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[wpilib] Add physics simulation support with state-space (#2615)

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This includes physics simulation support for arms/elevator models, as well as differential drivetrains.

Swerve might be added at a later date.

Co-authored-by: Claudius Tewari <cttewari@gmail.com>
Co-authored-by: Prateek Machiraju <prateek.machiraju@gmail.com>
Co-authored-by: Tyler Veness <calcmogul@gmail.com>
This commit is contained in:
Matt
2020-09-20 09:39:52 -07:00
committed by GitHub
parent 0503225928
commit b61f08d3fa
43 changed files with 3787 additions and 31 deletions
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121
wpilibc/src/main/native/cpp/simulation/DifferentialDrivetrainSim.cpp Normal file
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/*----------------------------------------------------------------------------*/
/* Copyright (c) 2020 FIRST. 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 "frc/simulation/DifferentialDrivetrainSim.h"
#include <frc/system/plant/LinearSystemId.h>
#include "frc/system/RungeKutta.h"
using namespace frc;
using namespace frc::sim;
DifferentialDrivetrainSim::DifferentialDrivetrainSim(
const LinearSystem<2, 2, 2>& plant, units::meter_t trackWidth,
DCMotor driveMotor, double gearRatio, units::meter_t wheelRadius)
: m_plant(plant),
m_rb(trackWidth / 2.0),
m_wheelRadius(wheelRadius),
m_motor(driveMotor),
m_originalGearing(gearRatio),
m_currentGearing(gearRatio) {
m_x.setZero();
m_u.setZero();
}
DifferentialDrivetrainSim::DifferentialDrivetrainSim(
frc::DCMotor driveMotor, double gearing, units::kilogram_square_meter_t J,
units::kilogram_t mass, units::meter_t wheelRadius,
units::meter_t trackWidth)
: DifferentialDrivetrainSim(
frc::LinearSystemId::DrivetrainVelocitySystem(
driveMotor, mass, wheelRadius, trackWidth / 2.0, J, gearing),
trackWidth, driveMotor, gearing, wheelRadius) {}
void DifferentialDrivetrainSim::SetInputs(units::volt_t leftVoltage,
units::volt_t rightVoltage) {
m_u << leftVoltage.to<double>(), rightVoltage.to<double>();
}
void DifferentialDrivetrainSim::SetGearing(double newGearing) {
m_currentGearing = newGearing;
}
void DifferentialDrivetrainSim::Update(units::second_t dt) {
m_x = RungeKutta([this](auto& x, auto& u) { return Dynamics(x, u); }, m_x,
m_u, dt);
}
double DifferentialDrivetrainSim::GetState(int state) const {
return m_x(state);
}
double DifferentialDrivetrainSim::GetGearing() const {
return m_currentGearing;
}
Eigen::Matrix<double, 7, 1> DifferentialDrivetrainSim::GetState() const {
return m_x;
}
Rotation2d DifferentialDrivetrainSim::GetHeading() const {
return Rotation2d(units::radian_t(m_x(State::kHeading)));
}
Pose2d DifferentialDrivetrainSim::GetEstimatedPosition() const {
return Pose2d(units::meter_t(m_x(State::kX)), units::meter_t(m_x(State::kY)),
Rotation2d(units::radian_t(m_x(State::kHeading))));
}
units::ampere_t DifferentialDrivetrainSim::GetCurrentDraw() const {
auto loadIleft =
m_motor.Current(units::radians_per_second_t(m_x(State::kLeftVelocity) *
m_currentGearing /
m_wheelRadius.to<double>()),
units::volt_t(m_u(0))) *
wpi::sgn(m_u(0));
auto loadIRight =
m_motor.Current(units::radians_per_second_t(m_x(State::kRightVelocity) *
m_currentGearing /
m_wheelRadius.to<double>()),
units::volt_t(m_u(1))) *
wpi::sgn(m_u(1));
return loadIleft + loadIRight;
}
Eigen::Matrix<double, 7, 1> DifferentialDrivetrainSim::Dynamics(
const Eigen::Matrix<double, 7, 1>& x,
const Eigen::Matrix<double, 2, 1>& u) {
// Because G^2 can be factored out of A, we can divide by the old ratio
// squared and multiply by the new ratio squared to get a new drivetrain
// model.
Eigen::Matrix<double, 4, 2> B;
B.block<2, 2>(0, 0) = m_plant.B() * m_currentGearing * m_currentGearing /
m_originalGearing / m_originalGearing;
B.block<2, 2>(2, 0).setZero();
// Because G can be factored out of B, we can divide by the old ratio and
// multiply by the new ratio to get a new drivetrain model.
Eigen::Matrix<double, 4, 4> A;
A.block<2, 2>(0, 0) = m_plant.A() * m_currentGearing / m_originalGearing;
A.block<2, 2>(2, 0).setIdentity();
A.block<4, 2>(0, 2).setZero();
double v = (x(State::kLeftVelocity) + x(State::kRightVelocity)) / 2.0;
Eigen::Matrix<double, 7, 1> xdot;
xdot(0) = v * std::cos(x(State::kHeading));
xdot(1) = v * std::sin(x(State::kHeading));
xdot(2) =
((x(State::kRightVelocity) - x(State::kLeftVelocity)) / (2.0 * m_rb))
.to<double>();
xdot.block<4, 1>(3, 0) = A * x.block<4, 1>(3, 0) + B * u;
return xdot;
}

