def generatePulses(frame):
# this dom is the one which should launch while its only LC partner (dom 2) is
# dead from previous launches
dom1 = OMKey(47, 1)
# this dom will be hit at all three times, first to ensure that both digitizers
# are busy and then to supply the LC high to dom1
dom2 = OMKey(47, 2)
# this dom will be pulse twice (time1 and time 2) to ensure that dom2 has LC and
# makes HLC readouts (to maximize deadtime)
dom3 = OMKey(47, 3)
#This is a IT DOM to test IT SLC
dom4 = OMKey(47, 62)
pulseWeight = 1000
time1 = 0
time2 = time1 + 6600
time3 = time2 + 8000
pulses = simclasses.I3MCPulseSeriesMap()
series1 = simclasses.I3MCPulseSeries()
series2 = simclasses.I3MCPulseSeries()
series3 = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
pulse.charge = pulseWeight
pulse.time = time1
series3.append(pulse)
series2.append(pulse)
pulse.time = time2
series3.append(pulse)
series2.append(pulse)
pulse.time = time3
series2.append(pulse)
series1.append(pulse)
pulses[dom1] = series1
pulses[dom2] = series2
pulses[dom3] = series3
pulse.charge = 5000
pulse.time = 500000
series2.append(pulse)
pulses[dom4] = series2
frame.Put("TestPulses", pulses)
def testDiscriminatorStressTest(self):
#Choosing an arbitrary DOM that we know exists in the detector configuration.
omKey = icetray.OMKey(42, 2)
geo = self.frame["I3Geometry"].omgeo
cal = self.frame["I3Calibration"].dom_cal
stat = self.frame["I3DetectorStatus"].dom_status
dom = DOMLauncher.I3InIceDOM(self.random_service, omKey)
dom.configure(cal[omKey], stat[omKey])
for n in range(0, 10):
pulses = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
dcstream = DOMLauncher.DCStream()
#print(n)
last = 0
for n in range(0, 2000):
pulse.charge = 1
pulse.time = last + np.random.uniform(31, 2000)
last = pulse.time
pulses.append(pulse)
dom.discriminator(pulses, dcstream)
#print(len(dcstream),int(n))
self.assert_(
len(dcstream) >= int(n),
"Have not missed any discriminator crossings")
dom.reset(True)
def testDiscriminatorEndurance(self):
#Choosing an arbitrary DOM that we know exists in the detector configuration.
omKey = icetray.OMKey(42, 2)
geo = self.frame["I3Geometry"].omgeo
cal = self.frame["I3Calibration"].dom_cal
stat = self.frame["I3DetectorStatus"].dom_status
dom = DOMLauncher.I3InIceDOM(self.random_service, omKey)
dom.configure(cal[omKey], stat[omKey])
for dt in np.linspace(30, 130, 100):
for n in range(1, 120):
pulses = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
dcstream = DOMLauncher.DCStream()
for n in range(0, int(n)):
pulse.charge = 3
pulse.time = n * dt
pulses.append(pulse)
dom.discriminator(pulses, dcstream)
self.assert_(
len(dcstream) >= int(n),
"Have not missed any discriminator crossings")
dom.reset(True)
def testDiscriminatorThreshold(self):
#Choosing an arbitrary DOM that we know exists in the detector configuration.
omKey = icetray.OMKey(47, 2)
geo = self.frame["I3Geometry"].omgeo
cal = self.frame["I3Calibration"].dom_cal
stat = self.frame["I3DetectorStatus"].dom_status
dom = DOMLauncher.I3InIceDOM(self.random_service, omKey)
dom.configure(cal[omKey], stat[omKey])
#Creating a sub threshold pulse.
pulses = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
pulse.charge = 0.99 * dom.discriminator_threshold_fraction
pulse.time = 100
pulses.append(pulse)
dcstream = DOMLauncher.DCStream()
dom.discriminator(pulses, dcstream)
self.assert_(
len(dcstream) == 0, "No trigger if charge is less than threshold")
#appending the pulse again so the total amplitude will be above the threshold.
