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allwpilib/wpilibc/Athena/src/PIDController.cpp
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/*----------------------------------------------------------------------------*/
/* Copyright (c) FIRST 2008-2016. All Rights Reserved. */
/* Open Source Software - may be modified and shared by FRC teams. The code */
/* must be accompanied by the FIRST BSD license file in the root directory of */
/* the project. */
/*----------------------------------------------------------------------------*/
#include "PIDController.h"
#include "Notifier.h"
#include "PIDSource.h"
#include "PIDOutput.h"
#include <math.h>
#include <vector>
#include "HAL/HAL.hpp"
static const std::string kP = "p";
static const std::string kI = "i";
static const std::string kD = "d";
static const std::string kF = "f";
static const std::string kSetpoint = "setpoint";
static const std::string kEnabled = "enabled";
/**
* Allocate a PID object with the given constants for P, I, D
* @param Kp the proportional coefficient
* @param Ki the integral coefficient
* @param Kd the derivative coefficient
* @param source The PIDSource object that is used to get values
* @param output The PIDOutput object that is set to the output value
* @param period the loop time for doing calculations. This particularly effects
* calculations of the
* integral and differental terms. The default is 50ms.
*/
PIDController::PIDController(float Kp, float Ki, float Kd, PIDSource *source,
PIDOutput *output, float period) {
Initialize(Kp, Ki, Kd, 0.0f, source, output, period);
}
/**
* Allocate a PID object with the given constants for P, I, D
* @param Kp the proportional coefficient
* @param Ki the integral coefficient
* @param Kd the derivative coefficient
* @param source The PIDSource object that is used to get values
* @param output The PIDOutput object that is set to the output value
* @param period the loop time for doing calculations. This particularly effects
* calculations of the
* integral and differental terms. The default is 50ms.
*/
PIDController::PIDController(float Kp, float Ki, float Kd, float Kf,
PIDSource *source, PIDOutput *output, float period) {
Initialize(Kp, Ki, Kd, Kf, source, output, period);
}
void PIDController::Initialize(float Kp, float Ki, float Kd, float Kf,
PIDSource *source, PIDOutput *output,
float period) {
m_controlLoop = std::make_unique<Notifier>(&PIDController::Calculate, this);
m_P = Kp;
m_I = Ki;
m_D = Kd;
m_F = Kf;
m_pidInput = source;
m_pidOutput = output;
m_period = period;
m_controlLoop->StartPeriodic(m_period);
m_setpointTimer.Start();
static int32_t instances = 0;
instances++;
HALReport(HALUsageReporting::kResourceType_PIDController, instances);
}
PIDController::~PIDController() {
if (m_table != nullptr) m_table->RemoveTableListener(this);
}
/**
* Read the input, calculate the output accordingly, and write to the output.
* This should only be called by the Notifier.
*/
void PIDController::Calculate() {
bool enabled;
PIDSource *pidInput;
PIDOutput *pidOutput;
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
pidInput = m_pidInput;
pidOutput = m_pidOutput;
enabled = m_enabled;
}
if (pidInput == nullptr) return;
if (pidOutput == nullptr) return;
if (enabled) {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
float input = pidInput->PIDGet();
float result;
PIDOutput *pidOutput;
m_error = m_setpoint - input;
if (m_continuous) {
if (fabs(m_error) > (m_maximumInput - m_minimumInput) / 2) {
if (m_error > 0) {
m_error = m_error - m_maximumInput + m_minimumInput;
} else {
m_error = m_error + m_maximumInput - m_minimumInput;
}
}
}
if (m_pidInput->GetPIDSourceType() == PIDSourceType::kRate) {
if (m_P != 0) {
double potentialPGain = (m_totalError + m_error) * m_P;
if (potentialPGain < m_maximumOutput) {
if (potentialPGain > m_minimumOutput)
m_totalError += m_error;
else
m_totalError = m_minimumOutput / m_P;
} else {
m_totalError = m_maximumOutput / m_P;
}
}
m_result = m_D * m_error + m_P * m_totalError + CalculateFeedForward();
}
else {
if (m_I != 0) {
double potentialIGain = (m_totalError + m_error) * m_I;
if (potentialIGain < m_maximumOutput) {
if (potentialIGain > m_minimumOutput)
m_totalError += m_error;
else
m_totalError = m_minimumOutput / m_I;
} else {
m_totalError = m_maximumOutput / m_I;
}
}
m_result = m_P * m_error + m_I * m_totalError +
m_D * (m_error - m_prevError) + CalculateFeedForward();
}
m_prevError = m_error;
if (m_result > m_maximumOutput)
m_result = m_maximumOutput;
else if (m_result < m_minimumOutput)
m_result = m_minimumOutput;
pidOutput = m_pidOutput;
result = m_result;
pidOutput->PIDWrite(result);
// Update the buffer.
