WebSVN - NaviCtrl - Blame - Rev 267

Rev	Author	Line No.	Line
242	killagreg	1	/#######################################################################################/
		2	/* !!! THIS IS NOT FREE SOFTWARE !!! */
		3	/#######################################################################################/
		4	// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
		5	// + Copyright (c) 2010 Ingo Busker, Holger Buss
		6	// + Nur f�r den privaten Gebrauch / NON-COMMERCIAL USE ONLY
		7	// + FOR NON COMMERCIAL USE ONLY
		8	// + www.MikroKopter.com
		9	// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
		10	// + Es gilt f�r das gesamte Projekt (Hardware, Software, Bin�rfiles, Sourcecode und Dokumentation),
		11	// + dass eine Nutzung (auch auszugsweise) nur f�r den privaten (nicht-kommerziellen) Gebrauch zul�ssig ist.
		12	// + Sollten direkte oder indirekte kommerzielle Absichten verfolgt werden, ist mit uns (info@mikrokopter.de) Kontakt
		13	// + bzgl. der Nutzungsbedingungen aufzunehmen.
		14	// + Eine kommerzielle Nutzung ist z.B.Verkauf von MikroKoptern, Best�ckung und Verkauf von Platinen oder Baus�tzen,
		15	// + Verkauf von Luftbildaufnahmen, usw.
		16	// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
		17	// + Werden Teile des Quellcodes (mit oder ohne Modifikation) weiterverwendet oder ver�ffentlicht,
		18	// + unterliegen sie auch diesen Nutzungsbedingungen und diese Nutzungsbedingungen incl. Copyright m�ssen dann beiliegen
		19	// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
		20	// + Sollte die Software (auch auszugesweise) oder sonstige Informationen des MikroKopter-Projekts
		21	// + auf anderen Webseiten oder sonstigen Medien ver�ffentlicht werden, muss unsere Webseite "http://www.mikrokopter.de"
		22	// + eindeutig als Ursprung verlinkt werden
		23	// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
		24	// + Keine Gew�hr auf Fehlerfreiheit, Vollst�ndigkeit oder Funktion
		25	// + Benutzung auf eigene Gefahr
		26	// + Wir �bernehmen keinerlei Haftung f�r direkte oder indirekte Personen- oder Sachsch�den
		27	// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
		28	// + Die Portierung oder Nutzung der Software (oder Teile davon) auf andere Systeme (ausser der Hardware von www.mikrokopter.de) ist nur
		29	// + mit unserer Zustimmung zul�ssig
		30	// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
		31	// + Die Funktion printf_P() unterliegt ihrer eigenen Lizenz und ist hiervon nicht betroffen
		32	// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
		33	// + Redistributions of source code (with or without modifications) must retain the above copyright notice,
		34	// + this list of conditions and the following disclaimer.
		35	// + * Neither the name of the copyright holders nor the names of contributors may be used to endorse or promote products derived
		36	// + from this software without specific prior written permission.
		37	// + * The use of this project (hardware, software, binary files, sources and documentation) is only permitted
		38	// + for non-commercial use (directly or indirectly)
		39	// + Commercial use (for excample: selling of MikroKopters, selling of PCBs, assembly, ...) is only permitted
		40	// + with our written permission
		41	// + * If sources or documentations are redistributet on other webpages, out webpage (http://www.MikroKopter.de) must be
		42	// + clearly linked as origin
		43	// + * porting the sources to other systems or using the software on other systems (except hardware from www.mikrokopter.de) is not allowed
		44	//
		45	// + THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
		46	// + AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
		47	// + IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
		48	// + ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
		49	// + LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
		50	// + CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
		51	// + SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
		52	// + INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
		53	// + CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
		54	// + ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
		55	// + POSSIBILITY OF SUCH DAMAGE.
