wpilibcIntegrationTests/src/main/native/cpp/TiltPanCameraTest.cpp - RealtimeRoboticsGroup/test - Gitiles

 /*----------------------------------------------------------------------------*/
 /* Copyright (c) 2014-2018 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 <cmath>

 #include "TestBench.h"
 #include "frc/ADXL345_SPI.h"
 #include "frc/AnalogGyro.h"
 #include "frc/Servo.h"
 #include "frc/Timer.h"
 #include "gtest/gtest.h"

 using namespace frc;

 static constexpr double kServoResetTime = 2.0;

 static constexpr double kTestAngle = 90.0;

 static constexpr double kTiltSetpoint0 = 0.22;
 static constexpr double kTiltSetpoint45 = 0.45;
 static constexpr double kTiltSetpoint90 = 0.68;
 static constexpr double kTiltTime = 1.0;
 static constexpr double kAccelerometerTolerance = 0.2;
 static constexpr double kSensitivity = 0.013;

 /**
  * A fixture for the camera with two servos and a gyro
  */
 class TiltPanCameraTest : public testing::Test {
  protected:
   static AnalogGyro* m_gyro;
   Servo *m_tilt, *m_pan;
   Accelerometer* m_spiAccel;

   static void SetUpTestCase() {
     // The gyro object blocks for 5 seconds in the constructor, so only
     // construct it once for the whole test case
     m_gyro = new AnalogGyro(TestBench::kCameraGyroChannel);
     m_gyro->SetSensitivity(kSensitivity);
   }

   static void TearDownTestCase() { delete m_gyro; }

   void SetUp() override {
     m_tilt = new Servo(TestBench::kCameraTiltChannel);
     m_pan = new Servo(TestBench::kCameraPanChannel);
     m_spiAccel = new ADXL345_SPI(SPI::kOnboardCS1);

     m_tilt->Set(kTiltSetpoint45);
     m_pan->SetAngle(0.0);

     Wait(kServoResetTime);

     m_gyro->Reset();
   }

   void DefaultGyroAngle();
   void GyroAngle();
   void GyroCalibratedParameters();

   void TearDown() override {
     delete m_tilt;
     delete m_pan;
     delete m_spiAccel;
   }
 };

 AnalogGyro* TiltPanCameraTest::m_gyro = nullptr;

 /**
  * Test if the gyro angle defaults to 0 immediately after being reset.
  */
 void TiltPanCameraTest::DefaultGyroAngle() {
   EXPECT_NEAR(0.0, m_gyro->GetAngle(), 1.0);
 }

 /**
  * Test if the servo turns 90 degrees and the gyroscope measures this angle
  * Note servo on TestBench is not the same type of servo that servo class
  * was designed for so setAngle is significantly off. This has been calibrated
  * for the servo on the rig.
  */
 void TiltPanCameraTest::GyroAngle() {
   // Make sure that the gyro doesn't get jerked when the servo goes to zero.
   m_pan->SetAngle(0.0);
   Wait(0.5);
   m_gyro->Reset();

   for (int32_t i = 0; i < 600; i++) {
     m_pan->Set(i / 1000.0);
     Wait(0.001);
   }

   double gyroAngle = m_gyro->GetAngle();

   EXPECT_NEAR(gyroAngle, kTestAngle, 10.0)
       << "Gyro measured " << gyroAngle << " degrees, servo should have turned "
       << kTestAngle << " degrees";
 }

 /**
  * Gets calibrated parameters from previously calibrated gyro, allocates a new
  * gyro with the given parameters for center and offset, and re-runs tests on
  * the new gyro.
  */
 void TiltPanCameraTest::GyroCalibratedParameters() {
   uint32_t cCenter = m_gyro->GetCenter();
   double cOffset = m_gyro->GetOffset();
   delete m_gyro;
   m_gyro = new AnalogGyro(TestBench::kCameraGyroChannel, cCenter, cOffset);
   m_gyro->SetSensitivity(kSensitivity);

   // Default gyro angle test
   // Accumulator needs a small amount of time to reset before being tested
   m_gyro->Reset();
   Wait(0.001);
   EXPECT_NEAR(0.0, m_gyro->GetAngle(), 1.0);

