Control Lyapunov Functions : A Control Strategy for Damping of Power Oscillations in Large Power Systems

Ghandhari, Mehrdad

January 2000

In the present climate of deregulation and privatisation, theutilities are often separated into generation, transmission anddistribution companies so as to help promote economic efficiencyand encourage competition. Also, environmental concerns,right-of-way and cost problems have delayed the construction ofboth generation facilities and new transmission lines while thedemand for electric power has continued to grow, which must bemet by increased loading of available lines. A consequence isthat power system damping is often reduced which leads to a poordamping of electromechanical power oscillations and/or impairmentof transient stability. The aim of this thesis is to examine theability of Controllable Series Devices (CSDs), such as Unified Power Flow Controller (UPFC)   Controllable Series Capacitor (CSC)   Quadrature Boosting Transformer (QBT)   for improving transient stability and damping ofelectromechanical oscillations in a power system. For these devices, a general model is used in power systemanalysis. This model is referred to as injection model which isvalid for load flow and angle stability analysis. The model isalso helpful for understanding the impact of the CSDs on powersystem stability. A control strategy for damping of electromechanical poweroscillations is also derived based on Lyapunov theory. Lyapunovtheory deals with dynamical systems without input. For thisreason, it has traditionally been applied only to closed-loopcontrol systems, that is, systems for which the input has beeneliminated through the substitution of a predetermined feedbackcontrol. However, in this thesis, Lyapunov function candidatesare used in feedback design itself by making the Lyapunovderivative negative when choosing the control. This controlstrategy is called Control Lyapunov Function (CLF) for systemswith control input. / QC 20100609

UPFC

CSC

QBT

Lyapunov function

Control Lyapunov Function

SIME

Sliding mode

Electric power engineering

Elkraftteknik

Computationally effective optimization methods for complex process control and scheduling problems

Yu, Yang

Unknown Date

No description available.

Real time optimization

Control Lyapunov function

Benders decomposition

Approximate dynamic programming

Model predictive control

Safety-critical Geometric Control Design with Application to Aerial Transportation

Wu, Guofan

01 December 2017

Safety constraints are ubiquitous in many robotic applications. For instance, aerial robots such as quadrotors or hexcoptors need to realize fast collision-free flight, and bipedal robots have to choose their discrete footholds properly to gain the desired friction and pressure contact forces. In this thesis, we address the safety critical control problem for fully-actuated and under-actuated mechanical systems. Since many mechanical systems evolve on nonlinear manifolds, we extend the concept of Control Barrier Function to a new concept called geometric Control Barrier Function which is specifically designed to handle safety constraints on manifolds. This type of Control Barrier Function stems from geometric control techniques and has a coordinate free and compact representation. In a similar fashion, we also extend the concept of Control Lyapunov Function to the concept of geometric Control Lyapunov Function to realize tracking on the manifolds. Based on these new geometric versions of CLF and CBF, we propose a general control design method for fully-actuated systems with both state and input constraints. In this CBF-CLF-QP control design, the control input is computed based on a state-dependent Quadratic Programming (QP) where the safety constraints are strictly enforced using geometric CBF but the tracking constraint is imposed through a type of relaxation. Through this type of relaxation, the controller could still keep the system state safe even in the cases when the reference is unsafe during some time period. For a single quadrotor, we propose the concept of augmented Control Barrier Function specifically to let it avoid external obstacles. Using this augmented CBF, we could still utilize the idea of CBF-CLF-QP controller in a sequential QP control design framework to let this quadrotor remain safe during the flight. In meantime, we also apply the geometric control techniques to the aerial transportation problem where a payload is carried by multiple quadrotors through cable suspension. This type of transportation method allows multiple quadrotors to share the payload weight, but introduces internal safety constraints at the same time. By employing both linear and nonlinear techniques, we are able to carry the payload pose to follow a pre-defined reference trajectory.

Aerial Transportation

Geometric Control Barrier Function

Geometric Control Lyapunov Function

Safety-critical Geometric Control

Switching Stabilization of Continuous-Time Switched Systems

Lu, Yueyun

January 2016

No description available.

