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Dynamic stability basically deals with the interactions between the system's components. Following a disturbance, the system's variables undergo transitions that can induce oscillations in active and reactive power generation, resulting in the occurrence of voltage oscillatory modes and frequency deviation in the system. Depending on the entity of the disturbance, the small- or large-signal stability of the system under consideration can be investigated. The introduction of RES-based generation that does not participate in the network services (i.e., frequency and voltage regulation) due to lack of special controls will undoubtedly affect both the overall frequency and voltage stability. Large-scale transient stability is also a concern not to be overlooked: inverter-based wind and solar generation have different angle/speed swing behaviors with respect to traditional generation due to reduced inertia, different voltage swing behaviors due to different voltage control systems, different power flow patterns, and different displacements of synchronous generation at key locations. Therefore, although power system stability and dynamics have played a very central role in the management and study of electrical power systems thus far, it is also true that the emerging scenario requires new methodologies, technologies, and analyses. In this light, the current Special Issue aims to collect contributions (i.e., research papers and review articles) on power system dynamics and stability from experts in academia and industry.
Technology: general issues --- History of engineering & technology --- power system stability --- inertia estimation --- PMU --- microgrids --- frequency control --- grid-forming --- 100% converter-interfaced generation --- virtual synchronous machine --- forced oscillation --- inverter-based resources (IBRs) --- grid vulnerability analysis --- active power modulation --- virtual inertia --- fast frequency measurement --- fast frequency regulation --- distributed energy resources --- ancillary services --- power hardware-in-the-loop --- legacy resources --- large perturbation angle stability --- small perturbation angle stability --- voltage stability --- synthetic inertia --- demand response --- reactive compensation --- power system restoration --- primary frequency control --- frequency nadir estimation --- low inertia systems --- real-time dynamic simulation --- national power grid --- cyber physical system (CPS) --- co-simulation --- battery energy storage system (BESS) --- energy management system (EMS) --- load modelling --- line modelling --- power system analysis --- transient stability --- small-signal stability --- inverter-based resources --- modular multilevel converters --- primary frequency regulation --- battery energy storage system --- Ornstein–Uhlenbeck stochastic process --- compound poisson stochastic process --- frequency stability --- rotor angle stability --- power system inertia --- converter-interfaced generation --- renewable power generators
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Electric power systems are headed for a true changing of the guard, due to the urgent need for achieving sustainable energy delivery. Fortunately, the development of new technologies is driving the transition of power systems toward a carbon-free paradigm while maintaining the current standards of quality, efficiency, and resilience. The introduction of HVDC and FACTS in the 20th century, taking advantage of dramatic improvements in power electronics and control, gave rise to unprecedented levels of flexibility and speed of response in comparison with traditional electromechanical devices. This flexibility is nowadays required more than ever in order to solve a puzzle with pieces that do not always fit perfectly. This Special Issue aims to address the role that FACTS and HVDC systems can play in helping electric power systems face the challenges of the near future.
History of engineering & technology --- VSC-HVDC --- unbalanced grid conditions --- double frequency ripples --- power compensation --- passive-based control --- disturbance observer --- dynamic capacitor --- inductive unbalanced load --- reactive power compensation --- imbalance suppression --- compensation ability --- HVDC transmission --- hybrid multi-terminal HVDC --- LCC --- MTDC --- power system analysis --- VSC --- breakers --- hybrid DC circuit breaker --- fault current limiters --- non-superconducting fault current limiters --- current-limiting inductors --- voltage source converter --- FACTS --- grid services --- CHIL --- PHIL --- lab testing --- field testing --- standards --- STATCOM --- replica --- review --- korean power system --- subsynchronous resonance (SSR) --- synchronous voltage reversal (SVR) --- thyristor controlled series capacitor (TCSC) --- test signal method --- virtual synchronous machine --- synchronous power controller --- power quality --- harmonics --- hybrid power quality compensation system --- the thyristor-controlled L and C-type filter (TCL-CTF) --- ancillary services --- HVDC systems --- loss management --- frequency control --- voltage and reactive power control --- black start --- congestion management --- distribution networks --- hybrid AC/DC networks --- power systems --- high voltage direct current (HVDC) transmission --- HVDC systems based on voltage source converters (VSC-HVDC) --- multi-terminal --- transient stability --- control strategies --- communication latency --- power oscillations --- UPFC --- non-linear control --- neural network --- model reference control --- High voltage direct current (HVDC) --- continuous commutation failures --- DC blocking --- emergency power support --- stability --- VSC-HVDC --- unbalanced grid conditions --- double frequency ripples --- power compensation --- passive-based control --- disturbance observer --- dynamic capacitor --- inductive unbalanced load --- reactive power compensation --- imbalance suppression --- compensation ability --- HVDC transmission --- hybrid multi-terminal HVDC --- LCC --- MTDC --- power system analysis --- VSC --- breakers --- hybrid DC circuit breaker --- fault current limiters --- non-superconducting fault current limiters --- current-limiting inductors --- voltage source converter --- FACTS --- grid services --- CHIL --- PHIL --- lab testing --- field testing --- standards --- STATCOM --- replica --- review --- korean power system --- subsynchronous resonance (SSR) --- synchronous voltage reversal (SVR) --- thyristor controlled series capacitor (TCSC) --- test signal method --- virtual synchronous machine --- synchronous power controller --- power quality --- harmonics --- hybrid power quality compensation system --- the thyristor-controlled L and C-type filter (TCL-CTF) --- ancillary services --- HVDC systems --- loss management --- frequency control --- voltage and reactive power control --- black start --- congestion management --- distribution networks --- hybrid AC/DC networks --- power systems --- high voltage direct current (HVDC) transmission --- HVDC systems based on voltage source converters (VSC-HVDC) --- multi-terminal --- transient stability --- control strategies --- communication latency --- power oscillations --- UPFC --- non-linear control --- neural network --- model reference control --- High voltage direct current (HVDC) --- continuous commutation failures --- DC blocking --- emergency power support --- stability
Choose an application
Electric power systems are headed for a true changing of the guard, due to the urgent need for achieving sustainable energy delivery. Fortunately, the development of new technologies is driving the transition of power systems toward a carbon-free paradigm while maintaining the current standards of quality, efficiency, and resilience. The introduction of HVDC and FACTS in the 20th century, taking advantage of dramatic improvements in power electronics and control, gave rise to unprecedented levels of flexibility and speed of response in comparison with traditional electromechanical devices. This flexibility is nowadays required more than ever in order to solve a puzzle with pieces that do not always fit perfectly. This Special Issue aims to address the role that FACTS and HVDC systems can play in helping electric power systems face the challenges of the near future.
