6050::getRotationX()
garfieldsg 0:662207e34fba 2051 {
garfieldsg 0:662207e34fba 2052 i2Cdev.readBytes(devAddr, MPU6050_RA_GYRO_XOUT_H, 2, buffer);
garfieldsg 0:662207e34fba 2053 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 2054 }
garfieldsg 0:662207e34fba 2055 /** Get Y-axis gyroscope reading.
garfieldsg 0:662207e34fba 2056 * @return Y-axis rotation measurement in 16-bit 2's complement format
garfieldsg 0:662207e34fba 2057 * @see getMotion6()
garfieldsg 0:662207e34fba 2058 * @see MPU6050_RA_GYRO_YOUT_H
garfieldsg 0:662207e34fba 2059 */
garfieldsg 0:662207e34fba 2060 int16_t MPU6050::getRotationY()
garfieldsg 0:662207e34fba 2061 {
garfieldsg 0:662207e34fba 2062 i2Cdev.readBytes(devAddr, MPU6050_RA_GYRO_YOUT_H, 2, buffer);
garfieldsg 0:662207e34fba 2063 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 2064 }
garfieldsg 0:662207e34fba 2065 /** Get Z-axis gyroscope reading.
garfieldsg 0:662207e34fba 2066 * @return Z-axis rotation measurement in 16-bit 2's complement format
garfieldsg 0:662207e34fba 2067 * @see getMotion6()
garfieldsg 0:662207e34fba 2068 * @see MPU6050_RA_GYRO_ZOUT_H
garfieldsg 0:662207e34fba 2069 */
garfieldsg 0:662207e34fba 2070 int16_t MPU6050::getRotationZ()
garfieldsg 0:662207e34fba 2071 {
garfieldsg 0:662207e34fba 2072 i2Cdev.readBytes(devAddr, MPU6050_RA_GYRO_ZOUT_H, 2, buffer);
garfieldsg 0:662207e34fba 2073 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 2074 }
garfieldsg 0:662207e34fba 2075
garfieldsg 0:662207e34fba 2076 // EXT_SENS_DATA_* registers
garfieldsg 0:662207e34fba 2077
garfieldsg 0:662207e34fba 2078 /** Read single byte from external sensor data register.
garfieldsg 0:662207e34fba 2079 * These registers store data read from external sensors by the Slave 0, 1, 2,
garfieldsg 0:662207e34fba 2080 * and 3 on the auxiliary I2C interface. Data read by Slave 4 is stored in
garfieldsg 0:662207e34fba 2081 * I2C_SLV4_DI (Register 53).
garfieldsg 0:662207e34fba 2082 *
garfieldsg 0:662207e34fba 2083 * External sensor data is written to these registers at the Sample Rate as
garfieldsg 0:662207e34fba 2084 * defined in Register 25. This access rate can be reduced by using the Slave
garfieldsg 0:662207e34fba 2085 * Delay Enable registers (Register 103).
garfieldsg 0:662207e34fba 2086 *
garfieldsg 0:662207e34fba 2087 * External sensor data registers, along with the gyroscope measurement
garfieldsg 0:662207e34fba 2088 * registers, accelerometer measurement registers, and temperature measurement
garfieldsg 0:662207e34fba 2089 * registers, are composed of two sets of registers: an internal register set
garfieldsg 0:662207e34fba 2090 * and a user-facing read register set.
garfieldsg 0:662207e34fba 2091 *
garfieldsg 0:662207e34fba 2092 * The data within the external sensors' internal register set is always updated
garfieldsg 0:662207e34fba 2093 * at the Sample Rate (or the reduced access rate) whenever the serial interface
garfieldsg 0:662207e34fba 2094 * is idle. This guarantees that a burst read of sensor registers will read
garfieldsg 0:662207e34fba 2095 * measurements from the same sampling instant. Note that if burst reads are not
garfieldsg 0:662207e34fba 2096 * used, the user is responsible for ensuring a set of single byte reads
garfieldsg 0:662207e34fba 2097 * correspond to a single sampling instant by checking the Data Ready interrupt.
garfieldsg 0:662207e34fba 2098 *
garfieldsg 0:662207e34fba 2099 * Data is placed in these external sensor data registers according to
garfieldsg 0:662207e34fba 2100 * I2C_SLV0_CTRL, I2C_SLV1_CTRL, I2C_SLV2_CTRL, and I2C_SLV3_CTRL (Registers 39,
garfieldsg 0:662207e34fba 2101 * 42, 45, and 48). When more than zero bytes are read (I2C_SLVx_LEN > 0) from
garfieldsg 0:662207e34fba 2102 * an enabled slave (I2C_SLVx_EN = 1), the slave is read at the Sample Rate (as
garfieldsg 0:662207e34fba 2103 * defined in Register 25) or delayed rate (if specified in Register 52 and
garfieldsg 0:662207e34fba 2104 * 103). During each Sample cycle, slave reads are performed in order of Slave
garfieldsg 0:662207e34fba 2105 * number. If all slaves are enabled with more than zero bytes to be read, the
garfieldsg 0:662207e34fba 2106 * order will be Slave 0, followed by Slave 1, Slave 2, and Slave 3.
garfieldsg 0:662207e34fba 2107 *
garfieldsg 0:662207e34fba 2108 * Each enabled slave will have EXT_SENS_DATA registers associated with it by
garfieldsg 0:662207e34fba 2109 * number of bytes read (I2C_SLVx_LEN) in order of slave number, starting from
garfieldsg 0:662207e34fba 2110 * EXT_SENS_DATA_00. Note that this means enabling or disabling a slave may
garfieldsg 0:662207e34fba 2111 * change the higher numbered slaves' associated registers. Furthermore, if
garfieldsg 0:662207e34fba 2112 * fewer total bytes are being read from the external sensors as a result of
garfieldsg 0:662207e34fba 2113 * such a change, then the data remaining in the registers which no longer have
garfieldsg 0:662207e34fba 2114 * an associated slave device (i.e. high numbered registers) will remain in
garfieldsg 0:662207e34fba 2115 * these previously allocated registers unless reset.
garfieldsg 0:662207e34fba 2116 *
garfieldsg 0:662207e34fba 2117 * If the sum of the read lengths of all SLVx transactions exceed the number of
garfieldsg 0:662207e34fba 2118 * available EXT_SENS_DATA registers, the excess bytes will be dropped. There
garfieldsg 0:662207e34fba 2119 * are 24 EXT_SENS_DATA registers and hence the total read lengths between all
garfieldsg 0:662207e34fba 2120 * the slaves cannot be greater than 24 or some bytes will be lost.
garfieldsg 0:662207e34fba 2121 *
garfieldsg 0:662207e34fba 2122 * Note: Slave 4's behavior is distinct from that of Slaves 0-3. For further
garfieldsg 0:662207e34fba 2123 * information regarding the characteristics of Slave 4, please refer to
garfieldsg 0:662207e34fba 2124 * Registers 49 to 53.
garfieldsg 0:662207e34fba 2125 *
garfieldsg 0:662207e34fba 2126 * EXAMPLE:
garfieldsg 0:662207e34fba 2127 * Suppose that Slave 0 is enabled with 4 bytes to be read (I2C_SLV0_EN = 1 and
garfieldsg 0:662207e34fba 2128 * I2C_SLV0_LEN = 4) while Slave 1 is enabled with 2 bytes to be read so that
garfieldsg 0:662207e34fba 2129 * I2C_SLV1_EN = 1 and I2C_SLV1_LEN = 2. In such a situation, EXT_SENS_DATA _00
garfieldsg 0:662207e34fba 2130 * through _03 will be associated with Slave 0, while EXT_SENS_DATA _04 and 05
garfieldsg 0:662207e34fba 2131 * will be associated with Slave 1. If Slave 2 is enabled as well, registers
garfieldsg 0:662207e34fba 2132 * starting from EXT_SENS_DATA_06 will be allocated to Slave 2.
garfieldsg 0:662207e34fba 2133 *
garfieldsg 0:662207e34fba 2134 * If Slave 2 is disabled while Slave 3 is enabled in this same situation, then
garfieldsg 0:662207e34fba 2135 * registers starting from EXT_SENS_DATA_06 will be allocated to Slave 3
garfieldsg 0:662207e34fba 2136 * instead.
garfieldsg 0:662207e34fba 2137 *
garfieldsg 0:662207e34fba 2138 * REGISTER ALLOCATION FOR DYNAMIC DISABLE VS. NORMAL DISABLE:
garfieldsg 0:662207e34fba 2139 * If a slave is disabled at any time, the space initially allocated to the
garfieldsg 0:662207e34fba 2140 * slave in the EXT_SENS_DATA register, will remain associated with that slave.
garfieldsg 0:662207e34fba 2141 * This is to avoid dynamic adjustment of the register allocation.
garfieldsg 0:662207e34fba 2142 *
garfieldsg 0:662207e34fba 2143 * The allocation of the EXT_SENS_DATA registers is recomputed only when (1) all
garfieldsg 0:662207e34fba 2144 * slaves are disabled, or (2) the I2C_MST_RST bit is set (Register 106).
garfieldsg 0:662207e34fba 2145 *
garfieldsg 0:662207e34fba 2146 * This above is also true if one of the slaves gets NACKed and stops
garfieldsg 0:662207e34fba 2147 * functioning.
garfieldsg 0:662207e34fba 2148 *
garfieldsg 0:662207e34fba 2149 * @param position Starting position (0-23)
garfieldsg 0:662207e34fba 2150 * @return Byte read from register
garfieldsg 0:662207e34fba 2151 */
garfieldsg 0:662207e34fba 2152 uint8_t MPU6050::getExternalSensorByte(int position)
garfieldsg 0:662207e34fba 2153 {
garfieldsg 0:662207e34fba 2154 i2Cdev.readByte(devAddr, MPU6050_RA_EXT_SENS_DATA_00 + position, buffer);
garfieldsg 0:662207e34fba 2155 return buffer[0];
garfieldsg 0:662207e34fba 2156 }
garfieldsg 0:662207e34fba 2157 /** Read word (2 bytes) from external sensor data registers.
garfieldsg 0:662207e34fba 2158 * @param position Starting position (0-21)
garfieldsg 0:662207e34fba 2159 * @return Word read from register
garfieldsg 0:662207e34fba 2160 * @see getExternalSensorByte()
garfieldsg 0:662207e34fba 2161 */
garfieldsg 0:662207e34fba 2162 uint16_t MPU6050::getExternalSensorWord(int position)
garfieldsg 0:662207e34fba 2163 {
garfieldsg 0:662207e34fba 2164 i2Cdev.readBytes(devAddr, MPU6050_RA_EXT_SENS_DATA_00 + position, 2, buffer);
garfieldsg 0:662207e34fba 2165 return (((uint16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 2166 }
garfieldsg 0:662207e34fba 2167 /** Read double word (4 bytes) from external sensor data registers.
garfieldsg 0:662207e34fba 2168 * @param position Starting position (0-20)
garfieldsg 0:662207e34fba 2169 * @return Double word read from registers
garfieldsg 0:662207e34fba 2170 * @see getExternalSensorByte()
garfieldsg 0:662207e34fba 2171 */
garfieldsg 0:662207e34fba 2172 uint32_t MPU6050::getExternalSensorDWord(int position)
garfieldsg 0:662207e34fba 2173 {
garfieldsg 0:662207e34fba 2174 i2Cdev.readBytes(devAddr, MPU6050_RA_EXT_SENS_DATA_00 + position, 4, buffer);
garfieldsg 0:662207e34fba 2175 return (((uint32_t)buffer[0]) << 24) | (((uint32_t)buffer[1]) << 16) | (((uint16_t)buffer[2]) << 8) | buffer[3];
garfieldsg 0:662207e34fba 2176 }
garfieldsg 0:662207e34fba 2177
garfieldsg 0:662207e34fba 2178 // MOT_DETECT_STATUS register
garfieldsg 0:662207e34fba 2179
garfieldsg 0:662207e34fba 2180 /** Get X-axis negative motion detection interrupt status.
garfieldsg 0:662207e34fba 2181 * @return Motion detection status
garfieldsg 0:662207e34fba 2182 * @see MPU6050_RA_MOT_DETECT_STATUS
garfieldsg 0:662207e34fba 2183 * @see MPU6050_MOTION_MOT_XNEG_BIT
garfieldsg 0:662207e34fba 2184 */
garfieldsg 0:662207e34fba 2185 bool MPU6050::getXNegMotionDetected()
garfieldsg 0:662207e34fba 2186 {
garfieldsg 0:662207e34fba 2187 i2Cdev.readBit(devAddr, MPU6050_RA_MOT_DETECT_STATUS, MPU6050_MOTION_MOT_XNEG_BIT, buffer);
garfieldsg 0:662207e34fba 2188 return buffer[0];
garfieldsg 0:662207e34fba 2189 }
garfieldsg 0:662207e34fba 2190 /** Get X-axis positive motion detection interrupt status.
garfieldsg 0:662207e34fba 2191 * @return Motion detection status
garfieldsg 0:662207e34fba 2192 * @see MPU6050_RA_MOT_DETECT_STATUS
garfieldsg 0:662207e34fba 2193 * @see MPU6050_MOTION_MOT_XPOS_BIT
garfieldsg 0:662207e34fba 2194 */
garfieldsg 0:662207e34fba 2195 bool MPU6050::getXPosMotionDetected()
garfieldsg 0:662207e34fba 2196 {
garfieldsg 0:662207e34fba 2197 i2Cdev.readBit(devAddr, MPU6050_RA_MOT_DETECT_STATUS, MPU6050_MOTION_MOT_XPOS_BIT, buffer);
garfieldsg 0:662207e34fba 2198 return buffer[0];
garfieldsg 0:662207e34fba 2199 }
garfieldsg 0:662207e34fba 2200 /** Get Y-axis negative motion detection interrupt status.
garfieldsg 0:662207e34fba 2201 * @return Motion detection status
garfieldsg 0:662207e34fba 2202 * @see MPU6050_RA_MOT_DETECT_STATUS
garfieldsg 0:662207e34fba 2203 * @see MPU6050_MOTION_MOT_YNEG_BIT
garfieldsg 0:662207e34fba 2204 */
garfieldsg 0:662207e34fba 2205 bool MPU6050::getYNegMotionDetected()
garfieldsg 0:662207e34fba 2206 {
garfieldsg 0:662207e34fba 2207 i2Cdev.readBit(devAddr, MPU6050_RA_MOT_DETECT_STATUS, MPU6050_MOTION_MOT_YNEG_BIT, buffer);
garfieldsg 0:662207e34fba 2208 return buffer[0];
garfieldsg 0:662207e34fba 2209 }
garfieldsg 0:662207e34fba 2210 /** Get Y-axis positive motion detection interrupt status.
