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https://bitbucket.org/librepilot/librepilot.git
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04c42bd316
1. Make autotakeoff height configurable 2. Fix the pidcontroldown transfer to solve the rough transition between pid controllers for landing, takeoff, braking etc.
375 lines
12 KiB
C++
375 lines
12 KiB
C++
/**
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******************************************************************************
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* @addtogroup OpenPilotModules OpenPilot Modules
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* @{
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* @addtogroup PathFollower PID interface class
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* @brief PID loop for down control
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* @{
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*
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* @file pidcontroldown.h
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* @author The OpenPilot Team, http://www.openpilot.org Copyright (C) 2015.
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* @brief Executes PID control for down direction
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*
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* @see The GNU Public License (GPL) Version 3
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*
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*****************************************************************************/
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/*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 3 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful, but
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* WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
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* or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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* for more details.
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*
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* You should have received a copy of the GNU General Public License along
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* with this program; if not, write to the Free Software Foundation, Inc.,
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* 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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*/
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extern "C" {
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#include <openpilot.h>
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#include <callbackinfo.h>
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#include <math.h>
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#include <pid.h>
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#include <CoordinateConversions.h>
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#include <sin_lookup.h>
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#include <pathdesired.h>
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#include <paths.h>
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#include "plans.h"
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#include <stabilizationdesired.h>
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#include <pidstatus.h>
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#include <vtolselftuningstats.h>
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}
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#include "pathfollowerfsm.h"
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#include "pidcontroldown.h"
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#define NEUTRALTHRUST_PH_POSITIONAL_ERROR_LIMIT 0.5f
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#define NEUTRALTHRUST_PH_VEL_DESIRED_LIMIT 0.2f
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#define NEUTRALTHRUST_PH_VEL_STATE_LIMIT 0.2f
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#define NEUTRALTHRUST_PH_VEL_ERROR_LIMIT 0.1f
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#define NEUTRALTHRUST_START_DELAY (2 * 20) // 2 seconds at rate of 20Hz (50ms update rate)
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#define NEUTRALTHRUST_END_COUNT (NEUTRALTHRUST_START_DELAY + (4 * 20)) // 4 second sample
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PIDControlDown::PIDControlDown()
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: deltaTime(0.0f), mVelocitySetpointTarget(0.0f), mVelocitySetpointCurrent(0.0f), mVelocityState(0.0f), mDownCommand(0.0f),
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mFSM(NULL), mNeutral(0.5f), mVelocityMax(1.0f), mPositionSetpointTarget(0.0f), mPositionState(0.0f),
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mMinThrust(0.1f), mMaxThrust(0.6f), mActive(false)
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{
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Deactivate();
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}
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PIDControlDown::~PIDControlDown() {}
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void PIDControlDown::Initialize(PathFollowerFSM *fsm)
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{
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mFSM = fsm;
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}
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void PIDControlDown::SetThrustLimits(float min_thrust, float max_thrust)
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{
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mMinThrust = min_thrust;
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mMaxThrust = max_thrust;
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}
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void PIDControlDown::Deactivate()
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{
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// pid_zero(&PID);
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mActive = false;
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}
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void PIDControlDown::Activate()
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{
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float currentThrust;
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StabilizationDesiredThrustGet(¤tThrust);
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pid2_transfer(&PID, currentThrust);
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mActive = true;
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}
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void PIDControlDown::UpdateParameters(float kp, float ki, float kd, float beta, float dT, float velocityMax)
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{
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// pid_configure(&PID, kp, ki, kd, ilimit);
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float Ti = kp / ki;
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float Td = kd / kp;
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float Tt = (Ti + Td) / 2.0f;
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float kt = 1.0f / Tt;
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float N = 10.0f;
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float Tf = Td / N;
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if (ki < 1e-6f) {
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// Avoid Ti being infinite
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Ti = 1e6f;
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// Tt antiwindup time constant - we don't need antiwindup with no I term
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Tt = 1e6f;
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kt = 0.0f;
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}
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if (kd < 1e-6f) {
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// PI Controller or P Controller
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Tf = Ti / N;
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}
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if (beta > 1.0f) {
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beta = 1.0f;
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} else if (beta < 0.4f) {
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beta = 0.4f;
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}
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pid2_configure(&PID, kp, ki, kd, Tf, kt, dT, beta, mNeutral, mNeutral, -1.0f);
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deltaTime = dT;
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mVelocityMax = velocityMax;
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}
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void PIDControlDown::UpdatePositionalParameters(float kp)
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{
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pid_configure(&PIDpos, kp, 0.0f, 0.0f, 0.0f);
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}
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void PIDControlDown::UpdatePositionSetpoint(float setpointDown)
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{
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mPositionSetpointTarget = setpointDown;
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}
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void PIDControlDown::UpdatePositionState(float pvDown)
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{
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mPositionState = pvDown;
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setup_neutralThrustCalc();
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}
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// This is a pure position hold position control
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void PIDControlDown::ControlPosition()
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{
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// Current progress location relative to end
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float velDown = 0.0f;
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velDown = pid_apply(&PIDpos, mPositionSetpointTarget - mPositionState, deltaTime);
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UpdateVelocitySetpoint(velDown);
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run_neutralThrustCalc();
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}
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void PIDControlDown::ControlPositionWithPath(struct path_status *progress)
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{
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// Current progress location relative to end
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float velDown = progress->path_vector[2];
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velDown += pid_apply(&PIDpos, progress->correction_vector[2], deltaTime);
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UpdateVelocitySetpoint(velDown);
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}
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void PIDControlDown::run_neutralThrustCalc(void)
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{
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// if auto thrust and we have not run a correction calc check for PH and stability to then run an assessment
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// note that arming into this flight mode is not allowed, so assumption here is that
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// we have not landed. If GPSAssist+Manual/Cruise control thrust mode is used, a user overriding the
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// altitude maintaining PID will have moved the throttle state to FLIGHTSTATUS_ASSISTEDTHROTTLESTATE_MANUAL.
