Uncertainty modelling in power system state estimation

Al-Othman, Abdul Rahman K.

January 2004

As a special case of the static state estimation problem, the load-flow problem is studied in this thesis. It is demonstrated that the non-linear load-flow formulation may be solved by real-coded genetic algorithms. Due to its global optimisation ability, the proposed method can be useful for off-line studies where multiple solutions are suspected. This thesis presents two methods for estimating the uncertainty interval in power system state estimation due to uncertainty in the measurements. The proposed formulations are based on a parametric approach which takes in account the meter inaccuracies. A nonlinear and a linear formulation are proposed to estimate the tightest possible upper and lower bounds on the states. The uncertainty analysis, in power system state estimation, is also extended to other physical quantities such as the network parameters. The uncertainty is then assumed to be present in both measurements and network parameters. To find the tightest possible upper and lower bounds of any state variable, the problem is solved by a Sequential Quadratic Programming (SQP) technique. A new robust estimator based on the concept of uncertainty in the measurements is developed here. This estimator is known as Maximum Constraints Satisfaction (MCS). Robustness and performance of the proposed estimator is analysed via simulation of simple regression examples, D.C. and A.C. power system models.

621.319028551

Network partitioning techniques based on network natural properties for power system application

Alkhelaiwi, Ali Mani Turki

January 2002

In this thesis, the problem of partitioning a network into interconnected sub-networks is addressed. The goal is to achieve a partitioning which satisfies a set of specific engineering constraints, imposed in this case, by the requirements of the decomposed state-estimation (DSE) in electrical power systems. The network-partitioning problem is classified as NP-hard problem. Although many heuristic algorithms have been proposed for its solution, these often lack directness and computational simplicity. In this thesis, three new partitioning techniques are described which (i) satisfy the DSE constraints, and (ii) simplify the NP-hard problem by using the natural graph properties of a network. The first technique is based on partitioning a spanning tree optimally using the natural property of the spanning tree branches. As with existing heuristic techniques, information on the partitioning is obtained only at the end of the partitioning process. The study of the DSE constraints leads to define conditions of an ideal balanced partitioning. This enables data on the balanced partitioning to be obtained, including the numbers of boundary nodes and cut-edges. The second partitioning technique is designed to obtain these data for a given network, by finding the minimum covering set of nodes with maximum nodal degree. Further simplification is then possible if additional graph-theoretical properties are used. A new natural property entitled the 'edge state phenomenon' is defined. The edge state phenomenon may be exploited to generate new network properties. In the third partitioning technique, two of these, the 'network external closed path' and the 'open internal paths', are used to identify the balanced partitioning, and hence to partition the network. Examples of the application of all three methods to network partitioning are provided.

621.31

Design of a Battery State Estimator Using a Dual Extended Kalman Filter

Wahlstrom, Michael

January 2010

Today's automotive industry is undergoing significant changes in technology due to economic, political and environmental pressures. The shift from conventional internal combustion vehicles to hybrid and plug in hybrid electric vehicles brings with it a new host of technical challenges. As the vehicles become more electrified, and the batteries become larger, there are many difficulties facing the battery integration including both embedded control and supervisory control. A very important aspect of Li-Ion battery integration is the state estimation of the battery. State estimation can include multiple states, however the two most important are the state of charge and state of health of the battery. Determining an accurate state of charge estimation of a battery has been an important part of consumer electronics for years now [1]. In small portable electronics, the state of charge of the battery is used to determine the time remaining on the current battery charge. Although difficult, the estimation is simplified by the relatively low charge and discharge currents (approximately + 3C) of the devices and the non-dynamic duty cycle. Hybrid vehicle battery packs can reach much higher charge and discharge currents (+ 20C) [2]. This higher current combined with a very dynamic duty cycle, large changes in temperature, longer periods without usage and long life requirements make state of charge estimation in Hybrid Electric Vehicles (HEV) much more difficult. There have been a host of methods employed by various previous authors. One of the most important factors in state of charge estimation is having an accurate estimation of the actual capacity (depending on state of health) of the battery at any time [3]. Without having an understanding of the state of health of the battery, the state of charge estimation can vary greatly. This paper proposes a state of charge and state of health estimation based on a dual Extended Kalman Filter (EKF). Employing an EKF for the state estimation of the battery pack not only allows for enhanced accuracy of the estimation but allows the control engineer to develop vehicle performance criteria based not only on the state of charge estimation, but also the state of health.

