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d2Ibr_dV2

PURPOSE ^

D2IBR_DV2 Computes 2nd derivatives of complex branch current w.r.t. voltage.

SYNOPSIS ^

function [Haa, Hav, Hva, Hvv] = d2Ibr_dV2(Ybr, V, lam)

DESCRIPTION ^

D2IBR_DV2   Computes 2nd derivatives of complex branch current w.r.t. voltage.
   [HAA, HAV, HVA, HVV] = D2IBR_DV2(CBR, YBR, V, LAM) returns 4 matrices
   containing the partial derivatives w.r.t. voltage angle and magnitude
   of the product of a vector LAM with the 1st partial derivatives of the
   complex branch currents. Takes sparse branch admittance matrix YBR,
   voltage vector V and nl x 1 vector of multipliers LAM. Output matrices
   are sparse.

   Example:
       [Ybus, Yf, Yt] = makeYbus(baseMVA, bus, branch);
       Ybr = Yf;
       [Haa, Hav, Hva, Hvv] = d2Ibr_dV2(Ybr, V, lam);

   Here the output matrices correspond to:
       Haa = (d/dVa (dIbr_dVa.')) * lam
       Hav = (d/dVm (dIbr_dVa.')) * lam
       Hva = (d/dVa (dIbr_dVm.')) * lam
       Hvv = (d/dVm (dIbr_dVm.')) * lam

   For more details on the derivations behind the derivative code used
   in MATPOWER information, see:

   [TN2]  R. D. Zimmerman, "AC Power Flows, Generalized OPF Costs and
          their Derivatives using Complex Matrix Notation", MATPOWER
          Technical Note 2, February 2010.
             http://www.pserc.cornell.edu/matpower/TN2-OPF-Derivatives.pdf

CROSS-REFERENCE INFORMATION ^

This function calls: This function is called by:

SOURCE CODE ^

0001 function [Haa, Hav, Hva, Hvv] = d2Ibr_dV2(Ybr, V, lam)
0002 %D2IBR_DV2   Computes 2nd derivatives of complex branch current w.r.t. voltage.
0003 %   [HAA, HAV, HVA, HVV] = D2IBR_DV2(CBR, YBR, V, LAM) returns 4 matrices
0004 %   containing the partial derivatives w.r.t. voltage angle and magnitude
0005 %   of the product of a vector LAM with the 1st partial derivatives of the
0006 %   complex branch currents. Takes sparse branch admittance matrix YBR,
0007 %   voltage vector V and nl x 1 vector of multipliers LAM. Output matrices
0008 %   are sparse.
0009 %
0010 %   Example:
0011 %       [Ybus, Yf, Yt] = makeYbus(baseMVA, bus, branch);
0012 %       Ybr = Yf;
0013 %       [Haa, Hav, Hva, Hvv] = d2Ibr_dV2(Ybr, V, lam);
0014 %
0015 %   Here the output matrices correspond to:
0016 %       Haa = (d/dVa (dIbr_dVa.')) * lam
0017 %       Hav = (d/dVm (dIbr_dVa.')) * lam
0018 %       Hva = (d/dVa (dIbr_dVm.')) * lam
0019 %       Hvv = (d/dVm (dIbr_dVm.')) * lam
0020 %
0021 %   For more details on the derivations behind the derivative code used
0022 %   in MATPOWER information, see:
0023 %
0024 %   [TN2]  R. D. Zimmerman, "AC Power Flows, Generalized OPF Costs and
0025 %          their Derivatives using Complex Matrix Notation", MATPOWER
0026 %          Technical Note 2, February 2010.
0027 %             http://www.pserc.cornell.edu/matpower/TN2-OPF-Derivatives.pdf
0028 
0029 %   MATPOWER
0030 %   Copyright (c) 2008-2015 by Power System Engineering Research Center (PSERC)
0031 %   by Ray Zimmerman, PSERC Cornell
0032 %
0033 %   $Id: d2Ibr_dV2.m 2644 2015-03-11 19:34:22Z ray $
0034 %
0035 %   This file is part of MATPOWER.
0036 %   Covered by the 3-clause BSD License (see LICENSE file for details).
0037 %   See http://www.pserc.cornell.edu/matpower/ for more info.
0038 
0039 %% define
0040 nb = length(V);
0041 
0042 diaginvVm = sparse(1:nb, 1:nb, ones(nb, 1)./abs(V), nb, nb);
0043 
0044 Haa = sparse(1:nb, 1:nb, -(Ybr.' * lam) .* V, nb, nb);
0045 Hva = -1j * Haa * diaginvVm;
0046 Hav = Hva;
0047 Hvv = sparse(nb, nb);

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