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/*
Copyright 2008, by Killagreg
This program (files mm3.c and mm3.h) is free software; you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation;
either version 3 of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
Please note: The original implementation was done by Niklas Nold.
All the other files for the project "Mikrokopter" by H. Buss and I. Busker are under the license (License.txt) published by www.mikrokopter.de
*/
#include <stdlib.h>
#include <avr/io.h>
#include <avr/interrupt.h>
#include <inttypes.h>
#include "mm3.h"
#include "main.h"
#include "mymath.h"
#include "fc.h"
#include "timer0.h"
#include "rc.h"
#include "eeprom.h"
#include "printf_P.h"
// for compatibility reasons gcc3.x <-> gcc4.x
#ifndef SPCR
#define SPCR SPCR0
#endif
#ifndef SPIE
#define SPIE SPIE0
#endif
#ifndef SPE
#define SPE SPE0
#endif
#ifndef DORD
#define DORD DORD0
#endif
#ifndef MSTR
#define MSTR MSTR0
#endif
#ifndef CPOL
#define CPOL CPOL0
#endif
#ifndef CPHA
#define CPHA CPHA0
#endif
#ifndef SPR1
#define SPR1 SPR01
#endif
#ifndef SPR0
#define SPR0 SPR00
#endif
#ifndef SPDR
#define SPDR SPDR0
#endif
#ifndef SPSR
#define SPSR SPSR0
#endif
#ifndef SPIF
#define SPIF SPIF0
#endif
#ifndef WCOL
#define WCOL WCOL0
#endif
#ifndef SPI2X
#define SPI2X SPI2X0
#endif
// -------------------------
#define MAX_AXIS_VALUE 500
typedef struct
{
uint8_t STATE
;
uint16_t DRDY
;
uint8_t AXIS
;
int16_t x_axis
;
int16_t y_axis
;
int16_t z_axis
;
} MM3_working_t
;
// MM3 State Machine
#define MM3_STATE_RESET 0
#define MM3_STATE_START_TRANSFER 1
#define MM3_STATE_WAIT_DRDY 2
#define MM3_STATE_DRDY 3
#define MM3_STATE_BYTE2 4
#define MM3_X_AXIS 0x01
#define MM3_Y_AXIS 0x02
#define MM3_Z_AXIS 0x03
#define MM3_PERIOD_32 0x00
#define MM3_PERIOD_64 0x10
#define MM3_PERIOD_128 0x20
#define MM3_PERIOD_256 0x30
#define MM3_PERIOD_512 0x40
#define MM3_PERIOD_1024 0x50
#define MM3_PERIOD_2048 0x60
#define MM3_PERIOD_4096 0x70
#if defined(USE_WALTER_EXT) // walthers board
// Output Pins (J9)PC6->MM3_SS ,(J8)PB2->MM3_RESET
#define MM3_SS_PORT PORTC //J9->MM3_SS
#define MM3_SS_DDR DDRC
#define MM3_SS_PIN PC6
#define MM3_RESET_PORT PORTB //J8->MM3_RESET
#define MM3_RESET_DDR DDRB
#define MM3_RESET_PIN PB2
#elif defined(USE_NICK666) // nick666 version 0.67g
#define MM3_SS_PORT PORTD //J5->MM3_SS
#define MM3_SS_DDR DDRD
#define MM3_SS_PIN PD3
#define MM3_RESET_PORT PORTB //J8->MM3_RESET
#define MM3_RESET_DDR DDRB
#define MM3_RESET_PIN PB2
#else // killagregs board
// Output Pins PC4->MM3_SS ,PC5->MM3_RESET
#define MM3_SS_PORT PORTC
#define MM3_SS_DDR DDRC
#define MM3_SS_PIN PC4
