ardupilot/ArduCopter/Attitude.pde

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/// -*- tab-width: 4; Mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*-
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static int
get_stabilize_roll(int32_t target_angle)
{
int32_t error = 0;
int32_t rate = 0;
static float current_rate = 0;
current_rate = (current_rate *.7) + (omega.x * DEGX100) * .3;
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// angle error
error = wrap_180(target_angle - dcm.roll_sensor);
#if FRAME_CONFIG == HELI_FRAME
// limit the error we're feeding to the PID
error = constrain(error, -4500, 4500);
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// convert to desired Rate:
rate = g.pi_stabilize_roll.get_pi(error, G_Dt);
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// output control:
rate = constrain(rate, -4500, 4500);
return (int)rate;
#else
// limit the error we're feeding to the PID
error = constrain(error, -2500, 2500);
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// conver to desired Rate:
rate = g.pi_stabilize_roll.get_p(error);
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// experiment to pipe iterm directly into the output
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int16_t iterm = g.pi_stabilize_roll.get_i(error, G_Dt);
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// rate control
error = rate - (omega.x * DEGX100);
rate = g.pi_rate_roll.get_pi(error, G_Dt);
// D term
int16_t d_temp = current_rate * g.stablize_d;
rate -= d_temp;
// output control:
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rate = constrain(rate, -2500, 2500);
return (int)rate + iterm;
#endif
}
static int
get_stabilize_pitch(int32_t target_angle)
{
int32_t error = 0;
int32_t rate = 0;
static float current_rate = 0;
//current_rate = (omega.y * DEGX100);
current_rate = (current_rate *.7) + (omega.y * DEGX100) * .3;
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// angle error
error = wrap_180(target_angle - dcm.pitch_sensor);
#if FRAME_CONFIG == HELI_FRAME
// limit the error we're feeding to the PID
error = constrain(error, -4500, 4500);
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// convert to desired Rate:
rate = g.pi_stabilize_pitch.get_pi(error, G_Dt);
// output control:
rate = constrain(rate, -4500, 4500);
return (int)rate;
#else
// angle error
error = constrain(error, -2500, 2500);
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// conver to desired Rate:
rate = g.pi_stabilize_pitch.get_p(error);
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// experiment to pipe iterm directly into the output
int16_t iterm = g.pi_stabilize_pitch.get_i(error, G_Dt);
// rate control
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error = rate - (omega.y * DEGX100);
//error = rate - (omega.y * DEGX100);
rate = g.pi_rate_pitch.get_pi(error, G_Dt);
// D term
int16_t d_temp = current_rate * g.stablize_d;
rate -= d_temp;
// output control:
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rate = constrain(rate, -2500, 2500);
return (int)rate + iterm;
#endif
}
#define YAW_ERROR_MAX 2000
static int
get_stabilize_yaw(int32_t target_angle)
{
int32_t error;
int32_t rate;
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// angle error
error = wrap_180(target_angle - dcm.yaw_sensor);
// limit the error we're feeding to the PID
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error = constrain(error, -YAW_ERROR_MAX, YAW_ERROR_MAX);
// convert to desired Rate:
rate = g.pi_stabilize_yaw.get_p(error);
// experiment to pipe iterm directly into the output
int16_t iterm = g.pi_stabilize_yaw.get_i(error, G_Dt);
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#if FRAME_CONFIG == HELI_FRAME // cannot use rate control for helicopters
if( !g.heli_ext_gyro_enabled ) {
error = rate - (omega.z * DEGX100);
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rate = g.pi_rate_yaw.get_pi(error, G_Dt);
}
// output control:
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rate = constrain(rate, -4500, 4500);
#else
error = rate - (omega.z * DEGX100);
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rate = g.pi_rate_yaw.get_pi(error, G_Dt);
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// output control:
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int16_t yaw_input = 1400 + abs(g.rc_4.control_in);
// smoother Yaw control:
rate = constrain(rate, -yaw_input, yaw_input);
#endif
return (int)rate + iterm;
}
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#define ALT_ERROR_MAX 400
static int16_t
get_nav_throttle(int32_t z_error)
{
static int16_t old_output = 0;
//static int16_t rate_d = 0;
int16_t rate_error;
int16_t output;
// limit error to prevent I term run up
z_error = constrain(z_error, -ALT_ERROR_MAX, ALT_ERROR_MAX);
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// convert to desired Rate:
rate_error = g.pi_alt_hold.get_p(z_error); //_p = .85
// compensates throttle setpoint error for hovering
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int16_t iterm = g.pi_alt_hold.get_i(z_error, .1);
// calculate rate error
rate_error = rate_error - climb_rate;
// limit the rate - iterm is not used
output = constrain((int)g.pi_throttle.get_p(rate_error), -160, 180);
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// a positive climb rate means we're going up
