Пример #1
0
    matrix = densop.get_elm()
    eigvals = eigh(matrix, eigvals_only=True)
    eigvals_out = [eigvals[i] for i in range(len(eigvals)) if eigvals[i] > MIN_DOUBLE]

    return eigvals_out
    
if __name__ == '__main__':

    # whole quantum state
    qubit_num = 5
    qs = random_qstate(qubit_num)
    de = DensOp(qstate=[qs], prob=[1.0])  # pure state

    # partial density operators (system A and B)
    id_A, id_B = random_qubit_id(qubit_num)
    de_A = de.patrace(id_B)
    de_B = de.patrace(id_A)

    # eigen-values of density operators (system A and B)
    eval_A = eigen_values(de_A)
    eval_B = eigen_values(de_B)

    print("== system A ==")
    print("- qubit id =", id_A)
    print("- square trace = ", de_A.sqtrace())
    print("- eigen values =", eval_A)
    print("- rank =", len(eval_A))

    print("== system B ==")
    print("- qubit id =", id_B)
    print("- square trace = ", de_B.sqtrace())
Пример #2
0
from qlazy import QState, DensOp

qs = QState(4)

qs.h(0).h(1)  # unitary operation for 0,1-system
qs.x(2).z(3)  # unitary operation for 2,3-system

de1 = DensOp(qstate=[qs], prob=[1.0]) # product state
de1_reduced = de1.patrace([0,1])   # trace-out 0,1-system

print("== partial trace of product state ==")
print(" * trace = ", de1_reduced.trace())
print(" * square trace = ", de1_reduced.sqtrace())
    
qs.cx(1,3).cx(0,2)  # entangle between 0,1-system and 2,3-system

de2 = DensOp(qstate=[qs], prob=[1.0])  # entangled state
de2_reduced = de2.patrace([0,1])    # trace-out 0,1-system

print("== partial trace of entangled state ==")
print(" * trace = ", de2_reduced.trace())
print(" * square trace = ", de2_reduced.sqtrace())

print("== partial state of entangled state ==")
qs.show([2,3])