Example #1
0
def make_A(Y_series, Y_shunt, pq, pv, pqpv):

    # create system matrix A of the model 4 of the Wallace article
    N = len(Y_shunt)
    NPQ = len(pq)
    NPV = len(pv)
    NPQPV = NPQ + NPV

    dij_y = dia_matrix((Y_shunt, zeros(1)), shape=(N, N)).tocsc()
    dij = dia_matrix((ones(N), zeros(1)), shape=(N, N)).tocsc()
    G = Y_series.real
    B = Y_series.imag

    A1 = (G + dij_y.real)[pqpv, :][:, pqpv]
    A2 = (B - dij_y.imag)[pqpv, :][:, pqpv]

    M = (B - dij_y.imag)
    M[:, pv] = zeros((N, 1))
    APQ3 = M[pq, :][:, pqpv]

    M = (G + dij_y.imag)
    M[:, pv] = zeros((N, 1))
    APQ4 = M[pq, :][:, pqpv]

    APV3 = (2 * dij)[pv, :][:, pqpv]
    APV4 = csc_matrix((NPV, NPQPV))

    A = sp_vstack((sp_hstack((A1, A2)), sp_hstack(
        (APQ3, APQ4)), sp_hstack((APV3, APV4)))).tocsc()

    print("\ndij_y:\n", dij_y.toarray())
    print("\ndij:\n", dij.toarray())

    print("\nA1:\n", A1.toarray())
    print("\nA2:\n", A2.toarray())

    print("\nAPQ3:\n", APQ3.toarray())
    print("\nAPQ4:\n", APQ4.toarray())

    print("\nAPV3:\n", APV3.toarray())
    print("\nAPV4:\n", APV4.toarray())

    return A, NPQPV
Example #2
0
def make_A2(Y_series, Y_shunt, pq, pv, pqpv, types):
    """

    Args:
        Y_series: series admittances matrix
        Y_shunt: shunt admittances vector
        pq:
        pv:
    Returns:

    """

    # create system matrix A of the model 4 of the Wallace article
    NPQ = len(pq)
    NPV = len(pv)
    NPQPV = NPQ + NPV

    dij_y = dia_matrix((Y_shunt[pqpv], zeros(1)), shape=(NPQPV, NPQPV)).tocsc()
    dij_pv = coo_matrix((ones(NPV) * 2, (linspace(0, NPV - 1, NPV), pv)),
                        shape=(NPV, NPQPV)).tocsc()

    G = Y_series.real[pqpv, :][:, pqpv]
    B = Y_series.imag[pqpv, :][:, pqpv]

    Gpq = csc_matrix((NPQ, NPQPV))
    Bpq = csc_matrix((NPQ, NPQPV))
    dij_y_pq = csc_matrix((NPQ, NPQPV), dtype=complex_type)
    ii = 0
    for i, ti in enumerate(types):
        if ti == 1:
            jj = 0
            for j, tj in enumerate(types):
                if tj == 1:
                    Gpq[ii, jj] = Y_series.real[i, j]
                    Bpq[ii, jj] = Y_series.imag[i, j]
                    if ii == jj:
                        dij_y_pq[ii, jj] = Y_shunt[i]
                if tj == 1 or tj == 2:
                    jj += 1
            ii += 1

    print('G:\n', Y_series.real.toarray())
    print('B:\n', Y_series.imag.toarray())
    print('dij_y_pq:\n', dij_y_pq.toarray())

    A1 = G + dij_y.real
    print('\nA1:\n', G.toarray(), '\n+\n', dij_y.real.toarray())

    A2 = B - dij_y.imag
    print('\nA2:\n', B.toarray(), '\n-\n', dij_y.imag.toarray())

    APQ3 = Bpq - dij_y_pq.imag
    print('\nA_PQ3:\n', Bpq.toarray(), '\n-\n', dij_y_pq.imag.toarray())

    APQ4 = Gpq + dij_y_pq.real
    print('\nA_PQ4:\n', Gpq.toarray(), '\n+\n', dij_y_pq.real.toarray())

    APV3 = dij_pv
    print('\nA_PV3:\n', dij_pv.toarray())

    APV4 = csc_matrix((NPV, NPQPV))
    print('\nA_PV4:\n', APV4.toarray())

    A = sp_vstack((sp_hstack((A1, A2)), sp_hstack(
        (APQ3, APQ4)), sp_hstack((APV3, APV4)))).tocsc()

    return A, NPQPV