pulses.append(pulse)
dom.discriminator(pulses, dcstream)
self.assert_(
len(dcstream) > 0, "Trigger if charge is greater than threshold")
def generatePulses(frame):
global n
dom1 = OMKey(47,1)
dom2 = OMKey(47,2)
dom3 = OMKey(47,15)
dom4 = OMKey(47,25)
dom5 = OMKey(47,26)
pulseWeight = 10
pulses = simclasses.I3MCPulseSeriesMap()
series = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
pulse.charge = pulseWeight
if(n==1):
time1 = 0
time2 = 29*icetray.I3Units.microsecond
else:
time1 = 2*29*icetray.I3Units.microsecond
time2 = 3*29*icetray.I3Units.microsecond
series2 = simclasses.I3MCPulseSeries()
series3 = simclasses.I3MCPulseSeries()
pulse.time = time1
series.append(pulse)
pulse.time = time2
series.append(pulse)
pulses[dom1]=series
pulses[dom2]=series
pulses[dom3]=series
if(n == 1):
pulses[dom4]=series
else:
pulse.time = 29*icetray.I3Units.microsecond+200
series = simclasses.I3MCPulseSeries()
series.append(pulse)
pulses[dom5]=series
frame.Put("TestPulses",pulses)
def dom_simulation(frame, time_shift=10, nhits=n_hits):
global hit_times
random_service = phys_services.I3GSLRandomService(2)
geo = frame["I3Geometry"].omgeo
cal = frame["I3Calibration"].dom_cal
stat = frame["I3DetectorStatus"].dom_status
#DOMLauncher.I3DOM.merge_pulses = True
#DOMLauncher.I3DOM.use_tabulation(True)
omKey1 = icetray.OMKey(47, 2)
dom1 = DOMLauncher.I3InIceDOM(random_service, omKey1)
dom1.configure(cal[omKey1], stat[omKey1])
omKey2 = icetray.OMKey(47, 3)
dom2 = DOMLauncher.I3InIceDOM(random_service, omKey2)
dom2.configure(cal[omKey2], stat[omKey2])
dom1.rapcal_time_shift = 0
dom2.rapcal_time_shift = time_shift
#making the doms neigbors
dom2.get_neighbors().append(dom1)
dom1.get_neighbors().append(dom2)
pulses = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
pulse.charge = 1
pulse.time = 0
for i in range(nhits):
pulses.append(pulse)
hit_times += [pulse.time]
pulse.time += 29e3
triggers = DOMLauncher.DCStream()
print("simulating discriminator")
dom1.discriminator(pulses, triggers)
dom2.discriminator(pulses, triggers)
triggers = sorted(triggers, key=lambda t: t.time)
i = 0
for trigg in triggers:
if (i % 100 == 0):
print(trigg.DOM, trigg.time)
i += 1
if (trigg.DOM == omKey1):
dom1.add_trigger(trigg)
elif (trigg.DOM == omKey2):
dom2.add_trigger(trigg)
print("ending simulation")
dom1.trigger_launch(False)
dom2.trigger_launch(False)
launch_map = dataclasses.I3DOMLaunchSeriesMap()
launch_map[dom1.get_omkey()] = dom1.get_domlaunches()
launch_map[dom2.get_omkey()] = dom2.get_domlaunches()
frame["InIceRawData"] = launch_map
def testDiscriminatorFindStressTest(self):
#Choosing an arbitrary DOM that we know exists in the detector configuration.
omKey = icetray.OMKey(42, 2)
geo = self.frame["I3Geometry"].omgeo
cal = self.frame["I3Calibration"].dom_cal
stat = self.frame["I3DetectorStatus"].dom_status
dom = DOMLauncher.I3InIceDOM(self.random_service, omKey)
dom.configure(cal[omKey], stat[omKey])
for n in range(0, 10):
dcstream = DOMLauncher.DCStream()
pulses = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
last = 0
seeds = list()
for s in range(0, 5000):
seed = last + np.random.uniform(10000, 12000)
seeds.append(seed)
last = seed
pulse_times = np.random.normal(seed, 1.,
10) #np.random.poisson(10))
pulse_times = sorted(pulse_times)
for pulse_time in pulse_times:
pulse.charge = 2
pulse.time = pulse_time
#last = pulse.time
pulses.append(pulse)
dom.discriminator(pulses, dcstream)
notfound = 0
#print(len(dcstream),int(5000))
index = 0
foundAll = True
for seed in seeds:
for i in range(index, len(dcstream)):
tr = dcstream[i]
index = i
if (np.abs(seed - tr.time) < 400):
break
elif ((tr.time - seed) > 400):
notfound += 1
foundAll = False
break
self.assert_(foundAll,
"Missed %d discriminator crossings" % notfound)
def testSLC(self):
random_service = phys_services.I3GSLRandomService(1337)
key = OMKey(40, 40)
cal = self.frame["I3Calibration"].dom_cal
stat = self.frame["I3DetectorStatus"].dom_status
for charge in range(1, 160):
charge = charge / 2.