//rate_d = ((rate_d + climb_rate)>>1) * .1; // replace with gain
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// slight adjustment to alt hold output
//output -= constrain(rate_d, -25, 25);
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// light filter of output
output = (old_output * 3 + output) / 4;
// save our output
old_output = output;
// output control:
return output + iterm;
}
static int
get_rate_roll(int32_t target_rate)
{
int32_t error = (target_rate * 3.5) - (omega.x * DEGX100);
error = constrain(error, -20000, 20000);
return g.pi_acro_roll.get_pi(error, G_Dt);
}
static int
get_rate_pitch(int32_t target_rate)
{
int32_t error = (target_rate * 3.5) - (omega.y * DEGX100);
error = constrain(error, -20000, 20000);
return g.pi_acro_pitch.get_pi(error, G_Dt);
}
static int
get_rate_yaw(int32_t target_rate)
{
int32_t error = (target_rate * 4.5) - (omega.z * DEGX100);
target_rate = g.pi_rate_yaw.get_pi(error, G_Dt);
// output control:
return (int)constrain(target_rate, -2500, 2500);
}
// Keeps old data out of our calculation / logs
static void reset_nav_params(void)
{
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// forces us to update nav throttle
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invalid_throttle = true;
nav_throttle = 0;
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// always start Circle mode at same angle
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circle_angle = 0;
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// We must be heading to a new WP, so XTrack must be 0
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crosstrack_error = 0;
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// Will be set by new command
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target_bearing = 0;
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// Will be set by new command
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wp_distance = 0;
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// Will be set by new command, used by loiter
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long_error = 0;
lat_error = 0;
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// Will be set by new command, used by loiter
next_WP.alt = 0;
}
/*
reset all I integrators
*/
static void reset_I_all(void)
{
reset_rate_I();
reset_stability_I();
reset_nav_I();
reset_wind_I();
reset_throttle_I();
reset_optflow_I();
// This is the only place we reset Yaw
g.pi_stabilize_yaw.reset_I();
}
static void reset_rate_I()
{
g.pi_rate_roll.reset_I();
g.pi_rate_pitch.reset_I();
g.pi_acro_roll.reset_I();
g.pi_acro_pitch.reset_I();
g.pi_rate_yaw.reset_I();
}
static void reset_optflow_I(void)
{
g.pi_optflow_roll.reset_I();
g.pi_optflow_pitch.reset_I();
}
static void reset_wind_I(void)
{
// Wind Compensation
g.pi_loiter_lat.reset_I();
g.pi_loiter_lon.reset_I();
}
static void reset_nav_I(void)
{
// Rate control for WP navigation
g.pi_nav_lat.reset_I();
g.pi_nav_lon.reset_I();
}
static void reset_throttle_I(void)
{
// For Altitude Hold
g.pi_alt_hold.reset_I();
g.pi_throttle.reset_I();
}
static void reset_stability_I(void)
{
// Used to balance a quad
// This only needs to be reset during Auto-leveling in flight
g.pi_stabilize_roll.reset_I();
g.pi_stabilize_pitch.reset_I();
}
/*************************************************************
throttle control
****************************************************************/
static long
get_nav_yaw_offset(int yaw_input, int reset)
{
int32_t _yaw;
if(reset == 0){
// we are on the ground
return dcm.yaw_sensor;
}else{
// re-define nav_yaw if we have stick input
if(yaw_input != 0){
// set nav_yaw + or - the current location
_yaw = yaw_input + dcm.yaw_sensor;
// we need to wrap our value so we can be 0 to 360 (*100)
return wrap_360(_yaw);
}else{
// no stick input, lets not change nav_yaw
return nav_yaw;
}
}
}
static int get_angle_boost(int value)
{
float temp = cos_pitch_x * cos_roll_x;
temp = 1.0 - constrain(temp, .5, 1.0);
return (int)(temp * value);
}
#define NUM_G_SAMPLES 40
#if ACCEL_ALT_HOLD == 2
// z -14.4306 = going up
// z -6.4306 = going down
static int get_z_damping()
{
int output;
Z_integrator += get_world_Z_accel() - Z_offset;
output = Z_integrator * 3;
Z_integrator = Z_integrator * .8;
output = constrain(output, -100, 100);
return output;
}
float get_world_Z_accel()
{
accels_rot = dcm.get_dcm_matrix() * imu.get_accel();
//Serial.printf("z %1.4f\n", accels_rot.z);
return accels_rot.z;
}
static void init_z_damper()
{
Z_offset = 0;
for (int i = 0; i < NUM_G_SAMPLES; i++){
delay(5);
read_AHRS();
Z_offset += get_world_Z_accel();
}
Z_offset /= (float)NUM_G_SAMPLES;
}
// Accelerometer Z dampening by Aurelio R. Ramos
// ---------------------------------------------
#elif ACCEL_ALT_HOLD == 1
// contains G and any other DC offset
static float estimatedAccelOffset = 0;
// state
static float synVelo = 0;
static float synPos = 0;
static float synPosFiltered = 0;
static float posError = 0;
static float prevSensedPos = 0;
// tuning for dead reckoning
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static const float dt_50hz = 0.02;
static float synPosP = 10 * dt_50hz;
static float synPosI = 15 * dt_50hz;
static float synVeloP = 1.5 * dt_50hz;
static float maxVeloCorrection = 5 * dt_50hz;
static float maxSensedVelo = 1;
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static float synPosFilter = 0.5;
// Z damping term.
