def initServer(self):
self.start_time = time.time()
self.keep_line_center_measurements = conf.keep_line_center_measurements
self.keep_B_measurements = conf.keep_B_measurements
self.tr = Transitions_SD()
self.fitter = fitter()
self.t_measure_line_center = numpy.array([])
self.t_measure_B = numpy.array([])
self.B_field = numpy.array([])
self.line_center = numpy.array([])
self.B_fit = None
self.line_center_fit = None
self.dv = None
yield self.connect_data_vault()
yield self.setupListeners()
def initServer(self):
#Record server start time
self.start_time = time.time()
#Load default tracking durations and calculators
self.keep_line_center_measurements_local = keep_line_center_measurements_local
self.keep_line_center_measurements_global = keep_line_center_measurements_global
self.keep_B_measurements_local = keep_B_measurements_local
self.tr = Transitions_SD()
self.fitter = fitter()
#Create 8 dictionaries to store fit and nofit data for all clients
self.t_measure_line_center = dict.fromkeys(client_list,
numpy.array([]))
self.t_measure_B = dict.fromkeys(client_list, numpy.array([]))
self.t_measure_line_center_nofit = dict.fromkeys(
client_list, numpy.array([]))
self.t_measure_B_nofit = dict.fromkeys(client_list, numpy.array([]))
self.line_center = dict.fromkeys(client_list, numpy.array([]))
self.line_center_nofit = dict.fromkeys(client_list, numpy.array([]))
self.B_field = dict.fromkeys(client_list, numpy.array([]))
self.B_field_nofit = dict.fromkeys(client_list, numpy.array([]))
#Create 3 dictionaries to store fit parameters for local B fit, local line center fit and global line center fit for all clients
self.line_center_fit_local = dict.fromkeys(client_list)
self.B_fit_local = dict.fromkeys(client_list)
self.line_center_fit_global = dict.fromkeys(client_list)
#create 2 dictionaries to store global line center fit data points for all clients
self.t_measure_line_center_fit_global_data = dict.fromkeys(
client_list, numpy.array([]))
self.line_center_fit_global_data = dict.fromkeys(
client_list, numpy.array([]))
#Create a dictionary to store global fit client lists for all clients
self.global_fit_list = dict.fromkeys(client_list, [])
#Create a dictionary to decide whether to return local one or global one when somebody calls a same setting
self.bool_global = dict.fromkeys(client_list, False)
self.bool_keep_last = dict.fromkeys(client_list, False)
#Data vault
'''
self.dv = {}
yield self.connect_data_vault()
yield self.setupListeners()
'''
#Auto update everything
updater = LoopingCall(self.do_fit_global)
updater.start(auto_update_rate)
def initServer(self):
self.start_time = time.time()
self.keep_line_center_measurements = conf.keep_line_center_measurements
self.keep_B_measurements = conf.keep_B_measurements
self.tr = Transitions_SD()
self.fitter = fitter()
self.t_measure_line_center = numpy.array([])
self.t_measure_B = numpy.array([])
self.B_field = numpy.array([])
self.line_center = numpy.array([])
self.B_fit = None
self.line_center_fit = None
self.dv = None
yield self.connect_data_vault()
yield self.setupListeners()
class SDTracker(LabradServer):
"""Provides ability to track drifts of the SD line"""
name = 'SD Tracker'
onNewFit = Signal(768120, 'signal: new fit', '')
@inlineCallbacks
def initServer(self):
self.start_time = time.time()
self.keep_line_center_measurements = conf.keep_line_center_measurements
self.keep_B_measurements = conf.keep_B_measurements
self.tr = Transitions_SD()
self.fitter = fitter()
self.t_measure_line_center = numpy.array([])
self.t_measure_B = numpy.array([])
self.B_field = numpy.array([])
self.line_center = numpy.array([])
self.B_fit = None
self.line_center_fit = None
self.dv = None
yield self.connect_data_vault()
yield self.setupListeners()
@inlineCallbacks
def connect_data_vault(self):
try:
#reconnect to data vault and navigate to the directory
self.dv = yield self.client.data_vault
directory = list(conf.save_folder)
localtime = time.localtime()
dirappend = [time.strftime("%Y%b%d", localtime)]
directory.extend(dirappend)
yield self.dv.cd(directory, True)
datasetNameAppend = time.strftime("%Y%b%d_%H%M_%S", localtime)
save_name = '{0} {1}'.format(conf.dataset_name, datasetNameAppend)
self.line_center_dataset = yield self.dv.new(
save_name, [('t', 'sec')],
[('Cavity Drift', 'Line Center', 'MHz'),
('Cavity Drift', 'B Field', 'gauss')])
yield self.dv.add_parameter('start_time', time.time())
except AttributeError:
self.dv = None
@inlineCallbacks
def setupListeners(self):
yield self.client.manager.subscribe_to_named_message(
'Server Connect', conf.signal_id, True)
yield self.client.manager.subscribe_to_named_message(
'Server Disconnect', conf.signal_id + 1, True)
yield self.client.manager.addListener(
listener=self.followServerConnect, source=None, ID=conf.signal_id)
yield self.client.manager.addListener(
listener=self.followServerDisconnect,
source=None,
ID=conf.signal_id + 1)
@inlineCallbacks
def followServerConnect(self, cntx, serverName):
serverName = serverName[1]
if serverName == 'Data Vault':
yield self.connect_data_vault()
else:
yield None
@inlineCallbacks
def followServerDisconnect(self, cntx, serverName):
serverName = serverName[1]
if serverName == 'Data Vault':
self.dv = None
yield None
@setting(1, 'Get Transition Names', returns='*s')
def get_transitions(self, c):
'''Returns the names of possible transitions'''
return self.tr.transitions()
@setting(2, 'Set Measurements', lines='*(sv[MHz])', returns='')
def set_measurements(self, c, lines):
'''takes the naames and frequencies of two lines and performs tracking'''
t_measure = time.time() - self.start_time
if not len(lines) == 2:
raise Exception("Please provide measurement for two lines")
name1, f1 = lines[0]
name2, f2 = lines[1]
if name1 not in self.tr.transitions(
) or name2 not in self.tr.transitions():
raise Exception("Lines do not match known transitions")
if name1 == name2:
raise Exception("Provided Measurements must be of different lines")
B, freq = self.tr.energies_to_magnetic_field(
((name1, f1), (name2, f2)))
self.t_measure_B = numpy.append(self.t_measure_B, t_measure)
self.t_measure_line_center = numpy.append(self.t_measure_line_center,
t_measure)
self.B_field = numpy.append(self.B_field, B['gauss'])
self.line_center = numpy.append(self.line_center, freq['MHz'])
#try to save to data vault
yield self.save_result_datavault(t_measure, freq['MHz'], B['gauss'])
self.do_fit()
@inlineCallbacks
def save_result_datavault(self, t_measure, freq, b_field):
try:
yield self.dv.add((t_measure, freq, b_field))
except AttributeError:
print 'Data Vault Not Available, not saving'
yield None
@setting(4, "Get Fit Parameters", name='s', returns='*v')
def get_fit_parameters(self, c, name):
'''returns the parameters for the latest fit, name can be linecenter or bfield'''
if name == 'linecenter':
fit = self.line_center_fit
elif name == 'bfield':
fit = self.B_fit
else:
raise Exception("Provided name not found")
if fit is not None:
return fit
else:
raise Exception("Fit has not been calculated")
@setting(5, "Get Current Lines", returns='*(sv[MHz])')
def get_current_lines(self, c):
'''get the frequency of the current line specified by name. if name is not provided, get all lines'''
lines = []
current_time = time.time() - self.start_time
try:
B = self.fitter.evaluate(current_time, self.B_fit)