garfieldsg 0:662207e34fba 2211 * @return Motion detection status
garfieldsg 0:662207e34fba 2212 * @see MPU6050_RA_MOT_DETECT_STATUS
garfieldsg 0:662207e34fba 2213 * @see MPU6050_MOTION_MOT_YPOS_BIT
garfieldsg 0:662207e34fba 2214 */
garfieldsg 0:662207e34fba 2215 bool MPU6050::getYPosMotionDetected()
garfieldsg 0:662207e34fba 2216 {
garfieldsg 0:662207e34fba 2217 i2Cdev.readBit(devAddr, MPU6050_RA_MOT_DETECT_STATUS, MPU6050_MOTION_MOT_YPOS_BIT, buffer);
garfieldsg 0:662207e34fba 2218 return buffer[0];
garfieldsg 0:662207e34fba 2219 }
garfieldsg 0:662207e34fba 2220 /** Get Z-axis negative motion detection interrupt status.
garfieldsg 0:662207e34fba 2221 * @return Motion detection status
garfieldsg 0:662207e34fba 2222 * @see MPU6050_RA_MOT_DETECT_STATUS
garfieldsg 0:662207e34fba 2223 * @see MPU6050_MOTION_MOT_ZNEG_BIT
garfieldsg 0:662207e34fba 2224 */
garfieldsg 0:662207e34fba 2225 bool MPU6050::getZNegMotionDetected()
garfieldsg 0:662207e34fba 2226 {
garfieldsg 0:662207e34fba 2227 i2Cdev.readBit(devAddr, MPU6050_RA_MOT_DETECT_STATUS, MPU6050_MOTION_MOT_ZNEG_BIT, buffer);
garfieldsg 0:662207e34fba 2228 return buffer[0];
garfieldsg 0:662207e34fba 2229 }
garfieldsg 0:662207e34fba 2230 /** Get Z-axis positive motion detection interrupt status.
garfieldsg 0:662207e34fba 2231 * @return Motion detection status
garfieldsg 0:662207e34fba 2232 * @see MPU6050_RA_MOT_DETECT_STATUS
garfieldsg 0:662207e34fba 2233 * @see MPU6050_MOTION_MOT_ZPOS_BIT
garfieldsg 0:662207e34fba 2234 */
garfieldsg 0:662207e34fba 2235 bool MPU6050::getZPosMotionDetected()
garfieldsg 0:662207e34fba 2236 {
garfieldsg 0:662207e34fba 2237 i2Cdev.readBit(devAddr, MPU6050_RA_MOT_DETECT_STATUS, MPU6050_MOTION_MOT_ZPOS_BIT, buffer);
garfieldsg 0:662207e34fba 2238 return buffer[0];
garfieldsg 0:662207e34fba 2239 }
garfieldsg 0:662207e34fba 2240 /** Get zero motion detection interrupt status.
garfieldsg 0:662207e34fba 2241 * @return Motion detection status
garfieldsg 0:662207e34fba 2242 * @see MPU6050_RA_MOT_DETECT_STATUS
garfieldsg 0:662207e34fba 2243 * @see MPU6050_MOTION_MOT_ZRMOT_BIT
garfieldsg 0:662207e34fba 2244 */
garfieldsg 0:662207e34fba 2245 bool MPU6050::getZeroMotionDetected()
garfieldsg 0:662207e34fba 2246 {
garfieldsg 0:662207e34fba 2247 i2Cdev.readBit(devAddr, MPU6050_RA_MOT_DETECT_STATUS, MPU6050_MOTION_MOT_ZRMOT_BIT, buffer);
garfieldsg 0:662207e34fba 2248 return buffer[0];
garfieldsg 0:662207e34fba 2249 }
garfieldsg 0:662207e34fba 2250
garfieldsg 0:662207e34fba 2251 // I2C_SLV*_DO register
garfieldsg 0:662207e34fba 2252
garfieldsg 0:662207e34fba 2253 /** Write byte to Data Output container for specified slave.
garfieldsg 0:662207e34fba 2254 * This register holds the output data written into Slave when Slave is set to
garfieldsg 0:662207e34fba 2255 * write mode. For further information regarding Slave control, please
garfieldsg 0:662207e34fba 2256 * refer to Registers 37 to 39 and immediately following.
garfieldsg 0:662207e34fba 2257 * @param num Slave number (0-3)
garfieldsg 0:662207e34fba 2258 * @param data Byte to write
garfieldsg 0:662207e34fba 2259 * @see MPU6050_RA_I2C_SLV0_DO
garfieldsg 0:662207e34fba 2260 */
garfieldsg 0:662207e34fba 2261 void MPU6050::setSlaveOutputByte(uint8_t num, uint8_t data)
garfieldsg 0:662207e34fba 2262 {
garfieldsg 0:662207e34fba 2263 if (num > 3) return;
garfieldsg 0:662207e34fba 2264 i2Cdev.writeByte(devAddr, MPU6050_RA_I2C_SLV0_DO + num, data);
garfieldsg 0:662207e34fba 2265 }
garfieldsg 0:662207e34fba 2266
garfieldsg 0:662207e34fba 2267 // I2C_MST_DELAY_CTRL register
garfieldsg 0:662207e34fba 2268
garfieldsg 0:662207e34fba 2269 /** Get external data shadow delay enabled status.
garfieldsg 0:662207e34fba 2270 * This register is used to specify the timing of external sensor data
garfieldsg 0:662207e34fba 2271 * shadowing. When DELAY_ES_SHADOW is set to 1, shadowing of external
garfieldsg 0:662207e34fba 2272 * sensor data is delayed until all data has been received.
garfieldsg 0:662207e34fba 2273 * @return Current external data shadow delay enabled status.
garfieldsg 0:662207e34fba 2274 * @see MPU6050_RA_I2C_MST_DELAY_CTRL
garfieldsg 0:662207e34fba 2275 * @see MPU6050_DELAYCTRL_DELAY_ES_SHADOW_BIT
garfieldsg 0:662207e34fba 2276 */
garfieldsg 0:662207e34fba 2277 bool MPU6050::getExternalShadowDelayEnabled()
garfieldsg 0:662207e34fba 2278 {
garfieldsg 0:662207e34fba 2279 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_DELAY_CTRL, MPU6050_DELAYCTRL_DELAY_ES_SHADOW_BIT, buffer);
garfieldsg 0:662207e34fba 2280 return buffer[0];
garfieldsg 0:662207e34fba 2281 }
garfieldsg 0:662207e34fba 2282 /** Set external data shadow delay enabled status.
garfieldsg 0:662207e34fba 2283 * @param enabled New external data shadow delay enabled status.
garfieldsg 0:662207e34fba 2284 * @see getExternalShadowDelayEnabled()
garfieldsg 0:662207e34fba 2285 * @see MPU6050_RA_I2C_MST_DELAY_CTRL
garfieldsg 0:662207e34fba 2286 * @see MPU6050_DELAYCTRL_DELAY_ES_SHADOW_BIT
garfieldsg 0:662207e34fba 2287 */
garfieldsg 0:662207e34fba 2288 void MPU6050::setExternalShadowDelayEnabled(bool enabled)
garfieldsg 0:662207e34fba 2289 {
garfieldsg 0:662207e34fba 2290 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_MST_DELAY_CTRL, MPU6050_DELAYCTRL_DELAY_ES_SHADOW_BIT, enabled);
garfieldsg 0:662207e34fba 2291 }
garfieldsg 0:662207e34fba 2292 /** Get slave delay enabled status.
garfieldsg 0:662207e34fba 2293 * When a particular slave delay is enabled, the rate of access for the that
garfieldsg 0:662207e34fba 2294 * slave device is reduced. When a slave's access rate is decreased relative to
garfieldsg 0:662207e34fba 2295 * the Sample Rate, the slave is accessed every:
garfieldsg 0:662207e34fba 2296 *
garfieldsg 0:662207e34fba 2297 * 1 / (1 + I2C_MST_DLY) Samples
garfieldsg 0:662207e34fba 2298 *
garfieldsg 0:662207e34fba 2299 * This base Sample Rate in turn is determined by SMPLRT_DIV (register * 25)
garfieldsg 0:662207e34fba 2300 * and DLPF_CFG (register 26).
garfieldsg 0:662207e34fba 2301 *
garfieldsg 0:662207e34fba 2302 * For further information regarding I2C_MST_DLY, please refer to register 52.
garfieldsg 0:662207e34fba 2303 * For further information regarding the Sample Rate, please refer to register 25.
garfieldsg 0:662207e34fba 2304 *
garfieldsg 0:662207e34fba 2305 * @param num Slave number (0-4)
garfieldsg 0:662207e34fba 2306 * @return Current slave delay enabled status.
garfieldsg 0:662207e34fba 2307 * @see MPU6050_RA_I2C_MST_DELAY_CTRL
garfieldsg 0:662207e34fba 2308 * @see MPU6050_DELAYCTRL_I2C_SLV0_DLY_EN_BIT
garfieldsg 0:662207e34fba 2309 */
garfieldsg 0:662207e34fba 2310 bool MPU6050::getSlaveDelayEnabled(uint8_t num)
garfieldsg 0:662207e34fba 2311 {
garfieldsg 0:662207e34fba 2312 // MPU6050_DELAYCTRL_I2C_SLV4_DLY_EN_BIT is 4, SLV3 is 3, etc.
garfieldsg 0:662207e34fba 2313 if (num > 4) return 0;
garfieldsg 0:662207e34fba 2314 i2Cdev.readBit(devAddr, MPU6050_RA_I2C_MST_DELAY_CTRL, num, buffer);
garfieldsg 0:662207e34fba 2315 return buffer[0];
garfieldsg 0:662207e34fba 2316 }
garfieldsg 0:662207e34fba 2317 /** Set slave delay enabled status.
garfieldsg 0:662207e34fba 2318 * @param num Slave number (0-4)
garfieldsg 0:662207e34fba 2319 * @param enabled New slave delay enabled status.
garfieldsg 0:662207e34fba 2320 * @see MPU6050_RA_I2C_MST_DELAY_CTRL
garfieldsg 0:662207e34fba 2321 * @see MPU6050_DELAYCTRL_I2C_SLV0_DLY_EN_BIT
garfieldsg 0:662207e34fba 2322 */
garfieldsg 0:662207e34fba 2323 void MPU6050::setSlaveDelayEnabled(uint8_t num, bool enabled)
garfieldsg 0:662207e34fba 2324 {
garfieldsg 0:662207e34fba 2325 i2Cdev.writeBit(devAddr, MPU6050_RA_I2C_MST_DELAY_CTRL, num, enabled);
garfieldsg 0:662207e34fba 2326 }
garfieldsg 0:662207e34fba 2327
garfieldsg 0:662207e34fba 2328 // SIGNAL_PATH_RESET register
garfieldsg 0:662207e34fba 2329
garfieldsg 0:662207e34fba 2330 /** Reset gyroscope signal path.
garfieldsg 0:662207e34fba 2331 * The reset will revert the signal path analog to digital converters and
garfieldsg 0:662207e34fba 2332 * filters to their power up configurations.
garfieldsg 0:662207e34fba 2333 * @see MPU6050_RA_SIGNAL_PATH_RESET
garfieldsg 0:662207e34fba 2334 * @see MPU6050_PATHRESET_GYRO_RESET_BIT
garfieldsg 0:662207e34fba 2335 */
garfieldsg 0:662207e34fba 2336 void MPU6050::resetGyroscopePath()
garfieldsg 0:662207e34fba 2337 {
garfieldsg 0:662207e34fba 2338 i2Cdev.writeBit(devAddr, MPU6050_RA_SIGNAL_PATH_RESET, MPU6050_PATHRESET_GYRO_RESET_BIT, true);
garfieldsg 0:662207e34fba 2339 }
garfieldsg 0:662207e34fba 2340 /** Reset accelerometer signal path.
garfieldsg 0:662207e34fba 2341 * The reset will revert the signal path analog to digital converters and
garfieldsg 0:662207e34fba 2342 * filters to their power up configurations.
garfieldsg 0:662207e34fba 2343 * @see MPU6050_RA_SIGNAL_PATH_RESET
garfieldsg 0:662207e34fba 2344 * @see MPU6050_PATHRESET_ACCEL_RESET_BIT
garfieldsg 0:662207e34fba 2345 */
garfieldsg 0:662207e34fba 2346 void MPU6050::resetAccelerometerPath()
garfieldsg 0:662207e34fba 2347 {
garfieldsg 0:662207e34fba 2348 i2Cdev.writeBit(devAddr, MPU6050_RA_SIGNAL_PATH_RESET, MPU6050_PATHRESET_ACCEL_RESET_BIT, true);
garfieldsg 0:662207e34fba 2349 }
garfieldsg 0:662207e34fba 2350 /** Reset temperature sensor signal path.
garfieldsg 0:662207e34fba 2351 * The reset will revert the signal path analog to digital converters and
garfieldsg 0:662207e34fba 2352 * filters to their power up configurations.
garfieldsg 0:662207e34fba 2353 * @see MPU6050_RA_SIGNAL_PATH_RESET
garfieldsg 0:662207e34fba 2354 * @see MPU6050_PATHRESET_TEMP_RESET_BIT
garfieldsg 0:662207e34fba 2355 */
garfieldsg 0:662207e34fba 2356 void MPU6050::resetTemperaturePath()
garfieldsg 0:662207e34fba 2357 {
garfieldsg 0:662207e34fba 2358 i2Cdev.writeBit(devAddr, MPU6050_RA_SIGNAL_PATH_RESET, MPU6050_PATHRESET_TEMP_RESET_BIT, true);
garfieldsg 0:662207e34fba 2359 }
garfieldsg 0:662207e34fba 2360
garfieldsg 0:662207e34fba 2361 // MOT_DETECT_CTRL register
garfieldsg 0:662207e34fba 2362
garfieldsg 0:662207e34fba 2363 /** Get accelerometer power-on delay.
garfieldsg 0:662207e34fba 2364 * The accelerometer data path provides samples to the sensor registers, Motion
garfieldsg 0:662207e34fba 2365 * detection, Zero Motion detection, and Free Fall detection modules. The
garfieldsg 0:662207e34fba 2366 * signal path contains filters which must be flushed on wake-up with new
garfieldsg 0:662207e34fba 2367 * samples before the detection modules begin operations. The default wake-up
garfieldsg 0:662207e34fba 2368 * delay, of 4ms can be lengthened by up to 3ms. This additional delay is
garfieldsg 0:662207e34fba 2369 * specified in ACCEL_ON_DELAY in units of 1 LSB = 1 ms. The user may select
garfieldsg 0:662207e34fba 2370 * any value above zero unless instructed otherwise by InvenSense. Please refer
garfieldsg 0:662207e34fba 2371 * to Section 8 of the MPU-6000/MPU-6050 Product Specification document for
garfieldsg 0:662207e34fba 2372 * further information regarding the detection modules.
