Disseny de controladors òptims per al robot Pioneer

Aquest projecte titulat: “Disseny de controladors òptims per al robot Pioneer”, té com a funció incloure en la recerca, que ja està iniciada, del control del Robot Pioneer 2DX, una nova versió d’agents go to per al funcionament del robot. La problemàtica que ens trobem és sobretot per al primer controlador. Fins ara el sistema multi-agent fet, feia servir un agent go to que generava la trajectòria a seguir i la controlava mitjançant un PID. Introduint un mètode geomètric com és el cas del pure pursuit la cosa es complica ja que és més complex l’ajustament del funcionament d’aquest. Centrant-nos en canvi el cas del segon controlador el problema es simplifica ja que l’ajustatge d’aquest mateix es pot realitzar de manera empírica i la problemàtica per a la situació en concret es millora amb major facilitat. És per aquest motiu, sobretot pel primer controlador, que s’han hagut de realitzar algunes modificacions en el plantejament del projecte al llarg d’aquest. En un principi estava pensat crear aquest controlador a través de Matlab® mitjançant l’eina Simulink® però per problemes de software en un moment donat hem hagut de redirigir el projecte cap al llenguatge base de l’estructura multi-agent com és el C++. Per aquest motiu també s’ha hagut de prescindir de la implementació d’aquests també en l’estructura LabView®.

Simplification, approximation and deformation of large models

The high level of realism and interaction in many computer graphic applications requires techniques for processing complex geometric models. First, we present a method that provides an accurate low-resolution approximation from a multi-chart textured model that guarantees geometric fidelity and correct preservation of the appearance attributes. Then, we introduce a mesh structure called Compact Model that approximates dense triangular meshes while preserving sharp features, allowing adaptive reconstructions and supporting textured models. Next, we design a new space deformation technique called *Cages based on a multi-level system of cages that preserves the smoothness of the mesh between neighbouring cages and is extremely versatile, allowing the use of heterogeneous sets of coordinates and different levels of deformation. Finally, we propose a hybrid method that allows to apply any deformation technique on large models obtaining high quality results with a reduced memory footprint and a high performance.

Disseny d'agents físics: inclusió de capacitats específiques per a l'avaluació de l'eficiència d'accions

