Verification of behaviourist multi-agent systems by means of formally guided simulations
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2011 |
| Tipo de documento: | Tese |
| Idioma: | eng |
| Título da fonte: | Biblioteca Digital de Teses e Dissertações da USP |
| Texto Completo: | http://www.teses.usp.br/teses/disponiveis/45/45134/tde-10042012-100539/ |
Resumo: | Multi-agent systems (MASs) can be used to model phenomena that can be decomposed into several interacting agents which exist within an environment. In particular, they can be used to model human and animal societies, for the purpose of analysing their properties by computational means. This thesis is concerned with the automated analysis of a particular kind of such social models, namely, those based on behaviourist principles, which contrasts with the more dominant cognitive approaches found in the MAS literature. The hallmark of behaviourist theories is the emphasis on the definition of behaviour in terms of the interaction between agents and their environment. In this manner, not merely re exive actions, but also learning, drives, and emotions can be defined. More specifically, in this thesis we introduce a formal agent architecture (specified with the Z Notation) based on the Behaviour Analysis theory of B. F. Skinner, and provide a suitable formal notion of environment (based on the pi-calculus process algebra) to bring such agents together as an MAS. Simulation is often used to analyse MASs. The techniques involved typically consist in implementing and then simulating a MAS several times to either collect statistics or see what happens through animation. However, simulations can be used in a more verification-oriented manner if one considers that they are actually explorations of large state-spaces. In this thesis we propose a novel verification technique based on this insight, which consists in simulating a MAS in a guided way in order to check whether some hypothesis about it holds or not. To this end, we leverage the prominent position that environments have in the MASs of this thesis: the formal specification of the environment of a MAS serves to compute the possible evolutions of the MAS as a transition system, thereby establishing the state-space to be investigated. In this computation, agents are taken into account by being simulated in order to determine, at each environmental state, what their actions are. Each simulation execution is a sequence of states in this state-space, which is computed on-the-fly, as the simulation progresses. The hypothesis to be investigated, in turn, is given as another transition system, called a simulation purpose, which defines the desirable and undesirable simulations (e.g., \"every time the agent does X, it will do Y later\"). It is then possible to check whether the MAS satisfies the simulation purpose according to a number of precisely defined notions of satisfiability. Algorithmically, this corresponds to building a synchronous product of these two transitions systems (i.e., the MAS\'s and the simulation purpose) on-the-fly and using it to operate a simulator. That is to say, the simulation purpose is used to guide the simulator, so that only the relevant states are actually simulated. By the end of such an algorithm, it delivers either a conclusive or an inconclusive verdict. If conclusive, it becomes known whether the MAS satisfies the simulation purpose with respect to the observations made during simulations. If inconclusive, it is possible to perform some adjustments and try again. In summary, then, in this thesis we provide four novel elements: (i) an agent architecture; (ii) a formal specification of the environment of these agents, so that they can be composed into an MAS; (iii) a structure to describe the property of interest, which we named simulation purpose; and (iv) a technique to formally analyse the resulting MAS with respect to a simulation purpose. These elements are implemented in a tool, called Formally Guided Simulator (FGS). Case studies executable in FGS are provided to illustrate the approach. |
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Verification of behaviourist multi-agent systems by means of formally guided simulationsVerificação de sistemas multi-agentes comportamentalistas através de simulações formalmente guiadasambientesbehaviourismcomportamentalismoenvironmentsformal methodsformal verificationmétodos formaismodel-based testingmulti-agent systemssimulaçãosimulationsistemas multi-agentesteste baseado em modelosverificação formalMulti-agent systems (MASs) can be used to model phenomena that can be decomposed into several interacting agents which exist within an environment. In particular, they can be used to model human and animal societies, for the purpose of analysing their properties by computational means. This thesis is concerned with the automated analysis of a particular kind of such social models, namely, those based on behaviourist principles, which contrasts with the more dominant cognitive approaches found in the MAS literature. The