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第三版目录。
" @* w1 n* c* v. s1 Introduction 1
" G0 @/ H1 {4 c' L' j( o1.1 Purpose of the Course / 1
, `; D: W; E( t1.2 Course Scope / 2/ v8 f; y. P2 n$ C5 v3 P7 ?# \
1.3 Economic Importance / 2& c2 j+ h# }9 Q0 [4 q
1.4 Deregulation: Vertical to Horizontal / 37 U" Z$ {: V8 M' p, a
1.5 Problems: New and Old / 3
, {2 X# b- w: ~7 \7 _# N1.6 Characteristics of Steam Units / 6
2 @0 H9 M7 |7 ]' a1 D1.6.1 Variations in Steam Unit Characteristics / 10
9 I& I9 i; J" v$ y. S% o4 @1.6.2 Combined Cycle Units / 139 J8 L B. R: h9 {; f1 Q: p, t
1.6.3 Cogeneration Plants / 14
; @6 B0 v# V* e& V) {. S" h6 w$ O1.6.4 Light-Water Moderated Nuclear Reactor Units / 17* k& c1 v, W: C8 _% m; v$ U% B
1.6.5 Hydroelectric Units / 18
! }. g' W1 v6 w$ T# k; A& }: C1.6.6 Energy Storage / 21
* J) }$ H/ Y/ m8 M8 y1.7 Renewable Energy / 222 }9 L/ F* l6 F" Q u. k' l
1.7.1 Wind Power / 23: `/ M3 |4 [! J& W
1.7.2 Cut-In Speed / 23# t3 v6 K& d" d3 k
1.7.3 Rated Output Power and Rated Output Wind Speed / 24
, a( k" {# ^/ V8 g1.7.4 Cut-Out Speed / 24
1 `! Z. m0 c, Q( d; e1.7.5 Wind Turbine Efficiency or Power Coefficient / 24. f+ q9 V; Y0 J9 `; O% ^3 A
1.7.6 Solar Power / 256 v; R |+ M- p
APPENDIX 1A Typical Generation Data / 26
( {% l7 [; f, y0 gAPPENDIX 1B Fossil Fuel Prices / 28* g8 v' L% I) k) `/ I
APPENDIX 1C Unit Statistics / 29" Y. a% q/ k2 g5 K! H
CONTENTS1 z& M0 |1 ]$ y+ s- P
viii contents
4 t$ P0 W& E& w) x3 { P! [References for Generation Systems / 31" w H1 L8 Y( N- {$ k- [, Z
Further Reading / 31# `" M' R1 |8 @
2 Industrial Organization, Managerial Economics, and Finance 35" u; j% X' {5 G8 X
2.1 Introduction / 35
8 }* d# O1 `. o+ g. H, r6 {2.2 Business Environments / 36
4 i4 j0 M3 l. ~5 @, D. o* {) b2.2.1 Regulated Environment / 37; }) b: U/ _" |
2.2.2 Competitive Market Environment / 38
: J% E. T- K R2 H1 K* v- [2.3 Theory of the Firm / 40: k+ T9 A+ h$ G8 }
2.4 Competitive Market Solutions / 42; j: b) }# z" e# ^% I8 ^, Y
2.5 Supplier Solutions / 45' T. Y1 a: S# ~0 O: j1 W8 N
2.5.1 Supplier Costs / 46: c( n% ?+ z; x2 h
2.5.2 Individual Supplier Curves / 469 p2 e5 R7 Y: ^. v
2.5.3 Competitive Environments / 47
3 P* ^% P7 A+ M6 ?2.5.4 Imperfect Competition / 51( x" t! O7 G! ]+ Y5 s5 T5 O2 w
2.5.5 Other Factors / 52
$ z9 {) ]6 q" F- l4 h; d# A2.6 Cost of Electric Energy Production / 534 H1 F9 j0 p. v7 {
2.7 Evolving Markets / 54
% Z+ C8 m A6 S' L a O4 J; K% r2.7.1 Energy Flow Diagram / 575 C$ _( K5 p7 S6 D {
2.8 Multiple Company Environments / 58+ L/ O; m6 g$ T* H
2.8.1 Leontief Model: Input–Output Economics / 580 ?0 R0 A" H; q8 R; d0 b
2.8.2 Scarce Fuel Resources / 60
; Z9 s3 ~9 { \2.9 Uncertainty and Reliability / 61
