def test_rotate_basis_reverse(self):
        rotation_matrix_reverse = numpy.zeros((self.n_qubits, self.n_qubits))
        rotation_matrix_reverse[0, 1] = 1
        rotation_matrix_reverse[1, 0] = 1

        one_body = numpy.zeros((self.n_qubits, self.n_qubits))
        two_body = numpy.zeros((self.n_qubits, self.n_qubits,
                                self.n_qubits, self.n_qubits))
        one_body_reverse = numpy.zeros((self.n_qubits, self.n_qubits))
        two_body_reverse = numpy.zeros((self.n_qubits, self.n_qubits,
                                        self.n_qubits, self.n_qubits))
        i = 0
        j = 0
        i_reverse = pow(self.n_qubits, 2) - 1
        j_reverse = pow(self.n_qubits, 4) - 1
        for p in range(self.n_qubits):
            for q in range(self.n_qubits):
                one_body[p, q] = i
                i = i + 1
                one_body_reverse[p, q] = i_reverse
                i_reverse = i_reverse - 1
                for r in range(self.n_qubits):
                    for s in range(self.n_qubits):
                        two_body[p, q, r, s] = j
                        j = j + 1
                        two_body_reverse[p, q, r, s] = j_reverse
                        j_reverse = j_reverse - 1
        polynomial_tensor = PolynomialTensor(
            {(): self.constant, (1, 0): one_body, (1, 1, 0, 0): two_body})
        want_polynomial_tensor = PolynomialTensor(
            {(): self.constant, (1, 0): one_body_reverse,
             (1, 1, 0, 0): two_body_reverse})
        polynomial_tensor.rotate_basis(rotation_matrix_reverse)
        self.assertEqual(polynomial_tensor, want_polynomial_tensor)
    def test_mul(self):
        new_tensor = self.polynomial_tensor_a * self.polynomial_tensor_b
        self.assertEqual(new_tensor, self.polynomial_tensor_axb)

        new_tensor_1 = self.polynomial_tensor_a * 2.
        new_tensor_2 = 2. * self.polynomial_tensor_a

        self.assertEqual(
            new_tensor_1,
            PolynomialTensor({
                (): self.constant * 2.,
                (1, 0): self.one_body_a * 2.,
                (1, 1, 0, 0): self.two_body_a * 2.
            }))
        self.assertEqual(
            new_tensor_2,
            PolynomialTensor({
                (): self.constant * 2.,
                (1, 0): self.one_body_a * 2.,
                (1, 1, 0, 0): self.two_body_a * 2.
            }))
        self.assertEqual(get_fermion_operator(new_tensor_1),
                         get_fermion_operator(self.polynomial_tensor_a) * 2.)
        self.assertEqual(get_fermion_operator(new_tensor_2),
                         get_fermion_operator(self.polynomial_tensor_a) * 2.)
    def test_rotate_basis_identical(self):
        rotation_matrix_identical = numpy.zeros((self.n_qubits, self.n_qubits))
        rotation_matrix_identical[0, 0] = 1
        rotation_matrix_identical[1, 1] = 1

        one_body = numpy.zeros((self.n_qubits, self.n_qubits))
        two_body = numpy.zeros(
            (self.n_qubits, self.n_qubits, self.n_qubits, self.n_qubits))
        one_body_spinful = numpy.zeros((2 * self.n_qubits, 2 * self.n_qubits))
        two_body_spinful = numpy.zeros((2 * self.n_qubits, 2 * self.n_qubits,
                                        2 * self.n_qubits, 2 * self.n_qubits))
        i = 0
        j = 0
        for p in range(self.n_qubits):
            for q in range(self.n_qubits):
                one_body[p, q] = i
                one_body_spinful[p, q] = i
                one_body_spinful[p + self.n_qubits, q + self.n_qubits] = i
                i = i + 1
                for r in range(self.n_qubits):
                    for s in range(self.n_qubits):
                        two_body[p, q, r, s] = j
                        two_body_spinful[p, q, r, s] = j
                        two_body_spinful[p + self.n_qubits, q + self.n_qubits,
                                         r + self.n_qubits,
                                         s + self.n_qubits] = j
                        j = j + 1
        polynomial_tensor = PolynomialTensor({
            (): self.constant,
            (1, 0): one_body,
            (1, 1, 0, 0): two_body
        })
        want_polynomial_tensor = PolynomialTensor({
            (): self.constant,
            (1, 0): one_body,
            (1, 1, 0, 0): two_body
        })
        polynomial_tensor_spinful = PolynomialTensor({
            ():
            self.constant,
            (1, 0):
            one_body_spinful,
            (1, 1, 0, 0):
            two_body_spinful
        })
        want_polynomial_tensor_spinful = PolynomialTensor({
            ():
            self.constant,
            (1, 0):
            one_body_spinful,
            (1, 1, 0, 0):
            two_body_spinful
        })

