BasicPredefinedGenerator.generate_HHtau() - Code Metrics - Inspection of "Pulsed 3.0" - Ulm-IQO/qudi - Measure and Improve Code Quality continuously with Scrutinizer

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Pull Request — master (#384)

unknown
created 2018-06-26 12:52 UTC
BasicPredefinedGenerator.generate_HHtau() B

↳ Parent: BasicPredefinedGenerator
Complexity

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Total Lines
Duplication

Lines	80
Ratio	100 %
Importance

Changes	2
Bugs	0	Features	0
Metric	Value
cc	3
dl	80
loc	80
rs	7.6545
c	2
b	0
f	0
How to fix Long Method

# -*- coding: utf-8 -*-

"""
This file contains the Qudi Predefined Methods for sequence generator

Qudi is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.

Qudi is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
GNU General Public License for more details.

You should have received a copy of the GNU General Public License
along with Qudi. If not, see <http://www.gnu.org/licenses/>.

Copyright (c) the Qudi Developers. See the COPYRIGHT.txt file at the
top-level directory of this distribution and at <https://github.com/Ulm-IQO/qudi/>
"""

import numpy as np
from logic.pulsed.pulse_objects import PulseBlock, PulseBlockEnsemble
from logic.pulsed.pulse_objects import PredefinedGeneratorBase

"""
General Pulse Creation Procedure:
=================================
- Create at first each PulseBlockElement object
- add all PulseBlockElement object to a list and combine them to a
  PulseBlock object.
- Create all needed PulseBlock object with that idea, that means
  PulseBlockElement objects which are grouped to PulseBlock objects.
- Create from the PulseBlock objects a PulseBlockEnsemble object.
- If needed and if possible, combine the created PulseBlockEnsemble objects
  to the highest instance together in a PulseSequence object.
"""


class BasicPredefinedGenerator(PredefinedGeneratorBase):
    """

    """
    def __init__(self, *args, **kwargs):
        super().__init__(*args, **kwargs)

    def generate_laser_on(self, name='laser_on', length=3.0e-6):

        """ Generates Laser on.

        @param str name: Name of the PulseBlockEnsemble
        @param float length: laser duration in seconds

        @return object: the generated PulseBlockEnsemble object.
        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # create the laser element
        laser_element = self._get_laser_element(length=length, increment=0)
        # Create block and append to created_blocks list
        laser_block = PulseBlock(name=name)
        laser_block.append(laser_element)
        created_blocks.append(laser_block)
        # Create block ensemble and append to created_ensembles list
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=False)
        block_ensemble.append((laser_block.name, 0))
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

    def generate_laser_mw_on(self, name='laser_mw_on', length=3.0e-6):
        """ General generation method for laser on and microwave on generation.

        @param string name: Name of the PulseBlockEnsemble to be generated
        @param float length: Length of the PulseBlockEnsemble in seconds

        @return object: the generated PulseBlockEnsemble object.
        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # create the laser_mw element
        laser_mw_element = self._get_mw_laser_element(length=length,
                                                      increment=0,
                                                      amp=self.microwave_amplitude,
                                                      freq=self.microwave_frequency,
                                                      phase=0)
        # Create block and append to created_blocks list
        laser_mw_block = PulseBlock(name=name)
        laser_mw_block.append(laser_mw_element)
        created_blocks.append(laser_mw_block)
        # Create block ensemble and append to created_ensembles list
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=False)
        block_ensemble.append((laser_mw_block.name, 0))
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

    def generate_idle(self, name='idle', length=3.0e-6):

        """ Generate just a simple idle ensemble.