. }6 q0 ?2 V$ xPROBLEMS / 616 W" L/ D' E; s( [" m2 [" m6 n$ Q
Reference / 62
4 R# v3 A$ E. c1 o% i$ f3 Economic Dispatch of Thermal Units and Methods of Solution 639 I; F! D0 j, D6 P- D2 M) v
3.1 The Economic Dispatch Problem / 63
6 t1 p$ g1 {" }% c3.2 Economic Dispatch with Piecewise Linear Cost Functions / 68% j. V0 z( Y% o% q7 d% D
3.3 LP Method / 69
: |( S3 S) u5 k* o8 `. B3.3.1 Piecewise Linear Cost Functions / 69
+ F% s/ U# F3 q, n; i* C3.3.2 Economic Dispatch with LP / 71
9 Y- A9 E0 u D; K6 R3 q) Y5 Q1 R: G3.4 The Lambda Iteration Method / 73
( m8 D. q0 y/ q% S: @3.5 Economic Dispatch Via Binary Search / 76, L3 K7 P) \" K! D: p: K W+ ~& g
3.6 Economic Dispatch Using Dynamic Programming / 78
' y6 s. u) N0 k6 X; y6 b! a6 A3.7 Composite Generation Production Cost Function / 81
* |' S" }" C( F: h3.8 Base Point and Participation Factors / 85
% e. i# h0 E8 p6 ~0 U! [& A3.9 Thermal System Dispatching with Network Losses
* ]. M8 ?' r: n. V5 w6 pConsidered / 88
; b! y3 A2 r3 u t% T* M# W: F0 R8 lcontents ix
1 {% z4 w' m$ z5 }# X" m, `' X3.10 The Concept of Locational Marginal Price (LMP) / 92
6 `6 w* N0 E3 X; i# k5 g3.11 Auction Mechanisms / 95
$ ?& Z0 G* ?! t2 _6 S* r6 w3.11.1 PJM Incremental Price Auction as a. i G* A% z. z* J$ T: b5 B& W
Graphical Solution / 95: R$ F+ O% P4 G9 P! U
3.11.2 Auction Theory Introduction / 98" t: }' M, p/ ?
3.11.3 Auction Mechanisms / 100$ T" x3 E/ ~) m
3.11.4 English (First-Price Open-Cry = Ascending) / 101
. f, o8 ^: F; x1 j3.11.5 Dutch (Descending) / 103
/ [+ p0 i! ]( n2 ?9 ~/ g3.11.6 First-Price Sealed Bid / 1041 }/ N: V( l5 {
3.11.7 Vickrey (Second-Price Sealed Bid) / 1057 ?& w) P$ q/ x/ W; V& ?
3.11.8 All Pay (e.g., Lobbying Activity) / 1054 z9 A! T; ?1 r' O: n( k
APPENDIX 3A Optimization Within Constraints / 106
5 X& j! Y& h/ I' A2 Z1 [8 mAPPENDIX 3B Linear Programming (LP) / 117
_2 z) G3 M H( T$ e- M3 f3 TAPPENDIX 3C Non-Linear Programming / 128
9 R/ }- g1 i$ I0 }9 s3 q9 tAPPENDIX 3D Dynamic Programming (DP) / 128; k& @" ` E7 L0 x' E( m, r& Q
APPENDIX 3E Convex Optimization / 135: Q4 l# t% ]" M6 k
PROBLEMS / 138
. F4 O3 Q, y! o5 oReferences / 146; Y- v& Q# C& b3 M$ h
4 Unit Commitment 1473 v2 _, y7 p6 @% v. f4 v
4.1 Introduction / 147 S% L+ ^" I8 L
4.1.1 Economic Dispatch versus Unit Commitment / 147
6 e5 Y* N F; X! K6 [4.1.2 Constraints in Unit Commitment / 1529 s7 r- e+ i! {! t
4.1.3 Spinning Reserve / 152& p% @ L8 W* u& h# |$ \
4.1.4 Thermal Unit Constraints / 153
9 ^& x- h2 Q# ?+ m% o( ~4.1.5 Other Constraints / 155
* m+ {# e$ h: i% |2 g0 I' c/ Q4 S4 o# i4.2 Unit Commitment Solution Methods / 155
% ]* }! G @- ?6 o- N; g4.2.1 Priority-List Methods / 156