center = self.fitter.evaluate(current_time, self.line_center_fit)
except TypeError:
raise Exception("Fit is not available")
B = WithUnit(B, 'gauss')
center = WithUnit(center, 'MHz')
result = self.tr.get_transition_energies(B, center)
for name, freq in result:
lines.append((name, freq))
return lines
@setting(6, "Get Current Line", name='s', returns='v[MHz]')
def get_current_line(self, c, name):
lines = yield self.get_current_lines(c)
d = dict(lines)
try:
returnValue(d[name])
except KeyError:
raise Exception("Requested line not found")
@setting(10, 'Remove B Measurement', point='i')
def remove_B_measurement(self, c, point):
'''removes the point w, can also be negative to count from the end'''
try:
self.t_measure_B = numpy.delete(self.t_measure_B, point)
self.B_field = numpy.delete(self.B_field, point)
except ValueError or IndexError:
raise Exception("Point not found")
self.do_fit()
@setting(11, 'Remove Line Center Measurement', point='i')
def remove_line_center_measurement(self, c, point):
'''removes the point w, can also be negative to count from the end'''
try:
self.t_measure_line_center = numpy.delete(
self.t_measure_line_center, point)
self.line_center = numpy.delete(self.line_center, point)
except ValueError or IndexError:
raise Exception("Point not found")
self.do_fit()
@setting(8, 'Get Fit History', returns='(*(v[s]v[gauss]) *(v[s]v[MHz]))')
def get_fit_history(self, c):
history_B = []
history_line_center = []
for t, b_field in zip(self.t_measure_B, self.B_field):
history_B.append((WithUnit(t, 's'), WithUnit(b_field, 'gauss')))
for t, freq in zip(self.t_measure_line_center, self.line_center):
history_line_center.append((WithUnit(t,
's'), WithUnit(freq, 'MHz')))
return [history_B, history_line_center]
@setting(9, 'History Duration', duration='*v[s]', returns='*v[s]')
def get_history_duration(self, c, duration=None):
if duration is not None:
self.keep_B_measurements = duration[0]['s']
self.keep_line_center_measurements = duration[1]['s']
return [
WithUnit(self.keep_B_measurements, 's'),
WithUnit(self.keep_line_center_measurements, 's')
]
def do_fit(self):
self.remove_old_measurements()
if (len(self.t_measure_B) and len(self.t_measure_line_center)):
self.B_fit = self.fitter.fit(self.t_measure_B, self.B_field)
self.line_center_fit = self.fitter.fit(self.t_measure_line_center,
self.line_center)
self.onNewFit(None)
def remove_old_measurements(self):
current_time = time.time() - self.start_time
keep_line_center = numpy.where(
(current_time -
self.t_measure_line_center) < self.keep_line_center_measurements)
keep_B = numpy.where(
(current_time - self.t_measure_B) < self.keep_B_measurements)
self.t_measure_line_center = self.t_measure_line_center[
keep_line_center]
self.t_measure_B = self.t_measure_B[keep_B]
self.B_field = self.B_field[keep_B]
self.line_center = self.line_center[keep_line_center]
class SDTracker(LabradServer):
"""Provides ability to track drifts of the SD line"""
name = 'SD Tracker'
onNewFit = Signal( 768120, 'signal: new fit', '' )
@inlineCallbacks
def initServer(self):
self.start_time = time.time()
self.keep_line_center_measurements = conf.keep_line_center_measurements
self.keep_B_measurements = conf.keep_B_measurements
self.tr = Transitions_SD()
self.fitter = fitter()
self.t_measure_line_center = numpy.array([])
self.t_measure_B = numpy.array([])
self.B_field = numpy.array([])
self.line_center = numpy.array([])
self.B_fit = None
self.line_center_fit = None
self.dv = None
yield self.connect_data_vault()
yield self.setupListeners()
@inlineCallbacks
def connect_data_vault(self):
try:
#reconnect to data vault and navigate to the directory
self.dv = yield self.client.data_vault
directory = list(conf.save_folder)
localtime = time.localtime()
dirappend = [time.strftime("%Y%b%d",localtime)]
directory.extend(dirappend)
yield self.dv.cd(directory, True)
datasetNameAppend = time.strftime("%Y%b%d_%H%M_%S",localtime)
save_name = '{0} {1}'.format(conf.dataset_name, datasetNameAppend)
self.line_center_dataset = yield self.dv.new(save_name, [('t', 'sec')], [('Cavity Drift','Line Center','MHz'),('Cavity Drift','B Field','gauss')])
yield self.dv.add_parameter('start_time', time.time())
except AttributeError:
self.dv = None
@inlineCallbacks
def setupListeners(self):
yield self.client.manager.subscribe_to_named_message('Server Connect', conf.signal_id, True)
yield self.client.manager.subscribe_to_named_message('Server Disconnect', conf.signal_id+1, True)
yield self.client.manager.addListener(listener = self.followServerConnect, source = None, ID = conf.signal_id)
yield self.client.manager.addListener(listener = self.followServerDisconnect, source = None, ID = conf.signal_id+1)
@inlineCallbacks
def followServerConnect(self, cntx, serverName):
serverName = serverName[1]
if serverName == 'Data Vault':
yield self.connect_data_vault()
else:
yield None
@inlineCallbacks
def followServerDisconnect(self, cntx, serverName):
serverName = serverName[1]
if serverName == 'Data Vault':
self.dv = None
yield None
@setting(1, 'Get Transition Names', returns = '*s')
def get_transitions(self, c):
'''Returns the names of possible transitions'''
return self.tr.transitions()
@setting(2, 'Set Measurements', lines = '*(sv[MHz])', returns = '')
def set_measurements(self, c, lines):
'''takes the naames and frequencies of two lines and performs tracking'''
t_measure = time.time() - self.start_time
if not len(lines) == 2: raise Exception ("Please provide measurement for two lines")
name1,f1 = lines[0]
name2,f2 = lines[1]
if name1 not in self.tr.transitions() or name2 not in self.tr.transitions():
raise Exception("Lines do not match known transitions")
if name1 == name2: raise Exception("Provided Measurements must be of different lines")
B,freq = self.tr.energies_to_magnetic_field( ( (name1,f1),(name2,f2) ))
self.t_measure_B = numpy.append(self.t_measure_B , t_measure)
self.t_measure_line_center= numpy.append(self.t_measure_line_center, t_measure)
self.B_field = numpy.append(self.B_field , B['gauss'])
self.line_center = numpy.append(self.line_center , freq['MHz'])
#try to save to data vault
yield self.save_result_datavault(t_measure, freq['MHz'], B['gauss'])
self.do_fit()
@inlineCallbacks
def save_result_datavault(self, t_measure, freq, b_field):
try:
yield self.dv.add((t_measure, freq, b_field))
except AttributeError:
print 'Data Vault Not Available, not saving'
yield None
@setting(4, "Get Fit Parameters", name = 's', returns = '*v')
def get_fit_parameters(self, c, name):
'''returns the parameters for the latest fit, name can be linecenter or bfield'''
if name == 'linecenter':
fit = self.line_center_fit
elif name =='bfield':
fit = self.B_fit
else:
raise Exception("Provided name not found")
if fit is not None:
return fit
else:
raise Exception("Fit has not been calculated")
@setting(5, "Get Current Lines", returns = '*(sv[MHz])')
def get_current_lines(self, c):
'''get the frequency of the current line specified by name. if name is not provided, get all lines'''
lines = []
current_time = time.time() - self.start_time
try:
B = self.fitter.evaluate(current_time, self.B_fit)
center = self.fitter.evaluate(current_time, self.line_center_fit)
except TypeError:
raise Exception ("Fit is not available")
B = WithUnit(B, 'gauss')
center = WithUnit(center, 'MHz')
