def testNoise(self): """ Test for Processor with noise """ # setup and fidelity without noise init_state = qubit_states(2, [0, 0, 0, 0]) tlist = np.array([0., np.pi / 2.]) a = destroy(2) proc = Processor(N=2) proc.add_control(sigmax(), targets=1, label="sx") proc.set_all_coeffs({"sx": np.array([1.])}) proc.set_all_tlist(tlist) result = proc.run_state(init_state=init_state) assert_allclose(fidelity(result.states[-1], qubit_states(2, [0, 1, 0, 0])), 1, rtol=1.e-7) # decoherence noise dec_noise = DecoherenceNoise([0.25 * a], targets=1) proc.add_noise(dec_noise) result = proc.run_state(init_state=init_state) assert_allclose(fidelity(result.states[-1], qubit_states(2, [0, 1, 0, 0])), 0.981852, rtol=1.e-3) # white random noise proc.model._noise = [] white_noise = RandomNoise(0.2, np.random.normal, loc=0.1, scale=0.1) proc.add_noise(white_noise) result = proc.run_state(init_state=init_state)
def testSpline(self): """ Test if the spline kind is correctly transfered into the arguments in QobjEvo """ tlist = np.array([1, 2, 3, 4, 5, 6], dtype=float) coeff = np.array([1, 1, 1, 1, 1, 1], dtype=float) processor = Processor(N=1, spline_kind="step_func") processor.add_control(sigmaz(), label="sz") processor.set_all_coeffs({"sz": coeff}) processor.set_tlist(tlist) ideal_qobjevo, _ = processor.get_qobjevo(noisy=False) assert_(ideal_qobjevo.args["_step_func_coeff"]) noisy_qobjevo, c_ops = processor.get_qobjevo(noisy=True) assert_(noisy_qobjevo.args["_step_func_coeff"]) processor.add_noise(ControlAmpNoise(coeff=coeff, tlist=tlist)) noisy_qobjevo, c_ops = processor.get_qobjevo(noisy=True) assert_(noisy_qobjevo.args["_step_func_coeff"]) tlist = np.array([1, 2, 3, 4, 5, 6], dtype=float) coeff = np.array([1, 1, 1, 1, 1, 1], dtype=float) processor = Processor(N=1, spline_kind="cubic") processor.add_control(sigmaz(), label="sz") processor.set_all_coeffs({"sz": coeff}) processor.set_all_tlist(tlist) ideal_qobjevo, _ = processor.get_qobjevo(noisy=False) assert ("_step_func_coeff" not in ideal_qobjevo.args) noisy_qobjevo, c_ops = processor.get_qobjevo(noisy=True) assert ("_step_func_coeff" not in noisy_qobjevo.args) processor.t1 = 100. processor.add_noise(ControlAmpNoise(coeff=coeff, tlist=tlist)) noisy_qobjevo, c_ops = processor.get_qobjevo(noisy=True) assert ("_step_func_coeff" not in noisy_qobjevo.args)
def testPlot(self): """ Test for plotting functions """ try: import matplotlib.pyplot as plt except Exception: return True # step_func tlist = np.linspace(0., 2*np.pi, 20) processor = Processor(N=1, spline_kind="step_func") processor.add_control(sigmaz()) processor.pulses[0].tlist = tlist processor.pulses[0].coeff = np.array([np.sin(t) for t in tlist]) processor.plot_pulses() plt.clf() # cubic spline tlist = np.linspace(0., 2*np.pi, 20) processor = Processor(N=1, spline_kind="cubic") processor.add_control(sigmaz()) processor.pulses[0].tlist = tlist processor.pulses[0].coeff = np.array([np.sin(t) for t in tlist]) processor.plot_pulses() plt.clf()
