def testBadInstantiationPrevented(self):
try:
#tried instantiating an HPD with a bad hysteretic envelope
self.badHystPeakDetector = HystereticPeakDetector(0.0, 1, -1, 0)
self.assertTrue(False)
except ValueError as error:
self.assertTrue("Can't instantiate" in str(error))
def setUp(self):
installArrayTypeEqualityFunction(self)
resetTimeSourceForTestingPurposes(global_time)
self.hpd = HystereticPeakDetector(0.0, -1.0, 1.0, 2.0)
class PeakDetectorTestCase(unittest.TestCase):
def setUp(self):
installArrayTypeEqualityFunction(self)
resetTimeSourceForTestingPurposes(global_time)
self.hpd = HystereticPeakDetector(0.0, -1.0, 1.0, 2.0)
def tearDown(self):
pass
def testBadInstantiationPrevented(self):
try:
#tried instantiating an HPD with a bad hysteretic envelope
self.badHystPeakDetector = HystereticPeakDetector(0.0,1,-1,0)
self.assertTrue(False)
except ValueError as error:
self.assertTrue("Can't instantiate" in str(error))
def testRisingEdgeDetectionFromInit(self):
risingsequence=[float(i)/10 for i in range(25)]
for element in risingsequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.RISING_EDGE)
def testFallingEdgeDetection(self):
fallingsequence=[-float(i)/10 for i in range(25)]
for element in fallingsequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.FALLING_EDGE)
def testRisingEdgeDetectionComplex(self):
#sin from 0 to 6.5 pi
sinEndsRising=[2.5*sin(math.pi*float(i)/4) for i in range(27)]
for element in sinEndsRising:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.RISING_EDGE)
def testFallingEdgeDetectionComplex(self):
#-sin from 0 to 6.5 pi
sinEndsFalling=[-2.5*sin(math.pi*float(i)/4) for i in range(27)]
for element in sinEndsFalling:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.FALLING_EDGE)
def testRisingEdgeHysteresis(self):
#tests that a falling edge which does not hit hysteretic
#limits is not detected
two_cycle_rising=[-2.5*sin(math.pi*float(i)/10 ) for i in range(16)]
short_falling_edge=[ (2.5-float(i)/20) for i in range(10)]
two_cycle_rising.extend(short_falling_edge)
for element in two_cycle_rising:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.RISING_EDGE)
def testFallingEdgeHysteresis(self):
#tests that a rising edge which does not hit hysteretic
#limits is not detected
#sine with falling edge at end
two_cycle_falling=[2.5*sin(math.pi*float(i)/10 ) for i in range(16)]
short_rising_edge=[ -(2.5-float(i)/20) for i in range(10)]
two_cycle_falling.extend(short_rising_edge)
for element in two_cycle_falling:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.FALLING_EDGE)
def testConvergingDetection(self):
converging_sequence=[(11-float(i)/4)*sin(math.pi*float(i)/10)
for i in range(41)]
for element in converging_sequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertTrue( self.hpd.isConverging() )
def testLimitCycleDetection(self):
lc_sequence=[2.5*sin(math.pi*float(i)/10)
for i in range(201)]
for element in lc_sequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertTrue( self.hpd.isLimitCycle() )
def testInstabilityDetection(self):
unstable_sequence=[float(i)/4*sin(math.pi*float(i)/10)
for i in range(41)]
for element in unstable_sequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertTrue( self.hpd.isUnstable() )
def testConvergenceDetection(self):
convergent_sequence=[(2.5-float(i)/50)*sin(math.pi*float(i)/10)
for i in range(101) ]
for element in convergent_sequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertTrue( self.hpd.hasConverged() )
def setUp(self):
installArrayTypeEqualityFunction(self)
resetTimeSourceForTestingPurposes(global_time)
self.hpd = HystereticPeakDetector(0.0, -1.0, 1.0, 2.0)
class PeakDetectorTestCase(unittest.TestCase):
def setUp(self):
installArrayTypeEqualityFunction(self)
resetTimeSourceForTestingPurposes(global_time)
self.hpd = HystereticPeakDetector(0.0, -1.0, 1.0, 2.0)
def tearDown(self):
pass
def testBadInstantiationPrevented(self):
try:
#tried instantiating an HPD with a bad hysteretic envelope
self.badHystPeakDetector = HystereticPeakDetector(0.0, 1, -1, 0)
self.assertTrue(False)
except ValueError as error:
self.assertTrue("Can't instantiate" in str(error))
def testRisingEdgeDetectionFromInit(self):
risingsequence = [float(i) / 10 for i in range(25)]
for element in risingsequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.RISING_EDGE)
def testFallingEdgeDetection(self):
fallingsequence = [-float(i) / 10 for i in range(25)]
for element in fallingsequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.FALLING_EDGE)
def testRisingEdgeDetectionComplex(self):
#sin from 0 to 6.5 pi
sinEndsRising = [2.5 * sin(math.pi * float(i) / 4) for i in range(27)]
for element in sinEndsRising:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.RISING_EDGE)
def testFallingEdgeDetectionComplex(self):
#-sin from 0 to 6.5 pi
sinEndsFalling = [
-2.5 * sin(math.pi * float(i) / 4) for i in range(27)
]
for element in sinEndsFalling:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.FALLING_EDGE)
def testRisingEdgeHysteresis(self):
#tests that a falling edge which does not hit hysteretic
#limits is not detected
two_cycle_rising = [
-2.5 * sin(math.pi * float(i) / 10) for i in range(16)
]
short_falling_edge = [(2.5 - float(i) / 20) for i in range(10)]
two_cycle_rising.extend(short_falling_edge)
for element in two_cycle_rising:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.RISING_EDGE)
def testFallingEdgeHysteresis(self):
#tests that a rising edge which does not hit hysteretic
#limits is not detected
#sine with falling edge at end
two_cycle_falling = [
2.5 * sin(math.pi * float(i) / 10) for i in range(16)
]
short_rising_edge = [-(2.5 - float(i) / 20) for i in range(10)]
two_cycle_falling.extend(short_rising_edge)
for element in two_cycle_falling:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertEquals(self.hpd.getEdgeType(), self.hpd.FALLING_EDGE)
def testConvergingDetection(self):
converging_sequence = [
(11 - float(i) / 4) * sin(math.pi * float(i) / 10)
for i in range(41)
]
for element in converging_sequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertTrue(self.hpd.isConverging())
def testLimitCycleDetection(self):
lc_sequence = [2.5 * sin(math.pi * float(i) / 10) for i in range(201)]
for element in lc_sequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertTrue(self.hpd.isLimitCycle())
def testInstabilityDetection(self):
unstable_sequence = [
float(i) / 4 * sin(math.pi * float(i) / 10) for i in range(41)
]
for element in unstable_sequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertTrue(self.hpd.isUnstable())
def testConvergenceDetection(self):
convergent_sequence = [
(2.5 - float(i) / 50) * sin(math.pi * float(i) / 10)
for i in range(101)
]
for element in convergent_sequence:
global_time.updateDelta(0.1)
self.hpd.update(element)
self.assertTrue(self.hpd.hasConverged())