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wpilibc/src/main/native/cpp/simulation/ElevatorSim.cpp Normal file
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/*----------------------------------------------------------------------------*/
/* Copyright (c) 2020 FIRST. 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 "frc/simulation/ElevatorSim.h"
#include <wpi/MathExtras.h>
#include "frc/StateSpaceUtil.h"
#include "frc/system/RungeKutta.h"
#include "frc/system/plant/LinearSystemId.h"
using namespace frc;
using namespace frc::sim;
ElevatorSim::ElevatorSim(const DCMotor& gearbox, units::kilogram_t carriageMass,
double gearing, units::meter_t drumRadius,
units::meter_t minHeight, units::meter_t maxHeight,
bool addNoise,
const std::array<double, 1>& m_measurementStdDevs)
: LinearSystemSim(LinearSystemId::ElevatorSystem(gearbox, carriageMass,
drumRadius, gearing),
addNoise, m_measurementStdDevs),
m_motor(gearbox),
m_drumRadius(drumRadius),
m_minHeight(minHeight),
m_maxHeight(maxHeight),
m_gearing(gearing) {}
bool ElevatorSim::HasHitLowerLimit(const Eigen::Matrix<double, 2, 1>& x) const {
return x(0) < m_minHeight.to<double>();
}
bool ElevatorSim::HasHitUpperLimit(const Eigen::Matrix<double, 2, 1>& x) const {
return x(0) > m_maxHeight.to<double>();
}
units::meter_t ElevatorSim::GetPosition() const { return units::meter_t{Y(0)}; }
units::meters_per_second_t ElevatorSim::GetVelocity() const {
return units::meters_per_second_t{m_x(1)};
}
units::ampere_t ElevatorSim::GetCurrentDraw() const {
// I = V / R - omega / (Kv * R)
// Reductions are greater than 1, so a reduction of 10:1 would mean the motor
// is spinning 10x faster than the output.
// v = r w, so w = v / r
units::meters_per_second_t velocity{m_x(1)};
units::radians_per_second_t motorVelocity =
velocity / m_drumRadius * m_gearing * 1_rad;
// Perform calculation and return.
return m_motor.Current(motorVelocity, units::volt_t{m_u(0)}) *
wpi::sgn(m_u(0));
}
Eigen::Matrix<double, 2, 1> ElevatorSim::UpdateX(
const Eigen::Matrix<double, 2, 1>& currentXhat,
const Eigen::Matrix<double, 1, 1>& u, units::second_t dt) {
auto updatedXhat = RungeKutta(
[&](const Eigen::Matrix<double, 2, 1>& x,
const Eigen::Matrix<double, 1, 1>& u_)
-> Eigen::Matrix<double, 2, 1> {
return m_plant.A() * x + m_plant.B() * u_ + MakeMatrix<2, 1>(0.0, -9.8);
},
currentXhat, u, dt);
// Check for collision after updating x-hat.
if (HasHitLowerLimit(updatedXhat)) {
return MakeMatrix<2, 1>(m_minHeight.to<double>(), 0.0);
} else if (HasHitUpperLimit(updatedXhat)) {
return MakeMatrix<2, 1>(m_maxHeight.to<double>(), 0.0);
}
return updatedXhat;
}

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wpilibc/src/main/native/cpp/simulation/FlywheelSim.cpp Normal file
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/*----------------------------------------------------------------------------*/
/* Copyright (c) 2020 FIRST. 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 "frc/simulation/FlywheelSim.h"
#include <wpi/MathExtras.h>
#include "frc/system/plant/LinearSystemId.h"
using namespace frc;
using namespace frc::sim;
FlywheelSim::FlywheelSim(const LinearSystem<1, 1, 1>& plant,
const DCMotor& gearbox, double gearing, bool addNoise,
const std::array<double, 1>& measurementStdDevs)
: LinearSystemSim<1, 1, 1>(plant, addNoise, measurementStdDevs),
m_motor(gearbox),
m_gearing(gearing) {}
FlywheelSim::FlywheelSim(const DCMotor& gearbox, double gearing,
units::kilogram_square_meter_t moi, bool addNoise,
const std::array<double, 1>& measurementStdDevs)
: FlywheelSim(LinearSystemId::FlywheelSystem(gearbox, moi, gearing),
gearbox, gearing, addNoise, measurementStdDevs) {}
units::radians_per_second_t FlywheelSim::GetAngularVelocity() const {
return units::radians_per_second_t{Y(0)};
}
units::ampere_t FlywheelSim::GetCurrentDraw() const {
// I = V / R - omega / (Kv * R)
// Reductions are greater than 1, so a reduction of 10:1 would mean the motor
// is spinning 10x faster than the output.
return m_motor.Current(GetAngularVelocity() * m_gearing,
units::volt_t{m_u(0)}) *
wpi::sgn(m_u(0));
}