for i in range(0, 30):
dom = DOMLauncher.I3InIceDOM(random_service, key)
dom.configure(cal[key], stat[key])
pulses = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
pulse.charge = charge
pulse.time = 0
pulses.append(pulse)
dcstream = DOMLauncher.DCStream()
dom.discriminator(pulses, dcstream)
dcstream = sorted(dcstream, key=lambda t: t.time)
for trigger in dcstream:
dom.add_trigger(trigger)
dom.trigger_launch(True)
launches = dom.get_domlaunches()
for launch in launches:
self.assert_(launch.lc_bit == False,
"All launches should be SLC")
global nLaunches
nLaunches += 1
stamp = launch.raw_charge_stamp
any_big = False
all_even = True
for sample in stamp:
if sample >= 512:
any_big = True
if sample % 2 == 1:
all_even = False
if (any_big):
global nBig
nBig += 1
if any_big and not all_even:
print("Bad SLC readout:", stamp)
self.assert_(
not any_big or (any_big and all_even),
"All samples must be small, or all must be even")
def testTiming(frame):
global random_service
#Choosing an arbitrary DOM that we know exists in the detector configuration.
omKey = icetray.OMKey(42, 2)
#geo = self.frame["I3Geometry"].omgeo
cal = frame["I3Calibration"].dom_cal
stat = frame["I3DetectorStatus"].dom_status
dom = DOMLauncher.I3InIceDOM(random_service, omKey)
dom.configure(cal[omKey], stat[omKey])
import time
#
pulses = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
print("Testing pulses densly distributed pulses")
N = 2000
for n in range(0, N):
pulse.charge = 3
pulse.time = n * 20
pulses.append(pulse)
tstream = DOMLauncher.DCStream()
t1_st = time.clock() #stopwatch.Timer()
dom.discriminator(pulses, tstream)
t1_end = time.clock()
print("Discriminator1 elapsed time: %f, and found DCs: %d" %
((t1_end - t1_st), len(tstream)))
print("Testing pulses far apart")
pulses = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
N = 2000
for n in range(0, N):
pulse.charge = 3
pulse.time = n * 29000
pulses.append(pulse)
tstream = DOMLauncher.DCStream()
t1_st = time.clock() #stopwatch.Timer()
dom.discriminator(pulses, tstream)
t1_end = time.clock()
print("Discriminator1 elapsed time: %f, and found DCs: %d" %
((t1_end - t1_st), len(tstream)))
print("Testing random pulses pulse distribution")
pulses = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
last_t = 0
N = 2000
for n in range(0, N):
pulse.charge = 3
pulse.time = last_t + np.random.uniform(10, 29000)
last_t = pulse.time
pulses.append(pulse)
tstream = DOMLauncher.DCStream()
t1_st = time.clock() #stopwatch.Timer()
dom.discriminator(pulses, tstream)
t1_end = time.clock()
print("Discriminator1 elapsed time: %f, and found DCs: %d" %
((t1_end - t1_st), len(tstream)))
def testSLC(self):
geo = self.frame["I3Geometry"].omgeo
cal = self.frame["I3Calibration"].dom_cal
stat = self.frame["I3DetectorStatus"].dom_status
omKey1 = icetray.OMKey(47, 2)
dom1 = DOMLauncher.I3InIceDOM(self.random_service, omKey1)
dom1.configure(cal[omKey1], stat[omKey1])
omKey2 = icetray.OMKey(47, 3)
dom2 = DOMLauncher.I3InIceDOM(self.random_service, omKey2)
dom2.configure(cal[omKey2], stat[omKey2])
#making the doms neigbors
dom2.get_neighbors().append(dom1)
dom1.get_neighbors().append(dom2)
pulses1 = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
pulse.charge = 1
pulse.time = 0
pulses1.append(pulse)
pulses2 = simclasses.I3MCPulseSeries()
pulse.time = 1025
pulses2.append(pulse)
dcstream = DOMLauncher.DCStream()
dom1.discriminator(pulses1, dcstream)
dom2.discriminator(pulses2, dcstream)
dcstream = sorted(dcstream, key=lambda t: t.time)
for trigg in dcstream:
#print(trigg.DOM, trigg.time)
if (trigg.DOM == omKey1):
dom1.add_trigger(trigg)
elif (trigg.DOM == omKey2):
dom2.add_trigger(trigg)
dom1.trigger_launch(True)
dom2.trigger_launch(True)
launches1 = dom1.get_domlaunches()
launches2 = dom2.get_domlaunches()
self.assert_(
len(launches1) == 1, "First frame: DOM 1 produced one launch.")
