def test_fullchain(self, caplog):
        qbt1 = scq.Transmon.create()
        qbt2 = scq.TunableTransmon.create()
        hs = scq.HilbertSpace([qbt1, qbt2])
        pvals_by_name = {"ng": np.linspace(0.0, 1.0, 3)}

        def update_hilbertspace(ng):
            qbt1.ng = ng

        sweep = scq.ParameterSweep(
            hilbertspace=hs,
            paramvals_by_name=pvals_by_name,
            update_hilbertspace=update_hilbertspace,
            evals_count=5,
        )
        central_dispatch.LOGGER.setLevel(logging.DEBUG)
        qbt1.EC = 0.67
        assert "Transmon broadcasting QUANTUMSYSTEM_UPDATE" in caplog.text
        assert (
            "Central dispatch calling HilbertSpace about QUANTUMSYSTEM_UPDATE"
            in caplog.text)
        assert "Client HilbertSpace broadcasting HILBERTSPACE_UPDATE" in caplog.text
        assert (
            "Central dispatch calling ParameterSweep about HILBERTSPACE_UPDATE"
            in caplog.text)
        central_dispatch.LOGGER.setLevel(logging.WARNING)
 def test_unregister(self, caplog):
     qbt = scq.Transmon.create()
     hs = scq.HilbertSpace([qbt])
     central_dispatch.LOGGER.setLevel(logging.DEBUG)
     del hs
     assert "Unregistering HilbertSpace" in caplog.text
     central_dispatch.LOGGER.setLevel(logging.WARNING)
Esempio n. 3
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def test_explorer():
    qbt = qubit.Fluxonium(
        EJ=2.55,
        EC=0.72,
        EL=0.12,
        flux=0.0,
        cutoff=110,
        truncated_dim=9
    )

    osc = qubit.Oscillator(
        E_osc=4.0,
        truncated_dim=5
    )

    hilbertspace = qubit.HilbertSpace([qbt, osc])

    interaction = InteractionTerm(
        g_strength=0.2,
        op1=qbt.n_operator(),
        subsys1=qbt,
        op2=osc.creation_operator() + osc.annihilation_operator(),
        subsys2=osc
    )

    interaction_list = [interaction]
    hilbertspace.interaction_list = interaction_list

    param_name = r'$\Phi_{ext}/\Phi_0$'
    param_vals = np.linspace(-0.5, 0.5, 100)

    subsys_update_list = [qbt]

    def update_hilbertspace(param_val):
        qbt.flux = param_val

    sweep = ParameterSweep(
        param_name=param_name,
        param_vals=param_vals,
        evals_count=10,
        hilbertspace=hilbertspace,
        subsys_update_list=subsys_update_list,
        update_hilbertspace=update_hilbertspace,
    )
    swp.generate_chi_sweep(sweep)
    swp.generate_charge_matrixelem_sweep(sweep)

    explorer = Explorer(
        sweep=sweep,
        evals_count=10
    )

    explorer.interact()
Esempio n. 4
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    def hilbertspace_initialize():
        transmon1 = qubit.Transmon(
            EJ=40.0,
            EC=0.2,
            ng=0.0,
            ncut=40,
            truncated_dim=3  # after diagonalization, we will keep 3 levels
        )

        transmon2 = qubit.Transmon(EJ=3.0,
                                   EC=1.0,
                                   ng=0.0,
                                   ncut=10,
                                   truncated_dim=4)

        resonator = qubit.Oscillator(
            omega=6.0,
            truncated_dim=4  # up to 3 photons (0,1,2,3)
        )
        # Form a list of all components making up the Hilbert space.
        return qubit.HilbertSpace([transmon1, transmon2, resonator])
 def test_register(self, caplog):
     central_dispatch.LOGGER.setLevel(logging.DEBUG)
     qbt = scq.Transmon.create()
     hs = scq.HilbertSpace([qbt])
     assert "Registering HilbertSpace for QUANTUMSYSTEM_UPDATE" in caplog.text
     central_dispatch.LOGGER.setLevel(logging.WARNING)
Esempio n. 6
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'''
Two transmons coupled to a resonator

Follow the link for details
https://scqubits.readthedocs.io/en/latest/guide/ipynb/hilbertspace.html#Example:-two-transmons-coupled-to-a-harmonic-mode
'''

import scqubits as qubit
import scqubits.utils.plotting as plot
import numpy as np
from scqubits import HilbertSpace, InteractionTerm, ParameterSweep
import qutip as qt
import matplotlib.pyplot as plt

tmon1 = qubit.Transmon(EJ=40,EC=0.2,ng=0.3, ncut=40, truncated_dim=4)

tmon2 = qubit.Transmon(EJ=15.0, EC=0.15, ng=0.0,  ncut=30,truncated_dim=4)

resonator = qubit.Oscillator(
    E_osc=4.5,
    truncated_dim=4  # up to 3 photons (0,1,2,3)
)

hilbertspace = qubit.HilbertSpace([tmon1, tmon2, resonator])
print(hilbertspace)

bare_hamiltonian = hilbertspace.bare_hamiltonian()
print("---------- Bare Hamiltonian -------------")
print(bare_hamiltonian)
#plt.show()