Description of idx

DESCRIPTION

IDX_BRCH   Defines constants for named column indices to branch matrix.
   Example:

   [F_BUS, T_BUS, BR_R, BR_X, BR_B, RATE_A, RATE_B, RATE_C, ...
   TAP, SHIFT, BR_STATUS, PF, QF, PT, QT, MU_SF, MU_ST, ...
   ANGMIN, ANGMAX, MU_ANGMIN, MU_ANGMAX] = idx_brch;

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

    branch(4, BR_STATUS) = 0;              % take branch 4 out of service
    Ploss = branch(:, PF) + branch(:, PT); % compute real power loss vector
 
   The index, name and meaning of each column of the branch matrix is given
   below:

   columns 1-11 must be included in input matrix (in case file)
    1  F_BUS       f, from bus number
    2  T_BUS       t, to bus number
    3  BR_R        r, resistance (p.u.)
    4  BR_X        x, reactance (p.u.)
    5  BR_B        b, total line charging susceptance (p.u.)
    6  RATE_A      rateA, MVA rating A (long term rating)
    7  RATE_B      rateB, MVA rating B (short term rating)
    8  RATE_C      rateC, MVA rating C (emergency rating)
    9  TAP         ratio, transformer off nominal turns ratio
    10 SHIFT       angle, transformer phase shift angle (degrees)
    11 BR_STATUS   initial branch status, 1 - in service, 0 - out of service
    12 ANGMIN      minimum angle difference, angle(Vf) - angle(Vt) (degrees)
    13 ANGMAX      maximum angle difference, angle(Vf) - angle(Vt) (degrees)
                   (The voltage angle difference is taken to be unbounded below
                    if ANGMIN < -360 and unbounded above if ANGMAX > 360.
                    If both parameters are zero, it is unconstrained.)

   columns 14-17 are added to matrix after power flow or OPF solution
   they are typically not present in the input matrix
    14 PF          real power injected into "from" end of branch (MW)
    15 QF          reactive power injected into "from" end of branch (MVAr)
    16 PT          real power injected into "to" end of branch (MW)
    17 QT          reactive power injected into "to" end of branch (MVAr)

   columns 18-21 are added to matrix after OPF solution
   they are typically not present in the input matrix
                   (assume OPF objective function has units, u)
    18 MU_SF       Kuhn-Tucker multiplier on MVA limit at "from" bus (u/MVA)
    19 MU_ST       Kuhn-Tucker multiplier on MVA limit at "to" bus (u/MVA)
    20 MU_ANGMIN   Kuhn-Tucker multiplier lower angle difference limit (u/degree)
    21 MU_ANGMAX   Kuhn-Tucker multiplier upper angle difference limit (u/degree)

   See also DEFINE_CONSTANTS.

CROSS-REFERENCE INFORMATION

check_feasibility CHECK_FEASIBILITY Returns the maximum constraint violation in p.u.

makeBloss [BL2, BL1, BL0] = MAKEBLOSS(MPC)

make_opf_feasible MAKE_OPF_FEASIBLE Attempts to relax constraints to make an OPF feasible.

insolvablepf INSOLVABLEPF A sufficient condition for power flow insolvability

insolvablepf_limitQ INSOLVABLEPF_LIMITQ A sufficient condition for power flow insolvability

makeIncidence MAKEINCIDENCE Builds the bus incidence matrix.

makesdpmat MAKESDPMAT Creates the matrix functions used in the semidefinite

sdpopf_solver SDPOPF_SOLVER A semidefinite programming relaxtion of the OPF problem

t_insolvablepf T_INSOLVABLEPF Test for power flow insolvability condition

t_insolvablepf_limitQ T_INSOLVABLEPF_LIMITQ Test for power flow insolvability condition

t_insolvablepfsos T_INSOLVABLEPF Test for power flow insolvability condition

t_insolvablepfsos_limitQ T_INSOLVABLEPF Test for power flow insolvability condition

t_opf_sdpopf T_OPF_SDPOPF Tests for SDP-based AC optimal power flow.

