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1	5d8d461e	Jan Hoffmann	/*!
2			* @file Adafruit_BNO055.cpp
3			*
4			* @mainpage Adafruit BNO055 Orientation Sensor
5	75f03d2e	Szymon Kaliski	*
6	5d8d461e	Jan Hoffmann	* @section intro_sec Introduction
7			*
8	75f03d2e	Szymon Kaliski	* This is a library for the BNO055 orientation sensor
9	5d8d461e	Jan Hoffmann	*
10	75f03d2e	Szymon Kaliski	* Designed specifically to work with the Adafruit BNO055 Breakout.
11	5d8d461e	Jan Hoffmann	*
12	75f03d2e	Szymon Kaliski	* Pick one up today in the adafruit shop!
13			* ------> https://www.adafruit.com/product/2472
14	5d8d461e	Jan Hoffmann	*
15	75f03d2e	Szymon Kaliski	* These sensors use I2C to communicate, 2 pins are required to interface.
16	5d8d461e	Jan Hoffmann	*
17	75f03d2e	Szymon Kaliski	* Adafruit invests time and resources providing this open source code,
18			* please support Adafruit andopen-source hardware by purchasing products
19			* from Adafruit!
20	5d8d461e	Jan Hoffmann	*
21			* @section author Author
22			*
23			* K.Townsend (Adafruit Industries)
24			*
25	75f03d2e	Szymon Kaliski	* @section license License
26			*
27			* MIT license, all text above must be included in any redistribution
28	5d8d461e	Jan Hoffmann	*/
29	4bc1c0c1	Kevin Townsend
30	55e2f6d1	Jan Hoffmann	#include "Arduino.h"
31	4bc1c0c1	Kevin Townsend
32			#include <limits.h>
33	55e2f6d1	Jan Hoffmann	#include <math.h>
34	4bc1c0c1	Kevin Townsend
35			#include "Adafruit_BNO055.h"
36
37			/*!
38	5d8d461e	Jan Hoffmann	* @brief Instantiates a new Adafruit_BNO055 class
39	9a8e8b26	Jan Hoffmann	* @param sensorID
40			* sensor ID
41			* @param address
42			* i2c address
43	dbc34b4d	Jan Hoffmann	* @param *theWire
44			* Wire object
45	5d8d461e	Jan Hoffmann	*/
46	9a8e8b26	Jan Hoffmann	Adafruit_BNO055::Adafruit_BNO055(int32_t sensorID, uint8_t address,
47			TwoWire *theWire) {
48			_sensorID = sensorID;
49			_address = address;
50	83911fa6	Jan Hoffmann	_wire = theWire;
51	9a8e8b26	Jan Hoffmann	}
52	f7556b0d	Jan Hoffmann
53			/*!
54			* @brief Sets up the HW
55			* @param mode
56			* mode values
57			* [OPERATION_MODE_CONFIG,
58			* OPERATION_MODE_ACCONLY,
59			* OPERATION_MODE_MAGONLY,
60			* OPERATION_MODE_GYRONLY,
61			* OPERATION_MODE_ACCMAG,
62			* OPERATION_MODE_ACCGYRO,
63			* OPERATION_MODE_MAGGYRO,
64			* OPERATION_MODE_AMG,
65			* OPERATION_MODE_IMUPLUS,
66			* OPERATION_MODE_COMPASS,
67			* OPERATION_MODE_M4G,
68			* OPERATION_MODE_NDOF_FMC_OFF,
69			* OPERATION_MODE_NDOF]
70			* @return true if process is successful
71			*/
72	9a8e8b26	Jan Hoffmann	bool Adafruit_BNO055::begin(adafruit_bno055_opmode_t mode) {
73			#if defined(ARDUINO_SAMD_ZERO) && (_address == BNO055_ADDRESS_A)
74	f7556b0d	Jan Hoffmann	#error \
75			"On an arduino Zero, BNO055's ADR pin must be high. Fix that, then delete this line."
76			_address = BNO055_ADDRESS_B;
77			#endif
78
79	463eabf7	Wetmelon	/* Enable I2C */
80	f7556b0d	Jan Hoffmann	_wire->begin();
81	463eabf7	Wetmelon
82	9a8e8b26	Jan Hoffmann	// BNO055 clock stretches for 500us or more!
83	78cc710f	ladyada	#ifdef ESP8266
84	9a8e8b26	Jan Hoffmann	_wire->setClockStretchLimit(1000); // Allow for 1000us of clock stretching
85	78cc710f	ladyada	#endif
86
87	463eabf7	Wetmelon	/* Make sure we have the right device */
88			uint8_t id = read8(BNO055_CHIP_ID_ADDR);
89	55e2f6d1	Jan Hoffmann	if (id != BNO055_ID) {
90	9a8e8b26	Jan Hoffmann	delay(1000); // hold on for boot
91	463eabf7	Wetmelon	id = read8(BNO055_CHIP_ID_ADDR);
92	55e2f6d1	Jan Hoffmann	if (id != BNO055_ID) {
93	9a8e8b26	Jan Hoffmann	return false; // still not? ok bail
94	463eabf7	Wetmelon	}
95			}
96
97			/* Switch to config mode (just in case since this is the default) */
98			setMode(OPERATION_MODE_CONFIG);
99
100			/* Reset */
101			write8(BNO055_SYS_TRIGGER_ADDR, 0x20);
102	5f6b7a75	Jan Hoffmann	/* Delay incrased to 30ms due to power issues https://tinyurl.com/y375z699 */
103			delay(30);
104	55e2f6d1	Jan Hoffmann	while (read8(BNO055_CHIP_ID_ADDR) != BNO055_ID) {
105	463eabf7	Wetmelon	delay(10);
106			}
107			delay(50);
108
109			/* Set to normal power mode */
110			write8(BNO055_PWR_MODE_ADDR, POWER_MODE_NORMAL);
111			delay(10);
112
113			write8(BNO055_PAGE_ID_ADDR, 0);
114
115	9a8e8b26	Jan Hoffmann	/* Set the output units */
116			/*
117			uint8_t unitsel = (0 << 7) \| // Orientation = Android
118			(0 << 4) \| // Temperature = Celsius
119			(0 << 2) \| // Euler = Degrees
120			(1 << 1) \| // Gyro = Rads
121			(0 << 0); // Accelerometer = m/s^2
122			write8(BNO055_UNIT_SEL_ADDR, unitsel);
123			*/
124	463eabf7	Wetmelon
125	378858ec	Shunya Sato	/* Configure axis mapping (see section 3.4) */
126	9a8e8b26	Jan Hoffmann	/*
127			write8(BNO055_AXIS_MAP_CONFIG_ADDR, REMAP_CONFIG_P2); // P0-P7, Default is P1
128			delay(10);
129			write8(BNO055_AXIS_MAP_SIGN_ADDR, REMAP_SIGN_P2); // P0-P7, Default is P1
130			delay(10);
131			*/
132
133	463eabf7	Wetmelon	write8(BNO055_SYS_TRIGGER_ADDR, 0x0);
134			delay(10);
135			/* Set the requested operating mode (see section 3.3) */
136			setMode(mode);
137			delay(20);
138
139			return true;
140	4bc1c0c1	Kevin Townsend	}
141
142			/*!