def test_plot(self): """ Test for plotting functions """ try: import matplotlib.pyplot as plt except Exception: return True # step_func tlist = np.linspace(0., 2 * np.pi, 20) processor = Processor(N=1, spline_kind="step_func") processor.add_control(sigmaz(), label="sz") processor.set_all_coeffs({"sz": np.array([np.sin(t) for t in tlist])}) processor.set_all_tlist(tlist) fig, _ = processor.plot_pulses(use_control_latex=False) # testing under Xvfb with pytest-xvfb complains if figure windows are # left open, so we politely close it: plt.close(fig) # cubic spline tlist = np.linspace(0., 2 * np.pi, 20) processor = Processor(N=1, spline_kind="cubic") processor.add_control(sigmaz(), label="sz") processor.set_all_coeffs({"sz": np.array([np.sin(t) for t in tlist])}) processor.set_all_tlist(tlist) fig, _ = processor.plot_pulses(use_control_latex=False) # testing under Xvfb with pytest-xvfb complains if figure windows are # left open, so we politely close it: plt.close(fig)
def testMultiLevelSystem(self): """ Test for processor with multi-level system """ N = 2 proc = Processor(N=N, dims=[2, 3]) proc.add_control(tensor(sigmaz(), rand_dm(3, density=1.)), label="sz0") proc.set_all_coeffs({"sz0": np.array([1, 2])}) proc.set_all_tlist(np.array([0., 1., 2])) proc.run_state(init_state=tensor([basis(2, 0), basis(3, 1)]))
def testMultiLevelSystem(self): """ Test for processor with multi-level system """ N = 2 proc = Processor(N=N, dims=[2, 3]) proc.add_control(tensor(sigmaz(), rand_dm(3, density=1.))) proc.pulses[0].coeff = np.array([1, 2]) proc.pulses[0].tlist = np.array([0., 1., 2]) proc.run_state(init_state=tensor([basis(2, 0), basis(3, 1)]))
def test_pulse_mode(self): processor = Processor(2) processor.add_control(sigmax(), targets=0, label="sx") processor.set_coeffs({"sx": np.array([1., 2., 3.])}) processor.set_tlist({"sx": np.array([0., 1., 2., 3.])}) processor.pulse_mode = "continuous" assert (processor.pulse_mode == "continuous") assert (processor.pulses[0].spline_kind == "cubic") processor.pulse_mode = "discrete" assert (processor.pulse_mode == "discrete") assert (processor.pulses[0].spline_kind == "step_func")
def testGetObjevo(self): tlist = np.array([1, 2, 3, 4, 5, 6], dtype=float) coeff = np.array([1, 1, 1, 1, 1, 1], dtype=float) processor = Processor(N=1) processor.add_control(sigmaz()) processor.pulses[0].tlist = tlist processor.pulses[0].coeff = coeff # without noise unitary_qobjevo, _ = processor.get_qobjevo( args={"test": True}, noisy=False) assert_allclose(unitary_qobjevo.ops[0].qobj, sigmaz()) assert_allclose(unitary_qobjevo.tlist, tlist) assert_allclose(unitary_qobjevo.ops[0].coeff, coeff[0]) assert_(unitary_qobjevo.args["test"], msg="Arguments not correctly passed on") # with decoherence noise dec_noise = DecoherenceNoise( c_ops=sigmax(), coeff=coeff, tlist=tlist) processor.add_noise(dec_noise) assert_equal(unitary_qobjevo.to_list(), processor.get_qobjevo(noisy=False)[0].to_list()) noisy_qobjevo, c_ops = processor.get_qobjevo( args={"test": True}, noisy=True) assert_(noisy_qobjevo.args["_step_func_coeff"], msg="Spline type not correctly passed on") assert_(noisy_qobjevo.args["test"], msg="Arguments not correctly passed on") assert_(sigmaz() in [pair[0] for pair in noisy_qobjevo.to_list()]) assert_equal(c_ops[0].ops[0].qobj, sigmax()) assert_equal(c_ops[0].tlist, tlist) # with amplitude noise processor = Processor(N=1, spline_kind="cubic") processor.add_control(sigmaz()) tlist = np.linspace(1, 6, int(5/0.2)) coeff = np.random.rand(len(tlist)) processor.pulses[0].tlist = tlist processor.pulses[0].coeff = coeff amp_noise = ControlAmpNoise(coeff=coeff, tlist=tlist) processor.add_noise(amp_noise) noisy_qobjevo, c_ops = processor.get_qobjevo( args={"test": True}, noisy=True) assert_(not noisy_qobjevo.args["_step_func_coeff"], msg="Spline type not correctly passed on") assert_(noisy_qobjevo.args["test"], msg="Arguments not correctly passed on") assert_equal(len(noisy_qobjevo.ops), 2) assert_equal(sigmaz(), noisy_qobjevo.ops[0].qobj) assert_allclose(coeff, noisy_qobjevo.ops[0].coeff, rtol=1.e-10)