7 H: e, D! C+ `: n2 P9 [4.2.2 Lagrange Relaxation Solution / 157
# J; |8 t6 q6 o2 P. l% n# O3 _4.2.3 Mixed Integer Linear Programming / 1664 u. s0 n" Z* H' h5 \5 y
4.3 Security-Constrained Unit Commitment (SCUC) / 167
" d+ G% O9 r r& I0 l V4.4 Daily Auctions Using a Unit Commitment / 167
' [+ W% I& w# ]0 o2 p# w% H& z4 c" v, SAPPENDIX 4A Dual Optimization on a Nonconvex
" d: d6 V% B' B# @* ~+ J f9 TProblem / 1679 f4 L9 i- T& b" V8 [
APPENDIX 4B Dynamic-Programming Solution to' v3 g; B6 @% R8 m
Unit Commitment / 173
, w1 x6 d' g( x P e$ l y* w4B.1 Introduction / 1736 ~ V& ^8 Y7 Y {! B
4B.2 Forward DP Approach / 174* ?6 }* X" M2 @. K# b+ `: \
PROBLEMS / 182
9 U: q, J% T, ?! D' z, ix contents! ~* q( ~% u) E' q% |* J
5 Generation with Limited Energy Supply 1870 z* m/ h: }' l4 N; U- a" r e
5.1 Introduction / 1874 u+ ]6 L F6 b0 G
5.2 Fuel Scheduling / 1880 a0 F3 X% ^8 b m' F
5.3 Take-or-Pay Fuel Supply Contract / 188$ o' E9 R5 j) z0 h2 M/ I
5.4 Complex Take-or-Pay Fuel Supply Models / 194 Q) Y5 v0 ~4 R/ ~6 ~- v
5.4.1 Hard Limits and Slack Variables / 194/ M5 S0 P0 p# T+ U' ~! N
5.5 Fuel Scheduling by Linear Programming / 1954 M0 i4 C/ f; x2 o/ m
5.6 Introduction to Hydrothermal Coordination / 202' L$ ^# O; |0 P3 _
5.6.1 Long-Range Hydro-Scheduling / 203
5 v* R i/ F6 v: G, ~" E5.6.2 Short-Range Hydro-Scheduling / 204
; ?! e& {2 I. } r7 S" I, M5.7 Hydroelectric Plant Models / 204+ |' Y& T. c0 x; G+ z0 \
5.8 Scheduling Problems / 207
" _. o8 r! m" u5.8.1 Types of Scheduling Problems / 2072 H- ]2 G# A4 V+ E( \$ e3 b; S6 O
5.8.2 Scheduling Energy / 207
: [ B( M' Q6 K5.9 The Hydrothermal Scheduling Problem / 211* N) L: p+ Z4 E" I
5.9.1 Hydro-Scheduling with Storage Limitations / 211, U) Q. ?- T1 H; \$ A6 M
5.9.2 Hydro-Units in Series (Hydraulically Coupled) / 216
4 y3 @( b6 Q: ?5.9.3 Pumped-Storage Hydroplants / 218
. A6 G( K: V% R' w( z3 Q: Q5.10 Hydro-Scheduling using Linear Programming / 222
0 N4 q7 ?, R; G+ ^) z# Y+ N+ j* sAPPENDIX 5A Dynamic-Programming Solution to hydrothermal$ ]5 i* B& V1 y8 v Y
Scheduling / 225
- u/ s2 v9 t. |. Y7 d4 h$ Q8 Z, w5.A.1 Dynamic Programming Example / 2274 c _/ T" X j) U
5.A.1.1 Procedure / 228. `7 S# {4 h* d: ?9 X, P! j/ n) y6 P
5.A.1.2 Extension to Other Cases / 231
* M/ h m: _( w6 t5.A.1.3 Dynamic-Programming Solution to Multiple Hydroplant
) Y. b* d+ H' T4 t7 b* e. }Problem / 232
8 W( X1 ~" s# l/ @( x4 ]PROBLEMS / 234
$ N) L1 ~8 p- }. q# z6 Transmission System Effects 243/ Z# j/ U+ c0 E" u' G# x. s
6.1 Introduction / 243
?: b. Y2 o* K" r# U' ~6.2 Conversion of Equipment Data to Bus and Branch Data / 247
4 Z& N1 ?. D v6.3 Substation Bus Processing / 248. [ u' p7 T% X; R4 y& b1 m) `