143	5d8d461e	Jan Hoffmann	* @brief Puts the chip in the specified operating mode
144			* @param mode
145	f7556b0d	Jan Hoffmann	* mode values
146			* [OPERATION_MODE_CONFIG,
147			* OPERATION_MODE_ACCONLY,
148			* OPERATION_MODE_MAGONLY,
149			* OPERATION_MODE_GYRONLY,
150			* OPERATION_MODE_ACCMAG,
151			* OPERATION_MODE_ACCGYRO,
152			* OPERATION_MODE_MAGGYRO,
153			* OPERATION_MODE_AMG,
154			* OPERATION_MODE_IMUPLUS,
155			* OPERATION_MODE_COMPASS,
156			* OPERATION_MODE_M4G,
157			* OPERATION_MODE_NDOF_FMC_OFF,
158			* OPERATION_MODE_NDOF]
159	5d8d461e	Jan Hoffmann	*/
160	55e2f6d1	Jan Hoffmann	void Adafruit_BNO055::setMode(adafruit_bno055_opmode_t mode) {
161	463eabf7	Wetmelon	_mode = mode;
162			write8(BNO055_OPR_MODE_ADDR, _mode);
163			delay(30);
164	4bc1c0c1	Kevin Townsend	}
165
166			/*!
167	5d8d461e	Jan Hoffmann	* @brief Changes the chip's axis remap
168			* @param remapcode
169	f7556b0d	Jan Hoffmann	* remap code possible values
170			* [REMAP_CONFIG_P0
171			* REMAP_CONFIG_P1 (default)
172			* REMAP_CONFIG_P2
173			* REMAP_CONFIG_P3
174			* REMAP_CONFIG_P4
175			* REMAP_CONFIG_P5
176			* REMAP_CONFIG_P6
177			* REMAP_CONFIG_P7]
178	5d8d461e	Jan Hoffmann	*/
179	55e2f6d1	Jan Hoffmann	void Adafruit_BNO055::setAxisRemap(
180			adafruit_bno055_axis_remap_config_t remapcode) {
181	a97e0fe1	kA®0šhî	adafruit_bno055_opmode_t modeback = _mode;
182
183			setMode(OPERATION_MODE_CONFIG);
184			delay(25);
185			write8(BNO055_AXIS_MAP_CONFIG_ADDR, remapcode);
186			delay(10);
187			/* Set the requested operating mode (see section 3.3) */
188			setMode(modeback);
189			delay(20);
190			}
191
192			/*!
193	5d8d461e	Jan Hoffmann	* @brief Changes the chip's axis signs
194			* @param remapsign
195	f7556b0d	Jan Hoffmann	* remap sign possible values
196			* [REMAP_SIGN_P0
197			* REMAP_SIGN_P1 (default)
198			* REMAP_SIGN_P2
199			* REMAP_SIGN_P3
200			* REMAP_SIGN_P4
201			* REMAP_SIGN_P5
202			* REMAP_SIGN_P6
203			* REMAP_SIGN_P7]
204	5d8d461e	Jan Hoffmann	*/
205	55e2f6d1	Jan Hoffmann	void Adafruit_BNO055::setAxisSign(adafruit_bno055_axis_remap_sign_t remapsign) {
206	a97e0fe1	kA®0šhî	adafruit_bno055_opmode_t modeback = _mode;
207
208			setMode(OPERATION_MODE_CONFIG);
209			delay(25);
210			write8(BNO055_AXIS_MAP_SIGN_ADDR, remapsign);
211			delay(10);
212			/* Set the requested operating mode (see section 3.3) */
213			setMode(modeback);
214			delay(20);
215			}
216
217			/*!
218	5d8d461e	Jan Hoffmann	* @brief Use the external 32.768KHz crystal
219	f7556b0d	Jan Hoffmann	* @param usextal
220			* use external crystal boolean
221	5d8d461e	Jan Hoffmann	*/
222	55e2f6d1	Jan Hoffmann	void Adafruit_BNO055::setExtCrystalUse(boolean usextal) {
223	463eabf7	Wetmelon	adafruit_bno055_opmode_t modeback = _mode;
224
225			/* Switch to config mode (just in case since this is the default) */
226			setMode(OPERATION_MODE_CONFIG);
227			delay(25);
228			write8(BNO055_PAGE_ID_ADDR, 0);
229			if (usextal) {
230			write8(BNO055_SYS_TRIGGER_ADDR, 0x80);
231			} else {
232			write8(BNO055_SYS_TRIGGER_ADDR, 0x00);
233			}
234			delay(10);
235			/* Set the requested operating mode (see section 3.3) */
236			setMode(modeback);
237			delay(20);
238	c4f272e1	ladyada	}
239
240			/*!
