schematic representation of the UOK‐MG.Figure 4.10 The ESS and grid experimental dynamic responses.Figure 4.11 The pseudo‐spectrum estimation via MUSIC.Figure 4.12 Comparison of frequency response computed from the experiment an...Figure 4.13 Block diagram representation of control area i. βi, Ri, TgiFigure 4.14 (a) Frequency behaviors and (b) RoCoF of generators 1 to 3 of th...Figure 4.15 Single‐line diagram of two‐area system.Figure 4.16 Frequency response of generators 1, 2, and 3 of the two‐area pow...Figure 4.17 Single‐line diagram of NYNE test system showing coherent areas a...Figure 4.18 Virtual inertia allocation for NYNE test system.Figure 4.19 Frequency responses of NYNE test system for different approaches...Figure 4.20 Participation factor of the machines participating in the critic...Figure 4.21 Virtual inertia allocation for NYNE test system.
5 Chapter 5Figure 5.1 Illustration of clusters associated with weighted, connected grap...Figure 5.2 Overview of the steps in computing voltage control areas. Here,
Figure 5.3 Illustration of distance (similarity) matrices and the associated...Figure 5.4 Mapping from the original space to the DM space.Figure 5.5 Single‐line diagram of the study region showing the 230‐/400‐kV t...Figure 5.6 Sensitivity coefficients associated with bus 153 (unnormalized va...Figure 5.7 Estimated spatial distribution of voltage control areas based on ...Figure 5.8 Reactive power deviations following a double‐line outage for cont...Figure 5.9 Reactive power output for generators in zone 2 for the contingenc...Figure 5.10 SVC reactive output power for contingency scenario CE06.Figure 5.11 Bus voltage magnitudes for contingency scenario CE06.Figure 5.12 Approximate boundaries and geographical locations for clusters e...Figure 5.13 The candidate pilot node locations. Empty dashed circles show pi...Figure 5.14 Leading eigenvector of the Markov transition matrix: (a) conting...Figure 5.15 Dominant eigenvector extracted using the MCL for contingency sce...Figure 5.16 Partial least squares regression of datasets X and Y.6 Chapter 6Figure 6.1 Conceptual overview of the adopted control scheme showing the gri...Figure 6.2 Mechanical system explaining the adopted control scheme.Figure 6.3 Flowchart representation of the proposed control strategy;
repr...Figure 6.4 Frequency response model with virtual inertia.Figure 6.5 Beat voltage for early closing of the switch; upper plot: beat vo...Figure 6.6 Voltages on either side of the static switch [15].Figure 6.7 Single‐line diagram of two‐area system.Figure 6.8 ESS effect on frequency response.Figure 6.9 Single‐line diagram of the 68‐bus system showing coherent areas a...Figure 6.10 Penetration level as a function of frequency nadir.Figure 6.11 ESS effect on frequency response.Figure 6.12 Stable region of power systemFigure 6.13 Virtual inertia allocation for NYNE test system.Figure 6.14 Trace of generating units in the Δδ – ΔV plane in response ...Figure 6.15 Trace of generating units in the Δδ – ΔV plane in response ...Figure 6.16 Effects of flexible inertia on voltage regulation and small‐sign...7 Chapter 7Figure 7.1 Ten‐bus, six‐machine test system.Figure 7.2 Generic wind farm/solar photovoltaic model.Figure 7.3 Normalized speed‐based mode shapes of the electromechanical eigen...Figure 7.4 Speed deviations response following a three‐phase fault at bus 7 ...Figure 7.5 System rotor angle deviations following a three‐phase fault at bu...Figure 7.6 System bus frequency deviations following a three‐phase fault at ...Figure 7.7 System bus voltage deviations following a three‐phase fault at bu...Figure 7.8 Speed deviations of system machines and wind farms following a th...Figure 7.9 Participation factors for mode 1 in Table 7.5.Figure 7.10 Dominant DMD modes from the decomposition
following a three‐ph...Figure 7.11 Speed‐based mode shape for mode 1 in Table 7.3 computed using DM...Figure 7.12 Speed signals following a three‐phase fault at bus 7; (a) Cluste...Figure 7.13 Schematic illustration of the seven‐area test system showing maj...Figure 7.14 Active and reactive control characteristics: (a) reactive and (b...Figure 7.15 Two‐mass wind mechanical model.Figure 7.16 Frequency deviations for contingency scenario CS04; (a) WFs in A...Figure 7.17 Frequency deviations for contingency scenario CS02: (a) WFs in A...Figure 7.18 System response to a three‐phase fault at the POIS (contingency ...Figure 7.19 Bus frequency signals following a three‐phase fault at the POIS ...Figure 7.20 Speed‐based mode shape of 0.395 Hz interarea mode 1.8 Chapter 8Figure 8.1 Simplified system representation.Figure 8.2 Simplified schematic of the study region within Area 6. Dashed li...Figure 8.3 WFs’ active power output following a stub three‐phase fault at th...Figure 8.4 Wind farms terminal voltages following a three‐phase stub fault a...Figure 8.5 SVC reactive power output following a three‐phase stub fault at t...Figure 8.6 WFs’ bus frequencies following a three‐phase stub fault at the PO...Figure 8.7 Wind farms reactive power output (contingency scenario CS03).Figure 8.8 WFs reactive power output (contingency scenario CS03).Figure 8.9 SVC reactive power output (contingency scenario CS03).Figure 8.10 Speed‐based mode shape (contingency scenario CS03).Figure 8.11 The COG dynamic equivalent adopted for assessing energy exchange...Figure 8.12 Generator active power response following the simultaneous outag...Figure 8.13 Partial least squares regression between WFs and generation sour...Figure 8.14 Frequency response at the POIS following the outage of a 750 MW ...Figure 8.15 Frequency nadir as a function of the magnitude of generator trip...Figure 8.16 Simplified diagram of the WF reactive power control loop.Figure 8.17 Bus voltage magnitudes at the POIS for various control and dynam...Figure 8.18 Bus voltage magnitudes at selected buses in Area 6 (contingency ...Figure 8.19 Fourier spectra of bus voltage magnitude deviations in Figure 8....
Guide
6 Preface
9 List of Abbreviations and Acronyms
12 Index
13 WILEY END USER LICENSE AGREEMENT
Pages
1 ii
2 iii
3 iv
4 v
5 xiii