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#include <stdlib.h>
#include <avr/io.h>
#include "eeprom.h"
#include "flight.h"
#include "output.h"
// Necessary for external control and motor test
#include "uart0.h"
// for scope debugging
// #include "rc.h"
#include "timer2.h"
#include "attitude.h"
#include "controlMixer.h"
#include "commands.h"
#ifdef USE_MK3MAG
#include "gps.h"
#endif
#define CHECK_MIN_MAX(value, min, max) {if(value < min) value = min; else if(value > max) value = max;}
/*
* These are no longer maintained, just left at 0. The original implementation just summed the acc.
* value to them every 2 ms. No filtering or anything. Just a case for an eventual overflow?? Hey???
*/
// int16_t naviAccPitch = 0, naviAccRoll = 0, naviCntAcc = 0;
int8_t pitchPFactor, rollPFactor, yawPFactor;
int8_t pitchDFactor, rollDFactor, yawDFactor;
int32_t IPart[2] = {0,0};
/************************************************************************/
/* Filter for motor value smoothing (necessary???) */
/************************************************************************/
int16_t outputFilter(int16_t newvalue, int16_t oldvalue) {
switch (dynamicParams.UserParams[5]) {
case 0:
return newvalue;
case 1:
return (oldvalue + newvalue) / 2;
case 2:
if (newvalue > oldvalue)
return (1 * (int16_t) oldvalue + newvalue) / 2; //mean of old and new
else
return newvalue - (oldvalue - newvalue) * 1; // 2 * new - old
case 3:
if (newvalue < oldvalue)
return (1 * (int16_t) oldvalue + newvalue) / 2; //mean of old and new
else
return newvalue - (oldvalue - newvalue) * 1; // 2 * new - old
default:
return newvalue;
}
}
/************************************************************************/
/* Neutral Readings */
/************************************************************************/
#define CONTROL_CONFIG_SCALE 10
void flight_setNeutral() {
MKFlags |= MKFLAG_CALIBRATE;
// not really used here any more.
controlMixer_initVariables();
}
void setFlightParameters
(
uint8_t _pitchPFactor,
uint8_t _rollPFactor,
uint8_t _yawPFactor,
uint8_t _pitchDFactor,
uint8_t _rollDFactor,
uint8_t _yawDFactor
) {
pitchPFactor = _pitchPFactor;
rollPFactor = _rollPFactor;
yawPFactor = _yawPFactor;
pitchDFactor = _pitchDFactor;
rollDFactor = _rollDFactor;
yawDFactor = _yawDFactor;
}
void setNormalFlightParameters(void) {
setFlightParameters
(
dynamicParams.GyroPitchP / CONTROL_CONFIG_SCALE, // 12 seems good
dynamicParams.GyroRollP / CONTROL_CONFIG_SCALE, // 9 seems good
dynamicParams.GyroYawP / (CONTROL_CONFIG_SCALE/2), // 24 seems too little
dynamicParams.GyroPitchD / CONTROL_CONFIG_SCALE,
dynamicParams.GyroRollD / CONTROL_CONFIG_SCALE,
dynamicParams.GyroYawD / CONTROL_CONFIG_SCALE
);
}
void setStableFlightParameters(void) {
setFlightParameters(0, 0, 0, 0, 0, 0);
}
/************************************************************************/
/* Main Flight Control */
/************************************************************************/
void flight_control(void) {
// Mixer Fractions that are combined for Motor Control
int16_t yawTerm, throttleTerm, term[2];
// PID controller variables
int16_t PDPart[2], PDPartYaw;
static int8_t debugDataTimer = 1;
// High resolution motor values for smoothing of PID motor outputs
static int16_t outputFilters[MAX_OUTPUTS];
uint8_t i;
// Fire the main flight attitude calculation, including integration of angles.
// We want that to kick as early as possible, not to delay new AD sampling further.