self.assert_(
len(launches2) == 1, "First frame: DOM 2 produced one launch.")
self.assert_(
launches1[0].lc_bit == False and launches2[0].lc_bit == False,
"First frame: Launches do not have LC.")
# Simulating that we are going to the next frame and thus reset the DOMObjects.
dom1.reset(True)
dom2.reset(True)
# Now we resimulate the same event and should get the same result back if the reset was
# correct.
dcstream = DOMLauncher.DCStream()
dom1.discriminator(pulses1, dcstream)
dom2.discriminator(pulses2, dcstream)
dcstream = sorted(dcstream, key=lambda t: t.time)
for trigg in dcstream:
if (trigg.DOM == omKey1):
dom1.add_trigger(trigg)
elif (trigg.DOM == omKey2):
dom2.add_trigger(trigg)
dom1.trigger_launch(True)
dom2.trigger_launch(True)
launches1 = dom1.get_domlaunches()
launches2 = dom2.get_domlaunches()
self.assert_(
len(launches1) == 1, "Second frame: DOM 1 produced one launch.")
self.assert_(
len(launches2) == 1, "Second frame: DOM 2 produced one launch.")
self.assert_(
launches1[0].lc_bit == False and launches2[0].lc_bit == False,
"Second frame: Launches do not have LC.")
# Simulating once more. This time we will not force the DOMs to launch at the
# end of the frame.
dom1.reset(True)
dom2.reset(True)
dcstream = DOMLauncher.DCStream()
dom1.discriminator(pulses1, dcstream)
dom2.discriminator(pulses2, dcstream)
dcstream = sorted(dcstream, key=lambda t: t.time)
for trigg in dcstream:
if (trigg.DOM == omKey1):
dom1.add_trigger(trigg)
elif (trigg.DOM == omKey2):
dom2.add_trigger(trigg)
#Testing the option to not force launches at the end of the frame.
#This option is used in Multi Frame Event mode.
dom1.trigger_launch(False)
dom2.trigger_launch(False)
launches1 = dom1.get_domlaunches()
launches2 = dom2.get_domlaunches()
self.assert_(
len(launches1) == 1, "Second frame: DOM 1 produced one launch.")
self.assert_(
len(launches2) == 0,
"Second frame: DOM 2 did not produce a launch.")
self.assert_(launches1[0].lc_bit == False,
"Third frame: Launch do not have LC.")
def testHLC(self):
geo = self.frame["I3Geometry"].omgeo
cal = self.frame["I3Calibration"].dom_cal
stat = self.frame["I3DetectorStatus"].dom_status
omKey1 = icetray.OMKey(47, 2)
dom1 = DOMLauncher.I3InIceDOM(self.random_service, omKey1)
dom1.configure(cal[omKey1], stat[omKey1])
omKey2 = icetray.OMKey(47, 3)
dom2 = DOMLauncher.I3InIceDOM(self.random_service, omKey2)
dom2.configure(cal[omKey2], stat[omKey2])
#making the doms neigbors
dom2.get_neighbors().append(dom1)
dom1.get_neighbors().append(dom2)
pulses1 = simclasses.I3MCPulseSeries()
pulse = simclasses.I3MCPulse()
pulse.charge = 1
pulse.time = 100
pulses1.append(pulse)
pulse.time = 6800
pulses1.append(pulse)
pulse.time = 7850
pulses1.append(pulse)
pulse.time = 8300
pulses1.append(pulse)
pulse.time = 8500
pulses1.append(pulse)
pulses2 = simclasses.I3MCPulseSeries()
pulse.time = 500
pulses2.append(pulse)
dcstream = DOMLauncher.DCStream()
dom1.discriminator(pulses1, dcstream)
dom2.discriminator(pulses2, dcstream)
dcstream = sorted(dcstream, key=lambda t: t.time)
for trigg in dcstream:
if (trigg.DOM == omKey1):
dom1.add_trigger(trigg)
elif (trigg.DOM == omKey2):
dom2.add_trigger(trigg)
dom1.trigger_launch(True)
dom2.trigger_launch(True)
launches1 = dom1.get_domlaunches()
launches2 = dom2.get_domlaunches()
self.assert_(len(launches1) > 0, "DOM 1 produced launch.")