result = self.tr.get_transition_energies(B, center)
for name,freq in result:
lines.append((name, freq))
return lines
@setting(6, "Get Current Line", name = 's', returns = 'v[MHz]')
def get_current_line(self, c, name):
lines = yield self.get_current_lines(c)
d = dict(lines)
try:
returnValue(d[name])
except KeyError:
raise Exception ("Requested line not found")
@setting(10, 'Remove B Measurement', point = 'i')
def remove_B_measurement(self, c, point):
'''removes the point w, can also be negative to count from the end'''
try:
self.t_measure_B = numpy.delete(self.t_measure_B, point)
self.B_field = numpy.delete(self.B_field, point)
except ValueError or IndexError:
raise Exception("Point not found")
self.do_fit()
@setting(11, 'Remove Line Center Measurement', point = 'i')
def remove_line_center_measurement(self, c, point):
'''removes the point w, can also be negative to count from the end'''
try:
self.t_measure_line_center = numpy.delete(self.t_measure_line_center, point)
self.line_center = numpy.delete(self.line_center, point)
except ValueError or IndexError:
raise Exception("Point not found")
self.do_fit()
@setting(8, 'Get Fit History', returns = '(*(v[s]v[gauss]) *(v[s]v[MHz]))')
def get_fit_history(self, c):
history_B = []
history_line_center = []
for t,b_field in zip(self.t_measure_B, self.B_field):
history_B.append((WithUnit(t,'s'),WithUnit(b_field,'gauss')))
for t, freq in zip(self.t_measure_line_center, self.line_center):
history_line_center.append((WithUnit(t,'s'), WithUnit(freq, 'MHz')))
return [history_B, history_line_center]
@setting(9, 'History Duration', duration = '*v[s]', returns = '*v[s]')
def get_history_duration(self, c, duration = None):
if duration is not None:
self.keep_B_measurements = duration[0]['s']
self.keep_line_center_measurements = duration[1]['s']
return [ WithUnit(self.keep_B_measurements,'s'), WithUnit(self.keep_line_center_measurements, 's') ]
def do_fit(self):
self.remove_old_measurements()
if (len(self.t_measure_B) and len(self.t_measure_line_center)):
self.B_fit = self.fitter.fit(self.t_measure_B, self.B_field)
self.line_center_fit = self.fitter.fit(self.t_measure_line_center, self.line_center)
self.onNewFit(None)
def remove_old_measurements(self):
current_time = time.time() - self.start_time
keep_line_center = numpy.where( (current_time - self.t_measure_line_center) < self.keep_line_center_measurements)
keep_B = numpy.where( (current_time - self.t_measure_B) < self.keep_B_measurements)
self.t_measure_line_center = self.t_measure_line_center[keep_line_center]
self.t_measure_B = self.t_measure_B[keep_B]
self.B_field = self.B_field[keep_B]
self.line_center = self.line_center[keep_line_center]
class SDTrackerGlobal(LabradServer):
"""Provides ability to track drifts of the SD line"""
name = 'SD Tracker Global'
onNewFit = Signal(768120, 'signal: new fit', '')
for ite1, ite2 in enumerate(client_list):
ite1 = 768121 + ite1
ite3 = 'signal: new save {}'.format(ite2)
exe_str = "onNewSave" + ite2.replace(
' ', ''
) + " = Signal( 768121 + ite1, 'signal: new save " + ite2 + "', 's')"
exec(exe_str)
del ite1, ite2, ite3, exe_str
#@inlineCallbacks
def initServer(self):
#Record server start time
self.start_time = time.time()
#Load default tracking durations and calculators
self.keep_line_center_measurements_local = keep_line_center_measurements_local
self.keep_line_center_measurements_global = keep_line_center_measurements_global
self.keep_B_measurements_local = keep_B_measurements_local
self.tr = Transitions_SD()
self.fitter = fitter()
#Create 8 dictionaries to store fit and nofit data for all clients
self.t_measure_line_center = dict.fromkeys(client_list,
numpy.array([]))
self.t_measure_B = dict.fromkeys(client_list, numpy.array([]))
self.t_measure_line_center_nofit = dict.fromkeys(
client_list, numpy.array([]))
self.t_measure_B_nofit = dict.fromkeys(client_list, numpy.array([]))
self.line_center = dict.fromkeys(client_list, numpy.array([]))
self.line_center_nofit = dict.fromkeys(client_list, numpy.array([]))
self.B_field = dict.fromkeys(client_list, numpy.array([]))
self.B_field_nofit = dict.fromkeys(client_list, numpy.array([]))
#Create 3 dictionaries to store fit parameters for local B fit, local line center fit and global line center fit for all clients
self.line_center_fit_local = dict.fromkeys(client_list)
self.B_fit_local = dict.fromkeys(client_list)
self.line_center_fit_global = dict.fromkeys(client_list)
#create 2 dictionaries to store global line center fit data points for all clients
self.t_measure_line_center_fit_global_data = dict.fromkeys(
client_list, numpy.array([]))
self.line_center_fit_global_data = dict.fromkeys(
client_list, numpy.array([]))
#Create a dictionary to store global fit client lists for all clients
self.global_fit_list = dict.fromkeys(client_list, [])
#Create a dictionary to decide whether to return local one or global one when somebody calls a same setting
self.bool_global = dict.fromkeys(client_list, False)
self.bool_keep_last = dict.fromkeys(client_list, False)
#Data vault
'''
self.dv = {}
yield self.connect_data_vault()
yield self.setupListeners()
'''
#Auto update everything
updater = LoopingCall(self.do_fit_global)
updater.start(auto_update_rate)
'''
@inlineCallbacks
def connect_data_vault(self):
try:
#reconnect to data vault and navigate to the directory
self.dv = yield self.client.data_vault
directory = list(conf.save_folder)
localtime = time.localtime()
dirappend = [time.strftime("%Y%b%d",localtime)]
directory.extend(dirappend)
yield self.dv.cd(directory, True)
datasetNameAppend = time.strftime("%Y%b%d_%H%M_%S",localtime)
save_name = '{0} {1}'.format(conf.dataset_name, datasetNameAppend)
self.line_center_dataset = yield self.dv.new(save_name, [('t', 'sec')], [('Cavity Drift','Line Center','MHz'),('Cavity Drift','B Field','gauss')])
yield self.dv.add_parameter('start_time', time.time())
except AttributeError:
self.dv = None
@inlineCallbacks
def setupListeners(self):
yield self.client.manager.subscribe_to_named_message('Server Connect', conf.signal_id, True)
yield self.client.manager.subscribe_to_named_message('Server Disconnect', conf.signal_id+1, True)
yield self.client.manager.addListener(listener = self.followServerConnect, source = None, ID = conf.signal_id)
yield self.client.manager.addListener(listener = self.followServerDisconnect, source = None, ID = conf.signal_id+1)
@inlineCallbacks
def followServerConnect(self, cntx, serverName):
serverName = serverName[1]
if serverName == 'Data Vault':
yield self.connect_data_vault()
else:
yield None
@inlineCallbacks
def followServerDisconnect(self, cntx, serverName):
serverName = serverName[1]
if serverName == 'Data Vault':
self.dv = None
yield None
@inlineCallbacks
def save_result_datavault(self, t_measure, freq, b_field, client):
self.client_examination(client)
try:
yield self.dv.add((t_measure, freq, b_field))
except AttributeError:
print 'Data Vault Not Available, not saving'
yield None
'''
def arraydict_join(self, dic, key_list=None):
'''Create a joined array from selected keys in a dictionary'''
array = numpy.array([])
if key_list == None:
for key in dic.keys():
if type(dic[key]) == numpy.ndarray:
array = numpy.append(array, dic[key])
else:
raise Exception(
'Value type in dictionary is not numpy.ndarray.')
