Aplicação do algoritmo genético de Chu-Beasley especializado no ajuste dos parâmetros dos controladores suplementares e dispositivo FACTS IPFC / Application of the specialized Chu-Beasley's genetic algorithm for adjusting the parameters of supplementary controllers and the IPFC FACTS device

Fortes, Elenilson de Vargas [UNESP]

21 October 2016

Submitted by ELENILSON DE VARGAS FORTES null (vargasfortes@yahoo.com.br) on 2016-10-27T22:01:08Z No. of bitstreams: 1 Tese.pdf: 4090366 bytes, checksum: c721654fbc082e717b79dc074adcbfa0 (MD5) / Approved for entry into archive by Juliano Benedito Ferreira (julianoferreira@reitoria.unesp.br) on 2016-11-03T18:32:27Z (GMT) No. of bitstreams: 1 fortes_ev_dr_ilha.pdf: 4090366 bytes, checksum: c721654fbc082e717b79dc074adcbfa0 (MD5) / Made available in DSpace on 2016-11-03T18:32:27Z (GMT). No. of bitstreams: 1 fortes_ev_dr_ilha.pdf: 4090366 bytes, checksum: c721654fbc082e717b79dc074adcbfa0 (MD5) Previous issue date: 2016-10-21 / Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) / Este trabalho apresenta o Algoritmo Genético de Chu-Beasley Especializado para realizar o ajuste coordenado dos parâmetros de controladores Proporcional-Integral e suplementares de amortecimento (Estabilizadores de Sistemas de Potência e Interline Power Flow Controller - Power Oscillation Damping) em sistemas elétricos de potência multimáquinas. O objetivo principal deste trabalho é inserir amortecimento adicional às oscilações eletromecânicas de baixa frequência classificadas como local e interárea. Para representar o sistema, é utilizado o Modelo de Sensibilidade de Corrente. Desse modo, todos os seus dispositivos e componentes foram modelados por injeção de corrente e, portanto, um novo modelo de injeção de corrente para o Interline Power Flow Controller é apresentado. Três sistemas teste foram utilizados nas simulações realizadas neste trabalho, sendo: Simétrico de Duas Áreas, New England e o Sul Brasileiro Reduzido. O desempenho da metodologia proposta (Algoritmo Genético de Chu-Beasley Especializado), no que concerne ao ajuste dos parâmetros dos controladores, foi comparado a outros dois algoritmos bastantes difundidos na literatura: Particle Swarm Optimization e o Algoritmo Genético com Elitismo. Os resultados demonstraram que o algoritmo Genético de Chu-Beasley Especializado foi mais eficiente que as demais técnicas apresentadas, obtendo soluções robustas quando variações de cargas foram consideradas, sendo, portanto, credenciado como ferramenta no estudo da análise da estabilidade a pequenas perturbações. / CNPq: 141084/2016-2

Estabilidade a pequenas perturbações

Estabilizadores de sistemas de potência

Modelo de sensibilidade de corrente

Metaheurísticas

Interline power flow controller

Power oscillation damping

Estudo da estabilidade a pequenas perturbações de sistemas elétricos de potência multimáquinas sob a ação dos controladores FACTS TCSC e UPFC /

Furini, Marcos Amorielle.