241	5d8d461e	Jan Hoffmann	* @brief Gets the latest system status info
242			* @param system_status
243	f7556b0d	Jan Hoffmann	* system status info
244	5d8d461e	Jan Hoffmann	* @param self_test_result
245	f7556b0d	Jan Hoffmann	* self test result
246	5d8d461e	Jan Hoffmann	* @param system_error
247	f7556b0d	Jan Hoffmann	* system error info
248	5d8d461e	Jan Hoffmann	*/
249	55e2f6d1	Jan Hoffmann	void Adafruit_BNO055::getSystemStatus(uint8_t *system_status,
250			uint8_t *self_test_result,
251			uint8_t *system_error) {
252	463eabf7	Wetmelon	write8(BNO055_PAGE_ID_ADDR, 0);
253
254			/* System Status (see section 4.3.58)
255			0 = Idle
256			1 = System Error
257			2 = Initializing Peripherals
258			3 = System Iniitalization
259			4 = Executing Self-Test
260			5 = Sensor fusio algorithm running
261	75f03d2e	Szymon Kaliski	6 = System running without fusion algorithms
262	5d8d461e	Jan Hoffmann	*/
263	463eabf7	Wetmelon
264			if (system_status != 0)
265	55e2f6d1	Jan Hoffmann	*system_status = read8(BNO055_SYS_STAT_ADDR);
266	463eabf7	Wetmelon
267	5d8d461e	Jan Hoffmann	/* Self Test Results
268	463eabf7	Wetmelon	1 = test passed, 0 = test failed
269	75f03d2e	Szymon Kaliski
270	463eabf7	Wetmelon	Bit 0 = Accelerometer self test
271			Bit 1 = Magnetometer self test
272			Bit 2 = Gyroscope self test
273			Bit 3 = MCU self test
274	75f03d2e	Szymon Kaliski
275			0x0F = all good!
276	5d8d461e	Jan Hoffmann	*/
277	463eabf7	Wetmelon
278			if (self_test_result != 0)
279			*self_test_result = read8(BNO055_SELFTEST_RESULT_ADDR);
280
281			/* System Error (see section 4.3.59)
282			0 = No error
283			1 = Peripheral initialization error
284			2 = System initialization error
285			3 = Self test result failed
286			4 = Register map value out of range
287			5 = Register map address out of range
288			6 = Register map write error
289			7 = BNO low power mode not available for selected operat ion mode
290			8 = Accelerometer power mode not available
291			9 = Fusion algorithm configuration error
292	75f03d2e	Szymon Kaliski	A = Sensor configuration error
293	5d8d461e	Jan Hoffmann	*/
294	463eabf7	Wetmelon
295			if (system_error != 0)
296	55e2f6d1	Jan Hoffmann	*system_error = read8(BNO055_SYS_ERR_ADDR);
297	463eabf7	Wetmelon
298			delay(200);
299	4bc1c0c1	Kevin Townsend	}
300
301			/*!
302	5d8d461e	Jan Hoffmann	* @brief Gets the chip revision numbers
303	f7556b0d	Jan Hoffmann	* @param info
304			* revision info
305	5d8d461e	Jan Hoffmann	*/
306	55e2f6d1	Jan Hoffmann	void Adafruit_BNO055::getRevInfo(adafruit_bno055_rev_info_t *info) {
307	463eabf7	Wetmelon	uint8_t a, b;
308	4bc1c0c1	Kevin Townsend
309	463eabf7	Wetmelon	memset(info, 0, sizeof(adafruit_bno055_rev_info_t));
310	4bc1c0c1	Kevin Townsend
311	463eabf7	Wetmelon	/* Check the accelerometer revision */
312			info->accel_rev = read8(BNO055_ACCEL_REV_ID_ADDR);
313	67f3cff5	Kevin Townsend
314	463eabf7	Wetmelon	/* Check the magnetometer revision */
315	55e2f6d1	Jan Hoffmann	info->mag_rev = read8(BNO055_MAG_REV_ID_ADDR);
316	67f3cff5	Kevin Townsend
317	463eabf7	Wetmelon	/* Check the gyroscope revision */
318	55e2f6d1	Jan Hoffmann	info->gyro_rev = read8(BNO055_GYRO_REV_ID_ADDR);
319	67f3cff5	Kevin Townsend
320	463eabf7	Wetmelon	/* Check the SW revision */
321	55e2f6d1	Jan Hoffmann	info->bl_rev = read8(BNO055_BL_REV_ID_ADDR);
322	40f91f6f	Tony DiCola
323	463eabf7	Wetmelon	a = read8(BNO055_SW_REV_ID_LSB_ADDR);
324			b = read8(BNO055_SW_REV_ID_MSB_ADDR);
325			info->sw_rev = (((uint16_t)b) << 8) \| ((uint16_t)a);
326	4bc1c0c1	Kevin Townsend	}
327
328			/*!
329	5d8d461e	Jan Hoffmann	* @brief Gets current calibration state. Each value should be a uint8_t
330			* pointer and it will be set to 0 if not calibrated and 3 if
331			* fully calibrated.
332	f7556b0d	Jan Hoffmann	* See section 34.3.54
333	5d8d461e	Jan Hoffmann	* @param sys
334	f7556b0d	Jan Hoffmann	* Current system calibration status, depends on status of all sensors,
335			* read-only
336	5d8d461e	Jan Hoffmann	* @param gyro
337	f7556b0d	Jan Hoffmann	* Current calibration status of Gyroscope, read-only
338	5d8d461e	Jan Hoffmann	* @param accel
339	f7556b0d	Jan Hoffmann	* Current calibration status of Accelerometer, read-only
340	5d8d461e	Jan Hoffmann	* @param mag
341	f7556b0d	Jan Hoffmann	* Current calibration status of Magnetometer, read-only
342	5d8d461e	Jan Hoffmann	*/
343	55e2f6d1	Jan Hoffmann	void Adafruit_BNO055::getCalibration(uint8_t sys, uint8_t gyro,
344			uint8_t accel, uint8_t mag) {
345	463eabf7	Wetmelon	uint8_t calData = read8(BNO055_CALIB_STAT_ADDR);
346			if (sys != NULL) {
347			*sys = (calData >> 6) & 0x03;
348			}
349			if (gyro != NULL) {
350			*gyro = (calData >> 4) & 0x03;
351			}
352			if (accel != NULL) {
353			*accel = (calData >> 2) & 0x03;
354			}
355			if (mag != NULL) {
356			*mag = calData & 0x03;
357			}
358	40f91f6f	Tony DiCola	}
359
360			/*!