else:
for key in key_list:
if key not in dic.keys():
raise Exception('{0} not in {1}'.format(key, dic.keys()))
elif type(dic[key]) == numpy.ndarray:
array = numpy.append(array, dic[key])
else:
raise Exception(
'Value type in dictionary is not numpy.ndarray.')
return array
def client_examination(self, client):
'''Examine whether client is in client list which consists of all clients'''
if client not in client_list:
raise Exception("{0} is not in client list: {1}".format(
client, client_list))
else:
pass
@setting(1, 'Get Transition Names', returns='*s')
def get_transitions(self, c):
'''Returns the names of possible transitions'''
return self.tr.transitions()
@setting(2, 'Set Measurements', lines='*(sv[MHz])', client='s')
def set_measurements(self, c, lines, client):
'''
Takes the names and frequencies of two lines and performs tracking.
Input i.e.: ([("S-1/2D-1/2", U(-22.0, 'MHz')), ("S-1/2D-5/2", U(-27, 'MHz'))], 'lattice')
'''
self.client_examination(client)
t_measure = time.time() - self.start_time
if not len(lines) == 2:
raise Exception("Please provide measurement for two lines")
name1, f1 = lines[0]
name2, f2 = lines[1]
if name1 not in self.tr.transitions(
) or name2 not in self.tr.transitions():
raise Exception("Lines do not match known transitions")
if name1 == name2:
raise Exception("Provided Measurements must be of different lines")
B, freq = self.tr.energies_to_magnetic_field(
((name1, f1), (name2, f2)))
# arrays which contain the time when the measurement was taken
self.t_measure_B[client] = numpy.append(self.t_measure_B[client],
t_measure)
self.t_measure_line_center[client] = numpy.append(
self.t_measure_line_center[client], t_measure)
# arrays of B_field and line center
self.B_field[client] = numpy.append(self.B_field[client], B['gauss'])
self.line_center[client] = numpy.append(self.line_center[client],
freq['MHz'])
# try to save to data vault
# yield self.save_result_datavault(t_measure, freq['MHz'], B['gauss'])
# save the epoch time, NOT the time since the software started t_measure
#yield self.save_result_datavault(time.time(), freq['MHz'], B['gauss'], client)
self.do_fit_local(client)
exe_str = "self.onNewSave" + client.replace(
' ', '') + "('linecenter_bfield')"
exec exe_str
@setting(3,
"Set Measurements With One Line",
line='*(sv[MHz])',
client='s')
def set_measurements_with_one_line(self, c, line, client):
'''
Takes the names and frequencies of one line, and get line center from fit parameters, and performs tracking.
Input i.e.: ([("S-1/2D-1/2", U(-22.0, 'MHz')), 'lattice')
'''
self.client_examination(client)
t_measure = time.time() - self.start_time
name, f = line[0]
freq = yield self.get_current_center(c, client)
B = self.tr.energy_line_center_to_magnetic_field((name, f), freq)
self.t_measure_B[client] = numpy.append(self.t_measure_B[client],
t_measure)
self.B_field[client] = numpy.append(self.B_field[client], B['gauss'])
self.do_fit_local(client)
exe_str = "self.onNewSave" + client.replace(' ', '') + "('bfield')"
exec exe_str
@setting(4,
'Set Measurements with Bfield and Line Center',
B='*(sv[gauss])',
freq='*(sv[MHz])',
client='s')
def set_measurements_with_bfield_and_line_center(self, c, B, freq, client):
'''
takes the Bfield and the line center and sets up tracking
Input i.e.: ([('bfield', U(5.0, 'gauss'))], [('line_center', U(-22.0, 'MHz'))], 'lattice')
'''
self.client_examination(client)
t_measure = time.time() - self.start_time
B = B[0][1]
freq = freq[0][1]
# arrays which contain the time when the measurement was taken
self.t_measure_B[client] = numpy.append(self.t_measure_B[client],
t_measure)
self.t_measure_line_center[client] = numpy.append(
self.t_measure_line_center[client], t_measure)
# arrays of B_field and line center
self.B_field[client] = numpy.append(self.B_field[client], B['gauss'])
self.line_center[client] = numpy.append(self.line_center[client],
freq['MHz'])
# try to save to data vault
# yield self.save_result_datavault(t_measure, freq['MHz'], B['gauss'])
# save the epoch time, NOT the time since the software started t_measure
#yield self.save_result_datavault(time.time(), freq['MHz'], B['gauss'], client)
self.do_fit_local(client)
exe_str = "self.onNewSave" + client.replace(
' ', '') + "('linecenter_bfield')"
exec exe_str
# @setting(12, 'Set Measurement One Line', line = 'sv[MHz]', client = 's', returns = '')
# def set_measurement_one_line(self, c, line, client):
# ''' takes name and frequency of one line, and assumes the cavity position from previous data '''
# t_measure = time.time() - self.start_time
# name,f = line
# if name not in self.tr.transitions():
# raise Exception("Line does not match a known transition")
@setting(5, "Set Measurements With Bfield", B='*(sv[gauss])', client='s')
def set_measurements_with_bfield(self, c, B, client):
'''
takes the Bfield and sets up tracking
Input i.e.: ([('bfield', U(5.0, 'gauss'))], 'lattice')
'''
self.client_examination(client)
t_measure = time.time() - self.start_time
B = B[0][1]
self.t_measure_B[client] = numpy.append(self.t_measure_B[client],
t_measure)
self.B_field[client] = numpy.append(self.B_field[client], B['gauss'])
self.do_fit_local(client)
exe_str = "self.onNewSave" + client.replace(' ', '') + "('bfield')"
exec exe_str
@setting(6,
"Set Measurements With Line Center",
freq='*(sv[MHz])',
client='s')
def set_measurements_with_line_center(self, c, freq, client):
'''
takes the line center and sets up tracking
Input i.e.: ([('line_center', U(-22.0, 'MHz'))], 'lattice')
'''
self.client_examination(client)
t_measure = time.time() - self.start_time
freq = freq[0][1]
self.t_measure_line_center[client] = numpy.append(
self.t_measure_line_center[client], t_measure)
self.line_center[client] = numpy.append(self.line_center[client],
freq['MHz'])
self.do_fit_local(client)
exe_str = "self.onNewSave" + client.replace(' ', '') + "('linecenter')"
exec exe_str
@setting(7, "Get Clients", returns='*s')
def get_clients(self, c):
'''Get all registered clients'''
return client_list
