Sectorisation automatisée de l'espace aérien par algorithme génétique / Automated Airspace Sectorization by Genetic Algorithm

Sergeeva, Marina

15 June 2017

Avec la croissance continue du trafic aérien et la limitation des ressources, il est nécessaire de réduire la congestion de l'espace aérien. Ces dernières années, un intérêt particulier a été porté au problème de la sectorisation de l'espace aérien.Pour pallier à cette augmentation continue du trafic en Europe, il est nécessaire d'optimiser la gestion du trafic aérien. Une automatisation de la sectorisation de l'espace aérien peut permettre, dans cette optique, d'accroître l'adaptabilité des configurations du secteur aérien à une nouvelle demande de trafic. L'objectif de la première partie de cette thèse est de proposer une méthode globale de sectorisation de l'espace aérien européen en se basant sur une modélisation mathématique et des méthodes d'optimisation heuristiques. La méthode de sectorisation proposée est basée sur la division initiale de l'espace aérien en cellules de Voronoi à l'aide de méthodes des k-moyennes. Pour des raisons de complexité combinatoire induite, un algorithme d'optimisation stochastique est utilisé pour résoudre le problème de sectorisation. Un algorithme génétique est utilisé pour construire les secteurs de l'espace aérien dans plusieurs zones de contrôle européennes, en se basant sur des données réelles de trafic aérien pendant plusieurs jours.De plus, les configurations du secteur de l'espace aérien doivent être adaptées dynamiquement pour offrir une efficacité et une flexibilité maximales en fonction des conditions météorologiques et de circulation. L'objectif de la deuxième partie de cette thèse est d'adapter automatiquement les configurations de l'espace aérien en fonction de l'évolution du trafic, au cours d'une journée de fonctionnement. Pour atteindre cet objectif, il faut considérer que l'espace aérien est divisé en blocs d'espaces aériens 3D qui doivent être groupés ou dégroupés en fonction de l'état du trafic. La méthode proposée est basée sur une technique de partitionnement de graphe et sur des algorithmes génétiques. La méthode est testée sur plusieurs zones de contrôle européennes. / With the continuous air traffic growth and limits of resources, there is a need for reducing the congestion of the airspace systems. Nowadays, several projects are launched, aimed at modernizing the global air transportation system and air traffic management. In recent years, special interest has been paid to the solution of the airspace sectorization problem. This thesis is devoted to studying the airspace sectorization in Europe and the possibilities to improve it.The airspace sectorization needs to be optimized with the support of automation in order to increase an adaptability of airspace sector configurations to the new traffic demands. The aim of the first part of this thesis is to propose a global method for the sector design of the European airspace based on a mathematical modeling and heuristic optimization methods. The proposed resolution method to solve the sector design problem is based on the initial division of the airspace into Voronoi cells using k-means clustering algorithm. Then, due to the induced combinatorial complexity, a stochastic optimization method is applied to solve the sector design problem. Resolution method based on metaheuristic algorithm called Genetic Algorithm (GA) has been developed to build airspace sectors in several control areas of Europe, involving traffic data for several days. Furthermore, airspace sector configurations need to be dynamically adjusted to provide maximum efficiency and flexibility in response to changing weather/traffic conditions. The objective of the second part of this thesis is to automatically adapt the airspace configurations according to the evolution of traffic. In order to reach this objective, the airspace is considered to be divided into predefined 3D airspace blocks which have to be grouped or ungrouped depending on the traffic situation. The resolution method based on the graph partitioning technique and on the metaheuristic algorithm (GA) has been developed to generate a sequence of sector configurations, composed of the predefined airspace blocks. The overall methodology, is implemented and tested with air traffic data taken for one day of operation and for several different airspace control areas of Europe.

