class TestSimulatedDevice(unittest.TestCase): def setUp(self): self.front = QuantumEfficiency.IdealQE(1.1) self.back = QuantumEfficiency.ZeroQE() self.device = SimpleDevice(self.front) self.optical = SimpleOpticalParameters(0.5, 1.0) self.illumination = IlluminationParameters() self.params = SimulationParameters(self.optical, self.illumination) def test_eqes(self): compare.CompareArrays(self, self.front, self.device.front_eqe()) compare.CompareArrays(self, self.back, self.device.back_eqe()) def test_voltage(self): self.device.set_voltage(1.0) self.assertRaises(Exception, self.device.front_eqe, self.device) def test_optical_params(self): self.assertAlmostEqual(self.params.optical.front_reflectance(600), 0.5) self.assertAlmostEqual(self.params.optical.back_reflectance(600), 1.0) def test_illumination(self): self.assertTrue(self.illumination.dark) self.illumination.add_light(Spectrum.AM15G(), True) self.assertFalse(self.illumination.dark) self.assertIsNot(self.illumination.absolute_light(True), None) self.assertIs(self.illumination.absolute_light(False), None) #We should return an error if there's more than one light self.illumination.add_light(Spectrum.AM15G(), True) self.assertRaises(Exception, self.illumination.absolute_light, self.illumination, True)
def setUp(self):
self.front = QuantumEfficiency.IdealQE(1.1)
self.back = QuantumEfficiency.ZeroQE()
self.device = SimpleDevice(self.front)
self.optical = SimpleOpticalParameters(0.5, 1.0)
self.illumination = IlluminationParameters()
self.params = SimulationParameters(self.optical, self.illumination)
class TestSimulatedDevice(unittest.TestCase):
def setUp(self):
self.front = QuantumEfficiency.IdealQE(1.1)
self.back = QuantumEfficiency.ZeroQE()
self.device = SimpleDevice(self.front)
self.optical = SimpleOpticalParameters(0.5, 1.0)
self.illumination = IlluminationParameters()
self.params = SimulationParameters(self.optical, self.illumination)
def test_eqes(self):
compare.CompareArrays(self, self.front, self.device.front_eqe())
compare.CompareArrays(self, self.back, self.device.back_eqe())
def test_voltage(self):
self.device.set_voltage(1.0)
self.assertRaises(Exception, self.device.front_eqe, self.device)
def test_optical_params(self):
self.assertAlmostEqual(self.params.optical.front_reflectance(600), 0.5)
self.assertAlmostEqual(self.params.optical.back_reflectance(600), 1.0)
def test_illumination(self):
self.assertTrue(self.illumination.dark)
self.illumination.add_light(Spectrum.AM15G(), True)
self.assertFalse(self.illumination.dark)
self.assertIsNot(self.illumination.absolute_light(True), None)
self.assertIs(self.illumination.absolute_light(False), None)
#We should return an error if there's more than one light
self.illumination.add_light(Spectrum.AM15G(), True)
self.assertRaises(Exception, self.illumination.absolute_light,
self.illumination, True)
def setUp(self): self.front = QuantumEfficiency.IdealQE(1.1) self.back = QuantumEfficiency.ZeroQE() self.device = SimpleDevice(self.front) self.optical = SimpleOpticalParameters(0.5, 1.0) self.illumination = IlluminationParameters() self.params = SimulationParameters(self.optical, self.illumination)
def test_current(self):
sil = SimpleDevice.FromPC1DDirectory(
os.path.join(os.path.dirname(__file__), "data", "si_reference"))
current = sil.current()
self.assertAlmostEqual(current, 0.0335616807321)
def test_simpledevice(self):
sil = SimpleDevice.FromPC1DDirectory(
os.path.join(os.path.dirname(__file__), "data", "si_reference"))