Battery

State of Charge

Kalman Filter

Lithium Ion

State Estimation

Mechanical Engineering

Robust state estimation and model validation techniques in computer vision

Al-Takrouri, Saleh Othman Saleh, Electrical Engineering & Telecommunications, Faculty of Engineering, UNSW

January 2008

The main objective of this thesis is to apply ideas and techniques from modern control theory, especially from robust state estimation and model validation, to various important problems in computer vision. Robust model validation is used in texture recognition where new approaches for classifying texture samples and segmenting textured images are developed. Also, a new model validation approach to motion primitive recognition is demonstrated by considering the motion segmentation problem for a mobile wheeled robot. A new approach to image inpainting based on robust state estimation is proposed where the implementation presented here concerns with recovering corrupted frames in video sequences. Another application addressed in this thesis based on robust state estimation is video-based tracking. A new tracking system is proposed to follow connected regions in video frames representing the objects in consideration. The system accommodates tracking multiple objects and is designed to be robust towards occlusions. To demonstrate the performance of the proposed solutions, examples are provided where the developed methods are applied to various gray-scale images, colored images, gray-scale videos and colored videos. In addition, a new algorithm is introduced for motion estimation via inverse polynomial interpolation. Motion estimation plays a primary role within the video-based tracking system proposed in this thesis. The proposed motion estimation algorithm is also applied to medical image sequences. Motion estimation results presented in this thesis include pairs of images from a echocardiography video and a robot-assisted surgery video.

Computer vision.

Robust state estimation.

Robust model validation.

Control theory .

Robust control .

Estimation theory .

Practical issues in theoretical descriptions of experimental quantum state and entanglement estimation

Yin, Jun

06 1900

xii, 133 p. : ill. (some col.) / We study entanglement estimation and verification in realistic situations, taking into account experimental imperfections and statistical fluctuations due to finite data. We consider both photonic and spin-1/2 systems. We study how entanglement created with mixed photon wave packets is degraded. We apply statistical analysis to and propose criteria for reliable entanglement verification and estimation. Finally we devote some effort to making quantum state estimation efficient by applying information criteria. This dissertation includes previously published co-authored material. / Committee in charge: Michael G. Raymer, Chair; Steven J. van Enk, Advisor; Stephen Hs,u Member; Jens U. Noeckel, Member; Je rey A. Cina, Outside Member;

Quantum physics

Theoretical physics

Pure sciences

Entanglement estimation

Experimental quantum

Quantum state estimation

Quantum computers

Aplicação de filtros de partículas para a assimilação de dados em problemas de fronteira móvel / Application des filtres particulaires à l’assimilation de données en propagation de fronts thermiques

Betencurte da Silva, Wellington

29 November 2012

Bon nombre de problèmes d’ingénierie requièrent l’estimation de l’état de systèmes dynamiques. La modélisation de l’espace des états du système est faite à travers un vecteur d’état qui contient toutes informations utiles pour la description du système. Les problèmes d’estimation d’état sont aussi connus comme problèmes inverses non stationnaires. Ils sont d'un grand intérêt dans de nombreuses applications pratiques, afin de produire une estimation séquentielle des variables souhaitées, à partir de modèles stochastiques et de mesures expérimentales. Ceci dans le but d’optimiser statistiquement l’erreur. Ce travail a pour objectif d’appliquer des méthodes de Filtres à Particules à des thermiques et de combustion. Ces algorithmes sont appliqués successivement à un problème de conduction de chaleur, à un problème de solidification et finalement à un problème de propagation d’incendies. / Many areas of engineering require state estimation of dynamic systems. State relevant information to describe the desired system. The state estimation problems are also known as transient inverse problems. They are of great interest in many practical applications, in order to produce sequential estimates of the desired variables through stochastic models and experimental measurements, in such a way that the error is statistically minimized. In this work we solve state estimation problems with the Bayesian class of particle filters, in heat transfer and combustion. These algorithms havebeen applied to problems of one-dimensional transient heat conduction, solidification and fire propagation.

