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https://github.com/wpilibsuite/allwpilib
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97 lines
3.1 KiB
C++
97 lines
3.1 KiB
C++
// Copyright (c) FIRST and other WPILib contributors.
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// Open Source Software; you can modify and/or share it under the terms of
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// the WPILib BSD license file in the root directory of this project.
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#include <cmath>
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#include <gtest/gtest.h>
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#include "frc/EigenCore.h"
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#include "frc/system/NumericalIntegration.h"
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// Test that integrating dx/dt = eˣ works
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TEST(NumericalIntegrationTest, Exponential) {
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frc::Vectord<1> y0{0.0};
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frc::Vectord<1> y1 = frc::RK4(
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[](const frc::Vectord<1>& x) { return frc::Vectord<1>{std::exp(x(0))}; },
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y0, 0.1_s);
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EXPECT_NEAR(y1(0), std::exp(0.1) - std::exp(0), 1e-3);
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}
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// Test that integrating dx/dt = eˣ works when we provide a u
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TEST(NumericalIntegrationTest, ExponentialWithU) {
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frc::Vectord<1> y0{0.0};
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frc::Vectord<1> y1 = frc::RK4(
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[](const frc::Vectord<1>& x, const frc::Vectord<1>& u) {
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return frc::Vectord<1>{std::exp(u(0) * x(0))};
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},
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y0, frc::Vectord<1>{1.0}, 0.1_s);
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EXPECT_NEAR(y1(0), std::exp(0.1) - std::exp(0), 1e-3);
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}
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// Tests RK4 with a time varying solution. From
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// http://www2.hawaii.edu/~jmcfatri/math407/RungeKuttaTest.html:
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//
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// dx/dt = x (2 / (eᵗ + 1) - 1)
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//
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// The true (analytical) solution is:
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//
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// x(t) = 12eᵗ/(eᵗ + 1)²
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TEST(NumericalIntegrationTest, RK4TimeVarying) {
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frc::Vectord<1> y0{12.0 * std::exp(5.0) / std::pow(std::exp(5.0) + 1.0, 2.0)};
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frc::Vectord<1> y1 = frc::RK4(
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[](units::second_t t, const frc::Vectord<1>& x) {
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return frc::Vectord<1>{x(0) *
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(2.0 / (std::exp(t.value()) + 1.0) - 1.0)};
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},
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5_s, y0, 1_s);
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EXPECT_NEAR(y1(0), 12.0 * std::exp(6.0) / std::pow(std::exp(6.0) + 1.0, 2.0),
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1e-3);
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}
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// Tests that integrating dx/dt = 0 works with RKDP
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TEST(NumericalIntegrationTest, ZeroRKDP) {
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frc::Vectord<1> y1 = frc::RKDP(
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[](const frc::Vectord<1>& x, const frc::Vectord<1>& u) {
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return frc::Vectord<1>::Zero();
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},
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frc::Vectord<1>{0.0}, frc::Vectord<1>{0.0}, 0.1_s);
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EXPECT_NEAR(y1(0), 0.0, 1e-3);
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}
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// Tests that integrating dx/dt = eˣ works with RKDP
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TEST(NumericalIntegrationTest, ExponentialRKDP) {
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frc::Vectord<1> y0{0.0};
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frc::Vectord<1> y1 = frc::RKDP(
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[](const frc::Vectord<1>& x, const frc::Vectord<1>& u) {
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return frc::Vectord<1>{std::exp(x(0))};
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},
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y0, frc::Vectord<1>{0.0}, 0.1_s);
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EXPECT_NEAR(y1(0), std::exp(0.1) - std::exp(0), 1e-3);
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}
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// Tests RKDP with a time varying solution. From
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// http://www2.hawaii.edu/~jmcfatri/math407/RungeKuttaTest.html:
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//
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// dx/dt = x(2/(eᵗ + 1) - 1)
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//
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// The true (analytical) solution is:
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//
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// x(t) = 12eᵗ/(eᵗ + 1)²
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TEST(NumericalIntegrationTest, RKDPTimeVarying) {
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frc::Vectord<1> y0{12.0 * std::exp(5.0) / std::pow(std::exp(5.0) + 1.0, 2.0)};
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frc::Vectord<1> y1 = frc::RKDP(
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[](units::second_t t, const frc::Vectord<1>& x) {
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return frc::Vectord<1>{x(0) *
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(2.0 / (std::exp(t.value()) + 1.0) - 1.0)};
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},
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5_s, y0, 1_s, 1e-12);
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EXPECT_NEAR(y1(0), 12.0 * std::exp(6.0) / std::pow(std::exp(6.0) + 1.0, 2.0),
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1e-3);
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}
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