def CNOT_phase_check_sweep_CNOT_phase():
m = CNOTPhaseCheckSweepCNOTphase('CNOT_phase')
BSM.prepare(m)
pts = 17
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# MW pulses
m.params['CNOT_phase'] = np.linspace(0,360,pts)
# for the autoanalysis
m.params['sweep_name'] = 'first CNOT phase'
m.params['sweep_pts'] = m.params['CNOT_phase']
funcs.finish(m, debug=False, upload=True)
def CNOT_phase_check_sweep_time():
m = CNOTPhaseCheckSweepTime('CNOT_to_pi2')
BSM.prepare(m)
pts = 17
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# MW pulses
m.params['CNOT_to_pi2_time'] = np.linspace(150e-9, 250e-9, pts)
# for the autoanalysis
m.params['sweep_name'] = 'second_CNOT_to_pi2_time'
m.params['sweep_pts'] = m.params['CNOT_to_pi2_time']
funcs.finish(m, debug=False, upload=True)
def CNOT_phase_check_sweep_time():
m = CNOTPhaseCheckSweepTime('CNOT_to_pi2')
BSM.prepare(m)
pts = 17
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# MW pulses
m.params['CNOT_to_pi2_time'] = np.linspace(150e-9,250e-9,pts)
# for the autoanalysis
m.params['sweep_name'] = 'second_CNOT_to_pi2_time'
m.params['sweep_pts'] = m.params['CNOT_to_pi2_time']
funcs.finish(m, debug=False, upload=True)
def CNOT_phase_check_sweep_CNOT_phase():
m = CNOTPhaseCheckSweepCNOTphase('CNOT_phase')
BSM.prepare(m)
pts = 17
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# MW pulses
m.params['CNOT_phase'] = np.linspace(0, 360, pts)
# for the autoanalysis
m.params['sweep_name'] = 'first CNOT phase'
m.params['sweep_pts'] = m.params['CNOT_phase']
funcs.finish(m, debug=False, upload=True)
def CNOT_phase_check():
m = CNOTPhaseCheck('2_times_CNOT')
BSM.prepare(m)
pts = 17
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# MW pulses
m.params['multiplicity'] = 2 #number of CNOT pulses
m.params['analysis_phases'] = np.linspace(0, 360, pts)
# for the autoanalysis
m.params['sweep_name'] = 'second pi/2 phase'
m.params['sweep_pts'] = m.params['analysis_phases']
funcs.finish(m, debug=False, upload=True)
def CNOT_phase_check_mI0_both_pi2_phases():
m = CNOTPhaseCheckmI0BothPi2Phases('mI0_pi2_phases_sweep_both')
BSM.prepare(m)
pts = 16
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# MW pulses
m.params['analysis_phases'] = - 62 + np.linspace(0,360,pts)
m.params['prepare_phases'] = - m.params['analysis_phases']
# for the autoanalysis
m.params['sweep_name'] = 'second pi/2 phase'
m.params['sweep_pts'] = m.params['analysis_phases']
funcs.finish(m, debug=False, upload=True)
def CNOT_phase_check():
m = CNOTPhaseCheck('2_times_CNOT')
BSM.prepare(m)
pts = 17
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# MW pulses
m.params['multiplicity'] = 2 #number of CNOT pulses
m.params['analysis_phases'] = np.linspace(0,360,pts)
# for the autoanalysis
m.params['sweep_name'] = 'second pi/2 phase'
m.params['sweep_pts'] = m.params['analysis_phases']
funcs.finish(m, debug=False, upload=True)
def CNOT_phase_check_mI0_both_pi2_phases():
m = CNOTPhaseCheckmI0BothPi2Phases('mI0_pi2_phases_sweep_both')
BSM.prepare(m)
pts = 16
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# MW pulses
m.params['analysis_phases'] = -62 + np.linspace(0, 360, pts)
m.params['prepare_phases'] = -m.params['analysis_phases']
# for the autoanalysis
m.params['sweep_name'] = 'second pi/2 phase'
m.params['sweep_pts'] = m.params['analysis_phases']
funcs.finish(m, debug=False, upload=True)
def sweep_amplitude(name):
m = CORPSEPiCalibration(name)
funcs.prepare(m)
pts = 11
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# sweep params
m.params['CORPSE_pi_sweep_amps'] = np.linspace(0.6, 0.8, pts)
m.params['multiplicity'] = 11
m.params['delay_reps'] = 15