@setting(8, "Bool Global", client='s', boolean='b', returns='b')
def bool_global(self, c, client, boolean=None):
'''
Set the global or local auto-return boolean to be Ture or False
Input i.e.: (True, 'lattice')
'''
if boolean is not None:
self.bool_global[client] = boolean
return self.bool_global[client]
@setting(9, "Bool Keep Last Point", client='s', boolean='b', returns='b')
def bool_keep_last_point(self, c, client, boolean=None):
'''
Set the global or local auto-return boolean to be Ture or False
Input i.e.: (True, 'lattice')
'''
if boolean is not None:
self.bool_keep_last[client] = boolean
return self.bool_keep_last[client]
@setting(10, "Get Current Time", returns='v[min]')
def get_current_time(self, c):
'''Return current time which subtracts start time'''
current_time = time.time() - self.start_time
current_time = WithUnit(current_time, 's')
return current_time.inUnitsOf('min')
@setting(11, 'Remove B Measurement', point='i', client='s')
def remove_B_measurement(self, c, point, client):
'''
Removes the point w, can also be negative to count from the end
Input i.e.: (0, 'lattice')
'''
self.client_examination(client)
try:
self.t_measure_B_nofit[client] = numpy.append(
self.t_measure_B_nofit[client],
self.t_measure_B[client][point])
self.B_field_nofit[client] = numpy.append(
self.B_field_nofit[client], self.B_field[client][point])
self.t_measure_B[client] = numpy.delete(self.t_measure_B[client],
point)
self.B_field[client] = numpy.delete(self.B_field[client], point)
except ValueError or IndexError:
raise Exception("Point not found")
self.do_fit_local(client)
@setting(12, 'Remove Line Center Measurement', point='i', client='s')
def remove_line_center_measurement(self, c, point, client):
'''
Removes the point w, can also be negative to count from the end
Input i.e.: (0, 'lattice')
'''
self.client_examination(client)
try:
self.t_measure_line_center_nofit[client] = numpy.append(
self.t_measure_line_center_nofit[client],
self.t_measure_line_center[client][point])
self.line_center_nofit[client] = numpy.append(
self.line_center_nofit[client],
self.line_center[client][point])
self.t_measure_line_center[client] = numpy.delete(
self.t_measure_line_center[client], point)
self.line_center[client] = numpy.delete(self.line_center[client],
point)
except ValueError or IndexError:
raise Exception("Point not found")
self.do_fit_local(client)
@setting(113, 'Remove All Measurements', client='s')
def remove_all_measurements(self, c, client):
'''
Removes all measured data by a specified client
Input i.e.: ('lattice')
'''
self.client_examination(client)
self.t_measure_line_center_nofit[client] = numpy.append(
self.t_measure_line_center_nofit[client],
self.t_measure_line_center[client])
self.line_center_nofit[client] = numpy.append(
self.line_center_nofit[client], self.line_center[client])
self.t_measure_B_nofit[client] = numpy.append(
self.t_measure_B_nofit[client], self.t_measure_B[client])
self.B_field_nofit[client] = numpy.append(self.B_field_nofit[client],
self.B_field[client])
self.t_measure_line_center[client] = numpy.array([])
self.line_center[client] = numpy.array([])
self.t_measure_B[client] = numpy.array([])
self.B_field[client] = numpy.array([])
self.do_fit_local(client)
@setting(14,
'Get Fit History',
client='s',
returns='(*(v[s]v[gauss]) *(v[s]v[MHz]))')
def get_fit_history(self, c, client):
'''
Get last local fit data points, including B field and line center
Input i.e.: ('lattice')
Return i.e.: ([(Value(58.58644199371338, 's'), Value(3.307939265053879, 'gauss')),
(Value(335.5155029296875, 's'), Value(3.307939265053879, 'gauss'))],
[(Value(58.58644199371338, 's'), Value(-21.578811982043565, 'MHz')),
(Value(335.5155029296875, 's'), Value(-21.578811982043565, 'MHz'))])
'''
self.client_examination(client)
history_B = []
history_line_center = []
for t, b_field in zip(self.t_measure_B[client], self.B_field[client]):
history_B.append((WithUnit(t, 's'), WithUnit(b_field, 'gauss')))
for t, freq in zip(self.t_measure_line_center[client],
self.line_center[client]):
history_line_center.append((WithUnit(t,
's'), WithUnit(freq, 'MHz')))
return [history_B, history_line_center]
@setting(15,
'Get Excluded Points',
client='s',
returns='(*(v[s]v[gauss]) *(v[s]v[MHz]))')
def get_excluded_points(self, c, client):
'''
Get excluded local fit data points, including B field and line center
Input i.e.: ('lattice')
Return i.e.: ([(Value(58.58644199371338, 's'), Value(3.307939265053879, 'gauss')),
(Value(335.5155029296875, 's'), Value(3.307939265053879, 'gauss'))],
[(Value(58.58644199371338, 's'), Value(-21.578811982043565, 'MHz')),
(Value(335.5155029296875, 's'), Value(-21.578811982043565, 'MHz'))])
'''
self.client_examination(client)
excluded_B = []
excluded_line_center = []
for t, b_field in zip(self.t_measure_B_nofit[client],
self.B_field_nofit[client]):
excluded_B.append((WithUnit(t, 's'), WithUnit(b_field, 'gauss')))
for t, freq in zip(self.t_measure_line_center_nofit[client],
self.line_center_nofit[client]):
excluded_line_center.append((WithUnit(t,
's'), WithUnit(freq, 'MHz')))
return [excluded_B, excluded_line_center]
@setting(16,
"Get Lines From Bfield and Center",
B='v[gauss]',
freq='v[MHz]',
returns='*(sv[MHz])')
def get_lines_from_bfield_and_center(self, c, B, freq):
'''
Input B field and line center, i.e.: (WithUnit(5.0, 'gauss'), WithUnit(-22.0, 'MHz'))
Returns lines and frequencies, i.e.:[('S-1/2D-5/2', Value(-35.99419287374014, 'MHz')),
('S-1/2D-3/2', Value(-27.594108162862444, 'MHz')),
('S-1/2D-1/2', Value(-19.194023451984748, 'MHz')),
('S-1/2D+1/2', Value(-10.793938741107052, 'MHz')),
('S-1/2D+3/2', Value(-2.393854030229356, 'MHz')),
('S+1/2D-3/2', Value(-41.606145969770644, 'MHz')),
('S+1/2D-1/2', Value(-33.206061258892944, 'MHz')),
('S+1/2D+1/2', Value(-24.805976548015252, 'MHz')),
('S+1/2D+3/2', Value(-16.405891837137556, 'MHz')),
('S+1/2D+5/2', Value(-8.005807126259862, 'MHz'))]
'''
all_lines = self.tr.get_transition_energies(B, freq)
return all_lines
@setting(30, "Get Fit Parameters Local", name='s', client='s', returns='?')