        @param str name: Name of the PulseBlockEnsemble to be generated
        @param float length: Length of the PulseBlockEnsemble in seconds

        @return object: the generated PulseBlockEnsemble object.
        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # create the laser_mw element
        idle_element = self._get_idle_element(length=length, increment=0)
        # Create block and append to created_blocks list
        idle_block = PulseBlock(name=name)
        idle_block.append(idle_element)
        created_blocks.append(idle_block)
        # Create block ensemble and append to created_ensembles list
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=False)
        block_ensemble.append((idle_block.name, 0))
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

    def generate_rabi(self, name='rabi', tau_start=10.0e-9, tau_step=10.0e-9, number_of_taus=50):

        """

        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # get tau array for measurement ticks
        tau_array = tau_start + np.arange(number_of_taus) * tau_step

        # create the laser_mw element
        mw_element = self._get_mw_element(length=tau_start,
                                          increment=tau_step,
                                          amp=self.microwave_amplitude,
                                          freq=self.microwave_frequency,
                                          phase=0)
        waiting_element = self._get_idle_element(length=self.wait_time,
                                                 increment=0)
        laser_element = self._get_laser_gate_element(length=self.laser_length,
                                                     increment=0)
        delay_element = self._get_delay_gate_element()

        # Create block and append to created_blocks list
        rabi_block = PulseBlock(name=name)
        rabi_block.append(mw_element)
        rabi_block.append(laser_element)
        rabi_block.append(delay_element)
        rabi_block.append(waiting_element)
        created_blocks.append(rabi_block)

        # Create block ensemble
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=False)
        block_ensemble.append((rabi_block.name, number_of_taus - 1))

        # Create and append sync trigger block if needed
        if self.sync_channel:
            sync_block = PulseBlock(name='sync_trigger')
            sync_block.append(self._get_sync_element())
            created_blocks.append(sync_block)
            block_ensemble.append((sync_block.name, 0))

        # add metadata to invoke settings later on
        block_ensemble.measurement_information['alternating'] = False
        block_ensemble.measurement_information['laser_ignore_list'] = list()
        block_ensemble.measurement_information['controlled_variable'] = tau_array
        block_ensemble.measurement_information['units'] = ('s', '')
        block_ensemble.measurement_information['number_of_lasers'] = number_of_taus
        block_ensemble.measurement_information['counting_length'] = self._get_ensemble_count_length(
            ensemble=block_ensemble, created_blocks=created_blocks)

        # Append ensemble to created_ensembles list
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

    def generate_pulsedodmr(self, name='pulsedODMR', freq_start=2870.0e6, freq_step=0.2e6,

                            num_of_points=50):
        """

        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # Create frequency array
        freq_array = freq_start + np.arange(num_of_points) * freq_step

        # create the elements
        waiting_element = self._get_idle_element(length=self.wait_time,
                                                 increment=0)
        laser_element = self._get_laser_gate_element(length=self.laser_length,
                                                     increment=0)
        delay_element = self._get_delay_gate_element()

        # Create block and append to created_blocks list
        pulsedodmr_block = PulseBlock(name=name)
        for mw_freq in freq_array:
            mw_element = self._get_mw_element(length=self.rabi_period / 2,
                                              increment=0,
                                              amp=self.microwave_amplitude,
                                              freq=mw_freq,
                                              phase=0)
            pulsedodmr_block.append(mw_element)
            pulsedodmr_block.append(laser_element)
            pulsedodmr_block.append(delay_element)
            pulsedodmr_block.append(waiting_element)
        created_blocks.append(pulsedodmr_block)

        # Create block ensemble
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=False)
        block_ensemble.append((pulsedodmr_block.name, 0))

        # Create and append sync trigger block if needed
        if self.sync_channel:
            sync_block = PulseBlock(name='sync_trigger')
            sync_block.append(self._get_sync_element())
            created_blocks.append(sync_block)
            block_ensemble.append((sync_block.name, 0))

        # add metadata to invoke settings later on
        block_ensemble.measurement_information['alternating'] = False
        block_ensemble.measurement_information['laser_ignore_list'] = list()
        block_ensemble.measurement_information['controlled_variable'] = freq_array
        block_ensemble.measurement_information['units'] = ('Hz', '')
        block_ensemble.measurement_information['number_of_lasers'] = num_of_points
        block_ensemble.measurement_information['counting_length'] = self._get_ensemble_count_length(
            ensemble=block_ensemble, created_blocks=created_blocks)

        # append ensemble to created ensembles
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

    def generate_ramsey(self, name='ramsey', tau_start=1.0e-6, tau_step=1.0e-6, num_of_points=50,
                        alternating=True):
        """