January 2008

Orientador: Percival Bueno de Araujo / Banca: Antonio Padilha Feltrin / Banca: Wellington Santos Mota / Resumo: O objetivo desta Dissertação de Mestrado é apresentar a possibilidade de fornecer amortecimento às oscilações de baixa freqüência do sistema elétrico de potência através dos dispositivos FACTS (Flexible Alternating Current Transmission System) TCSC (Thyristor Controlled Series Capacitor) e UPFC (Unified Power Flow Controller). Para isso realiza-se o desenvolvimento e implementação do Modelo de Sensibilidade de Potência para sistemas multmáquinas. Na seqüência são introduzidos os dispositivos TCSC e UPFC, bem como os seus controladores. Apresentam-se resultados de acordo com a evolução dos modelos que representam os dispositivos FACTS, ou seja, parte-se de uma compensação fixa, passando para um modelo dinâmico de primeira ordem e por fim, é incluído o controlador POD (Power Oscillation Damping). A utilização de sinais locais e remotos para entrada do controlador POD também é analisada. Além disso são mostrados os resultados obtidos pela técnica clássica de introdução de amortecimento através de sinais suplementares (os estabilizadores de sistemas de potência - PSS: Power System Stabilizers). O projeto dos controladores POD e PSS é baseado no método da compensação de fase, utilizando a teoria de controle clássico. Fatores de participação, autovetores, autovalores e resíduos de funções de transferência são utilizados como índices para examinar a melhor alocação dos controladores POD e PSS no sistema elétrico de potência. / Abstract: The objective of this work is to present the possibility to provide damping to low frequencies oscillations of the electrical power systems by FACTS devices (Flexible Alternating Current Transmission System): TCSC (Thyristor Controlled Series Capacitor) and UPFC (Unified Power Flow Controller). This is developed and implemented using the Power Sensitivity Model for multimachine systems. Afterwards, the TCSC and UPFC devices are introduced as well as the controllers. Results are presented according to the evolution of the models that represent the FACTS devices, i.e., it starts with a fixed compensation, passing through a first order dynamic model and finally, it is included a POD controller (Power Oscillation Damping). It is also analyzed the inclusion of local and remote signals for the input of the POD controller. Besides, results obtained by classical techniques of introducing damping by supplementary signals (Power Systems Stabilizer - PSS) are shown. The project of POD and PSS controllers are based on the Phase Compensation Method using the classical control theory. Participation Factor like eigenvalues, eigenvectors and transfer function residues are used as index to examine the best allocation of the POD and PSS controllers on the electrical power systems. / Mestre

Electric power systems. eng

Small signal stability. eng

Electromechanical oscillations. eng

TCSC. eng

UPFC. eng

Power oscillation damping. eng

Aplicação do algoritmo genético de Chu-Beasley especializado no ajuste dos parâmetros dos controladores suplementares e dispositivo FACTS IPFC /

Fortes, Elenilson de Vargas

January 2016

Orientador: Percival Bueno de Araujo / Resumo: Este trabalho apresenta o Algoritmo Genético de Chu-Beasley Especializado para realizar o ajuste coordenado dos parâmetros de controladores Proporcional-Integral e suplementares de amortecimento (Estabilizadores de Sistemas de Potência e Interline Power Flow Controller - Power Oscillation Damping) em sistemas elétricos de potência multimáquinas. O objetivo principal deste trabalho é inserir amortecimento adicional às oscilações eletromecânicas de baixa frequência classificadas como local e interárea. Para representar o sistema, é utilizado o Modelo de Sensibilidade de Corrente. Desse modo, todos os seus dispositivos e componentes foram modelados por injeção de corrente e, portanto, um novo modelo de injeção de corrente para o Interline Power Flow Controller é apresentado. Três sistemas teste foram utilizados nas simulações realizadas neste trabalho, sendo: Simétrico de Duas Áreas, New England e o Sul Brasileiro Reduzido. O desempenho da metodologia proposta (Algoritmo Genético de Chu-Beasley Especializado), no que concerne ao ajuste dos parâmetros dos controladores, foi comparado a outros dois algoritmos bastantes difundidos na literatura: Particle Swarm Optimization e o Algoritmo Genético com Elitismo. Os resultados demonstraram que o algoritmo Genético de Chu-Beasley Especializado foi mais eficiente que as demais técnicas apresentadas, obtendo soluções robustas quando variações de cargas foram consideradas, sendo, portanto, credenciado como ferramenta no estudo da análise d... (Resumo completo, clicar acesso eletrônico abaixo) / Doutor