        polynomial_tensor.rotate_basis(rotation_matrix_identical)
        polynomial_tensor_spinful.rotate_basis(rotation_matrix_identical)
        self.assertEqual(polynomial_tensor, want_polynomial_tensor)
        self.assertEqual(polynomial_tensor_spinful,
                         want_polynomial_tensor_spinful)
 def test_iter_and_str(self):
     one_body = numpy.zeros((self.n_qubits, self.n_qubits))
     two_body = numpy.zeros((self.n_qubits, self.n_qubits,
                             self.n_qubits, self.n_qubits))
     one_body[0, 1] = 11.0
     two_body[0, 1, 1, 0] = 22.0
     polynomial_tensor = PolynomialTensor(
         {(): self.constant, (1, 0): one_body, (1, 1, 0, 0): two_body})
     want_str = ('() 23.0\n((0, 1), (1, 0)) 11.0\n'
                 '((0, 1), (1, 1), (1, 0), (0, 0)) 22.0\n')
     self.assertEqual(str(polynomial_tensor), want_str)
     self.assertEqual(polynomial_tensor.__repr__(), want_str)
Esempio n. 5
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    def do_rotate_basis_high_order(self, order):
        key = (1, ) * (order // 2) + (0, ) * ((order + 1) // 2)
        shape = (1, ) * order
        num = numpy.random.rand()
        rotation = numpy.exp(numpy.random.rand() * numpy.pi * 2j)

        polynomial_tensor = PolynomialTensor({key: numpy.zeros(shape) + num})

        # If order is odd, there are one more 0 than 1 in key
        if order % 2 == 1: num *= rotation
        want_polynomial_tensor = PolynomialTensor(
            {key: numpy.zeros(shape) + num})

        polynomial_tensor.rotate_basis(numpy.array([[rotation]]))

        return polynomial_tensor, want_polynomial_tensor
 def test_different_keys_mult(self):
     result = self.polynomial_tensor_a * self.polynomial_tensor_operand
     expected = PolynomialTensor({
         (1, 0):
         numpy.multiply(self.one_body_a, self.one_body_operand)
     })
     self.assertEqual(result, expected)
 def test_div(self):
     new_tensor = self.polynomial_tensor_a / 2.
     self.assertEqual(new_tensor, PolynomialTensor(
         {(): self.constant / 2.,
          (1, 0): self.one_body_a / 2.,
          (1, 1, 0, 0): self.two_body_a / 2.}))
     self.assertEqual(get_fermion_operator(new_tensor),
                      get_fermion_operator(self.polynomial_tensor_a) / 2.)
 def test_different_keys_sub(self):
     result = self.polynomial_tensor_a - self.polynomial_tensor_operand
     expected = PolynomialTensor(
         {(): self.constant,
          (1, 0): numpy.subtract(self.one_body_a, self.one_body_operand),
          (1, 1, 0, 0): self.two_body_a,
          (0, 0, 1, 1): self.two_body_operand})
     self.assertEqual(result, expected)
 def test_idiv(self):
     new_tensor = copy.deepcopy(self.polynomial_tensor_a)
     new_tensor /= 3.
     self.assertEqual(new_tensor, PolynomialTensor(
         {(): self.constant / 3.,
          (1, 0): self.one_body_a / 3.,
          (1, 1, 0, 0): self.two_body_a / 3.}))
     self.assertEqual(get_fermion_operator(new_tensor),
                      get_fermion_operator(self.polynomial_tensor_a) / 3.)
 def test_mod(self):
     new_constant = 2.0
     new_one_body = numpy.zeros_like(self.one_body_a)
     new_one_body[0, 1] = 2
     new_two_body = numpy.zeros_like(self.two_body_a)
     new_two_body[0, 1, 0, 1] = 1
     new_two_body[1, 1, 0, 0] = 2
     new_tensor = PolynomialTensor({(): new_constant,
         (1, 0): new_one_body, (1, 1, 0, 0): new_two_body})
     assert new_tensor == (self.polynomial_tensor_a % 3)
Esempio n. 11
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    def test_init_none(self):
        n_qubits = 2
        constant = 23.0