Electrical Engineering

switched systems

switching stabilization

control-Lyapunov function

sliding motion

Filippov solution

A Multichoice Control Strategy for a VSC-HVdc

Latorre, Hector

January 2008

<p>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.</p><p>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.</p><p>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.</p><p>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.</p><p>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.</p>

Control Lyapunov Function

Modal Analysis

Power Oscillation Damping

Transient Stability

Voltage Stability

VSC-HVdc

Electrical engineering

Elektroteknik

Switching Control Strategies for the Robust Stabilization of a DC-DC Zeta Converter / DC-DCゼータコンバータのロバスト安定化のためのスイッチング制御方策

Hafez, Bin Sarkawi

24 September 2021

京都大学 / 新制・課程博士 / 博士(情報学) / 甲第23545号 / 情博第775号 / 新制||情||132(附属図書館) / 京都大学大学院情報学研究科数理工学専攻 / (主査)教授 太田 快人, 教授 山下 信雄, 教授 大塚 敏之 / 学位規則第4条第1項該当 / Doctor of Informatics / Kyoto University / DFAM

Switching control

Robust control

DC-DC Zeta converter

Hybrid system control

Control Lyapunov function

Linear matrix inequality

007

Controle à estrutura variável com múltiplas entradas - múltiplas saídas, aplicado a um veículo robótico submarino

Cardoso, Reginaldo

January 2018

Orientador: Prof. Dr. Magno Enrique Mendoza Meza / Coorientadora: Profª. Drª. Silvia Lenyra Meirelles Campos Titotto / Dissertação (mestrado) - Universidade Federal do ABC, Programa de Pós-Graduação em Engenharia Mecânica, Santo André, 2018.

MODOS DESLIZANTES MULTIVARIÁVEL

HYBRID REMOTELY OPERATED VEHICLE

CONTROL LYAPUNOV FUNCTION

BACKSTEPPING

MULTIVARIABLE SLIDING MODES

Commande d'un véhicule hypersonique à propulsion aérobie : modélisation et synthèse / Control of a hypersonic airbreathing vehicle : modeling and synthesis

Poulain, François

28 March 2012

La propulsion aérobie à grande vitesse est depuis longtemps identifiée comme l'un des prochains sauts technologiques à franchir dans le domaine des lanceurs spatiaux. Cependant, les véhicules hypersoniques (HSV) fonctionnant dans des domaines de vitesse extrêmement élevées, de nombreuses contraintes et incertitudes entravent les garanties des propriétés des contrôleurs. L'objet de cette thèse est d'étudier la synthèse de commande d'un tel véhicule.Pour commencer, il s'agit de définir un modèle représentatif d'un HSV exploitable pour la commande. Dans ce travail, nous construisons deux modèles de HSV. Un pour la simulation en boucle fermée, et le second afin de poser précisément le problème de commande.Nous proposons ensuite une synthèse de commande de la dynamique longitudinale dans le plan vertical de symétrie. Celle-ci est robuste aux incertitudes de modélisation, tolérante à des saturations, et n'excite pas les dynamiques rapides négligées. Ses propriétés sont évaluées sur différents cas de simulation. Puis, une extension est proposée afin de résoudre le problème de commande simultanée des dynamiques longitudinale et latérale, sous les mêmes contraintes.Ce résultat est obtenu par une assignation de fonction de Lyapunov, suite à une étude des dynamiques longitudinale et latérale. Par ailleurs, pour traiter les erreurs de poursuite dues aux incertitudes de modélisation, nous nous intéressons au problème de régulation asymptotique robuste par retour d'état. Nous montrons que cette régulation peut être accomplie en stabilisant le système augmenté d'un intégrateur de la sortie. Ceci constitue une extension de la structure de contrôle proportionnel-intégral au cas des systèmes non linéaires. / High speed airbreathing thrust has been known for a long time as one of the next technological step to be overcome in space launchers domain. However, HyperSonic Vehicles (HSV) speed operating ranges being extremely high, numerous constraints and uncertainties restrict the ensuring of control properties. The purpose of this thesis is to study control synthesis for such a vehicle.First, it concern the definition of a HSV model for controlling purpose. In this work is constructed two HSV models. One in order to effect closed loop simulation, and the other in order to precisely establish the control problem.Then, is proposed a control synthesis for the longitudinal dynamics restricted to the symmetric vertical plane. It is robust to modelling uncertainties, allows saturation, and does not excite neglected fast dynamics. Its properties are evaluated on different cases of simulation. Next, an extension is proposed in order to solve the problem of controlling simultaneously longitudinal and lateral dynamics, under the same constraints.This result is obtained by the use of control Lyapunov functions, following the study of longitudinal and lateral dynamics. Furthermore, in order to solve tracking errors due to modelling uncertainties, the problem of robust asymptotic regulation by state feedback has been addressed. It is shown that such a regulation can be achieved by stabilizing the system augmented by an output integrator. This constitutes an extension for nonlinear systems of the proportional-integral control structure.