Estabilidade a pequenas perturbações

Estabilizadores de sistemas de potência

Interline power flow controller

Power oscillation damping

Modelo de sensibilidade de corrente

Metaheurísticas

Performance Quantification of Interarea Oscillation Damping Using HVDC

Björk, Joakim

January 2019

With the transition towards renewable energy, and the deregulation of the electricity market, generation patterns and grid topology are changing. These changes increase the need for transfer capacity. One limiting factor, which sometimes leads to underutilization of the transmission grid, is interarea oscillations. These system-wide modes involve groups of generators oscillating relative to each other and are sometimes hard to control due to their scale and complexity. In this thesis we investigate how high-voltage direct current (HVDC) transmission can be used to attenuate interarea oscillations. The thesis has two main contributions. In the first contribution we show how the stability of two asynchronous grids can be improved by modulating the active power of a single interconnecting HVDC link. One concern with modulating HVDC active power is that the interaction between interarea modes of the two grids may have a negative impact on system stability. By studying the controllability Gramian, we show that it is always possible to improve the damping in both grids as long as the frequencies of their interarea modes are not too close. For simplified models, it is explicitly shown how the controllability, and therefore the achievable damping improvements, deteriorates as the frequency difference becomes small. The second contribution of the thesis is to show how coordinated control of two (or more) links can be used to avoid interaction between troublesome interarea modes. We investigate the performance of some multivariable control designs. In particular we look at input usage as well as robustness to measurement, communication, and actuator failures. Suitable controllers are thereby characterized. / Övergången till förnybar energi och avregleringen av elmarknaden leder till förändrade produktions-och överföringsmönster. Dessa förändringar medför behov av en ökad överföringskapacitet. En begränsande faktor, som kan leda till ett underutnyttjande av stamnätet, är interareapendlingar. Dessa systemövergripande pendlingar involverar grupper av generatorer som svänger i förhållande till varandra. Interareapendlingar är ibland svåra att styra på grund av deras skala och komplexitet. I denna avhandling undersöker vi hur förbindelser med högspänd likström, engleska high-voltage direct current (HVDC), kan användas för att dämpa interareapendlingar. Avhandlingen har två huvudbidrag. I det första bidraget visar vi hur stabiliteten hos två olika synkrona nät kan förbättras genom att modulera den aktiva effekten hos en enda HVDC-länk. Ett bekymmer med aktiv effektmodulering är att växelverkan mellan interareapendlingar hos de två näten kan ha en negativ inverkan på systemets stabilitet. Genom att studera styrbarhetsgramianen visar vi att det alltid är möjligt att förbättra dämpningen i båda näten så länge som frekvenserna hos deras interareapendlingar inte ligger för nära varandra. För förenklade modeller visas det uttryckligen hur styrbarheten och därmed de möjliga dämpningsförbättringarna, försämras då frekvensskillnaden blir liten. Avhandlings andra bidrag visar hur koordinerad styrning av två (eller fler) länkar kan användas för att undvika växelverkan mellan besvärliga interareapendlingar. Vi undersöker prestandan hos olika typer av flervariabla regulatorer. I synnerhet undersökers styrsignalsanvändning samt robusthet mot mät-, kommunikations- och aktuatorfel. Därigenom karakteriseras lämpliga regulatortyper. / <p>QC 20190308</p>

HVDC transmission control

interarea oscillations

power oscillation damping

small-signal stability

frequency control

controllability

MIMO control

decoupling control

multivariable interaction

Control Engineering

Reglerteknik

A Multichoice Control Strategy for a VSC-HVdc

Latorre, Hector F.

January 2008

Utilization of power electronics based controllable systems (or devices) in transmission systems has opened new opportunities for the power industry to optimize utilization of the existing transmission systems, and at the same time to keep high system reliability and security. As a member of these controllable systems, Voltage Source Converters-based High Voltage direct current (VSC-HVdc) systems have the ability to rapidly control the transmitted active power, and also to independently exchange reactive power with transmissions systems. Therefore, VSC-HVdcs with a suitable control scheme can offer an alternative means to enhance transient stability, to improve power oscillations damping, and to provide voltage support. An interesting application of this system is the analysis of a power system when a VSC-HVdc is connected in parallel with ac transmission lines. This thesis presents the derivation of control strategies to damp power oscillations, to enhance the transient stability and to provide voltage support for a VSC-HVdc. The thesis also formulates a multichoice control strategy and its application when the VSC-HVdc is connected in a synchronous system. The control strategy for enhancing transient stability is based on the theory of Control Lyapunov Function. The control strategy for increasing the damping is based on Linear Analysis. A very effective well known way to increase damping in the system is modulating the active power through the HVdc. However, besides the control of active power, the thesis explores an alternative way to mitigate power oscillations by controlling the reactive power. This condition might be very useful when the dc link in the VSC-HVdc system is out of service, but the converter stations are in operating conditions. A simple model of VSC-HVdc is considered in order to test the control strategy. The model represents the VSC-HVdc as an element in the power system that provides adequate interaction with other systems elements. The model is intended for analysis of power flows and electromechanical transients. It is then sufficient to consider the power frequency components of voltages and currents represented by phasors that vary with time during transients. The model is valid for symmetrical conditions, i.e. positive sequence phasors are used for the representation of the electrical state. / QC 20101117

Control Lyapunov Function

Modal Analysis

Power Oscillation Damping

Transient Stability

Voltage Stability

VSC-HVdc

Annan elektroteknik och elektronik

Robust decentralised output feedback control of interconnected grid system

Athanasius, Germane, Information Technology & Electrical Engineering, Australian Defence Force Academy, UNSW