garfieldsg 0:662207e34fba 2373 * @return Current accelerometer power-on delay
garfieldsg 0:662207e34fba 2374 * @see MPU6050_RA_MOT_DETECT_CTRL
garfieldsg 0:662207e34fba 2375 * @see MPU6050_DETECT_ACCEL_ON_DELAY_BIT
garfieldsg 0:662207e34fba 2376 */
garfieldsg 0:662207e34fba 2377 uint8_t MPU6050::getAccelerometerPowerOnDelay()
garfieldsg 0:662207e34fba 2378 {
garfieldsg 0:662207e34fba 2379 i2Cdev.readBits(devAddr, MPU6050_RA_MOT_DETECT_CTRL, MPU6050_DETECT_ACCEL_ON_DELAY_BIT, MPU6050_DETECT_ACCEL_ON_DELAY_LENGTH, buffer);
garfieldsg 0:662207e34fba 2380 return buffer[0];
garfieldsg 0:662207e34fba 2381 }
garfieldsg 0:662207e34fba 2382 /** Set accelerometer power-on delay.
garfieldsg 0:662207e34fba 2383 * @param delay New accelerometer power-on delay (0-3)
garfieldsg 0:662207e34fba 2384 * @see getAccelerometerPowerOnDelay()
garfieldsg 0:662207e34fba 2385 * @see MPU6050_RA_MOT_DETECT_CTRL
garfieldsg 0:662207e34fba 2386 * @see MPU6050_DETECT_ACCEL_ON_DELAY_BIT
garfieldsg 0:662207e34fba 2387 */
garfieldsg 0:662207e34fba 2388 void MPU6050::setAccelerometerPowerOnDelay(uint8_t delay)
garfieldsg 0:662207e34fba 2389 {
garfieldsg 0:662207e34fba 2390 i2Cdev.writeBits(devAddr, MPU6050_RA_MOT_DETECT_CTRL, MPU6050_DETECT_ACCEL_ON_DELAY_BIT, MPU6050_DETECT_ACCEL_ON_DELAY_LENGTH, delay);
garfieldsg 0:662207e34fba 2391 }
garfieldsg 0:662207e34fba 2392 /** Get Free Fall detection counter decrement configuration.
garfieldsg 0:662207e34fba 2393 * Detection is registered by the Free Fall detection module after accelerometer
garfieldsg 0:662207e34fba 2394 * measurements meet their respective threshold conditions over a specified
garfieldsg 0:662207e34fba 2395 * number of samples. When the threshold conditions are met, the corresponding
garfieldsg 0:662207e34fba 2396 * detection counter increments by 1. The user may control the rate at which the
garfieldsg 0:662207e34fba 2397 * detection counter decrements when the threshold condition is not met by
garfieldsg 0:662207e34fba 2398 * configuring FF_COUNT. The decrement rate can be set according to the
garfieldsg 0:662207e34fba 2399 * following table:
garfieldsg 0:662207e34fba 2400 *
garfieldsg 0:662207e34fba 2401 * <pre>
garfieldsg 0:662207e34fba 2402 * FF_COUNT | Counter Decrement
garfieldsg 0:662207e34fba 2403 * ---------+------------------
garfieldsg 0:662207e34fba 2404 * 0 | Reset
garfieldsg 0:662207e34fba 2405 * 1 | 1
garfieldsg 0:662207e34fba 2406 * 2 | 2
garfieldsg 0:662207e34fba 2407 * 3 | 4
garfieldsg 0:662207e34fba 2408 * </pre>
garfieldsg 0:662207e34fba 2409 *
garfieldsg 0:662207e34fba 2410 * When FF_COUNT is configured to 0 (reset), any non-qualifying sample will
garfieldsg 0:662207e34fba 2411 * reset the counter to 0. For further information on Free Fall detection,
garfieldsg 0:662207e34fba 2412 * please refer to Registers 29 to 32.
garfieldsg 0:662207e34fba 2413 *
garfieldsg 0:662207e34fba 2414 * @return Current decrement configuration
garfieldsg 0:662207e34fba 2415 * @see MPU6050_RA_MOT_DETECT_CTRL
garfieldsg 0:662207e34fba 2416 * @see MPU6050_DETECT_FF_COUNT_BIT
garfieldsg 0:662207e34fba 2417 */
garfieldsg 0:662207e34fba 2418 uint8_t MPU6050::getFreefallDetectionCounterDecrement()
garfieldsg 0:662207e34fba 2419 {
garfieldsg 0:662207e34fba 2420 i2Cdev.readBits(devAddr, MPU6050_RA_MOT_DETECT_CTRL, MPU6050_DETECT_FF_COUNT_BIT, MPU6050_DETECT_FF_COUNT_LENGTH, buffer);
garfieldsg 0:662207e34fba 2421 return buffer[0];
garfieldsg 0:662207e34fba 2422 }
garfieldsg 0:662207e34fba 2423 /** Set Free Fall detection counter decrement configuration.
garfieldsg 0:662207e34fba 2424 * @param decrement New decrement configuration value
garfieldsg 0:662207e34fba 2425 * @see getFreefallDetectionCounterDecrement()
garfieldsg 0:662207e34fba 2426 * @see MPU6050_RA_MOT_DETECT_CTRL
garfieldsg 0:662207e34fba 2427 * @see MPU6050_DETECT_FF_COUNT_BIT
garfieldsg 0:662207e34fba 2428 */
garfieldsg 0:662207e34fba 2429 void MPU6050::setFreefallDetectionCounterDecrement(uint8_t decrement)
garfieldsg 0:662207e34fba 2430 {
garfieldsg 0:662207e34fba 2431 i2Cdev.writeBits(devAddr, MPU6050_RA_MOT_DETECT_CTRL, MPU6050_DETECT_FF_COUNT_BIT, MPU6050_DETECT_FF_COUNT_LENGTH, decrement);
garfieldsg 0:662207e34fba 2432 }
garfieldsg 0:662207e34fba 2433 /** Get Motion detection counter decrement configuration.
garfieldsg 0:662207e34fba 2434 * Detection is registered by the Motion detection module after accelerometer
garfieldsg 0:662207e34fba 2435 * measurements meet their respective threshold conditions over a specified
garfieldsg 0:662207e34fba 2436 * number of samples. When the threshold conditions are met, the corresponding
garfieldsg 0:662207e34fba 2437 * detection counter increments by 1. The user may control the rate at which the
garfieldsg 0:662207e34fba 2438 * detection counter decrements when the threshold condition is not met by
garfieldsg 0:662207e34fba 2439 * configuring MOT_COUNT. The decrement rate can be set according to the
garfieldsg 0:662207e34fba 2440 * following table:
garfieldsg 0:662207e34fba 2441 *
garfieldsg 0:662207e34fba 2442 * <pre>
garfieldsg 0:662207e34fba 2443 * MOT_COUNT | Counter Decrement
garfieldsg 0:662207e34fba 2444 * ----------+------------------
garfieldsg 0:662207e34fba 2445 * 0 | Reset
garfieldsg 0:662207e34fba 2446 * 1 | 1
garfieldsg 0:662207e34fba 2447 * 2 | 2
garfieldsg 0:662207e34fba 2448 * 3 | 4
garfieldsg 0:662207e34fba 2449 * </pre>
garfieldsg 0:662207e34fba 2450 *
garfieldsg 0:662207e34fba 2451 * When MOT_COUNT is configured to 0 (reset), any non-qualifying sample will
garfieldsg 0:662207e34fba 2452 * reset the counter to 0. For further information on Motion detection,
garfieldsg 0:662207e34fba 2453 * please refer to Registers 29 to 32.
garfieldsg 0:662207e34fba 2454 *
garfieldsg 0:662207e34fba 2455 */
garfieldsg 0:662207e34fba 2456 uint8_t MPU6050::getMotionDetectionCounterDecrement()
garfieldsg 0:662207e34fba 2457 {
garfieldsg 0:662207e34fba 2458 i2Cdev.readBits(devAddr, MPU6050_RA_MOT_DETECT_CTRL, MPU6050_DETECT_MOT_COUNT_BIT, MPU6050_DETECT_MOT_COUNT_LENGTH, buffer);
garfieldsg 0:662207e34fba 2459 return buffer[0];
garfieldsg 0:662207e34fba 2460 }
garfieldsg 0:662207e34fba 2461 /** Set Motion detection counter decrement configuration.
garfieldsg 0:662207e34fba 2462 * @param decrement New decrement configuration value
garfieldsg 0:662207e34fba 2463 * @see getMotionDetectionCounterDecrement()
garfieldsg 0:662207e34fba 2464 * @see MPU6050_RA_MOT_DETECT_CTRL
garfieldsg 0:662207e34fba 2465 * @see MPU6050_DETECT_MOT_COUNT_BIT
garfieldsg 0:662207e34fba 2466 */
garfieldsg 0:662207e34fba 2467 void MPU6050::setMotionDetectionCounterDecrement(uint8_t decrement)
garfieldsg 0:662207e34fba 2468 {
garfieldsg 0:662207e34fba 2469 i2Cdev.writeBits(devAddr, MPU6050_RA_MOT_DETECT_CTRL, MPU6050_DETECT_MOT_COUNT_BIT, MPU6050_DETECT_MOT_COUNT_LENGTH, decrement);
garfieldsg 0:662207e34fba 2470 }
garfieldsg 0:662207e34fba 2471
garfieldsg 0:662207e34fba 2472 // USER_CTRL register
garfieldsg 0:662207e34fba 2473
garfieldsg 0:662207e34fba 2474 /** Get FIFO enabled status.
garfieldsg 0:662207e34fba 2475 * When this bit is set to 0, the FIFO buffer is disabled. The FIFO buffer
garfieldsg 0:662207e34fba 2476 * cannot be written to or read from while disabled. The FIFO buffer's state
garfieldsg 0:662207e34fba 2477 * does not change unless the MPU-60X0 is power cycled.
garfieldsg 0:662207e34fba 2478 * @return Current FIFO enabled status
garfieldsg 0:662207e34fba 2479 * @see MPU6050_RA_USER_CTRL
garfieldsg 0:662207e34fba 2480 * @see MPU6050_USERCTRL_FIFO_EN_BIT
garfieldsg 0:662207e34fba 2481 */
garfieldsg 0:662207e34fba 2482 bool MPU6050::getFIFOEnabled()
garfieldsg 0:662207e34fba 2483 {
garfieldsg 0:662207e34fba 2484 i2Cdev.readBit(devAddr, MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_FIFO_EN_BIT, buffer);
garfieldsg 0:662207e34fba 2485 return buffer[0];
garfieldsg 0:662207e34fba 2486 }
garfieldsg 0:662207e34fba 2487 /** Set FIFO enabled status.
garfieldsg 0:662207e34fba 2488 * @param enabled New FIFO enabled status
garfieldsg 0:662207e34fba 2489 * @see getFIFOEnabled()
garfieldsg 0:662207e34fba 2490 * @see MPU6050_RA_USER_CTRL
garfieldsg 0:662207e34fba 2491 * @see MPU6050_USERCTRL_FIFO_EN_BIT
garfieldsg 0:662207e34fba 2492 */
garfieldsg 0:662207e34fba 2493 void MPU6050::setFIFOEnabled(bool enabled)
garfieldsg 0:662207e34fba 2494 {
garfieldsg 0:662207e34fba 2495 i2Cdev.writeBit(devAddr, MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_FIFO_EN_BIT, enabled);
garfieldsg 0:662207e34fba 2496 }
garfieldsg 0:662207e34fba 2497 /** Get I2C Master Mode enabled status.
garfieldsg 0:662207e34fba 2498 * When this mode is enabled, the MPU-60X0 acts as the I2C Master to the
garfieldsg 0:662207e34fba 2499 * external sensor slave devices on the auxiliary I2C bus. When this bit is
garfieldsg 0:662207e34fba 2500 * cleared to 0, the auxiliary I2C bus lines (AUX_DA and AUX_CL) are logically
garfieldsg 0:662207e34fba 2501 * driven by the primary I2C bus (SDA and SCL). This is a precondition to
garfieldsg 0:662207e34fba 2502 * enabling Bypass Mode. For further information regarding Bypass Mode, please
garfieldsg 0:662207e34fba 2503 * refer to Register 55.
garfieldsg 0:662207e34fba 2504 * @return Current I2C Master Mode enabled status
garfieldsg 0:662207e34fba 2505 * @see MPU6050_RA_USER_CTRL
garfieldsg 0:662207e34fba 2506 * @see MPU6050_USERCTRL_I2C_MST_EN_BIT
garfieldsg 0:662207e34fba 2507 */
garfieldsg 0:662207e34fba 2508 bool MPU6050::getI2CMasterModeEnabled()
garfieldsg 0:662207e34fba 2509 {
garfieldsg 0:662207e34fba 2510 i2Cdev.readBit(devAddr, MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_I2C_MST_EN_BIT, buffer);
garfieldsg 0:662207e34fba 2511 return buffer[0];
garfieldsg 0:662207e34fba 2512 }
garfieldsg 0:662207e34fba 2513 /** Set I2C Master Mode enabled status.
garfieldsg 0:662207e34fba 2514 * @param enabled New I2C Master Mode enabled status
garfieldsg 0:662207e34fba 2515 * @see getI2CMasterModeEnabled()
garfieldsg 0:662207e34fba 2516 * @see MPU6050_RA_USER_CTRL
garfieldsg 0:662207e34fba 2517 * @see MPU6050_USERCTRL_I2C_MST_EN_BIT
garfieldsg 0:662207e34fba 2518 */
garfieldsg 0:662207e34fba 2519 void MPU6050::setI2CMasterModeEnabled(bool enabled)
garfieldsg 0:662207e34fba 2520 {
garfieldsg 0:662207e34fba 2521 i2Cdev.writeBit(devAddr, MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_I2C_MST_EN_BIT, enabled);
garfieldsg 0:662207e34fba 2522 }
garfieldsg 0:662207e34fba 2523 /** Switch from I2C to SPI mode (MPU-6000 only)
garfieldsg 0:662207e34fba 2524 * If this is set, the primary SPI interface will be enabled in place of the
garfieldsg 0:662207e34fba 2525 * disabled primary I2C interface.
garfieldsg 0:662207e34fba 2526 */
garfieldsg 0:662207e34fba 2527 void MPU6050::switchSPIEnabled(bool enabled)
garfieldsg 0:662207e34fba 2528 {
garfieldsg 0:662207e34fba 2529 i2Cdev.writeBit(devAddr, MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_I2C_IF_DIS_BIT, enabled);
garfieldsg 0:662207e34fba 2530 }
garfieldsg 0:662207e34fba 2531 /** Reset the FIFO.
garfieldsg 0:662207e34fba 2532 * This bit resets the FIFO buffer when set to 1 while FIFO_EN equals 0. This
garfieldsg 0:662207e34fba 2533 * bit automatically clears to 0 after the reset has been triggered.