Problèmes d’estimation d’état

Filtres bayésiens

Transfert de chaleur

Combustion

Problems state estimation

Bayesian filters

Heat transfer

Combustion

Topology Attacks on Power System Operation and Consequences Analysis

January 2015

abstract: The large distributed electric power system is a hierarchical network involving the transportation of power from the sources of power generation via an intermediate densely connected transmission network to a large distribution network of end-users at the lowest level of the hierarchy. At each level of the hierarchy (generation/ trans- mission/ distribution), the system is managed and monitored with a combination of (a) supervisory control and data acquisition (SCADA); and (b) energy management systems (EMSs) that process the collected data and make control and actuation de- cisions using the collected data. However, at all levels of the hierarchy, both SCADA and EMSs are vulnerable to cyber attacks. Furthermore, given the criticality of the electric power infrastructure, cyber attacks can have severe economic and social con- sequences. This thesis focuses on cyber attacks on SCADA and EMS at the transmission level of the electric power system. The goal is to study the consequences of three classes of cyber attacks that can change topology data. These classes include: (i) unobservable state-preserving cyber attacks that only change the topology data; (ii) unobservable state-and-topology cyber-physical attacks that change both states and topology data to enable a coordinated physical and cyber attack; and (iii) topology- targeted man-in-the-middle (MitM) communication attacks that alter topology data shared during inter-EMS communication. Specically, attack class (i) and (ii) focus on the unobservable attacks on single regional EMS while class (iii) focuses on the MitM attacks on communication links between regional EMSs. For each class of attacks, the theoretical attack model and the implementation of attacks are provided, and the worst-case attack and its consequences are exhaustively studied. In particularly, for class (ii), a two-stage optimization problem is introduced to study worst-case attacks that can cause a physical line over ow that is unobservable in the cyber layer. The long-term implication and the system anomalies are demonstrated via simulation. For attack classes (i) and (ii), both mathematical and experimental analyses sug- gest that these unobservable attacks can be limited or even detected with resiliency mechanisms including load monitoring, anomalous re-dispatches checking, and his- torical data comparison. For attack class (iii), countermeasures including anomalous tie-line interchange verication, anomalous re-dispatch alarms, and external contin- gency lists sharing are needed to thwart such attacks. / Dissertation/Thesis / Masters Thesis Electrical Engineering 2015

Electrical engineering

Cyber-physical system

False data injection

State estimation

Topology

Two-stage optimization

Vulnerability analysis

Displacement Estimation for Homodyne Michelson Interferometers Based on Particle Filtering

Ersbo, Petter

January 2018

The current method for displacement estimation for homodyne Michelson interferometer is biased and gives little information about the statistical properties of the estimate. This thesis suggests an alternative estimation method, which has the potential to address these shortcomings. The method is based on a bootstrap Particle smoother, and gives similar displacement estimate quality compared to the least squares based method that is commonly used today. It is however significantly more computationally intensive, and hence the estimation quality has to be improved, while reducing the execution time, to obtain an algorithm that improves on the current one. In total, four estimation methods, based on particle filters or particle smoothers, are implemented in Matlab and evaluated. The recommended method is the most accurate one and is simple to implement in other programming languages. Most of the evaluation is done based on simulated data, but the three methods that work are tested on measured data as well. They all give reasonable displacement estimates for the measured data, but as the true displacement is unknown, the quality of the estimates cannot be assessed based on the measured data. Apart from the evaluation of the estimation methods, an introduction to both particle filtering and interferometry is given in the report, as well as a summary of the current, least squares based, estimator.

interferometry

particle filter

state estimation

Övrig annan teknik

State Estimation for Enhanced Monitoring, Reliability, Restoration and Control of Smart Distribution Systems