self.assert_(len(launches2) > 0, "DOM 2 produced launch.")
self.assert_(
launches1[0].lc_bit == True and launches2[0].lc_bit == True,
"First pair of launches have LC.")
for launch in launches1:
self.assert_(launch.time < 7000,
"No launch during launch decision deadtime.")
def TestSetup(frame, add_empty_trigger=False, add_mchits=True):
p = dataclasses.I3Particle()
p.time = TIME
frame["MCPrimary"] = p
mctree = dataclasses.I3MCTree()
mctree.add_primary(p)
frame["MCTree"] = mctree
# I3MMCTrack
mmctrack = simclasses.I3MMCTrack()
mmctrack.SetParticle(p)
mmctrack.ti = TIME
mmctrack.tc = TIME
mmctrack.tf = TIME
mmctracklist = simclasses.I3MMCTrackList()
mmctracklist.append(mmctrack)
frame["MMCTracks"] = mmctracklist
# I3TriggerHierarchy
t = dataclasses.I3Trigger()
t.time = TIME
t.fired = True
trigger_h = dataclasses.I3TriggerHierarchy()
if not add_empty_trigger:
trigger_h.insert(t)
frame["Trigger"] = trigger_h
# I3VectorI3Trigger
t1 = dataclasses.I3Trigger()
t1.time = TIME
t1.fired = True
trigger_v = dataclasses.I3VectorI3Trigger()
trigger_v.append(t1)
frame["TriggerVector"] = trigger_v
# I3FlasherInfoVector
fi = dataclasses.I3FlasherInfo()
fi.flash_time = TIME
fi_v = dataclasses.I3FlasherInfoVect()
fi_v.append(fi)
frame["FlasherInfos"] = fi_v
# I3DOMLaunchSeriesMap
d = dataclasses.I3DOMLaunch()
d.time = TIME
launchseries = dataclasses.I3DOMLaunchSeries()
launchseries.append(d)
launchmap = dataclasses.I3DOMLaunchSeriesMap()
launchmap[icetray.OMKey(21, 30)] = launchseries
frame["DOMLaunchMap"] = launchmap
# I3MCHit
mchit = dataclasses.I3MCHit()
mchit.time = TIME
mchitseries = dataclasses.I3MCHitSeries()
mchitseries.append(mchit)
mchitmap = dataclasses.I3MCHitSeriesMap()
mchitmap[icetray.OMKey(21, 30)] = mchitseries
if add_mchits:
frame["MCHitMap"] = mchitmap
# I3MCPE
mcpe = simclasses.I3MCPE()
mcpe.time = TIME
mcpeseries = simclasses.I3MCPESeries()
mcpeseries.append(mcpe)
mcpemap = simclasses.I3MCPESeriesMap()
mcpemap[icetray.OMKey(21, 30)] = mcpeseries
frame["MCPEMap"] = mcpemap
# I3MCPulse
mcpulse = simclasses.I3MCPulse()
mcpulse.time = TIME
mcpulseseries = simclasses.I3MCPulseSeries()
mcpulseseries.append(mcpulse)
mcpulsemap = simclasses.I3MCPulseSeriesMap()
mcpulsemap[icetray.OMKey(21, 30)] = mcpulseseries
frame["MCPulseMap"] = mcpulsemap
# I3Double
sometime = dataclasses.I3Double(TIME)
frame["SomeTime"] = sometime
nottime = dataclasses.I3Double(TIME)
frame["NotTime"] = nottime