garfieldsg 0:662207e34fba 2534 * @see MPU6050_RA_USER_CTRL
garfieldsg 0:662207e34fba 2535 * @see MPU6050_USERCTRL_FIFO_RESET_BIT
garfieldsg 0:662207e34fba 2536 */
garfieldsg 0:662207e34fba 2537 void MPU6050::resetFIFO()
garfieldsg 0:662207e34fba 2538 {
garfieldsg 0:662207e34fba 2539 i2Cdev.writeBit(devAddr, MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_FIFO_RESET_BIT, true);
garfieldsg 0:662207e34fba 2540 }
garfieldsg 0:662207e34fba 2541 /** Reset the I2C Master.
garfieldsg 0:662207e34fba 2542 * This bit resets the I2C Master when set to 1 while I2C_MST_EN equals 0.
garfieldsg 0:662207e34fba 2543 * This bit automatically clears to 0 after the reset has been triggered.
garfieldsg 0:662207e34fba 2544 * @see MPU6050_RA_USER_CTRL
garfieldsg 0:662207e34fba 2545 * @see MPU6050_USERCTRL_I2C_MST_RESET_BIT
garfieldsg 0:662207e34fba 2546 */
garfieldsg 0:662207e34fba 2547 void MPU6050::resetI2CMaster()
garfieldsg 0:662207e34fba 2548 {
garfieldsg 0:662207e34fba 2549 i2Cdev.writeBit(devAddr, MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_I2C_MST_RESET_BIT, true);
garfieldsg 0:662207e34fba 2550 }
garfieldsg 0:662207e34fba 2551 /** Reset all sensor registers and signal paths.
garfieldsg 0:662207e34fba 2552 * When set to 1, this bit resets the signal paths for all sensors (gyroscopes,
garfieldsg 0:662207e34fba 2553 * accelerometers, and temperature sensor). This operation will also clear the
garfieldsg 0:662207e34fba 2554 * sensor registers. This bit automatically clears to 0 after the reset has been
garfieldsg 0:662207e34fba 2555 * triggered.
garfieldsg 0:662207e34fba 2556 *
garfieldsg 0:662207e34fba 2557 * When resetting only the signal path (and not the sensor registers), please
garfieldsg 0:662207e34fba 2558 * use Register 104, SIGNAL_PATH_RESET.
garfieldsg 0:662207e34fba 2559 *
garfieldsg 0:662207e34fba 2560 * @see MPU6050_RA_USER_CTRL
garfieldsg 0:662207e34fba 2561 * @see MPU6050_USERCTRL_SIG_COND_RESET_BIT
garfieldsg 0:662207e34fba 2562 */
garfieldsg 0:662207e34fba 2563 void MPU6050::resetSensors()
garfieldsg 0:662207e34fba 2564 {
garfieldsg 0:662207e34fba 2565 i2Cdev.writeBit(devAddr, MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_SIG_COND_RESET_BIT, true);
garfieldsg 0:662207e34fba 2566 }
garfieldsg 0:662207e34fba 2567
garfieldsg 0:662207e34fba 2568 // PWR_MGMT_1 register
garfieldsg 0:662207e34fba 2569
garfieldsg 0:662207e34fba 2570 /** Trigger a full device reset.
garfieldsg 0:662207e34fba 2571 * A small delay of ~50ms may be desirable after triggering a reset.
garfieldsg 0:662207e34fba 2572 * @see MPU6050_RA_PWR_MGMT_1
garfieldsg 0:662207e34fba 2573 * @see MPU6050_PWR1_DEVICE_RESET_BIT
garfieldsg 0:662207e34fba 2574 */
garfieldsg 0:662207e34fba 2575 void MPU6050::reset()
garfieldsg 0:662207e34fba 2576 {
garfieldsg 0:662207e34fba 2577 i2Cdev.writeBit(devAddr, MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_DEVICE_RESET_BIT, true);
garfieldsg 0:662207e34fba 2578 }
garfieldsg 0:662207e34fba 2579 /** Get sleep mode status.
garfieldsg 0:662207e34fba 2580 * Setting the SLEEP bit in the register puts the device into very low power
garfieldsg 0:662207e34fba 2581 * sleep mode. In this mode, only the serial interface and internal registers
garfieldsg 0:662207e34fba 2582 * remain active, allowing for a very low standby current. Clearing this bit
garfieldsg 0:662207e34fba 2583 * puts the device back into normal mode. To save power, the individual standby
garfieldsg 0:662207e34fba 2584 * selections for each of the gyros should be used if any gyro axis is not used
garfieldsg 0:662207e34fba 2585 * by the application.
garfieldsg 0:662207e34fba 2586 * @return Current sleep mode enabled status
garfieldsg 0:662207e34fba 2587 * @see MPU6050_RA_PWR_MGMT_1
garfieldsg 0:662207e34fba 2588 * @see MPU6050_PWR1_SLEEP_BIT
garfieldsg 0:662207e34fba 2589 */
garfieldsg 0:662207e34fba 2590 bool MPU6050::getSleepEnabled()
garfieldsg 0:662207e34fba 2591 {
garfieldsg 0:662207e34fba 2592 i2Cdev.readBit(devAddr, MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_SLEEP_BIT, buffer);
garfieldsg 0:662207e34fba 2593 return buffer[0];
garfieldsg 0:662207e34fba 2594 }
garfieldsg 0:662207e34fba 2595 /** Set sleep mode status.
garfieldsg 0:662207e34fba 2596 * @param enabled New sleep mode enabled status
garfieldsg 0:662207e34fba 2597 * @see getSleepEnabled()
garfieldsg 0:662207e34fba 2598 * @see MPU6050_RA_PWR_MGMT_1
garfieldsg 0:662207e34fba 2599 * @see MPU6050_PWR1_SLEEP_BIT
garfieldsg 0:662207e34fba 2600 */
garfieldsg 0:662207e34fba 2601 void MPU6050::setSleepEnabled(bool enabled)
garfieldsg 0:662207e34fba 2602 {
garfieldsg 0:662207e34fba 2603 i2Cdev.writeBit(devAddr, MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_SLEEP_BIT, enabled);
garfieldsg 0:662207e34fba 2604 }
garfieldsg 0:662207e34fba 2605 /** Get wake cycle enabled status.
garfieldsg 0:662207e34fba 2606 * When this bit is set to 1 and SLEEP is disabled, the MPU-60X0 will cycle
garfieldsg 0:662207e34fba 2607 * between sleep mode and waking up to take a single sample of data from active
garfieldsg 0:662207e34fba 2608 * sensors at a rate determined by LP_WAKE_CTRL (register 108).
garfieldsg 0:662207e34fba 2609 * @return Current sleep mode enabled status
garfieldsg 0:662207e34fba 2610 * @see MPU6050_RA_PWR_MGMT_1
garfieldsg 0:662207e34fba 2611 * @see MPU6050_PWR1_CYCLE_BIT
garfieldsg 0:662207e34fba 2612 */
garfieldsg 0:662207e34fba 2613 bool MPU6050::getWakeCycleEnabled()
garfieldsg 0:662207e34fba 2614 {
garfieldsg 0:662207e34fba 2615 i2Cdev.readBit(devAddr, MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_CYCLE_BIT, buffer);
garfieldsg 0:662207e34fba 2616 return buffer[0];
garfieldsg 0:662207e34fba 2617 }
garfieldsg 0:662207e34fba 2618 /** Set wake cycle enabled status.
garfieldsg 0:662207e34fba 2619 * @param enabled New sleep mode enabled status
garfieldsg 0:662207e34fba 2620 * @see getWakeCycleEnabled()
garfieldsg 0:662207e34fba 2621 * @see MPU6050_RA_PWR_MGMT_1
garfieldsg 0:662207e34fba 2622 * @see MPU6050_PWR1_CYCLE_BIT
garfieldsg 0:662207e34fba 2623 */
garfieldsg 0:662207e34fba 2624 void MPU6050::setWakeCycleEnabled(bool enabled)
garfieldsg 0:662207e34fba 2625 {
garfieldsg 0:662207e34fba 2626 i2Cdev.writeBit(devAddr, MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_CYCLE_BIT, enabled);
garfieldsg 0:662207e34fba 2627 }
garfieldsg 0:662207e34fba 2628 /** Get temperature sensor enabled status.
garfieldsg 0:662207e34fba 2629 * Control the usage of the internal temperature sensor.
garfieldsg 0:662207e34fba 2630 *
garfieldsg 0:662207e34fba 2631 * Note: this register stores the *disabled* value, but for consistency with the
garfieldsg 0:662207e34fba 2632 * rest of the code, the function is named and used with standard true/false
garfieldsg 0:662207e34fba 2633 * values to indicate whether the sensor is enabled or disabled, respectively.
garfieldsg 0:662207e34fba 2634 *
garfieldsg 0:662207e34fba 2635 * @return Current temperature sensor enabled status
garfieldsg 0:662207e34fba 2636 * @see MPU6050_RA_PWR_MGMT_1
garfieldsg 0:662207e34fba 2637 * @see MPU6050_PWR1_TEMP_DIS_BIT
garfieldsg 0:662207e34fba 2638 */
garfieldsg 0:662207e34fba 2639 bool MPU6050::getTempSensorEnabled()
garfieldsg 0:662207e34fba 2640 {
garfieldsg 0:662207e34fba 2641 i2Cdev.readBit(devAddr, MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_TEMP_DIS_BIT, buffer);
garfieldsg 0:662207e34fba 2642 return buffer[0] == 0; // 1 is actually disabled here
garfieldsg 0:662207e34fba 2643 }
garfieldsg 0:662207e34fba 2644 /** Set temperature sensor enabled status.
garfieldsg 0:662207e34fba 2645 * Note: this register stores the *disabled* value, but for consistency with the
garfieldsg 0:662207e34fba 2646 * rest of the code, the function is named and used with standard true/false
garfieldsg 0:662207e34fba 2647 * values to indicate whether the sensor is enabled or disabled, respectively.
garfieldsg 0:662207e34fba 2648 *
garfieldsg 0:662207e34fba 2649 * @param enabled New temperature sensor enabled status
garfieldsg 0:662207e34fba 2650 * @see getTempSensorEnabled()
garfieldsg 0:662207e34fba 2651 * @see MPU6050_RA_PWR_MGMT_1
garfieldsg 0:662207e34fba 2652 * @see MPU6050_PWR1_TEMP_DIS_BIT
garfieldsg 0:662207e34fba 2653 */
garfieldsg 0:662207e34fba 2654 void MPU6050::setTempSensorEnabled(bool enabled)
garfieldsg 0:662207e34fba 2655 {
garfieldsg 0:662207e34fba 2656 // 1 is actually disabled here
garfieldsg 0:662207e34fba 2657 i2Cdev.writeBit(devAddr, MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_TEMP_DIS_BIT, !enabled);
garfieldsg 0:662207e34fba 2658 }
garfieldsg 0:662207e34fba 2659 /** Get clock source setting.
garfieldsg 0:662207e34fba 2660 * @return Current clock source setting
garfieldsg 0:662207e34fba 2661 * @see MPU6050_RA_PWR_MGMT_1
garfieldsg 0:662207e34fba 2662 * @see MPU6050_PWR1_CLKSEL_BIT
garfieldsg 0:662207e34fba 2663 * @see MPU6050_PWR1_CLKSEL_LENGTH
garfieldsg 0:662207e34fba 2664 */
garfieldsg 0:662207e34fba 2665 uint8_t MPU6050::getClockSource()
garfieldsg 0:662207e34fba 2666 {
garfieldsg 0:662207e34fba 2667 i2Cdev.readBits(devAddr, MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_CLKSEL_BIT, MPU6050_PWR1_CLKSEL_LENGTH, buffer);
garfieldsg 0:662207e34fba 2668 return buffer[0];
garfieldsg 0:662207e34fba 2669 }
garfieldsg 0:662207e34fba 2670 /** Set clock source setting.
garfieldsg 0:662207e34fba 2671 * An internal 8MHz oscillator, gyroscope based clock, or external sources can
garfieldsg 0:662207e34fba 2672 * be selected as the MPU-60X0 clock source. When the internal 8 MHz oscillator
garfieldsg 0:662207e34fba 2673 * or an external source is chosen as the clock source, the MPU-60X0 can operate
garfieldsg 0:662207e34fba 2674 * in low power modes with the gyroscopes disabled.
garfieldsg 0:662207e34fba 2675 *
garfieldsg 0:662207e34fba 2676 * Upon power up, the MPU-60X0 clock source defaults to the internal oscillator.
garfieldsg 0:662207e34fba 2677 * However, it is highly recommended that the device be configured to use one of
garfieldsg 0:662207e34fba 2678 * the gyroscopes (or an external clock source) as the clock reference for
garfieldsg 0:662207e34fba 2679 * improved stability. The clock source can be selected according to the following table:
garfieldsg 0:662207e34fba 2680 *
garfieldsg 0:662207e34fba 2681 * <pre>
garfieldsg 0:662207e34fba 2682 * CLK_SEL | Clock Source
garfieldsg 0:662207e34fba 2683 * --------+--------------------------------------
garfieldsg 0:662207e34fba 2684 * 0 | Internal oscillator
garfieldsg 0:662207e34fba 2685 * 1 | PLL with X Gyro reference
garfieldsg 0:662207e34fba 2686 * 2 | PLL with Y Gyro reference
garfieldsg 0:662207e34fba 2687 * 3 | PLL with Z Gyro reference
garfieldsg 0:662207e34fba 2688 * 4 | PLL with external 32.768kHz reference
garfieldsg 0:662207e34fba 2689 * 5 | PLL with external 19.2MHz reference
garfieldsg 0:662207e34fba 2690 * 6 | Reserved
garfieldsg 0:662207e34fba 2691 * 7 | Stops the clock and keeps the timing generator in reset
garfieldsg 0:662207e34fba 2692 * </pre>
garfieldsg 0:662207e34fba 2693 *
garfieldsg 0:662207e34fba 2694 * @param source New clock source setting
garfieldsg 0:662207e34fba 2695 * @see getClockSource()
garfieldsg 0:662207e34fba 2696 * @see MPU6050_RA_PWR_MGMT_1
garfieldsg 0:662207e34fba 2697 * @see MPU6050_PWR1_CLKSEL_BIT
garfieldsg 0:662207e34fba 2698 * @see MPU6050_PWR1_CLKSEL_LENGTH
garfieldsg 0:662207e34fba 2699 */
garfieldsg 0:662207e34fba 2700 void MPU6050::setClockSource(uint8_t source)
garfieldsg 0:662207e34fba 2701 {
garfieldsg 0:662207e34fba 2702 i2Cdev.writeBits(devAddr, MPU6050_RA_PWR_MGMT_1, MPU6050_PWR1_CLKSEL_BIT, MPU6050_PWR1_CLKSEL_LENGTH, source);
garfieldsg 0:662207e34fba 2703 }
garfieldsg 0:662207e34fba 2704
garfieldsg 0:662207e34fba 2705 // PWR_MGMT_2 register
garfieldsg 0:662207e34fba 2706
garfieldsg 0:662207e34fba 2707 /** Get wake frequency in Accel-Only Low Power Mode.