6.4 Equipment Modeling / 248
& @3 g, X2 ^& V4 g* e6.5 Dispatcher Power Flow for Operational Planning / 2516 y; ^; u" \, r( D: _
6.6 Conservation of Energy (Tellegen’s Theorem) / 2529 b$ z" w0 D+ N7 ~2 V
6.7 Existing Power Flow Techniques / 253
/ \! i8 n" T: R7 v, u# t- s7 \6.8 The Newton–Raphson Method Using the Augmented
2 P4 D" |3 c( s) J' i1 NJacobian Matrix / 254$ I* @* b! U& B
6.8.1 Power Flow Statement / 2544 I$ [1 f* ?+ p3 X9 l
6.9 Mathematical Overview / 2570 u2 p$ N5 L7 s' R/ A3 X
contents xi
% Q+ T3 }; v2 K+ B) O6.10 AC System Control Modeling / 259
+ X2 S- k q3 j% T: a) ?6.11 Local Voltage Control / 2599 [" d) l b' T6 \9 i8 G! H2 [1 `$ S
6.12 Modeling of Transmission Lines and Transformers / 259
! |. h6 C, N1 k6 w& \& }6.12.1 Transmission Line Flow Equations / 259
) c$ l3 Y& {3 ^- m+ m. J6.12.2 Transformer Flow Equations / 260
2 C: _' K0 V& }2 U6.13 HVDC links / 261
( j8 m. t! W9 t# R' A* `6.13.1 Modeling of HVDC Converters; D& E# x! P( {1 R0 D
and FACT Devices / 264. Q, m% z; K5 k( b9 \- H6 W
6.13.2 Definition of Angular Relationships in0 V: `6 v# r, d. `; S* x3 |
HVDC Converters / 264
7 `1 z$ V, d' F6.13.3 Power Equations for a Six-Pole HVDC/ [% O1 g% [% n# }+ ^3 K2 C
Converter / 2642 V) f1 l9 T+ i# D6 A% S- n3 ]
6.14 Brief Review of Jacobian Matrix Processing / 2676 F7 M' H4 w8 W
6.15 Example 6A: AC Power Flow Case / 269, r, i. t( f0 n
6.16 The Decoupled Power Flow / 271
# h4 W# o$ D5 p8 T6.17 The Gauss–Seidel Method / 275
3 o) v Y) x% S2 Q5 m- p) G6.18 The “DC” or Linear Power Flow / 277% g1 P& f, O0 w- S6 f0 D9 C) p
6.18.1 DC Power Flow Calculation / 277
f7 x# w7 W5 X% K* t8 {6.18.2 Example 6B: DC Power Flow Example on the
% i3 `& E4 u" T' ^( iSix-Bus Sample System / 278
% T2 j5 s, O, h% z: S9 S8 v0 _6.19 Unified Eliminated Variable Hvdc Method / 278' m: ]8 Y+ N* S
6.19.1 Changes to Jacobian Matrix Reduced / 279
8 J) b' O& u3 v5 q: m1 l$ D6.19.2 Control Modes / 280& m7 N( B: i# ~
6.19.3 Analytical Elimination / 2806 Z3 |8 A& W% @0 b" ~2 h
6.19.4 Control Mode Switching / 283
8 B, s4 c* X6 j" g6.19.5 Bipolar and 12-Pulse Converters / 283
5 d4 i% G: E( [$ ?8 v9 R3 R: G6.20 Transmission Losses / 284
! o3 J( H. t b5 L7 j. l2 G' Y6.20.1 A Two-Generator System Example / 284
. r, H t9 Y' W4 w6.20.2 Coordination Equations, Incremental Losses,
" B6 Z5 t7 v& P* E$ N$ wand Penalty Factors / 286$ ~7 d1 v: `/ g. \3 c
6.21 Discussion of Reference Bus Penalty Factors / 288
. G* T/ q" l" M: x# s& P5 z7 B2 F6.22 Bus Penalty Factors Direct from the AC Power Flow / 2893 G0 J2 a3 S& H$ x1 x5 k& _8 F
PROBLEMS / 291
5 D+ Q" F7 O: @. Z, u1 a7 Power System Security 296" r$ j2 ~" p& V9 `* W3 R+ Z
7.1 Introduction / 296 H) y+ s' `. _# i7 R% N