Propulsion aérobie

Véhicules hypersoniques

Commande non linéaire

Modélisation

Forwarding

Action intégrale

Airbreathing propulsion

Hypersonic vehicles

Nonlinear control

Modelling

Control-Lyapunov function

Forwarding

Integral action

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 nonlinear control : from continuous time to sampled-data with aerospace applications. / Commande non linéaire robuste : du temps-continu jusqu’aux systèmes sous échantillonnage avec applications aérospatiales.

Mattei, Giovanni

13 February 2015

La thèse porte sur le développement des techniques non linéaires robustes de stabilisation et commande des systèmes avec perturbations de model. D’abord, on introduit les concepts de base de stabilité et stabilisabilité robuste dans le contexte des systèmes non linéaires. Ensuite, on présente une méthodologie de stabilisation par retour d’état en présence d’incertitudes qui ne sont pas dans l’image de la commande («unmatched»). L’approche récursive du «backstepping» permet de compenser les perturbations «unmatched» et de construire une fonction de Lyapunov contrôlée robuste, utilisable pour le calcul ultérieur d’un compensateur des incertitudes dans l’image de la commande («matched»). Le contrôleur obtenu est appelé «recursive Lyapunov redesign». Ensuite, on introduit la technique de stabilisation par «Immersion & Invariance» comme outil pour rendre un donné contrôleur non linéaire, robuste par rapport à dynamiques non modelées. La première technique de contrôle non linéaire robuste proposée est appliquée au projet d’un autopilote pour un missile air-air et au développement d’une loi de commande d’attitude pour un satellite avec appendices flexibles. L’efficacité du «recursive Lyapunov redesign» est mis en évidence dans le deux cas d’étude considérés. En parallèle, on propose une méthode systématique de calcul des termes incertains basée sur un modèle déterministe d’incertitude. La partie finale du travail de thèse est relative à la stabilisation des systèmes sous échantillonnage. En particulier, on reformule, dans le contexte digital, la technique d’Immersion et Invariance. En premier lieu, on propose des solutions constructives en temps continu dans le cas d’une classe spéciale des systèmes en forme triangulaire «feedback form», au moyen de «backstepping» et d’arguments de domination non linéaire. L’implantation numérique est basée sur une loi multi-échelles, dont l’existence est garantie pour la classe des systèmes considérée. Le contrôleur digital assure la propriété d’attractivité et des trajectoires bornées. La loi de commande, calculée par approximation finie d’un développement asymptotique, est validée en simulation de deux exemples académiques et deux systèmes physiques, le pendule inversé sur un chariot et le satellite rigide. / The dissertation deals with the problems of stabilization and control of nonlinear systems with deterministic model uncertainties. First, in the context of uncertain systems analysis, we introduce and explain the basic concepts of robust stability and stabilizability. Then, we propose a method of stabilization via state-feedback in presence of unmatched uncertainties in the dynamics. The recursive backstepping approach allows to compensate the uncertain terms acting outside the control span and to construct a robust control Lyapunov function, which is exploited in the subsequent design of a compensator for the matched uncertainties. The obtained controller is called recursive Lyapunov redesign. Next, we introduce the stabilization technique through Immersion \& Invariance (I\&I) as a tool to improve the robustness of a given nonlinear controller with respect to unmodeled dynamics. The recursive Lyapunov redesign is then applied to the attitude stabilization of a spacecraft with flexible appendages and to the autopilot design of an asymmetric air-to-air missile. Contextually, we develop a systematic method to rapidly evaluate the aerodynamic perturbation terms exploiting the deterministic model of the uncertainty. The effectiveness of the proposed controller is highlighted through several simulations in the second case-study considered. In the final part of the work, the technique of I\& I is reformulated in the digital setting in the case of a special class of systems in feedback form, for which constructive continuous-time solutions exist, by means of backstepping and nonlinear domination arguments. The sampled-data implementation is based on a multi-rate control solution, whose existence is guaranteed for the class of systems considered. The digital controller guarantees, under sampling, the properties of manifold attractivity and trajectory boundedness. The control law, computed by finite approximation of a series expansion, is finally validated through numerical simulations in two academic examples and in two case-studies, namely the cart-pendulum system and the rigid spacecraft.

Commande non linéaire

Commande robuste

Fonction de Lyapunov contrôlée robuste

Modélisation de l'incertitude

Backstepping robuste

Commande multi-échelles

Projet d'autopilote pour missile

Stabilisation d'attitude

Satellite flexible

Nonlinear control

Robust control

Robust control Lyapunov function

Uncertainty modeling

Robust Backstepping

Nonlinear sampled data control

Multi-rate control

Missile autopilot design

Attitude stabilization

Flexible spacecraft

Recursive Lyapunov redesign

Lypunov redesign

Immersion and invariance