L'experiència de l'autor en la temàtica d'agents intel·ligents i la seva aplicació als robots que emulen el joc de futbol han donat el bagatge suficient per poder encetar i proposar la temàtica plantejada en aquesta tesi: com fer que un complicat robot pugui treure el màxim suc de l'autoconeixement de l'estructura de control inclosa al seu propi cos físic, i així poder cooperar millor amb d'altres agents per optimitzar el rendiment a l'hora de resoldre problemes de cooperació. Per resoldre aquesta qüestió es proposa incorporar la dinàmica del cos físic en les decisions cooperatives dels agents físics unificant els móns de l'automàtica, la robòtica i la intel·ligència artificial a través de la noció de capacitat: la capacitat vista com a entitat on els enginyers de control dipositen el seu coneixement, i a la vegada la capacitat vista com la utilitat on un agent hi diposita el seu autoconeixement del seu cos físic que ha obtingut per introspecció. En aquesta tesi es presenta l'arquitectura DPAA que s'organitza seguint una jerarquia vertical en tres nivells d'abstracció o mòduls control, supervisor i agent, els quals presenten una estructura interna homogènia que facilita les tasques de disseny de l'agent. Aquests mòduls disposen d'un conjunt específic de capacitats que els permeten avaluar com seran les accions que s'executaran en un futur. En concret, al mòdul de control (baix nivell d'abstracció) les capacitats consisteixen en paràmetres que descriuen el comportament dinàmic i estàtic que resulta d'executar un controlador determinat, és a dir, encapsulen el coneixement de l'enginyer de control. Així, a través dels mecanismes de comunicació entre mòduls aquest coneixement pot anar introduint-se als mecanismes de decisió dels mòduls superiors (supervisor i agent) de forma que quan els paràmetres dinàmics i estàtics indiquin que pot haver-hi problemes a baix nivell, els mòduls superiors es poden responsabilitzar d'inhibir o no l'execució d'algunes accions. Aquest procés top-down intern d'avaluació de la viabilitat d'executar una acció determinada s'anomena procés d'introspecció. Es presenten diversos exemples per tal d'il·lustrar com es pot dissenyar un agent físic amb dinàmica pròpia utilitzant l'arquitectura DPAA com a referent. En concret, es mostra tot el procés a seguir per dissenyar un sistema real format per dos robots en formació de comboi, i es mostra com es pot resoldre el problema de la col·lisió utilitzant les capacitats a partir de les especificacions de disseny de l'arquitectura DPAA. Al cinquè capítol s'hi exposa el procés d'anàlisi i disseny en un domini més complex: un grup de robots que emulen el joc del futbol. Els resultats que s'hi mostren fan referència a l'avaluació de la validesa de l'arquitectura per resoldre el problema de la passada de la pilota. S'hi mostren diversos resultats on es veu que és possible avaluar si una passada de pilota és viable o no. Encara que aquesta possibilitat ja ha estat demostrada en altres treballs, l'aportació d'aquesta tesi està en el fet que és possible avaluar la viabilitat a partir de l'encapsulament de la dinàmica en unes capacitats específiques, és a dir, és possible saber quines seran les característiques de la passada: el temps del xut, la precisió o inclòs la geometria del moviment del robot xutador. Els resultats mostren que la negociació de les condicions de la passada de la pilota és possible a partir de capacitats atòmiques, les quals inclouen informació sobre les característiques de la dinàmica dels controladors. La complexitat del domini proposat fa difícil comparar els resultats amb els altres treballs. Cal tenir present que els resultats mostrats s'han obtingut utilitzant un simulador fet a mida que incorpora les dinàmiques dels motors dels robots i de la pilota. En aquest sentit cal comentar que no existeixen treballs publicats sobre el problema de la passada en què es tingui en compte la dinàmica dels robots. El present treball permet assegurar que la inclusió de paràmetres dinàmics en el conjunt de les capacitats de l'agent físic permet obtenir un millor comportament col·lectiu dels robots, i que aquesta millora es deu al fet que en les etapes de decisió els agents utilitzen informació relativa a la viabilitat sobre les seves accions: aquesta viabilitat es pot calcular a partir del comportament dinàmic dels controladors. De fet, la definició de capacitats a partir de paràmetres dinàmics permet treballar fàcilment amb sistemes autònoms heterogenis: l'agent físic pot ser conscient de les seves capacitats d'actuació a través de mecanismes interns d'introspecció, i això permet que pugui prendre compromisos amb altres agents físics.

KNIME: the Konstanz Information Miner

The Konstanz Information Miner is a modular environment which enables easy visual assembly and interactive execution of a data pipeline. It is designed as a teaching, research and collaboration platform, which enables easy integration of new algorithms, data manipulation or visualization methods as new modules or nodes. In this paper we describe some of the design aspects of the underlying architecture and briefly sketch how new nodes can be incorporated.

General systems perspective on achieving continuous synergy in a project organisation

Studies of construction labour productivity have revealed that limited predictability and multi-agent social complexity make long-range planning of construction projects extremely inaccurate. Fire-fighting, a cultural feature of construction project management, social and structural diversity of involved permanent organizations, and structural temporality all contribute towards relational failures and frequent changes. The main purpose of this paper is therefore to demonstrate that appropriate construction planning may have a profound synergistic effect on structural integration of a project organization. Using the general systems theory perspective it is further a specific objective to investigate and evaluate organizational effects of changes in planning and potentials for achieving continuous project-organizational synergy. The newly developed methodology recognises that planning should also represent a continuous, improvement-leading driving force throughout a project. The synergistic effect of the process planning membership duality fostered project-wide integration, eliminated internal boundaries, and created a pool of constantly upgrading knowledge. It maintained a creative environment that resulted in a number of process-related improvements from all parts of the organization. As a result labour productivity has seen increases of more than 30%, profits have risen from an average of 12% to more than 18%, and project durations have been reduced by several days.

Intelligent agents: are they feasible in swarm-array computing?

