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test_cartesian.py

test_cartesian.py 4.0 KB
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  1. """Tests for cartesian.py"""
    2. 

  2. 

  3. from sympy.core.numbers import (I, pi)
    4. 

  4. from sympy.core.singleton import S
    5. 

  5. from sympy.core.symbol import symbols
    6. 

  6. from sympy.functions.elementary.exponential import exp
    7. 

  7. from sympy.functions.elementary.miscellaneous import sqrt
    8. 

  8. from sympy.functions.special.delta_functions import DiracDelta
    9. 

  9. from sympy.sets.sets import Interval
    10. 

  10. 

  11. from sympy.physics.quantum import qapply, represent, L2, Dagger
    12. 

  12. from sympy.physics.quantum import Commutator, hbar
    13. 

  13. from sympy.physics.quantum.cartesian import (
    14. 

  14.     XOp, YOp, ZOp, PxOp, X, Y, Z, Px, XKet, XBra, PxKet, PxBra,
    15. 

  15.     PositionKet3D, PositionBra3D
    16. 

  16. )
    17. 

  17. from sympy.physics.quantum.operator import DifferentialOperator
    18. 

  18. 

  19. x, y, z, x_1, x_2, x_3, y_1, z_1 = symbols('x,y,z,x_1,x_2,x_3,y_1,z_1')
    20. 

  20. px, py, px_1, px_2 = symbols('px py px_1 px_2')
    21. 

  21. 

  22. 

  23. def test_x():
    24. 

  24.     assert X.hilbert_space == L2(Interval(S.NegativeInfinity, S.Infinity))
    25. 

  25.     assert Commutator(X, Px).doit() == I*hbar
    26. 

  26.     assert qapply(X*XKet(x)) == x*XKet(x)
    27. 

  27.     assert XKet(x).dual_class() == XBra
    28. 

  28.     assert XBra(x).dual_class() == XKet
    29. 

  29.     assert (Dagger(XKet(y))*XKet(x)).doit() == DiracDelta(x - y)
    30. 

  30.     assert (PxBra(px)*XKet(x)).doit() == \
    31. 

  31.         exp(-I*x*px/hbar)/sqrt(2*pi*hbar)
    32. 

  32.     assert represent(XKet(x)) == DiracDelta(x - x_1)
    33. 

  33.     assert represent(XBra(x)) == DiracDelta(-x + x_1)
    34. 

  34.     assert XBra(x).position == x
    35. 

  35.     assert represent(XOp()*XKet()) == x*DiracDelta(x - x_2)
    36. 

  36.     assert represent(XOp()*XKet()*XBra('y')) == \
    37. 

  37.         x*DiracDelta(x - x_3)*DiracDelta(x_1 - y)
    38. 

  38.     assert represent(XBra("y")*XKet()) == DiracDelta(x - y)
    39. 

  39.     assert represent(
    40. 

  40.         XKet()*XBra()) == DiracDelta(x - x_2) * DiracDelta(x_1 - x)
    41. 

  41. 

  42.     rep_p = represent(XOp(), basis=PxOp)
    43. 

  43.     assert rep_p == hbar*I*DiracDelta(px_1 - px_2)*DifferentialOperator(px_1)
    44. 

  44.     assert rep_p == represent(XOp(), basis=PxOp())
    45. 

  45.     assert rep_p == represent(XOp(), basis=PxKet)
    46. 

  46.     assert rep_p == represent(XOp(), basis=PxKet())
    47. 

  47. 

  48.     assert represent(XOp()*PxKet(), basis=PxKet) == \
    49. 

  49.         hbar*I*DiracDelta(px - px_2)*DifferentialOperator(px)
    50. 

  50. 

  51. 

  52. def test_p():
    53. 

  53.     assert Px.hilbert_space == L2(Interval(S.NegativeInfinity, S.Infinity))
    54. 

  54.     assert qapply(Px*PxKet(px)) == px*PxKet(px)
    55. 

  55.     assert PxKet(px).dual_class() == PxBra
    56. 

  56.     assert PxBra(x).dual_class() == PxKet
    57. 

  57.     assert (Dagger(PxKet(py))*PxKet(px)).doit() == DiracDelta(px - py)
    58. 

  58.     assert (XBra(x)*PxKet(px)).doit() == \
    59. 

  59.         exp(I*x*px/hbar)/sqrt(2*pi*hbar)
    60. 

  60.     assert represent(PxKet(px)) == DiracDelta(px - px_1)
    61. 

  61. 

  62.     rep_x = represent(PxOp(), basis=XOp)
    63. 

  63.     assert rep_x == -hbar*I*DiracDelta(x_1 - x_2)*DifferentialOperator(x_1)
    64. 

  64.     assert rep_x == represent(PxOp(), basis=XOp())
    65. 

  65.     assert rep_x == represent(PxOp(), basis=XKet)
    66. 

  66.     assert rep_x == represent(PxOp(), basis=XKet())
    67. 

  67. 

  68.     assert represent(PxOp()*XKet(), basis=XKet) == \
    69. 

  69.         -hbar*I*DiracDelta(x - x_2)*DifferentialOperator(x)
    70. 

  70.     assert represent(XBra("y")*PxOp()*XKet(), basis=XKet) == \
    71. 

  71.         -hbar*I*DiracDelta(x - y)*DifferentialOperator(x)
    72. 

  72. 

  73. 

  74. def test_3dpos():
    75. 

  75.     assert Y.hilbert_space == L2(Interval(S.NegativeInfinity, S.Infinity))
    76. 

  76.     assert Z.hilbert_space == L2(Interval(S.NegativeInfinity, S.Infinity))
    77. 

  77. 

  78.     test_ket = PositionKet3D(x, y, z)
    79. 

  79.     assert qapply(X*test_ket) == x*test_ket
    80. 

  80.     assert qapply(Y*test_ket) == y*test_ket
    81. 

  81.     assert qapply(Z*test_ket) == z*test_ket
    82. 

  82.     assert qapply(X*Y*test_ket) == x*y*test_ket
    83. 

  83.     assert qapply(X*Y*Z*test_ket) == x*y*z*test_ket
    84. 

  84.     assert qapply(Y*Z*test_ket) == y*z*test_ket
    85. 

  85. 

  86.     assert PositionKet3D() == test_ket
    87. 

  87.     assert YOp() == Y
    88. 

  88.     assert ZOp() == Z
    89. 

  89. 

  90.     assert PositionKet3D.dual_class() == PositionBra3D
    91. 

  91.     assert PositionBra3D.dual_class() == PositionKet3D
    92. 

  92. 

  93.     other_ket = PositionKet3D(x_1, y_1, z_1)
    94. 

  94.     assert (Dagger(other_ket)*test_ket).doit() == \
    95. 

  95.         DiracDelta(x - x_1)*DiracDelta(y - y_1)*DiracDelta(z - z_1)
    96. 

  96. 

  97.     assert test_ket.position_x == x
    98. 

  98.     assert test_ket.position_y == y
    99. 

  99.     assert test_ket.position_z == z
    100. 

  100.     assert other_ket.position_x == x_1
    101. 

  101.     assert other_ket.position_y == y_1
    102. 

  102.     assert other_ket.position_z == z_1
    103. 

  103. 

  104.     # TODO: Add tests for representations
    105.