        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # get tau array for measurement ticks
        tau_array = tau_start + np.arange(num_of_points) * tau_step

        # create the elements
        waiting_element = self._get_idle_element(length=self.wait_time,
                                                 increment=0)
        laser_element = self._get_laser_gate_element(length=self.laser_length,
                                                     increment=0)
        delay_element = self._get_delay_gate_element()
        pihalf_element = self._get_mw_element(length=self.rabi_period / 4,
                                              increment=0,
                                              amp=self.microwave_amplitude,
                                              freq=self.microwave_frequency,
                                              phase=0)
        # Use a 180 deg phase shiftet pulse as 3pihalf pulse if microwave channel is analog
        if self.microwave_channel.startswith('a'):
            pi3half_element = self._get_mw_element(length=self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=180)
        else:
            pi3half_element = self._get_mw_element(length=3 * self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=0)
        tau_element = self._get_idle_element(length=tau_start, increment=tau_step)

        # Create block and append to created_blocks list
        ramsey_block = PulseBlock(name=name)
        ramsey_block.append(pihalf_element)
        ramsey_block.append(tau_element)
        ramsey_block.append(pihalf_element)
        ramsey_block.append(laser_element)
        ramsey_block.append(delay_element)
        ramsey_block.append(waiting_element)
        if alternating:
            ramsey_block.append(pihalf_element)
            ramsey_block.append(tau_element)
            ramsey_block.append(pi3half_element)
            ramsey_block.append(laser_element)
            ramsey_block.append(delay_element)
            ramsey_block.append(waiting_element)
        created_blocks.append(ramsey_block)

        # Create block ensemble
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=True)
        block_ensemble.append((ramsey_block.name, num_of_points - 1))

        # Create and append sync trigger block if needed
        if self.sync_channel:
            sync_block = PulseBlock(name='sync_trigger')
            sync_block.append(self._get_sync_element())
            created_blocks.append(sync_block)
            block_ensemble.append((sync_block.name, 0))

        # add metadata to invoke settings later on
        number_of_lasers = 2 * num_of_points if alternating else num_of_points
        block_ensemble.measurement_information['alternating'] = alternating
        block_ensemble.measurement_information['laser_ignore_list'] = list()
        block_ensemble.measurement_information['controlled_variable'] = tau_array
        block_ensemble.measurement_information['units'] = ('s', '')
        block_ensemble.measurement_information['number_of_lasers'] = number_of_lasers
        block_ensemble.measurement_information['counting_length'] = self._get_ensemble_count_length(
            ensemble=block_ensemble, created_blocks=created_blocks)

        # append ensemble to created ensembles
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

    def generate_hahnecho(self, name='hahn_echo', tau_start=1.0e-6, tau_step=1.0e-6,
                          num_of_points=50, alternating=True):
        """

        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # get tau array for measurement ticks
        tau_array = tau_start + np.arange(num_of_points) * tau_step

        # create the elements
        waiting_element = self._get_idle_element(length=self.wait_time,
                                                 increment=0)
        laser_element = self._get_laser_gate_element(length=self.laser_length,
                                                     increment=0)
        delay_element = self._get_delay_gate_element()
        pihalf_element = self._get_mw_element(length=self.rabi_period / 4,
                                              increment=0,
                                              amp=self.microwave_amplitude,
                                              freq=self.microwave_frequency,
                                              phase=0)
        pi_element = self._get_mw_element(length=self.rabi_period / 2,
                                          increment=0,
                                          amp=self.microwave_amplitude,
                                          freq=self.microwave_frequency,
                                          phase=0)
        # Use a 180 deg phase shiftet pulse as 3pihalf pulse if microwave channel is analog
        if self.microwave_channel.startswith('a'):
            pi3half_element = self._get_mw_element(length=self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=180)
        else:
            pi3half_element = self._get_mw_element(length=3 * self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=0)
        tau_element = self._get_idle_element(length=tau_start, increment=tau_step)