m_buf.push(m_error);
m_bufTotal += m_error;
// Remove old elements when buffer is full.
if (m_buf.size() > m_bufLength) {
m_bufTotal -= m_buf.front();
m_buf.pop();
}
}
}
/**
* Calculate the feed forward term
*
* Both of the provided feed forward calculations are velocity feed forwards.
* If a different feed forward calculation is desired, the user can override
* this function and provide his or her own. This function does no
* synchronization because the PIDController class only calls it in synchronized
* code, so be careful if calling it oneself.
*
* If a velocity PID controller is being used, the F term should be set to 1
* over the maximum setpoint for the output. If a position PID controller is
* being used, the F term should be set to 1 over the maximum speed for the
* output measured in setpoint units per this controller's update period (see
* the default period in this class's constructor).
*/
double PIDController::CalculateFeedForward() {
if (m_pidInput->GetPIDSourceType() == PIDSourceType::kRate) {
return m_F * GetSetpoint();
}
else {
double temp = m_F * GetDeltaSetpoint();
m_prevSetpoint = m_setpoint;
m_setpointTimer.Reset();
return temp;
}
}
/**
* Set the PID Controller gain parameters.
* Set the proportional, integral, and differential coefficients.
* @param p Proportional coefficient
* @param i Integral coefficient
* @param d Differential coefficient
*/
void PIDController::SetPID(double p, double i, double d) {
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_P = p;
m_I = i;
m_D = d;
}
if (m_table != nullptr) {
m_table->PutNumber("p", m_P);
m_table->PutNumber("i", m_I);
m_table->PutNumber("d", m_D);
}
}
/**
* Set the PID Controller gain parameters.
* Set the proportional, integral, and differential coefficients.
* @param p Proportional coefficient
* @param i Integral coefficient
* @param d Differential coefficient
* @param f Feed forward coefficient
*/
void PIDController::SetPID(double p, double i, double d, double f) {
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_P = p;
m_I = i;
m_D = d;
m_F = f;
}
if (m_table != nullptr) {
m_table->PutNumber("p", m_P);
m_table->PutNumber("i", m_I);
m_table->PutNumber("d", m_D);
m_table->PutNumber("f", m_F);
}
}
/**
* Get the Proportional coefficient
* @return proportional coefficient
*/
double PIDController::GetP() const {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
return m_P;
}
/**
* Get the Integral coefficient
* @return integral coefficient
*/
double PIDController::GetI() const {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
return m_I;
}
/**
* Get the Differential coefficient
* @return differential coefficient
*/
double PIDController::GetD() const {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
return m_D;
}
/**
* Get the Feed forward coefficient
* @return Feed forward coefficient
*/
double PIDController::GetF() const {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
return m_F;
}
/**
* Return the current PID result
* This is always centered on zero and constrained the the max and min outs
* @return the latest calculated output
*/
float PIDController::Get() const {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
return m_result;
}
/**
* Set the PID controller to consider the input to be continuous,
* Rather then using the max and min in as constraints, it considers them to
* be the same point and automatically calculates the shortest route to
* the setpoint.