#define MM3_RESET_PORT PORTC
#define MM3_RESET_DDR DDRC
#define MM3_RESET_PIN PC5
#endif
#define MM3_SS_ON MM3_SS_PORT &= ~(1<<MM3_SS_PIN);
#define MM3_SS_OFF MM3_SS_PORT |= (1<<MM3_SS_PIN);
#define MM3_RESET_ON MM3_RESET_PORT |= (1<<MM3_RESET_PIN);
#define MM3_RESET_OFF MM3_RESET_PORT &= ~(1<<MM3_RESET_PIN);
MM3_calib_t MM3_calib
;
volatile MM3_working_t MM3
;
volatile uint8_t MM3_Timeout
= 0;
/*********************************************/
/* Initialize Interface to MM3 Compass */
/*********************************************/
void MM3_Init
(void)
{
uint8_t sreg
= SREG
;
cli
();
// Configure Pins for SPI
// set SCK (PB7), MOSI (PB5) as output
DDRB
|= (1<<DDB7
)|(1<<DDB5
);
// set MISO (PB6) as input
DDRB
&= ~
(1<<DDB6
);
// Output Pins MM3_SS ,MM3_RESET
MM3_SS_DDR
|= (1<<MM3_SS_PIN
);
MM3_RESET_DDR
|= (1<<MM3_RESET_PIN
);
// set pins permanent to low
MM3_SS_PORT
&= ~
((1<<MM3_SS_PIN
));
MM3_RESET_PORT
&= ~
((1<<MM3_RESET_PIN
));
// Initialize SPI-Interface
// Enable interrupt (SPIE=1)
// Enable SPI bus (SPE=1)
// MSB transmitted first (DORD = 0)
// Master SPI Mode (MSTR=1)
// Clock polarity low when idle (CPOL=0)
// Clock phase sample at leading edge (CPHA=0)
// Clock rate = SYSCLK/128 (SPI2X=0, SPR1=1, SPR0=1) 20MHz/128 = 156.25kHz
SPCR
= (1<<SPIE
)|(1<<SPE
)|(0<<DORD
)|(1<<MSTR
)|(0<<CPOL
)|(0<<CPHA
)|(1<<SPR1
)|(1<<SPR0
);
SPSR
&= ~
(1<<SPI2X
);
// Init Statemachine
MM3.
AXIS = MM3_X_AXIS
;
MM3.
STATE = MM3_STATE_RESET
;
// Read calibration from EEprom
MM3_calib.
X_off = (int8_t)GetParamByte
(PID_MM3_X_OFF
);
MM3_calib.
Y_off = (int8_t)GetParamByte
(PID_MM3_Y_OFF
);
MM3_calib.
Z_off = (int8_t)GetParamByte
(PID_MM3_Z_OFF
);
MM3_calib.
X_range = (int16_t)GetParamWord
(PID_MM3_X_RANGE
);
MM3_calib.
Y_range = (int16_t)GetParamWord
(PID_MM3_Y_RANGE
);
MM3_calib.
Z_range = (int16_t)GetParamWord
(PID_MM3_Z_RANGE
);
MM3_Timeout
= 0;
SREG
= sreg
;
}
/*********************************************/
/* Get Data from MM3 */
/*********************************************/
void MM3_Update
(void) // called every 102.4 µs by timer 0 ISR
{
switch (MM3.
STATE)
{
case MM3_STATE_RESET
:
MM3_SS_ON
// select slave
MM3_RESET_ON
// RESET to High, MM3 Reset
MM3.
STATE = MM3_STATE_START_TRANSFER
;
return;
case MM3_STATE_START_TRANSFER
:
MM3_RESET_OFF
// RESET auf Low (was 102.4 µs at high level)
// write to SPDR triggers automatically the transfer MOSI MISO
// MM3 Period, + AXIS code
switch(MM3.
AXIS)
{
case MM3_X_AXIS
:
SPDR
= MM3_PERIOD_256
+ MM3_X_AXIS
;
break;
case MM3_Y_AXIS
:
SPDR
= MM3_PERIOD_256
+ MM3_Y_AXIS
;
break;
case MM3_Z_AXIS
:
SPDR
= MM3_PERIOD_256
+ MM3_Z_AXIS
;
break;
default:
MM3.