t_testglobalopt T_TESTGLOBALOPT Test for Global Optimality Condition

testGlobalOpt TESTGLOABALOPT A sufficient condition for OPF global optimality

doSE DOSE Do state estimation.

getV0 GETV0 Get initial voltage profile for power flow calculation.

outputpfsoln OUTPUTPFSOLN Output power flow solution.

runse RUNSE Runs a state estimator.

state_est STATE_EST Solves a state estimation problem.

sgvm_branch_perm SGVM_BRANCH_PERM permute the branch properties of the mpc case

sgvm_minqflow SGVM_MINQFLOW minimize magintude of reactive flows by adding shunts

syngrid SYNGRID Create a synthetic power grid model in MATPOWER format.

t_syngrid T_SYNGRID Tests for syngrid().

apply_changes APPLY_CHANGES Applies a set of changes to a MATPOWER case

calc_branch_angle CALC_BRANCH_ANGLE Calculate branch angle differences across active branches

case_info CASE_INFO Prints information about islands in a network.

cdf2mpc CDF2MPC Converts an IEEE CDF data file into a MATPOWER case struct.

compare_case COMPARE_CASE Compares the bus, gen, branch matrices of 2 MATPOWER cases.

cpf_flim_event CPF_FLIM_EVENT Event function to detect branch flow limit (MVA) violations

cpf_flim_event_cb CPF_FLIM_EVENT_CB Callback to handle FLIM events

dSbr_dV DSBR_DV Computes partial derivatives of branch power flows w.r.t. voltage.

dcopf_solver DCOPF_SOLVER Solves a DC optimal power flow.

define_constants DEFINE_CONSTANTS Defines useful constants for indexing data, etc.

ext2int EXT2INT Converts external to internal indexing.

extract_islands function mpck = extract_islands(mpc, groups, k, custom)

find_islands FIND_ISLANDS Finds islands in a network

get_losses GET_LOSSES Returns series losses (and reactive injections) per branch.

int2ext INT2EXT Converts internal to external bus numbering.

loadcase LOADCASE Load .m or .mat case files or data struct in MATPOWER format.

makeAang MAKEAANG Construct constraints for branch angle difference limits.

makeB MAKEB Builds the FDPF matrices, B prime and B double prime.

makeBdc MAKEBDC Builds the B matrices and phase shift injections for DC power flow.

makeLODF MAKELODF Builds the line outage distribution factor matrix.

makeYbus MAKEYBUS Builds the bus admittance matrix and branch admittance matrices.

nlpopf_solver NLPOPF_SOLVER Solves AC optimal power flow using MP-Opt-Model.

opf OPF Solves an optimal power flow.

opf_branch_flow_fcn OPF_BRANCH_FLOW_FCN Evaluates AC branch flow constraints and Jacobian.

opf_branch_flow_hess OPF_BRANCH_FLOW_HESS Evaluates Hessian of branch flow constraints.

opf_execute OPF_EXECUTE Executes the OPF specified by an OPF model object.

opf_setup OPF Constructs an OPF model object from a MATPOWER case struct.

pfsoln PFSOLN Updates bus, gen, branch data structures to match power flow soln.

printpf PRINTPF Prints power flow results.

psse_convert PSSE_CONVERT Converts data read from PSS/E RAW file to MATPOWER case.

psse_convert_xfmr PSSE_CONVERT_XFMR Convert transformer data from PSS/E RAW to MATPOWER

runcpf RUNCPF Runs a full AC continuation power flow

runpf RUNPF Runs a power flow.

save2psse SAVE2PSSE Saves a MATPOWER case to PSS/E RAW format.

savecase SAVECASE Saves a MATPOWER case file, given a filename and the data.

t_apply_changes T_APPLY_CHANGES Tests for code in apply_changes.m.

t_cpf T_CPF Tests for continuation power flow.

t_dcline T_DCLINE Tests for DC line extension in TOGGLE_DCLINE.