def get_fit_parameters_local(self, c, name, client):
'''
returns the parameters for the latest local fit, name can be linecenter or bfield
Input i.e.: ('linecenter', 'lattice') or ('bfield', 'lattice')
Returns i.e.: DimensionlessArray([ 5.21549529e-18, -2.15788120e+01]) or None
'''
self.client_examination(client)
if name == 'linecenter':
fit = self.line_center_fit_local[client]
elif name == 'bfield':
fit = self.B_fit_local[client]
else:
raise Exception("Provided name or client not found")
if fit is not None:
return fit
else:
return None
@setting(31, "Get Fit Line Center Global", client='s', returns='?')
def get_fit_line_center_global(self, c, client):
'''
returns the parameters for the latest global line center fit
Input i.e.: ('lattice')
Returns i.e.: DimensionlessArray([ 2.35051007e-03, -2.23465187e+01]) or None
'''
self.client_examination(client)
fit = self.line_center_fit_global[client]
if fit is not None:
return fit
else:
return None
@setting(32, "Get Fit Line Center", client='s', returns='?')
def get_fit_line_center(self, c, client):
'''
Automatically detect whether to return global or local line center fit parameters
Input i.e.: ('lattice')
Returns i.e.: DimensionlessArray([ 2.35051007e-03, -2.23465187e+01]) or None
'''
if self.bool_global[client]:
fit = yield self.get_fit_line_center_global(c, client)
else:
fit = yield self.get_fit_parameters_local(c, 'linecenter', client)
returnValue(fit)
@setting(40, "Get Current Lines local", client='s', returns='*(sv[MHz])')
def get_current_lines_local(self, c, client):
'''
get the frequency of all current lines calculated by local fit parmeters
Input i.e.: ('lattice')
Returns i.e.: [('S-1/2D-5/2', Value(-30.837199999999978, 'MHz')),
('S-1/2D-3/2', Value(-25.279805991021753, 'MHz')),
('S-1/2D-1/2', Value(-19.722411982043525, 'MHz')),
('S-1/2D+1/2', Value(-14.165017973065297, 'MHz')),
('S-1/2D+3/2', Value(-8.607623964087065, 'MHz')),
('S+1/2D-3/2', Value(-34.54999999999998, 'MHz')),
('S+1/2D-1/2', Value(-28.992605991021755, 'MHz')),
('S+1/2D+1/2', Value(-23.435211982043526, 'MHz')),
('S+1/2D+3/2', Value(-17.877817973065298, 'MHz')),
('S+1/2D+5/2', Value(-12.320423964087073, 'MHz'))]
'''
self.client_examination(client)
lines = []
current_time = time.time() - self.start_time
try:
B = self.fitter.evaluate(current_time, self.B_fit_local[client])
center = self.fitter.evaluate(current_time,
self.line_center_fit_local[client])
#print 'try worked'
except TypeError:
# print 'exception coming'
raise Exception("Fit is not available")
B = WithUnit(B, 'gauss')
center = WithUnit(center, 'MHz')
result = self.tr.get_transition_energies(B, center)
#print 'heres the result'
#print result
for name, freq in result:
lines.append((name, freq))
return lines
@setting(41, "Get Current Lines Global", client='s', returns='*(sv[MHz])')
def get_current_lines_global(self, c, client):
'''
get the frequency of all current lines calculated by global fit parameters
Input i.e.: ('lattice')
Returns i.e.: [('S-1/2D-5/2', Value(-30.837199999999978, 'MHz')),
('S-1/2D-3/2', Value(-25.279805991021753, 'MHz')),
('S-1/2D-1/2', Value(-19.722411982043525, 'MHz')),
('S-1/2D+1/2', Value(-14.165017973065297, 'MHz')),
('S-1/2D+3/2', Value(-8.607623964087065, 'MHz')),
('S+1/2D-3/2', Value(-34.54999999999998, 'MHz')),
('S+1/2D-1/2', Value(-28.992605991021755, 'MHz')),
('S+1/2D+1/2', Value(-23.435211982043526, 'MHz')),
('S+1/2D+3/2', Value(-17.877817973065298, 'MHz')),
('S+1/2D+5/2', Value(-12.320423964087073, 'MHz'))]
'''
self.client_examination(client)
lines = []
current_time = time.time() - self.start_time
try:
B = self.fitter.evaluate(current_time, self.B_fit_local[client])
center = self.fitter.evaluate(current_time,
self.line_center_fit_global[client])
#print 'try worked'
except TypeError:
# print 'exception coming'
raise Exception("Fit is not available")
B = WithUnit(B, 'gauss')
center = WithUnit(center, 'MHz')
result = self.tr.get_transition_energies(B, center)
#print 'heres the result'
#print result
for name, freq in result:
lines.append((name, freq))
return lines
@setting(42, "Get Current Lines", client='s', returns='*(sv[MHz])')
def get_current_lines(self, c, client):
'''
Automatically detect whether to return global lines or local lines
Input i.e.: ('lattice')
Returns i.e.: [('S-1/2D-5/2', Value(-30.837199999999978, 'MHz')),
('S-1/2D-3/2', Value(-25.279805991021753, 'MHz')),
('S-1/2D-1/2', Value(-19.722411982043525, 'MHz')),
('S-1/2D+1/2', Value(-14.165017973065297, 'MHz')),
('S-1/2D+3/2', Value(-8.607623964087065, 'MHz')),
('S+1/2D-3/2', Value(-34.54999999999998, 'MHz')),
('S+1/2D-1/2', Value(-28.992605991021755, 'MHz')),
('S+1/2D+1/2', Value(-23.435211982043526, 'MHz')),
('S+1/2D+3/2', Value(-17.877817973065298, 'MHz')),
('S+1/2D+5/2', Value(-12.320423964087073, 'MHz'))]
'''
if self.bool_global[client]:
lines = yield self.get_current_lines_global(c, client)
else:
lines = yield self.get_current_lines_local(c, client)
returnValue(lines)
@setting(50,
"Get Current Line Local",
name='s',
client='s',
returns='v[MHz]')
def get_current_line_local(self, c, name, client):
'''
Get the frequency of the current line specified by name and calculated by local fit parameters
Input i.e.: ('S-1/2D-5/2'. 'lattice')
Returns i.e.: Value(-30.837200000000003, 'MHz')
'''
self.client_examination(client)
lines = yield self.get_current_lines_local(c, client)
d = dict(lines)
## print 'done getting lines'
## print d.keys()
## temp = WithUnit(1.0,'MHz')
## yield temp
## return
## try:
## yield d[name]
## return
## except KeyError:
## raise Exception("Requested line not found")
#print d.makeReport()
try:
#return d[name]
returnValue(d[name])
except KeyError:
raise Exception("Requested line not found")
@setting(51,
"Get Current Line Global",
name='s',
client='s',
returns='v[MHz]')
def get_current_line_global(self, c, name, client):
'''
Get the frequency of the current line specified by name and calculated by global fit parameters
Input i.e.: ('S-1/2D-5/2'. 'lattice')
Returns i.e.: Value(-30.837200000000003, 'MHz')
'''
self.client_examination(client)
lines = yield self.get_current_lines_global(c, client)
d = dict(lines)
## print 'done getting lines'
## print d.keys()
## temp = WithUnit(1.0,'MHz')
## yield temp
## return
## try:
## yield d[name]
## return
## except KeyError:
## raise Exception("Requested line not found")
#print d.makeReport()
try:
#return d[name]
returnValue(d[name])
except KeyError:
raise Exception("Requested line not found")
@setting(52, "Get Current Line", name='s', client='s', returns='v[MHz]')
def get_current_line(self, c, name, client):
'''
Automatically detect whether to return global line or local line specified by name