		56	// ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
254	killagreg	57	#include <math.h>
242	killagreg	58	#include <string.h>
		59	#include "91x_lib.h"
253	killagreg	60	#include "ncmag.h"
242	killagreg	61	#include "i2c.h"
		62	#include "timer1.h"
		63	#include "led.h"
		64	#include "spi_slave.h"
		65	#include "uart1.h"
254	killagreg	66	#include "eeprom.h"
256	killagreg	67	#include "mymath.h"
242	killagreg	68
253	killagreg	69	u8 NCMAG_Present = 0;
254	killagreg	70	u8 NCMAG_IsCalibrated = 0;
242	killagreg	71
253	killagreg	72	#define MAG_TYPE_NONE 0
		73	#define MAG_TYPE_HMC5843 1
		74	#define MAG_TYPE_LSM303DLH 2
254	killagreg	75	u8 NCMAG_MagType = MAG_TYPE_NONE;
242	killagreg	76
254	killagreg	77	#define CALIBRATION_VERSION 1
		78	#define EEPROM_ADR_MAG_CALIBRATION 50
		79
256	killagreg	80	#define NCMAG_MIN_RAWVALUE -2047
		81	#define NCMAG_MAX_RAWVALUE 2047
		82	#define NCMAG_INVALID_DATA -4096
		83
254	killagreg	84	typedef struct
		85	{
		86	s16 Range;
		87	s16 Offset;
256	killagreg	88	} __attribute__((packed)) Scaling_t;
254	killagreg	89
		90	typedef struct
		91	{
		92	Scaling_t MagX;
		93	Scaling_t MagY;
		94	Scaling_t MagZ;
		95	u8 Version;
		96	u8 crc;
256	killagreg	97	} __attribute__((packed)) Calibration_t;
254	killagreg	98
		99	Calibration_t Calibration; // calibration data in RAM
		100
253	killagreg	101	// i2c MAG interface
		102	#define MAG_SLAVE_ADDRESS 0x3C // i2C slave address mag. sensor registers
242	killagreg	103
253	killagreg	104	// register mapping
		105	#define REG_MAG_CRA 0x00
		106	#define REG_MAG_CRB 0x01
		107	#define REG_MAG_MODE 0x02
		108	#define REG_MAG_DATAX_MSB 0x03
		109	#define REG_MAG_DATAX_LSB 0x04
		110	#define REG_MAG_DATAY_MSB 0x05
		111	#define REG_MAG_DATAY_LSB 0x06
		112	#define REG_MAG_DATAZ_MSB 0x07
		113	#define REG_MAG_DATAZ_LSB 0x08
		114	#define REG_MAG_STATUS 0x09
		115	#define REG_MAG_IDA 0x0A
		116	#define REG_MAG_IDB 0x0B
		117	#define REG_MAG_IDC 0x0C
242	killagreg	118
253	killagreg	119	// bit mask for configuration mode
		120	#define CRA_MODE_MASK 0x03
		121	#define CRA_MODE_NORMAL 0x00 //default
		122	#define CRA_MODE_POSBIAS 0x01
		123	#define CRA_MODE_NEGBIAS 0x02
		124	#define CRA_MODE_SELFTEST 0x03
242	killagreg	125
253	killagreg	126	// bit mask for measurement mode
		127	#define MODE_MASK 0xFF
		128	#define MODE_CONTINUOUS 0x00
		129	#define MODE_SINGLE 0x01 // default
		130	#define MODE_IDLE 0x02
		131	#define MODE_SLEEP 0x03
		132
242	killagreg	133	// bit mask for rate
253	killagreg	134	#define CRA_RATE_MASK 0x1C
		135
		136	// bit mask for gain
		137	#define CRB_GAIN_MASK 0xE0
		138
		139	// ids
		140	#define MAG_IDA 0x48
		141	#define MAG_IDB 0x34
		142	#define MAG_IDC 0x33
		143
		144	// the special HMC5843 interface
		145	// bit mask for rate
242	killagreg	146	#define HMC5843_CRA_RATE_0_5HZ 0x00
		147	#define HMC5843_CRA_RATE_1HZ 0x04
		148	#define HMC5843_CRA_RATE_2HZ 0x08
		149	#define HMC5843_CRA_RATE_5HZ 0x0C
		150	#define HMC5843_CRA_RATE_10HZ 0x10 //default
		151	#define HMC5843_CRA_RATE_20HZ 0x14
		152	#define HMC5843_CRA_RATE_50HZ 0x18
		153	// bit mask for gain
		154	#define HMC5843_CRB_GAIN_07GA 0x00
		155	#define HMC5843_CRB_GAIN_10GA 0x20 //default
		156	#define HMC5843_CRB_GAIN_15GA 0x40
		157	#define HMC5843_CRB_GAIN_20GA 0x60
		158	#define HMC5843_CRB_GAIN_32GA 0x80
		159	#define HMC5843_CRB_GAIN_38GA 0xA0
		160	#define HMC5843_CRB_GAIN_45GA 0xC0
		161	#define HMC5843_CRB_GAIN_65GA 0xE0
253	killagreg	162	// self test value
		163	#define HMC5843_TEST_XSCALE 715
		164	#define HMC5843_TEST_YSCALE 715
		165	#define HMC5843_TEST_ZSCALE 715
242	killagreg	166
		167
253	killagreg	168	// the special LSM302DLH interface
		169	// bit mask for rate
		170	#define LSM303DLH_CRA_RATE_0_75HZ 0x00
		171	#define LSM303DLH_CRA_RATE_1_5HZ 0x04
		172	#define LSM303DLH_CRA_RATE_3_0HZ 0x08
		173	#define LSM303DLH_CRA_RATE_7_5HZ 0x0C
		174	#define LSM303DLH_CRA_RATE_15HZ 0x10 //default