garfieldsg 0:662207e34fba 2708 * The MPU-60X0 can be put into Accerlerometer Only Low Power Mode by setting
garfieldsg 0:662207e34fba 2709 * PWRSEL to 1 in the Power Management 1 register (Register 107). In this mode,
garfieldsg 0:662207e34fba 2710 * the device will power off all devices except for the primary I2C interface,
garfieldsg 0:662207e34fba 2711 * waking only the accelerometer at fixed intervals to take a single
garfieldsg 0:662207e34fba 2712 * measurement. The frequency of wake-ups can be configured with LP_WAKE_CTRL
garfieldsg 0:662207e34fba 2713 * as shown below:
garfieldsg 0:662207e34fba 2714 *
garfieldsg 0:662207e34fba 2715 * <pre>
garfieldsg 0:662207e34fba 2716 * LP_WAKE_CTRL | Wake-up Frequency
garfieldsg 0:662207e34fba 2717 * -------------+------------------
garfieldsg 0:662207e34fba 2718 * 0 | 1.25 Hz
garfieldsg 0:662207e34fba 2719 * 1 | 2.5 Hz
garfieldsg 0:662207e34fba 2720 * 2 | 5 Hz
garfieldsg 0:662207e34fba 2721 * 3 | 10 Hz
garfieldsg 0:662207e34fba 2722 * <pre>
garfieldsg 0:662207e34fba 2723 *
garfieldsg 0:662207e34fba 2724 * For further information regarding the MPU-60X0's power modes, please refer to
garfieldsg 0:662207e34fba 2725 * Register 107.
garfieldsg 0:662207e34fba 2726 *
garfieldsg 0:662207e34fba 2727 * @return Current wake frequency
garfieldsg 0:662207e34fba 2728 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2729 */
garfieldsg 0:662207e34fba 2730 uint8_t MPU6050::getWakeFrequency()
garfieldsg 0:662207e34fba 2731 {
garfieldsg 0:662207e34fba 2732 i2Cdev.readBits(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_LP_WAKE_CTRL_BIT, MPU6050_PWR2_LP_WAKE_CTRL_LENGTH, buffer);
garfieldsg 0:662207e34fba 2733 return buffer[0];
garfieldsg 0:662207e34fba 2734 }
garfieldsg 0:662207e34fba 2735 /** Set wake frequency in Accel-Only Low Power Mode.
garfieldsg 0:662207e34fba 2736 * @param frequency New wake frequency
garfieldsg 0:662207e34fba 2737 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2738 */
garfieldsg 0:662207e34fba 2739 void MPU6050::setWakeFrequency(uint8_t frequency)
garfieldsg 0:662207e34fba 2740 {
garfieldsg 0:662207e34fba 2741 i2Cdev.writeBits(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_LP_WAKE_CTRL_BIT, MPU6050_PWR2_LP_WAKE_CTRL_LENGTH, frequency);
garfieldsg 0:662207e34fba 2742 }
garfieldsg 0:662207e34fba 2743
garfieldsg 0:662207e34fba 2744 /** Get X-axis accelerometer standby enabled status.
garfieldsg 0:662207e34fba 2745 * If enabled, the X-axis will not gather or report data (or use power).
garfieldsg 0:662207e34fba 2746 * @return Current X-axis standby enabled status
garfieldsg 0:662207e34fba 2747 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2748 * @see MPU6050_PWR2_STBY_XA_BIT
garfieldsg 0:662207e34fba 2749 */
garfieldsg 0:662207e34fba 2750 bool MPU6050::getStandbyXAccelEnabled()
garfieldsg 0:662207e34fba 2751 {
garfieldsg 0:662207e34fba 2752 i2Cdev.readBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_XA_BIT, buffer);
garfieldsg 0:662207e34fba 2753 return buffer[0];
garfieldsg 0:662207e34fba 2754 }
garfieldsg 0:662207e34fba 2755 /** Set X-axis accelerometer standby enabled status.
garfieldsg 0:662207e34fba 2756 * @param New X-axis standby enabled status
garfieldsg 0:662207e34fba 2757 * @see getStandbyXAccelEnabled()
garfieldsg 0:662207e34fba 2758 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2759 * @see MPU6050_PWR2_STBY_XA_BIT
garfieldsg 0:662207e34fba 2760 */
garfieldsg 0:662207e34fba 2761 void MPU6050::setStandbyXAccelEnabled(bool enabled)
garfieldsg 0:662207e34fba 2762 {
garfieldsg 0:662207e34fba 2763 i2Cdev.writeBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_XA_BIT, enabled);
garfieldsg 0:662207e34fba 2764 }
garfieldsg 0:662207e34fba 2765 /** Get Y-axis accelerometer standby enabled status.
garfieldsg 0:662207e34fba 2766 * If enabled, the Y-axis will not gather or report data (or use power).
garfieldsg 0:662207e34fba 2767 * @return Current Y-axis standby enabled status
garfieldsg 0:662207e34fba 2768 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2769 * @see MPU6050_PWR2_STBY_YA_BIT
garfieldsg 0:662207e34fba 2770 */
garfieldsg 0:662207e34fba 2771 bool MPU6050::getStandbyYAccelEnabled()
garfieldsg 0:662207e34fba 2772 {
garfieldsg 0:662207e34fba 2773 i2Cdev.readBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_YA_BIT, buffer);
garfieldsg 0:662207e34fba 2774 return buffer[0];
garfieldsg 0:662207e34fba 2775 }
garfieldsg 0:662207e34fba 2776 /** Set Y-axis accelerometer standby enabled status.
garfieldsg 0:662207e34fba 2777 * @param New Y-axis standby enabled status
garfieldsg 0:662207e34fba 2778 * @see getStandbyYAccelEnabled()
garfieldsg 0:662207e34fba 2779 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2780 * @see MPU6050_PWR2_STBY_YA_BIT
garfieldsg 0:662207e34fba 2781 */
garfieldsg 0:662207e34fba 2782 void MPU6050::setStandbyYAccelEnabled(bool enabled)
garfieldsg 0:662207e34fba 2783 {
garfieldsg 0:662207e34fba 2784 i2Cdev.writeBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_YA_BIT, enabled);
garfieldsg 0:662207e34fba 2785 }
garfieldsg 0:662207e34fba 2786 /** Get Z-axis accelerometer standby enabled status.
garfieldsg 0:662207e34fba 2787 * If enabled, the Z-axis will not gather or report data (or use power).
garfieldsg 0:662207e34fba 2788 * @return Current Z-axis standby enabled status
garfieldsg 0:662207e34fba 2789 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2790 * @see MPU6050_PWR2_STBY_ZA_BIT
garfieldsg 0:662207e34fba 2791 */
garfieldsg 0:662207e34fba 2792 bool MPU6050::getStandbyZAccelEnabled()
garfieldsg 0:662207e34fba 2793 {
garfieldsg 0:662207e34fba 2794 i2Cdev.readBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_ZA_BIT, buffer);
garfieldsg 0:662207e34fba 2795 return buffer[0];
garfieldsg 0:662207e34fba 2796 }
garfieldsg 0:662207e34fba 2797 /** Set Z-axis accelerometer standby enabled status.
garfieldsg 0:662207e34fba 2798 * @param New Z-axis standby enabled status
garfieldsg 0:662207e34fba 2799 * @see getStandbyZAccelEnabled()
garfieldsg 0:662207e34fba 2800 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2801 * @see MPU6050_PWR2_STBY_ZA_BIT
garfieldsg 0:662207e34fba 2802 */
garfieldsg 0:662207e34fba 2803 void MPU6050::setStandbyZAccelEnabled(bool enabled)
garfieldsg 0:662207e34fba 2804 {
garfieldsg 0:662207e34fba 2805 i2Cdev.writeBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_ZA_BIT, enabled);
garfieldsg 0:662207e34fba 2806 }
garfieldsg 0:662207e34fba 2807 /** Get X-axis gyroscope standby enabled status.
garfieldsg 0:662207e34fba 2808 * If enabled, the X-axis will not gather or report data (or use power).
garfieldsg 0:662207e34fba 2809 * @return Current X-axis standby enabled status
garfieldsg 0:662207e34fba 2810 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2811 * @see MPU6050_PWR2_STBY_XG_BIT
garfieldsg 0:662207e34fba 2812 */
garfieldsg 0:662207e34fba 2813 bool MPU6050::getStandbyXGyroEnabled()
garfieldsg 0:662207e34fba 2814 {
garfieldsg 0:662207e34fba 2815 i2Cdev.readBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_XG_BIT, buffer);
garfieldsg 0:662207e34fba 2816 return buffer[0];
garfieldsg 0:662207e34fba 2817 }
garfieldsg 0:662207e34fba 2818 /** Set X-axis gyroscope standby enabled status.
garfieldsg 0:662207e34fba 2819 * @param New X-axis standby enabled status
garfieldsg 0:662207e34fba 2820 * @see getStandbyXGyroEnabled()
garfieldsg 0:662207e34fba 2821 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2822 * @see MPU6050_PWR2_STBY_XG_BIT
garfieldsg 0:662207e34fba 2823 */
garfieldsg 0:662207e34fba 2824 void MPU6050::setStandbyXGyroEnabled(bool enabled)
garfieldsg 0:662207e34fba 2825 {
garfieldsg 0:662207e34fba 2826 i2Cdev.writeBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_XG_BIT, enabled);
garfieldsg 0:662207e34fba 2827 }
garfieldsg 0:662207e34fba 2828 /** Get Y-axis gyroscope standby enabled status.
garfieldsg 0:662207e34fba 2829 * If enabled, the Y-axis will not gather or report data (or use power).
garfieldsg 0:662207e34fba 2830 * @return Current Y-axis standby enabled status
garfieldsg 0:662207e34fba 2831 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2832 * @see MPU6050_PWR2_STBY_YG_BIT
garfieldsg 0:662207e34fba 2833 */
garfieldsg 0:662207e34fba 2834 bool MPU6050::getStandbyYGyroEnabled()
garfieldsg 0:662207e34fba 2835 {
garfieldsg 0:662207e34fba 2836 i2Cdev.readBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_YG_BIT, buffer);
garfieldsg 0:662207e34fba 2837 return buffer[0];
garfieldsg 0:662207e34fba 2838 }
garfieldsg 0:662207e34fba 2839 /** Set Y-axis gyroscope standby enabled status.
garfieldsg 0:662207e34fba 2840 * @param New Y-axis standby enabled status
garfieldsg 0:662207e34fba 2841 * @see getStandbyYGyroEnabled()
garfieldsg 0:662207e34fba 2842 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2843 * @see MPU6050_PWR2_STBY_YG_BIT
garfieldsg 0:662207e34fba 2844 */
garfieldsg 0:662207e34fba 2845 void MPU6050::setStandbyYGyroEnabled(bool enabled)
garfieldsg 0:662207e34fba 2846 {
garfieldsg 0:662207e34fba 2847 i2Cdev.writeBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_YG_BIT, enabled);
garfieldsg 0:662207e34fba 2848 }
garfieldsg 0:662207e34fba 2849 /** Get Z-axis gyroscope standby enabled status.
garfieldsg 0:662207e34fba 2850 * If enabled, the Z-axis will not gather or report data (or use power).
garfieldsg 0:662207e34fba 2851 * @return Current Z-axis standby enabled status
garfieldsg 0:662207e34fba 2852 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2853 * @see MPU6050_PWR2_STBY_ZG_BIT
garfieldsg 0:662207e34fba 2854 */
garfieldsg 0:662207e34fba 2855 bool MPU6050::getStandbyZGyroEnabled()
garfieldsg 0:662207e34fba 2856 {
garfieldsg 0:662207e34fba 2857 i2Cdev.readBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_ZG_BIT, buffer);
garfieldsg 0:662207e34fba 2858 return buffer[0];
garfieldsg 0:662207e34fba 2859 }
garfieldsg 0:662207e34fba 2860 /** Set Z-axis gyroscope standby enabled status.
garfieldsg 0:662207e34fba 2861 * @param New Z-axis standby enabled status
garfieldsg 0:662207e34fba 2862 * @see getStandbyZGyroEnabled()
garfieldsg 0:662207e34fba 2863 * @see MPU6050_RA_PWR_MGMT_2
garfieldsg 0:662207e34fba 2864 * @see MPU6050_PWR2_STBY_ZG_BIT
garfieldsg 0:662207e34fba 2865 */
garfieldsg 0:662207e34fba 2866 void MPU6050::setStandbyZGyroEnabled(bool enabled)
garfieldsg 0:662207e34fba 2867 {
garfieldsg 0:662207e34fba 2868 i2Cdev.writeBit(devAddr, MPU6050_RA_PWR_MGMT_2, MPU6050_PWR2_STBY_ZG_BIT, enabled);
garfieldsg 0:662207e34fba 2869 }
garfieldsg 0:662207e34fba 2870
garfieldsg 0:662207e34fba 2871 // FIFO_COUNT* registers
garfieldsg 0:662207e34fba 2872
garfieldsg 0:662207e34fba 2873 /** Get current FIFO buffer size.
garfieldsg 0:662207e34fba 2874 * This value indicates the number of bytes stored in the FIFO buffer. This
garfieldsg 0:662207e34fba 2875 * number is in turn the number of bytes that can be read from the FIFO buffer
garfieldsg 0:662207e34fba 2876 * and it is directly proportional to the number of samples available given the
garfieldsg 0:662207e34fba 2877 * set of sensor data bound to be stored in the FIFO (register 35 and 36).
garfieldsg 0:662207e34fba 2878 * @return Current FIFO buffer size
garfieldsg 0:662207e34fba 2879 */
garfieldsg 0:662207e34fba 2880 uint16_t MPU6050::getFIFOCount()
garfieldsg 0:662207e34fba 2881 {
garfieldsg 0:662207e34fba 2882 i2Cdev.readBytes(devAddr, MPU6050_RA_FIFO_COUNTH, 2, buffer);
garfieldsg 0:662207e34fba 2883 return (((uint16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 2884 }
garfieldsg 0:662207e34fba 2885
garfieldsg 0:662207e34fba 2886 // FIFO_R_W register
garfieldsg 0:662207e34fba 2887
garfieldsg 0:662207e34fba 2888 /** Get byte from FIFO buffer.
garfieldsg 0:662207e34fba 2889 * This register is used to read and write data from the FIFO buffer. Data is
garfieldsg 0:662207e34fba 2890 * written to the FIFO in order of register number (from lowest to highest). If
garfieldsg 0:662207e34fba 2891 * all the FIFO enable flags (see below) are enabled and all External Sensor
garfieldsg 0:662207e34fba 2892 * Data registers (Registers 73 to 96) are associated with a Slave device, the
garfieldsg 0:662207e34fba 2893 * contents of registers 59 through 96 will be written in order at the Sample
garfieldsg 0:662207e34fba 2894 * Rate.