t_get_losses T_GET_LOSSES Tests for code in GET_LOSSES.

t_hessian T_HESSIAN Numerical tests of 2nd derivative code.

t_islands T_ISLANDS Tests for FIND_ISLANDS, EXTRACT_ISLANDS, CONNECTED_COMPONENTS and CASE_INFO.

t_jacobian T_JACOBIAN Numerical tests of partial derivative code.

t_load2disp T_LOAD2DISP Tests for LOAD2DISP.

t_loadcase T_LOADCASE Test that LOADCASE works with a struct as well as case file.

t_makeLODF T_MAKELODF Tests for MAKELODF.

t_makePTDF T_MAKEPTDF Tests for MAKEPTDF.

t_opf_dc_bpmpd T_OPF_DC_BPMPD Tests for DC optimal power flow using BPMPD_MEX solver.

t_opf_dc_clp T_OPF_DC_CLP Tests for DC optimal power flow using CLP solver.

t_opf_dc_cplex T_OPF_DC_CPLEX Tests for DC optimal power flow using CPLEX solver.

t_opf_dc_default T_OPF_DC_DEFAULT Tests for DC optimal power flow using DEFAULT solver.

t_opf_dc_glpk T_OPF_DC_GLPK Tests for DC optimal power flow using GLPK solver.

t_opf_dc_gurobi T_OPF_DC_GUROBI Tests for DC optimal power flow using Gurobi solver.

t_opf_dc_ipopt T_OPF_DC_MIPS Tests for DC optimal power flow using MIPS solver.

t_opf_dc_mips T_OPF_DC_MIPS Tests for DC optimal power flow using MIPS solver.

t_opf_dc_mips_sc T_OPF_DC_MIPS_SC Tests for DC optimal power flow using MIPS-sc solver.

t_opf_dc_mosek T_OPF_DC_MOSEK Tests for DC optimal power flow using MOSEK solver.

t_opf_dc_osqp T_OPF_DC_OSQP Tests for DC optimal power flow using OSQP solver.

t_opf_dc_ot T_OPF_DC_OT Tests for DC optimal power flow using Opt Tbx solvers.

t_opf_default T_OPF_DEFAULT Tests for AC optimal power flow using default solver.

t_opf_fmincon T_OPF_FMINCON Tests for FMINCON-based optimal power flow.

t_opf_ipopt T_OPF_IPOPT Tests for IPOPT-based AC optimal power flow.

t_opf_knitro T_OPF_FMINCON Tests for FMINCON-based optimal power flow.

t_opf_minopf T_OPF_MINOPF Tests for MINOS-based optimal power flow.

t_opf_mips T_OPF_MIPS Tests for MIPS-based AC optimal power flow.

t_opf_model T_OPF_MODEL Tests for OPF_MODEL.

t_opf_model_legacy T_OPF_MODEL_LEGACY Tests for OPF_MODEL, using the deprecated ADD_CONSTRAINTS.

t_opf_softlims T_OPF_SOFTLIMS Tests for userfcn callbacks (softlims) w/OPF.

t_opf_tspopf_pdipm T_OPF_TSPOPF_PDIPM Tests for PDIPM-based optimal power flow.

t_opf_tspopf_scpdipm T_OPF_TSPOPF_SCPDIPM Tests for SCPDIPM-based optimal power flow.

t_opf_tspopf_tralm T_OPF_TSPOPF_TRALM Tests for TRALM-based optimal power flow.

t_opf_userfcns T_OPF_USERFCNS Tests for userfcn callbacks (reserves/iflims) w/OPF.

t_pf_ac T_PF_AC Tests for AC power flow solvers.

t_pf_dc T_PF_DC Tests for DC power flow solver.

t_pf_radial T_PF_RADIAL Tests for distribution power flow solvers.

t_printpf T_PRINTPF Tests for PRINTPF.

t_vdep_load T_VDEP_LOAD Test voltage dependent ZIP load model for PF, CPF, OPF.

toggle_iflims TOGGLE_IFLIMS Enable, disable or check status of set of interface flow limits.