* @param continuous Set to true turns on continuous, false turns off continuous
*/
void PIDController::SetContinuous(bool continuous) {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_continuous = continuous;
}
/**
* Sets the maximum and minimum values expected from the input.
*
* @param minimumInput the minimum value expected from the input
* @param maximumInput the maximum value expected from the output
*/
void PIDController::SetInputRange(float minimumInput, float maximumInput) {
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_minimumInput = minimumInput;
m_maximumInput = maximumInput;
}
SetSetpoint(m_setpoint);
}
/**
* Sets the minimum and maximum values to write.
*
* @param minimumOutput the minimum value to write to the output
* @param maximumOutput the maximum value to write to the output
*/
void PIDController::SetOutputRange(float minimumOutput, float maximumOutput) {
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_minimumOutput = minimumOutput;
m_maximumOutput = maximumOutput;
}
}
/**
* Set the setpoint for the PIDController
* Clears the queue for GetAvgError().
* @param setpoint the desired setpoint
*/
void PIDController::SetSetpoint(float setpoint) {
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
if (m_maximumInput > m_minimumInput) {
if (setpoint > m_maximumInput)
m_setpoint = m_maximumInput;
else if (setpoint < m_minimumInput)
m_setpoint = m_minimumInput;
else
m_setpoint = setpoint;
} else {
m_setpoint = setpoint;
}
// Clear m_buf.
m_buf = std::queue<double>();
}
if (m_table != nullptr) {
m_table->PutNumber("setpoint", m_setpoint);
}
}
/**
* Returns the current setpoint of the PIDController
* @return the current setpoint
*/
double PIDController::GetSetpoint() const {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
return m_setpoint;
}
/**
* Returns the change in setpoint over time of the PIDController
* @return the change in setpoint over time
*/
double PIDController::GetDeltaSetpoint() const {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
return (m_setpoint - m_prevSetpoint) / m_setpointTimer.Get();
}
/**
* Returns the current difference of the input from the setpoint
* @return the current error
*/
float PIDController::GetError() const {
double pidInput;
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
pidInput = m_pidInput->PIDGet();
}
return GetSetpoint() - pidInput;
}
/**
* Sets what type of input the PID controller will use
*/
void PIDController::SetPIDSourceType(PIDSourceType pidSource) {
m_pidInput->SetPIDSourceType(pidSource);
}
/**
* Returns the type of input the PID controller is using
* @return the PID controller input type
*/
PIDSourceType PIDController::GetPIDSourceType() const {
return m_pidInput->GetPIDSourceType();
}
/**
* Returns the current average of the error over the past few iterations.
* You can specify the number of iterations to average with SetToleranceBuffer()
* (defaults to 1). This is the same value that is used for OnTarget().
* @return the average error
*/
float PIDController::GetAvgError() const {
float avgError = 0;
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
// Don't divide by zero.
if (m_buf.size()) avgError = m_bufTotal / m_buf.size();
}
return avgError;
}
/*
* Set the percentage error which is considered tolerable for use with
* OnTarget.
* @param percentage error which is tolerable
*/
void PIDController::SetTolerance(float percent) {
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_toleranceType = kPercentTolerance;
m_tolerance = percent;
}
}
/*
* Set the percentage error which is considered tolerable for use with
* OnTarget.
* @param percentage error which is tolerable
*/
void PIDController::SetPercentTolerance(float percent) {
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_toleranceType = kPercentTolerance;
m_tolerance = percent;
}
}
/*
* Set the absolute error which is considered tolerable for use with
* OnTarget.
* @param percentage error which is tolerable
*/
void PIDController::SetAbsoluteTolerance(float absTolerance) {
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_toleranceType = kAbsoluteTolerance;
m_tolerance = absTolerance;
}
}
/*
* Set the number of previous error samples to average for tolerancing. When
* determining whether a mechanism is on target, the user may want to use a
* rolling average of previous measurements instead of a precise position or
* velocity. This is useful for noisy sensors which return a few erroneous
* measurements when the mechanism is on target. However, the mechanism will
* not register as on target for at least the specified bufLength cycles.