garfieldsg 0:662207e34fba 2895 *
garfieldsg 0:662207e34fba 2896 * The contents of the sensor data registers (Registers 59 to 96) are written
garfieldsg 0:662207e34fba 2897 * into the FIFO buffer when their corresponding FIFO enable flags are set to 1
garfieldsg 0:662207e34fba 2898 * in FIFO_EN (Register 35). An additional flag for the sensor data registers
garfieldsg 0:662207e34fba 2899 * associated with I2C Slave 3 can be found in I2C_MST_CTRL (Register 36).
garfieldsg 0:662207e34fba 2900 *
garfieldsg 0:662207e34fba 2901 * If the FIFO buffer has overflowed, the status bit FIFO_OFLOW_INT is
garfieldsg 0:662207e34fba 2902 * automatically set to 1. This bit is located in INT_STATUS (Register 58).
garfieldsg 0:662207e34fba 2903 * When the FIFO buffer has overflowed, the oldest data will be lost and new
garfieldsg 0:662207e34fba 2904 * data will be written to the FIFO.
garfieldsg 0:662207e34fba 2905 *
garfieldsg 0:662207e34fba 2906 * If the FIFO buffer is empty, reading this register will return the last byte
garfieldsg 0:662207e34fba 2907 * that was previously read from the FIFO until new data is available. The user
garfieldsg 0:662207e34fba 2908 * should check FIFO_COUNT to ensure that the FIFO buffer is not read when
garfieldsg 0:662207e34fba 2909 * empty.
garfieldsg 0:662207e34fba 2910 *
garfieldsg 0:662207e34fba 2911 * @return Byte from FIFO buffer
garfieldsg 0:662207e34fba 2912 */
garfieldsg 0:662207e34fba 2913 uint8_t MPU6050::getFIFOByte()
garfieldsg 0:662207e34fba 2914 {
garfieldsg 0:662207e34fba 2915 i2Cdev.readByte(devAddr, MPU6050_RA_FIFO_R_W, buffer);
garfieldsg 0:662207e34fba 2916 return buffer[0];
garfieldsg 0:662207e34fba 2917 }
garfieldsg 0:662207e34fba 2918 void MPU6050::getFIFOBytes(uint8_t *data, uint8_t length)
garfieldsg 0:662207e34fba 2919 {
garfieldsg 0:662207e34fba 2920 i2Cdev.readBytes(devAddr, MPU6050_RA_FIFO_R_W, length, data);
garfieldsg 0:662207e34fba 2921 }
garfieldsg 0:662207e34fba 2922 /** Write byte to FIFO buffer.
garfieldsg 0:662207e34fba 2923 * @see getFIFOByte()
garfieldsg 0:662207e34fba 2924 * @see MPU6050_RA_FIFO_R_W
garfieldsg 0:662207e34fba 2925 */
garfieldsg 0:662207e34fba 2926 void MPU6050::setFIFOByte(uint8_t data)
garfieldsg 0:662207e34fba 2927 {
garfieldsg 0:662207e34fba 2928 i2Cdev.writeByte(devAddr, MPU6050_RA_FIFO_R_W, data);
garfieldsg 0:662207e34fba 2929 }
garfieldsg 0:662207e34fba 2930
garfieldsg 0:662207e34fba 2931 // WHO_AM_I register
garfieldsg 0:662207e34fba 2932
garfieldsg 0:662207e34fba 2933 /** Get Device ID.
garfieldsg 0:662207e34fba 2934 * This register is used to verify the identity of the device (0b110100, 0x34).
garfieldsg 0:662207e34fba 2935 * @return Device ID (6 bits only! should be 0x34)
garfieldsg 0:662207e34fba 2936 * @see MPU6050_RA_WHO_AM_I
garfieldsg 0:662207e34fba 2937 * @see MPU6050_WHO_AM_I_BIT
garfieldsg 0:662207e34fba 2938 * @see MPU6050_WHO_AM_I_LENGTH
garfieldsg 0:662207e34fba 2939 */
garfieldsg 0:662207e34fba 2940 uint8_t MPU6050::getDeviceID()
garfieldsg 0:662207e34fba 2941 {
garfieldsg 0:662207e34fba 2942 i2Cdev.readBits(devAddr, MPU6050_RA_WHO_AM_I, MPU6050_WHO_AM_I_BIT, MPU6050_WHO_AM_I_LENGTH, buffer);
garfieldsg 0:662207e34fba 2943 return buffer[0];
garfieldsg 0:662207e34fba 2944 }
garfieldsg 0:662207e34fba 2945 /** Set Device ID.
garfieldsg 0:662207e34fba 2946 * Write a new ID into the WHO_AM_I register (no idea why this should ever be
garfieldsg 0:662207e34fba 2947 * necessary though).
garfieldsg 0:662207e34fba 2948 * @param id New device ID to set.
garfieldsg 0:662207e34fba 2949 * @see getDeviceID()
garfieldsg 0:662207e34fba 2950 * @see MPU6050_RA_WHO_AM_I
garfieldsg 0:662207e34fba 2951 * @see MPU6050_WHO_AM_I_BIT
garfieldsg 0:662207e34fba 2952 * @see MPU6050_WHO_AM_I_LENGTH
garfieldsg 0:662207e34fba 2953 */
garfieldsg 0:662207e34fba 2954 void MPU6050::setDeviceID(uint8_t id)
garfieldsg 0:662207e34fba 2955 {
garfieldsg 0:662207e34fba 2956 i2Cdev.writeBits(devAddr, MPU6050_RA_WHO_AM_I, MPU6050_WHO_AM_I_BIT, MPU6050_WHO_AM_I_LENGTH, id);
garfieldsg 0:662207e34fba 2957 }
garfieldsg 0:662207e34fba 2958
garfieldsg 0:662207e34fba 2959 // ======== UNDOCUMENTED/DMP REGISTERS/METHODS ========
garfieldsg 0:662207e34fba 2960
garfieldsg 0:662207e34fba 2961 // XG_OFFS_TC register
garfieldsg 0:662207e34fba 2962
garfieldsg 0:662207e34fba 2963 uint8_t MPU6050::getOTPBankValid()
garfieldsg 0:662207e34fba 2964 {
garfieldsg 0:662207e34fba 2965 i2Cdev.readBit(devAddr, MPU6050_RA_XG_OFFS_TC, MPU6050_TC_OTP_BNK_VLD_BIT, buffer);
garfieldsg 0:662207e34fba 2966 return buffer[0];
garfieldsg 0:662207e34fba 2967 }
garfieldsg 0:662207e34fba 2968 void MPU6050::setOTPBankValid(bool enabled)
garfieldsg 0:662207e34fba 2969 {
garfieldsg 0:662207e34fba 2970 i2Cdev.writeBit(devAddr, MPU6050_RA_XG_OFFS_TC, MPU6050_TC_OTP_BNK_VLD_BIT, enabled);
garfieldsg 0:662207e34fba 2971 }
garfieldsg 0:662207e34fba 2972 int8_t MPU6050::getXGyroOffset()
garfieldsg 0:662207e34fba 2973 {
garfieldsg 0:662207e34fba 2974 i2Cdev.readBits(devAddr, MPU6050_RA_XG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, buffer);
garfieldsg 0:662207e34fba 2975 return buffer[0];
garfieldsg 0:662207e34fba 2976 }
garfieldsg 0:662207e34fba 2977 void MPU6050::setXGyroOffset(int8_t offset)
garfieldsg 0:662207e34fba 2978 {
garfieldsg 0:662207e34fba 2979 i2Cdev.writeBits(devAddr, MPU6050_RA_XG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, offset);
garfieldsg 0:662207e34fba 2980 }
garfieldsg 0:662207e34fba 2981
garfieldsg 0:662207e34fba 2982 // YG_OFFS_TC register
garfieldsg 0:662207e34fba 2983
garfieldsg 0:662207e34fba 2984 int8_t MPU6050::getYGyroOffset()
garfieldsg 0:662207e34fba 2985 {
garfieldsg 0:662207e34fba 2986 i2Cdev.readBits(devAddr, MPU6050_RA_YG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, buffer);
garfieldsg 0:662207e34fba 2987 return buffer[0];
garfieldsg 0:662207e34fba 2988 }
garfieldsg 0:662207e34fba 2989 void MPU6050::setYGyroOffset(int8_t offset)
garfieldsg 0:662207e34fba 2990 {
garfieldsg 0:662207e34fba 2991 i2Cdev.writeBits(devAddr, MPU6050_RA_YG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, offset);
garfieldsg 0:662207e34fba 2992 }
garfieldsg 0:662207e34fba 2993
garfieldsg 0:662207e34fba 2994 // ZG_OFFS_TC register
garfieldsg 0:662207e34fba 2995
garfieldsg 0:662207e34fba 2996 int8_t MPU6050::getZGyroOffset()
garfieldsg 0:662207e34fba 2997 {
garfieldsg 0:662207e34fba 2998 i2Cdev.readBits(devAddr, MPU6050_RA_ZG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, buffer);
garfieldsg 0:662207e34fba 2999 return buffer[0];
garfieldsg 0:662207e34fba 3000 }
garfieldsg 0:662207e34fba 3001 void MPU6050::setZGyroOffset(int8_t offset)
garfieldsg 0:662207e34fba 3002 {
garfieldsg 0:662207e34fba 3003 i2Cdev.writeBits(devAddr, MPU6050_RA_ZG_OFFS_TC, MPU6050_TC_OFFSET_BIT, MPU6050_TC_OFFSET_LENGTH, offset);
garfieldsg 0:662207e34fba 3004 }
garfieldsg 0:662207e34fba 3005
garfieldsg 0:662207e34fba 3006 // X_FINE_GAIN register
garfieldsg 0:662207e34fba 3007
garfieldsg 0:662207e34fba 3008 int8_t MPU6050::getXFineGain()
garfieldsg 0:662207e34fba 3009 {
garfieldsg 0:662207e34fba 3010 i2Cdev.readByte(devAddr, MPU6050_RA_X_FINE_GAIN, buffer);
garfieldsg 0:662207e34fba 3011 return buffer[0];
garfieldsg 0:662207e34fba 3012 }
garfieldsg 0:662207e34fba 3013 void MPU6050::setXFineGain(int8_t gain)
garfieldsg 0:662207e34fba 3014 {
garfieldsg 0:662207e34fba 3015 i2Cdev.writeByte(devAddr, MPU6050_RA_X_FINE_GAIN, gain);
garfieldsg 0:662207e34fba 3016 }
garfieldsg 0:662207e34fba 3017
garfieldsg 0:662207e34fba 3018 // Y_FINE_GAIN register
garfieldsg 0:662207e34fba 3019
garfieldsg 0:662207e34fba 3020 int8_t MPU6050::getYFineGain()
garfieldsg 0:662207e34fba 3021 {
garfieldsg 0:662207e34fba 3022 i2Cdev.readByte(devAddr, MPU6050_RA_Y_FINE_GAIN, buffer);
garfieldsg 0:662207e34fba 3023 return buffer[0];
garfieldsg 0:662207e34fba 3024 }
garfieldsg 0:662207e34fba 3025 void MPU6050::setYFineGain(int8_t gain)
garfieldsg 0:662207e34fba 3026 {
garfieldsg 0:662207e34fba 3027 i2Cdev.writeByte(devAddr, MPU6050_RA_Y_FINE_GAIN, gain);
garfieldsg 0:662207e34fba 3028 }
garfieldsg 0:662207e34fba 3029
garfieldsg 0:662207e34fba 3030 // Z_FINE_GAIN register
garfieldsg 0:662207e34fba 3031
garfieldsg 0:662207e34fba 3032 int8_t MPU6050::getZFineGain()
garfieldsg 0:662207e34fba 3033 {
garfieldsg 0:662207e34fba 3034 i2Cdev.readByte(devAddr, MPU6050_RA_Z_FINE_GAIN, buffer);
garfieldsg 0:662207e34fba 3035 return buffer[0];
garfieldsg 0:662207e34fba 3036 }
garfieldsg 0:662207e34fba 3037 void MPU6050::setZFineGain(int8_t gain)
garfieldsg 0:662207e34fba 3038 {
garfieldsg 0:662207e34fba 3039 i2Cdev.writeByte(devAddr, MPU6050_RA_Z_FINE_GAIN, gain);
garfieldsg 0:662207e34fba 3040 }
garfieldsg 0:662207e34fba 3041
garfieldsg 0:662207e34fba 3042 // XA_OFFS_* registers
garfieldsg 0:662207e34fba 3043
garfieldsg 0:662207e34fba 3044 int16_t MPU6050::getXAccelOffset()
garfieldsg 0:662207e34fba 3045 {
garfieldsg 0:662207e34fba 3046 i2Cdev.readBytes(devAddr, MPU6050_RA_XA_OFFS_H, 2, buffer);
garfieldsg 0:662207e34fba 3047 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 3048 }
garfieldsg 0:662207e34fba 3049 void MPU6050::setXAccelOffset(int16_t offset)
garfieldsg 0:662207e34fba 3050 {
garfieldsg 0:662207e34fba 3051 i2Cdev.writeWord(devAddr, MPU6050_RA_XA_OFFS_H, offset);
garfieldsg 0:662207e34fba 3052 }
garfieldsg 0:662207e34fba 3053
garfieldsg 0:662207e34fba 3054 // YA_OFFS_* register
garfieldsg 0:662207e34fba 3055
garfieldsg 0:662207e34fba 3056 int16_t MPU6050::getYAccelOffset()
garfieldsg 0:662207e34fba 3057 {
garfieldsg 0:662207e34fba 3058 i2Cdev.readBytes(devAddr, MPU6050_RA_YA_OFFS_H, 2, buffer);
garfieldsg 0:662207e34fba 3059 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 3060 }
garfieldsg 0:662207e34fba 3061 void MPU6050::setYAccelOffset(int16_t offset)
garfieldsg 0:662207e34fba 3062 {
garfieldsg 0:662207e34fba 3063 i2Cdev.writeWord(devAddr, MPU6050_RA_YA_OFFS_H, offset);
garfieldsg 0:662207e34fba 3064 }
garfieldsg 0:662207e34fba 3065
garfieldsg 0:662207e34fba 3066 // ZA_OFFS_* register
garfieldsg 0:662207e34fba 3067
garfieldsg 0:662207e34fba 3068 int16_t MPU6050::getZAccelOffset()
garfieldsg 0:662207e34fba 3069 {
garfieldsg 0:662207e34fba 3070 i2Cdev.readBytes(devAddr, MPU6050_RA_ZA_OFFS_H, 2, buffer);
garfieldsg 0:662207e34fba 3071 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 3072 }
garfieldsg 0:662207e34fba 3073 void MPU6050::setZAccelOffset(int16_t offset)
garfieldsg 0:662207e34fba 3074 {
garfieldsg 0:662207e34fba 3075 i2Cdev.writeWord(devAddr, MPU6050_RA_ZA_OFFS_H, offset);
garfieldsg 0:662207e34fba 3076 }
garfieldsg 0:662207e34fba 3077