The work reported in this paper proposes 'Intelligent Agents', a Swarm-Array computing approach focused to apply autonomic computing concepts to parallel computing systems and build reliable systems for space applications. Swarm-array computing is a robotics a swarm robotics inspired novel computing approach considered as a path to achieve autonomy in parallel computing systems. In the intelligent agent approach, a task to be executed on parallel computing cores is considered as a swarm of autonomous agents. A task is carried to a computing core by carrier agents and can be seamlessly transferred between cores in the event of a predicted failure, thereby achieving self-* objectives of autonomic computing. The approach is validated on a multi-agent simulator.

Intelligent cores and intelligent agents: two approaches to achieve autonomy in swarm-array computing

How can a bridge be built between autonomic computing approaches and parallel computing systems? How can autonomic computing approaches be extended towards building reliable systems? How can existing technologies be merged to provide a solution for self-managing systems? The work reported in this paper aims to answer these questions by proposing Swarm-Array Computing, a novel technique inspired from swarm robotics and built on the foundations of autonomic and parallel computing paradigms. Two approaches based on intelligent cores and intelligent agents are proposed to achieve autonomy in parallel computing systems. The feasibility of the proposed approaches is validated on a multi-agent simulator.

Applying autonomic computing concepts to parallel computing using intelligent agents

The work reported in this paper is motivated by the fact that there is a need to apply autonomic computing concepts to parallel computing systems. Advancing on prior work based on intelligent cores [36], a swarm-array computing approach, this paper focuses on ‘Intelligent agents’ another swarm-array computing approach in which the task to be executed on a parallel computing core is considered as a swarm of autonomous agents. A task is carried to a computing core by carrier agents and is seamlessly transferred between cores in the event of a predicted failure, thereby achieving self-ware objectives of autonomic computing. The feasibility of the proposed swarm-array computing approach is validated on a multi-agent simulator.

Achieving intelligent agents and its feasibility in swarm-array computing

The work reported in this paper proposes ‘Intelligent Agents’, a Swarm-Array computing approach focused to apply autonomic computing concepts to parallel computing systems and build reliable systems for space applications. Swarm-array computing is a robotics a swarm robotics inspired novel computing approach considered as a path to achieve autonomy in parallel computing systems. In the intelligent agent approach, a task to be executed on parallel computing cores is considered as a swarm of autonomous agents. A task is carried to a computing core by carrier agents and can be seamlessly transferred between cores in the event of a predicted failure, thereby achieving self-* objectives of autonomic computing. The approach is validated on a multi-agent simulator.

Positioning Janus nanoparticles in block copolymer scaffolds

The periodic domains formed by block copolymer melts have been heralded as potential scaffolds for arranging nanoparticles in 3d space, provided we can control the positioning of the particles. Recent experiments have located particles at the domain interfaces by grafting mixed brushes to their surfaces. Here the underlying mechanism, which involves the transformation into Janus particles, is investigated with self-consistent field theory using a new multi-coordinate-system algorithm.

Exploring carrier agents in swarm-array computing

How can a bridge be built between autonomic computing approaches and parallel computing systems? The work reported in this paper is motivated towards bridging this gap by proposing a swarm-array computing approach based on ‘Intelligent Agents’ to achieve autonomy for distributed parallel computing systems. In the proposed approach, a task to be executed on parallel computing cores is carried onto a computing core by carrier agents that can seamlessly transfer between processing cores in the event of a predicted failure. The cognitive capabilities of the carrier agents on a parallel processing core serves in achieving the self-ware objectives of autonomic computing, hence applying autonomic computing concepts for the benefit of parallel computing systems. The feasibility of the proposed approach is validated by simulation studies using a multi-agent simulator on an FPGA (Field-Programmable Gate Array) and experimental studies using MPI (Message Passing Interface) on a computer cluster. Preliminary results confirm that applying autonomic computing principles to parallel computing systems is beneficial.