def testChooseSolver(self): # setup and fidelity without noise init_state = qubit_states(2, [0, 0, 0, 0]) tlist = np.array([0., np.pi/2.]) a = destroy(2) proc = Processor(N=2) proc.add_control(sigmax(), targets=1) proc.pulses[0].tlist = tlist proc.pulses[0].coeff = np.array([1]) result = proc.run_state(init_state=init_state, solver="mcsolve") assert_allclose( fidelity(result.states[-1], qubit_states(2, [0, 1, 0, 0])), 1, rtol=1.e-7)
def testChooseSolver(self): # setup and fidelity without noise init_state = qubit_states(2, [0, 0, 0, 0]) tlist = np.linspace(0., np.pi / 2., 10) a = destroy(2) proc = Processor(N=2, t2=100) proc.add_control(sigmax(), targets=1, label="sx") proc.set_all_coeffs({"sx": np.array([1.] * len(tlist))}) proc.set_all_tlist(tlist) observerable = tensor([qutip.qeye(2), qutip.sigmax()]) result1 = proc.run_state(init_state=init_state, solver="mcsolve", e_ops=observerable) assert result1.solver == "mcsolve"
def test_control_and_coeffs(self): processor = Processor(2) processor.add_control(sigmax()) processor.add_control(sigmaz()) # Set coeffs and tlist without a label coeffs = np.array([[1., 2., 3.], [3., 2., 1.]]) processor.set_coeffs(coeffs) assert_allclose(coeffs, processor.coeffs) tlist = np.array([0., 1., 2., 3.]) processor.set_tlist(tlist) assert_allclose(tlist, processor.get_full_tlist()) processor.set_tlist({0: tlist, 1: tlist}) assert_allclose(tlist, processor.get_full_tlist()) # Pulses assert (len(processor.pulses) == 2) assert (processor.find_pulse(0) == processor.pulses[0]) assert (processor.find_pulse(1) == processor.pulses[1]) with pytest.raises(KeyError): processor.find_pulse("non_exist_pulse")
def test_save_read(self): """ Test for saving and reading a pulse matrix """ proc = Processor(N=2) proc.add_control(sigmaz(), label="sz") proc.add_control(sigmax(), label="sx") proc1 = Processor(N=2) proc1.add_control(sigmaz(), label="sz") proc1.add_control(sigmax(), label="sx") proc2 = Processor(N=2) proc2.add_control(sigmaz(), label="sz") proc2.add_control(sigmax(), label="sx") # TODO generalize to different tlist tlist = np.array([0.0, 0.1, 0.2, 0.3, 0.4, 0.5]) amp1 = np.arange(0, 5, 1) amp2 = np.arange(5, 0, -1) proc.set_all_coeffs({ label: amp for label, amp in zip(proc.get_control_labels(), [amp1, amp2]) }) proc.set_all_tlist(tlist) proc.save_coeff("qutip_test_CircuitProcessor.txt") proc1.read_coeff("qutip_test_CircuitProcessor.txt") os.remove("qutip_test_CircuitProcessor.txt") assert_allclose(proc1.get_full_coeffs(), proc.get_full_coeffs()) assert_allclose(proc1.get_full_tlist(), proc.get_full_tlist()) proc.save_coeff("qutip_test_CircuitProcessor.txt", inctime=False) proc2.read_coeff("qutip_test_CircuitProcessor.txt", inctime=False) proc2.set_all_tlist(tlist) os.remove("qutip_test_CircuitProcessor.txt") assert_allclose(proc2.get_full_coeffs(), proc.get_full_coeffs())