garfieldsg 0:662207e34fba 3078 // XG_OFFS_USR* registers
garfieldsg 0:662207e34fba 3079
garfieldsg 0:662207e34fba 3080 int16_t MPU6050::getXGyroOffsetUser()
garfieldsg 0:662207e34fba 3081 {
garfieldsg 0:662207e34fba 3082 i2Cdev.readBytes(devAddr, MPU6050_RA_XG_OFFS_USRH, 2, buffer);
garfieldsg 0:662207e34fba 3083 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 3084 }
garfieldsg 0:662207e34fba 3085 void MPU6050::setXGyroOffsetUser(int16_t offset)
garfieldsg 0:662207e34fba 3086 {
garfieldsg 0:662207e34fba 3087 i2Cdev.writeWord(devAddr, MPU6050_RA_XG_OFFS_USRH, offset);
garfieldsg 0:662207e34fba 3088 }
garfieldsg 0:662207e34fba 3089
garfieldsg 0:662207e34fba 3090 // YG_OFFS_USR* register
garfieldsg 0:662207e34fba 3091
garfieldsg 0:662207e34fba 3092 int16_t MPU6050::getYGyroOffsetUser()
garfieldsg 0:662207e34fba 3093 {
garfieldsg 0:662207e34fba 3094 i2Cdev.readBytes(devAddr, MPU6050_RA_YG_OFFS_USRH, 2, buffer);
garfieldsg 0:662207e34fba 3095 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 3096 }
garfieldsg 0:662207e34fba 3097 void MPU6050::setYGyroOffsetUser(int16_t offset)
garfieldsg 0:662207e34fba 3098 {
garfieldsg 0:662207e34fba 3099 i2Cdev.writeWord(devAddr, MPU6050_RA_YG_OFFS_USRH, offset);
garfieldsg 0:662207e34fba 3100 }
garfieldsg 0:662207e34fba 3101
garfieldsg 0:662207e34fba 3102 // ZG_OFFS_USR* register
garfieldsg 0:662207e34fba 3103
garfieldsg 0:662207e34fba 3104 int16_t MPU6050::getZGyroOffsetUser()
garfieldsg 0:662207e34fba 3105 {
garfieldsg 0:662207e34fba 3106 i2Cdev.readBytes(devAddr, MPU6050_RA_ZG_OFFS_USRH, 2, buffer);
garfieldsg 0:662207e34fba 3107 return (((int16_t)buffer[0]) << 8) | buffer[1];
garfieldsg 0:662207e34fba 3108 }
garfieldsg 0:662207e34fba 3109 void MPU6050::setZGyroOffsetUser(int16_t offset)
garfieldsg 0:662207e34fba 3110 {
garfieldsg 0:662207e34fba 3111 i2Cdev.writeWord(devAddr, MPU6050_RA_ZG_OFFS_USRH, offset);
garfieldsg 0:662207e34fba 3112 }
garfieldsg 0:662207e34fba 3113
garfieldsg 0:662207e34fba 3114 // INT_ENABLE register (DMP functions)
garfieldsg 0:662207e34fba 3115
garfieldsg 0:662207e34fba 3116 bool MPU6050::getIntPLLReadyEnabled()
garfieldsg 0:662207e34fba 3117 {
garfieldsg 0:662207e34fba 3118 i2Cdev.readBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_PLL_RDY_INT_BIT, buffer);
garfieldsg 0:662207e34fba 3119 return buffer[0];
garfieldsg 0:662207e34fba 3120 }
garfieldsg 0:662207e34fba 3121 void MPU6050::setIntPLLReadyEnabled(bool enabled)
garfieldsg 0:662207e34fba 3122 {
garfieldsg 0:662207e34fba 3123 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_PLL_RDY_INT_BIT, enabled);
garfieldsg 0:662207e34fba 3124 }
garfieldsg 0:662207e34fba 3125 bool MPU6050::getIntDMPEnabled()
garfieldsg 0:662207e34fba 3126 {
garfieldsg 0:662207e34fba 3127 i2Cdev.readBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_DMP_INT_BIT, buffer);
garfieldsg 0:662207e34fba 3128 return buffer[0];
garfieldsg 0:662207e34fba 3129 }
garfieldsg 0:662207e34fba 3130 void MPU6050::setIntDMPEnabled(bool enabled)
garfieldsg 0:662207e34fba 3131 {
garfieldsg 0:662207e34fba 3132 i2Cdev.writeBit(devAddr, MPU6050_RA_INT_ENABLE, MPU6050_INTERRUPT_DMP_INT_BIT, enabled);
garfieldsg 0:662207e34fba 3133 }
garfieldsg 0:662207e34fba 3134
garfieldsg 0:662207e34fba 3135 // DMP_INT_STATUS
garfieldsg 0:662207e34fba 3136
garfieldsg 0:662207e34fba 3137 bool MPU6050::getDMPInt5Status()
garfieldsg 0:662207e34fba 3138 {
garfieldsg 0:662207e34fba 3139 i2Cdev.readBit(devAddr, MPU6050_RA_DMP_INT_STATUS, MPU6050_DMPINT_5_BIT, buffer);
garfieldsg 0:662207e34fba 3140 return buffer[0];
garfieldsg 0:662207e34fba 3141 }
garfieldsg 0:662207e34fba 3142 bool MPU6050::getDMPInt4Status()
garfieldsg 0:662207e34fba 3143 {
garfieldsg 0:662207e34fba 3144 i2Cdev.readBit(devAddr, MPU6050_RA_DMP_INT_STATUS, MPU6050_DMPINT_4_BIT, buffer);
garfieldsg 0:662207e34fba 3145 return buffer[0];
garfieldsg 0:662207e34fba 3146 }
garfieldsg 0:662207e34fba 3147 bool MPU6050::getDMPInt3Status()
garfieldsg 0:662207e34fba 3148 {
garfieldsg 0:662207e34fba 3149 i2Cdev.readBit(devAddr, MPU6050_RA_DMP_INT_STATUS, MPU6050_DMPINT_3_BIT, buffer);
garfieldsg 0:662207e34fba 3150 return buffer[0];
garfieldsg 0:662207e34fba 3151 }
garfieldsg 0:662207e34fba 3152 bool MPU6050::getDMPInt2Status()
garfieldsg 0:662207e34fba 3153 {
garfieldsg 0:662207e34fba 3154 i2Cdev.readBit(devAddr, MPU6050_RA_DMP_INT_STATUS, MPU6050_DMPINT_2_BIT, buffer);
garfieldsg 0:662207e34fba 3155 return buffer[0];
garfieldsg 0:662207e34fba 3156 }
garfieldsg 0:662207e34fba 3157 bool MPU6050::getDMPInt1Status()
garfieldsg 0:662207e34fba 3158 {
garfieldsg 0:662207e34fba 3159 i2Cdev.readBit(devAddr, MPU6050_RA_DMP_INT_STATUS, MPU6050_DMPINT_1_BIT, buffer);
garfieldsg 0:662207e34fba 3160 return buffer[0];
garfieldsg 0:662207e34fba 3161 }
garfieldsg 0:662207e34fba 3162 bool MPU6050::getDMPInt0Status()
garfieldsg 0:662207e34fba 3163 {
garfieldsg 0:662207e34fba 3164 i2Cdev.readBit(devAddr, MPU6050_RA_DMP_INT_STATUS, MPU6050_DMPINT_0_BIT, buffer);
garfieldsg 0:662207e34fba 3165 return buffer[0];
garfieldsg 0:662207e34fba 3166 }
garfieldsg 0:662207e34fba 3167
garfieldsg 0:662207e34fba 3168 // INT_STATUS register (DMP functions)
garfieldsg 0:662207e34fba 3169
garfieldsg 0:662207e34fba 3170 bool MPU6050::getIntPLLReadyStatus()
garfieldsg 0:662207e34fba 3171 {
garfieldsg 0:662207e34fba 3172 i2Cdev.readBit(devAddr, MPU6050_RA_INT_STATUS, MPU6050_INTERRUPT_PLL_RDY_INT_BIT, buffer);
garfieldsg 0:662207e34fba 3173 return buffer[0];
garfieldsg 0:662207e34fba 3174 }
garfieldsg 0:662207e34fba 3175 bool MPU6050::getIntDMPStatus()
garfieldsg 0:662207e34fba 3176 {
garfieldsg 0:662207e34fba 3177 i2Cdev.readBit(devAddr, MPU6050_RA_INT_STATUS, MPU6050_INTERRUPT_DMP_INT_BIT, buffer);
garfieldsg 0:662207e34fba 3178 return buffer[0];
garfieldsg 0:662207e34fba 3179 }
garfieldsg 0:662207e34fba 3180
garfieldsg 0:662207e34fba 3181 // USER_CTRL register (DMP functions)
garfieldsg 0:662207e34fba 3182
garfieldsg 0:662207e34fba 3183 bool MPU6050::getDMPEnabled()
garfieldsg 0:662207e34fba 3184 {
garfieldsg 0:662207e34fba 3185 i2Cdev.readBit(devAddr, MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_DMP_EN_BIT, buffer);
garfieldsg 0:662207e34fba 3186 return buffer[0];
garfieldsg 0:662207e34fba 3187 }
garfieldsg 0:662207e34fba 3188 void MPU6050::setDMPEnabled(bool enabled)
garfieldsg 0:662207e34fba 3189 {
garfieldsg 0:662207e34fba 3190 i2Cdev.writeBit(devAddr, MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_DMP_EN_BIT, enabled);
garfieldsg 0:662207e34fba 3191 }
garfieldsg 0:662207e34fba 3192 void MPU6050::resetDMP()
garfieldsg 0:662207e34fba 3193 {
garfieldsg 0:662207e34fba 3194 i2Cdev.writeBit(devAddr, MPU6050_RA_USER_CTRL, MPU6050_USERCTRL_DMP_RESET_BIT, true);
garfieldsg 0:662207e34fba 3195 }
garfieldsg 0:662207e34fba 3196
garfieldsg 0:662207e34fba 3197 // BANK_SEL register
garfieldsg 0:662207e34fba 3198
garfieldsg 0:662207e34fba 3199 void MPU6050::setMemoryBank(uint8_t bank, bool prefetchEnabled, bool userBank)
garfieldsg 0:662207e34fba 3200 {
garfieldsg 0:662207e34fba 3201 bank &= 0x1F;
garfieldsg 0:662207e34fba 3202 if (userBank) bank |= 0x20;
garfieldsg 0:662207e34fba 3203 if (prefetchEnabled) bank |= 0x40;
garfieldsg 0:662207e34fba 3204 i2Cdev.writeByte(devAddr, MPU6050_RA_BANK_SEL, bank);
garfieldsg 0:662207e34fba 3205 }
garfieldsg 0:662207e34fba 3206
garfieldsg 0:662207e34fba 3207 // MEM_START_ADDR register
garfieldsg 0:662207e34fba 3208
garfieldsg 0:662207e34fba 3209 void MPU6050::setMemoryStartAddress(uint8_t address)
garfieldsg 0:662207e34fba 3210 {
garfieldsg 0:662207e34fba 3211 i2Cdev.writeByte(devAddr, MPU6050_RA_MEM_START_ADDR, address);
garfieldsg 0:662207e34fba 3212 }
garfieldsg 0:662207e34fba 3213
garfieldsg 0:662207e34fba 3214 // MEM_R_W register
garfieldsg 0:662207e34fba 3215
garfieldsg 0:662207e34fba 3216 uint8_t MPU6050::readMemoryByte()
garfieldsg 0:662207e34fba 3217 {
garfieldsg 0:662207e34fba 3218 i2Cdev.readByte(devAddr, MPU6050_RA_MEM_R_W, buffer);
garfieldsg 0:662207e34fba 3219 return buffer[0];
garfieldsg 0:662207e34fba 3220 }
garfieldsg 0:662207e34fba 3221 void MPU6050::writeMemoryByte(uint8_t data)
garfieldsg 0:662207e34fba 3222 {
garfieldsg 0:662207e34fba 3223 i2Cdev.writeByte(devAddr, MPU6050_RA_MEM_R_W, data);
garfieldsg 0:662207e34fba 3224 }
garfieldsg 0:662207e34fba 3225 void MPU6050::readMemoryBlock(uint8_t *data, uint16_t dataSize, uint8_t bank, uint8_t address)
garfieldsg 0:662207e34fba 3226 {
garfieldsg 0:662207e34fba 3227 setMemoryBank(bank);
garfieldsg 0:662207e34fba 3228 setMemoryStartAddress(address);
garfieldsg 0:662207e34fba 3229 uint8_t chunkSize;
garfieldsg 0:662207e34fba 3230 for (uint16_t i = 0; i < dataSize;) {
garfieldsg 0:662207e34fba 3231 // determine correct chunk size according to bank position and data size
garfieldsg 0:662207e34fba 3232 chunkSize = MPU6050_DMP_MEMORY_CHUNK_SIZE;
garfieldsg 0:662207e34fba 3233
garfieldsg 0:662207e34fba 3234 // make sure we don't go past the data size
garfieldsg 0:662207e34fba 3235 if (i + chunkSize > dataSize) chunkSize = dataSize - i;
garfieldsg 0:662207e34fba 3236
garfieldsg 0:662207e34fba 3237 // make sure this chunk doesn't go past the bank boundary (256 bytes)
garfieldsg 0:662207e34fba 3238 if (chunkSize > 256 - address) chunkSize = 256 - address;
garfieldsg 0:662207e34fba 3239
garfieldsg 0:662207e34fba 3240 // read the chunk of data as specified
garfieldsg 0:662207e34fba 3241 i2Cdev.readBytes(devAddr, MPU6050_RA_MEM_R_W, chunkSize, data + i);
garfieldsg 0:662207e34fba 3242
garfieldsg 0:662207e34fba 3243 // increase byte index by [chunkSize]
garfieldsg 0:662207e34fba 3244 i += chunkSize;
garfieldsg 0:662207e34fba 3245
garfieldsg 0:662207e34fba 3246 // uint8_t automatically wraps to 0 at 256
garfieldsg 0:662207e34fba 3247 address += chunkSize;
garfieldsg 0:662207e34fba 3248
garfieldsg 0:662207e34fba 3249 // if we aren't done, update bank (if necessary) and address
garfieldsg 0:662207e34fba 3250 if (i < dataSize) {
garfieldsg 0:662207e34fba 3251 if (address == 0) bank++;
garfieldsg 0:662207e34fba 3252 setMemoryBank(bank);
garfieldsg 0:662207e34fba 3253 setMemoryStartAddress(address);
garfieldsg 0:662207e34fba 3254 }
garfieldsg 0:662207e34fba 3255 }
garfieldsg 0:662207e34fba 3256 }
garfieldsg 0:662207e34fba 3257 bool MPU6050::writeMemoryBlock(const uint8_t *data, uint16_t dataSize, uint8_t bank, uint8_t address, bool verify, bool useProgMem)
garfieldsg 0:662207e34fba 3258 {
garfieldsg 0:662207e34fba 3259 setMemoryBank(bank);
garfieldsg 0:662207e34fba 3260 setMemoryStartAddress(address);
garfieldsg 0:662207e34fba 3261 uint8_t chunkSize;
akode 2:f8bfb37b2e1f 3262 uint8_t *verifyBuffer = NULL;