AXIS = MM3_X_AXIS
;
MM3.
STATE = MM3_STATE_RESET
;
return;
}
// DRDY line is not connected, therefore
// wait before reading data back
MM3.
DRDY = SetDelay
(8); // wait 8ms for data ready
MM3.
STATE = MM3_STATE_WAIT_DRDY
;
return;
case MM3_STATE_WAIT_DRDY
:
if (CheckDelay
(MM3.
DRDY))
{
// write something into SPDR to trigger data reading
SPDR
= 0x00;
MM3.
STATE = MM3_STATE_DRDY
;
}
return;
}
}
/*********************************************/
/* Interrupt SPI transfer complete */
/*********************************************/
ISR
(SPI_STC_vect
)
{
static int8_t tmp
;
int16_t value
;
switch (MM3.
STATE)
{
// 1st byte received
case MM3_STATE_DRDY
:
tmp
= SPDR
; // store 1st byte
SPDR
= 0x00; // trigger transfer of 2nd byte
MM3.
STATE = MM3_STATE_BYTE2
;
return;
case MM3_STATE_BYTE2
: // 2nd byte received
value
= (int16_t)tmp
; // combine the 1st and 2nd byte to a word
value
<<= 8; // shift 1st byte to MSB-Position
value
|= (int16_t)SPDR
; // add 2nd byte
if(abs(value
) < MAX_AXIS_VALUE
) // ignore spikes
{
switch (MM3.
AXIS)
{
case MM3_X_AXIS
:
MM3.
x_axis = value
;
MM3.
AXIS = MM3_Y_AXIS
;
break;
case MM3_Y_AXIS
:
MM3.
y_axis = value
;
MM3.
AXIS = MM3_Z_AXIS
;
break;
case MM3_Z_AXIS
:
MM3.
z_axis = value
;
MM3.
AXIS = MM3_X_AXIS
;
break;
default:
MM3.
AXIS = MM3_X_AXIS
;
break;
}
}
MM3_SS_OFF
// deselect slave
MM3.
STATE = MM3_STATE_RESET
;
// Update timeout is called every 102.4 µs.
// It takes 2 cycles to write a measurement data request for one axis and
// at at least 8 ms / 102.4 µs = 79 cycles to read the requested data back.
// I.e. 81 cycles * 102.4 µs = 8.3ms per axis.
// The two function accessing the MM3 Data - MM3_Calibrate() and MM3_Heading() -
// decremtent the MM3_Timeout every 100 ms.
// incrementing the counter by 1 every 8.3 ms is sufficient to avoid a timeout.
if ((MM3.
x_axis != MM3.
y_axis) || (MM3.
x_axis != MM3.
z_axis) || (MM3.
y_axis != MM3.
z_axis))
{ // if all axis measurements give diffrent readings the data should be valid
if(MM3_Timeout
< 20) MM3_Timeout
++;
}
else // something is very strange here
{
if(MM3_Timeout
) MM3_Timeout
--;
}
return;
default:
return;
}
}
/*********************************************/
/* Calibrate Compass */
/*********************************************/
void MM3_Calibrate
(void)
{
static int16_t x_min
, x_max
, y_min
, y_max
, z_min
, z_max
;
switch(CompassCalState
)
{
case 1: // change to x-y axis
x_min
= 10000;
x_max
= -10000;
y_min
= 10000;
y_max
= -10000;
z_min
= 10000;
z_max
= -10000;
break;
case 2:
// find Min and Max of the X- and Y-Axis
if(MM3.
x_axis < x_min
) x_min
= MM3.
x_axis;
if(MM3.
x_axis > x_max
) x_max
= MM3.
x_axis;
if(MM3.
y_axis < y_min
) y_min
= MM3.
y_axis;
if(MM3.
y_axis > y_max
) y_max
= MM3.
y_axis;
break;
case 3:
// change to z-Axis
break;
case 4:
RED_ON
; // find Min and Max of the Z-axis
if(MM3.
z_axis < z_min
) z_min
= MM3.
z_axis;
if(MM3.
z_axis > z_max
) z_max
= MM3.
z_axis;
break;
case 5:
// calc range of all axis
MM3_calib.