        one_body = numpy.zeros((self.n_qubits, self.n_qubits))
        two_body = numpy.zeros((self.n_qubits, self.n_qubits,
                                self.n_qubits, self.n_qubits))
        one_body[0, 1] = 2
        one_body[1, 0] = 3
        two_body[0, 1, 0, 1] = 4
        two_body[1, 1, 0, 0] = 5
        polynomial_tensor = PolynomialTensor(
                None,
                {(1, 0): one_body, (1, 1, 0, 0): two_body})
        self.assertAlmostEqual(polynomial_tensor.constant, 0.)

        self.polynomial_tensor_a[()] = 0.
        self.assertAlmostEqual(self.polynomial_tensor_a, polynomial_tensor)
        self.polynomial_tensor_a[()] = self.constant
    def setUp(self):
        self.n_qubits = 2
        self.constant = 23.0

        one_body_a = numpy.zeros((self.n_qubits, self.n_qubits))
        two_body_a = numpy.zeros((self.n_qubits, self.n_qubits,
                                  self.n_qubits, self.n_qubits))
        one_body_a[0, 1] = 2
        one_body_a[1, 0] = 3
        two_body_a[0, 1, 0, 1] = 4
        two_body_a[1, 1, 0, 0] = 5
        self.one_body_a = one_body_a
        self.two_body_a = two_body_a

        self.polynomial_tensor_a = PolynomialTensor(
            {(): self.constant, (1, 0): one_body_a, (1, 1, 0, 0): two_body_a})

        self.one_body_operand = numpy.zeros((self.n_qubits, self.n_qubits))
        self.two_body_operand = numpy.zeros((self.n_qubits, self.n_qubits,
                                             self.n_qubits, self.n_qubits))
        self.one_body_operand[0, 1] = 6
        self.one_body_operand[1, 0] = 7
        self.two_body_operand[0, 1, 0, 1] = 8
        self.two_body_operand[1, 1, 0, 0] = 9
        self.polynomial_tensor_operand = PolynomialTensor(
                {(1, 0): self.one_body_operand,
                 (0, 0, 1, 1): self.two_body_operand})

        self.polynomial_tensor_a_with_zeros = PolynomialTensor(
            {(): self.constant, (1, 0): one_body_a, (1, 1, 0, 0): two_body_a,
             (1, 1, 0, 0, 0, 0): numpy.zeros([self.n_qubits] * 6)})

        one_body_na = numpy.zeros((self.n_qubits, self.n_qubits))
        two_body_na = numpy.zeros((self.n_qubits, self.n_qubits,
                                   self.n_qubits, self.n_qubits))
        one_body_na[0, 1] = -2
        one_body_na[1, 0] = -3
        two_body_na[0, 1, 0, 1] = -4
        two_body_na[1, 1, 0, 0] = -5
        self.polynomial_tensor_na = PolynomialTensor(
            {(): -self.constant, (1, 0): one_body_na,
             (1, 1, 0, 0): two_body_na})