January 2012

abstract: The Smart Grid initiative describes the collaborative effort to modernize the U.S. electric power infrastructure. Modernization efforts incorporate digital data and information technology to effectuate control, enhance reliability, encourage small customer sited distributed generation (DG), and better utilize assets. The Smart Grid environment is envisioned to include distributed generation, flexible and controllable loads, bidirectional communications using smart meters and other technologies. Sensory technology may be utilized as a tool that enhances operation including operation of the distribution system. Addressing this point, a distribution system state estimation algorithm is developed in this thesis. The state estimation algorithm developed here utilizes distribution system modeling techniques to calculate a vector of state variables for a given set of measurements. Measurements include active and reactive power flows, voltage and current magnitudes, phasor voltages with magnitude and angle information. The state estimator is envisioned as a tool embedded in distribution substation computers as part of distribution management systems (DMS); the estimator acts as a supervisory layer for a number of applications including automation (DA), energy management, control and switching. The distribution system state estimator is developed in full three-phase detail, and the effect of mutual coupling and single-phase laterals and loads on the solution is calculated. The network model comprises a full three-phase admittance matrix and a subset of equations that relates measurements to system states. Network equations and variables are represented in rectangular form. Thus a linear calculation procedure may be employed. When initialized to the vector of measured quantities and approximated non-metered load values, the calculation procedure is non-iterative. This dissertation presents background information used to develop the state estimation algorithm, considerations for distribution system modeling, and the formulation of the state estimator. Estimator performance for various power system test beds is investigated. Sample applications of the estimator to Smart Grid systems are presented. Applications include monitoring, enabling demand response (DR), voltage unbalance mitigation, and enhancing voltage control. Illustrations of these applications are shown. Also, examples of enhanced reliability and restoration using a sensory based automation infrastructure are shown. / Dissertation/Thesis / Ph.D. Electrical Engineering 2012

Electrical engineering

Engineering

control

distribution systems

power systems

reliability

Smart Grid

State estimation

Filtros de Kalman robustos para sistemas dinâmicos singulares em tempo discreto / Robust Kalman filters for discrete-time singular systems

Aline Fernanda Bianco

29 June 2009

Esta tese trata do problema de estimativa robusta ótima para sistemas dinâmicos regulares discretos no tempo. Novos algoritmos recursivos são formulados para as estimativas filtradas e preditoras com as correspondentes equações de Riccati. O filtro robusto tipo Kalman e a equação de Riccati correspondente são obtidos numa formulação mais geral, estendendo os resultados apresentados na literatura. O funcional quadrático proposto para deduzir este filtro faz a combinação das técnicas mínimos quadrados regularizados e funções penalidade. O sistema considerado para obtenção de tais estimativas é singular, discreto, variante no tempo, com ruídos correlacionados e todos os parâmetros do modelo linear estão sujeitos a incertezas. As incertezas paramétricas são limitadas por norma. As propriedades de estabilidade e convergência do filtro de Kalman para sistemas nominais e incertos são provadas, mostrando-se que o filtro em estado permanente é estável e a recursão de Riccati associada a ele é uma sequência monótona não decrescente, limitada superiormente pela solução da equação algébrica de Riccati. / This thesis considers the optimal robust estimates problem for discrete-time singular dymanic systems. New recursive algorithms are developed for the Kalman filtered and predicted estimated recursions with the corresponding Riccati equations. The singular robust Kalman type filter and the corresponding recursive Riccati equation arer obtained in their most general formulation, extending the results presented in the literature. The quadratic functional developed to deduce this filter combines regularized least squares and penalty functions approaches. The system considered to obtain the estimates is singular, time varying with correlated noises and all parameter matrices of the underlying linear model are subject to uncertainties. The parametric uncertainty is assumed to be norm bounded. The properties of stability and convergence of the Kalman filter for nominal and uncertain system models are proved, where we show that steady state filter is stable and the Riccati recursion associated with this is a nondecreasing monotone sequence with upper bound.

Convergência

Estabilidade

Estimativa de estado

Filtragem robusta

Sistemas singulares

Convergence

Robust filtering

Singular systems

Stability

State estimation