Optimisation

Algorithme génétique

Métriques de complexité

Sectorisation

Design du secteur

Optimization

Genetic Algorithm

Complexity metric

Sector design

Sectorisation

Dynamic sector configuration

Exploring complexity metrics for artifact- centric business process Models

Marin, Mike Andy

02 1900

This study explores complexity metrics for business artifact process models described by Case Management Model and Notation (CMMN). Process models are usually described using Business Process Management (BPM), which is a relatively mature discipline with a large number of practitioners. Over the last few decades a new way of describing data intensive business processes has emerged in BPM literature, for which traditional BPM is no longer adequate. This emerging method, used to describe more flexible processes, is called business artifacts with Guard-Stage-Milestone (GSM). The work on GSM influenced CMMN, which was created to fill a market need for more flexible case management processes for knowledge workers. Complexity metrics have been developed for traditional BPM models, such as the Business Process Model and Notation (BPMN). However, traditional BPM is not suitable for describing GSM or CMMN process models. Therefore, complexity metrics developed for traditional process models may not be applicable to business artifact process models such as CMMN. This study addresses this gap by exploring complexity metrics for business artifact process models using CMMN. The findings of this study have practical implications for the CMMN standard and for the commercial products implementing CMMN. This research makes the following contributions: • The development of a formal description of CMMN using first-order logic. • An exploration of the relationship between CMMN and GSM and the development of transformation procedures between them. • A comparison between the method complexity of CMMN and other popular process methods, including BPMN, Unified Modeling Language (UML) Activity diagrams, and Event-driven Process Charts (EPC). • The creation of a systematic literature review of complexity metrics for process models, which was conducted in order to inform the creation of CMMN metrics. • The identification of a set of complexity metrics for the CMMN standard, which underwent theoretical and empirical validation. This research advances literature in the areas of method complexity, complexity metrics for process models, declarative processes, and research on CMMN by characterizing CMMN method complexity, identifying complexity metrics for CMMN, and exploring the relationship between CMMN and GSM. / School of Computing / Ph. D. (Computer Science)

Business Artifacts

Business Process Management

Business Process Model

BPM

Case Management

Case Management Model and Notation

CMMN

Guard-Stage-Model

GSM

Complexity Metric

Process Model Complexity

Method Complexity

511.352

Computational Complexity

Business enterprises -- Data processing

Software measurement

Exploring complexity metrics for artifact-centric business process models

Marin, Mike A.

02 1900

This study explores complexity metrics for business artifact process models described by Case Management Model and Notation (CMMN). Process models are usually described using Business Process Management (BPM), which is a relatively mature discipline with a large number of practitioners. Over the last few decades a new way of describing data intensive business processes has emerged in BPM literature, for which traditional BPM is no longer adequate. This emerging method, used to describe more flexible processes, is called business artifacts with Guard-Stage-Milestone (GSM). The work on GSM influenced CMMN, which was created to fill a market need for more flexible case management processes for knowledge workers. Complexity metrics have been developed for traditional BPM models, such as the Business Process Model and Notation (BPMN). However, traditional BPM is not suitable for describing GSM or CMMN process models. Therefore, complexity metrics developed for traditional process models may not be applicable to business artifact process models such as CMMN. This study addresses this gap by exploring complexity metrics for business artifact process models using CMMN. The findings of this study have practical implications for the CMMN standard and for the commercial products implementing CMMN. This research makes the following contributions: • The development of a formal description of CMMN using first-order logic. • An exploration of the relationship between CMMN and GSM and the development of transformation procedures between them. • A comparison between the method complexity of CMMN and other popular process methods, including BPMN, Unified Modeling Language (UML) Activity diagrams, and Event-driven Process Charts (EPC). • The creation of a systematic literature review of complexity metrics for process models, which was conducted in order to inform the creation of CMMN metrics. • The identification of a set of complexity metrics for the CMMN standard, which underwent theoretical and empirical validation. This research advances literature in the areas of method complexity, complexity metrics for process models, declarative processes, and research on CMMN by characterizing CMMN method complexity, identifying complexity metrics for CMMN, and exploring the relationship between CMMN and GSM. / Ph.D. (Computer Science)

Business Artifacts

Business Process Management

BPM

Business Process Model

Case Management

Case Management Model and Notation

CMMN

Guard-Stage-Milestone

GSM

Complexity Metric

Process Model Complexity

Method Complexity

658.40630285

Business planning -- Simulation methods

Application of the human-machine interaction model to Multiple Attribute Task Battery (MATB): Task component interaction and the strategy paradigm

Walters, Craig M.

19 September 2012

No description available.

Information Systems

HMI

MATB

human performance

human machine interaction

multiple attribute task battery

multi attribute task battery

strategy

strategy paradigm

human

information theory

quantitative informatic model

system complexity metric

task interaction