toggle_softlims TOGGLE_SOFTLIMS Relax DC optimal power flow branch limits.

most MOST MATPOWER Optimal Scheduling Tool

most_summary MOST_SUMMARY Collects and optionally prints a summary of MOST results.

ex_contab EX_CONTAB Example contingency data for stochastic unit commitment.

t_most_30b_1_1_0 T_MOST_30B_1_1_0 Tests for MOST.

t_most_30b_1_1_0_uc T_MOST_30B_1_1_0_UC Tests for MOST.

t_most_30b_1_1_17 T_MOST_30B_1_1_17 Tests for MOST.

t_most_30b_3_1_0 T_MOST_30B_3_1_0 Tests for MOST.

t_most_30b_3_1_17 T_MOST_30B_3_1_17 Tests for MOST.

t_most_3b_1_1_0 T_MOST_3B_1_1_0 Tests for MOST.

t_most_3b_1_1_2 T_MOST_3B_1_1_2 Tests for MOST.

t_most_3b_3_1_0 T_MOST_3B_3_1_0 Tests for MOST.

t_most_3b_3_1_2 T_MOST_3B_1_1_2 Tests for MOST.

t_most_sp T_MOST_SP Tests of single-period continuous optimizations

t_most_spuc T_MOST_SPUC Tests of single-period unit commitment optimizations

t_most_suc T_MOST_SUC Tests of stochastic unit commitment optimizations.

t_most_uc T_MOST_UC Tests of deteministic unit commitment optimizations

t_most_w_ds T_MOST_W_DS Test for MOST with dynamical system constraints.

