Ejemplo n.º 1
0
def run_ro(ro_0, H, config):
    # ---------------------------------------------------------------------------------------------
    U = Unitary(H, config.dt)
    # U.write_to_file(U_csv)

    U_conj = U.get_conj()
    # ---------------------------------------------------------------------------------------------
    ro_t = ro_0

    ro_0_sqrt = lg.fractional_matrix_power(ro_0, 0.5)

    fidelity = []

    with open(config.fid_csv, 'w') as csv_file:
        writer = csv.writer(
            csv_file, lineterminator='\n')

        st = []

        for i in H.states.values():
            st.append(str(i))

        writer.writerow(st)

        for t in range(0, config.nt + 1):
            fidelity_t = Fidelity(ro_sqrt=ro_0_sqrt, sigma=ro_t)
            # print(fidelity_t)
            # exit(0)
            ro_t = U.data.dot(ro_t).dot(U_conj)
            # print(np.around(ro_t, 3))
            # if t > 3:
            # exit(1)
            # fidelity_t = D(ro_0, ro_t)
            # fidelity_t = D_HS(ro_0, ro_t)

            # fidelity_t = round(fidelity_t, 5)

            # print(np.abs(np.diag(ro_t.data)))
            # exit(0)

            fidelity.append(fidelity_t)
    # exit(0)
    print('Min fidelity:', np.min(fidelity))
    print('Max fidelity:', np.max(fidelity))

    list_to_csv(config.fid_csv, fidelity, header=['fidelity'])
Ejemplo n.º 2
0
def run(ro_0, H, dt, nt, config, fidelity_mode=False):
    # --------------------------------------------------------
    U = Unitary(H, dt)

    if __debug__:
        U.write_to_file(config.U_csv)

    U_conj = U.conj()
    # --------------------------------------------------------
    if fidelity_mode:
        ro_0_sqrt = lg.fractional_matrix_power(ro_0.data, 0.5)

        fidelity = []

    ro_t = ro_0.data
    # ----------------------------------------------------------------------------
    with open(config.z_csv, "w") as csv_file:
        writer = csv.writer(csv_file,
                            quoting=csv.QUOTE_NONE,
                            lineterminator="\n")

        for t in range(0, nt):
            diag_abs = np.abs(np.diag(ro_t))

            trace_abs = np.sum(diag_abs)

            Assert(abs(1 - trace_abs) <= 0.1, "ro is not normed", cf())

            writer.writerow(["{:.5f}".format(x) for x in diag_abs])
            # --------------------------------------------------------------------
            if fidelity_mode:
                fidelity_t = round(Fidelity(ro_0_sqrt, ro_t), 5)
                fidelity_t = "{:.5f}".format(fidelity_t)

                fidelity.append(fidelity_t)
            # --------------------------------------------------------------------
            ro_t = U.data.dot(ro_t).dot(U_conj)
    # ----------------------------------------------------------------------------
    states = H.states

    write_x(states, config.x_csv, ind_1=[0, H.n], ind_2=[H.n, 0])
    write_t(T_str_v(config.T), config.nt, config.y_csv)
    # ----------------------------------------------------------
    if fidelity_mode:
        list_to_csv(config.fid_csv, fidelity, header=["fidelity"])
Ejemplo n.º 3
0
def run_ro(ro_0, H, dt, nt):
    # ---------------------------------------------------------------------------------------------
    U = Unitary(H, dt)

    if __debug__:
        U.write_to_file(U_csv)

    U_conj = U.conj()
    # ----------------------------------------------------
    ro_t = ro_0.data
    ro_0_sqrt = lg.fractional_matrix_power(ro_0.data, 0.5)
    # ----------------------------------------------------
    FIDELITY = []
    # ----------------------------------------------------
    with open(z_csv, "w") as csv_file:
        writer = csv.writer(csv_file,
                            quoting=csv.QUOTE_NONE,
                            lineterminator="\n")

        for t in range(0, nt):
            p = np.abs(np.diag(ro_t))

            trace = np.sum(p)