        # Create block and append to created_blocks list
        hahn_block = PulseBlock(name=name)
        hahn_block.append(pihalf_element)
        hahn_block.append(tau_element)
        hahn_block.append(pi_element)
        hahn_block.append(tau_element)
        hahn_block.append(pihalf_element)
        hahn_block.append(laser_element)
        hahn_block.append(delay_element)
        hahn_block.append(waiting_element)
        if alternating:
            hahn_block.append(pihalf_element)
            hahn_block.append(tau_element)
            hahn_block.append(pi_element)
            hahn_block.append(tau_element)
            hahn_block.append(pi3half_element)
            hahn_block.append(laser_element)
            hahn_block.append(delay_element)
            hahn_block.append(waiting_element)
        created_blocks.append(hahn_block)

        # Create block ensemble
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=True)
        block_ensemble.append((hahn_block.name, num_of_points - 1))

        # Create and append sync trigger block if needed
        if self.sync_channel:
            sync_block = PulseBlock(name='sync_trigger')
            sync_block.append(self._get_sync_element())
            created_blocks.append(sync_block)
            block_ensemble.append((sync_block.name, 0))

        # add metadata to invoke settings later on
        number_of_lasers = 2 * num_of_points if alternating else num_of_points
        block_ensemble.measurement_information['alternating'] = alternating
        block_ensemble.measurement_information['laser_ignore_list'] = list()
        block_ensemble.measurement_information['controlled_variable'] = tau_array
        block_ensemble.measurement_information['units'] = ('s', '')
        block_ensemble.measurement_information['number_of_lasers'] = number_of_lasers
        block_ensemble.measurement_information['counting_length'] = self._get_ensemble_count_length(
            ensemble=block_ensemble, created_blocks=created_blocks)

        # append ensemble to created ensembles
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

    def generate_HHamp(self, name='hh_amp', spinlock_length=20e-6, amp_start=0.05, amp_step=0.01,

                       num_of_points=50):
        """

        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # get amplitude array for measurement ticks
        amp_array = amp_start + np.arange(num_of_points) * amp_step

        # create the elements
        waiting_element = self._get_idle_element(length=self.wait_time, increment=0)
        laser_element = self._get_laser_gate_element(length=self.laser_length, increment=0)
        delay_element = self._get_delay_gate_element()
        pihalf_element = self._get_mw_element(length=self.rabi_period / 4,
                                              increment=0,
                                              amp=self.microwave_amplitude,
                                              freq=self.microwave_frequency,
                                              phase=0)
        # Use a 180 deg phase shiftet pulse as 3pihalf pulse if microwave channel is analog
        if self.microwave_channel.startswith('a'):
            pi3half_element = self._get_mw_element(length=self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=180)
        else:
            pi3half_element = self._get_mw_element(length=3 * self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=0)

        # Create block and append to created_blocks list
        hhamp_block = PulseBlock(name=name)
        for sl_amp in amp_array:
            sl_element = self._get_mw_element(length=spinlock_length,
                                              increment=0,
                                              amp=sl_amp,
                                              freq=self.microwave_frequency,
                                              phase=90)
            hhamp_block.append(pihalf_element)
            hhamp_block.append(sl_element)
            hhamp_block.append(pihalf_element)
            hhamp_block.append(laser_element)
            hhamp_block.append(delay_element)
            hhamp_block.append(waiting_element)

            hhamp_block.append(pi3half_element)
            hhamp_block.append(sl_element)
            hhamp_block.append(pihalf_element)
            hhamp_block.append(laser_element)
            hhamp_block.append(delay_element)
            hhamp_block.append(waiting_element)
        created_blocks.append(hhamp_block)

        # Create block ensemble
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=True)
        block_ensemble.append((hhamp_block.name, 0))

        # Create and append sync trigger block if needed
        if self.sync_channel:
            sync_block = PulseBlock(name='sync_trigger')
            sync_block.append(self._get_sync_element())
            created_blocks.append(sync_block)
            block_ensemble.append((sync_block.name, 0))

        # add metadata to invoke settings later on
        block_ensemble.measurement_information['alternating'] = True
        block_ensemble.measurement_information['laser_ignore_list'] = list()
        block_ensemble.measurement_information['controlled_variable'] = amp_array
        block_ensemble.measurement_information['units'] = ('V', '')
        block_ensemble.measurement_information['number_of_lasers'] = 2 * num_of_points
        block_ensemble.measurement_information['counting_length'] = self._get_ensemble_count_length(
            ensemble=block_ensemble, created_blocks=created_blocks)