January 2008

The novel contribution of the thesis is the design and implementation of decentralised output feedback power system controllers for power oscillation damping (POD) over the entire operating regime of the power system. The POD controllers are designed for the linearised models of the nonlinear power system dynamics. The linearised models are combined and treated as parameter varying switched systems. The thesis contains novel results for the controller design, bumpless switching and stability analysis of such switched systems. Use of switched controllers against the present trend of having single controller helps to reduce the conservatism and to increase the uncertainty handling capability of the power system controller design. Minimax-LQG control design method is used for the controller design. Minimax-LQG control combines the advantages of both LQG and H control methods with respect to robustness and the inclusion of uncertainty and noise in the controller design. Also, minimax-LQG control allows the use of multiple integral quadratic constraints to bound the different types of uncertainties in the power system application. During switching between controllers, switching stability of the system is guaranteed by constraining the minimum time between two consecutive switchings. An expression is developed to compute the minimum time required between switchings including the effect of jumps in the states. Bumpless switching scheme is used to minimise the switching transients which occur when the controllers are switched. Another contribution of the thesis is to include the effect of on load tap changing transformers in the power system controller design. A simplified power system model linking generator and tap changing transformer dynamics is developed for this purpose and included in the controller design. The performance of the proposed linear controllers are validated by nonlinear computer simulations and through real time digital simulations. The designed controllers improve power system damping and provide uniform performance over the entire operating regime of the generator.

Electric power systems

Electric power system stability

Switched controllers

Interconnected grid system

POD controllers

Power oscillation damping

Load tap changing transformers

Bumpless switching scheme

Control of Dynamically Assisted Phase-shifting Transformers

Johansson, Nicklas

January 2008

<p>In this thesis, controllers for power oscillation damping, transient stability improvement and power flow control by means of a Controlled Series Compensator (CSC) and and a Dynamic Power Flow Controller (DPFC) are proposed. These devices belong to the group of power system components referred to as Flexible AC Transmission System (FACTS) devices. The developed controllers use only quantities measured locally at the FACTS device as inputs, thereby avoiding the risk of interrupted communications associated with the use of remote signals for control.</p><p>For power systems with one dominating, poorly damped inter-area power oscillation mode, it is shown that a simple generic system model can be used as a basis for damping- and power flow control design. The model for control of CSC includes two synchronous machine models representing the two grid areas participating in the oscillation and three reactance variables, representing the interconnecting transmission lines and the FACTS device. The model for control of DPFC is of the same type but it also includes the phase shift of the internal phase-shifting transformer of the DPFC.</p><p>The key parameters of the generic grid models are adaptively set during the controller operation by estimation from the step responses in the FACTS line power to the changes in the line series reactance inserted by the FACTS device. The power oscillation damping controller is based on a time-discrete, non-linear approach which aims to damp the power oscillations and set the desired power flow on the FACTS line by means of two step changes in the line reactance separated in time by half an oscillation cycle.</p><p>A verification of the proposed controllers was done by means of digital simulations using power system models of different complexities. The CSC and DPFC controllers were shown to significantly improve the small-signal- and transient stability in one four-machine system of a type commonly used to study inter-area oscillations. The CSC controller was also tested for 18 different contingencies in a 23-machine system, resulting in an improvement in both the system transient stability and the damping of the critical oscillation mode. </p>

Thyristor Controlled Series Capacitor

Thyristor Switched Series Capacitor

Controlled Series Compensator

Dynamic Power Flow Controller

Phase-Shifting Transformer

Power Oscillation Damping

Transient Stability

Power Flow Control

Adaptive Control

Electric power engineering

Elkraftteknik

Aspects on Dynamic Power Flow Controllers and Related Devices for Increased Flexibility in Electric Power Systems

