📄 caseformat.m
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%CASEFORMAT Defines the MATPOWER case file format.% A MATPOWER case file is an M-file or MAT-file which defines the variables% baseMVA, bus, gen, branch, areas, and gencost. With the exception of% baseMVA, a scalar, each data variable is a matrix, where a row corresponds% to a single bus, branch, gen, etc. The format of the data is similar to% the PTI format described in% http://www.ee.washington.edu/research/pstca/formats/pti.txt% except where noted. An item marked with (+) indicates that it is included% in this data but is not part of the PTI format. An item marked with (-) is% one that is in the PTI format but is not included here. Those marked with% (2) were added for version 2 of the case file format. The columns for% each data matrix are given below.%% MATPOWER Case Version Information:% A version 1 case file defined the data matrices directly. The last two,% areas and gencost, were optional since they were not needed for running% a simple power flow. In version 2, each of the data matrices are stored% as fields in a struct. It is this struct, rather than the individual% matrices that is returned by a version 2 M-casefile. Likewise a version 2% MAT-casefile stores a struct named 'mpc' (for MATPOWER case). The struct% also contains a 'version' field so MATPOWER knows how to interpret the% data. Any case file which does not return a struct, or any struct which% does not have a 'version' field is considered to be in version 1 format.%% See also IDX_BUS, IDX_BRCH, IDX_GEN, IDX_AREA and IDX_COST regarding% constants which can be used as named column indices for the data matrices.% Also described in the first three are additional columns that are added% to the bus, branch and gen matrices by the power flow and OPF solvers.%% Bus Data Format% 1 bus number (1 to 29997)% 2 bus type% PQ bus = 1% PV bus = 2% reference bus = 3% isolated bus = 4% 3 Pd, real power demand (MW)% 4 Qd, reactive power demand (MVAr)% 5 Gs, shunt conductance (MW (demanded) at V = 1.0 p.u.)% 6 Bs, shunt susceptance (MVAr (injected) at V = 1.0 p.u.)% 7 area number, 1-100% 8 Vm, voltage magnitude (p.u.)% 9 Va, voltage angle (degrees)% (-) (bus name)% 10 baseKV, base voltage (kV)% 11 zone, loss zone (1-999)% (+) 12 maxVm, maximum voltage magnitude (p.u.)% (+) 13 minVm, minimum voltage magnitude (p.u.)%% Generator Data Format% 1 bus number% (-) (machine identifier, 0-9, A-Z)% 2 Pg, real power output (MW)% 3 Qg, reactive power output (MVAr)% 4 Qmax, maximum reactive power output (MVAr)% 5 Qmin, minimum reactive power output (MVAr)% 6 Vg, voltage magnitude setpoint (p.u.)% (-) (remote controlled bus index)% 7 mBase, total MVA base of this machine, defaults to baseMVA% (-) (machine impedance, p.u. on mBase)% (-) (step up transformer impedance, p.u. on mBase)% (-) (step up transformer off nominal turns ratio)% 8 status, > 0 - machine in service% <= 0 - machine out of service% (-) (% of total VAr's to come from this gen in order to hold V at% remote bus controlled by several generators)% 9 Pmax, maximum real power output (MW)% 10 Pmin, minimum real power output (MW)% (2) 11 Pc1, lower real power output of PQ capability curve (MW)% (2) 12 Pc2, upper real power output of PQ capability curve (MW)% (2) 13 Qc1min, minimum reactive power output at Pc1 (MVAr)% (2) 14 Qc1max, maximum reactive power output at Pc1 (MVAr)% (2) 15 Qc2min, minimum reactive power output at Pc2 (MVAr)% (2) 16 Qc2max, maximum reactive power output at Pc2 (MVAr)% (2) 17 ramp rate for load following/AGC (MW/min)% (2) 18 ramp rate for 10 minute reserves (MW)% (2) 19 ramp rate for 30 minute reserves (MW)% (2) 20 ramp rate for reactive power (2 sec timescale) (MVAr/min)% (2) 21 APF, area participation factor%% Branch Data Format% 1 f, from bus number% 2 t, to bus number% (-) (circuit identifier)% 3 r, resistance (p.u.)% 4 x, reactance (p.u.)% 5 b, total line charging susceptance (p.u.)% 6 rateA, MVA rating A (long term rating)% 7 rateB, MVA rating B (short term rating)% 8 rateC, MVA rating C (emergency rating)% 9 ratio, transformer off nominal turns ratio ( = 0 for lines )% (taps at 'from' bus, impedance at 'to' bus, i.e. ratio = Vf / Vt)% 10 angle, transformer phase shift angle (degrees)% (-) (Gf, shunt conductance at from bus p.u.)% (-) (Bf, shunt susceptance at from bus p.u.)% (-) (Gt, shunt conductance at to bus p.u.)% (-) (Bt, shunt susceptance at to bus p.u.)% 11 initial branch status, 1 - in service, 0 - out of service% (2) 12 minimum angle difference, angle(Vf) - angle(Vt) (degrees)% (2) 13 maximum angle difference, angle(Vf) - angle(Vt) (degrees)%% (+) Area Data Format% 1 i, area number% 2 price_ref_bus, reference bus for that area% % (+) Generator Cost Data Format% NOTE: If gen has n rows, then the first n rows of gencost contain% the cost for active power produced by the corresponding generators.% If gencost has 2*n rows then rows n+1 to 2*n contain the reactive% power costs in the same format.% 1 model, 1 - piecewise linear, 2 - polynomial% 2 startup, startup cost in US dollars% 3 shutdown, shutdown cost in US dollars% 4 n, number of cost coefficients to follow for polynomial% cost function, or number of data points for piecewise linear% 5 and following, cost data defining total cost function% For polynomial cost:% c2, c1, c0% where the polynomial is c0 + c1*P + c2*P^2% For piecewise linear cost:% x0, y0, x1, y1, x2, y2, ...% where x0 < x1 < x2 < ... and the points (x0,y0), (x1,y1),% (x2,y2), ... are the end- and break-points of the cost function.% MATPOWER% $Id: caseformat.m,v 1.7 2005/10/14 16:47:24 ray Exp $% by Ray Zimmerman, PSERC Cornell% Copyright (c) 1996-2005 by Power System Engineering Research Center (PSERC)% See http://www.pserc.cornell.edu/matpower/ for more info.⌨️ 快捷键说明
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