def nspinflips(name):
m = NSpinflips(name)
funcs.prepare(m)
SP_power = 20e-9
m.params['AWG_SP_amplitude'] = qt.instruments['NewfocusAOM_lt1'].power_to_voltage(
SP_power, controller='sec')
m.params['AWG_SP_duration'] = 10e-6
pts = 15
rep_factor = 200
m.params['pts'] = pts
m.params['AWG_sequence_repetitions'] = np.arange(pts) * rep_factor
m.params['reps_per_ROsequence'] = 1000
# for testing
m.params['msm1_CORPSE_pi_amp'] = 0.796974
m.params['pi2pi_mIm1_mod_frq'] = 2.828067e9 - 2.8e9 - 2.19290e6
m.params['pi2pi_mIm1_amp'] = 0.108
m.params['pi2pi_mIm1_duration'] = 396e-9
# for the autoanalysis
m.params['sweep_name'] = 'SP cycles'
m.params['sweep_pts'] = m.params['AWG_sequence_repetitions']
funcs.finish(m, upload=True, debug=False)
def run_gaussian_electron_rabi(name):
m = ShapedRabiMsmt(name) # BSM.ElectronRabiMsmt(name)
sil_name='sil9'
funcs.prepare(m, sil_name, yellow=False)
pts = 11
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
m.params['MW_pulse_multiplicities'] = np.linspace(0,10,pts).astype(int) * 1
m.params['MW_pulse_delays'] = np.ones(pts) * 100e-9
#initialisation:cfg.set(branch+
m.params['AWG_MBI_MW_pulse_mod_frq']= m.params['mIp1_mod_frq']
m.params['AWG_MBI_MW_pulse_ssbmod_frq']=m.params['AWG_MBI_MW_pulse_mod_frq']
m.params['pulse_mod_frqs'] = np.ones(pts) * m.params['mIm1_mod_frq']
m.params['pulse_amps'] = np.ones(pts)*0.07#np.linspace(0,0.12,pts)
m.params['pulse_durations']= np.ones(pts) * 395e-9
# for the autoanalysis
m.params['sweep_name'] = 'MW_pulse_multiplicities'
m.params['sweep_pts'] = m.params['MW_pulse_multiplicities']
m.PulseClass = pulselib.MW_IQmod_pulse
#pulselib.MW_IQmod_pulse
#pulselib.GaussianPulse_Envelope_IQ
#pulselib.HermitePulse_Envelope_IQ
#pulselib.ReburpPulse_Envelope_IQ
funcs.finish(m, upload=True, debug=False)
def run_gaussian_electron_rabi(name):
m = ShapedRabiMsmt(name) # BSM.ElectronRabiMsmt(name)
sil_name='sil9'
funcs.prepare(m, sil_name, yellow=False)
pts = 11
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
m.params['MW_pulse_multiplicities'] = np.linspace(0,10,pts).astype(int) * 1
m.params['MW_pulse_delays'] = np.ones(pts) * 100e-9
#initialisation:cfg.set(branch+
m.params['AWG_MBI_MW_pulse_mod_frq']= m.params['mIp1_mod_frq']
m.params['AWG_MBI_MW_pulse_ssbmod_frq']=m.params['AWG_MBI_MW_pulse_mod_frq']
m.params['pulse_mod_frqs'] = np.ones(pts) * m.params['mIm1_mod_frq']