		175	#define LSM303DLH_CRA_RATE_30HZ 0x14
		176	#define LSM303DLH_CRA_RATE_75HZ 0x18
		177	// bit mask for gain
		178	#define LSM303DLH_CRB_GAIN_XXGA 0x00
		179	#define LSM303DLH_CRB_GAIN_13GA 0x20 //default
		180	#define LSM303DLH_CRB_GAIN_19GA 0x40
		181	#define LSM303DLH_CRB_GAIN_25GA 0x60
		182	#define LSM303DLH_CRB_GAIN_40GA 0x80
		183	#define LSM303DLH_CRB_GAIN_47GA 0xA0
		184	#define LSM303DLH_CRB_GAIN_56GA 0xC0
		185	#define LSM303DLH_CRB_GAIN_81GA 0xE0
		186	// self test value
		187	#define LSM303DLH_TEST_XSCALE 655
		188	#define LSM303DLH_TEST_YSCALE 655
		189	#define LSM303DLH_TEST_ZSCALE 630
		190
		191	// the i2c ACC interface
		192	#define ACC_SLAVE_ADDRESS 0x30 // i2c slave for acc. sensor registers
		193	// register mapping
		194	#define REG_ACC_CTRL1 0x20
		195	#define REG_ACC_CTRL2 0x21
		196	#define REG_ACC_CTRL3 0x22
		197	#define REG_ACC_CTRL4 0x23
		198	#define REG_ACC_CTRL5 0x24
		199	#define REG_ACC_HP_FILTER_RESET 0x25
		200	#define REG_ACC_REFERENCE 0x26
		201	#define REG_ACC_STATUS 0x27
		202	#define REG_ACC_X_LSB 0x28
		203	#define REG_ACC_X_MSB 0x29
		204	#define REG_ACC_Y_LSB 0x2A
		205	#define REG_ACC_Y_MSB 0x2B
		206	#define REG_ACC_Z_LSB 0x2C
		207	#define REG_ACC_Z_MSB 0x2D
		208
		209
		210
242	killagreg	211	typedef struct
		212	{
253	killagreg	213	u8 A;
		214	u8 B;
		215	u8 C;
		216	} __attribute__((packed)) Identification_t;
242	killagreg	217
253	killagreg	218	volatile Identification_t NCMAG_Identification;
242	killagreg	219
253	killagreg	220	typedef struct
		221	{
		222	u8 cra;
		223	u8 crb;
		224	u8 mode;
		225	} __attribute__((packed)) MagConfig_t;
242	killagreg	226
253	killagreg	227	volatile MagConfig_t MagConfig;
242	killagreg	228
253	killagreg	229	typedef struct
		230	{
		231	u8 ctrl_1;
		232	u8 ctrl_2;
		233	u8 ctrl_3;
		234	u8 ctrl_4;
		235	u8 ctrl_5;
		236	} __attribute__((packed)) AccConfig_t;
		237
		238	volatile AccConfig_t AccConfig;
		239
254	killagreg	240	volatile s16vec_t AccRawVector;
		241	volatile s16vec_t MagRawVector;
253	killagreg	242
		243
254	killagreg	244	u8 NCMag_CalibrationWrite(void)
		245	{
		246	u8 i, crc = 0xAA;
		247	EEPROM_Result_t eres;
		248	u8 pBuff = (u8)&Calibration;
		249
		250	Calibration.Version = CALIBRATION_VERSION;
256	killagreg	251	for(i = 0; i<(sizeof(Calibration)-1); i++)
254	killagreg	252	{
		253	crc += pBuff[i];
		254	}
		255	Calibration.crc = ~crc;
		256	eres = EEPROM_WriteBlock(EEPROM_ADR_MAG_CALIBRATION, pBuff, sizeof(Calibration));
		257	if(EEPROM_SUCCESS == eres) i = 1;
		258	else i = 0;
		259	return(i);
		260	}
		261
		262	u8 NCMag_CalibrationRead(void)
		263	{
		264	u8 i, crc = 0xAA;
		265	u8 pBuff = (u8)&Calibration;
		266
		267	if(EEPROM_SUCCESS == EEPROM_ReadBlock(EEPROM_ADR_MAG_CALIBRATION, pBuff, sizeof(Calibration)))
		268	{
256	killagreg	269	for(i = 0; i<(sizeof(Calibration)-1); i++)
254	killagreg	270	{
		271	crc += pBuff[i];
		272	}
		273	crc = ~crc;
		274	if(Calibration.crc != crc) return(0); // crc mismatch
257	killagreg	275	if(Calibration.Version == CALIBRATION_VERSION) return(1);
254	killagreg	276	}
		277	return(0);
		278	}
		279
		280
		281	void NCMAG_Calibrate(void)
		282	{
		283	static s16 Xmin = 0, Xmax = 0, Ymin = 0, Ymax = 0, Zmin = 0, Zmax = 0;
256	killagreg	284	static s16 X = 0, Y = 0, Z = 0;
254	killagreg	285	static u8 OldCalState = 0;
		286
256	killagreg	287	X = (4*X + MagRawVector.X + 3)/5;
		288	Y = (4*Y + MagRawVector.Y + 3)/5;
		289	Z = (4*Z + MagRawVector.Z + 3)/5;
		290
254	killagreg	291	switch(Compass_CalState)
		292	{
		293	case 1:
		294	// 1st step of calibration
		295	// initialize ranges
		296	// used to change the orientation of the NC in the horizontal plane
		297	Xmin = 10000;
		298	Xmax = -10000;
		299	Ymin = 10000;
		300	Ymax = -10000;
		301	Zmin = 10000;
		302	Zmax = -10000;
		303	break;
		304
		305	case 2: // 2nd step of calibration
		306	// find Min and Max of the X- and Y-Sensors during rotation in the horizontal plane
256	killagreg	307	if(X < Xmin) Xmin = X;