* @param bufLength Number of previous cycles to average. Defaults to 1.
*/
void PIDController::SetToleranceBuffer(unsigned bufLength) {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_bufLength = bufLength;
// Cut the buffer down to size if needed.
while (m_buf.size() > bufLength) {
m_bufTotal -= m_buf.front();
m_buf.pop();
}
}
/*
* Return true if the error is within the percentage of the total input range,
* determined by SetTolerance. This asssumes that the maximum and minimum input
* were set using SetInput.
* Currently this just reports on target as the actual value passes through the
* setpoint.
* Ideally it should be based on being within the tolerance for some period of
* time.
* This will return false until at least one input value has been computed.
*/
bool PIDController::OnTarget() const {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
if (m_buf.size() == 0) return false;
double error = GetAvgError();
switch (m_toleranceType) {
case kPercentTolerance:
return fabs(error) < m_tolerance / 100 * (m_maximumInput - m_minimumInput);
break;
case kAbsoluteTolerance:
return fabs(error) < m_tolerance;
break;
case kNoTolerance:
// TODO: this case needs an error
return false;
}
return false;
}
/**
* Begin running the PIDController
*/
void PIDController::Enable() {
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_enabled = true;
}
if (m_table != nullptr) {
m_table->PutBoolean("enabled", true);
}
}
/**
* Stop running the PIDController, this sets the output to zero before stopping.
*/
void PIDController::Disable() {
{
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_pidOutput->PIDWrite(0);
m_enabled = false;
}
if (m_table != nullptr) {
m_table->PutBoolean("enabled", false);
}
}
/**
* Return true if PIDController is enabled.
*/
bool PIDController::IsEnabled() const {
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
return m_enabled;
}
/**
* Reset the previous error,, the integral term, and disable the controller.
*/
void PIDController::Reset() {
Disable();
std::lock_guard<priority_recursive_mutex> sync(m_mutex);
m_prevError = 0;
m_totalError = 0;
m_result = 0;
}
std::string PIDController::GetSmartDashboardType() const {
return "PIDController";
}
void PIDController::InitTable(std::shared_ptr<ITable> table) {
if (m_table != nullptr) m_table->RemoveTableListener(this);
m_table = table;
if (m_table != nullptr) {
m_table->PutNumber(kP, GetP());
m_table->PutNumber(kI, GetI());
m_table->PutNumber(kD, GetD());
m_table->PutNumber(kF, GetF());
m_table->PutNumber(kSetpoint, GetSetpoint());
m_table->PutBoolean(kEnabled, IsEnabled());
m_table->AddTableListener(this, false);
}
}
std::shared_ptr<ITable> PIDController::GetTable() const { return m_table; }
void PIDController::ValueChanged(ITable* source, llvm::StringRef key,
std::shared_ptr<nt::Value> value, bool isNew) {
if (key == kP || key == kI || key == kD || key == kF) {
if (m_P != m_table->GetNumber(kP, 0.0) ||
m_I != m_table->GetNumber(kI, 0.0) ||
m_D != m_table->GetNumber(kD, 0.0) ||
m_F != m_table->GetNumber(kF, 0.0)) {
SetPID(m_table->GetNumber(kP, 0.0), m_table->GetNumber(kI, 0.0),
m_table->GetNumber(kD, 0.0), m_table->GetNumber(kF, 0.0));
}
} else if (key == kSetpoint && value->IsDouble() &&
m_setpoint != value->GetDouble()) {
SetSetpoint(value->GetDouble());
} else if (key == kEnabled && value->IsBoolean() &&
m_enabled != value->GetBoolean()) {
if (value->GetBoolean()) {
Enable();
} else {
Disable();
}
}
}
void PIDController::UpdateTable() {}
void PIDController::StartLiveWindowMode() { Disable(); }
void PIDController::StopLiveWindowMode() {}