m.params['pulse_amps'] = np.ones(pts)*0.07#np.linspace(0,0.12,pts)
m.params['pulse_durations']= np.ones(pts) * 395e-9
# for the autoanalysis
m.params['sweep_name'] = 'MW_pulse_multiplicities'
m.params['sweep_pts'] = m.params['MW_pulse_multiplicities']
m.PulseClass = pulselib.MW_IQmod_pulse
#pulselib.MW_IQmod_pulse
#pulselib.GaussianPulse_Envelope_IQ
#pulselib.HermitePulse_Envelope_IQ
#pulselib.ReburpPulse_Envelope_IQ
funcs.finish(m, upload=True, debug=False)
def calibrate_MBI_fidelity(name, params=None):
m = MBIFidelity(name)
mbi_funcs.prepare(m)
if params != None:
m.params.from_dict(params.to_dict())
pts = 4
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 40000
# overwrite this: at the moment the regular MBI program does not support that yet
# (5 nov 2013)
m.params['max_MBI_attempts'] = 100
m.params['N_randomize_duration'] = 50
m.params['Ex_N_randomize_amplitude'] = 10e-9
m.params['A_N_randomize_amplitude'] = 10e-9
m.params['repump_N_randomize_amplitude'] = 0
# MW pulses
m.params['MW_pulse_multiplicities'] = np.ones(pts).astype(int)
m.params['MW_pulse_delays'] = np.ones(pts) * 2000e-9
# TODO put this into the msmt parameters file
MIM1_AMP = 0.005254
MI0_AMP = 0.005185
MIP1_AMP = 0.005038
m.params['MW_pulse_durations'] = np.ones(
pts) * 8.3e-6 # the four readout pulse durations
m.params['MW_pulse_amps'] = np.array(
[MIM1_AMP, MI0_AMP, MIP1_AMP,
0.]) # calibrated powers for equal-length pi-pulses
# Assume for now that we're initializing into m_I = -1 (no other nuclear spins)
f_m1 = m.params['AWG_MBI_MW_pulse_mod_frq']
f_HF = m.params['N_HF_frq']
m.params['MW_pulse_mod_frqs'] = f_m1 + np.array([0, 1, 2, 5]) * f_HF
# for the autoanalysis
m.params['sweep_name'] = 'Readout transitions'
m.params['sweep_pts'] = m.params['MW_pulse_mod_frqs']
m.params['sweep_pt_names'] = [
'$m_I = -1$', '$m_I = 0$', '$m_I = +1$', 'None'
]
funcs.finish(m, debug=False)
def rr(name):
m = RR(name)
funcs.prepare(m)
pts = 1
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# RR settings
# m.params['CORPSE_pi_amp'] = 0 # 0 for RO from ms=0!
m.params['nr_of_ROsequences'] = 10
m.params['AWG_MBI_MW_pulse_ssbmod_frq'] = m.params['mI0_mod_frq'] # m.params['mIm1_mod_frq']
# for the autoanalysis
m.params['sweep_name'] = 'n/a'
m.params['sweep_pts'] = m.params['pts']
finish_RR(m, m.params['nr_of_ROsequences'], upload=True, debug=False)
def rr(name):
m = RR(name)
funcs.prepare(m)
