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/*********************************************************************************/
/* Attitude sense system (processing of gyro, accelerometer and altimeter data)  */
/*********************************************************************************/

#ifndef _ATTITUDE_H
#define _ATTITUDE_H

#include <inttypes.h>

#include "analog.h"
#include "timer0.h"

/*
 * If you have no acc. sensor or do not want to use it, remove this define. This will cause the
 * acc. sensor to be ignored at attitude calibration.
 */

#define ATTITUDE_USE_ACC_SENSORS yes

/*
 * Default hysteresis to use for the -180 degree to 180 degree wrap.
 */

#define PITCHOVER_HYSTERESIS 0L
#define ROLLOVER_HYSTERESIS 0L

/*
 * The frequency at which numerical integration takes place. 488 in original code.
 */

#define INTEGRATION_FREQUENCY F_MAINLOOP

/*
 * Gyro readings are divided by this before being used in attitude control. This will scale them
 * to match the scale of the stick control etc. variables. This is just a rough non-precision
 * scaling - the below definitions make precise conversion factors.
 */

#define HIRES_GYRO_INTEGRATION_FACTOR 1
// (int)((GYRO_RATE_FACTOR_PITCHROLL * INTEGRATION_FREQUENCY * GYRO_PITCHROLL_CORRECTION) / 1250)

/*
 Gyro integration:

 The control loop executes at INTEGRATION_FREQUENCY Hz, and for each iteration
 gyro_ATT[PITCH/ROLL] is added to gyroIntegral[PITCH/ROLL].
 Assuming a constant rotation rate v and a zero initial gyroIntegral
 (for this explanation), we get:

 gyroIntegral =
 t * INTEGRATION_FREQUENCY * v * GYRO_RATE_FACTOR_PITCHROLL / HIRES_GYRO_INTEGRATION_FACTOR

 For one degree of rotation: t*v = 1:

 gyroIntegral = INTEGRATION_FREQUENCY * v * GYRO_RATE_FACTOR_PITCHROLL / HIRES_GYRO_INTEGRATION_FACTOR

 This number (INTEGRATION_FREQUENCY * v * GYRO_RATE_FACTOR_PITCHROLL / HIRES_GYRO_INTEGRATION_FACTOR) is the integral-to-degree factor.

 Examples:
 FC1.3:                 GYRO_DEG_FACTOR_PITCHROLL = 2545
 FC2.0:                 GYRO_DEG_FACTOR_PITCHROLL = 2399
 My InvenSense copter:  GYRO_DEG_FACTOR_PITCHROLL = 1333
 */

//#define GYRO_PITCHROLL_CORRECTION GYRO_PITCHROLL_CORRECTION_should_be_overridden_with_a_-D_at_compile_time
#define GYRO_DEG_FACTOR_PITCHROLL (uint16_t)(GYRO_RATE_FACTOR_PITCHROLL * INTEGRATION_FREQUENCY * GYRO_PITCHROLL_CORRECTION / HIRES_GYRO_INTEGRATION_FACTOR)
#define GYRO_DEG_FACTOR_YAW (uint16_t)(GYRO_RATE_FACTOR_YAW * INTEGRATION_FREQUENCY * GYRO_YAW_CORRECTION)

/*
 * Constant for deriving an attitude angle from acceleration measurement.
 *
 * The value is derived from the datasheet of the ACC sensor where 5g are scaled to VRef.
 * 1g is (3V * 1024) / (5 * 3V) = 205 counts. The ADC ISR sums 2 acc. samples to each
 * [pitch/roll]AxisAcc and thus reads about acc = 410 counts / g.
 * We approximate a small pitch/roll angle v by assuming that the copter does not accelerate:
 * In this explanation it is assumed that the ADC values are 0 based, and gravity is included.
 * The sine of v is the far side / the hypothenusis:
 * sin v = acc / sqrt(acc^2 + acc_z^2)
 * Using that v is a small angle, and the near side is about equal to the the hypothenusis:
 * sin v ~= acc / acc_z
 * Assuming that the multicopter is hovering at small pitch and roll angles, acc_z is about 410,
 * and sin v ~= v (small angles, in radians):
 * sin v ~= acc / 410
 * v / 57.3 ~= acc / 410
 * v ~= acc * 57.3 / 410
 * acc / v ~= 410 / 57.3 ~= 7, that is: There are about 7 counts per degree.
 *
 * Summary: DEG_ACC_FACTOR = (2 * 1024 * [sensitivity of acc. meter in V/g]) / (3V * 57.3)
 */

#define DEG_ACC_FACTOR 7


/*
 * This is ([gyro integral value] / degree) / (degree / acc. sensor value) = gyro integral value / acc.sensor value
 * = the factor an acc. sensor should be multiplied by to get the gyro integral
 * value for the same (small) angle.
 * The value is about 200.
 */

#define GYRO_ACC_FACTOR ((GYRO_DEG_FACTOR_PITCHROLL) / (DEG_ACC_FACTOR))

#define PITCHROLLOVER180 (GYRO_DEG_FACTOR_PITCHROLL * 180L)
#define PITCHROLLOVER360 (GYRO_DEG_FACTOR_PITCHROLL * 360L)
#define YAWOVER180       (GYRO_DEG_FACTOR_YAW * 180L)
#define YAWOVER360       (GYRO_DEG_FACTOR_YAW * 360L)

/*
 * Rotation rates
 */

extern int16_t rate_PID[2], rate_ATT[2], yawRate;
extern int16_t differential[2];

/*
 * Attitudes calculated by numerical integration of gyro rates
 */

extern int32_t attitude[2];

// This is really a flight module thing, but it should be corrected along
// when the yaw angle is corrected from the compass, and that happens here.
// extern int32_t yawAngleDiff;

/*
 * Compass navigation
 */

extern int32_t heading;
extern uint16_t ignoreCompassTimer;
extern uint16_t accVector;

extern int32_t headingError;


/*
 * Dynamic gyro offsets. These are signed values that are subtracted from the gyro measurements,
 * to help canceling out drift and vibration noise effects. The dynamic offsets themselves
 * can be updated in flight by different ways, for example:
 * - Just taking them from parameters, so the pilot can trim manually in a PC or mobile tool
 * - Summing up how much acc. meter correction was done to the gyro integrals over the last n
 *   integration, and then adding the sum / n to the dynamic offset
 * - Detect which way the pilot pulls the stick to keep the copter steady, and correct by that
 * - Invent your own...
 */

extern int16_t dynamicOffset[2], dynamicOffsetYaw;

/*
 * For NaviCtrl use.
 */

extern int16_t averageAcc[2], averageAccCount;

/*
 * Re-init flight attitude, setting all angles to 0 (or to whatever can be derived from acc. sensor).
 * To be called when the pilot commands gyro calibration (eg. by moving the left stick up-left or up-right).
 */

void attitude_setNeutral(void);

/*
 * Experiment.
 */

// void attitude_startDynamicCalibration(void);
// void attitude_continueDynamicCalibration(void);

int32_t getAngleEstimateFromAcc(uint8_t axis);

/*
 * Main routine, called from the flight loop.
 */

void calculateFlightAttitude(void);

void attitude_resetHeadingToMagnetic(void);

#endif //_ATTITUDE_H