Home > matpower7.0 > lib > idx_gen.m

idx_gen

PURPOSE ^

IDX_GEN Defines constants for named column indices to gen matrix.

SYNOPSIS ^

function [GEN_BUS, PG, QG, QMAX, QMIN, VG, MBASE, GEN_STATUS, PMAX, PMIN,MU_PMAX, MU_PMIN, MU_QMAX, MU_QMIN, PC1, PC2, QC1MIN, QC1MAX,QC2MIN, QC2MAX, RAMP_AGC, RAMP_10, RAMP_30, RAMP_Q, APF] = idx_gen

DESCRIPTION ^

IDX_GEN   Defines constants for named column indices to gen matrix.
   Example:

   [GEN_BUS, PG, QG, QMAX, QMIN, VG, MBASE, GEN_STATUS, PMAX, PMIN, ...
   MU_PMAX, MU_PMIN, MU_QMAX, MU_QMIN, PC1, PC2, QC1MIN, QC1MAX, ...
   QC2MIN, QC2MAX, RAMP_AGC, RAMP_10, RAMP_30, RAMP_Q, APF] = idx_gen;

   Some examples of usage, after defining the constants using the line above,
   are:

    Pg = gen(4, PG);   % get the real power output of generator 4
    gen(:, PMIN) = 0;  % set to zero the minimum real power limit of all gens
 
   The index, name and meaning of each column of the gen matrix is given
   below:

   columns 1-21 must be included in input matrix (in case file)
    1  GEN_BUS     bus number
    2  PG          Pg, real power output (MW)
    3  QG          Qg, reactive power output (MVAr)
    4  QMAX        Qmax, maximum reactive power output (MVAr)
    5  QMIN        Qmin, minimum reactive power output (MVAr)
    6  VG          Vg, voltage magnitude setpoint (p.u.)
    7  MBASE       mBase, total MVA base of machine, defaults to baseMVA
    8  GEN_STATUS  status, > 0 - in service, <= 0 - out of service
    9  PMAX        Pmax, maximum real power output (MW)
    10 PMIN        Pmin, minimum real power output (MW)
    11 PC1         Pc1, lower real power output of PQ capability curve (MW)
    12 PC2         Pc2, upper real power output of PQ capability curve (MW)
    13 QC1MIN      Qc1min, minimum reactive power output at Pc1 (MVAr)
    14 QC1MAX      Qc1max, maximum reactive power output at Pc1 (MVAr)
    15 QC2MIN      Qc2min, minimum reactive power output at Pc2 (MVAr)
    16 QC2MAX      Qc2max, maximum reactive power output at Pc2 (MVAr)
    17 RAMP_AGC    ramp rate for load following/AGC (MW/min)
    18 RAMP_10     ramp rate for 10 minute reserves (MW)
    19 RAMP_30     ramp rate for 30 minute reserves (MW)
    20 RAMP_Q      ramp rate for reactive power (2 sec timescale) (MVAr/min)
    21 APF         area participation factor
   
   columns 22-25 are added to matrix after OPF solution
   they are typically not present in the input matrix
                   (assume OPF objective function has units, u)
    22 MU_PMAX     Kuhn-Tucker multiplier on upper Pg limit (u/MW)
    23 MU_PMIN     Kuhn-Tucker multiplier on lower Pg limit (u/MW)
    24 MU_QMAX     Kuhn-Tucker multiplier on upper Qg limit (u/MVAr)
    25 MU_QMIN     Kuhn-Tucker multiplier on lower Qg limit (u/MVAr)

   See also DEFINE_CONSTANTS.

CROSS-REFERENCE INFORMATION ^

This function calls: This function is called by:

SOURCE CODE ^

0001 function [GEN_BUS, PG, QG, QMAX, QMIN, VG, MBASE, GEN_STATUS, PMAX, PMIN, ...
0002     MU_PMAX, MU_PMIN, MU_QMAX, MU_QMIN, PC1, PC2, QC1MIN, QC1MAX, ...
0003     QC2MIN, QC2MAX, RAMP_AGC, RAMP_10, RAMP_30, RAMP_Q, APF] = idx_gen
0004 %IDX_GEN   Defines constants for named column indices to gen matrix.
0005 %   Example:
0006 %
0007 %   [GEN_BUS, PG, QG, QMAX, QMIN, VG, MBASE, GEN_STATUS, PMAX, PMIN, ...
0008 %   MU_PMAX, MU_PMIN, MU_QMAX, MU_QMIN, PC1, PC2, QC1MIN, QC1MAX, ...
0009 %   QC2MIN, QC2MAX, RAMP_AGC, RAMP_10, RAMP_30, RAMP_Q, APF] = idx_gen;
0010 %
0011 %   Some examples of usage, after defining the constants using the line above,
0012 %   are:
0013 %
0014 %    Pg = gen(4, PG);   % get the real power output of generator 4
0015 %    gen(:, PMIN) = 0;  % set to zero the minimum real power limit of all gens
0016 %
0017 %   The index, name and meaning of each column of the gen matrix is given
0018 %   below:
0019 %
0020 %   columns 1-21 must be included in input matrix (in case file)
0021 %    1  GEN_BUS     bus number
0022 %    2  PG          Pg, real power output (MW)
0023 %    3  QG          Qg, reactive power output (MVAr)
0024 %    4  QMAX        Qmax, maximum reactive power output (MVAr)
0025 %    5  QMIN        Qmin, minimum reactive power output (MVAr)
0026 %    6  VG          Vg, voltage magnitude setpoint (p.u.)
0027 %    7  MBASE       mBase, total MVA base of machine, defaults to baseMVA
0028 %    8  GEN_STATUS  status, > 0 - in service, <= 0 - out of service
0029 %    9  PMAX        Pmax, maximum real power output (MW)
0030 %    10 PMIN        Pmin, minimum real power output (MW)
0031 %    11 PC1         Pc1, lower real power output of PQ capability curve (MW)
0032 %    12 PC2         Pc2, upper real power output of PQ capability curve (MW)
0033 %    13 QC1MIN      Qc1min, minimum reactive power output at Pc1 (MVAr)
0034 %    14 QC1MAX      Qc1max, maximum reactive power output at Pc1 (MVAr)
0035 %    15 QC2MIN      Qc2min, minimum reactive power output at Pc2 (MVAr)
0036 %    16 QC2MAX      Qc2max, maximum reactive power output at Pc2 (MVAr)
0037 %    17 RAMP_AGC    ramp rate for load following/AGC (MW/min)
0038 %    18 RAMP_10     ramp rate for 10 minute reserves (MW)
0039 %    19 RAMP_30     ramp rate for 30 minute reserves (MW)
0040 %    20 RAMP_Q      ramp rate for reactive power (2 sec timescale) (MVAr/min)
0041 %    21 APF         area participation factor
0042 %
0043 %   columns 22-25 are added to matrix after OPF solution
0044 %   they are typically not present in the input matrix
0045 %                   (assume OPF objective function has units, u)
0046 %    22 MU_PMAX     Kuhn-Tucker multiplier on upper Pg limit (u/MW)
0047 %    23 MU_PMIN     Kuhn-Tucker multiplier on lower Pg limit (u/MW)
0048 %    24 MU_QMAX     Kuhn-Tucker multiplier on upper Qg limit (u/MVAr)
0049 %    25 MU_QMIN     Kuhn-Tucker multiplier on lower Qg limit (u/MVAr)
0050 %
0051 %   See also DEFINE_CONSTANTS.
0052 
0053 %   MATPOWER
0054 %   Copyright (c) 1996-2016, Power Systems Engineering Research Center (PSERC)
0055 %   by Ray Zimmerman, PSERC Cornell
0056 %
0057 %   This file is part of MATPOWER.
0058 %   Covered by the 3-clause BSD License (see LICENSE file for details).
0059 %   See https://matpower.org for more info.
0060 
0061 %% define the indices
0062 GEN_BUS     = 1;    %% bus number
0063 PG          = 2;    %% Pg, real power output (MW)
0064 QG          = 3;    %% Qg, reactive power output (MVAr)
0065 QMAX        = 4;    %% Qmax, maximum reactive power output at Pmin (MVAr)
0066 QMIN        = 5;    %% Qmin, minimum reactive power output at Pmin (MVAr)
0067 VG          = 6;    %% Vg, voltage magnitude setpoint (p.u.)
0068 MBASE       = 7;    %% mBase, total MVA base of this machine, defaults to baseMVA
0069 GEN_STATUS  = 8;    %% status, 1 - machine in service, 0 - machine out of service
0070 PMAX        = 9;    %% Pmax, maximum real power output (MW)
0071 PMIN        = 10;   %% Pmin, minimum real power output (MW)
0072 PC1         = 11;   %% Pc1, lower real power output of PQ capability curve (MW)
0073 PC2         = 12;   %% Pc2, upper real power output of PQ capability curve (MW)
0074 QC1MIN      = 13;   %% Qc1min, minimum reactive power output at Pc1 (MVAr)
0075 QC1MAX      = 14;   %% Qc1max, maximum reactive power output at Pc1 (MVAr)
0076 QC2MIN      = 15;   %% Qc2min, minimum reactive power output at Pc2 (MVAr)
0077 QC2MAX      = 16;   %% Qc2max, maximum reactive power output at Pc2 (MVAr)
0078 RAMP_AGC    = 17;   %% ramp rate for load following/AGC (MW/min)
0079 RAMP_10     = 18;   %% ramp rate for 10 minute reserves (MW)
0080 RAMP_30     = 19;   %% ramp rate for 30 minute reserves (MW)
0081 RAMP_Q      = 20;   %% ramp rate for reactive power (2 sec timescale) (MVAr/min)
0082 APF         = 21;   %% area participation factor
0083 
0084 %% included in opf solution, not necessarily in input
0085 %% assume objective function has units, u
0086 MU_PMAX     = 22;   %% Kuhn-Tucker multiplier on upper Pg limit (u/MW)
0087 MU_PMIN     = 23;   %% Kuhn-Tucker multiplier on lower Pg limit (u/MW)
0088 MU_QMAX     = 24;   %% Kuhn-Tucker multiplier on upper Qg limit (u/MVAr)
0089 MU_QMIN     = 25;   %% Kuhn-Tucker multiplier on lower Qg limit (u/MVAr)
0090 
0091 %% Note: When a generator's PQ capability curve is not simply a box and the
0092 %% upper Qg limit is binding, the multiplier on this constraint is split into
0093 %% it's P and Q components and combined with the appropriate MU_Pxxx and
0094 %% MU_Qxxx values. Likewise for the lower Q limits.

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