        # append ensemble to created ensembles
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

    def generate_HHtau(self, name='hh_tau', spinlock_amp=0.1, tau_start=1e-6, tau_step=1e-6,

                       num_of_points=50):
        """

        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # get tau array for measurement ticks
        tau_array = tau_start + np.arange(num_of_points) * tau_step

        # create the elements
        waiting_element = self._get_idle_element(length=self.wait_time, increment=0)
        laser_element = self._get_laser_gate_element(length=self.laser_length, increment=0)
        delay_element = self._get_delay_gate_element()
        pihalf_element = self._get_mw_element(length=self.rabi_period / 4,
                                              increment=0,
                                              amp=self.microwave_amplitude,
                                              freq=self.microwave_frequency,
                                              phase=0)
        # Use a 180 deg phase shiftet pulse as 3pihalf pulse if microwave channel is analog
        if self.microwave_channel.startswith('a'):
            pi3half_element = self._get_mw_element(length=self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=180)
        else:
            pi3half_element = self._get_mw_element(length=3 * self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=0)
        sl_element = self._get_mw_element(length=tau_start,
                                          increment=tau_step,
                                          amp=spinlock_amp,
                                          freq=self.microwave_frequency,
                                          phase=90)

        # Create block and append to created_blocks list
        hhtau_block = PulseBlock(name=name)
        hhtau_block.append(pihalf_element)
        hhtau_block.append(sl_element)
        hhtau_block.append(pihalf_element)
        hhtau_block.append(laser_element)
        hhtau_block.append(delay_element)
        hhtau_block.append(waiting_element)

        hhtau_block.append(pi3half_element)
        hhtau_block.append(sl_element)
        hhtau_block.append(pihalf_element)
        hhtau_block.append(laser_element)
        hhtau_block.append(delay_element)
        hhtau_block.append(waiting_element)
        created_blocks.append(hhtau_block)

        # Create block ensemble
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=True)
        block_ensemble.append((hhtau_block.name, num_of_points - 1))

        # Create and append sync trigger block if needed
        if self.sync_channel:
            sync_block = PulseBlock(name='sync_trigger')
            sync_block.append(self._get_sync_element())
            created_blocks.append(sync_block)
            block_ensemble.append((sync_block.name, 0))

        # add metadata to invoke settings later on
        block_ensemble.measurement_information['alternating'] = True
        block_ensemble.measurement_information['laser_ignore_list'] = list()
        block_ensemble.measurement_information['controlled_variable'] = tau_array
        block_ensemble.measurement_information['units'] = ('s', '')
        block_ensemble.measurement_information['number_of_lasers'] = 2 * num_of_points
        block_ensemble.measurement_information['counting_length'] = self._get_ensemble_count_length(
            ensemble=block_ensemble, created_blocks=created_blocks)

        # append ensemble to created ensembles
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

    def generate_HHpol(self, name='hh_pol', spinlock_length=20.0e-6, spinlock_amp=0.1,
                       polarization_steps=50):
        """

        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # get steps array for measurement ticks
        steps_array = np.arange(2 * polarization_steps)

        # create the elements
        waiting_element = self._get_idle_element(length=self.wait_time, increment=0)
        laser_element = self._get_laser_gate_element(length=self.laser_length, increment=0)
        delay_element = self._get_delay_gate_element()
        pihalf_element = self._get_mw_element(length=self.rabi_period / 4,
                                              increment=0,
                                              amp=self.microwave_amplitude,
                                              freq=self.microwave_frequency,
                                              phase=0)
        # Use a 180 deg phase shiftet pulse as 3pihalf pulse if microwave channel is analog
        if self.microwave_channel.startswith('a'):
            pi3half_element = self._get_mw_element(length=self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=180)
        else:
            pi3half_element = self._get_mw_element(length=3 * self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=0)
        sl_element = self._get_mw_element(length=spinlock_length,
                                          increment=0,
                                          amp=spinlock_amp,
                                          freq=self.microwave_frequency,
                                          phase=90)