# for the autoanalysis
m.params['sweep_name'] = 'CORPSE amplitude (V)'
m.params['sweep_pts'] = m.params['CORPSE_pi_sweep_amps']
funcs.finish(m, debug=False)
def sweep_amplitude(name):
m = CORPSEPiCalibration(name)
funcs.prepare(m)
pts = 11
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# sweep params
m.params['CORPSE_pi_sweep_amps'] = np.linspace(0.6, 0.8, pts)
m.params['multiplicity'] = 11
m.params['delay_reps'] = 15
# for the autoanalysis
m.params['sweep_name'] = 'CORPSE amplitude (V)'
m.params['sweep_pts'] = m.params['CORPSE_pi_sweep_amps']
funcs.finish(m, debug=False)
def do_N_FT_Polarisation_check():
m = N_FT_Polarisation_Check('pulsed')
BSM.prepare(m,yellow=True)
#preparation line:
m.params['init_line'] = '-1'
#readout pulse line:
m.params['readout_line']='-1'
m.name=m.name+'_init_'+ m.params['init_line']+'_ro_'+m.params['readout_line']
m.params['FT_element_repetitions'] = np.array([1,1000,2000,3000,4000])
pts = len(m.params['FT_element_repetitions'])
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
m.params['sp_duration'] = 20e-6
m.params['FT_pulse_power']=100e-9
m.params['FT_pulse_amp']=\
m.A_aom.power_to_voltage(m.params['FT_pulse_power'], controller='sec')
m.params['yellow_pulse_power'] = 50e-9
m.params['yellow_pulse_amp'] =\
m.yellow_aom.power_to_voltage(m.params['yellow_pulse_power'], controller='sec')
# for the autoanalysis
m.params['sweep_name'] = 'FT_element_repetitions'
m.params['sweep_pts'] = m.params['FT_element_repetitions']
if m.params['init_line'] == '-1':
m.params['AWG_MBI_MW_pulse_mod_frq']=m.params['mIm1_mod_frq'] #ms=-1
elif m.params['init_line'] == '0':
m.params['AWG_MBI_MW_pulse_mod_frq']=m.params['mI0_mod_frq'] #ms=0
elif m.params['init_line'] == '+1':
m.params['AWG_MBI_MW_pulse_mod_frq']=m.params['mIp1_mod_frq']#ms=+1
print 'dont use this --> CORPSE is bad for +1'
else:
raise(Exception('Unknown init line' + str(m.params['init_line'])))
funcs.finish(m, debug=False, upload=True)
def do_N_FT_Polarisation_check():
m = N_FT_Polarisation_Check('pulsed')
BSM.prepare(m,yellow=True)
#preparation line:
m.params['init_line'] = '-1'
#readout pulse line:
m.params['readout_line']='-1'
m.name=m.name+'_init_'+ m.params['init_line']+'_ro_'+m.params['readout_line']
m.params['FT_element_repetitions'] = np.array([1,1000,2000,3000,4000])
pts = len(m.params['FT_element_repetitions'])
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
m.params['sp_duration'] = 20e-6
m.params['FT_pulse_power']=100e-9
m.params['FT_pulse_amp']=\
m.A_aom.power_to_voltage(m.params['FT_pulse_power'], controller='sec')
m.params['yellow_pulse_power'] = 50e-9
m.params['yellow_pulse_amp'] =\
m.yellow_aom.power_to_voltage(m.params['yellow_pulse_power'], controller='sec')
# for the autoanalysis
m.params['sweep_name'] = 'FT_element_repetitions'
m.params['sweep_pts'] = m.params['FT_element_repetitions']
if m.params['init_line'] == '-1':
m.params['AWG_MBI_MW_pulse_mod_frq']=m.params['mIm1_mod_frq'] #ms=-1
elif m.params['init_line'] == '0':
m.params['AWG_MBI_MW_pulse_mod_frq']=m.params['mI0_mod_frq'] #ms=0
elif m.params['init_line'] == '+1':
m.params['AWG_MBI_MW_pulse_mod_frq']=m.params['mIp1_mod_frq']#ms=+1
print 'dont use this --> CORPSE is bad for +1'
else:
raise(Exception('Unknown init line' + str(m.params['init_line'])))
funcs.finish(m, debug=False, upload=True)
def cal_4mhz_rabi(name):
m = pulsar_mbi_espin.ElectronRabi('cal_4mhz_rabi'+name)
funcs.prepare(m)
pts = 21
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
m.params['MW_pulse_multiplicities'] = np.ones(pts).astype(int)
m.params['MW_pulse_delays'] = np.ones(pts) * 20e-9
# MW pulses
m.params['MW_pulse_durations'] = np.linspace(0,500e-9,pts) + 5e-9