7.2 Factors Affecting Power System Security / 301
3 o, {5 H/ ?9 h, n) w7.3 Contingency Analysis: Detection of Network Problems / 301
. |3 P! h0 |$ c/ V7.3.1 Generation Outages / 301. R" Y9 q, O1 E1 F7 _$ q
7.3.2 Transmission Outages / 3021 n7 {; L& L" w& A
xii contents
7 j: {3 V: x- S7.4 An Overview of Security Analysis / 3069 U+ E: Q: c v0 o# j+ G3 y1 s4 B
7.4.1 Linear Sensitivity Factors / 3074 w% U7 V/ M4 x' g! D
7.5 Monitoring Power Transactions Using “Flowgates” / 313/ F0 ?& O( T" |/ ^; M, V1 f$ m
7.6 Voltage Collapse / 315; o4 J- `: l" a6 y
7.6.1 AC Power Flow Methods / 3176 V9 N! u7 Q6 d P" _5 |' _
7.6.2 Contingency Selection / 320! t8 c2 P1 A# n7 v; U0 k! A
7.6.3 Concentric Relaxation / 323/ M( `+ N& R( Q( @, f
7.6.4 Bounding / 3254 z; j5 Q* a2 c: C" c
7.6.5 Adaptive Localization / 3250 L5 t$ ]; U, m6 Y
APPENDIX 7A AC Power Flow Sample Cases / 327
) l/ E, ]' F$ d9 m: a6 hAPPENDIX 7B Calculation of Network Sensitivity Factors / 336
; k% x3 f0 G5 E. P8 F' a7B.1 Calculation of PTDF Factors / 336! t1 t2 b$ g5 ~3 s
7B.2 Calculation of LODF Factors / 339% t' U4 s9 v ]1 }, ]
7B.2.1 Special Cases / 341. L9 L5 f# U6 [
7B.3 Compensated PTDF Factors / 343
2 Z- M$ ]) x, g# n; OProblems / 343
! |6 [& O0 a" g1 M. o9 {% J* AReferences / 3490 ~- u4 L7 }1 o6 n7 w
8 Optimal Power Flow 350( V: ^9 Z* o' S
8.1 Introduction / 350: Z5 E/ f) w% g3 t# _/ l+ Y
8.2 The Economic Dispatch Formulation / 351+ j; I7 o$ x: Q X* B( _& q
8.3 The Optimal Power Flow Calculation Combining
6 ~5 {) \ y& P+ N. U' m: SEconomic Dispatch and the Power Flow / 3520 @5 ^3 x, M# t% R# N
8.4 Optimal Power Flow Using the DC Power Flow / 3543 Q8 N" z. }0 ^$ Z! T
8.5 Example 8A: Solution of the DC Power Flow OPF / 3568 N0 V& y1 C* K8 E; P
8.6 Example 8B: DCOPF with Transmission Line
+ j( b4 k8 N' p5 u4 a% Y6 W, sLimit Imposed / 361$ T+ b/ s/ q* a4 b# |- e" @ e
8.7 Formal Solution of the DCOPF / 365, ~4 N" a( _0 Y5 {" r
8.8 Adding Line Flow Constraints to the Linear
; B* N) G7 x. F9 w& X1 nProgramming Solution / 3656 G0 s1 y, j8 q" Y, t& C5 q+ i( T8 v
8.8.1 Solving the DCOPF Using Quadratic Programming / 367# I" T5 E1 _; i" i0 Y9 }: t
8.9 Solution of the ACOPF / 3687 L, k, S2 Y( U9 e+ U( q" X
8.10 Algorithms for Solution of the ACOPF / 369
9 s% _/ E; P7 w( K; {6 F, I8.11 Relationship Between LMP, Incremental Losses,
2 w( f; W" X0 S' band Line Flow Constraints / 3762 M4 ~' O( d# |* F# k1 p d3 f
8.11.1 Locational Marginal Price at a Bus with No Lines3 B f7 i9 s2 z6 k
Being Held at Limit / 377
4 v F% b4 ^) ?& I5 v- S. d8 d* H8.11.2 Locational Marginal Price with a Line Held at its Limit / 3789 t/ a8 j6 K b4 {
contents xiii1 |) n6 k$ ?# ?$ A5 ?