		308	else if(X > Xmax) Xmax = X;
		309	if(Y < Ymin) Ymin = Y;
		310	else if(Y > Ymax) Ymax = Y;
254	killagreg	311	break;
		312
		313	case 3: // 3rd step of calibration
		314	// used to change the orientation of the MK3MAG vertical to the horizontal plane
		315	break;
		316
		317	case 4:
		318	// find Min and Max of the Z-Sensor
256	killagreg	319	if(Z < Zmin) Zmin = Z;
		320	else if(Z > Zmax) Zmax = Z;
254	killagreg	321	break;
		322
		323	case 5:
		324	// Save values
		325	if(Compass_CalState != OldCalState) // avoid continously writing of eeprom!
		326	{
267	holgerb	327	#define MIN_CALIBRATION 256
254	killagreg	328	Calibration.MagX.Range = Xmax - Xmin;
		329	Calibration.MagX.Offset = (Xmin + Xmax) / 2;
		330	Calibration.MagY.Range = Ymax - Ymin;
		331	Calibration.MagY.Offset = (Ymin + Ymax) / 2;
		332	Calibration.MagZ.Range = Zmax - Zmin;
		333	Calibration.MagZ.Offset = (Zmin + Zmax) / 2;
265	holgerb	334	if((Calibration.MagX.Range > MIN_CALIBRATION) && (Calibration.MagY.Range > MIN_CALIBRATION) && (Calibration.MagZ.Range > MIN_CALIBRATION))
254	killagreg	335	{
		336	NCMAG_IsCalibrated = NCMag_CalibrationWrite();
265	holgerb	337	UART1_PutString("\r\n Calibration okay");
254	killagreg	338	}
		339	else
		340	{
		341	// restore old calibration data from eeprom
		342	NCMAG_IsCalibrated = NCMag_CalibrationRead();
265	holgerb	343	UART1_PutString("\r\n Calibration FAILED - Values too low: ");
		344	if(Calibration.MagX.Range < MIN_CALIBRATION) UART1_PutString("X! ");
		345	if(Calibration.MagY.Range < MIN_CALIBRATION) UART1_PutString("Y! ");
		346	if(Calibration.MagZ.Range < MIN_CALIBRATION) UART1_PutString("Z! ");
254	killagreg	347	}
		348	}
		349	break;
		350
		351	default:
		352	break;
		353	}
		354	OldCalState = Compass_CalState;
		355	}
		356
242	killagreg	357	// ---------- call back handlers -----------------------------------------
		358
		359	// rx data handler for id info request
253	killagreg	360	void NCMAG_UpdateIdentification(u8* pRxBuffer, u8 RxBufferSize)
254	killagreg	361	{ // if number of bytes are matching
253	killagreg	362	if(RxBufferSize == sizeof(NCMAG_Identification) )
242	killagreg	363	{
253	killagreg	364	memcpy((u8 *)&NCMAG_Identification, pRxBuffer, sizeof(NCMAG_Identification));
		365	}
242	killagreg	366	}
254	killagreg	367	// rx data handler for magnetic sensor raw data
253	killagreg	368	void NCMAG_UpdateMagVector(u8* pRxBuffer, u8 RxBufferSize)
254	killagreg	369	{ // if number of bytes are matching
		370	if(RxBufferSize == sizeof(MagRawVector) )
243	killagreg	371	{ // byte order from big to little endian
256	killagreg	372	s16 raw;
		373	raw = pRxBuffer[0]<<8;
		374	raw+= pRxBuffer[1];
		375	if(raw >= NCMAG_MIN_RAWVALUE && raw <= NCMAG_MAX_RAWVALUE) MagRawVector.X = raw;
		376	raw = pRxBuffer[2]<<8;
		377	raw+= pRxBuffer[3];
		378	if(raw >= NCMAG_MIN_RAWVALUE && raw <= NCMAG_MAX_RAWVALUE) MagRawVector.Y = raw;
		379	raw = pRxBuffer[4]<<8;
		380	raw+= pRxBuffer[5];
		381	if(raw >= NCMAG_MIN_RAWVALUE && raw <= NCMAG_MAX_RAWVALUE) MagRawVector.Z = raw;
242	killagreg	382	}
254	killagreg	383	if(Compass_CalState \|\| !NCMAG_IsCalibrated)
		384	{ // direct output the raw data
		385	memcpy((u8)&MagVector,(u8)&MagRawVector, sizeof(MagVector));
		386	Compass_Heading = -1;
		387	}
		388	else
		389	{
		390	// update MagVector from MagRaw Vector by Scaling
		391	MagVector.X = (s16)((1024L*(s32)(MagRawVector.X - Calibration.MagX.Offset))/Calibration.MagX.Range);
		392	MagVector.Y = (s16)((1024L*(s32)(MagRawVector.Y - Calibration.MagY.Offset))/Calibration.MagY.Range);
		393	MagVector.Z = (s16)((1024L*(s32)(MagRawVector.Z - Calibration.MagZ.Offset))/Calibration.MagZ.Range);
256	killagreg	394
		395	if(UART_VersionInfo.HardwareError[0] & NC_ERROR0_SPI_RX)
		396	{
		397	Compass_Heading = -1;
		398	}
		399	else // fc attitude is avialable
		400	{
		401	// calculate attitude correction
		402	// a float implementation takes too long for an ISR call!
