コード例 #1
0
    def test_state_fid(self):
        cost_fkt = StateInfidelity(schroedinger_solver, target=down)

        simulator = Simulator(solvers=[
            schroedinger_solver,
        ],
                              cost_fktns=[
                                  cost_fkt,
                              ])

        np.random.seed(0)
        random_pulse = np.random.randn(5, 2)

        diff_norm, diff_rel = simulator.compare_numeric_to_analytic_gradient(
            pulse=random_pulse, delta_eps=1e-6)
        self.assertLess(diff_norm, 1e-5)
        self.assertLess(diff_rel, 1e-5)
コード例 #2
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solver = LindbladSolver(
    h_drift=[
        zero_matrix,
    ],
    h_ctrl=[zero_matrix, zero_matrix],
    initial_state=DenseOperator(np.eye(4)),
    tau=[
        1,
    ],
    lindblad_operators=[
        sigma_minus,
    ],
    prefactor_function=prefactor_function,
    prefactor_derivative_function=prefactor_function_derivative)

cost_func = OperationInfidelity(solver=solver,
                                target=DenseOperator(np.eye(2)),
                                super_operator_formalism=True)

simulator = Simulator(solvers=[
    solver,
], cost_fktns=[
    cost_func,
])
pulse = 5 * np.ones((1, 2))

simulator.compare_numeric_to_analytic_gradient(pulse)

simulator.numeric_gradient(pulse)
simulator.wrapped_jac_function(pulse)
コード例 #3
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ファイル: test_gradients.py プロジェクト: qutech-lab/qopt
    def test_relative_gradients_xy(self):
        amp_bound = rabi.rabi_frequency_max / rabi.lin_freq_rel
        np.random.seed(0)
        initial_pulse = amp_bound * (
            2 * np.random.rand(rabi.n_time_samples, 2) - 1)

        ntg_quasi_static = NTGQuasiStatic(
            standard_deviation=[
                rabi.sigma_rabi,
            ],
            n_samples_per_trace=rabi.n_time_samples * rabi.oversampling,
            n_traces=10,
            always_redraw_samples=False,
            sampling_mode='uncorrelated_deterministic')

        tslot = SchroedingerSMonteCarlo(
            h_drift=[
                0 * rabi.h_drift,
            ],
            h_ctrl=rabi.h_ctrl,
            h_noise=[
                rabi.h_drift,
            ],
            noise_trace_generator=ntg_quasi_static,
            initial_state=DenseOperator(np.eye(2)),
            tau=[
                rabi.time_step,
            ] * rabi.n_time_samples,
            is_skew_hermitian=True,
            exponential_method='Frechet',
            transfer_function=rabi.exponential_transfer_function,
            amplitude_function=rabi.lin_amp_func)

        entanglement_infid = OperationInfidelity(
            solver=tslot,
            target=rabi.x_half,
            fidelity_measure='entanglement',
            index=['Entanglement Fidelity QS-Noise XY-Control'])

        tslot_noise = SchroedingerSMonteCarlo(
            h_drift=[
                0 * rabi.h_drift,
            ],
            h_ctrl=rabi.h_ctrl,
            h_noise=[
                rabi.h_drift,
            ],
            noise_trace_generator=ntg_quasi_static,
            initial_state=DenseOperator(np.eye(2)),
            tau=[
                rabi.time_step,
            ] * rabi.n_time_samples,
            is_skew_hermitian=True,
            exponential_method='Frechet',
            transfer_function=rabi.exponential_transfer_function,
            amplitude_function=rabi.lin_amp_func)

        entanglement_infid_qs_noise_xy = OperationNoiseInfidelity(
            solver=tslot_noise,
            target=rabi.x_half,
            fidelity_measure='entanglement',
            index=['Entanglement Fidelity QS-Noise XY-Control'],
            neglect_systematic_errors=True)

        dynamics = Simulator(solvers=[
            tslot,
        ],
                             cost_fktns=[
                                 entanglement_infid,
                             ])

        dynamics_noise = Simulator(solvers=[
            tslot_noise,
        ],
                                   cost_fktns=[entanglement_infid_qs_noise_xy])

        _, rel_grad_deviation_unperturbed = \
            dynamics.compare_numeric_to_analytic_gradient(initial_pulse)
        self.assertLess(rel_grad_deviation_unperturbed, 1e-6)

        _, rel_grad_deviation_qs_noise = \
            dynamics_noise.compare_numeric_to_analytic_gradient(initial_pulse)
        self.assertLess(rel_grad_deviation_qs_noise, 1e-4)
コード例 #4
0
ファイル: test_gradients.py プロジェクト: qutech-lab/qopt
    def test_phase_control_gradient(self):
        amp_bound = rabi.rabi_frequency_max / rabi.lin_freq_rel
        phase_bound_upper = 50 / 180 * np.pi
        phase_bound_lower = -50 / 180 * np.pi

        def random_phase_control_pulse(n):
            amp = amp_bound * (2 * np.random.rand(n) - 1)
            phase = (phase_bound_upper - phase_bound_lower) \
                * np.random.rand(n) \
                - (phase_bound_upper - phase_bound_lower) / 2
            return np.concatenate(
                (np.expand_dims(amp, 1), np.expand_dims(phase, 1)), axis=1)

        dynamics_phase_control = Simulator(
            solvers=[rabi.solver_qs_noise_phase_control],
            cost_fktns=[rabi.entanglement_infid_phase_control])

        ntg_quasi_static = NTGQuasiStatic(
            standard_deviation=[
                rabi.sigma_rabi,
            ],
            n_samples_per_trace=rabi.n_time_samples * rabi.oversampling,
            n_traces=10,
            always_redraw_samples=False,
            sampling_mode='uncorrelated_deterministic')

        time_slot_comp_qs_noise_phase_control = SchroedingerSMonteCarlo(
            h_drift=[
                0 * rabi.h_drift,
            ],
            h_ctrl=rabi.h_ctrl,
            h_noise=[
                rabi.h_drift,
            ],
            noise_trace_generator=ntg_quasi_static,
            initial_state=DenseOperator(np.eye(2)),
            tau=[
                rabi.time_step,
            ] * rabi.n_time_samples,
            is_skew_hermitian=True,
            exponential_method='Frechet',
            transfer_function=rabi.identity_transfer_function,
            amplitude_function=rabi.phase_ctrl_amp_func)

        entanglement_infid_qs_noise_phase_control = OperationNoiseInfidelity(
            solver=time_slot_comp_qs_noise_phase_control,
            target=rabi.x_half,
            fidelity_measure='entanglement',
            index=['Entanglement Fidelity QS-Noise Phase Control'],
            neglect_systematic_errors=True)

        dynamics_phase_control_qs_noise = Simulator(
            solvers=[
                time_slot_comp_qs_noise_phase_control,
            ],
            cost_fktns=[
                entanglement_infid_qs_noise_phase_control,
            ])

        np.random.seed(0)
        inital_pulse = random_phase_control_pulse(rabi.n_time_samples)

        _, rel_grad_deviation_unperturbed = dynamics_phase_control.\
            compare_numeric_to_analytic_gradient(inital_pulse)
        self.assertLess(rel_grad_deviation_unperturbed, 2e-6)

        _, rel_grad_deviation_qs_noise = dynamics_phase_control_qs_noise.\
            compare_numeric_to_analytic_gradient(inital_pulse)
        self.assertLess(rel_grad_deviation_qs_noise, 5e-5)