361	5d8d461e	Jan Hoffmann	* @brief Gets the temperature in degrees celsius
362			* @return temperature in degrees celsius
363			*/
364	55e2f6d1	Jan Hoffmann	int8_t Adafruit_BNO055::getTemp() {
365	463eabf7	Wetmelon	int8_t temp = (int8_t)(read8(BNO055_TEMP_ADDR));
366			return temp;
367	0e2e2723	Kevin Townsend	}
368
369			/*!
370	5d8d461e	Jan Hoffmann	* @brief Gets a vector reading from the specified source
371			* @param vector_type
372	f7556b0d	Jan Hoffmann	* possible vector type values
373			* [VECTOR_ACCELEROMETER
374			* VECTOR_MAGNETOMETER
375			* VECTOR_GYROSCOPE
376			* VECTOR_EULER
377			* VECTOR_LINEARACCEL
378			* VECTOR_GRAVITY]
379	5d8d461e	Jan Hoffmann	* @return vector from specified source
380			*/
381	55e2f6d1	Jan Hoffmann	imu::Vector<3> Adafruit_BNO055::getVector(adafruit_vector_type_t vector_type) {
382	463eabf7	Wetmelon	imu::Vector<3> xyz;
383			uint8_t buffer[6];
384	55e2f6d1	Jan Hoffmann	memset(buffer, 0, 6);
385	463eabf7	Wetmelon
386			int16_t x, y, z;
387			x = y = z = 0;
388
389			/* Read vector data (6 bytes) */
390			readLen((adafruit_bno055_reg_t)vector_type, buffer, 6);
391
392			x = ((int16_t)buffer[0]) \| (((int16_t)buffer[1]) << 8);
393			y = ((int16_t)buffer[2]) \| (((int16_t)buffer[3]) << 8);
394			z = ((int16_t)buffer[4]) \| (((int16_t)buffer[5]) << 8);
395
396	75f03d2e	Szymon Kaliski	/*!
397	5d8d461e	Jan Hoffmann	* Convert the value to an appropriate range (section 3.6.4)
398	75f03d2e	Szymon Kaliski	* and assign the value to the Vector type
399	5d8d461e	Jan Hoffmann	*/
400	55e2f6d1	Jan Hoffmann	switch (vector_type) {
401			case VECTOR_MAGNETOMETER:
402			/* 1uT = 16 LSB */
403			xyz[0] = ((double)x) / 16.0;
404			xyz[1] = ((double)y) / 16.0;
405			xyz[2] = ((double)z) / 16.0;
406			break;
407			case VECTOR_GYROSCOPE:
408			/* 1dps = 16 LSB */
409			xyz[0] = ((double)x) / 16.0;
410			xyz[1] = ((double)y) / 16.0;
411			xyz[2] = ((double)z) / 16.0;
412			break;
413			case VECTOR_EULER:
414			/* 1 degree = 16 LSB */
415			xyz[0] = ((double)x) / 16.0;
416			xyz[1] = ((double)y) / 16.0;
417			xyz[2] = ((double)z) / 16.0;
418			break;
419			case VECTOR_ACCELEROMETER:
420	e223568a	Jan Hoffmann	/* 1m/s^2 = 100 LSB */
421			xyz[0] = ((double)x) / 100.0;
422			xyz[1] = ((double)y) / 100.0;
423			xyz[2] = ((double)z) / 100.0;
424			break;
425	55e2f6d1	Jan Hoffmann	case VECTOR_LINEARACCEL:
426	e223568a	Jan Hoffmann	/* 1m/s^2 = 100 LSB */
427			xyz[0] = ((double)x) / 100.0;
428			xyz[1] = ((double)y) / 100.0;
429			xyz[2] = ((double)z) / 100.0;
430			break;
431	55e2f6d1	Jan Hoffmann	case VECTOR_GRAVITY:
432			/* 1m/s^2 = 100 LSB */
433			xyz[0] = ((double)x) / 100.0;
434			xyz[1] = ((double)y) / 100.0;
435			xyz[2] = ((double)z) / 100.0;
436			break;
437	463eabf7	Wetmelon	}
438
439			return xyz;
440	4bc1c0c1	Kevin Townsend	}
441
442			/*!
443	5d8d461e	Jan Hoffmann	* @brief Gets a quaternion reading from the specified source
444			* @return quaternion reading
445			*/
446	55e2f6d1	Jan Hoffmann	imu::Quaternion Adafruit_BNO055::getQuat() {
447	463eabf7	Wetmelon	uint8_t buffer[8];
448	55e2f6d1	Jan Hoffmann	memset(buffer, 0, 8);
449	463eabf7	Wetmelon
450			int16_t x, y, z, w;
451			x = y = z = w = 0;
452
453			/* Read quat data (8 bytes) */
454			readLen(BNO055_QUATERNION_DATA_W_LSB_ADDR, buffer, 8);
455			w = (((uint16_t)buffer[1]) << 8) \| ((uint16_t)buffer[0]);
456			x = (((uint16_t)buffer[3]) << 8) \| ((uint16_t)buffer[2]);
457			y = (((uint16_t)buffer[5]) << 8) \| ((uint16_t)buffer[4]);
458			z = (((uint16_t)buffer[7]) << 8) \| ((uint16_t)buffer[6]);
459
460	5d8d461e	Jan Hoffmann	/*!
461			* Assign to Quaternion
462			* See
463			* http://ae-bst.resource.bosch.com/media/products/dokumente/bno055/BST_BNO055_DS000_12~1.pdf
464	75f03d2e	Szymon Kaliski	* 3.6.5.5 Orientation (Quaternion)
465	5d8d461e	Jan Hoffmann	*/
466	55e2f6d1	Jan Hoffmann	const double scale = (1.0 / (1 << 14));
467	463eabf7	Wetmelon	imu::Quaternion quat(scale * w, scale * x, scale * y, scale * z);
468			return quat;
469	48741e1f	Kevin Townsend	}
470
471			/*!