Input i.e.: ('S-1/2D-5/2'. 'lattice')
Returns i.e.: Value(-30.837200000000003, 'MHz')
'''
if self.bool_global[client]:
line = yield self.get_current_line_global(c, name, client)
else:
line = yield self.get_current_line_local(c, name, client)
returnValue(line)
@setting(60, "Get Current B Local", client='s', returns='v[gauss]')
def get_current_b_local(self, c, client):
'''
Get current b field calculated by local fit parameters (global fit is not applicable)
Input i.e.: ('lattice')
Returns i.e.: Value(3.307939265053879, 'gauss')
'''
self.client_examination(client)
current_time = time.time() - self.start_time
try:
B = self.fitter.evaluate(current_time, self.B_fit_local[client])
B = WithUnit(B, 'gauss')
except TypeError:
# print 'exception coming'
raise Exception("Fit is not available")
return B
#returnValue(B)
@setting(70, "Get Current Center Local", client='s', returns='v[MHz]')
def get_current_center_local(self, c, client):
'''
Get current line center calculated by local fit parameters
Input i.e.: ('lattice')
Returns i.e.: Value(-21.578811982043565, 'MHz')
'''
self.client_examination(client)
current_time = time.time() - self.start_time
try:
center = self.fitter.evaluate(current_time,
self.line_center_fit_local[client])
center = WithUnit(center, 'MHz')
except TypeError:
# print 'exception coming'
raise Exception("Fit is not available")
return center
#returnValue(center)
@setting(71, "Get Current Center Global", client='s', returns='v[MHz]')
def get_current_center_global(self, c, client):
'''
Get current line center calculated by global fit parameters
Input i.e.: ('lattice')
Returns i.e.: Value(-21.578811982043565, 'MHz')
'''
self.client_examination(client)
current_time = time.time() - self.start_time
try:
center = self.fitter.evaluate(current_time,
self.line_center_fit_global[client])
center = WithUnit(center, 'MHz')
except TypeError:
# print 'exception coming'
raise Exception("Fit is not available")
return center
#returnValue(center)
@setting(72, "Get Current Center", client='s', returns='v[MHz]')
def get_current_center(self, c, client):
'''
Automatically detect whether to return global line center or local line center
Input i.e.: ('lattice')
Returns i.e.: Value(-21.578811982043565, 'MHz')
'''
if self.bool_global[client]:
center = yield self.get_current_center_global(c, client)
else:
center = yield self.get_current_center_local(c, client)
returnValue(center)
@setting(80,
'History Duration Local',
client='s',
duration='*v[s]',
returns='*v[s]')
def get_history_duration_local(self, c, client, duration=None):
'''
Get tracking durations for local B field and line center if duration == None
Input i.e.: ('lattice')
Returns i.e.: ValueArray(array([ 6000., 6000.]), 's')
Set tracking durations for local B field and line center if duration != None
Input i.e.: ('lattice', (WithUnit(7000, 's'), WithUnit(7000, 's')))
Returns i.e.: ValueArray(array([ 7000., 7000.]), 's')
'''
self.client_examination(client)
if duration is not None:
self.keep_B_measurements_local[client] = duration[0]['s']
self.keep_line_center_measurements_local[client] = duration[1]['s']
self.do_fit_local(client)
return [
WithUnit(self.keep_B_measurements_local[client], 's'),
WithUnit(self.keep_line_center_measurements_local[client], 's')
]
@setting(81,
'History Duration Global Line Center',
client='s',
duration='v[s]',
returns='v[s]')
def get_history_duration_global_line_center(self,
c,
client,
duration=None):
'''
Get tracking durations for global line center if duration == None
Input i.e.: ('lattice')
Returns i.e.: Value(6000.0, 's')
Set tracking durations for global line center if duration != None
Input i.e.: ('lattice', WithUnit(7000, 's'))
Returns i.e.: Value(7000.0, 's')
'''
self.client_examination(client)
if duration is not None:
self.keep_line_center_measurements_global[client] = duration['s']
self.do_fit_local(client)
return WithUnit(self.keep_line_center_measurements_global[client], 's')
@setting(90, 'Get Last B Field Global', returns='v')
def get_last_b_field_global(self, c):
'''
Returns the last entered global B field
Returns i.e.: 3.307939265053879
'''
B_field_global = self.arraydict_join(self.B_field)
t_measure_B_global = self.arraydict_join(self.t_measure_B)
last_index = numpy.where(
t_measure_B_global == numpy.max(t_measure_B_global))
return B_field_global[last_index]
@setting(91, 'Get Last B Field Local', client='s', returns='v')
def get_last_b_field_local(self, c, client):
'''
Returns the last entered local B field
Input i.e.: ('lattice')
Returns i.e.: 3.307939265053879
'''
self.client_examination(client)
return self.B_field[client][-1]
@setting(100, 'Get Last Line Center Global', returns='v')
def get_last_line_center_global(self, c):
'''
Returns the last entered global line center
Returns i.e.: -21.578811982043565
'''
line_center_global = self.arraydict_join(self.line_center)
t_measure_line_center_global = self.arraydict_join(
self.t_measure_line_center)
last_index = numpy.where(t_measure_line_center_global == numpy.max(
t_measure_line_center_global))
return line_center_global[last_index]
@setting(101, 'Get Last Line Center Local', client='s', returns='v')
def get_last_line_center_local(self, c, client):
'''
Returns the last entered local line center
Input i.e.: ('lattice')
Returns i.e.: -21.578811982043565
'''
self.client_examination(client)
return self.line_center[client][-1]
@setting(110, 'Get B Field Global', returns='*(s*v)')
def get_b_field_global(self, c):
'''
Returns all entered B fields
Returns i.e.: [('lattice', DimensionlessArray([ 3.30793927])),
('sqip', DimensionlessArray([], dtype=float64)),
('space time', DimensionlessArray([], dtype=float64)),
('cct', DimensionlessArray([], dtype=float64))]
'''
return self.B_field.items()
@setting(111, 'Get B Field Local', client='s', returns='*v')
def get_b_field_local(self, c, client):
'''
Returns the local B field
Input i.e.: ('lattice')
Returns i.e.: DimensionlessArray([ 3.30793927, 3.30793927])
'''
self.client_examination(client)
return self.B_field[client]
@setting(120, 'Get Line Center Global', returns='*(s*v)')
def get_line_center_global(self, c):
'''
Returns all entered line centers
Returns i.e.: [('lattice', DimensionlessArray([-21.57881198, -21.57881198])),
('sqip', DimensionlessArray([], dtype=float64)),
('space time', DimensionlessArray([], dtype=float64)),
('cct', DimensionlessArray([], dtype=float64))]
'''
return self.line_center.items()
@setting(121, 'Get Line Center Local', client='s', returns='*v')
def get_line_center_local(self, c, client):
'''
Returns the local line center
Input i.e.: ('lattice')
Returns i.e.: DimensionlessArray([-21.57881198, -21.57881198])
'''
self.client_examination(client)