8.12 Security-Constrained OPF / 3822 d2 ^8 x! {! Q" d" m
8.12.1 Security Constrained OPF Using the DC Power Flow
: b. d* t7 X, K$ N2 }6 C! O- }and Quadratic Programming / 384
5 M" i2 z+ `, y k6 g8.12.2 DC Power Flow / 385
p" T6 b6 `) b+ ~- `8.12.3 Line Flow Limits / 385
! j3 c5 s' m, g; c1 p8.12.4 Contingency Limits / 386
) w4 u1 |: w1 A2 X7 Q8 BAPPENDIX 8A Interior Point Method / 3917 p4 ~7 m) b, u( t/ ~. s2 |! X
APPENDIX 8B Data for the 12-Bus System / 3934 G( I. U& V4 @
APPENDIX 8C Line Flow Sensitivity Factors / 3953 V1 \! I! K7 }1 ~2 ?' m
APPENDIX 8D Linear Sensitivity Analysis of the2 j) U7 F! F6 S& v) ]7 H2 ?
AC Power Flow / 397! `& A; h" d+ |0 Q f1 A- ^! p, j
PROBLEMS / 399" s8 E$ T; @) M( q, T9 W' H
9 Introduction to State Estimation in Power Systems 403( G8 ^& ~3 p2 e. }
9.1 Introduction / 403
+ W3 f* w6 y& f- l8 P! \$ ]9.2 Power System State Estimation / 404" @2 s6 ~, |$ x2 y2 v+ _9 A
9.3 Maximum Likelihood Weighted Least-Squares! F: Y& D# P5 G
Estimation / 408
- p& ^/ [, Y9 N/ b2 M D. O) I |9.3.1 Introduction / 4082 Y$ O* X: V/ @& A& H3 b
9.3.2 Maximum Likelihood Concepts / 410. v O3 n2 u- C- S; i( z
9.3.3 Matrix Formulation / 414
% q0 o: ]' W9 q9.3.4 An Example of Weighted Least-Squares
. Z. ^+ F% p7 |6 a* W* A2 H" K1 q/ RState Estimation / 417
! g: c2 b) n: ] `; g" u. i3 F9.4 State Estimation of an Ac Network / 421
/ b& r8 D2 \: ~# S+ T9 D9.4.1 Development of Method / 421
+ y( ` e1 p" ~; b9.4.2 Typical Results of State Estimation on an, M+ z: f( ]' {, R) `( @5 V6 x
AC Network / 424! q: ?7 C: U8 I
9.5 State Estimation by Orthogonal Decomposition / 428& H( n$ n' u& o* d2 H
9.5.1 The Orthogonal Decomposition Algorithm / 431
- Y6 g1 e/ {" o u9.6 An Introduction to Advanced Topics in State Estimation / 435
+ G: L$ P* m, a7 u1 ?9.6.1 Sources of Error in State Estimation / 435; @ i' x. F3 @6 n6 o2 f& W
9.6.2 Detection and Identification of Bad Measurements / 436
3 ^/ F3 _; I1 g' Z9.6.3 Estimation of Quantities Not Being Measured / 443" E; o" E% M: J$ O
9.6.4 Network Observability and Pseudo-measurements / 444, Q9 B. z7 j3 V2 z: s
9.7 The Use of Phasor Measurement Units (PMUS) / 447
# _. ~: y+ N/ R: S; _, Y9.8 Application of Power Systems State Estimation / 451
& O( | |! J5 |1 ]9.9 Importance of Data Verification and Validation / 454& J9 c$ j9 H: Z! Y
9.10 Power System Control Centers / 454
$ T5 l8 J& `$ Y/ P9 I2 @xiv contents4 L+ j- h& w5 x: N
APPENDIX 9A Derivation of Least-Squares Equations / 456
$ K5 k6 Y# ]/ Z( g9 e1 u9A.1 The Overdetermined Case (Nm > Ns) / 457
5 N" @$ O/ S" B! n7 @9A.2 The Fully Determined Case (Nm = Ns) / 462
$ T" v! M/ I1 s( C' L4 l9A.3 The Underdetermined Case (Nm < Ns) / 4622 _* N: G6 a/ Q: z" |9 d2 O
