Development and Applications of Multi-Objectives Signal Control Strategy during Oversaturated Conditions

Adam, Zaeinulabddin Mohamed Ahmed

28 September 2012

Managing traffic during oversaturated conditions is a current challenge for practitioners due to the lack of adequate tools that can handle such situations. Unlike under-saturated conditions, operation of traffic signal systems during congestion requires careful consideration and analysis of the underlying causes of the congestion before developing mitigation strategies. The objectives of this research are to provide a practical guidance for practitioners to identify oversaturated scenarios and to develop a multi-objective methodology for selecting and evaluating mitigation strategy/ or combinations of strategies based on a guiding principles. The research focused on traffic control strategies that can be implemented by traffic signal systems. The research did not considered strategies that deals with demand reduction or seek to influence departure time choice, or route choice. The proposed timing methodology starts by detecting network's critical routes as a necessary step to identify the traffic patterns and potential problematic scenarios. A wide array of control strategies are defined and categorized to address oversaturation problematic scenarios. A timing procedure was then developed using the principles of oversaturation timing in cycle selection, split allocation, offset design, demand overflow, and queue allocation in non-critical links. Three regimes of operation were defined and considered in oversaturation timing: (1) loading, (2) processing, and (3) recovery. The research also provides a closed-form formula for switching control plans during the oversaturation regimes. The selection of optimal control plan is formulated as linear integer programming problem. Microscopic simulation results of two arterial test cases revealed that traffic control strategies developed using the proposed framework led to tangible performance improvements when compared to signal control strategies designed for operations in under-saturated conditions. The generated control plans successfully manage to allocate queues in network links. / Ph. D.

Signal system

Oversaturation control strategy

Critical route

Pareto front

Queue management

Wavelet analysis

Multi-objective control

Control of Criteria Emissions and Energy Management in Hybrid Electric Vehicles with Consideration of Three-Way Catalyst Dynamics

Jankord, Gregory J.

January 2020

No description available.

Mechanical Engineering

hybrid electric vehicle

HEV

emission

emissions

criteria emissions

criteria emission

optimal control

dynamic programming

multi-objective control

PHEV

Contrôle actif acoustique du bruit large bande dans un habitacle automobile / Active control of broadband noise in a car cabin

Loiseau, Paul

28 October 2016

L’atténuation des bruits gênants dans une automobile est classiquement réalisée par ajustement des caractéristiques mécaniques du véhicule : masse, raideur et amortissement. C’est une approche dite passive. Malheureusement, elle induit un ajout de masse important pour traiter les basses fréquences. Le contrôle actif de bruit (atténuation d’un bruit par superposition d’un contrebruit) est actuellement envisagé comme une solution possible à ce problème. L’objectif de cette thèse est d’évaluer les performances atteignables par cette solution. Un système acoustique étant par essence fortement résonant, sa modélisation sur une large plage de fréquence conduit à des modèles d’ordre élevé, pour l’obtention desquels une méthode d’identification appropriée doit être utilisée. C’est la méthode dessous espaces par approche fréquentielle dans le domaine continu qui a été retenue.La traduction du cahier des charges conduit à un problème de régulation multivariable H1 multi-objectif et multi-modèle avec contrainte de stabilité forte. Par ailleurs, actionneurs et capteurs ne sont pas colocalisés et on ne mesure pas la perturbation à rejeter. La volonté d’évaluer au plus près les performances atteignables justifie la résolution du problème par optimisation non lisse. Cette approche évite tout pessimisme, mais nécessite de par son caractère local une bonne initialisation et une structuration du régulateur parcimonieuse.La méthodologie proposée a été validée en simulation et expérimentalement. Elle permet une évaluation et une comparaison précises des performances atteignables en fonction des contraintes sur les mesures et les moyens d’action disponibles. / Classical methods used for noise reduction in cars are based on adjusting the mechanical properties: mass, stiffness and damping. They are qualified as passive and induce significative addition of weight for reducing low frequency noises. Active noise control is seen as a possible solution to achieve low frequency noise attenuation and weight reduction.The goal of this work is to evaluate achievable performances with such solution.Acoustic enclosures are known to be resonant systems of highorder. Obtaining a model of it, therefore requires a suitable identification method. The approach chosen is based on subspace methods. It processes data in the frequency domain for obtaining a continuous time model.The control problem derived from the specifications is a MIMO H1, multi-objective and multi-model problem with a strong stability constraint. Futhermore, actuators and sensors are not-colocated, and no measure of the disturbance is available. In order to precisely evaluate the achievable performances, this problem is solved using non smooth optimization.Such approach ensures the absence of pessimism, but requires an appropriate initialization and a parsimonious controller structure, because it does not ensure convergence toward the global optimum. The proposed methodology was validated in simulation and experimentally. It allows a precise evaluation and comparison of achievable performances according to the constraints on available measures and means of action.