pts = 1
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 1000
# RR settings
# m.params['CORPSE_pi_amp'] = 0 # 0 for RO from ms=0!
m.params['nr_of_ROsequences'] = 10
m.params['AWG_MBI_MW_pulse_ssbmod_frq'] = m.params['mI0_mod_frq'] # m.params['mIm1_mod_frq']
# for the autoanalysis
m.params['sweep_name'] = 'n/a'
m.params['sweep_pts'] = m.params['pts']
finish_RR(m, m.params['nr_of_ROsequences'], upload=True, 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(0.48, 0.57, 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(0.48, 0.57, 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 calibrate_MBI_fidelity(name, params=None):
m = MBIFidelity(name)
mbi_funcs.prepare(m)
if params != None:
m.params.from_dict(params.to_dict())
pts = 4
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 40000
# overwrite this: at the moment the regular MBI program does not support that yet
# (5 nov 2013)
m.params['max_MBI_attempts'] = 100
m.params['N_randomize_duration'] = 50
m.params['Ex_N_randomize_amplitude'] = 10e-9
m.params['A_N_randomize_amplitude'] = 10e-9
m.params['repump_N_randomize_amplitude'] = 0
# MW pulses
m.params['MW_pulse_multiplicities'] = np.ones(pts).astype(int)
m.params['MW_pulse_delays'] = np.ones(pts) * 2000e-9
# TODO put this into the msmt parameters file
MIM1_AMP = 0.005254
MI0_AMP = 0.005185
MIP1_AMP = 0.005038
m.params['MW_pulse_durations'] = np.ones(pts) * 8.3e-6 # the four readout pulse durations
m.params['MW_pulse_amps'] = np.array([MIM1_AMP, MI0_AMP, MIP1_AMP, 0.]) # calibrated powers for equal-length pi-pulses
# Assume for now that we're initializing into m_I = -1 (no other nuclear spins)
f_m1 = m.params['AWG_MBI_MW_pulse_mod_frq']
f_HF = m.params['N_HF_frq']
m.params['MW_pulse_mod_frqs'] = f_m1 + np.array([0,1,2,5]) * f_HF
# for the autoanalysis
m.params['sweep_name'] = 'Readout transitions'
m.params['sweep_pts'] = m.params['MW_pulse_mod_frqs']
m.params['sweep_pt_names'] = ['$m_I = -1$', '$m_I = 0$', '$m_I = +1$', 'None']
funcs.finish(m, debug=False)
def run(name):
m = pulsar_mbi_espin.ElectronRabi(name)
funcs.prepare(m)
pts = 21
m.params["pts"] = pts
m.params["reps_per_ROsequence"] = 500
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, 500e-9, pts) + 10e-9
m.params["MW_pulse_amps"] = np.ones(pts) * 0.8
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=False)
def cal_fast_rabi(name):
m = pulsar_mbi_espin.ElectronRabi('cal_fast_rabi'+name)
funcs.prepare(m, SIL_NAME)
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) * 0.4
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_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.ones(pts) * 2500e-9
m.params['MW_pulse_amps'] = np.linspace(0,0.03,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 amp (V)'
m.params['sweep_pts'] = m.params['MW_pulse_amps']
funcs.finish(m)
def run(name):
m = pulsar_mbi_espin.ElectronRamsey(name)
funcs.prepare(m, SIL_NAME)
pts = 21
m.params['pts'] = pts
m.params['reps_per_ROsequence'] = 500
m.params['MW_pulse_delays'] = np.linspace(0,3000e-9,pts)
# MW pulses
m.params['MW_pulse_durations'] = np.ones(pts) * m.params['fast_pi2_duration']
m.params['MW_pulse_amps'] = np.ones(pts) * m.params['fast_pi2_amp']
m.params['MW_pulse_mod_frqs'] = np.ones(pts) * \
m.params['AWG_MBI_MW_pulse_mod_frq']
m.params['MW_pulse_1_phases'] = np.ones(pts) * 0
m.params['MW_pulse_2_phases'] = np.ones(pts) * 0
# for the autoanalysis
m.params['sweep_name'] = 'evolution time (ns)'
m.params['sweep_pts'] = m.params['MW_pulse_delays'] /1e-9
funcs.finish(m, debug=False)
def cal_fast_pi2(name, mult=1):
m = pulsar_mbi_espin.ElectronRabi(
'cal_fast_pi_over_2_'+name+'_M=%d' % mult)
funcs.prepare(m, SIL_NAME)
# 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) * 32)
m.params['MW_pulse_amps'] = np.linspace(0.7, 0.9, 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_pi2pi_pi_len(name, mult=1):
m = pulsar_mbi_espin.ElectronRabiSplitMultElements(
'cal_pi2pi_pi_len_'+name+'_M=%d' % mult)
funcs.prepare(m, SIL_NAME)
# 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_pi2pi_pi(name, mult=1):
m = pulsar_mbi_espin.ElectronRabiSplitMultElements(
'cal_pi2pi_pi_'+name+'_M=%d' % mult)
funcs.prepare(m, SIL_NAME)
# 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'] = np.ones(pts) * 395e-9
m.params['MW_pulse_amps'] = np.linspace(0.09, 0.12, 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)