PROBLEMS / 464
+ s- ^, ^+ |+ M& l% u/ b( N10 Control of Generation 4687 y" B5 d4 a- t
10.1 Introduction / 468
! K$ C$ R: R. s10.2 Generator Model / 470/ n3 G- Q# p1 t8 |1 E- T3 e- L
10.3 Load Model / 473
, d$ S p7 \) w# t" p5 e10.4 Prime-Mover Model / 475
2 v- J) c# r3 |* [. @+ v7 U- a10.5 Governor Model / 4768 e; Y; M% q( V4 z2 e- z
10.6 Tie-Line Model / 481
+ P. i- m8 w+ }$ R5 a* s: D10.7 Generation Control / 485
. N9 O4 P% m9 w) I! d4 ^1 T: h10.7.1 Supplementary Control Action / 4852 Q& X" }& `9 R% @
10.7.2 Tie-Line Control / 4864 h) u' k3 K& \9 N! l, F" A
10.7.3 Generation Allocation / 4896 Y+ V" _0 [; s8 c! U( }
10.7.4 Automatic Generation Control (AGC)% S: s. _6 Z S
Implementation / 491
* J8 D+ {6 I: `5 N, z8 p7 X, O5 t, i10.7.5 AGC Features / 495; ?/ `4 d& ]! e0 N8 T6 l
10.7.6 NERC Generation Control Criteria / 496- @( C; v5 @0 u6 p0 X
PROBLEMS / 497
: l* ?; a S4 ]References / 5008 m% U" e, @! ^( I
11 Interchange, Pooling, Brokers, and Auctions 501
9 [; ^1 g G5 J0 g' n& D11.1 Introduction / 501
2 |9 V2 T3 u8 t$ u( m( i- P. z; [7 P11.2 Interchange Contracts / 504- K8 x+ Z. Q% ^% b, ^6 Y* L
11.2.1 Energy / 504
) s' g+ i/ V# Z6 Q9 ~11.2.2 Dynamic Energy / 506
6 z/ Y; |4 f1 h& g% }11.2.3 Contingent / 506; ~2 k% b% x0 z% a- j _3 {
11.2.4 Market Based / 507* ~: L& B, p+ N/ @( C3 A5 n$ c1 G
11.2.5 Transmission Use / 508
3 m) k- P6 m4 r+ A+ B11.2.6 Reliability / 5173 V; C; q3 n. k; }3 t5 h2 D. r
11.3 Energy Interchange between Utilities / 517
% A: a" b) s5 l& r11.4 Interutility Economy Energy Evaluation / 521
$ j: w6 v6 I5 y7 Q' J11.5 Interchange Evaluation with Unit Commitment / 522
+ R/ w. l6 `5 B1 d- r11.6 Multiple Utility Interchange Transactions—Wheeling / 523
2 D8 V3 u% L1 s; S) e4 ~! Q' ?! l11.7 Power Pools / 526
. ~# f6 Q) ]; f- x" k5 @" ccontents xv/ @+ V4 V# T$ s3 x5 V
11.8 The Energy-Broker System / 529
3 n ]6 B( G5 b! T11.9 Transmission Capability General Issues / 533, J. g6 R4 j! _* }
11.10 Available Transfer Capability and Flowgates / 5357 \! _& }6 ^$ k5 Z6 H1 r
11.10.1 Definitions / 5366 Y l" s2 B+ ], m* j* ~2 V& e: ]7 z
11.10.2 Process / 539# j1 `# x/ P, X) Y0 C/ ]
11.10.3 Calculation ATC Methodology / 540/ ?# j) R3 D& v
11.11 Security Constrained Unit Commitment (SCUC) / 550
) ~6 k5 T% k( G$ C- @1 _. D. @11.11.1 Loads and Generation in a Spot Market Auction / 550' v# w* w" }: s) R* K2 d
11.11.2 Shape of the Two Functions / 552 {# ?5 D, l5 s! R! @; w, Q, m! y* H& D
11.11.3 Meaning of the Lagrange Multipliers / 553
% `" U6 @9 s: v, J1 K) m11.11.4 The Day-Ahead Market Dispatch / 554
8 z) N3 v/ f& X11.12 Auction Emulation using Network LP / 555, H4 S, Y/ u0 ~; @. y2 r$ P1 C2 d