m.params['MW_pulse_amps'] = np.ones(pts) * 0.7
m.params['MW_pulse_mod_frqs'] = np.ones(pts) * \
m.params['AWG_MBI_MW_pulse_mod_frq']
# for the autoanalysis
m.params['sweep_name'] = 'MW pulse duration (ns)'
m.params['sweep_pts'] = m.params['MW_pulse_durations'] * 1e9
funcs.finish(m)
def run(name):
m = pulsar_mbi_espin.ElectronRabi(name)
funcs.prepare(m)
pts = 17
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
m.params['MW_pulse_multiplicities'] = np.ones(pts).astype(int)
m.params['MW_pulse_delays'] = np.ones(pts) * 2000e-9
# MW pulses
m.params['MW_pulse_durations'] = np.linspace(0, 1500e-9, pts) + 5e-9
m.params['MW_pulse_amps'] = np.ones(pts) * 0.166
m.params['MW_pulse_mod_frqs'] = np.ones(pts) * \
m.params['AWG_MBI_MW_pulse_mod_frq']
# for the autoanalysis
m.params['sweep_name'] = 'MW pulse duration (ns)'
m.params['sweep_pts'] = m.params['MW_pulse_durations'] * 1e9
funcs.finish(m, debug=True)
def cal_slow_pi(name):
m = pulsar_mbi_espin.ElectronRabi('cal_slow_pi_'+name)
funcs.prepare(m)
# measurement settings
pts = 11
m.params['reps_per_ROsequence'] = 500
m.params['pts'] = pts
m.params['MW_pulse_multiplicities'] = np.ones(pts).astype(int)
m.params['MW_pulse_delays'] = np.ones(pts) * 1e-9
# slow pi pulses
m.params['MW_pulse_durations'] = np.linspace(0,5e-6,pts) + 5e-9
m.params['MW_pulse_amps'] = np.ones(pts) * 0.03
m.params['MW_pulse_mod_frqs'] = np.ones(pts) * \
m.params['AWG_MBI_MW_pulse_mod_frq']
# for the autoanalysis
m.params['sweep_name'] = 'MW pulse duration (ns)'
m.params['sweep_pts'] = m.params['MW_pulse_durations'] * 1e9
funcs.finish(m)
def cal_pi2pi_pi_len(name, mult=1):
m = pulsar_mbi_espin.ElectronRabiSplitMultElements(
'cal_pi2pi_pi_len_'+name+'_M=%d' % mult)
funcs.prepare(m)
# measurement settings
pts = 11
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 500
m.params['MW_pulse_multiplicities'] = np.ones(pts).astype(int) * mult
m.params['MW_pulse_delays'] = np.ones(pts) * 15e-6
# hard pi pulses
m.params['MW_pulse_durations'] = 1e-9 * (np.linspace(-50,50,pts).astype(int) + 395)
m.params['MW_pulse_amps'] = np.ones(pts)*0.137
m.params['MW_pulse_mod_frqs'] = np.ones(pts) * \
m.params['f0']
# for the autoanalysis
m.params['sweep_name'] = 'MW pulse length (s)'
m.params['sweep_pts'] = m.params['MW_pulse_durations']
funcs.finish(m)
def cal_4mhz_pi2(name, mult=1):
m = pulsar_mbi_espin.ElectronRabi(
'cal_4MHz_pi_over_2_'+name+'_M=%d' % mult)
funcs.prepare(m)
# measurement settings
pts = 11
m.params['reps_per_ROsequence'] = 2000
m.params['pts'] = pts
m.params['MW_pulse_multiplicities'] = np.ones(pts).astype(int)
m.params['MW_pulse_delays'] = np.ones(pts) * 100e-9
# pulses
m.params['MW_pulse_durations'] = 1e-9 * (np.ones(pts) * 45)
m.params['MW_pulse_amps'] = np.linspace(0.65, 0.75, pts)
m.params['MW_pulse_mod_frqs'] = np.ones(pts) * \
m.params['AWG_MBI_MW_pulse_mod_frq']
# for the autoanalysis
m.params['sweep_name'] = 'MW pulse amplitude (V)'
m.params['sweep_pts'] = m.params['MW_pulse_amps']
funcs.finish(m)
def cal_hard_pi(name, mult=1):
m = pulsar_mbi_espin.ElectronRabiSplitMultElements(
'cal_hard_pi_'+name+'_M=%d' % mult)
funcs.prepare(m)
# measurement settings
pts = 11
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
m.params['MW_pulse_multiplicities'] = np.ones(pts).astype(int) * mult
m.params['MW_pulse_delays'] = np.ones(pts) * 15e-6
# hard pi pulses
m.params['MW_pulse_durations'] = 1e-9 * (np.ones(pts)*80)
m.params['MW_pulse_amps'] = np.linspace(0.78,0.92,pts)
m.params['MW_pulse_mod_frqs'] = np.ones(pts) * \
m.params['AWG_MBI_MW_pulse_mod_frq']
# for the autoanalysis
m.params['sweep_name'] = 'MW pulse amplitude (V)'
m.params['sweep_pts'] = m.params['MW_pulse_amps']
funcs.finish(m)