D2AIBR_DV2 Computes 2nd derivatives of |complex current|^2 w.r.t. V.
[HAA, HAV, HVA, HVV] = D2AIBR_DV2(DIBR_DVA, DIBR_DVM, IBR, 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 square of the magnitude of the branch currents.
Takes sparse first derivative matrices of complex flow, complex flow
vector, sparse branch admittance matrix YBR, voltage vector V and
nl x 1 vector of multipliers LAM. Output matrices are sparse.
Example:
f = branch(:, F_BUS);
Cf = sparse(1:nl, f, ones(nl, 1), nl, nb);
[Ybus, Yf, Yt] = makeYbus(baseMVA, bus, branch);
[dIf_dVa, dIf_dVm, dIt_dVa, dIt_dVm, If, It] = ...
dIbr_dV(branch, Yf, Yt, V);
Cbr = Cf;
Ybr = Yf;
dIbr_dVa = dIf_dVa;
dIbr_dVm = dIf_dVm;
Ibr = If;
[Haa, Hav, Hva, Hvv] = ...
d2AIbr_dV2(dIbr_dVa, dIbr_dVm, Ibr, Ybr, V, lam);
Here the output matrices correspond to:
Haa = (d/dVa (dAIbr_dVa.')) * lam
Hav = (d/dVm (dAIbr_dVa.')) * lam
Hva = (d/dVa (dAIbr_dVm.')) * lam
Hvv = (d/dVm (dAIbr_dVm.')) * lam
See also DIBR_DV.
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.pdf0001 function [Haa, Hav, Hva, Hvv] = ... 0002 d2AIbr_dV2(dIbr_dVa, dIbr_dVm, Ibr, Ybr, V, lam) 0003 %D2AIBR_DV2 Computes 2nd derivatives of |complex current|^2 w.r.t. V. 0004 % [HAA, HAV, HVA, HVV] = D2AIBR_DV2(DIBR_DVA, DIBR_DVM, IBR, YBR, V, LAM) 0005 % returns 4 matrices containing the partial derivatives w.r.t. voltage 0006 % angle and magnitude of the product of a vector LAM with the 1st partial 0007 % derivatives of the square of the magnitude of the branch currents. 0008 % Takes sparse first derivative matrices of complex flow, complex flow 0009 % vector, sparse branch admittance matrix YBR, voltage vector V and 0010 % nl x 1 vector of multipliers LAM. Output matrices are sparse. 0011 % 0012 % Example: 0013 % f = branch(:, F_BUS); 0014 % Cf = sparse(1:nl, f, ones(nl, 1), nl, nb); 0015 % [Ybus, Yf, Yt] = makeYbus(baseMVA, bus, branch); 0016 % [dIf_dVa, dIf_dVm, dIt_dVa, dIt_dVm, If, It] = ... 0017 % dIbr_dV(branch, Yf, Yt, V); 0018 % Cbr = Cf; 0019 % Ybr = Yf; 0020 % dIbr_dVa = dIf_dVa; 0021 % dIbr_dVm = dIf_dVm; 0022 % Ibr = If; 0023 % [Haa, Hav, Hva, Hvv] = ... 0024 % d2AIbr_dV2(dIbr_dVa, dIbr_dVm, Ibr, Ybr, V, lam); 0025 % 0026 % Here the output matrices correspond to: 0027 % Haa = (d/dVa (dAIbr_dVa.')) * lam 0028 % Hav = (d/dVm (dAIbr_dVa.')) * lam 0029 % Hva = (d/dVa (dAIbr_dVm.')) * lam 0030 % Hvv = (d/dVm (dAIbr_dVm.')) * lam 0031 % 0032 % See also DIBR_DV. 0033 % 0034 % For more details on the derivations behind the derivative code used 0035 % in MATPOWER information, see: 0036 % 0037 % [TN2] R. D. Zimmerman, "AC Power Flows, Generalized OPF Costs and 0038 % their Derivatives using Complex Matrix Notation", MATPOWER 0039 % Technical Note 2, February 2010. 0040 % http://www.pserc.cornell.edu/matpower/TN2-OPF-Derivatives.pdf 0041 0042 % MATPOWER 0043 % Copyright (c) 2008-2016, Power Systems Engineering Research Center (PSERC) 0044 % by Ray Zimmerman, PSERC Cornell 0045 % 0046 % This file is part of MATPOWER. 0047 % Covered by the 3-clause BSD License (see LICENSE file for details). 0048 % See http://www.pserc.cornell.edu/matpower/ for more info. 0049 0050 %% define 0051 nl = length(lam); 0052 0053 diaglam = sparse(1:nl, 1:nl, lam, nl, nl); 0054 diagIbr_conj = sparse(1:nl, 1:nl, conj(Ibr), nl, nl); 0055 0056 [Iaa, Iav, Iva, Ivv] = d2Ibr_dV2(Ybr, V, diagIbr_conj * lam); 0057 Haa = 2 * real( Iaa + dIbr_dVa.' * diaglam * conj(dIbr_dVa) ); 0058 Hva = 2 * real( Iva + dIbr_dVm.' * diaglam * conj(dIbr_dVa) ); 0059 Hav = 2 * real( Iav + dIbr_dVa.' * diaglam * conj(dIbr_dVm) ); 0060 Hvv = 2 * real( Ivv + dIbr_dVm.' * diaglam * conj(dIbr_dVm) );