		403	s16 tmp, Hx, Hy;
		404	s32 sinnick, cosnick, sinroll, cosroll;
		405
		406	tmp = FromFlightCtrl.AngleNick/10; // in deg
		407	sinnick = (s32)c_sin_8192(tmp);
		408	cosnick = (s32)c_cos_8192(tmp);
		409	tmp = FromFlightCtrl.AngleRoll/10; // in deg
		410	sinroll = (s32)c_sin_8192(tmp);
		411	cosroll = (s32)c_cos_8192(tmp);
		412	// tbd. compensation signs and oriantation has to be fixed
257	killagreg	413	Hx = (s16)((MagVector.Y * cosnick + MagVector.Z * sinnick)/8192L);
		414	Hy = (s16)((MagVector.X * cosroll - MagVector.Z * sinroll)/8192L);
256	killagreg	415	// calculate heading
		416	tmp = (s16)(c_tan2_546(Hy, Hx)/546L);
257	killagreg	417	if (tmp > 0) tmp = 360 - tmp;
		418	else tmp = -tmp;
256	killagreg	419	Compass_Heading = tmp;
		420	}
254	killagreg	421	}
242	killagreg	422	}
254	killagreg	423	// rx data handler for acceleration raw data
253	killagreg	424	void NCMAG_UpdateAccVector(u8* pRxBuffer, u8 RxBufferSize)
		425	{ // if number of byte are matching
254	killagreg	426	if(RxBufferSize == sizeof(AccRawVector) )
253	killagreg	427	{
254	killagreg	428	memcpy((u8*)&AccRawVector, pRxBuffer,sizeof(AccRawVector));
253	killagreg	429	}
		430	}
254	killagreg	431	// rx data handler for reading magnetic sensor configuration
253	killagreg	432	void NCMAG_UpdateMagConfig(u8* pRxBuffer, u8 RxBufferSize)
		433	{ // if number of byte are matching
		434	if(RxBufferSize == sizeof(MagConfig) )
		435	{
		436	memcpy((u8*)(&MagConfig), pRxBuffer, sizeof(MagConfig));
		437	}
		438	}
254	killagreg	439	// rx data handler for reading acceleration sensor configuration
253	killagreg	440	void NCMAG_UpdateAccConfig(u8* pRxBuffer, u8 RxBufferSize)
		441	{ // if number of byte are matching
		442	if(RxBufferSize == sizeof(AccConfig) )
		443	{
		444	memcpy((u8*)&AccConfig, pRxBuffer, sizeof(AccConfig));
		445	}
		446	}
254	killagreg	447	//----------------------------------------------------------------------
253	killagreg	448
254	killagreg	449
		450	// ---------------------------------------------------------------------
253	killagreg	451	u8 NCMAG_SetMagConfig(void)
		452	{
		453	u8 retval = 0;
		454	// try to catch the i2c buffer within 100 ms timeout
		455	if(I2C_LockBuffer(100))
		456	{
		457	u8 TxBytes = 0;
		458	I2C_Buffer[TxBytes++] = REG_MAG_CRA;
		459	memcpy((u8)(&I2C_Buffer[TxBytes]), (u8)&MagConfig, sizeof(MagConfig));
		460	TxBytes += sizeof(MagConfig);
		461	if(I2C_Transmission(MAG_SLAVE_ADDRESS, TxBytes, 0, 0))
		462	{
		463	if(I2C_WaitForEndOfTransmission(100))
		464	{
		465	if(I2C_Error == I2C_ERROR_NONE) retval = 1;
		466	}
		467	}
		468	}
		469	return(retval);
		470	}
242	killagreg	471
253	killagreg	472	// ----------------------------------------------------------------------------------------
		473	u8 NCMAG_GetMagConfig(void)
242	killagreg	474	{
253	killagreg	475	u8 retval = 0;
252	killagreg	476	// try to catch the i2c buffer within 100 ms timeout
248	killagreg	477	if(I2C_LockBuffer(100))
242	killagreg	478	{
253	killagreg	479	u8 TxBytes = 0;
		480	I2C_Buffer[TxBytes++] = REG_MAG_CRA;
		481	if(I2C_Transmission(MAG_SLAVE_ADDRESS, TxBytes, &NCMAG_UpdateMagConfig, sizeof(MagConfig)))
248	killagreg	482	{
252	killagreg	483	if(I2C_WaitForEndOfTransmission(100))
		484	{
		485	if(I2C_Error == I2C_ERROR_NONE) retval = 1;
		486	}
248	killagreg	487	}
242	killagreg	488	}
253	killagreg	489	return(retval);