        # Create block for "up"-polarization and append to created_blocks list
        up_block = PulseBlock(name=name + '_up')
        up_block.append(pihalf_element)
        up_block.append(sl_element)
        up_block.append(pihalf_element)
        up_block.append(laser_element)
        up_block.append(delay_element)
        up_block.append(waiting_element)
        created_blocks.append(up_block)

        # Create block for "down"-polarization and append to created_blocks list
        down_block = PulseBlock(name=name + '_down')
        down_block.append(pi3half_element)
        down_block.append(sl_element)
        down_block.append(pi3half_element)
        down_block.append(laser_element)
        down_block.append(delay_element)
        down_block.append(waiting_element)
        created_blocks.append(down_block)

        # Create block ensemble
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=True)
        block_ensemble.append((up_block.name, polarization_steps - 1))
        block_ensemble.append((down_block.name, polarization_steps - 1))

        # Create and append sync trigger block if needed
        if self.sync_channel:
            sync_block = PulseBlock(name='sync_trigger')
            sync_block.append(self._get_sync_element())
            created_blocks.append(sync_block)
            block_ensemble.append((sync_block.name, 0))

        # add metadata to invoke settings later on
        block_ensemble.measurement_information['alternating'] = False
        block_ensemble.measurement_information['laser_ignore_list'] = list()
        block_ensemble.measurement_information['controlled_variable'] = steps_array
        block_ensemble.measurement_information['units'] = ('#', '')
        block_ensemble.measurement_information['number_of_lasers'] = 2 * polarization_steps
        block_ensemble.measurement_information['counting_length'] = self._get_ensemble_count_length(
            ensemble=block_ensemble, created_blocks=created_blocks)

        # append ensemble to created ensembles
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

    def generate_xy8_tau(self, name='xy8_tau', tau_start=0.5e-6, tau_step=0.01e-6, num_of_points=50,

                         xy8_order=4, alternating=True):
        """

        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # get tau array for measurement ticks
        tau_array = tau_start + np.arange(num_of_points) * tau_step
        # calculate "real" start length of tau due to finite pi-pulse length
        real_start_tau = max(0, tau_start - self.rabi_period / 2)

        # create the elements
        waiting_element = self._get_idle_element(length=self.wait_time, increment=0)
        laser_element = self._get_laser_gate_element(length=self.laser_length, increment=0)
        delay_element = self._get_delay_gate_element()
        pihalf_element = self._get_mw_element(length=self.rabi_period / 4,
                                              increment=0,
                                              amp=self.microwave_amplitude,
                                              freq=self.microwave_frequency,
                                              phase=0)
        # Use a 180 deg phase shiftet pulse as 3pihalf pulse if microwave channel is analog
        if self.microwave_channel.startswith('a'):
            pi3half_element = self._get_mw_element(length=self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=180)
        else:
            pi3half_element = self._get_mw_element(length=3 * self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=0)
        pix_element = self._get_mw_element(length=self.rabi_period / 2,
                                           increment=0,
                                           amp=self.microwave_amplitude,
                                           freq=self.microwave_frequency,
                                           phase=0)
        piy_element = self._get_mw_element(length=self.rabi_period / 2,
                                           increment=0,
                                           amp=self.microwave_amplitude,
                                           freq=self.microwave_frequency,
                                           phase=90)
        tauhalf_element = self._get_idle_element(length=real_start_tau / 2, increment=tau_step / 2)
        tau_element = self._get_idle_element(length=real_start_tau, increment=tau_step)

