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Anders and Briegel in Python
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abp/local_cliffords.py

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  1.  #!/usr/bin/python

  2. # -*- coding: utf-8 -*-

  3. 

  4. """ 

  5. Generates and enumerates the 24 elements of the local Clifford group

  6. Following the prescription of Anders (thesis pg. 26):

  7. > Table 2.1: The 24 elements of the local Clifford group. The row index (here called the “sign symbol”) shows how the operator

  8. > U permutes the Pauli operators σ = X, Y, Z under the conjugation σ = ±UσU† . The column index (the “permutation

  9. > symbol”) indicates the sign obtained under the conjugation: For operators U in the I column it is the sign of the permutation

  10. > (indicated on the left). For elements in the X, Y and Z columns, it is this sign only if the conjugated Pauli operator is the one

  11. > indicated by the column header and the opposite sign otherwise.

  12. """ 

  13. 

  14. # TODO:

  15. # - check that we re-generate the table

  16. # - do conjugation

  17. # - do times table

  18. # - write tests

  19. 

  20. from numpy import *

  21. 

  22. def identify_pauli(m):

  23.     """ Given a signed Pauli matrix, name it. """

  24.     for sign in (+1, -1):

  25.         for pauli_label, pauli in zip("xyz", paulis):

  26.             if allclose(sign*pauli, m):

  27.                 return sign, pauli_label

  28. 

  29. def format_action(action):

  30.     return "".join("{}{}".format("+" if s>=0 else "-", p) for s, p in action)

  31. 

  32. # Some two-qubit matrices

  33. i = matrix(eye(2, dtype=complex))

  34. px = matrix([[0, 1], [1, 0]], dtype=complex)

  35. py = matrix([[0, -1j], [1j, 0]], dtype=complex)

  36. pz = matrix([[1, 0], [0, -1]], dtype=complex)

  37. h = matrix([[1, 1], [1, -1]], dtype=complex) / sqrt(2)

  38. p = matrix([[1, 0], [0, 1j]], dtype=complex)

  39. paulis = (px, py, pz)

  40. 

  41. # More two-qubit matrices

  42. s_rotations = [i, p, p*p, p*p*p]

  43. s_names = ["i", "p", "pp", "ppp"]

  44. c_rotations = [i, h, h*p, h*p*p, h*p*p*p, h*p*p*h]

  45. c_names = ["i", "h", "hp", "hpp", "hppp", "hpph"]

  46. 

  47. # Build the table of VOPs according to Anders (verbatim from thesis)

  48. table = (("a", "xyz", +1), ("b", "yxz", -1), ("c", "zyx", -1),

  49.           ("d", "xzy", -1), ("e", "yzx", +1), ("f", "zxy", +1))

  50. 

  51. # Build a big ol lookup table

  52. vop_names = []

  53. vop_actions = []

  54. vop_gates = [None]*24

  55. vop_unitaries = [None]*24

  56. 

  57. for label, permutation, sign in table:

  58.     for column, operator in zip("ixyz", "i"+permutation):

  59.         effect = [((sign if (p==column or column=="i") else -sign), p)

  60.                         for p in permutation]

  61.         vop_names.append(label+operator)

  62.         vop_actions.append(format_action(effect))

  63. 

  64. for s, sn in zip(s_rotations, s_names):

  65.     for c, cn in zip(c_rotations, c_names):

  66.         u = s*c

  67.         action = format_action(identify_pauli(u*p*u.H) for p in paulis)

  68.         index = vop_actions.index(action)

  69.         vop_gates[index] = sn+cn

  70.         vop_unitaries[index] = u

  71. 

  72. # Add some more useful lookups