Johansson, Nicklas

January 2011

This thesis studies different aspects of Flexible AC Transmission System (FACTS) devices which are used to improve the power transfer capability and increase the controllability in electric power systems. In the thesis, different aspects on the usage and control of Dynamic Power Flow Controllers (DPFC) and related FACTS devices are studied. The DPFC is a combination of a Phase Shifting Transformer (PST) and a Thyristor Switched Series Capacitor (TSSC)/Thyristor Switched Series Reactor (TSSR). The thesis proposes and studies a new method, the Ideal Phase-Shifter (IPS) method, for selection and rating of Power Flow Controllers (PFC) in a power grid. The IPS method, which is based on steady-state calculations, is proposed as a first step in the design process for a PFC. The method uses the Power controller plane, introduced by Brochu et al in 1999. The IPS method extends the usage of decoupling methods in the Power controller plane to a power system of arbitrary size. The IPS method was in the thesis used to compare the ratings of different PFC:s required to improve the power transfer capability in two test systems. The studied devices were here the PST, the TSSC/TSSR and the DPFC. The thesis treats control of ideal Controlled Series Capacitors (CSC), TCSC, TSSC/TSSR, and DPFC. The goals of the FACTS controllers which are developed are Power Oscillation Damping (POD), fast power flow control, and transient stability improvement in the power system. New adaptive control strategies for POD and power flow control are proposed and studied in different models of power systems by time-domain simulations. A strategy for transient stability improvement is also proposed and studied. Additionally, different methods for study of Subsynchronous Resonance (SSR), which is associated with series compensation in power systems, are investigated. Here, four of the most common methods for frequency scanning to determine the electrical damping of subsynchronous oscillations in a power grid are studied. The study reveals significant differences of the electrical damping estimates of the studied standard methods when applied to a four-machine test system. / QC 20110819

Adaptive Control

Controlled Series Compensator

Dynamic Power Flow Controller

Frequency Scanning

Phase-Shifting Transformer

Power Controller Plane

Power Flow Control

Power Oscillation Damping

Subsynchronous Resonance

Thyristor Controlled Series Compensator

Thyristor Switched Series Compensator

Transient Stability

Electrical engineering

Elektroteknik

Aplicação do algoritmo bioinspirado Novel Bat Algorithm na parametrização dos controladores suplementares de amortecimento e dispositivo FACTS GUPFC /

Miotto, Ednei Luiz

January 2018

Orientador: Percival Bueno de Araujo / Resumo: Este trabalho apresenta o Novel Bat Algorithm com uma nova técnica para realizar o ajuste coordenado dos parâmetros de controladores suplementares de amortecimento (Estabilizadores de Sistemas de Potência e do conjunto Generalized Unified Power Flow Controller – Power Oscillation Damping) em sistemas elétricos de potência multimáquinas. O objetivo principal é inserir amortecimento adicional aos modos oscilatórios de baixa frequência e, consequentemente, garantir a estabilidade do sistema elétrico frente a pequenas perturbações. Para representar o sistema elétrico de potência será utilizado o Modelo de Sensibilidade de Potência. Desse modo, todos os seus dispositivos e componentes foram modelados por injeções de potência. Análises estáticas e dinâmicas foram realizadas em dois sistemas teste, sendo: o Sistema Simétrico de Duas Áreas e o Sistema New England. A eficiência do dispositivo FACTS Generalized Unified Power Flow Controller atuando em conjunto com uma estrutura de controle baseada em controladores Proporcional – Integral foi criteriosamente avaliada para o controle de fluxos de potências ativa e reativa, para a melhoria do perfil de tensão do sistema elétrico e na redução das perdas no sistema de transmissão. O desempenho do Novel Bat Algorithm, no que concerne ao ajuste dos parâmetros dos controladores, foi comparado a outros quatro algoritmos bio-inspirados bastante difundidos na literatura: Particle Swarm Optimization, Bacterial Foragim Optimization, Bat Algorithm e... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: This work presents the Novel Bat Algorithm as a new technique for the to perform the coordinated tuning of the parameters of the supplementary damping controllers (Power Systems Stabilizers and Generalized Unified Power Flow Controller - Power Oscillation Damping) in multi-machine electric power systems. The main objective is to insert damping to low-frequency oscillations and thus ensure the stability of the electrical system against minor disturbances. The Power Sensitivity Model is used to represent the system. Thus, all devices and their components are modeled by power injection. Static and dynamic analyzes were performed in the two systems: the two-areas symmetric, and the New England. The performance of the proposed methodology (Novel Bat Algorithm), for tuning of the parameters of the controllers was compared to four other algorithms, presented in the literature: The Particle Swarm Optimization method, Bacterial Foraging Optimization method, Bat Algorithm method and a Genetic Algorithm with elitism. The results demonstrated that the Novel Bat Algorithm was more effective than the other techniques presented, generating robust solutions when variations on the scenarios of loads were considered, and therefore accredited it as a tool in the analysis of the study of small-signal stability. / Doutor

