Ejemplo n.º 1
0
def su2_to_circuit(act, param):
    phi0, phi1, phi2 = param
    th0 = phi0
    th1 = 1 / 2 * (phi1 + phi2)
    th2 = 1 / 2 * (phi1 - phi2)
    S = R(act, np.pi / 2)
    Sd = R(act, -np.pi / 2)
    gates = []
    gates.append(expIphiZ(act, th2))
    gates.append(Sd | H(act) | expIphiZ(act, th0) | H(act) | S)
    gates.append(expIphiZ(act, th1))

    return pyqcs.list_to_circuit(gates)
Ejemplo n.º 2
0
def prepare_momentum_eigenstate(nqbits, qbits_px, qbits_py, qbits_phi, px_init,
                                py_init, phi_init, antifermion):
    with log_time(__name__, "prepare_momentum_eigenstate"):
        state = State.new_zero_state(nqbits)

        circuit_px_init = [
            X(q) for i, q in enumerate(qbits_px) if px_init & (1 << i)
        ]
        circuit_px_init = list_to_circuit(circuit_px_init)
        circuit_py_init = [
            X(q) for i, q in enumerate(qbits_py) if py_init & (1 << i)
        ]
        circuit_py_init = list_to_circuit(circuit_py_init)

        if (not antifermion):
            state = (H(qbits_phi[0])
                     | RZ(qbits_phi[0], phi_init)
                     | circuit_px_init | circuit_py_init) * state
        else:
            state = (X(qbits_phi[0])
                     | H(qbits_phi[0])
                     | RZ(qbits_phi[0], phi_init)
                     | circuit_px_init | circuit_py_init) * state
    return state
Ejemplo n.º 3
0
def QFT(bits):
    if (isinstance(bits, int)):
        bits = [i for i in range(bits.bit_length() + 1) if bits & (1 << i)]
    if (not isinstance(bits, (list, tuple))):
        raise TypeError("bits must be either int, list or tuple")

    reversed_bits = list(reversed(bits))

    circuit = [
        H(qbit) | cascading_crk(i, reversed_bits)
        for i, qbit in enumerate(reversed_bits)
    ]
    circuit = list_to_circuit(circuit)

    nbits = len(bits)
    swap_bits = list_to_circuit(
        [SWAP(bits[i], bits[nbits - i - 1]) for i in range(nbits // 2)])

    return circuit | swap_bits
Ejemplo n.º 4
0
import numpy as np
from pyqcs import H, list_to_circuit, PrettyState as State
from lib.circuits import CRI

state = list_to_circuit([H(i) for i in range(2)]) * State.new_zero_state(2)

print(state)
print("->")
print(CRI(0, 1, np.pi / 2) * state)
ancillas = list(range(8, 8 + 5))

print(input_states)

circuit = (list_to_circuit([X(i) for i in qbits_px[-6:]])
           | ncontrolled(qbits_px[0], CR, ancillas, qbits_px[-6:], np.pi / 2)
           | list_to_circuit([X(i) for i in qbits_px[-6:]]))
circuit = ncontrolled(qbits_px[0], CR, ancillas, qbits_px[-6:], np.pi / 2)

print(qbits_px)
print(qbits_px[-6:])

#for config in input_states:
#    print("-"*80)
#    setup_circuit = list_to_circuit([X(i) for i,j in enumerate(config) if j])
#    state = State.new_zero_state(len(ancillas) + len(qbits_px))
#    state = setup_circuit * state
#
#    resulting_state = circuit * state
#
#    print(state)
#    print("->")
#    print(resulting_state)

state = list_to_circuit(
    [H(i)
     for i in qbits_px]) * State.new_zero_state(len(ancillas) + len(qbits_px))
print(state)
print("->")
print(circuit * state)
Ejemplo n.º 6
0
def CRX(act, control, phi):
    return (CX(act, control)
            | (H(act) | R(act, -phi) | X(act) | R(act, phi) | X(act) | H(act))
            | CX(act, control))
Ejemplo n.º 7
0
def C2X(act, c1, c2):
    return (H(act) | CX(act, c2) | T(act).get_dagger() | CX(act, c1)
            | T(act) | CX(act, c2) | T(act).get_dagger() | CX(act, c1)
            | T(act) | H(act) | T(c2).get_dagger() | CX(c2, c1)
            | T(c2).get_dagger() | CX(c2, c1) | T(c1) | S(c2))
Ejemplo n.º 8
0
def CRY(act, control, phi):
    return (CX(act, control)
            | (S(act) | H(act) | R(act, -phi) | X(act) | R(act, phi) | X(act)
               | H(act) | S(act).get_dagger())
            | CX(act, control))