History of engineering & technology --- VSC-HVDC --- unbalanced grid conditions --- double frequency ripples --- power compensation --- passive-based control --- disturbance observer --- dynamic capacitor --- inductive unbalanced load --- reactive power compensation --- imbalance suppression --- compensation ability --- HVDC transmission --- hybrid multi-terminal HVDC --- LCC --- MTDC --- power system analysis --- VSC --- breakers --- hybrid DC circuit breaker --- fault current limiters --- non-superconducting fault current limiters --- current-limiting inductors --- voltage source converter --- FACTS --- grid services --- CHIL --- PHIL --- lab testing --- field testing --- standards --- STATCOM --- replica --- review --- korean power system --- subsynchronous resonance (SSR) --- synchronous voltage reversal (SVR) --- thyristor controlled series capacitor (TCSC) --- test signal method --- virtual synchronous machine --- synchronous power controller --- power quality --- harmonics --- hybrid power quality compensation system --- the thyristor-controlled L and C-type filter (TCL-CTF) --- ancillary services --- HVDC systems --- loss management --- frequency control --- voltage and reactive power control --- black start --- congestion management --- distribution networks --- hybrid AC/DC networks --- power systems --- high voltage direct current (HVDC) transmission --- HVDC systems based on voltage source converters (VSC-HVDC) --- multi-terminal --- transient stability --- control strategies --- communication latency --- power oscillations --- UPFC --- non-linear control --- neural network --- model reference control --- High voltage direct current (HVDC) --- continuous commutation failures --- DC blocking --- emergency power support --- stability
Choose an application
Electric power systems are headed for a true changing of the guard, due to the urgent need for achieving sustainable energy delivery. Fortunately, the development of new technologies is driving the transition of power systems toward a carbon-free paradigm while maintaining the current standards of quality, efficiency, and resilience. The introduction of HVDC and FACTS in the 20th century, taking advantage of dramatic improvements in power electronics and control, gave rise to unprecedented levels of flexibility and speed of response in comparison with traditional electromechanical devices. This flexibility is nowadays required more than ever in order to solve a puzzle with pieces that do not always fit perfectly. This Special Issue aims to address the role that FACTS and HVDC systems can play in helping electric power systems face the challenges of the near future.
VSC-HVDC --- unbalanced grid conditions --- double frequency ripples --- power compensation --- passive-based control --- disturbance observer --- dynamic capacitor --- inductive unbalanced load --- reactive power compensation --- imbalance suppression --- compensation ability --- HVDC transmission --- hybrid multi-terminal HVDC --- LCC --- MTDC --- power system analysis --- VSC --- breakers --- hybrid DC circuit breaker --- fault current limiters --- non-superconducting fault current limiters --- current-limiting inductors --- voltage source converter --- FACTS --- grid services --- CHIL --- PHIL --- lab testing --- field testing --- standards --- STATCOM --- replica --- review --- korean power system --- subsynchronous resonance (SSR) --- synchronous voltage reversal (SVR) --- thyristor controlled series capacitor (TCSC) --- test signal method --- virtual synchronous machine --- synchronous power controller --- power quality --- harmonics --- hybrid power quality compensation system --- the thyristor-controlled L and C-type filter (TCL-CTF) --- ancillary services --- HVDC systems --- loss management --- frequency control --- voltage and reactive power control --- black start --- congestion management --- distribution networks --- hybrid AC/DC networks --- power systems --- high voltage direct current (HVDC) transmission --- HVDC systems based on voltage source converters (VSC-HVDC) --- multi-terminal --- transient stability --- control strategies --- communication latency --- power oscillations --- UPFC --- non-linear control --- neural network --- model reference control --- High voltage direct current (HVDC) --- continuous commutation failures --- DC blocking --- emergency power support --- stability
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