akode 2:f8bfb37b2e1f 3263 uint8_t *progBuffer = NULL;
garfieldsg 0:662207e34fba 3264 uint16_t i;
garfieldsg 0:662207e34fba 3265 uint8_t j;
garfieldsg 0:662207e34fba 3266 if (verify) verifyBuffer = (uint8_t *)malloc(MPU6050_DMP_MEMORY_CHUNK_SIZE);
garfieldsg 0:662207e34fba 3267 if (useProgMem) progBuffer = (uint8_t *)malloc(MPU6050_DMP_MEMORY_CHUNK_SIZE);
garfieldsg 0:662207e34fba 3268 for (i = 0; i < dataSize;) {
garfieldsg 0:662207e34fba 3269 // determine correct chunk size according to bank position and data size
garfieldsg 0:662207e34fba 3270 chunkSize = MPU6050_DMP_MEMORY_CHUNK_SIZE;
garfieldsg 0:662207e34fba 3271
garfieldsg 0:662207e34fba 3272 // make sure we don't go past the data size
garfieldsg 0:662207e34fba 3273 if (i + chunkSize > dataSize) chunkSize = dataSize - i;
garfieldsg 0:662207e34fba 3274
garfieldsg 0:662207e34fba 3275 // make sure this chunk doesn't go past the bank boundary (256 bytes)
garfieldsg 0:662207e34fba 3276 if (chunkSize > 256 - address) chunkSize = 256 - address;
garfieldsg 0:662207e34fba 3277
garfieldsg 0:662207e34fba 3278 if (useProgMem) {
garfieldsg 0:662207e34fba 3279 // write the chunk of data as specified
garfieldsg 0:662207e34fba 3280 for (j = 0; j < chunkSize; j++) progBuffer[j] = pgm_read_byte(data + i + j);
garfieldsg 0:662207e34fba 3281 } else {
garfieldsg 0:662207e34fba 3282 // write the chunk of data as specified
garfieldsg 0:662207e34fba 3283 progBuffer = (uint8_t *)data + i;
garfieldsg 0:662207e34fba 3284 }
garfieldsg 0:662207e34fba 3285
garfieldsg 0:662207e34fba 3286 i2Cdev.writeBytes(devAddr, MPU6050_RA_MEM_R_W, chunkSize, progBuffer);
garfieldsg 0:662207e34fba 3287
garfieldsg 0:662207e34fba 3288 // verify data if needed
garfieldsg 0:662207e34fba 3289 if (verify && verifyBuffer) {
garfieldsg 0:662207e34fba 3290 setMemoryBank(bank);
garfieldsg 0:662207e34fba 3291 setMemoryStartAddress(address);
garfieldsg 0:662207e34fba 3292 i2Cdev.readBytes(devAddr, MPU6050_RA_MEM_R_W, chunkSize, verifyBuffer);
garfieldsg 0:662207e34fba 3293 if (memcmp(progBuffer, verifyBuffer, chunkSize) != 0) {
garfieldsg 0:662207e34fba 3294 /*Serial.print("Block write verification error, bank ");
garfieldsg 0:662207e34fba 3295 Serial.print(bank, DEC);
garfieldsg 0:662207e34fba 3296 Serial.print(", address ");
garfieldsg 0:662207e34fba 3297 Serial.print(address, DEC);
garfieldsg 0:662207e34fba 3298 Serial.print("!\nExpected:");
garfieldsg 0:662207e34fba 3299 for (j = 0; j < chunkSize; j++) {
garfieldsg 0:662207e34fba 3300 Serial.print(" 0x");
garfieldsg 0:662207e34fba 3301 if (progBuffer[j] < 16) Serial.print("0");
garfieldsg 0:662207e34fba 3302 Serial.print(progBuffer[j], HEX);
garfieldsg 0:662207e34fba 3303 }
garfieldsg 0:662207e34fba 3304 Serial.print("\nReceived:");
garfieldsg 0:662207e34fba 3305 for (uint8_t j = 0; j < chunkSize; j++) {
garfieldsg 0:662207e34fba 3306 Serial.print(" 0x");
garfieldsg 0:662207e34fba 3307 if (verifyBuffer[i + j] < 16) Serial.print("0");
garfieldsg 0:662207e34fba 3308 Serial.print(verifyBuffer[i + j], HEX);
garfieldsg 0:662207e34fba 3309 }
garfieldsg 0:662207e34fba 3310 Serial.print("\n");*/
garfieldsg 0:662207e34fba 3311 free(verifyBuffer);
garfieldsg 0:662207e34fba 3312 if (useProgMem) free(progBuffer);
garfieldsg 0:662207e34fba 3313 return false; // uh oh.
garfieldsg 0:662207e34fba 3314 }
garfieldsg 0:662207e34fba 3315 }
garfieldsg 0:662207e34fba 3316
garfieldsg 0:662207e34fba 3317 // increase byte index by [chunkSize]
garfieldsg 0:662207e34fba 3318 i += chunkSize;
garfieldsg 0:662207e34fba 3319
garfieldsg 0:662207e34fba 3320 // uint8_t automatically wraps to 0 at 256
garfieldsg 0:662207e34fba 3321 address += chunkSize;
garfieldsg 0:662207e34fba 3322
garfieldsg 0:662207e34fba 3323 // if we aren't done, update bank (if necessary) and address
garfieldsg 0:662207e34fba 3324 if (i < dataSize) {
garfieldsg 0:662207e34fba 3325 if (address == 0) bank++;
garfieldsg 0:662207e34fba 3326 setMemoryBank(bank);
garfieldsg 0:662207e34fba 3327 setMemoryStartAddress(address);
garfieldsg 0:662207e34fba 3328 }
garfieldsg 0:662207e34fba 3329 }
garfieldsg 0:662207e34fba 3330 if (verify) free(verifyBuffer);
garfieldsg 0:662207e34fba 3331 if (useProgMem) free(progBuffer);
garfieldsg 0:662207e34fba 3332 return true;
garfieldsg 0:662207e34fba 3333 }
garfieldsg 0:662207e34fba 3334 bool MPU6050::writeProgMemoryBlock(const uint8_t *data, uint16_t dataSize, uint8_t bank, uint8_t address, bool verify)
garfieldsg 0:662207e34fba 3335 {
garfieldsg 0:662207e34fba 3336 return writeMemoryBlock(data, dataSize, bank, address, verify, true);
garfieldsg 0:662207e34fba 3337 }
garfieldsg 0:662207e34fba 3338 bool MPU6050::writeDMPConfigurationSet(const uint8_t *data, uint16_t dataSize, bool useProgMem)
garfieldsg 0:662207e34fba 3339 {
akode 2:f8bfb37b2e1f 3340 uint8_t success, special;
akode 2:f8bfb37b2e1f 3341 uint8_t *progBuffer = NULL;
garfieldsg 0:662207e34fba 3342 uint16_t i, j;
garfieldsg 0:662207e34fba 3343 if (useProgMem) {
garfieldsg 0:662207e34fba 3344 progBuffer = (uint8_t *)malloc(8); // assume 8-byte blocks, realloc later if necessary
garfieldsg 0:662207e34fba 3345 }
garfieldsg 0:662207e34fba 3346
garfieldsg 0:662207e34fba 3347 // config set data is a long string of blocks with the following structure:
garfieldsg 0:662207e34fba 3348 // [bank] [offset] [length] [byte[0], byte[1], ..., byte[length]]
garfieldsg 0:662207e34fba 3349 uint8_t bank, offset, length;
garfieldsg 0:662207e34fba 3350 for (i = 0; i < dataSize;) {
garfieldsg 0:662207e34fba 3351 if (useProgMem) {
garfieldsg 0:662207e34fba 3352 bank = pgm_read_byte(data + i++);
garfieldsg 0:662207e34fba 3353 offset = pgm_read_byte(data + i++);
garfieldsg 0:662207e34fba 3354 length = pgm_read_byte(data + i++);
garfieldsg 0:662207e34fba 3355 } else {
garfieldsg 0:662207e34fba 3356 bank = data[i++];
garfieldsg 0:662207e34fba 3357 offset = data[i++];
garfieldsg 0:662207e34fba 3358 length = data[i++];
garfieldsg 0:662207e34fba 3359 }
garfieldsg 0:662207e34fba 3360
garfieldsg 0:662207e34fba 3361 // write data or perform special action
garfieldsg 0:662207e34fba 3362 if (length > 0) {
garfieldsg 0:662207e34fba 3363 // regular block of data to write
garfieldsg 0:662207e34fba 3364 /*Serial.print("Writing config block to bank ");
garfieldsg 0:662207e34fba 3365 Serial.print(bank);
garfieldsg 0:662207e34fba 3366 Serial.print(", offset ");
garfieldsg 0:662207e34fba 3367 Serial.print(offset);
garfieldsg 0:662207e34fba 3368 Serial.print(", length=");
garfieldsg 0:662207e34fba 3369 Serial.println(length);*/
garfieldsg 0:662207e34fba 3370 if (useProgMem) {
garfieldsg 0:662207e34fba 3371 if (sizeof(progBuffer) < length) progBuffer = (uint8_t *)realloc(progBuffer, length);
garfieldsg 0:662207e34fba 3372 for (j = 0; j < length; j++) progBuffer[j] = pgm_read_byte(data + i + j);
garfieldsg 0:662207e34fba 3373 } else {
garfieldsg 0:662207e34fba 3374 progBuffer = (uint8_t *)data + i;
garfieldsg 0:662207e34fba 3375 }
garfieldsg 0:662207e34fba 3376 success = writeMemoryBlock(progBuffer, length, bank, offset, true);
garfieldsg 0:662207e34fba 3377 i += length;
garfieldsg 0:662207e34fba 3378 } else {
garfieldsg 0:662207e34fba 3379 // special instruction
garfieldsg 0:662207e34fba 3380 // NOTE: this kind of behavior (what and when to do certain things)
garfieldsg 0:662207e34fba 3381 // is totally undocumented. This code is in here based on observed
garfieldsg 0:662207e34fba 3382 // behavior only, and exactly why (or even whether) it has to be here
garfieldsg 0:662207e34fba 3383 // is anybody's guess for now.
garfieldsg 0:662207e34fba 3384 if (useProgMem) {
garfieldsg 0:662207e34fba 3385 special = pgm_read_byte(data + i++);
garfieldsg 0:662207e34fba 3386 } else {
garfieldsg 0:662207e34fba 3387 special = data[i++];
garfieldsg 0:662207e34fba 3388 }
garfieldsg 0:662207e34fba 3389 /*Serial.print("Special command code ");
garfieldsg 0:662207e34fba 3390 Serial.print(special, HEX);
garfieldsg 0:662207e34fba 3391 Serial.println(" found...");*/
garfieldsg 0:662207e34fba 3392 if (special == 0x01) {
garfieldsg 0:662207e34fba 3393 // enable DMP-related interrupts
garfieldsg 0:662207e34fba 3394
garfieldsg 0:662207e34fba 3395 //setIntZeroMotionEnabled(true);
garfieldsg 0:662207e34fba 3396 //setIntFIFOBufferOverflowEnabled(true);
garfieldsg 0:662207e34fba 3397 //setIntDMPEnabled(true);
garfieldsg 0:662207e34fba 3398 i2Cdev.writeByte(devAddr, MPU6050_RA_INT_ENABLE, 0x32); // single operation
garfieldsg 0:662207e34fba 3399
garfieldsg 0:662207e34fba 3400 success = true;
garfieldsg 0:662207e34fba 3401 } else {
garfieldsg 0:662207e34fba 3402 // unknown special command
garfieldsg 0:662207e34fba 3403 success = false;
garfieldsg 0:662207e34fba 3404 }
garfieldsg 0:662207e34fba 3405 }
garfieldsg 0:662207e34fba 3406
garfieldsg 0:662207e34fba 3407 if (!success) {
garfieldsg 0:662207e34fba 3408 if (useProgMem) free(progBuffer);
garfieldsg 0:662207e34fba 3409 return false; // uh oh
garfieldsg 0:662207e34fba 3410 }
garfieldsg 0:662207e34fba 3411 }
garfieldsg 0:662207e34fba 3412 if (useProgMem) free(progBuffer);
garfieldsg 0:662207e34fba 3413 return true;
garfieldsg 0:662207e34fba 3414 }
garfieldsg 0:662207e34fba 3415 bool MPU6050::writeProgDMPConfigurationSet(const uint8_t *data, uint16_t dataSize)
garfieldsg 0:662207e34fba 3416 {
garfieldsg 0:662207e34fba 3417 return writeDMPConfigurationSet(data, dataSize, false);
garfieldsg 0:662207e34fba 3418 }
garfieldsg 0:662207e34fba 3419
garfieldsg 0:662207e34fba 3420 // DMP_CFG_1 register
garfieldsg 0:662207e34fba 3421
garfieldsg 0:662207e34fba 3422 uint8_t MPU6050::getDMPConfig1()
garfieldsg 0:662207e34fba 3423 {
garfieldsg 0:662207e34fba 3424 i2Cdev.readByte(devAddr, MPU6050_RA_DMP_CFG_1, buffer);
garfieldsg 0:662207e34fba 3425 return buffer[0];
garfieldsg 0:662207e34fba 3426 }
garfieldsg 0:662207e34fba 3427 void MPU6050::setDMPConfig1(uint8_t config)
garfieldsg 0:662207e34fba 3428 {
garfieldsg 0:662207e34fba 3429 i2Cdev.writeByte(devAddr, MPU6050_RA_DMP_CFG_1, config);
garfieldsg 0:662207e34fba 3430 }
garfieldsg 0:662207e34fba 3431
garfieldsg 0:662207e34fba 3432 // DMP_CFG_2 register
garfieldsg 0:662207e34fba 3433
garfieldsg 0:662207e34fba 3434 uint8_t MPU6050::getDMPConfig2()
garfieldsg 0:662207e34fba 3435 {
garfieldsg 0:662207e34fba 3436 i2Cdev.readByte(devAddr, MPU6050_RA_DMP_CFG_2, buffer);
garfieldsg 0:662207e34fba 3437 return buffer[0];
garfieldsg 0:662207e34fba 3438 }
garfieldsg 0:662207e34fba 3439 void MPU6050::setDMPConfig2(uint8_t config)
garfieldsg 0:662207e34fba 3440 {
garfieldsg 0:662207e34fba 3441 i2Cdev.writeByte(devAddr, MPU6050_RA_DMP_CFG_2, config);
garfieldsg 0:662207e34fba 3442 }