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1 Chapter 1Table 1‐1 Economic Analysis of ST versus UPFC over a 45‐year time period.Table 1‐2 Various features of all Shunt–Shunt and Shunt–Series configuration...Table 1‐3 Various compensators for utility applications.Table 1‐4 Features, advantages, and benefits of various solutions.

2 Chapter 2Table 2‐1 Electrical system data.Table 2‐2 Equations for natural active and reactive power flows (Psn and QsnTable 2‐3 Equations for active and reactive power flows (Ps′ and Qs′...Table 2‐4 Equations relating the active and reactive power flows (Ps′ ...Table 2‐5 Equations for magnitude (Vs′) and modified power angle (δ...Table 2‐6 Equations for magnitude (Vs′), modified power angle (δ′...Table 2‐7 Equations for magnitude (Vs′s) and relative phase angle (β...Table 2‐8 Line current for a VR and a PAR (asym).Table 2‐9 Relationships between active and reactive power flows (Ps and Qs) ...Table 2‐10 Equations for active and reactive power flows (Ps and Qs), (Pr an...Table 2‐11 Equations for magnitude (Vs′s) and relative phase angle (β...Table 2‐12 Equations forPs, Pr, Ps′, and Pse when a VR is used.Table 2‐13 Equations relating (Ps and Qs), (Pr and Qr), (Ps′ and Qs′...Table 2‐14 Equations forPs, Pr, Ps′, and Pse when a PAR (asym) is used...Table 2‐15 Equations relating (Ps and Qs), (Pr and Qr), (Ps′ and Qs′...Table 2‐16 Equations for active and reactive power flows (Ps′ and Qs′...Table 2‐17 Equations relating the active and reactive power flows (Ps′Table 2‐18 Selected operating points of an IR and the corresponding series‐c...Table 2‐19 Selected operating points of a VR and the corresponding series‐co...Table 2‐20 Selected operating points of a PAR (asym) and the corresponding s...Table 2‐21 Selected operating points of a PAR (sym) and the corresponding se...Table 2‐22 Selected operating points of a RR and the corresponding series‐co...Table 2‐23 Series‐compensating resistance (Rse) and reactance (Xse) for an I...Table 2‐24 Series‐compensating impedance (Zse) for an IR, a VR, a PAR (asym)...Table 2‐25 Electrical system data and base power flow data.Table 2‐26RPI, LI, and APR of a PAR (sym) for power flow increases in three case...Table 2‐27RPI, LI, and APR of a PAR (asym) for power flow increases in three cas...Table 2‐28RPI, LI, and APR of a RR for power flow increases in three cases: Case...Table 2‐29RPI, LI, and APR of an IR for power flow increases in three cases: Cas...Table 2‐30 Comparison ofAPR of a PAR (sym), a PAR (asym), a RR, and an IR fo...Table 2‐31 Comparison ofRPI, LI, and APR of a PAR (sym), a PAR (asym), a RR,...Table 2‐32 Comparison ofRPI, LI, and APR per unit of active power (Pr) trans...Table 2‐33 Figure of merits of shunt compensation with a power angle of.Table 2‐34 Figure of merits of shunt compensation with a power angle of.Table 2‐35 Figure of merits of shunt compensation with a power angle of.Table 2‐36 Figure of merits of series compensation with a power angle of.Table 2‐37 Figure of merits of series compensation with a power angle of.Table 2‐38 Figure of merits of series compensation with a power angle of.Table 2‐39 Control parameters and their effects onVs′s, β, Vs′...Table 2‐40 Comparison ofRPI, LI, and APR per unit of active power (Pr) trans...Table 2‐41 Comparison ofSI of a PAR (sym), a PAR (asym), a RR, and an IR for...

3 Chapter 3Table 3‐1 Electrical system data.Table 3‐2 Electrical system data.Table 3‐3 Electrical system data.Table 3‐4 Sending‐end voltage, power flows at the receiving end, and the exc...Table 3‐5 Effects of the variation of series‐compensating voltage on the pow...

4 Chapter 4Table 4‐1 Electrical system data.Table 4-2 Effects of the variation of series‐compensating voltage (Vs′ s...Table 4‐3 Effects of the variation of series‐compensating voltage (Vs′s...Table 4‐4 Electrical system data.Table 4‐5 Electrical system data.Table 4‐6 Effects of the variation of series‐compensating voltage (Vs′s...Table 4‐7 Electrical system data.Table 4‐8 Effects of the variation of shunt‐compensating voltage (Vs′)...Table 4‐9 Electrical system data.Table 4‐10 Effects of the variation of series‐compensating voltage (Vs′s...Table 4‐11 Electrical system data.Table 4‐12 Effects of the variation of series‐compensating voltage (Vs′s...Table 4‐13 Electrical system data.Table 4‐14 Effects of the variation of series‐compensating voltage (Vs′s...

5 Chapter 5Table 5‐1 Electrical system data.Table 5‐2 Electrical system data.Table 5‐3 Electrical system data.Table 5‐4 Electrical system data.Table 5‐5 Electrical system data.Table 5‐6 Electrical system data.

6 Chapter 6Table 2‐1 Electrical system data.Table 6‐1 Active turns‐ratios of the secondary, series‐compensating windings in t...Table 6‐2 Active turns‐ratios of the secondary, series‐compensating windings in t...Table 6‐3 Active turns‐ratios of the secondary, series‐compensating windings in t...Table 6‐4 Compensating voltage, modified sending‐end voltage, power flows at the ...Table 3‐2 Electrical system data.Table 6‐5 Compensating voltage, modified sending‐end voltage, power flows at the ...Table 6‐6 Electrical system data.Table 6‐7 Compensating voltage, modified sending‐end voltage, power flows at the ...Table 6‐8 Electrical system data.Table 6‐9 Compensating voltage, modified sending‐end voltage, power flows at the ...Table 6‐10 Electrical system data.Table 6‐11 Compensating voltage, modified sending‐end voltage, power flows a...Table 6‐12 Compensating voltage, modified sending‐end voltage, power flows at the...Table 6‐13 Components of Option 1 compensating voltages in the A, B, and C p...Table 6‐14 Components of Option 2 compensating voltages in the A, B, and C p...Table 6‐15 The compensating voltages in Option 3 for all phases.Table 6‐16 Comparison among the voltage‐regulating transformer (VRT), phase angle...

7 Appendix BTable B‐1 Line current for a VR and a PAR (asym).

8 Appendix CTable C‐1 Chilean grid simulation results.Table C‐2 Chilean contingency scenario results.

Power Flow Control Solutions for a Modern Grid Using SMART Power Flow Controllers

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