            Assert(abs(1 - trace) <= 0.1, "ro is not normed", cf())

            writer.writerow(["{:.5f}".format(x) for x in p])
            # --------------------------------------------------
            fidelity_t = Fidelity(ro_0_sqrt, ro_t)
            FIDELITY.append(fidelity_t)
            # --------------------------------------------------
            ro_t = U.data.dot(ro_t).dot(U_conj)
    # ---------------------------------------------------------------------------------------------
    states = H.states

    write_x(states, x_csv, ind_1=[0, H.n], ind_2=[H.n, 0])
    write_t(T_str_v(T), nt, y_csv)
    # write_t(T / mks / 1e-2, nt, y_csv)
    # # -------------------------
    list_to_csv(fid_csv, FIDELITY, header=["fidelity"])
Ejemplo n.º 4
0
def run(ro_0, H, dt, nt, l, config, fidelity_mode=False):
    # --------------------------------------------------------
    a = get_a(H, H.capacity, H.n)
    _a = Matrix(H.size, H.size, dtype=np.complex128)
    _a.data = a.data
    # _a.write_to_file('a')
    # print(a)
    # if __debug__:
    # _a.write_to_file(a_csv)

    a_cross = a.getH()
    across_a = np.dot(a_cross, a)
    _a_cross_a = Matrix(H.size, H.size, dtype=np.complex128)
    _a_cross_a.data = across_a.data

    # print(a)
    # exit(1)
    # print("H:\n", color="yellow")
    # H.matrix.set_header(H.states)
    # H.matrix.print_pd()

    # _a.set_header(H.states)
    # print("a:\n", color="yellow")
    # _a.print_pd()

    # _a_cross_a.set_header(H.states)
    # print("acrossa:\n", color="yellow")
    # _a_cross_a.print_pd()

    # for i in range(a.shape[0]):
    #     for j in range(a.shape[1]):
    #         if a[i, j]:
    #             print(H.states[i], H.states[j], a[i, j])

    # exit(1)
    # print(np.matrix(a))
    # if __debug__:
    # _a_cross_a.write_to_file(a_cross_a_csv)
    # --------------------------------------------------------
    U = Unitary(H, dt)

    # if __debug__:
    # U.write_to_file(config.U_csv)

    U_conj = U.conj()
    # --------------------------------------------------------

    ro_t = ro_0.data

    for k, v in H.states.items():
        if v == [H.capacity, 0, 0]:
            index1 = k
        if v == [0, H.n, 0]:
            index2 = k

    if fidelity_mode:
        ro_0_sqrt = lg.fractional_matrix_power(
            ro_0.data[index1:index2 + 1, index1:index2 + 1], 0.5)

        fidelity = []

    # print(np.round(np.diag(ro_t), 3))
    # print()

    # print("ρ(0):\n", color="yellow")
    # ro_0.set_header(H.states)
    # ro_0.print_pd()
    H.print_states()

    # ----------------------------------------------------------------------------
    with open(config.z_csv, "w") as csv_file:
        writer = csv.writer(csv_file,
                            quoting=csv.QUOTE_NONE,
                            lineterminator="\n")

        for t in range(0, nt + 1):
            # print(t, nt)
            # diag_abs = np.abs(np.diag(ro_t)[index1:index2 + 1])

            # trace_abs = np.sum(diag_abs)
            diag = np.diag(ro_t)

            p = np.abs(diag[index1:index2 + 1])
            # p = np.asarray(p).reshape(-1)
            # p = np.around(p, precision)

            norm = np.sum(np.abs(diag))
            # print(t, "norm:", norm)
            Assert(
                abs(1 - norm) <= 0.1,
                str(t) + " " + str(norm) + ": ro is not normed", cf())
            # Assert(abs(1 - trace_abs) <= 0.1, "ro is not normed", cf())

            writer.writerow(["{:.3f}".format(x) for x in p])
            # writer.writerow(["{:.5f}".format(x) for x in diag_abs])
            # --------------------------------------------------------------------
            if fidelity_mode:
                fidelity_t = Fidelity(
                    ro_0_sqrt, ro_t[index1:index2 + 1, index1:index2 + 1])
                fidelity.append(fidelity_t)
            # --------------------------------------------------------------------
            # for i in np.diag(ro_t):
            #     v = str(np.round(i, 3))
            #     # v = str(np.round(i, 3))
            #     print(v.rjust(5, ' '), end=' ')