242	killagreg	490	}
		491
		492	// ----------------------------------------------------------------------------------------
253	killagreg	493	u8 NCMAG_SetAccConfig(void)
242	killagreg	494	{
252	killagreg	495	u8 retval = 0;
253	killagreg	496	// try to catch the i2c buffer within 100 ms timeout
248	killagreg	497	if(I2C_LockBuffer(100))
242	killagreg	498	{
253	killagreg	499	u8 TxBytes = 0;
		500	I2C_Buffer[TxBytes++] = REG_ACC_CTRL1;
		501	memcpy((u8)(&I2C_Buffer[TxBytes]), (u8)&AccConfig, sizeof(AccConfig));
		502	TxBytes += sizeof(AccConfig);
		503	if(I2C_Transmission(ACC_SLAVE_ADDRESS, TxBytes, 0, 0))
		504	{
		505	if(I2C_WaitForEndOfTransmission(100))
		506	{
		507	if(I2C_Error == I2C_ERROR_NONE) retval = 1;
		508	}
		509	}
		510	}
		511	return(retval);
		512	}
		513
		514	// ----------------------------------------------------------------------------------------
		515	u8 NCMAG_GetAccConfig(void)
		516	{
		517	u8 retval = 0;
		518	// try to catch the i2c buffer within 100 ms timeout
		519	if(I2C_LockBuffer(100))
		520	{
		521	u8 TxBytes = 0;
		522	I2C_Buffer[TxBytes++] = REG_ACC_CTRL1;
		523	if(I2C_Transmission(ACC_SLAVE_ADDRESS, TxBytes, &NCMAG_UpdateAccConfig, sizeof(AccConfig)))
		524	{
		525	if(I2C_WaitForEndOfTransmission(100))
		526	{
		527	if(I2C_Error == I2C_ERROR_NONE) retval = 1;
		528	}
		529	}
		530	}
		531	return(retval);
		532	}
		533
		534	// ----------------------------------------------------------------------------------------
		535	u8 NCMAG_GetIdentification(void)
		536	{
		537	u8 retval = 0;
		538	// try to catch the i2c buffer within 100 ms timeout
		539	if(I2C_LockBuffer(100))
		540	{
		541	u16 TxBytes = 0;
		542	NCMAG_Identification.A = 0xFF;
		543	NCMAG_Identification.B = 0xFF;
		544	NCMAG_Identification.C = 0xFF;
		545	I2C_Buffer[TxBytes++] = REG_MAG_IDA;
248	killagreg	546	// initiate transmission
253	killagreg	547	if(I2C_Transmission(MAG_SLAVE_ADDRESS, TxBytes, &NCMAG_UpdateIdentification, sizeof(NCMAG_Identification)))
248	killagreg	548	{
253	killagreg	549	if(I2C_WaitForEndOfTransmission(100))
252	killagreg	550	{
		551	if(I2C_Error == I2C_ERROR_NONE) retval = 1;
		552	}
248	killagreg	553	}
242	killagreg	554	}
253	killagreg	555	return(retval);
242	killagreg	556	}
		557
253	killagreg	558	// ----------------------------------------------------------------------------------------
		559	void NCMAG_GetMagVector(void)
		560	{
		561	// try to catch the I2C buffer within 0 ms
		562	if(I2C_LockBuffer(0))
		563	{
		564	u16 TxBytes = 0;
		565	// set register pointer
		566	I2C_Buffer[TxBytes++] = REG_MAG_DATAX_MSB;
		567	// initiate transmission
		568	I2C_Transmission(MAG_SLAVE_ADDRESS, TxBytes, &NCMAG_UpdateMagVector, sizeof(MagVector));
		569	}
		570	}
		571
242	killagreg	572	//----------------------------------------------------------------
253	killagreg	573	void NCMAG_GetAccVector(void)
243	killagreg	574	{
252	killagreg	575	// try to catch the I2C buffer within 0 ms
		576	if(I2C_LockBuffer(0))
243	killagreg	577	{
248	killagreg	578	u16 TxBytes = 0;
243	killagreg	579	// set register pointer
253	killagreg	580	I2C_Buffer[TxBytes++] = REG_ACC_X_LSB;
243	killagreg	581	// initiate transmission
254	killagreg	582	I2C_Transmission(ACC_SLAVE_ADDRESS, TxBytes, &NCMAG_UpdateAccVector, sizeof(AccRawVector));
243	killagreg	583	}
		584	}
		585