X_range = (x_max
- x_min
);
MM3_calib.
Y_range = (y_max
- y_min
);
MM3_calib.
Z_range = (z_max
- z_min
);
// calc offset of all axis
MM3_calib.
X_off = (x_max
+ x_min
) / 2;
MM3_calib.
Y_off = (y_max
+ y_min
) / 2;
MM3_calib.
Z_off = (z_max
+ z_min
) / 2;
// save to EEProm
SetParamByte
(PID_MM3_X_OFF
, (uint8_t)MM3_calib.
X_off);
SetParamByte
(PID_MM3_Y_OFF
, (uint8_t)MM3_calib.
Y_off);
SetParamByte
(PID_MM3_Z_OFF
, (uint8_t)MM3_calib.
Z_off);
SetParamWord
(PID_MM3_X_RANGE
, (uint16_t)MM3_calib.
X_range);
SetParamWord
(PID_MM3_Y_RANGE
, (uint16_t)MM3_calib.
Y_range);
SetParamWord
(PID_MM3_Z_RANGE
, (uint16_t)MM3_calib.
Z_range);
CompassCalState
= 0;
break;
default:
CompassCalState
= 0;
break;
}
}
/*
void MM3_Calibrate(void)
{
static uint8_t debugcounter = 0;
int16_t x_min = 0, x_max = 0, y_min = 0, y_max = 0, z_min = 0, z_max = 0;
uint8_t measurement = 50, beeper = 0;
uint16_t timer;
GRN_ON;
RED_OFF;
// get maximum and minimum reading of all axis
while (measurement)
{
// reset range markers if yawstick ist leftmost
if(PPM_in[ParamSet.ChannelAssignment[CH_YAW]] > 100)
{
x_min = 0;
x_max = 0;
y_min = 0;
y_max = 0;
z_min = 0;
z_max = 0;
}
if (MM3.x_axis > x_max) x_max = MM3.x_axis;
else if (MM3.x_axis < x_min) x_min = MM3.x_axis;
if (MM3.y_axis > y_max) y_max = MM3.y_axis;
else if (MM3.y_axis < y_min) y_min = MM3.y_axis;
if (MM3.z_axis > z_max) z_max = MM3.z_axis;
else if (MM3.z_axis < z_min) z_min = MM3.z_axis;
if (!beeper)
{
RED_FLASH;
GRN_FLASH;
BeepTime = 50;
beeper = 50;
}
beeper--;
// loop with period of 10 ms / 100 Hz
timer = SetDelay(10);
while(!CheckDelay(timer));
if(debugcounter++ > 30)
{
printf("\n\rXMin:%4d, XMax:%4d, YMin:%4d, YMax:%4d, ZMin:%4d, ZMax:%4d",x_min,x_max,y_min,y_max,z_min,z_max);
debugcounter = 0;
}
// If gas is less than 100, stop calibration with a delay of 0.5 seconds
if (PPM_in[ParamSet.ChannelAssignment[CH_GAS]] < 100) measurement--;
}
// Rage of all axis
MM3_calib.X_range = (x_max - x_min);
MM3_calib.Y_range = (y_max - y_min);
MM3_calib.Z_range = (z_max - z_min);
// Offset of all axis
MM3_calib.X_off = (x_max + x_min) / 2;
MM3_calib.Y_off = (y_max + y_min) / 2;
MM3_calib.Z_off = (z_max + z_min) / 2;
// save to EEProm
SetParamByte(PID_MM3_X_OFF, (uint8_t)MM3_calib.X_off);
SetParamByte(PID_MM3_Y_OFF, (uint8_t)MM3_calib.Y_off);
SetParamByte(PID_MM3_Z_OFF, (uint8_t)MM3_calib.Z_off);
SetParamWord(PID_MM3_X_RANGE, (uint16_t)MM3_calib.X_range);
SetParamWord(PID_MM3_Y_RANGE, (uint16_t)MM3_calib.Y_range);
SetParamWord(PID_MM3_Z_RANGE, (uint16_t)MM3_calib.Z_range);
}
*/
/*********************************************/
/* Calculate north direction (heading) */
/*********************************************/
void MM3_Heading
(void)
{
int32_t sin_nick
, cos_nick
, sin_roll
, cos_roll
, sin_yaw
, cos_yaw
;
int32_t Hx
, Hy
, Hz
, Hx_corr
, Hy_corr
;
int16_t angle
;
int16_t heading
;
if (MM3_Timeout
)
{
// Offset correction and normalization (values of H are +/- 512)
Hx
= (((int32_t)(MM3.