472	5d8d461e	Jan Hoffmann	* @brief Provides the sensor_t data for this sensor
473			* @param sensor
474	75f03d2e	Szymon Kaliski	*/
475	55e2f6d1	Jan Hoffmann	void Adafruit_BNO055::getSensor(sensor_t *sensor) {
476	463eabf7	Wetmelon	/* Clear the sensor_t object */
477			memset(sensor, 0, sizeof(sensor_t));
478
479			/* Insert the sensor name in the fixed length char array */
480	55e2f6d1	Jan Hoffmann	strncpy(sensor->name, "BNO055", sizeof(sensor->name) - 1);
481			sensor->name[sizeof(sensor->name) - 1] = 0;
482			sensor->version = 1;
483			sensor->sensor_id = _sensorID;
484			sensor->type = SENSOR_TYPE_ORIENTATION;
485			sensor->min_delay = 0;
486			sensor->max_value = 0.0F;
487			sensor->min_value = 0.0F;
488			sensor->resolution = 0.01F;
489	4bc1c0c1	Kevin Townsend	}
490
491			/*!
492	5d8d461e	Jan Hoffmann	* @brief Reads the sensor and returns the data as a sensors_event_t
493			* @param event
494			* @return always returns true
495			*/
496	55e2f6d1	Jan Hoffmann	bool Adafruit_BNO055::getEvent(sensors_event_t *event) {
497	463eabf7	Wetmelon	/* Clear the event */
498			memset(event, 0, sizeof(sensors_event_t));
499	4bc1c0c1	Kevin Townsend
500	55e2f6d1	Jan Hoffmann	event->version = sizeof(sensors_event_t);
501	463eabf7	Wetmelon	event->sensor_id = _sensorID;
502	55e2f6d1	Jan Hoffmann	event->type = SENSOR_TYPE_ORIENTATION;
503	463eabf7	Wetmelon	event->timestamp = millis();
504	fcd68623	Kevin Townsend
505	463eabf7	Wetmelon	/* Get a Euler angle sample for orientation */
506			imu::Vector<3> euler = getVector(Adafruit_BNO055::VECTOR_EULER);
507			event->orientation.x = euler.x();
508			event->orientation.y = euler.y();
509			event->orientation.z = euler.z();
510	312a5b9e	Wetmelon
511	463eabf7	Wetmelon	return true;
512	312a5b9e	Wetmelon	}
513	fcd68623	Kevin Townsend
514	312a5b9e	Wetmelon	/*!
515	f0ebdf46	Jan Hoffmann	* @brief Reads the sensor and returns the data as a sensors_event_t
516			* @param event
517			* @param vec_type
518			* specify the type of reading
519			* @return always returns true
520			*/
521			bool Adafruit_BNO055::getEvent(sensors_event_t *event, adafruit_vector_type_t vec_type)
522			{
523			/* Clear the event */
524			memset(event, 0, sizeof(sensors_event_t));
525
526			event->version = sizeof(sensors_event_t);
527			event->sensor_id = _sensorID;
528			event->timestamp = millis();
529
530			//read the data according to vec_type
531			imu::Vector<3> vec;
532			if (vec_type == Adafruit_BNO055::VECTOR_LINEARACCEL)
533			{
534	7bc8249a	Paul Otto	event->type = SENSOR_TYPE_LINEAR_ACCELERATION;
535	f0ebdf46	Jan Hoffmann	vec = getVector(Adafruit_BNO055::VECTOR_LINEARACCEL);
536
537			event->acceleration.x = vec.x();
538			event->acceleration.y = vec.y();
539			event->acceleration.z = vec.z();
540			}
541			else if (vec_type == Adafruit_BNO055::VECTOR_ACCELEROMETER)
542			{
543			event->type = SENSOR_TYPE_ACCELEROMETER;
544			vec = getVector(Adafruit_BNO055::VECTOR_ACCELEROMETER);
545
546			event->acceleration.x = vec.x();
547			event->acceleration.y = vec.y();
548			event->acceleration.z = vec.z();
549			}
550			else if (vec_type == Adafruit_BNO055::VECTOR_GRAVITY)
551			{
552			event->type = SENSOR_TYPE_ACCELEROMETER;
553			vec = getVector(Adafruit_BNO055::VECTOR_GRAVITY);
554
555			event->acceleration.x = vec.x();
556			event->acceleration.y = vec.y();
557			event->acceleration.z = vec.z();
558			}
559			else if (vec_type == Adafruit_BNO055::VECTOR_EULER)
560			{
561			event->type = SENSOR_TYPE_ORIENTATION;
562			vec = getVector(Adafruit_BNO055::VECTOR_EULER);
563
564			event->orientation.x = vec.x();
565			event->orientation.y = vec.y();
566			event->orientation.z = vec.z();
567			}
568			else if (vec_type == Adafruit_BNO055::VECTOR_GYROSCOPE)
569			{
570			event->type = SENSOR_TYPE_ROTATION_VECTOR;
571			vec = getVector(Adafruit_BNO055::VECTOR_GYROSCOPE);
572
573			event->gyro.x = vec.x();
574			event->gyro.y = vec.y();
575			event->gyro.z = vec.z();
576			}
577			else if (vec_type == Adafruit_BNO055::VECTOR_MAGNETOMETER)
578			{
579			event->type = SENSOR_TYPE_MAGNETIC_FIELD;
580			vec = getVector(Adafruit_BNO055::VECTOR_MAGNETOMETER);
581
582			event->magnetic.x = vec.x();
583			event->magnetic.y = vec.y();
584			event->magnetic.z = vec.z();
585			}
586
587
588			return true;
589			}
590
591
592			/*!