SOURCE CODE

0001 function [F_BUS, T_BUS, BR_R, BR_X, BR_B, RATE_A, RATE_B, ...
0002     RATE_C, TAP, SHIFT, BR_STATUS, PF, QF, PT, QT, MU_SF, MU_ST, ...
0003     ANGMIN, ANGMAX, MU_ANGMIN, MU_ANGMAX] = idx_brch
0004 %IDX_BRCH   Defines constants for named column indices to branch matrix.
0005 %   Example:
0006 %
0007 %   [F_BUS, T_BUS, BR_R, BR_X, BR_B, RATE_A, RATE_B, RATE_C, ...
0008 %   TAP, SHIFT, BR_STATUS, PF, QF, PT, QT, MU_SF, MU_ST, ...
0009 %   ANGMIN, ANGMAX, MU_ANGMIN, MU_ANGMAX] = idx_brch;
0010 %
0011 %   Some examples of usage, after defining the constants using the line above,
0012 %   are:
0013 %
0014 %    branch(4, BR_STATUS) = 0;              % take branch 4 out of service
0015 %    Ploss = branch(:, PF) + branch(:, PT); % compute real power loss vector
0016 %
0017 %   The index, name and meaning of each column of the branch matrix is given
0018 %   below:
0019 %
0020 %   columns 1-11 must be included in input matrix (in case file)
0021 %    1  F_BUS       f, from bus number
0022 %    2  T_BUS       t, to bus number
0023 %    3  BR_R        r, resistance (p.u.)
0024 %    4  BR_X        x, reactance (p.u.)
0025 %    5  BR_B        b, total line charging susceptance (p.u.)
0026 %    6  RATE_A      rateA, MVA rating A (long term rating)
0027 %    7  RATE_B      rateB, MVA rating B (short term rating)
0028 %    8  RATE_C      rateC, MVA rating C (emergency rating)
0029 %    9  TAP         ratio, transformer off nominal turns ratio
0030 %    10 SHIFT       angle, transformer phase shift angle (degrees)
0031 %    11 BR_STATUS   initial branch status, 1 - in service, 0 - out of service
0032 %    12 ANGMIN      minimum angle difference, angle(Vf) - angle(Vt) (degrees)
0033 %    13 ANGMAX      maximum angle difference, angle(Vf) - angle(Vt) (degrees)
0034 %                   (The voltage angle difference is taken to be unbounded below
0035 %                    if ANGMIN < -360 and unbounded above if ANGMAX > 360.
0036 %                    If both parameters are zero, it is unconstrained.)
0037 %
0038 %   columns 14-17 are added to matrix after power flow or OPF solution
0039 %   they are typically not present in the input matrix
0040 %    14 PF          real power injected into "from" end of branch (MW)
0041 %    15 QF          reactive power injected into "from" end of branch (MVAr)
0042 %    16 PT          real power injected into "to" end of branch (MW)
0043 %    17 QT          reactive power injected into "to" end of branch (MVAr)
0044 %
0045 %   columns 18-21 are added to matrix after OPF solution
0046 %   they are typically not present in the input matrix
0047 %                   (assume OPF objective function has units, u)
0048 %    18 MU_SF       Kuhn-Tucker multiplier on MVA limit at "from" bus (u/MVA)
0049 %    19 MU_ST       Kuhn-Tucker multiplier on MVA limit at "to" bus (u/MVA)
0050 %    20 MU_ANGMIN   Kuhn-Tucker multiplier lower angle difference limit (u/degree)
0051 %    21 MU_ANGMAX   Kuhn-Tucker multiplier upper angle difference limit (u/degree)
0052 %
0053 %   See also DEFINE_CONSTANTS.
0054 
0055 %   MATPOWER
0056 %   Copyright (c) 1996-2016, Power Systems Engineering Research Center (PSERC)
0057 %   by Ray Zimmerman, PSERC Cornell
0058 %
0059 %   This file is part of MATPOWER.
0060 %   Covered by the 3-clause BSD License (see LICENSE file for details).
0061 %   See https://matpower.org for more info.
0062 
0063 %% define the indices
0064 F_BUS       = 1;    %% f, from bus number
0065 T_BUS       = 2;    %% t, to bus number
0066 BR_R        = 3;    %% r, resistance (p.u.)
0067 BR_X        = 4;    %% x, reactance (p.u.)
0068 BR_B        = 5;    %% b, total line charging susceptance (p.u.)
0069 RATE_A      = 6;    %% rateA, MVA rating A (long term rating)
0070 RATE_B      = 7;    %% rateB, MVA rating B (short term rating)
0071 RATE_C      = 8;    %% rateC, MVA rating C (emergency rating)
0072 TAP         = 9;    %% ratio, transformer off nominal turns ratio
0073 SHIFT       = 10;   %% angle, transformer phase shift angle (degrees)
0074 BR_STATUS   = 11;   %% initial branch status, 1 - in service, 0 - out of service
0075 ANGMIN      = 12;   %% minimum angle difference, angle(Vf) - angle(Vt) (degrees)
0076 ANGMAX      = 13;   %% maximum angle difference, angle(Vf) - angle(Vt) (degrees)
0077 
0078 %% included in power flow solution, not necessarily in input
0079 PF          = 14;   %% real power injected at "from" bus end (MW)       (not in PTI format)
0080 QF          = 15;   %% reactive power injected at "from" bus end (MVAr) (not in PTI format)
0081 PT          = 16;   %% real power injected at "to" bus end (MW)         (not in PTI format)
0082 QT          = 17;   %% reactive power injected at "to" bus end (MVAr)   (not in PTI format)
0083 
0084 %% included in opf solution, not necessarily in input
0085 %% assume objective function has units, u
0086 MU_SF       = 18;   %% Kuhn-Tucker multiplier on MVA limit at "from" bus (u/MVA)
0087 MU_ST       = 19;   %% Kuhn-Tucker multiplier on MVA limit at "to" bus (u/MVA)
0088 MU_ANGMIN   = 20;   %% Kuhn-Tucker multiplier lower angle difference limit (u/degree)
0089 MU_ANGMAX   = 21;   %% Kuhn-Tucker multiplier upper angle difference limit (u/degree)

idx_brch

PURPOSE

SYNOPSIS

DESCRIPTION

CROSS-REFERENCE INFORMATION

SOURCE CODE