Contrôle actif acoustique

Atténuation large bande

Automobile

Commande multi-Objectif

Commande robuste

Active noise control

Broadband noise attenuation

Automotive control

Multi-Objective control

Robust control

Conception d’un système avancé de réacteur PWR flexible par les apports conjoints de l’ingénierie système et de l’automatique / Conception of an advanced flexible PWR reactor system using systems engineering and control theories

Lemazurier, Lori

02 February 2018

Devant l’augmentation de la part des énergies renouvelables en France, cette thèse propose d’étudier l’augmentation de la flexibilité des réacteurs à eau pressurisée en croisant deux disciplines pour, chacune, atteindre des objectifs complémentaires : l’Ingénierie Système (IS) et l’Automatique.Dans le contexte de l’ingénierie de systèmes complexes et du Model Based Systems Engineering, ce travail propose dans un premier temps une méthode de conception se fondant sur les principes normatifs de l’IS et respectant les habitudes et les pratiques courantes en ingénierie de Framatome. Cette méthode a pour vocation de formaliser et assurer le passage des exigences aux architectures et d’améliorer les capacités de vérification des modèles développés lors de la conception. Elle s’organise autour de langages de modélisation interopérables, couvrant l’ensemble des processus promus par l’IS. La méthode proposée est appliquée sur le système dont les performances sont les plus limitantes dans le contexte de l’augmentation de flexibilité : le Core Control. Ce composant algorithmique du réacteur assure le contrôle des paramètres de fonctionnement du cœur : la température moyenne, la distribution axiale de puissance et la position des groupes de grappes.La thèse propose ensuite des contributions techniques relevant du champ de l’Automatique. Il s’agit de concevoir un système de régulation répondant aux exigences issues de la formalisation IS évoquée ci-dessus. La solution proposée repose sur une stratégie de commande hiérarchisée, utilisant la complémentarité des approches dites de commande multi-objectif, de séquencement de gains et enfin de commande prédictive. Un modèle de réacteur nucléaire simplifié innovant est développé à des fins de conception du système de régulation et de simulations intermédiaires. Les résultats obtenus ont montré les capacités d’adaptation de la démarche proposée à des spécifications diverses. Les performances atteintes sont très encourageantes lorsque évaluées en simulation à partir d’un modèle réaliste et comparées à celles obtenues par les modes de pilotages classiques. / In the event of increasing renewable energies in France, this thesis proposes to study the flexibility increase of pressurized water reactors (PWR) throughout two different engineering disciplines aiming at complementary objectives: Systems Engineering (SE) and Control theory.In a first phase, within the frame of complex systems design and Model Based Systems Engineering, this work proposes a SE method based on SE standard principles and compliant with Framatome’s practices and addressing the revealed issues. This SE contribution is twofold: formalize and ensure the path from requirements to system architectures and enhance the capabilities of models verification. The method revolves around interoperable modeling languages, covering the SE processes: from requirement engineering to system architecture design. The method is applied to the system, which performances are the most limiting in the context of flexibility increase: the Core Control. This algorithmic reactor component ensures the control of: the average coolant temperature, the axial offset and the rod bank position, three of the core main functioning parameters.In order to provide a technical contribution relying on some advanced control methodologies. It consists in designing a control system meeting the requirements defined by the SE method application. The proposed solution is in a two-layer control strategy using the synergies of multi-objective control, gain-scheduling and predictive control strategies. A simplified innovative nuclear reactor model is employed to conceive the control algorithm, simulate and verify the developed models. The results obtained from this original approach showed the ability to adapt to various specifications. Compared to conventional core control modes, the simulation results showed very promising performances, while meeting the requirements, when evaluated on a realistic reactor model.

Commande multi-objectif

Régulateur à gains séquencés

Commande prédictive

Ingénierie système

MBSE

Vérification et validation

Nuclear core control

Multi-objective control

Gain-scheduling

Predictive control

Systems engineering

MBSE

Verification and validation

620

Multi-objective control of a self-locking compact electro-hydraulic cylinder drive

Grønkær, Nikolaj, Nielsen, Lasse Nørby, Nielsen, Frederik Ødum, Ketelsen, Søren, Schmidt, Lasse

25 June 2020

The field of self-contained linear hydraulic drives based on variable-speed electrical motors and fixed displacement pumps is gaining interest from both industry and academia. Some of the main reasons for this is the possibility to improve the energy efficiency of such drives compared to conventional valve controlled drives, and the possibility for electrical regeneration allowing power sharing between multiple drives [1]. The main drawback for such types of drive concepts is a low pressure in the nonload carrying cylinder chamber. This induces a low drive stiffness limiting the achievable drive bandwidth and hence the application range. However, a so-called self-locking compact drive architecture recently proposed allows maintaining a proper drive stiffness by virtue of separate forward and return flow paths, combining the advantages of efficient flow control into the cylinder and a throttle driven flow out of the cylinder. The multiple inputs available in this architecture allow the control to target several objectives concurrently, for example piston motion, drive stiffness and fluid temperature. The purpose of the study presented is to analyse the dynamic couplings between the control objectives via relative gain array (RGA) methods, and the realization of input- and output transformations effectively decoupling relevant dynamic interactions. These transformations allow the usage of simple SISO-controllers for each control objective, and a method for controlling motion and fluid temperature concurrently, is proposed and experimentally verified.

info:eu-repo/classification/ddc/620

ddc:620