253	killagreg	586	// --------------------------------------------------------
		587	void NCMAG_UpdateCompass(void)
243	killagreg	588	{
		589	static u32 TimerCompassUpdate = 0;
		590
254	killagreg	591	if( (I2C_State == I2C_STATE_OFF) \|\| !NCMAG_Present )
		592	{
		593	Compass_Heading = -1;
		594	return;
		595	}
253	killagreg	596
243	killagreg	597	if(CheckDelay(TimerCompassUpdate))
		598	{
254	killagreg	599	// check for new calibration state
		600	Compass_UpdateCalState();
		601	if(Compass_CalState) NCMAG_Calibrate();
		602	NCMAG_GetMagVector(); //Get new data;
243	killagreg	603	TimerCompassUpdate = SetDelay(20); // every 20 ms are 50 Hz
		604	}
		605	}
		606
254	killagreg	607	// --------------------------------------------------------
253	killagreg	608	u8 NCMAG_SelfTest(void)
243	killagreg	609	{
266	holgerb	610	u8 msg[64];
		611
253	killagreg	612	#define LIMITS(value, min, max) {min = (90 * value)/100; max = (110 * value)/100;}
243	killagreg	613	u32 time;
253	killagreg	614	s32 XMin = 0, XMax = 0, YMin = 0, YMax = 0, ZMin = 0, ZMax = 0;
		615	s16 xscale, yscale, zscale, scale_min, scale_max;
		616	u8 crb_gain, cra_rate;
		617	u8 i = 0, retval = 1;
243	killagreg	618
253	killagreg	619	switch(NCMAG_MagType)
		620	{
		621	case MAG_TYPE_HMC5843:
		622	crb_gain = HMC5843_CRB_GAIN_10GA;
		623	cra_rate = HMC5843_CRA_RATE_50HZ;
		624	xscale = HMC5843_TEST_XSCALE;
		625	yscale = HMC5843_TEST_YSCALE;
		626	zscale = HMC5843_TEST_ZSCALE;
		627	break;
		628
		629	case MAG_TYPE_LSM303DLH:
		630	crb_gain = LSM303DLH_CRB_GAIN_13GA;
		631	cra_rate = LSM303DLH_CRA_RATE_75HZ;
		632	xscale = LSM303DLH_TEST_XSCALE;
		633	yscale = LSM303DLH_TEST_YSCALE;
		634	zscale = LSM303DLH_TEST_ZSCALE;
		635	break;
		636
		637	default:
		638	return(0);
		639	}
		640
		641	MagConfig.cra = cra_rate\|CRA_MODE_POSBIAS;
		642	MagConfig.crb = crb_gain;
		643	MagConfig.mode = MODE_CONTINUOUS;
		644	// activate positive bias field
		645	NCMAG_SetMagConfig();
251	killagreg	646	// wait for stable readings
		647	time = SetDelay(50);
		648	while(!CheckDelay(time));
243	killagreg	649	// averaging
253	killagreg	650	#define AVERAGE 20
		651	for(i = 0; i<AVERAGE; i++)
243	killagreg	652	{
253	killagreg	653	NCMAG_GetMagVector();
243	killagreg	654	time = SetDelay(20);
		655	while(!CheckDelay(time));
254	killagreg	656	XMax += MagRawVector.X;
		657	YMax += MagRawVector.Y;
		658	ZMax += MagRawVector.Z;
243	killagreg	659	}
253	killagreg	660	MagConfig.cra = cra_rate\|CRA_MODE_NEGBIAS;
		661	// activate positive bias field
		662	NCMAG_SetMagConfig();
251	killagreg	663	// wait for stable readings
		664	time = SetDelay(50);
		665	while(!CheckDelay(time));
243	killagreg	666	// averaging
253	killagreg	667	for(i = 0; i < AVERAGE; i++)
243	killagreg	668	{
253	killagreg	669	NCMAG_GetMagVector();
243	killagreg	670	time = SetDelay(20);
		671	while(!CheckDelay(time));
254	killagreg	672	XMin += MagRawVector.X;
		673	YMin += MagRawVector.Y;
		674	ZMin += MagRawVector.Z;
243	killagreg	675	}
		676	// setup final configuration
253	killagreg	677	MagConfig.cra = cra_rate\|CRA_MODE_NORMAL;
		678	// activate positive bias field
		679	NCMAG_SetMagConfig();
266	holgerb	680	// check scale for all axes
243	killagreg	681	// prepare scale limits
253	killagreg	682	LIMITS(xscale, scale_min, scale_max);
267	holgerb	683	xscale = (XMax - XMin)/(2*AVERAGE);
266	holgerb	684	if((xscale > scale_max) \|\| (xscale < scale_min))