        one_body_b = numpy.zeros((self.n_qubits, self.n_qubits))
        two_body_b = numpy.zeros((self.n_qubits, self.n_qubits,
                                  self.n_qubits, self.n_qubits))
        one_body_b[0, 1] = 1
        one_body_b[1, 0] = 2
        two_body_b[0, 1, 0, 1] = 3
        two_body_b[1, 0, 0, 1] = 4
        self.polynomial_tensor_b = PolynomialTensor(
            {(): self.constant, (1, 0): one_body_b,
             (1, 1, 0, 0): two_body_b})

        one_body_ab = numpy.zeros((self.n_qubits, self.n_qubits))
        two_body_ab = numpy.zeros((self.n_qubits, self.n_qubits,
                                   self.n_qubits, self.n_qubits))
        one_body_ab[0, 1] = 3
        one_body_ab[1, 0] = 5
        two_body_ab[0, 1, 0, 1] = 7
        two_body_ab[1, 0, 0, 1] = 4
        two_body_ab[1, 1, 0, 0] = 5
        self.polynomial_tensor_ab = PolynomialTensor(
            {(): 2.0 * self.constant, (1, 0): one_body_ab,
             (1, 1, 0, 0): two_body_ab})

        constant_axb = self.constant * self.constant
        one_body_axb = numpy.zeros((self.n_qubits, self.n_qubits))
        two_body_axb = numpy.zeros((self.n_qubits, self.n_qubits,
                                    self.n_qubits, self.n_qubits))
        one_body_axb[0, 1] = 2
        one_body_axb[1, 0] = 6
        two_body_axb[0, 1, 0, 1] = 12
        self.polynomial_tensor_axb = PolynomialTensor(
            {(): constant_axb, (1, 0): one_body_axb,
             (1, 1, 0, 0): two_body_axb})

        self.n_qubits_plus_one = self.n_qubits + 1
        one_body_c = numpy.zeros((self.n_qubits_plus_one,
                                  self.n_qubits_plus_one))
        two_body_c = numpy.zeros((self.n_qubits_plus_one,
                                  self.n_qubits_plus_one,
                                  self.n_qubits_plus_one,
                                  self.n_qubits_plus_one))
        one_body_c[0, 1] = 1
        one_body_c[1, 0] = 2
        two_body_c[0, 1, 0, 1] = 3
        two_body_c[1, 0, 0, 1] = 4
        self.polynomial_tensor_c = PolynomialTensor(
            {(): self.constant, (1, 0): one_body_c,
             (1, 1, 0, 0): two_body_c})

        one_body_hole = numpy.zeros((self.n_qubits, self.n_qubits))
        two_body_hole = numpy.zeros((self.n_qubits, self.n_qubits,
                                     self.n_qubits, self.n_qubits))
        one_body_hole[0, 1] = 2
        one_body_hole[1, 0] = 3
        two_body_hole[0, 1, 0, 1] = 4
        two_body_hole[1, 1, 0, 0] = 5

        self.polynomial_tensor_hole = PolynomialTensor(
            {(): self.constant, (0, 1): one_body_hole,
             (0, 0, 1, 1): two_body_hole})

        one_body_spinful = numpy.zeros((2 * self.n_qubits, 2 * self.n_qubits))
        two_body_spinful = numpy.zeros((2 * self.n_qubits, 2 * self.n_qubits,
                                        2 * self.n_qubits, 2 * self.n_qubits))
        one_body_spinful[0, 1] = 2
        one_body_spinful[1, 0] = 3
        one_body_spinful[2, 3] = 6
        one_body_spinful[3, 2] = 7
        two_body_spinful[0, 1, 0, 1] = 4
        two_body_spinful[1, 1, 0, 0] = 5
        two_body_spinful[2, 1, 2, 3] = 8
        two_body_spinful[3, 3, 2, 2] = 9

        self.polynomial_tensor_spinful = PolynomialTensor(
            {(): self.constant, (1, 0): one_body_spinful,
             (1, 1, 0, 0): two_body_spinful})