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// In manualcontrol.c the state will stay in manual throttle until the throttle command exceeds the vtol thrust min,
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// avoiding auto-takeoffs. Therefore no need to check that here.
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if (neutralThrustEst.have_correction != true) {
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// Make FSM specific
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bool stable = (fabsf(mPositionSetpointTarget - mPositionState) < NEUTRALTHRUST_PH_POSITIONAL_ERROR_LIMIT &&
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fabsf(mVelocitySetpointCurrent) < NEUTRALTHRUST_PH_VEL_DESIRED_LIMIT &&
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fabsf(mVelocityState) < NEUTRALTHRUST_PH_VEL_STATE_LIMIT &&
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fabsf(mVelocitySetpointCurrent - mVelocityState) < NEUTRALTHRUST_PH_VEL_ERROR_LIMIT);
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if (stable) {
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if (neutralThrustEst.start_sampling) {
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neutralThrustEst.count++;
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// delay count for 2 seconds into hold allowing for stablisation
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if (neutralThrustEst.count > NEUTRALTHRUST_START_DELAY) {
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neutralThrustEst.sum += PID.I;
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if (PID.I < neutralThrustEst.min) {
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neutralThrustEst.min = PID.I;
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}
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if (PID.I > neutralThrustEst.max) {
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neutralThrustEst.max = PID.I;
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}
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}
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if (neutralThrustEst.count >= NEUTRALTHRUST_END_COUNT) {
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// 6 seconds have past
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// lets take an average
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neutralThrustEst.average = neutralThrustEst.sum / (float)(NEUTRALTHRUST_END_COUNT - NEUTRALTHRUST_START_DELAY);
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neutralThrustEst.correction = neutralThrustEst.average;
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PID.I -= neutralThrustEst.average;
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neutralThrustEst.start_sampling = false;
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neutralThrustEst.have_correction = true;
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// Write a new adjustment value
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// vtolSelfTuningStats.NeutralThrustOffset was incremental adjusted above
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VtolSelfTuningStatsData vtolSelfTuningStats;
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VtolSelfTuningStatsGet(&vtolSelfTuningStats);
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// add the average remaining i value to the
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vtolSelfTuningStats.NeutralThrustOffset += neutralThrustEst.correction;
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vtolSelfTuningStats.NeutralThrustCorrection = neutralThrustEst.correction; // the i term thrust correction value applied
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vtolSelfTuningStats.NeutralThrustAccumulator = PID.I; // the actual iaccumulator value after correction
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vtolSelfTuningStats.NeutralThrustRange = neutralThrustEst.max - neutralThrustEst.min;
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VtolSelfTuningStatsSet(&vtolSelfTuningStats);
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}
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} else {
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// start a tick count
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neutralThrustEst.start_sampling = true;
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neutralThrustEst.count = 0;
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neutralThrustEst.sum = 0.0f;
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neutralThrustEst.max = 0.0f;
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neutralThrustEst.min = 0.0f;
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}
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} else {
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// reset sampling as we did't get 6 continuous seconds
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neutralThrustEst.start_sampling = false;
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}
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} // else we already have a correction for this PH run
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}
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void PIDControlDown::setup_neutralThrustCalc(void)
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{
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// reset neutral thrust assessment.