11.13 Sealed Bid Discrete Auctions / 555% F4 I$ I! h1 Y( q" F2 c2 E. r
PROBLEMS / 560) _+ |$ e, T, L1 b1 @6 K
12 Short-Term Demand Forecasting 566
' o' P }4 o8 U7 m* P0 G g12.1 Perspective / 566
3 W+ x2 p0 R8 i/ g* ~4 U12.2 Analytic Methods / 569
) g1 S# S+ ~1 E12.3 Demand Models / 5713 d. V p Z3 X; x& T
12.4 Commodity Price Forecasting / 572
0 H0 A& ]/ @3 }4 T12.5 Forecasting Errors / 5734 ]; d( Y! r5 }1 v9 L% s8 }
12.6 System Identification / 573
% L: u/ l7 ?% i: c4 f9 w5 f$ J12.7 Econometric Models / 5748 U+ m4 }& A- @- D! |
12.7.1 Linear Environmental Model / 574% [- Q7 _: G1 y! M* a; v ?
12.7.2 Weather-Sensitive Models / 576
$ A& Y; m; O0 i* Q12.8 Time Series / 5787 Q# t6 }) X) C. D
12.8.1 Time Series Models Seasonal Component / 5781 r) U" J! G. u0 B* O+ B f
12.8.2 Auto-Regressive (AR) / 580: o- ]3 h7 x1 f3 ^8 @
12.8.3 Moving Average (MA) / 581
& i( U8 ]0 a6 H o+ R12.8.4 Auto-Regressive Moving Average (ARMA):5 b. N( u: @2 j% [1 [& [2 W1 R/ U1 Q
Box-Jenkins / 582- g3 W, O' e/ j: V! S
12.8.5 Auto-Regressive Integrated Moving-Average; u- s1 c, y. `" r
(ARIMA): Box-Jenkins / 584
; ]" U( H# U8 V' U3 g. w+ r1 ?8 W12.8.6 Others (ARMAX, ARIMAX, SARMAX, NARMA) / 585% L( x0 D8 E2 o7 K- `. |: |
12.9 Time Series Model Development / 585
# A7 R+ u! T% j$ N! ]4 ?2 @12.9.1 Base Demand Models / 5860 @1 Q2 [8 [7 [' a) O
12.9.2 Trend Models / 586/ O6 H0 d2 W( X* E
12.9.3 Linear Regression Method / 586
7 d" M1 W* a" y! uxvi contents
& H6 _$ j( Y8 o9 o12.9.4 Seasonal Models / 588
7 T+ v; B- X8 X P) R, E! A. s12.9.5 Stationarity / 588
4 c% g. t1 x2 G12.9.6 WLS Estimation Process / 590
$ ~1 I8 g6 e/ Z) ~12.9.7 Order and Variance Estimation / 591* {! |' ^2 T: \7 `
12.9.8 Yule-Walker Equations / 592
# {/ P# [; [0 L12.9.9 Durbin-Levinson Algorithm / 595
- l- `4 w4 Y/ L+ e$ n12.9.10 Innovations Estimation for MA and ARMA
! H# c! n% I/ YProcesses / 598( @( s' p, Y0 B2 }$ T
12.9.11 ARIMA Overall Process / 600
" @9 v7 d7 X1 O; T/ c% a12.10 Artificial Neural Networks / 603$ v8 @3 u, A( |# G! ~5 m8 g
12.10.1 Introduction to Artificial Neural Networks / 604; k l R- C/ W2 X0 `# H
12.10.2 Artificial Neurons / 605
6 c; Q3 {, W- W$ a" F1 ^% ~1 M- [5 F12.10.3 Neural network applications / 606
/ d3 E) e$ A1 T, x12.10.4 Hopfield Neural Networks / 606( I$ \/ j6 {: Z& ]6 } {
12.10.5 Feed-Forward Networks / 607! Z' b* m, f5 Y' s: ?
12.10.6 Back-Propagation Algorithm / 610- a) U( d5 c2 s
12.10.7 Interior Point Linear Programming Algorithms / 613
1 p0 ?$ d# f" |) L8 g12.11 Model Integration / 614
/ r; d3 \: X s: ^- `, c12.12 Demand Prediction / 614
1 L8 n$ I( V. A12.12.1 Hourly System Demand Forecasts / 615( h3 S% `5 A7 g" f. A
12.12.2 One-Step Ahead Forecasts / 615' }7 @6 q0 N; ]/ x7 l7 L& Z' k* a
12.12.3 Hourly Bus Demand Forecasts / 616
/ `7 [2 G& O# X2 b12.13 Conclusion / 616
9 C5 y3 i a$ ] oPROBLEMS / 617 |
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