   // Gyro angle test
   // Make sure that the gyro doesn't get jerked when the servo goes to zero.
   m_pan->SetAngle(0.0);
   Wait(0.5);
   m_gyro->Reset();

   for (int32_t i = 0; i < 600; i++) {
     m_pan->Set(i / 1000.0);
     Wait(0.001);
   }

   double gyroAngle = m_gyro->GetAngle();

   EXPECT_NEAR(gyroAngle, kTestAngle, 10.0)
       << "Gyro measured " << gyroAngle << " degrees, servo should have turned "
       << kTestAngle << " degrees";
 }

 /**
  * Run all gyro tests in one function to make sure they are run in order.
  */
 TEST_F(TiltPanCameraTest, TestAllGyroTests) {
   DefaultGyroAngle();
   GyroAngle();
   GyroCalibratedParameters();
 }

 /**
  * Test if the accelerometer measures gravity along the correct axes when the
  * camera rotates
  */
 TEST_F(TiltPanCameraTest, SPIAccelerometer) {
   m_tilt->Set(kTiltSetpoint0);
   Wait(kTiltTime);
   EXPECT_NEAR(-1.0, m_spiAccel->GetX(), kAccelerometerTolerance);
   EXPECT_NEAR(0.0, m_spiAccel->GetY(), kAccelerometerTolerance);
   EXPECT_NEAR(0.0, m_spiAccel->GetZ(), kAccelerometerTolerance);

   m_tilt->Set(kTiltSetpoint45);
   Wait(kTiltTime);
   EXPECT_NEAR(-std::sqrt(0.5), m_spiAccel->GetX(), kAccelerometerTolerance);
   EXPECT_NEAR(0.0, m_spiAccel->GetY(), kAccelerometerTolerance);
   EXPECT_NEAR(std::sqrt(0.5), m_spiAccel->GetZ(), kAccelerometerTolerance);

   m_tilt->Set(kTiltSetpoint90);
   Wait(kTiltTime);
   EXPECT_NEAR(0.0, m_spiAccel->GetX(), kAccelerometerTolerance);
   EXPECT_NEAR(0.0, m_spiAccel->GetY(), kAccelerometerTolerance);
   EXPECT_NEAR(1.0, m_spiAccel->GetZ(), kAccelerometerTolerance);
 }
	/----------------------------------------------------------------------------/
	/* Copyright (c) 2014-2018 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 <cmath>

	#include "TestBench.h"
	#include "frc/ADXL345_SPI.h"
	#include "frc/AnalogGyro.h"
	#include "frc/Servo.h"
	#include "frc/Timer.h"
	#include "gtest/gtest.h"

	using namespace frc;

	static constexpr double kServoResetTime = 2.0;

	static constexpr double kTestAngle = 90.0;

	static constexpr double kTiltSetpoint0 = 0.22;
	static constexpr double kTiltSetpoint45 = 0.45;
	static constexpr double kTiltSetpoint90 = 0.68;
	static constexpr double kTiltTime = 1.0;
	static constexpr double kAccelerometerTolerance = 0.2;
	static constexpr double kSensitivity = 0.013;

	/**
	* A fixture for the camera with two servos and a gyro
	*/
	class TiltPanCameraTest : public testing::Test {
	protected:
	static AnalogGyro* m_gyro;
	Servo m_tilt, m_pan;
	Accelerometer* m_spiAccel;

	static void SetUpTestCase() {
	// The gyro object blocks for 5 seconds in the constructor, so only
	// construct it once for the whole test case
	m_gyro = new AnalogGyro(TestBench::kCameraGyroChannel);
	m_gyro->SetSensitivity(kSensitivity);
	}

	static void TearDownTestCase() { delete m_gyro; }

	void SetUp() override {
	m_tilt = new Servo(TestBench::kCameraTiltChannel);
	m_pan = new Servo(TestBench::kCameraPanChannel);
	m_spiAccel = new ADXL345_SPI(SPI::kOnboardCS1);

	m_tilt->Set(kTiltSetpoint45);
	m_pan->SetAngle(0.0);

	Wait(kServoResetTime);

	m_gyro->Reset();
	}

	void DefaultGyroAngle();
	void GyroAngle();
	void GyroCalibratedParameters();

	void TearDown() override {
	delete m_tilt;
	delete m_pan;
	delete m_spiAccel;
	}
	};