calculateFlightAttitude();
controlMixer_update();
throttleTerm = control[CONTROL_THROTTLE];
/************************************************************************/
/* RC-signal is bad */
/************************************************************************/
if (controlMixer_getSignalQuality() <= SIGNAL_BAD) { // the rc-frame signal is not received or noisy
RED_ON;
beepRCAlarm();
setStableFlightParameters();
} else {
commands_handleCommands();
setNormalFlightParameters();
}
/************************************************************************/
/* Calculate control feedback from angle (gyro integral) */
/* and angular velocity (gyro signal) */
/************************************************************************/
PDPart[PITCH] = ((int32_t) rate_PID[PITCH] * pitchPFactor /
(256L / CONTROL_SCALING))
+ (differential[PITCH] * (int16_t) dynamicParams.GyroPitchD) / 16;
PDPart[ROLL] = ((int32_t) rate_PID[ROLL] * rollPFactor /
(256L / CONTROL_SCALING))
+ (differential[ROLL] * (int16_t) dynamicParams.GyroRollD) / 16;
PDPartYaw = (int32_t) (yawRate * 2 * (int32_t) yawPFactor) / (256L / CONTROL_SCALING)
+ (differential[YAW] * (int16_t) dynamicParams.GyroYawD) / 16;
IPart[PITCH] = controlIntegrals[CONTROL_ELEVATOR] - angle[PITCH];
if (IPart[PITCH] > PITCHROLLOVER180) IPart[PITCH] -= PITCHROLLOVER360;
else if (IPart[PITCH] <= -PITCHROLLOVER180) IPart[PITCH] += PITCHROLLOVER360;
if (IPart[PITCH] > HH_RANGE) IPart[PITCH] = HH_RANGE;
else if (IPart[PITCH] < -HH_RANGE) IPart[PITCH] = -HH_RANGE;
IPart[ROLL] = controlIntegrals[CONTROL_AILERONS] - angle[ROLL];
if (IPart[ROLL] > PITCHROLLOVER180) IPart[ROLL] -= PITCHROLLOVER360;
else if (IPart[ROLL] <= -PITCHROLLOVER180) IPart[ROLL] += PITCHROLLOVER360;
if (IPart[ROLL] > HH_RANGE) IPart[ROLL] = HH_RANGE;
else if (IPart[ROLL] < -HH_RANGE) IPart[ROLL] = -HH_RANGE;
term[PITCH] = control[CONTROL_ELEVATOR] + (staticParams.ControlSigns & 1 ? PDPart[PITCH] : -PDPart[PITCH]);
term[ROLL] = control[CONTROL_AILERONS] + (staticParams.ControlSigns & 2 ? PDPart[ROLL] : -PDPart[ROLL]);
yawTerm = control[CONTROL_RUDDER] + (staticParams.ControlSigns & 4 ? PDPartYaw : -PDPartYaw);
// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// Universal Mixer
// Each (pitch, roll, throttle, yaw) term is in the range [0..255 * CONTROL_SCALING].
// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
DebugOut.Analog[12] = term[PITCH];
DebugOut.Analog[13] = term[ROLL];
DebugOut.Analog[14] = throttleTerm;
DebugOut.Analog[15] = yawTerm;
for (i = 0; i < MAX_OUTPUTS; i++) {
int16_t tmp;
if (outputTestActive) {
outputs[i].SetPoint = outputTest[i] * 4;
} else {
// Follow the normal order of servos: Ailerons, elevator, throttle, rudder.
switch(i) {
case 0: tmp = term[ROLL]; break;
case 1: tmp = term[PITCH]; break;
case 2: tmp = throttleTerm - 310; break;
case 3: tmp = yawTerm; break;
default: tmp = 0;
}
outputFilters[i] = outputFilter(tmp, outputFilters[i]);
// Now we scale back down to a 0..255 range.
tmp = outputFilters[i];
outputs[i].SetPoint = tmp;
}
}
// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
// Debugging
// +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
if (!(--debugDataTimer)) {
debugDataTimer = 24; // update debug outputs at 488 / 24 = 20.3 Hz.
DebugOut.Analog[0] = (10 * angle[PITCH]) / GYRO_DEG_FACTOR_PITCHROLL; // in 0.1 deg
DebugOut.Analog[1] = (10 * angle[ROLL]) / GYRO_DEG_FACTOR_PITCHROLL; // in 0.1 deg
DebugOut.Analog[2] = yawGyroHeading / GYRO_DEG_FACTOR_YAW;
DebugOut.Analog[6] = pitchPFactor;
DebugOut.Analog[7] = rollPFactor;
DebugOut.Analog[8] = yawPFactor;
DebugOut.Analog[9] = pitchDFactor;
DebugOut.Analog[10] = rollDFactor;
DebugOut.Analog[11] = yawDFactor;
DebugOut.Analog[18] = (10 * controlIntegrals[CONTROL_ELEVATOR]) / GYRO_DEG_FACTOR_PITCHROLL; // in 0.1 deg
DebugOut.Analog[19] = (10 * controlIntegrals[CONTROL_AILERONS]) / GYRO_DEG_FACTOR_PITCHROLL; // in 0.1 deg
DebugOut.Analog[22] = (10 * IPart[PITCH]) / GYRO_DEG_FACTOR_PITCHROLL; // in 0.1 deg
DebugOut.Analog[23] = (10 * IPart[ROLL]) / GYRO_DEG_FACTOR_PITCHROLL; // in 0.1 deg
}
}