593	5d8d461e	Jan Hoffmann	* @brief Reads the sensor's offset registers into a byte array
594			* @param calibData
595			* @return true if read is successful
596			*/
597	55e2f6d1	Jan Hoffmann	bool Adafruit_BNO055::getSensorOffsets(uint8_t *calibData) {
598			if (isFullyCalibrated()) {
599			adafruit_bno055_opmode_t lastMode = _mode;
600			setMode(OPERATION_MODE_CONFIG);
601	312a5b9e	Wetmelon
602	55e2f6d1	Jan Hoffmann	readLen(ACCEL_OFFSET_X_LSB_ADDR, calibData, NUM_BNO055_OFFSET_REGISTERS);
603	312a5b9e	Wetmelon
604	55e2f6d1	Jan Hoffmann	setMode(lastMode);
605			return true;
606			}
607			return false;
608	312a5b9e	Wetmelon	}
609
610			/*!
611	5d8d461e	Jan Hoffmann	* @brief Reads the sensor's offset registers into an offset struct
612			* @param offsets_type
613	dbc34b4d	Jan Hoffmann	* type of offsets
614	5d8d461e	Jan Hoffmann	* @return true if read is successful
615			*/
616	55e2f6d1	Jan Hoffmann	bool Adafruit_BNO055::getSensorOffsets(
617			adafruit_bno055_offsets_t &offsets_type) {
618			if (isFullyCalibrated()) {
619			adafruit_bno055_opmode_t lastMode = _mode;
620			setMode(OPERATION_MODE_CONFIG);
621			delay(25);
622
623			/* Accel offset range depends on the G-range:
624			+/-2g = +/- 2000 mg
625			+/-4g = +/- 4000 mg
626			+/-8g = +/- 8000 mg
627			+/-1§g = +/- 16000 mg */
628			offsets_type.accel_offset_x = (read8(ACCEL_OFFSET_X_MSB_ADDR) << 8) \|
629			(read8(ACCEL_OFFSET_X_LSB_ADDR));
630			offsets_type.accel_offset_y = (read8(ACCEL_OFFSET_Y_MSB_ADDR) << 8) \|
631			(read8(ACCEL_OFFSET_Y_LSB_ADDR));
632			offsets_type.accel_offset_z = (read8(ACCEL_OFFSET_Z_MSB_ADDR) << 8) \|
633			(read8(ACCEL_OFFSET_Z_LSB_ADDR));
634
635			/* Magnetometer offset range = +/- 6400 LSB where 1uT = 16 LSB */
636			offsets_type.mag_offset_x =
637			(read8(MAG_OFFSET_X_MSB_ADDR) << 8) \| (read8(MAG_OFFSET_X_LSB_ADDR));
638			offsets_type.mag_offset_y =
639			(read8(MAG_OFFSET_Y_MSB_ADDR) << 8) \| (read8(MAG_OFFSET_Y_LSB_ADDR));
640			offsets_type.mag_offset_z =
641			(read8(MAG_OFFSET_Z_MSB_ADDR) << 8) \| (read8(MAG_OFFSET_Z_LSB_ADDR));
642
643			/* Gyro offset range depends on the DPS range:
644			2000 dps = +/- 32000 LSB
645			1000 dps = +/- 16000 LSB
646			500 dps = +/- 8000 LSB
647			250 dps = +/- 4000 LSB
648			125 dps = +/- 2000 LSB
649			... where 1 DPS = 16 LSB */
650			offsets_type.gyro_offset_x =
651			(read8(GYRO_OFFSET_X_MSB_ADDR) << 8) \| (read8(GYRO_OFFSET_X_LSB_ADDR));
652			offsets_type.gyro_offset_y =
653			(read8(GYRO_OFFSET_Y_MSB_ADDR) << 8) \| (read8(GYRO_OFFSET_Y_LSB_ADDR));
654			offsets_type.gyro_offset_z =
655			(read8(GYRO_OFFSET_Z_MSB_ADDR) << 8) \| (read8(GYRO_OFFSET_Z_LSB_ADDR));
656
657			/* Accelerometer radius = +/- 1000 LSB */
658			offsets_type.accel_radius =
659			(read8(ACCEL_RADIUS_MSB_ADDR) << 8) \| (read8(ACCEL_RADIUS_LSB_ADDR));
660
661			/* Magnetometer radius = +/- 960 LSB */
662			offsets_type.mag_radius =
663			(read8(MAG_RADIUS_MSB_ADDR) << 8) \| (read8(MAG_RADIUS_LSB_ADDR));
664	312a5b9e	Wetmelon
665	55e2f6d1	Jan Hoffmann	setMode(lastMode);
666			return true;
667			}
668			return false;
669			}
670	312a5b9e	Wetmelon
671			/*!
672	75f03d2e	Szymon Kaliski	* @brief Writes an array of calibration values to the sensor's offset
673	dbc34b4d	Jan Hoffmann	* @param *calibData
674	f7556b0d	Jan Hoffmann	* calibration data
675	5d8d461e	Jan Hoffmann	*/
676	55e2f6d1	Jan Hoffmann	void Adafruit_BNO055::setSensorOffsets(const uint8_t *calibData) {
677			adafruit_bno055_opmode_t lastMode = _mode;
678			setMode(OPERATION_MODE_CONFIG);
679			delay(25);
680	463eabf7	Wetmelon
681	55e2f6d1	Jan Hoffmann	/* Note: Configuration will take place only when user writes to the last
682			byte of each config data pair (ex. ACCEL_OFFSET_Z_MSB_ADDR, etc.).