		685	{
		686	retval = 0;
		687	sprintf(msg, "\r\n Value X: %d not %d-%d !", xscale, scale_min,scale_max);
		688	UART1_PutString(msg);
		689	}
267	holgerb	690	LIMITS(yscale, scale_min, scale_max);
266	holgerb	691	yscale = (YMax - YMin)/(2*AVERAGE);
		692	if((yscale > scale_max) \|\| (yscale < scale_min))
		693	{
		694	retval = 0;
		695	sprintf(msg, "\r\n Value Y: %d not %d-%d !", yscale, scale_min,scale_max);
		696	UART1_PutString(msg);
		697	}
267	holgerb	698	LIMITS(zscale, scale_min, scale_max);
266	holgerb	699	zscale = (ZMax - ZMin)/(2*AVERAGE);
		700	if((zscale > scale_max) \|\| (zscale < scale_min))
		701	{
		702	retval = 0;
		703	sprintf(msg, "\r\n Value Z: %d not %d-%d !", zscale, scale_min,scale_max);
		704	UART1_PutString(msg);
		705	}
253	killagreg	706	return(retval);
243	killagreg	707	}
		708
		709
		710	//----------------------------------------------------------------
253	killagreg	711	u8 NCMAG_Init(void)
242	killagreg	712	{
		713	u8 msg[64];
252	killagreg	714	u8 retval = 0;
242	killagreg	715	u8 repeat;
		716
253	killagreg	717	NCMAG_Present = 0;
		718	NCMAG_MagType = MAG_TYPE_HMC5843; // assuming having an HMC5843
		719	// polling for LSM302DLH option
		720	repeat = 0;
		721	do
		722	{
		723	retval = NCMAG_GetAccConfig();
		724	if(retval) break; // break loop on success
		725	UART1_PutString(".");
		726	repeat++;
		727	}while(repeat < 3);
		728	if(retval) NCMAG_MagType = MAG_TYPE_LSM303DLH; // must be a LSM303DLH
242	killagreg	729	// polling of identification
		730	repeat = 0;
		731	do
		732	{
253	killagreg	733	retval = NCMAG_GetIdentification();
252	killagreg	734	if(retval) break; // break loop on success
242	killagreg	735	UART1_PutString(".");
		736	repeat++;
252	killagreg	737	}while(repeat < 12);
253	killagreg	738	// if we got an answer to id request
252	killagreg	739	if(retval)
242	killagreg	740	{
253	killagreg	741	u8 n1[] = "HMC5843";
		742	u8 n2[] = "LSM303DLH";
		743	u8* pn;
		744	if(NCMAG_MagType == MAG_TYPE_LSM303DLH) pn = n2;
		745	else pn = n1;
		746	sprintf(msg, " %s ID%d/%d/%d", pn, NCMAG_Identification.A, NCMAG_Identification.B, NCMAG_Identification.C);
242	killagreg	747	UART1_PutString(msg);
253	killagreg	748	if ( (NCMAG_Identification.A == MAG_IDA)
		749	&& (NCMAG_Identification.B == MAG_IDB)
		750	&& (NCMAG_Identification.C == MAG_IDC))
242	killagreg	751	{
253	killagreg	752	if(!NCMAG_SelfTest())
243	killagreg	753	{
253	killagreg	754	UART1_PutString(" Selftest failed!");
243	killagreg	755	LED_RED_ON;
		756	}
254	killagreg	757	else
		758	{
		759	NCMAG_Present = 1;
264	killagreg	760	if(EEPROM_Init())
		761	{
		762	NCMAG_IsCalibrated = NCMag_CalibrationRead();
		763	if(!NCMAG_IsCalibrated) UART1_PutString("\r\n Not calibrated!");
		764	}
		765	else UART1_PutString("\r\n Calibration data not available!");
254	killagreg	766	}
242	killagreg	767	}
		768	else
		769	{
254	killagreg	770	UART1_PutString("\n\r Not compatible!");
256	killagreg	771	UART_VersionInfo.HardwareError[0] \|= NC_ERROR0_COMPASS_INCOMPATIBLE;
242	killagreg	772	LED_RED_ON;
		773	}
		774	}
253	killagreg	775	else // nothing found
		776	{
		777	NCMAG_MagType = MAG_TYPE_NONE;
		778	UART1_PutString("not found!");
		779	}
		780	return(NCMAG_Present);
242	killagreg	781	}
		782

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(root)/tags/V2.10b/ncmag.c @ 811 - Rev 267