        # Create block and append to created_blocks list
        xy8_block = PulseBlock(name=name)
        xy8_block.append(pihalf_element)
        xy8_block.append(tauhalf_element)
        for n in range(xy8_order):
            xy8_block.append(pix_element)
            xy8_block.append(tau_element)
            xy8_block.append(piy_element)
            xy8_block.append(tau_element)
            xy8_block.append(pix_element)
            xy8_block.append(tau_element)
            xy8_block.append(piy_element)
            xy8_block.append(tau_element)
            xy8_block.append(piy_element)
            xy8_block.append(tau_element)
            xy8_block.append(pix_element)
            xy8_block.append(tau_element)
            xy8_block.append(piy_element)
            xy8_block.append(tau_element)
            xy8_block.append(pix_element)
            if n != xy8_order - 1:
                xy8_block.append(tau_element)
        xy8_block.append(tauhalf_element)
        xy8_block.append(pihalf_element)
        xy8_block.append(laser_element)
        xy8_block.append(delay_element)
        xy8_block.append(waiting_element)
        if alternating:
            xy8_block.append(pihalf_element)
            xy8_block.append(tauhalf_element)
            for n in range(xy8_order):
                xy8_block.append(pix_element)
                xy8_block.append(tau_element)
                xy8_block.append(piy_element)
                xy8_block.append(tau_element)
                xy8_block.append(pix_element)
                xy8_block.append(tau_element)
                xy8_block.append(piy_element)
                xy8_block.append(tau_element)
                xy8_block.append(piy_element)
                xy8_block.append(tau_element)
                xy8_block.append(pix_element)
                xy8_block.append(tau_element)
                xy8_block.append(piy_element)
                xy8_block.append(tau_element)
                xy8_block.append(pix_element)
                if n != xy8_order - 1:
                    xy8_block.append(tau_element)
            xy8_block.append(tauhalf_element)
            xy8_block.append(pi3half_element)
            xy8_block.append(laser_element)
            xy8_block.append(delay_element)
            xy8_block.append(waiting_element)
        created_blocks.append(xy8_block)

        # Create block ensemble
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=True)
        block_ensemble.append((xy8_block.name, num_of_points - 1))

        # Create and append sync trigger block if needed
        if self.sync_channel:
            sync_block = PulseBlock(name='sync_trigger')
            sync_block.append(self._get_sync_element())
            created_blocks.append(sync_block)
            block_ensemble.append((sync_block.name, 0))

        # add metadata to invoke settings later on
        number_of_lasers = num_of_points * 2 if alternating else num_of_points
        block_ensemble.measurement_information['alternating'] = alternating
        block_ensemble.measurement_information['laser_ignore_list'] = list()
        block_ensemble.measurement_information['controlled_variable'] = tau_array
        block_ensemble.measurement_information['units'] = ('s', '')
        block_ensemble.measurement_information['number_of_lasers'] = number_of_lasers
        block_ensemble.measurement_information['counting_length'] = self._get_ensemble_count_length(
            ensemble=block_ensemble, created_blocks=created_blocks)

        # append ensemble to created ensembles
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

    def generate_xy8_freq(self, name='xy8_freq', freq_start=0.1e6, freq_step=0.01e6,

                          num_of_points=50, xy8_order=4, alternating=True):
        """

        """
        created_blocks = list()
        created_ensembles = list()
        created_sequences = list()

        # get frequency array for measurement ticks
        freq_array = freq_start + np.arange(num_of_points) * freq_step
        # get tau array from freq array
        tau_array = 1 / (2 * freq_array)
        # calculate "real" tau array (finite pi-pulse length)
        real_tau_array = tau_array - self.rabi_period / 2
        np.clip(real_tau_array, 0, None, real_tau_array)
        # Convert back to frequency in order to account for clipped values
        freq_array = 1 / (2 * (real_tau_array + self.rabi_period / 2))

        # create the elements
        waiting_element = self._get_idle_element(length=self.wait_time, increment=0)
        laser_element = self._get_laser_gate_element(length=self.laser_length, increment=0)
        delay_element = self._get_delay_gate_element()
        pihalf_element = self._get_mw_element(length=self.rabi_period / 4,
                                              increment=0,
                                              amp=self.microwave_amplitude,
                                              freq=self.microwave_frequency,
                                              phase=0)
        # Use a 180 deg phase shiftet pulse as 3pihalf pulse if microwave channel is analog
        if self.microwave_channel.startswith('a'):
            pi3half_element = self._get_mw_element(length=self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=180)
        else:
            pi3half_element = self._get_mw_element(length=3 * self.rabi_period / 4,
                                                   increment=0,
                                                   amp=self.microwave_amplitude,
                                                   freq=self.microwave_frequency,
                                                   phase=0)
        pix_element = self._get_mw_element(length=self.rabi_period / 2,
                                           increment=0,
                                           amp=self.microwave_amplitude,
                                           freq=self.microwave_frequency,
                                           phase=0)
        piy_element = self._get_mw_element(length=self.rabi_period / 2,
                                           increment=0,
                                           amp=self.microwave_amplitude,
                                           freq=self.microwave_frequency,
                                           phase=90)

