コード例 #1
0
def generate_xy8_qdyne(self,
                       name='XY8_Qdyne',
                       rabi_period=1.0e-8,
                       mw_freq=2870.0e6,
                       mw_amp=0.5,
                       tau=0.5e-6,
                       xy8_order=4,
                       frequency=1.0e6,
                       mw_channel='a_ch1',
                       laser_length=3.0e-7,
                       channel_amp=1.0,
                       delay_length=0.7e-6,
                       wait_time=1.0e-6,
                       seq_trig_channel='d_ch1',
                       gate_count_channel=''):
    """
    """

    # pre-computations

    period = 1 / frequency

    rabi_period = self._adjust_to_samplingrate(rabi_period, 4)
    tau = self._adjust_to_samplingrate(tau, 2)
    laser_length = self._adjust_to_samplingrate(laser_length, 1)
    delay_length = self._adjust_to_samplingrate(delay_length, 1)

    #trigger + 8*N tau + 2*pi/2 pulse + 2*tauhalf_excess + laser_length + aom_delay + wait_time
    sequence_length = 20.0e-9 + 8 * xy8_order * tau + rabi_period / 2 + laser_length + delay_length + wait_time
    if (sequence_length % period) == 0:
        extra_time = 0
    else:
        extra_time = period - (sequence_length % period)
    extra_time = self._adjust_to_samplingrate(extra_time, 1)

    # Sanity checks
    if gate_count_channel == '':
        gate_count_channel = None
    if seq_trig_channel == '':
        seq_trig_channel = None
    err_code = self._do_channel_sanity_checks(
        mw_channel=mw_channel,
        gate_count_channel=gate_count_channel,
        seq_trig_channel=seq_trig_channel)
    if err_code != 0:
        return

    # calculate "real" start length of the waiting times (tau and tauhalf)
    real_start_tau = tau - rabi_period / 2
    real_start_tauhalf = tau / 2 - rabi_period / 4
    if real_start_tau < 0.0 or real_start_tauhalf < 0.0:
        self.log.error(
            'XY8_Qdyne generation failed! Rabi period of {0:.3e} s is too long for start tau '
            'of {1:.3e} s.'.format(rabi_period, tau))
        return

    # get waiting element
    waiting_element = self._get_idle_element(wait_time + extra_time, 0.0,
                                             False)
    # get laser and delay element
    laser_element, delay_element = self._get_laser_element(
        laser_length, 0.0, False, delay_length, channel_amp,
        gate_count_channel)
    # get pihalf element
    pihalf_element = self._get_mw_element(rabi_period / 4.0, 0.0, mw_channel,
                                          False, mw_amp, mw_freq, 0.0)
    # get -x pihalf (3pihalf) element
    pi3half_element = self._get_mw_element(rabi_period / 4.0, 0.0, mw_channel,
                                           False, mw_amp, mw_freq, 180.)
    # get pi elements
    pix_element = self._get_mw_element(rabi_period / 2.0, 0.0, mw_channel,
                                       False, mw_amp, mw_freq, 0.0)
    piy_element = self._get_mw_element(rabi_period / 2.0, 0.0, mw_channel,
                                       False, mw_amp, mw_freq, 90.0)
    # get tauhalf element
    tauhalf_element = self._get_idle_element(real_start_tauhalf, 0, False)
    # get tau element
    tau_element = self._get_idle_element(real_start_tau, 0, False)

    if seq_trig_channel is not None:
        # get sequence trigger element
        seqtrig_element = self._get_trigger_element(20.0e-9,
                                                    0.0,
                                                    seq_trig_channel,
                                                    amp=channel_amp)
        # Create its own block out of the element
        seq_block = PulseBlock('seq_trigger', [seqtrig_element])
        # save block
        self.save_block('seq_trigger', seq_block)

    # create XY8-N_qdyne block element list
    elem_list = []

    elem_list.append(laser_element)
    elem_list.append(delay_element)
    elem_list.append(waiting_element)

    # actual Qdyne XY8 sequence
    elem_list.append(pihalf_element)
    elem_list.append(tauhalf_element)

    for n in range(xy8_order):

        elem_list.append(pix_element)
        elem_list.append(tau_element)
        elem_list.append(piy_element)
        elem_list.append(tau_element)
        elem_list.append(pix_element)
        elem_list.append(tau_element)
        elem_list.append(piy_element)
        elem_list.append(tau_element)
        elem_list.append(piy_element)
        elem_list.append(tau_element)
        elem_list.append(pix_element)
        elem_list.append(tau_element)
        elem_list.append(piy_element)
        elem_list.append(tau_element)
        elem_list.append(pix_element)
        if n != xy8_order - 1:
            elem_list.append(tau_element)
    elem_list.append(tauhalf_element)
    elem_list.append(pi3half_element)

    # create XY8-N block object
    block = PulseBlock(name, elem_list)
    self.save_block(name, block)

    # create block list and ensemble object
    block_list = [(block, 0)]
    if seq_trig_channel is not None:
        block_list.append((seq_block, 0))

