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allwpilib/wpimath/src/main/native/include/frc/controller/PIDController.h

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// Copyright (c) FIRST and other WPILib contributors.
// Open Source Software; you can modify and/or share it under the terms of
// the WPILib BSD license file in the root directory of this project.
#pragma once
#include <functional>
#include <limits>
#include <wpi/sendable/Sendable.h>
#include <wpi/sendable/SendableHelper.h>
#include "units/time.h"
namespace frc2 {
/**
* Implements a PID control loop.
*/
class PIDController : public wpi::Sendable,
public wpi::SendableHelper<PIDController> {
public:
/**
* Allocates a PIDController with the given constants for Kp, Ki, and Kd.
*
* @param Kp The proportional coefficient.
* @param Ki The integral coefficient.
* @param Kd The derivative coefficient.
* @param period The period between controller updates in seconds. The
* default is 20 milliseconds. Must be non-zero and positive.
*/
PIDController(double Kp, double Ki, double Kd,
units::second_t period = 20_ms);
~PIDController() override = default;
PIDController(const PIDController&) = default;
PIDController& operator=(const PIDController&) = default;
PIDController(PIDController&&) = default;
PIDController& operator=(PIDController&&) = default;
/**
* Sets the PID Controller gain parameters.
*
* Sets the proportional, integral, and differential coefficients.
*
* @param Kp Proportional coefficient
* @param Ki Integral coefficient
* @param Kd Differential coefficient
*/
void SetPID(double Kp, double Ki, double Kd);
/**
* Sets the proportional coefficient of the PID controller gain.
*
* @param Kp proportional coefficient
*/
void SetP(double Kp);
/**
* Sets the integral coefficient of the PID controller gain.
*
* @param Ki integral coefficient
*/
void SetI(double Ki);
/**
* Sets the differential coefficient of the PID controller gain.
*
* @param Kd differential coefficient
*/
void SetD(double Kd);
/**
* Gets the proportional coefficient.
*
* @return proportional coefficient
*/
double GetP() const;
/**
* Gets the integral coefficient.
*
* @return integral coefficient
*/
double GetI() const;
/**
* Gets the differential coefficient.
*
* @return differential coefficient
*/
double GetD() const;
/**
* Gets the period of this controller.
*
* @return The period of the controller.
*/
units::second_t GetPeriod() const;
/**
* Sets the setpoint for the PIDController.
*
* @param setpoint The desired setpoint.
*/
void SetSetpoint(double setpoint);
/**
* Returns the current setpoint of the PIDController.
*
* @return The current setpoint.
*/
double GetSetpoint() const;
/**
* Returns true if the error is within the tolerance of the setpoint.
*
* This will return false until at least one input value has been computed.
*/
bool AtSetpoint() const;
/**
* Enables continuous input.
*
* Rather then using the max and min input range as constraints, it considers
* them to be the same point and automatically calculates the shortest route
* to the setpoint.
*
* @param minimumInput The minimum value expected from the input.
* @param maximumInput The maximum value expected from the input.
*/
void EnableContinuousInput(double minimumInput, double maximumInput);
/**
* Disables continuous input.
*/
void DisableContinuousInput();
/**
* Returns true if continuous input is enabled.
*/
bool IsContinuousInputEnabled() const;
/**
* Sets the minimum and maximum values for the integrator.
*
* When the cap is reached, the integrator value is added to the controller
* output rather than the integrator value times the integral gain.
*
* @param minimumIntegral The minimum value of the integrator.
* @param maximumIntegral The maximum value of the integrator.
*/
void SetIntegratorRange(double minimumIntegral, double maximumIntegral);
/**
* Sets the error which is considered tolerable for use with AtSetpoint().
*
* @param positionTolerance Position error which is tolerable.
* @param velociytTolerance Velocity error which is tolerable.
*/
void SetTolerance(
double positionTolerance,
double velocityTolerance = std::numeric_limits<double>::infinity());
/**
* Returns the difference between the setpoint and the measurement.
*/
double GetPositionError() const;
/**
* Returns the velocity error.
*/
double GetVelocityError() const;
/**
* Returns the next output of the PID controller.
*
* @param measurement The current measurement of the process variable.
*/
double Calculate(double measurement);
/**
* Returns the next output of the PID controller.
*
* @param measurement The current measurement of the process variable.
* @param setpoint The new setpoint of the controller.
*/
double Calculate(double measurement, double setpoint);
/**
* Reset the previous error, the integral term, and disable the controller.
*/
void Reset();
void InitSendable(wpi::SendableBuilder& builder) override;
private:
// Factor for "proportional" control
double m_Kp;
// Factor for "integral" control
double m_Ki;
// Factor for "derivative" control
double m_Kd;
// The period (in seconds) of the control loop running this controller
units::second_t m_period;
double m_maximumIntegral = 1.0;
double m_minimumIntegral = -1.0;
double m_maximumInput = 0;
double m_minimumInput = 0;
// Do the endpoints wrap around? eg. Absolute encoder
bool m_continuous = false;
// The error at the time of the most recent call to Calculate()
double m_positionError = 0;
double m_velocityError = 0;
// The error at the time of the second-most-recent call to Calculate() (used
// to compute velocity)
double m_prevError = 0;
// The sum of the errors for use in the integral calc
double m_totalError = 0;
// The error that is considered at setpoint.
double m_positionTolerance = 0.05;
double m_velocityTolerance = std::numeric_limits<double>::infinity();
double m_setpoint = 0;
double m_measurement = 0;
};
} // namespace frc2
namespace frc {
using frc2::PIDController;
} // namespace frc
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