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// and do once for each position hold engagement
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neutralThrustEst.start_sampling = false;
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neutralThrustEst.count = 0;
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neutralThrustEst.sum = 0.0f;
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neutralThrustEst.have_correction = false;
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neutralThrustEst.average = 0.0f;
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neutralThrustEst.correction = 0.0f;
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neutralThrustEst.min = 0.0f;
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neutralThrustEst.max = 0.0f;
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}
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void PIDControlDown::UpdateNeutralThrust(float neutral)
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{
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if (mActive) {
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// adjust neutral and achieve bumpless transfer
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PID.va = neutral;
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pid2_transfer(&PID, mDownCommand);
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}
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mNeutral = neutral;
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}
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void PIDControlDown::UpdateVelocitySetpoint(float setpoint)
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{
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mVelocitySetpointTarget = setpoint;
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if (fabsf(mVelocitySetpointTarget) > mVelocityMax) {
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// maintain sign but set to max
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mVelocitySetpointTarget *= mVelocityMax / fabsf(mVelocitySetpointTarget);
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}
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}
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void PIDControlDown::RateLimit(float *spDesired, float *spCurrent, float rateLimit)
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{
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float velocity_delta = *spDesired - *spCurrent;
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if (fabsf(velocity_delta) < 1e-6f) {
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*spCurrent = *spDesired;
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return;
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}
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// Calculate the rate of change
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float accelerationDesired = velocity_delta / deltaTime;
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if (fabsf(accelerationDesired) > rateLimit) {
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accelerationDesired *= rateLimit / accelerationDesired;
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}
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if (fabsf(accelerationDesired) < 0.1f) {
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*spCurrent = *spDesired;
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} else {
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*spCurrent += accelerationDesired * deltaTime;
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}
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}
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void PIDControlDown::UpdateBrakeVelocity(float startingVelocity, float dT, float brakeRate, float currentVelocity, float *updatedVelocity)
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{
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if (startingVelocity >= 0.0f) {
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*updatedVelocity = startingVelocity - dT * brakeRate;
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if (*updatedVelocity > currentVelocity) {
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*updatedVelocity = currentVelocity;
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}
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if (*updatedVelocity < 0.0f) {
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*updatedVelocity = 0.0f;
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}
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} else {
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*updatedVelocity = startingVelocity + dT * brakeRate;
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if (*updatedVelocity < currentVelocity) {
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*updatedVelocity = currentVelocity;
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}
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if (*updatedVelocity > 0.0f) {
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*updatedVelocity = 0.0f;
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}
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}
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}
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void PIDControlDown::UpdateVelocityStateWithBrake(float pvDown, float path_time, float brakeRate)
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{
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mVelocityState = pvDown;
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float velocitySetpointDesired;
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UpdateBrakeVelocity(mVelocitySetpointTarget, path_time, brakeRate, pvDown, &velocitySetpointDesired);
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// Calculate the rate of change
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// RateLimit(velocitySetpointDesired[iaxis], mVelocitySetpointCurrent[iaxis], 2.0f );
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mVelocitySetpointCurrent = velocitySetpointDesired;
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}
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// Update velocity state called per dT. Also update current
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// desired velocity
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void PIDControlDown::UpdateVelocityState(float pv)
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{
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mVelocityState = pv;
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if (mFSM) {
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// The FSM controls the actual descent velocity and introduces step changes as required
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float velocitySetpointDesired = mFSM->BoundVelocityDown(mVelocitySetpointTarget);
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// RateLimit(velocitySetpointDesired, mVelocitySetpointCurrent, 2.0f );
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mVelocitySetpointCurrent = velocitySetpointDesired;
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} else {
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mVelocitySetpointCurrent = mVelocitySetpointTarget;
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}
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}
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float PIDControlDown::GetVelocityDesired(void)
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{
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return mVelocitySetpointCurrent;
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}
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float PIDControlDown::GetDownCommand(void)
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{
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PIDStatusData pidStatus;
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float ulow = mMinThrust;
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float uhigh = mMaxThrust;
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if (mFSM) {
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mFSM->BoundThrust(ulow, uhigh);
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}
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float downCommand = pid2_apply(&PID, mVelocitySetpointCurrent, mVelocityState, ulow, uhigh);
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pidStatus.setpoint = mVelocitySetpointCurrent;
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pidStatus.actual = mVelocityState;
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pidStatus.error = mVelocitySetpointCurrent - mVelocityState;
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pidStatus.setpoint = mVelocitySetpointCurrent;
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pidStatus.ulow = ulow;
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pidStatus.uhigh = uhigh;
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pidStatus.command = downCommand;
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pidStatus.P = PID.P;
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pidStatus.I = PID.I;
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pidStatus.D = PID.D;
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PIDStatusSet(&pidStatus);
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mDownCommand = downCommand;
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return mDownCommand;
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}
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