예제 #1
0
 def test_properties(self):
     g = Grid(dimensions=2, length=3, scale=5.0)
     self.assertEqual(g.num_points(), 9)
     self.assertEqual(g.volume_scale(), 25)
     self.assertEqual(list(g.all_points_indices()), [
         (0, 0),
         (0, 1),
         (0, 2),
         (1, 0),
         (1, 1),
         (1, 2),
         (2, 0),
         (2, 1),
         (2, 2),
     ])
예제 #2
0
    def test_coefficients(self):

        # Test that the coefficients post-JW transform are as claimed in paper.
        grid = Grid(dimensions=2, length=3, scale=2.)
        spinless = 1
        n_orbitals = grid.num_points()
        n_qubits = (2**(1 - spinless)) * n_orbitals
        volume = grid.volume_scale()

        # Kinetic operator.
        kinetic = dual_basis_kinetic(grid, spinless)
        qubit_kinetic = jordan_wigner(kinetic)

        # Potential operator.
        potential = dual_basis_potential(grid, spinless)
        qubit_potential = jordan_wigner(potential)

        # Check identity.
        identity = tuple()
        kinetic_coefficient = qubit_kinetic.terms[identity]
        potential_coefficient = qubit_potential.terms[identity]

        paper_kinetic_coefficient = 0.
        paper_potential_coefficient = 0.
        for indices in grid.all_points_indices():
            momenta = momentum_vector(indices, grid)
            paper_kinetic_coefficient += float(n_qubits) * momenta.dot(
                momenta) / float(4. * n_orbitals)

            if momenta.any():
                potential_contribution = -numpy.pi * float(n_qubits) / float(
                    2. * momenta.dot(momenta) * volume)
                paper_potential_coefficient += potential_contribution

        self.assertAlmostEqual(kinetic_coefficient, paper_kinetic_coefficient)
        self.assertAlmostEqual(potential_coefficient,
                               paper_potential_coefficient)

        # Check Zp.
        for p in range(n_qubits):
            zp = ((p, 'Z'), )
            kinetic_coefficient = qubit_kinetic.terms[zp]
            potential_coefficient = qubit_potential.terms[zp]

            paper_kinetic_coefficient = 0.
            paper_potential_coefficient = 0.
            for indices in grid.all_points_indices():
                momenta = momentum_vector(indices, grid)
                paper_kinetic_coefficient -= momenta.dot(momenta) / float(
                    4. * n_orbitals)

                if momenta.any():
                    potential_contribution = numpy.pi / float(
                        momenta.dot(momenta) * volume)
                    paper_potential_coefficient += potential_contribution

            self.assertAlmostEqual(kinetic_coefficient,
                                   paper_kinetic_coefficient)
            self.assertAlmostEqual(potential_coefficient,
                                   paper_potential_coefficient)

        # Check Zp Zq.
        if spinless:
            spins = [None]
        else:
            spins = [0, 1]

        for indices_a in grid.all_points_indices():
            for indices_b in grid.all_points_indices():

                paper_kinetic_coefficient = 0.
                paper_potential_coefficient = 0.

                position_a = position_vector(indices_a, grid)
                position_b = position_vector(indices_b, grid)
                differences = position_b - position_a

                for spin_a in spins:
                    for spin_b in spins:

                        p = orbital_id(grid, indices_a, spin_a)
                        q = orbital_id(grid, indices_b, spin_b)

                        if p == q:
                            continue

                        zpzq = ((min(p, q), 'Z'), (max(p, q), 'Z'))
                        if zpzq in qubit_potential.terms:
                            potential_coefficient = qubit_potential.terms[zpzq]

                        for indices_c in grid.all_points_indices():
                            momenta = momentum_vector(indices_c, grid)

                            if momenta.any():
                                potential_contribution = numpy.pi * numpy.cos(
                                    differences.dot(momenta)) / float(
                                        momenta.dot(momenta) * volume)
                                paper_potential_coefficient += (
                                    potential_contribution)

                        self.assertAlmostEqual(potential_coefficient,
                                               paper_potential_coefficient)