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wpilibc/src/main/native/cpp/simulation/SingleJointedArmSim.cpp Normal file
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/*----------------------------------------------------------------------------*/
/* Copyright (c) 2020 FIRST. 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 "frc/simulation/SingleJointedArmSim.h"
#include <cmath>
#include <units/voltage.h>
#include <wpi/MathExtras.h>
#include "frc/system/RungeKutta.h"
#include "frc/system/plant/LinearSystemId.h"
using namespace frc;
using namespace frc::sim;
SingleJointedArmSim::SingleJointedArmSim(
const LinearSystem<2, 1, 1>& system, const DCMotor motor, double G,
units::kilogram_t mass, units::meter_t armLength, units::radian_t minAngle,
units::radian_t maxAngle, bool addNoise,
const std::array<double, 1>& measurementStdDevs)
: LinearSystemSim<2, 1, 1>(system, addNoise, measurementStdDevs),
m_r(armLength),
m_minAngle(minAngle),
m_maxAngle(maxAngle),
m_mass(mass),
m_motor(motor),
m_gearing(G) {}
SingleJointedArmSim::SingleJointedArmSim(
const DCMotor& motor, units::kilogram_square_meter_t J, double G,
units::kilogram_t mass, units::meter_t armLength, units::radian_t minAngle,
units::radian_t maxAngle, bool addNoise,
const std::array<double, 1>& measurementStdDevs)
: SingleJointedArmSim(LinearSystemId::SingleJointedArmSystem(motor, J, G),
motor, G, mass, armLength, minAngle, maxAngle,
addNoise, measurementStdDevs) {}
SingleJointedArmSim::SingleJointedArmSim(
const DCMotor& motor, double G, units::kilogram_t mass,
units::meter_t armLength, units::radian_t minAngle,
units::radian_t maxAngle, bool addNoise,
const std::array<double, 1>& measurementStdDevs)
: SingleJointedArmSim(
LinearSystemId::SingleJointedArmSystem(
motor, 1.0 / 3.0 * mass * armLength * armLength, G),
motor, G, mass, armLength, minAngle, maxAngle, addNoise,
measurementStdDevs) {}
bool SingleJointedArmSim::HasHitLowerLimit(
const Eigen::Matrix<double, 2, 1>& x) const {
return x(0) < m_minAngle.to<double>();
}
bool SingleJointedArmSim::HasHitUpperLimit(
const Eigen::Matrix<double, 2, 1>& x) const {
return x(0) > m_maxAngle.to<double>();
}
units::radian_t SingleJointedArmSim::GetAngle() const {
return units::radian_t{m_x(0)};
}
units::radians_per_second_t SingleJointedArmSim::GetVelocity() const {
return units::radians_per_second_t{m_x(1)};
}
Eigen::Matrix<double, 2, 1> SingleJointedArmSim::UpdateX(
const Eigen::Matrix<double, 2, 1>& currentXhat,
const Eigen::Matrix<double, 1, 1>& u, units::second_t dt) {
// Horizontal case:
// Torque = F * r = I * alpha
// alpha = F * r / I
// Since F = mg,
// alpha = m * g * r / I
// Finally, multiply RHS by cos(theta) to account for the arm angle
// This acceleration is added to the linear system dynamics x-dot = Ax + Bu
// We therefore find that f(x, u) = Ax + Bu + [[0] [m * g * r / I *
// std::cos(theta)]]
auto updatedXhat = RungeKutta(
[&](const auto& x, const auto& u) -> Eigen::Matrix<double, 2, 1> {
return m_plant.A() * x + m_plant.B() * u +
MakeMatrix<2, 1>(0.0, (m_mass * m_r * -9.8 * 3.0 /
(m_mass * m_r * m_r) * std::cos(x(0)))
.template to<double>());
},
currentXhat, u, dt);
// Check for collisions.
if (HasHitLowerLimit(updatedXhat)) {
return MakeMatrix<2, 1>(m_minAngle.to<double>(), 0.0);
} else if (HasHitUpperLimit(updatedXhat)) {
return MakeMatrix<2, 1>(m_maxAngle.to<double>(), 0.0);
}
return updatedXhat;
}
units::ampere_t SingleJointedArmSim::GetCurrentDraw() const {
// Reductions are greater than 1, so a reduction of 10:1 would mean the motor
// is spinning 10x faster than the output
units::radians_per_second_t motorVelocity{m_x(1) * m_gearing};
return m_motor.Current(motorVelocity, units::volt_t{m_u(0)}) *
wpi::sgn(m_u(0));
}