Source code for test_torque2Dipole

#
#  ISC License
#
#  Copyright (c) 2016, Autonomous Vehicle Systems Lab, University of Colorado at Boulder
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#
#   Unit Test Script
#   Module Name:        torque2Dipole
#   Author:             Henry Macanas
#   Creation Date:      06 18, 2021
#
# import packages as needed e.g. 'numpy', 'ctypes, 'math' etc.
import numpy as np
from Basilisk.architecture import bskLogging
from Basilisk.architecture import messaging  # import the message definitions
from Basilisk.fswAlgorithms import torque2Dipole  # import the module that is to be tested
# Import all of the modules that we are going to be called in this simulation
from Basilisk.utilities import SimulationBaseClass
from Basilisk.utilities import macros
from Basilisk.utilities import unitTestSupport  # general support file with common unit test functions

accuracy = 1E-12

# uncomment this line is this test is to be skipped in the global unit test run, adjust message as needed
# @pytest.mark.skipif(conditionstring)
# uncomment this line if this test has an expected failure, adjust message as needed
# @pytest.mark.xfail(conditionstring)
# provide a unique test method name, starting with test_

[docs] def test_torque2Dipole_module(): # update "module" in this function name to reflect the module name r""" **Validation Test Description** This script tests that the 3x1 Body frame dipole vector, dipole_B, is computed correctly and that the algorithm doesn't fail when the inputs are given zero values. **Description of Variables Being Tested** In this file we are checking the values of the variable: - ``dipole_B[3]`` """ # each test method requires a single assert method to be called # pass on the testPlotFixture so that the main test function may set the DataStore attributes [testResults, testMessage] = torque2DipoleModuleTestFunction() assert testResults < 1, testMessage
def torque2DipoleModuleTestFunction(): testFailCount = 0 # zero unit test result counter testMessages = [] # create empty array to store test log messages unitTaskName = "unitTask" # arbitrary name (don't change) unitProcessName = "TestProcess" # arbitrary name (don't change) bskLogging.setDefaultLogLevel(bskLogging.BSK_WARNING) # Create a sim module as an empty container unitTestSim = SimulationBaseClass.SimBaseClass() # Create test thread testProcessRate = macros.sec2nano(0.01) # update process rate update time testProc = unitTestSim.CreateNewProcess(unitProcessName) testProc.addTask(unitTestSim.CreateNewTask(unitTaskName, testProcessRate)) # Initialize module under test's config message and add module to runtime call list module = torque2Dipole.torque2Dipole() module.ModelTag = "mtbMomentumManagement" # update python name of test module unitTestSim.AddModelToTask(unitTaskName, module) # Initialize TAMSensorBodyMsg tamSensorBodyInMsgContainer = messaging.TAMSensorBodyMsgPayload() tamSensorBodyInMsgContainer.tam_B = [1E-5, 0.0, 0.0] tamSensorBodyInMsg = messaging.TAMSensorBodyMsg().write(tamSensorBodyInMsgContainer) # Initialize CmdTorqueBodyMsg tauRequestInMsgContainer = messaging.CmdTorqueBodyMsgPayload() tauRequestInMsgContainer.torqueRequestBody = [10.* 1E-3, 20. * 1E-3, 30 * 1E-3] tauRequestInMsg = messaging.CmdTorqueBodyMsg().write(tauRequestInMsgContainer) # Setup logging on the test module output message so that we get all the writes to it resultDipoleRequestOutMsg = module.dipoleRequestOutMsg.recorder() unitTestSim.AddModelToTask(unitTaskName, resultDipoleRequestOutMsg) # connect the message interfaces module.tamSensorBodyInMsg.subscribeTo(tamSensorBodyInMsg) module.tauRequestInMsg.subscribeTo(tauRequestInMsg) # Set the simulation time. unitTestSim.ConfigureStopTime(macros.sec2nano(0.0)) # seconds to stop simulation unitTestSim.InitializeSimulation() ''' TEST 1: Check that dipole_B is non-zero expected value. ''' unitTestSim.ExecuteSimulation() b = np.array(tamSensorBodyInMsgContainer.tam_B) tau = np.array(tauRequestInMsgContainer.torqueRequestBody) expectedDipole = 1 / np.dot(b, b) * np.cross(b, tau) testFailCount, testMessages = unitTestSupport.compareVector(expectedDipole, resultDipoleRequestOutMsg.dipole_B[0], accuracy, "dipole_B", testFailCount, testMessages) ''' TEST 2: Check that dipole_B is zero when tam_B is zero. ''' tamSensorBodyInMsgContainer.tam_B = [0., 0., 0.] tamSensorBodyInMsg = messaging.TAMSensorBodyMsg().write(tamSensorBodyInMsgContainer) module.tamSensorBodyInMsg.subscribeTo(tamSensorBodyInMsg) unitTestSim.InitializeSimulation() unitTestSim.ExecuteSimulation() expectedDipole = [0., 0., 0.] testFailCount, testMessages = unitTestSupport.compareVector(expectedDipole, resultDipoleRequestOutMsg.dipole_B[0], accuracy, "dipole_B", testFailCount, testMessages) ''' TEST 3: Check that dipole_B is zero when torqueRequestBody is zero. ''' tamSensorBodyInMsgContainer.tam_B = [1E-5, 0.0, 0.0] tamSensorBodyInMsg = messaging.TAMSensorBodyMsg().write(tamSensorBodyInMsgContainer) module.tamSensorBodyInMsg.subscribeTo(tamSensorBodyInMsg) tauRequestInMsgContainer.torqueRequestBody = [0., 0., 0.] tauRequestInMsg = messaging.CmdTorqueBodyMsg().write(tauRequestInMsgContainer) module.tauRequestInMsg.subscribeTo(tauRequestInMsg) unitTestSim.InitializeSimulation() unitTestSim.ExecuteSimulation() expectedDipole = [0., 0., 0.] testFailCount, testMessages = unitTestSupport.compareVector(expectedDipole, resultDipoleRequestOutMsg.dipole_B[0], accuracy, "dipole_B", testFailCount, testMessages) print("Accuracy used: " + str(accuracy)) if testFailCount == 0: print("PASSED: torque2Dipole unit test") else: print("Failed: torque2Dipole unit test") return [testFailCount, ''.join(testMessages)] # # This statement below ensures that the unitTestScript can be run as a # stand-along python script # if __name__ == "__main__": test_torque2Dipole_module()