コード例 #1
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    def test_terms(self):

        ssys = SpinSystem(['mu', 'e'])

        # A scalar term
        term = InteractionTerm(ssys, [], 2.0)
        self.assertEqual(term.operator, ssys.operator({})*2)

        # Linear term
        term = SingleTerm(ssys, 0, [0, 0, 1])
        self.assertEqual(term.operator, ssys.operator({0: 'z'}))

        # Test copy
        copy = term.clone()
        copy._tensor[0] = 1

        self.assertTrue(isinstance(copy, SingleTerm))
        self.assertFalse(np.all(copy.tensor == term.tensor))

        # Bilinear term
        term = DoubleTerm(ssys, 0, 1, np.diag([1, 1, 2]))
        self.assertEqual(term.operator, ssys.operator({0: 'x', 1: 'x'}) +
                         ssys.operator({0: 'y', 1: 'y'}) +
                         2*ssys.operator({0: 'z', 1: 'z'}))

        # Rotation matrix
        R = np.array([[1, 0, 0], [0, 0, 1], [0, -1, 0]])
        rotterm = term.rotate(R)
        self.assertEqual(rotterm.operator, ssys.operator({0: 'x', 1: 'x'}) +
                         2*ssys.operator({0: 'y', 1: 'y'}) +
                         ssys.operator({0: 'z', 1: 'z'}))
コード例 #2
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    def test_integrate(self):

        ssys = SpinSystem(['e'])
        ssys.add_linear_term(0, [1, 0, 0])  # Precession around x
        H = ssys.hamiltonian
        rho0 = DensityOperator.from_vectors()  # Start along z
        avg = H.integrate_decaying(rho0, 1.0, ssys.operator({0: 'z'}))

        self.assertTrue(np.isclose(avg[0], 0.5 / (1.0 + 4 * np.pi**2)))
コード例 #3
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    def test_operator(self):

        ssys = SpinSystem(['mu', 'e'])

        self.assertEqual(ssys.operator({0: 'x'}),
                         SpinOperator.from_axes([0.5, 0.5], 'x0'))
        self.assertEqual(ssys.operator({0: 'z', 1: 'y'}),
                         SpinOperator.from_axes([0.5, 0.5], 'zy'))
        self.assertEqual(ssys.dimension, (2, 2))
コード例 #4
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    def test_check(self):

        ssys = SpinSystem(['mu', 'e'])

        self.assertEqual(ssys.gamma(0), constants.MU_GAMMA)
        self.assertEqual(ssys.gamma(1), constants.ELEC_GAMMA)

        self.assertEqual(len(ssys), 2)
        self.assertEqual(ssys.dimension, (2, 2))
コード例 #5
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    def test_evolve(self):

        ssys = SpinSystem(['e'])
        ssys.add_linear_term(0, [1, 0, 0])  # Precession around x
        H = ssys.hamiltonian
        rho0 = DensityOperator.from_vectors()  # Start along z
        t = np.linspace(0, 1, 100)

        evol = H.evolve(rho0, t, ssys.operator({0: 'z'}))

        self.assertTrue(
            np.all(np.isclose(evol[:, 0], 0.5 * np.cos(2 * np.pi * t))))
コード例 #6
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    def test_create(self):

        ssys = SpinSystem(['mu', 'e'])

        ssys = SpinSystem(['mu', ('H', 2)])

        # Test cloning
        ssys2 = ssys.clone()

        self.assertEqual(ssys.dimension, ssys2.dimension)

        # Check that the copy is deep
        ssys2._spins[0] = 'C'
        self.assertEqual(ssys.spins, ['mu', ('H', 2)])
コード例 #7
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    def test_lindbladian(self):

        ssys = SpinSystem(['mu'])
        ssys.add_linear_term(0, [0, 0, 1])

        H = ssys.hamiltonian
        L = ssys.lindbladian
        L0 = -1.0j*SuperOperator.commutator(ssys.operator({0: 'z'}))

        self.assertTrue(np.all(np.isclose(L.matrix, L0.matrix)))

        sx = ssys.operator({0: 'x'})
        d = 2.0
        ssys.add_dissipative_term(sx, d)

        L1 = L0 + d*(SuperOperator.bracket(sx) -
                     0.5*SuperOperator.anticommutator(sx*sx))

        L = ssys.lindbladian
        self.assertTrue(np.all(np.isclose(L.matrix, L1.matrix)))
コード例 #8
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    def test_addterms(self):

        ssys = SpinSystem(['mu', 'e'])

        t1 = ssys.add_linear_term(0, [1, 0, 1])

        self.assertEqual(t1.label, 'Single')
        self.assertEqual(t1.operator, ssys.operator({0: 'x'}) +
                         ssys.operator({0: 'z'}))

        t2 = ssys.add_bilinear_term(0, 1, np.eye(3))

        self.assertEqual(t2.label, 'Double')
        self.assertEqual(t2.operator, ssys.operator({0: 'x', 1: 'x'}) +
                         ssys.operator({0: 'y', 1: 'y'}) +
                         ssys.operator({0: 'z', 1: 'z'}))

        H = ssys.hamiltonian

        self.assertTrue(np.all(np.isclose(H.matrix,
                                          np.array([[0.75, 0, 0.5, 0.0],
                                                    [0, 0.25, 0.5, 0.5],
                                                    [0.5, 0.5, -0.75, 0],
                                                    [0.0, 0.5, 0, -0.25]]))))

        ssys.add_dissipative_term(ssys.operator({0: 'x'}), 1.0)
        self.assertTrue(ssys.is_dissipative)