683			Therefore the last byte must be written whenever the user wants to
684			changes the configuration. */
685
686			/* A writeLen() would make this much cleaner */
687			write8(ACCEL_OFFSET_X_LSB_ADDR, calibData[0]);
688			write8(ACCEL_OFFSET_X_MSB_ADDR, calibData[1]);
689			write8(ACCEL_OFFSET_Y_LSB_ADDR, calibData[2]);
690			write8(ACCEL_OFFSET_Y_MSB_ADDR, calibData[3]);
691			write8(ACCEL_OFFSET_Z_LSB_ADDR, calibData[4]);
692			write8(ACCEL_OFFSET_Z_MSB_ADDR, calibData[5]);
693
694			write8(MAG_OFFSET_X_LSB_ADDR, calibData[6]);
695			write8(MAG_OFFSET_X_MSB_ADDR, calibData[7]);
696			write8(MAG_OFFSET_Y_LSB_ADDR, calibData[8]);
697			write8(MAG_OFFSET_Y_MSB_ADDR, calibData[9]);
698			write8(MAG_OFFSET_Z_LSB_ADDR, calibData[10]);
699			write8(MAG_OFFSET_Z_MSB_ADDR, calibData[11]);
700
701			write8(GYRO_OFFSET_X_LSB_ADDR, calibData[12]);
702			write8(GYRO_OFFSET_X_MSB_ADDR, calibData[13]);
703			write8(GYRO_OFFSET_Y_LSB_ADDR, calibData[14]);
704			write8(GYRO_OFFSET_Y_MSB_ADDR, calibData[15]);
705			write8(GYRO_OFFSET_Z_LSB_ADDR, calibData[16]);
706			write8(GYRO_OFFSET_Z_MSB_ADDR, calibData[17]);
707
708			write8(ACCEL_RADIUS_LSB_ADDR, calibData[18]);
709			write8(ACCEL_RADIUS_MSB_ADDR, calibData[19]);
710
711			write8(MAG_RADIUS_LSB_ADDR, calibData[20]);
712			write8(MAG_RADIUS_MSB_ADDR, calibData[21]);
713
714			setMode(lastMode);
715	4bc1c0c1	Kevin Townsend	}
716
717	312a5b9e	Wetmelon	/*!
718	5d8d461e	Jan Hoffmann	* @brief Writes to the sensor's offset registers from an offset struct
719			* @param offsets_type
720	f7556b0d	Jan Hoffmann	* accel_offset_x = acceleration offset x
721			* accel_offset_y = acceleration offset y
722			* accel_offset_z = acceleration offset z
723			*
724			* mag_offset_x = magnetometer offset x
725			* mag_offset_y = magnetometer offset y
726			* mag_offset_z = magnetometer offset z
727			*
728			* gyro_offset_x = gyroscrope offset x
729			* gyro_offset_y = gyroscrope offset y
730			* gyro_offset_z = gyroscrope offset z
731	75f03d2e	Szymon Kaliski	*/
732	55e2f6d1	Jan Hoffmann	void Adafruit_BNO055::setSensorOffsets(
733			const adafruit_bno055_offsets_t &offsets_type) {
734			adafruit_bno055_opmode_t lastMode = _mode;
735			setMode(OPERATION_MODE_CONFIG);
736			delay(25);
737	463eabf7	Wetmelon
738	55e2f6d1	Jan Hoffmann	/* Note: Configuration will take place only when user writes to the last
739			byte of each config data pair (ex. ACCEL_OFFSET_Z_MSB_ADDR, etc.).
740			Therefore the last byte must be written whenever the user wants to
741			changes the configuration. */
742
743			write8(ACCEL_OFFSET_X_LSB_ADDR, (offsets_type.accel_offset_x) & 0x0FF);
744			write8(ACCEL_OFFSET_X_MSB_ADDR, (offsets_type.accel_offset_x >> 8) & 0x0FF);
745			write8(ACCEL_OFFSET_Y_LSB_ADDR, (offsets_type.accel_offset_y) & 0x0FF);
746			write8(ACCEL_OFFSET_Y_MSB_ADDR, (offsets_type.accel_offset_y >> 8) & 0x0FF);
747			write8(ACCEL_OFFSET_Z_LSB_ADDR, (offsets_type.accel_offset_z) & 0x0FF);
748			write8(ACCEL_OFFSET_Z_MSB_ADDR, (offsets_type.accel_offset_z >> 8) & 0x0FF);
749
750			write8(MAG_OFFSET_X_LSB_ADDR, (offsets_type.mag_offset_x) & 0x0FF);
751			write8(MAG_OFFSET_X_MSB_ADDR, (offsets_type.mag_offset_x >> 8) & 0x0FF);
752			write8(MAG_OFFSET_Y_LSB_ADDR, (offsets_type.mag_offset_y) & 0x0FF);
753			write8(MAG_OFFSET_Y_MSB_ADDR, (offsets_type.mag_offset_y >> 8) & 0x0FF);
754			write8(MAG_OFFSET_Z_LSB_ADDR, (offsets_type.mag_offset_z) & 0x0FF);
755			write8(MAG_OFFSET_Z_MSB_ADDR, (offsets_type.mag_offset_z >> 8) & 0x0FF);
756
757			write8(GYRO_OFFSET_X_LSB_ADDR, (offsets_type.gyro_offset_x) & 0x0FF);
758			write8(GYRO_OFFSET_X_MSB_ADDR, (offsets_type.gyro_offset_x >> 8) & 0x0FF);
759			write8(GYRO_OFFSET_Y_LSB_ADDR, (offsets_type.gyro_offset_y) & 0x0FF);
760			write8(GYRO_OFFSET_Y_MSB_ADDR, (offsets_type.gyro_offset_y >> 8) & 0x0FF);
761			write8(GYRO_OFFSET_Z_LSB_ADDR, (offsets_type.gyro_offset_z) & 0x0FF);
762			write8(GYRO_OFFSET_Z_MSB_ADDR, (offsets_type.gyro_offset_z >> 8) & 0x0FF);
763
764			write8(ACCEL_RADIUS_LSB_ADDR, (offsets_type.accel_radius) & 0x0FF);
765			write8(ACCEL_RADIUS_MSB_ADDR, (offsets_type.accel_radius >> 8) & 0x0FF);
766
767			write8(MAG_RADIUS_LSB_ADDR, (offsets_type.mag_radius) & 0x0FF);
768			write8(MAG_RADIUS_MSB_ADDR, (offsets_type.mag_radius >> 8) & 0x0FF);
769
770			setMode(lastMode);
771	312a5b9e	Wetmelon	}
772
773	741a95a7	Kevin Townsend	/*!