	AnalogGyro* TiltPanCameraTest::m_gyro = nullptr;

	/**
	* Test if the gyro angle defaults to 0 immediately after being reset.
	*/
	void TiltPanCameraTest::DefaultGyroAngle() {
	EXPECT_NEAR(0.0, m_gyro->GetAngle(), 1.0);
	}

	/**
	* Test if the servo turns 90 degrees and the gyroscope measures this angle
	* Note servo on TestBench is not the same type of servo that servo class
	* was designed for so setAngle is significantly off. This has been calibrated
	* for the servo on the rig.
	*/
	void TiltPanCameraTest::GyroAngle() {
	// Make sure that the gyro doesn't get jerked when the servo goes to zero.
	m_pan->SetAngle(0.0);
	Wait(0.5);
	m_gyro->Reset();

	for (int32_t i = 0; i < 600; i++) {
	m_pan->Set(i / 1000.0);
	Wait(0.001);
	}

	double gyroAngle = m_gyro->GetAngle();

	EXPECT_NEAR(gyroAngle, kTestAngle, 10.0)
	<< "Gyro measured " << gyroAngle << " degrees, servo should have turned "
	<< kTestAngle << " degrees";
	}

	/**
	* Gets calibrated parameters from previously calibrated gyro, allocates a new
	* gyro with the given parameters for center and offset, and re-runs tests on
	* the new gyro.
	*/
	void TiltPanCameraTest::GyroCalibratedParameters() {
	uint32_t cCenter = m_gyro->GetCenter();
	double cOffset = m_gyro->GetOffset();
	delete m_gyro;
	m_gyro = new AnalogGyro(TestBench::kCameraGyroChannel, cCenter, cOffset);
	m_gyro->SetSensitivity(kSensitivity);

	// Default gyro angle test
	// Accumulator needs a small amount of time to reset before being tested
	m_gyro->Reset();
	Wait(0.001);
	EXPECT_NEAR(0.0, m_gyro->GetAngle(), 1.0);

	// Gyro angle test
	// Make sure that the gyro doesn't get jerked when the servo goes to zero.
	m_pan->SetAngle(0.0);
	Wait(0.5);
	m_gyro->Reset();

	for (int32_t i = 0; i < 600; i++) {
	m_pan->Set(i / 1000.0);
	Wait(0.001);
	}

	double gyroAngle = m_gyro->GetAngle();

	EXPECT_NEAR(gyroAngle, kTestAngle, 10.0)
	<< "Gyro measured " << gyroAngle << " degrees, servo should have turned "
	<< kTestAngle << " degrees";
	}

	/**
	* Run all gyro tests in one function to make sure they are run in order.
	*/
	TEST_F(TiltPanCameraTest, TestAllGyroTests) {
	DefaultGyroAngle();
	GyroAngle();
	GyroCalibratedParameters();
	}

	/**
	* Test if the accelerometer measures gravity along the correct axes when the
	* camera rotates
	*/
	TEST_F(TiltPanCameraTest, SPIAccelerometer) {
	m_tilt->Set(kTiltSetpoint0);
	Wait(kTiltTime);
	EXPECT_NEAR(-1.0, m_spiAccel->GetX(), kAccelerometerTolerance);
	EXPECT_NEAR(0.0, m_spiAccel->GetY(), kAccelerometerTolerance);
	EXPECT_NEAR(0.0, m_spiAccel->GetZ(), kAccelerometerTolerance);

	m_tilt->Set(kTiltSetpoint45);
	Wait(kTiltTime);
	EXPECT_NEAR(-std::sqrt(0.5), m_spiAccel->GetX(), kAccelerometerTolerance);
	EXPECT_NEAR(0.0, m_spiAccel->GetY(), kAccelerometerTolerance);
	EXPECT_NEAR(std::sqrt(0.5), m_spiAccel->GetZ(), kAccelerometerTolerance);

	m_tilt->Set(kTiltSetpoint90);
	Wait(kTiltTime);
	EXPECT_NEAR(0.0, m_spiAccel->GetX(), kAccelerometerTolerance);
	EXPECT_NEAR(0.0, m_spiAccel->GetY(), kAccelerometerTolerance);
	EXPECT_NEAR(1.0, m_spiAccel->GetZ(), kAccelerometerTolerance);
	}