Emotion and anticipation in an enactive framework for cognition (response to Andy Clark)

Undeniably, anticipation plays a crucial role in cognition. By what means, to what extent, and what it achieves remain open questions. In a recent BBS target article, Clark (in press) depicts an integrative model of the brain that builds on hierarchical Bayesian models of neural processing (Rao and Ballard, 1999; Friston, 2005; Brown et al., 2011), and their most recent formulation using the free-energy principle borrowed from thermodynamics (Feldman and Friston, 2010; Friston, 2010; Friston et al., 2010). Hierarchical generative models of cognition, such as those described by Clark, presuppose the manipulation of representations and internal models of the world, in as much detail as is perceptually available. Perhaps surprisingly, Clark acknowledges the existence of a “virtual version of the sensory data” (p. 4), but with no reference to some of the historical debates that shaped cognitive science, related to the storage, manipulation, and retrieval of representations in a cognitive system (Shanahan, 1997), or accounting for the emergence of intentionality within such a system (Searle, 1980; Preston and Bishop, 2002). Instead of demonstrating how this Bayesian framework responds to these foundational questions, Clark describes the structure and the functional properties of an action-oriented, multi-level system that is meant to combine perception, learning, and experience (Niedenthal, 2007).

ATD: a multiplatform for semiautomatic 3-D detection of kidneys and their pathology in real time

This research presents a novel multi-functional system for medical Imaging-enabled Assistive Diagnosis (IAD). Although the IAD demonstrator has focused on abdominal images and supports the clinical diagnosis of kidneys using CT/MRI imaging, it can be adapted to work on image delineation, annotation and 3D real-size volumetric modelling of other organ structures such as the brain, spine, etc. The IAD provides advanced real-time 3D visualisation and measurements with fully automated functionalities as developed in two stages. In the first stage, via the clinically driven user interface, specialist clinicians use CT/MRI imaging datasets to accurately delineate and annotate the kidneys and their possible abnormalities, thus creating “3D Golden Standard Models”. Based on these models, in the second stage, clinical support staff i.e. medical technicians interactively define model-based rules and parameters for the integrated “Automatic Recognition Framework” to achieve results which are closest to that of the clinicians. These specific rules and parameters are stored in “Templates” and can later be used by any clinician to automatically identify organ structures i.e. kidneys and their possible abnormalities. The system also supports the transmission of these “Templates” to another expert for a second opinion. A 3D model of the body, the organs and their possible pathology with real metrics is also integrated. The automatic functionality was tested on eleven MRI datasets (comprising of 286 images) and the 3D models were validated by comparing them with the metrics from the corresponding “3D Golden Standard Models”. The system provides metrics for the evaluation of the results, in terms of Accuracy, Precision, Sensitivity, Specificity and Dice Similarity Coefficient (DSC) so as to enable benchmarking of its performance. The first IAD prototype has produced promising results as its performance accuracy based on the most widely deployed evaluation metric, DSC, yields 97% for the recognition of kidneys and 96% for their abnormalities; whilst across all the above evaluation metrics its performance ranges between 96% and 100%. Further development of the IAD system is in progress to extend and evaluate its clinical diagnostic support capability through development and integration of additional algorithms to offer fully computer-aided identification of other organs and their abnormalities based on CT/MRI/Ultra-sound Imaging.

Is the unfolding of the group discussion off-pattern? Improving coordination support in educational forums using mobile devices

A forum is a valuable tool to foster reflection in an in-depth discussion; however, it forces the course mediator to continually pay close attention in order to coordinate learners` activities. Moreover, monitoring a forum is time consuming given that it is impossible to know in advance when new messages are going to be posted. Additionally, a forum may be inactive for a long period and suddenly receive a burst of messages forcing forum mediators to frequently log on in order to know how the discussion is unfolding to intervene whenever it is necessary. Mediators also need to deal with a large amount of messages to identify off-pattern situations. This work presents a piece of action research that investigates how to improve coordination support in a forum using mobile devices for mitigating mediator`s difficulties in following the status of a forum. Based on summarized information extracted from message meta-data, mediators consult visual information summaries on PDAs and receive textual notifications in their mobile phone. This investigation revealed that mediators used the mobile-based coordination support to keep informed on what is taking place within the forum without the need to log on their desktop computer. (C) 2009 Elsevier Ltd. All rights reserved.