774	5d8d461e	Jan Hoffmann	* @brief Checks of all cal status values are set to 3 (fully calibrated)
775			* @return status of calibration
776			*/
777	55e2f6d1	Jan Hoffmann	bool Adafruit_BNO055::isFullyCalibrated() {
778			uint8_t system, gyro, accel, mag;
779			getCalibration(&system, &gyro, &accel, &mag);
780	510d0f10	Jan Hoffmann
781			switch (_mode) {
782			case OPERATION_MODE_ACCONLY:
783			return (accel == 3);
784			case OPERATION_MODE_MAGONLY:
785			return (mag == 3);
786			case OPERATION_MODE_GYRONLY:
787			case OPERATION_MODE_M4G: /* No magnetometer calibration required. */
788			return (gyro == 3);
789			case OPERATION_MODE_ACCMAG:
790			case OPERATION_MODE_COMPASS:
791			return (accel == 3 && mag == 3);
792			case OPERATION_MODE_ACCGYRO:
793			case OPERATION_MODE_IMUPLUS:
794			return (accel == 3 && gyro == 3);
795			case OPERATION_MODE_MAGGYRO:
796			return (mag == 3 && gyro == 3);
797			default:
798			return (system == 3 && gyro == 3 && accel == 3 && mag == 3);
799			}
800	312a5b9e	Wetmelon	}
801
802	4bc1c0c1	Kevin Townsend	/*!
803	a7b2a1c9	Jan Hoffmann	* @brief Enter Suspend mode (i.e., sleep)
804			*/
805			void Adafruit_BNO055::enterSuspendMode() {
806			adafruit_bno055_opmode_t modeback = _mode;
807
808			/* Switch to config mode (just in case since this is the default) */
809			setMode(OPERATION_MODE_CONFIG);
810			delay(25);
811			write8(BNO055_PWR_MODE_ADDR, 0x02);
812			/* Set the requested operating mode (see section 3.3) */
813			setMode(modeback);
814			delay(20);
815			}
816
817			/*!
818			* @brief Enter Normal mode (i.e., wake)
819			*/
820			void Adafruit_BNO055::enterNormalMode() {
821			adafruit_bno055_opmode_t modeback = _mode;
822
823			/* Switch to config mode (just in case since this is the default) */
824			setMode(OPERATION_MODE_CONFIG);
825			delay(25);
826			write8(BNO055_PWR_MODE_ADDR, 0x00);
827			/* Set the requested operating mode (see section 3.3) */
828			setMode(modeback);
829			delay(20);
830			}
831
832			/*!
833	5d8d461e	Jan Hoffmann	* @brief Writes an 8 bit value over I2C
834			*/
835	55e2f6d1	Jan Hoffmann	bool Adafruit_BNO055::write8(adafruit_bno055_reg_t reg, byte value) {
836	f7556b0d	Jan Hoffmann	_wire->beginTransmission(_address);
837	55e2f6d1	Jan Hoffmann	#if ARDUINO >= 100
838	f7556b0d	Jan Hoffmann	_wire->write((uint8_t)reg);
839			_wire->write((uint8_t)value);
840	55e2f6d1	Jan Hoffmann	#else
841	f7556b0d	Jan Hoffmann	_wire->send(reg);
842			_wire->send(value);
843	55e2f6d1	Jan Hoffmann	#endif
844	f7556b0d	Jan Hoffmann	_wire->endTransmission();
845	463eabf7	Wetmelon
846			/* ToDo: Check for error! */
847			return true;
848	4bc1c0c1	Kevin Townsend	}
849
850			/*!
851	5d8d461e	Jan Hoffmann	* @brief Reads an 8 bit value over I2C
852			*/
853	55e2f6d1	Jan Hoffmann	byte Adafruit_BNO055::read8(adafruit_bno055_reg_t reg) {
854	463eabf7	Wetmelon	byte value = 0;
855
856	f7556b0d	Jan Hoffmann	_wire->beginTransmission(_address);
857	55e2f6d1	Jan Hoffmann	#if ARDUINO >= 100
858	f7556b0d	Jan Hoffmann	_wire->write((uint8_t)reg);
859	55e2f6d1	Jan Hoffmann	#else
860	f7556b0d	Jan Hoffmann	_wire->send(reg);
861	55e2f6d1	Jan Hoffmann	#endif
862	f7556b0d	Jan Hoffmann	_wire->endTransmission();
863			_wire->requestFrom(_address, (byte)1);
864	55e2f6d1	Jan Hoffmann	#if ARDUINO >= 100
865	f7556b0d	Jan Hoffmann	value = _wire->read();
866	55e2f6d1	Jan Hoffmann	#else
867	f7556b0d	Jan Hoffmann	value = _wire->receive();
868	55e2f6d1	Jan Hoffmann	#endif
869	463eabf7	Wetmelon
870			return value;
871	4bc1c0c1	Kevin Townsend	}
872
873			/*!
874	5d8d461e	Jan Hoffmann	* @brief Reads the specified number of bytes over I2C
875			*/
876	55e2f6d1	Jan Hoffmann	bool Adafruit_BNO055::readLen(adafruit_bno055_reg_t reg, byte *buffer,
877			uint8_t len) {
878	f7556b0d	Jan Hoffmann	_wire->beginTransmission(_address);
879	55e2f6d1	Jan Hoffmann	#if ARDUINO >= 100
880	f7556b0d	Jan Hoffmann	_wire->write((uint8_t)reg);
881	55e2f6d1	Jan Hoffmann	#else
882	f7556b0d	Jan Hoffmann	_wire->send(reg);
883	55e2f6d1	Jan Hoffmann	#endif
884	f7556b0d	Jan Hoffmann	_wire->endTransmission();
885			_wire->requestFrom(_address, (byte)len);
886	463eabf7	Wetmelon
887	55e2f6d1	Jan Hoffmann	for (uint8_t i = 0; i < len; i++) {
888			#if ARDUINO >= 100
889	f7556b0d	Jan Hoffmann	buffer[i] = _wire->read();
890	55e2f6d1	Jan Hoffmann	#else
891	f7556b0d	Jan Hoffmann	buffer[i] = _wire->receive();
892	55e2f6d1	Jan Hoffmann	#endif
893	463eabf7	Wetmelon	}
894
895			/* ToDo: Check for errors! */
896			return true;
897			}