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static float fullDampP = 0.100;
float get_world_Z_accel()
{
accels_rot = dcm.get_dcm_matrix() * imu.get_accel();
return accels_rot.z;
}
static void init_z_damper()
{
estimatedAccelOffset = 0;
for (int i = 0; i < NUM_G_SAMPLES; i++){
delay(5);
read_AHRS();
estimatedAccelOffset += get_world_Z_accel();
}
estimatedAccelOffset /= (float)NUM_G_SAMPLES;
}
float dead_reckon_Z(float sensedPos, float sensedAccel)
{
// the following algorithm synthesizes position and velocity from
// a noisy altitude and accelerometer data.
// synthesize uncorrected velocity by integrating acceleration
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synVelo += (sensedAccel - estimatedAccelOffset) * dt_50hz;
// synthesize uncorrected position by integrating uncorrected velocity
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synPos += synVelo * dt_50hz;
// filter synPos, the better this filter matches the filtering and dead time
// of the sensed position, the less the position estimate will lag.
synPosFiltered = synPosFiltered * (1 - synPosFilter) + synPos * synPosFilter;
// calculate error against sensor position
posError = sensedPos - synPosFiltered;
// correct altitude
synPos += synPosP * posError;
// correct integrated velocity by posError
synVelo = synVelo + constrain(posError, -maxVeloCorrection, maxVeloCorrection) * synPosI;
// correct integrated velocity by the sensed position delta in a small proportion
// (i.e., the low frequency of the delta)
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float sensedVelo = (sensedPos - prevSensedPos) / dt_50hz;
synVelo += constrain(sensedVelo - synVelo, -maxSensedVelo, maxSensedVelo) * synVeloP;
prevSensedPos = sensedPos;
return synVelo;
}
static int get_z_damping()
{
float sensedAccel = get_world_Z_accel();
float sensedPos = current_loc.alt / 100.0;
float synVelo = dead_reckon_Z(sensedPos, sensedAccel);
return constrain(fullDampP * synVelo * (-1), -300, 300);
}
#else
static int get_z_damping()
{
return 0;
}
static void init_z_damper()
{
}
#endif
// calculate modified roll/pitch depending upon optical flow values
static int32_t
get_of_roll(int32_t control_roll)
{
#ifdef OPTFLOW_ENABLED
//static int32_t of_roll = 0; // we use global variable to make logging easier
static unsigned long last_of_roll_update = 0;
static float prev_value = 0;
float x_cm;
// check if new optflow data available
if( optflow.last_update != last_of_roll_update) {
last_of_roll_update = optflow.last_update;
// filter movement
x_cm = (optflow.x_cm + prev_value) / 2.0 * 50.0;
// only stop roll if caller isn't modifying roll
if( control_roll == 0 && current_loc.alt < 1500) {
of_roll = g.pi_optflow_roll.get_pi(-x_cm, 1.0); // we could use the last update time to calculate the time change
}else{
g.pi_optflow_roll.reset_I();
prev_value = 0;
}
}
// limit maximum angle
of_roll = constrain(of_roll, -1000, 1000);
return control_roll+of_roll;
#else
return control_roll;
#endif
}
static int32_t
get_of_pitch(int32_t control_pitch)
{
#ifdef OPTFLOW_ENABLED
//static int32_t of_pitch = 0; // we use global variable to make logging easier
static unsigned long last_of_pitch_update = 0;
static float prev_value = 0;
float y_cm;
// check if new optflow data available
if( optflow.last_update != last_of_pitch_update ) {
last_of_pitch_update = optflow.last_update;
// filter movement
y_cm = (optflow.y_cm + prev_value) / 2.0 * 50.0;
// only stop roll if caller isn't modifying roll
if( control_pitch == 0 && current_loc.alt < 1500 ) {
of_pitch = g.pi_optflow_pitch.get_pi(y_cm, 1.0); // we could use the last update time to calculate the time change
}else{
g.pi_optflow_pitch.reset_I();
prev_value = 0;
}
}
// limit maximum angle
of_pitch = constrain(of_pitch, -1000, 1000);
return control_pitch+of_pitch;
#else
return control_pitch;
#endif
}