x_axis - MM3_calib.
X_off)) * 1024) / (int32_t)MM3_calib.
X_range;
Hy
= (((int32_t)(MM3.
y_axis - MM3_calib.
Y_off)) * 1024) / (int32_t)MM3_calib.
Y_range;
Hz
= (((int32_t)(MM3.
z_axis - MM3_calib.
Z_off)) * 1024) / (int32_t)MM3_calib.
Z_range;
// Compensate the angle of the MM3-arrow to the head of the MK by a yaw rotation transformation
// assuming the MM3 board is mounted parallel to the frame.
// User Param 4 is used to define the positive angle from the MM3-arrow to the MK heading
// in a top view counter clockwise direction.
// North is in opposite direction of the small arrow on the MM3 board.
// Therefore 180 deg must be added to that angle.
angle
= ((int16_t)ParamSet.
UserParam4 + 180);
// wrap angle to interval of 0°- 359°
angle
+= 360;
angle
%= 360;
sin_yaw
= (int32_t)(c_sin_8192
(angle
));
cos_yaw
= (int32_t)(c_cos_8192
(angle
));
Hx_corr
= Hx
;
Hy_corr
= Hy
;
// rotate
Hx
= (Hx_corr
* cos_yaw
- Hy_corr
* sin_yaw
) / 8192;
Hy
= (Hx_corr
* sin_yaw
+ Hy_corr
* cos_yaw
) / 8192;
// tilt compensation
// calculate sinus cosinus of nick and tilt angle
angle
= (int16_t)(IntegralGyroNick
/GYRO_DEG_FACTOR
);
sin_nick
= (int32_t)(c_sin_8192
(angle
));
cos_nick
= (int32_t)(c_cos_8192
(angle
));
angle
= (int16_t)(IntegralGyroRoll
/GYRO_DEG_FACTOR
);
sin_roll
= (int32_t)(c_sin_8192
(angle
));
cos_roll
= (int32_t)(c_cos_8192
(angle
));
Hx_corr
= Hx
* cos_nick
;
Hx_corr
-= Hz
* sin_nick
;
Hx_corr
/= 8192;
Hy_corr
= Hy
* cos_roll
;
Hy_corr
+= Hz
* sin_roll
;
Hy_corr
/= 8192;
// calculate Heading
heading
= c_atan2
(Hy_corr
, Hx_corr
);
// atan returns angular range from -180 deg to 180 deg in counter clockwise notation
// but the compass course is defined in a range from 0 deg to 360 deg clockwise notation.
if (heading
< 0) heading
= -heading
;
else heading
= 360 - heading
;
}
else // MM3_Timeout = 0 i.e now new data from external board
{
if(!BeepTime
) BeepTime
= 100; // make noise to signal the compass problem
heading
= -1;
}
// update compass values in fc variables
CompassHeading
= heading
;
if (CompassHeading
< 0) CompassOffCourse
= 0;
else CompassOffCourse
= ((540 + CompassHeading
- CompassCourse
) % 360) - 180;
}