            # v = str(np.round(np.sum(np.abs(diag[:-1])), 3))

            # print(v)

            L = get_L(ro_t, a, a_cross, across_a)
            ro_t = U.data.dot(ro_t).dot(U_conj) + dt * (config.l * L)

    # ----------------------------------------------------------------------------
    states = {}
    # print(np.round(np.diag(ro_t), 3))
    # ro_0.data = ro_t
    # ro_0.set_header(H.states)
    # print("ρ(t):\n", color="yellow")
    # ro_0.print_pd()

    # ro_0.data = L
    # print("L(t):\n", color="yellow")
    # ro_0.write_to_file("L")
    # ro_0.print_pd()

    # exit(1)
    cnt = 0

    for k in range(index1, index2 + 1):
        states[cnt] = (H.states[k])[1:]
        cnt += 1
    print(states)
    write_x(states, config.x_csv, ind=[[0, H.n], [H.n, 0]])
    write_t(T_str_v(config.T), config.nt, config.y_csv)
    # write_t(config.T / config.mks / 1e-2, config.nt, config.y_csv)
    # ----------------------------------------------------------
    if fidelity_mode:
        list_to_csv(config.fid_csv, fidelity, header=["fidelity"])
Ejemplo n.º 5
0
def run(ro_0, H, dt, nt, config, fidelity_mode=False):
    # --------------------------------------------------------
    U = Unitary(H, dt)

    if __debug__:
        U.write_to_file(config.U_csv)

    U_conj = U.conj()
    # --------------------------------------------------------
    if fidelity_mode:
        ro_0_sqrt = lg.fractional_matrix_power(ro_0.data, 0.5)

        fidelity = []

    ro_t = ro_0.data
    # ----------------------------------------------------------------------------
    p_bin = dict.fromkeys(H.states_bin_keys)
    # --------------------------------------------------------
    with open(config.z_csv, "w") as csv_file:
        writer = csv.writer(csv_file,
                            quoting=csv.QUOTE_NONE,
                            lineterminator="\n")

        with open(config.z_all_csv, "w") as csv_all_file:
            writer_all = csv.writer(csv_all_file,
                                    quoting=csv.QUOTE_NONE,
                                    lineterminator="\n")

            for t in range(0, nt):
                diag_abs = np.abs(np.diag(ro_t))

                trace_abs = np.sum(diag_abs)

                Assert(abs(1 - trace_abs) <= 0.1, "ro is not normed", cf())

                for k, v in p_bin.items():
                    p_bin[k] = 0

                for k, v in H.states_bin.items():
                    for ind in v:
                        p_bin[k] += diag_abs[ind]

                v_bin = [p_bin[k] for k in H.states_bin_keys]
                # --------------------------------------------------
                writer.writerow(["{:.5f}".format(x) for x in v_bin])

                # if __debug__:
                # writer_all.writerow(["{:.5f}".format(x) for x in diag_abs])
                # --------------------------------------------------
                if fidelity_mode:
                    fidelity_t = Fidelity(ro_0_sqrt, ro_t)
                    fidelity.append(fidelity_t)
                # --------------------------------------------------
                ro_t = U.data.dot(ro_t).dot(U_conj)
    # --------------------------------------------------------------
    states_bin = {}

    cnt = 0

    for k in H.states_bin_keys:
        if k == "[" + str(0) + "," + str(int(
                config.n / 2)) + "]" or k == "[" + str(int(
                    config.n / 2)) + "," + str(0) + "]":

            states_bin[cnt] = str(k)
        else:
            states_bin[cnt] = ""
        cnt += 1
    # ----------------------------------------------------------
    states = {}

    cnt = 0

    for v in H.states_bin_keys:
        states[cnt] = v

        cnt += 1
    # ----------------------------------------------------------
    write_x(states, config.x_csv)
    write_t(config.T / config.mks, config.nt, config.y_csv)
    # ----------------------------------------------------------
    if fidelity_mode:
        list_to_csv(fid_csv, fidelity, header=["fidelity"])