        # Create block and append to created_blocks list
        xy8_block = PulseBlock(name=name)
        for ii, tau in enumerate(real_tau_array):
            tauhalf_element = self._get_idle_element(length=tau / 2, increment=0)
            tau_element = self._get_idle_element(length=tau, increment=0)
            xy8_block.append(pihalf_element)
            xy8_block.append(tauhalf_element)
            for n in range(xy8_order):
                xy8_block.append(pix_element)
                xy8_block.append(tau_element)
                xy8_block.append(piy_element)
                xy8_block.append(tau_element)
                xy8_block.append(pix_element)
                xy8_block.append(tau_element)
                xy8_block.append(piy_element)
                xy8_block.append(tau_element)
                xy8_block.append(piy_element)
                xy8_block.append(tau_element)
                xy8_block.append(pix_element)
                xy8_block.append(tau_element)
                xy8_block.append(piy_element)
                xy8_block.append(tau_element)
                xy8_block.append(pix_element)
                if n != xy8_order - 1:
                    xy8_block.append(tau_element)
            xy8_block.append(tauhalf_element)
            xy8_block.append(pihalf_element)
            xy8_block.append(laser_element)
            xy8_block.append(delay_element)
            xy8_block.append(waiting_element)
            if alternating:
                xy8_block.append(pihalf_element)
                xy8_block.append(tauhalf_element)
                for n in range(xy8_order):
                    xy8_block.append(pix_element)
                    xy8_block.append(tau_element)
                    xy8_block.append(piy_element)
                    xy8_block.append(tau_element)
                    xy8_block.append(pix_element)
                    xy8_block.append(tau_element)
                    xy8_block.append(piy_element)
                    xy8_block.append(tau_element)
                    xy8_block.append(piy_element)
                    xy8_block.append(tau_element)
                    xy8_block.append(pix_element)
                    xy8_block.append(tau_element)
                    xy8_block.append(piy_element)
                    xy8_block.append(tau_element)
                    xy8_block.append(pix_element)
                    if n != xy8_order - 1:
                        xy8_block.append(tau_element)
                xy8_block.append(tauhalf_element)
                xy8_block.append(pi3half_element)
                xy8_block.append(laser_element)
                xy8_block.append(delay_element)
                xy8_block.append(waiting_element)
        created_blocks.append(xy8_block)

        # Create block ensemble
        block_ensemble = PulseBlockEnsemble(name=name, rotating_frame=True)
        block_ensemble.append((xy8_block.name, 0))

        # Create and append sync trigger block if needed
        if self.sync_channel:
            sync_block = PulseBlock(name='sync_trigger')
            sync_block.append(self._get_sync_element())
            created_blocks.append(sync_block)
            block_ensemble.append((sync_block.name, 0))

        # add metadata to invoke settings later on
        number_of_lasers = num_of_points * 2 if alternating else num_of_points
        block_ensemble.measurement_information['alternating'] = alternating
        block_ensemble.measurement_information['laser_ignore_list'] = list()
        block_ensemble.measurement_information['controlled_variable'] = freq_array
        block_ensemble.measurement_information['units'] = ('Hz', '')
        block_ensemble.measurement_information['number_of_lasers'] = number_of_lasers
        block_ensemble.measurement_information['counting_length'] = self._get_ensemble_count_length(
            ensemble=block_ensemble, created_blocks=created_blocks)

        # append ensemble to created ensembles
        created_ensembles.append(block_ensemble)
        return created_blocks, created_ensembles, created_sequences

Ulm-IQO / qudi

Pull Request — master (#384)

BasicPredefinedGenerator.generate_HHtau() B

Complexity

Size

Duplication

Importance

How to fix Long Method

Long Method

Duplication Side-by-Side

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