    # create ensemble out of the block(s)
    block_ensemble = PulseBlockEnsemble(name=name,
                                        block_list=block_list,
                                        rotating_frame=True)
    # add metadata to invoke settings later on
    block_ensemble.sample_rate = self.sample_rate
    block_ensemble.activation_config = self.activation_config
    block_ensemble.amplitude_dict = self.amplitude_dict
    block_ensemble.laser_channel = self.laser_channel
    block_ensemble.alternating = False
    block_ensemble.laser_ignore_list = []
    # save ensemble
    self.save_ensemble(name, block_ensemble)
    return block_ensemble
コード例 #2
0
def generate_cpmg_nsweep(self,
                         name='CPMG_Nsweep',
                         rabi_period=1.0e-8,
                         mw_freq=2870.0e6,
                         mw_amp=0.1,
                         tau=0.5e-6,
                         start_n=1,
                         incr_n=1,
                         num_of_points=50,
                         mw_channel='a_ch1',
                         laser_length=3.0e-6,
                         channel_amp=1.0,
                         delay_length=0.7e-6,
                         wait_time=1.0e-6,
                         seq_trig_channel='',
                         gate_count_channel='',
                         alternating=True):
    """

    """
    # Sanity checks
    if gate_count_channel == '':
        gate_count_channel = None
    if seq_trig_channel == '':
        seq_trig_channel = None
    err_code = self._do_channel_sanity_checks(
        mw_channel=mw_channel,
        gate_count_channel=gate_count_channel,
        seq_trig_channel=seq_trig_channel)
    if err_code != 0:
        return
    # get pulse number array for measurement ticks
    n_array = start_n + np.arange(num_of_points) * incr_n
    n_array.astype(int)
    # calculate "real" start length of the waiting times (tau and tauhalf)
    real_tau = tau - rabi_period / 2
    real_tauhalf = tau / 2 - 3 * rabi_period / 8
    if real_tau < 0.0 or real_tauhalf < 0.0:
        self.log.error(
            'CPMG-N-sweep generation failed! Rabi period of {0:.3e} s is too long for start tau '
            'of {1:.3e} s.'.format(rabi_period, tau))
        return

    # get waiting element
    waiting_element = self._get_idle_element(wait_time, 0.0, False)
    # get laser and delay element
    laser_element, delay_element = self._get_laser_element(
        laser_length, 0.0, False, delay_length, channel_amp,
        gate_count_channel)
    # get pihalf element
    pihalf_element = self._get_mw_element(rabi_period / 4, 0.0, mw_channel,
                                          False, mw_amp, mw_freq, 0.0)
    # get -x pihalf (3pihalf) element
    pi3half_element = self._get_mw_element(rabi_period / 4, 0.0, mw_channel,
                                           False, mw_amp, mw_freq, 180.)
    # get pi elements
    piy_element = self._get_mw_element(rabi_period / 2, 0.0, mw_channel, False,
                                       mw_amp, mw_freq, 90.0)
    # get tauhalf element
    tauhalf_element = self._get_idle_element(real_tauhalf, 0, False)
    # get tau element
    tau_element = self._get_idle_element(real_tau, 0, False)

    if seq_trig_channel is not None:
        # get sequence trigger element
        seqtrig_element = self._get_trigger_element(20.0e-9,
                                                    0.0,
                                                    seq_trig_channel,
                                                    amp=channel_amp)
        # Create its own block out of the element
        seq_block = PulseBlock('seq_trigger', [seqtrig_element])
        # save block
        self.save_block('seq_trigger', seq_block)

    # create CPMG-N block element list
    elem_list = []
    # actual CPMG-N-sweep sequence

    for outer_counter, outer_element in enumerate(n_array):
        elem_list.append(pihalf_element)
        elem_list.append(tauhalf_element)
        for n in range(outer_element):
            elem_list.append(piy_element)
            if n != outer_element - 1:
                elem_list.append(tau_element)
        elem_list.append(tauhalf_element)
        elem_list.append(pihalf_element)
        elem_list.append(laser_element)
        elem_list.append(delay_element)
        elem_list.append(waiting_element)
        if alternating:
            elem_list.append(pihalf_element)
            elem_list.append(tauhalf_element)
            for n in range(outer_element):
                elem_list.append(piy_element)
                if n != outer_element - 1:
                    elem_list.append(tau_element)
            elem_list.append(tauhalf_element)
            elem_list.append(pi3half_element)
            elem_list.append(laser_element)
            elem_list.append(delay_element)
            elem_list.append(waiting_element)

    # create CPMG-N block object
    block = PulseBlock(name, elem_list)
    self.save_block(name, block)

    # create block list and ensemble object
    block_list = [(block, 0)]
    if seq_trig_channel is not None:
        block_list.append((seq_block, 0))

    # create ensemble out of the block(s)
    block_ensemble = PulseBlockEnsemble(name=name,
                                        block_list=block_list,
                                        rotating_frame=True)
    # add metadata to invoke settings later on
    block_ensemble.sample_rate = self.sample_rate
    block_ensemble.activation_config = self.activation_config
    block_ensemble.amplitude_dict = self.amplitude_dict
    block_ensemble.laser_channel = self.laser_channel
    block_ensemble.alternating = True
    block_ensemble.laser_ignore_list = []
    block_ensemble.controlled_vals_array = n_array
    # save ensemble
    self.save_ensemble(name, block_ensemble)
    return block_ensemble