def test_save_read(self): """ Test for saving and reading a pulse matrix """ proc = Processor(N=2) proc.add_control(sigmaz(), cyclic_permutation=True) proc1 = Processor(N=2) proc1.add_control(sigmaz(), cyclic_permutation=True) proc2 = Processor(N=2) proc2.add_control(sigmaz(), cyclic_permutation=True) # TODO generalize to different tlist tlist = np.array([0., 0.1, 0.2, 0.3, 0.4, 0.5]) amp1 = np.arange(0, 5, 1) amp2 = np.arange(5, 0, -1) proc.pulses[0].tlist = tlist proc.pulses[0].coeff = amp1 proc.pulses[1].tlist = tlist proc.pulses[1].coeff = amp2 proc.save_coeff("qutip_test_CircuitProcessor.txt") proc1.read_coeff("qutip_test_CircuitProcessor.txt") os.remove("qutip_test_CircuitProcessor.txt") assert_allclose(proc1.get_full_coeffs(), proc.get_full_coeffs()) assert_allclose(proc1.get_full_tlist(), proc.get_full_tlist()) proc.save_coeff("qutip_test_CircuitProcessor.txt", inctime=False) proc2.read_coeff("qutip_test_CircuitProcessor.txt", inctime=False) proc2.set_all_tlist(tlist) os.remove("qutip_test_CircuitProcessor.txt") assert_allclose(proc2.get_full_coeffs(), proc.get_full_coeffs())
def testSpline(self): """ Test if the spline kind is correctly transfered into the arguments in QobjEvo """ tlist = np.array([1, 2, 3, 4, 5, 6], dtype=float) coeff = np.array([1, 1, 1, 1, 1, 1], dtype=float) processor = Processor(N=1, spline_kind="step_func") processor.add_control(sigmaz()) processor.pulses[0].tlist = tlist processor.pulses[0].coeff = coeff ideal_qobjevo, _ = processor.get_qobjevo(noisy=False) assert_(ideal_qobjevo.args["_step_func_coeff"]) noisy_qobjevo, c_ops = processor.get_qobjevo(noisy=True) assert_(noisy_qobjevo.args["_step_func_coeff"]) processor.T1 = 100. processor.add_noise(ControlAmpNoise(coeff=coeff, tlist=tlist)) noisy_qobjevo, c_ops = processor.get_qobjevo(noisy=True) assert_(noisy_qobjevo.args["_step_func_coeff"]) tlist = np.array([1, 2, 3, 4, 5, 6], dtype=float) coeff = np.array([1, 1, 1, 1, 1, 1], dtype=float) processor = Processor(N=1, spline_kind="cubic") processor.add_control(sigmaz()) processor.pulses[0].tlist = tlist processor.pulses[0].coeff = coeff ideal_qobjevo, _ = processor.get_qobjevo(noisy=False) assert_(not ideal_qobjevo.args["_step_func_coeff"]) noisy_qobjevo, c_ops = processor.get_qobjevo(noisy=True) assert_(not noisy_qobjevo.args["_step_func_coeff"]) processor.T1 = 100. processor.add_noise(ControlAmpNoise(coeff=coeff, tlist=tlist)) noisy_qobjevo, c_ops = processor.get_qobjevo(noisy=True) assert_(not noisy_qobjevo.args["_step_func_coeff"])
def test_modify_ctrls(self): """ Test for modifying Hamiltonian, add_control, remove_pulse """ N = 2 proc = Processor(N=N) proc.ctrls proc.add_control(sigmaz()) assert_(tensor([sigmaz(), identity(2)]), proc.ctrls[0]) proc.add_control(sigmax(), cyclic_permutation=True) assert_allclose(len(proc.ctrls), 3) assert_allclose(tensor([sigmax(), identity(2)]), proc.ctrls[1]) assert_allclose(tensor([identity(2), sigmax()]), proc.ctrls[2]) proc.add_control(sigmay(), targets=1) assert_allclose(tensor([identity(2), sigmay()]), proc.ctrls[3]) proc.remove_pulse([0, 1, 2]) assert_allclose(tensor([identity(2), sigmay()]), proc.ctrls[0]) proc.remove_pulse(0) assert_allclose(len(proc.ctrls), 0)
def test_pulse_dict(self): processor = Processor(1) processor.add_control(sigmax(), 0, label="test") assert("test" in processor.get_pulse_dict())