return self.line_center[client]
@setting(122,
'Get Line Center Global Fit Data',
client='s',
returns='*(v[s]v[MHz])')
def get_line_center_global_fit_data(self, c, client):
'''
Returns the global fit dataset regarding to last global line center fit parameters
Input i.e.: ('lattice')
Returns i.e.: [(Value(6106.04318189621, 's'), Value(-21.578811982043565, 'MHz')),
(Value(7915.106670856476, 's'), Value(-21.578811982043565, 'MHz'))]
'''
self.client_examination(client)
history_global_line_center = []
for t, freq in zip(self.t_measure_line_center_fit_global_data[client],
self.line_center_fit_global_data[client]):
history_global_line_center.append(
(WithUnit(t, 's'), WithUnit(freq, 'MHz')))
return history_global_line_center
@setting(130, "Set Global Fit List", client='s', fit_list='*s')
def set_global_fit_list(self, c, client, fit_list):
'''
Set global line center fit client list
Input i.e.: ('lattice', ['cct', 'sqip', 'space time'])
'''
self.client_examination(client)
for key in fit_list:
if key not in client_list:
raise Exception('{0} not in client list {1}'.format(
key, client_list))
self.global_fit_list[client] = fit_list
self.do_fit_local(client)
@setting(131, "Get Global Fit List", client='s', returns='*s')
def get_global_fit_list(self, c, client):
'''
Get global line center fit client list
Input i.e.: ('lattice')
Returns i.e.: ['cct', 'sqip', 'space time']
'''
self.client_examination(client)
return self.global_fit_list[client]
def do_fit_global(self):
'''
Refresh data and fit parameters fot all clients
'''
bool_newfit = False
for client in client_list:
bool_refresh = self.remove_old_measurements(client)
if bool_refresh:
bool_newfit = True
if (len(self.t_measure_B[client])):
self.B_fit_local[client] = self.fitter.fit(
self.t_measure_B[client], self.B_field[client])
else:
self.B_fit_local[client] = None
if (len(self.t_measure_line_center[client])):
self.line_center_fit_local[client] = self.fitter.fit(
self.t_measure_line_center[client],
self.line_center[client])
else:
self.line_center_fit_local[client] = None
if (time.time() - self.start_time) > clear_all_duration:
t_measure_line_center_all = self.arraydict_join(
self.t_measure_line_center)
t_measure_B_all = self.arraydict_join(self.t_measure_B)
t_measure_all = numpy.append(t_measure_line_center_all,
t_measure_B_all)
try:
t_measure_min = t_measure_all.min()
except Exception as e:
t_measure_min = clear_all_duration
for client in client_list:
self.t_measure_line_center[
client] = self.t_measure_line_center[client] - t_measure_min
self.t_measure_B[
client] = self.t_measure_B[client] - t_measure_min
self.t_measure_line_center_nofit = dict.fromkeys(
client_list, numpy.array([]))
self.t_measure_B_nofit = dict.fromkeys(client_list,
numpy.array([]))
self.line_center_nofit = dict.fromkeys(client_list,
numpy.array([]))
self.B_field_nofit = dict.fromkeys(client_list, numpy.array([]))
self.start_time = self.start_time + t_measure_min
if bool_newfit:
for client in client_list:
line_center_global = self.arraydict_join(
self.line_center, self.global_fit_list[client])
t_measure_line_center_global = self.arraydict_join(
self.t_measure_line_center, self.global_fit_list[client])
keep_line_center = numpy.where(
(self.current_time - t_measure_line_center_global
) < self.keep_line_center_measurements_global[client])
self.line_center_fit_global_data[client] = line_center_global[
keep_line_center]
self.t_measure_line_center_fit_global_data[
client] = t_measure_line_center_global[keep_line_center]
if (len(self.t_measure_line_center_fit_global_data[client])):
self.line_center_fit_global[client] = self.fitter.fit(
self.t_measure_line_center_fit_global_data[client],
self.line_center_fit_global_data[client])
else:
self.line_center_fit_global[client] = None
self.onNewFit(None)
def do_fit_local(self, client):
'''
Refresh data points and fit parameters for a client
'''
self.client_examination(client)
self.remove_old_measurements(client)
if (len(self.t_measure_B[client])):
self.B_fit_local[client] = self.fitter.fit(
self.t_measure_B[client], self.B_field[client])
else:
self.B_fit_local[client] = None
if (len(self.t_measure_line_center[client])):
self.line_center_fit_local[client] = self.fitter.fit(
self.t_measure_line_center[client], self.line_center[client])
else:
self.line_center_fit_local[client] = None
for key in client_list:
line_center_global = self.arraydict_join(self.line_center,
self.global_fit_list[key])
t_measure_line_center_global = self.arraydict_join(
self.t_measure_line_center, self.global_fit_list[key])
keep_line_center = numpy.where(
(self.current_time - t_measure_line_center_global
) < self.keep_line_center_measurements_global[key])
self.line_center_fit_global_data[key] = line_center_global[
keep_line_center]
self.t_measure_line_center_fit_global_data[
key] = t_measure_line_center_global[keep_line_center]
if (len(self.t_measure_line_center_fit_global_data[key])):
self.line_center_fit_global[key] = self.fitter.fit(
self.t_measure_line_center_fit_global_data[key],
self.line_center_fit_global_data[key])
else:
self.line_center_fit_global[key] = None
self.onNewFit(None)
def remove_old_measurements(self, client):
'''
Remove old data points for a client. Old data points exceed local tracking durations
'''
self.client_examination(client)
self.current_time = time.time() - self.start_time
keep_line_center = numpy.where(
(self.current_time - self.t_measure_line_center[client]
) < self.keep_line_center_measurements_local[client])
keep_B = numpy.where((self.current_time - self.t_measure_B[client]
) < self.keep_B_measurements_local[client])
t_measure_line_center = self.t_measure_line_center[client][
keep_line_center]
t_measure_B = self.t_measure_B[client][keep_B]
line_center = self.line_center[client][keep_line_center]
B_field = self.B_field[client][keep_B]
if not numpy.array_equal(self.t_measure_line_center[client], []):
if numpy.array_equal(t_measure_line_center,
[]) and self.bool_keep_last[client]:
t_measure_line_center = self.t_measure_line_center[client][[
-1
]]
line_center = self.line_center[client][[-1]]
if not numpy.array_equal(self.t_measure_B[client], []):
if numpy.array_equal(t_measure_B,
[]) and self.bool_keep_last[client]:
t_measure_B = self.t_measure_B[client][[-1]]
B_field = self.B_field[client][[-1]]
bool_refresh = False
if not numpy.array_equal(self.t_measure_line_center[client],
t_measure_line_center):
bool_refresh = True
elif not numpy.array_equal(self.t_measure_B[client], t_measure_B):
bool_refresh = True
self.t_measure_line_center[client] = t_measure_line_center
self.t_measure_B[client] = t_measure_B
self.line_center[client] = line_center
self.B_field[client] = B_field
return bool_refresh