Modelo de sensibilidade de potência

Estabilizadores de sistemas de potência

Algoritmos bioinspirados

Power oscillation damping

Novel bat algorithm

Power sensitivity model

Power systems stabilizers

Bio-inspired algorithms

Small-signal stability

Aplicação do algoritmo bioinspirado Novel Bat Algorithm na parametrização dos controladores suplementares de amortecimento e dispositivo FACTS GUPFC / Application of the bio-inspired technique Novel Bat Algorithm in the parameterization of the additional damping controllers and FACTS GUPFC device

Miotto, Ednei Luiz

18 October 2018

Submitted by Ednei Luiz Miotto (edneimiotto@utfpr.edu.br) on 2018-11-05T12:58:43Z No. of bitstreams: 1 TESE EDNEI LUIZ MIOTTO.pdf: 5057627 bytes, checksum: 74b7d6f2bd477e7e02941873ca291fa3 (MD5) / Approved for entry into archive by Cristina Alexandra de Godoy null (cristina@adm.feis.unesp.br) on 2018-11-08T19:07:02Z (GMT) No. of bitstreams: 1 miotto_el_dr_ilha.pdf: 5057627 bytes, checksum: 74b7d6f2bd477e7e02941873ca291fa3 (MD5) / Made available in DSpace on 2018-11-08T19:07:02Z (GMT). No. of bitstreams: 1 miotto_el_dr_ilha.pdf: 5057627 bytes, checksum: 74b7d6f2bd477e7e02941873ca291fa3 (MD5) Previous issue date: 2018-10-18 / Este trabalho apresenta o Novel Bat Algorithm com uma nova técnica para realizar o ajuste coordenado dos parâmetros de controladores suplementares de amortecimento (Estabilizadores de Sistemas de Potência e do conjunto Generalized Unified Power Flow Controller – Power Oscillation Damping) em sistemas elétricos de potência multimáquinas. O objetivo principal é inserir amortecimento adicional aos modos oscilatórios de baixa frequência e, consequentemente, garantir a estabilidade do sistema elétrico frente a pequenas perturbações. Para representar o sistema elétrico de potência será utilizado o Modelo de Sensibilidade de Potência. Desse modo, todos os seus dispositivos e componentes foram modelados por injeções de potência. Análises estáticas e dinâmicas foram realizadas em dois sistemas teste, sendo: o Sistema Simétrico de Duas Áreas e o Sistema New England. A eficiência do dispositivo FACTS Generalized Unified Power Flow Controller atuando em conjunto com uma estrutura de controle baseada em controladores Proporcional – Integral foi criteriosamente avaliada para o controle de fluxos de potências ativa e reativa, para a melhoria do perfil de tensão do sistema elétrico e na redução das perdas no sistema de transmissão. O desempenho do Novel Bat Algorithm, no que concerne ao ajuste dos parâmetros dos controladores, foi comparado a outros quatro algoritmos bio-inspirados bastante difundidos na literatura: Particle Swarm Optimization, Bacterial Foragim Optimization, Bat Algorithm e o Algoritmo Genético com Elitismo. Os resultados demonstraram que o Novel Bat Algorithm foi mais eficiente que as demais técnicas avaliadas, obtendo soluções com amortecimento satisfatório, mesmo quando variações nos cenários de carregamento do sistema são consideradas, sendo, portanto, credenciado como ferramenta promissora para a análise da estabilidade a pequenas perturbações em sistemas elétricos de potência multimáquinas. / This work presents the Novel Bat Algorithm as a new technique for the to perform the coordinated tuning of the parameters of the supplementary damping controllers (Power Systems Stabilizers and Generalized Unified Power Flow Controller - Power Oscillation Damping) in multi-machine electric power systems. The main objective is to insert damping to low-frequency oscillations and thus ensure the stability of the electrical system against minor disturbances. The Power Sensitivity Model is used to represent the system. Thus, all devices and their components are modeled by power injection. Static and dynamic analyzes were performed in the two systems: the two-areas symmetric, and the New England. The performance of the proposed methodology (Novel Bat Algorithm), for tuning of the parameters of the controllers was compared to four other algorithms, presented in the literature: The Particle Swarm Optimization method, Bacterial Foraging Optimization method, Bat Algorithm method and a Genetic Algorithm with elitism. The results demonstrated that the Novel Bat Algorithm was more effective than the other techniques presented, generating robust solutions when variations on the scenarios of loads were considered, and therefore accredited it as a tool in the analysis of the study of small-signal stability.

Modelo de sensibilidade de potência

Estabilizadores de sistemas de potência

Algoritmos bioinspirados

Power oscillation damping

Novel bat algorithm

Power sensitivity model

Power systems stabilizers

Bio-inspired algorithms

Small-signal stability