hallmark of behaviourist theories is the emphasis on the definition of behaviour in terms of the interaction between agents and their environment. In this manner, not merely re exive actions, but also learning, drives, and emotions can be defined. More specifically, in this thesis we introduce a formal agent architecture (specified with the Z Notation) based on the Behaviour Analysis theory of B. F. Skinner, and provide a suitable formal notion of environment (based on the pi-calculus process algebra) to bring such agents together as an MAS. Simulation is often used to analyse MASs. The techniques involved typically consist in implementing and then simulating a MAS several times to either collect statistics or see what happens through animation. However, simulations can be used in a more verification-oriented manner if one considers that they are actually explorations of large state-spaces. In this thesis we propose a novel verification technique based on this insight, which consists in simulating a MAS in a guided way in order to check whether some hypothesis about it holds or not. To this end, we leverage the prominent position that environments have in the MASs of this thesis: the formal specification of the environment of a MAS serves to compute the possible evolutions of the MAS as a transition system, thereby establishing the state-space to be investigated. In this computation, agents are taken into account by being simulated in order to determine, at each environmental state, what their actions are. Each simulation execution is a sequence of states in this state-space, which is computed on-the-fly, as the simulation progresses. The hypothesis to be investigated, in turn, is given as another transition system, called a simulation purpose, which defines the desirable and undesirable simulations (e.g., \"every time the agent does X, it will do Y later\"). It is then possible to check whether the MAS satisfies the simulation purpose according to a number of precisely defined notions of satisfiability. Algorithmically, this corresponds to building a synchronous product of these two transitions systems (i.e., the MAS\'s and the simulation purpose) on-the-fly and using it to operate a simulator. That is to say, the simulation purpose is used to guide the simulator, so that only the relevant states are actually simulated. By the end of such an algorithm, it delivers either a conclusive or an inconclusive verdict. If conclusive, it becomes known whether the MAS satisfies the simulation purpose with respect to the observations made during simulations. If inconclusive, it is possible to perform some adjustments and try again. In summary, then, in this thesis we provide four novel elements: (i) an agent architecture; (ii) a formal specification of the environment of these agents, so that they can be composed into an MAS; (iii) a structure to describe the property of interest, which we named simulation purpose; and (iv) a technique to formally analyse the resulting MAS with respect to a simulation purpose. These elements are implemented in a tool, called Formally Guided Simulator (FGS). Case studies executable in FGS are provided to illustrate the approach.Sistemas multi-agentes (SMAs) podem ser usados para modelar fenômenos que podem ser decompostos em diversos agentes que interagem entre si dentro de um ambiente. Em particular, eles podem ser usados para modelar sociedades humanas e animais, com a finalidade de se analisar as suas propriedades computacionalmente. Esta tese trata da análise automatizada de um tipo particular de tais modelos sociais, a saber, aqueles baseados em princípios behavioristas, o que contrasta com as abordagens cognitivas mais dominante na literatura de SMAs. A principal característica das teorias behaviorista é a ênfase na descrição do comportamento em termos da interação entre agentes e seu ambiente. Desta forma, não apenas ações refl exivas, mas também de aprendizado, motivações, e as emoções podem ser definidas. Mais especificamente, nesta tese apresentamos uma arquitetura de agentes formal (especificada através da Notação Z) baseada na teoria da Análise do Comportamento de B. F. Skinner, e fornecemos uma noção adequada e formal de ambiente (com base na álgebra de processos pi-calculus) para colocar tais agentes juntos em um SMA. Simulações são freqüentemente utilizadas para se analisar SMAs. As técnicas envolvidas tipicamente consistem em simular um SMA diversas vezes, seja para coletar estatísticas, seja para observar o que acontece através de animações. Contudo, simulações podem ser usadas de forma a pertmitir a realização de verificações automatizadas do SMA caso sejam entendidas como explorações de grandes espaços-de-estados. Nesta tese propomos uma técnica de verificação baseada nessa observação, que consiste em simular um SMA de uma forma guiada, a fim de se determinar se uma dada hipótese sobre ele é verdadeira ou não. Para tal fim, tiramos proveito da importância que os ambientes têm nesta tese: a especificação formal do ambiente de um SMA serve para calcular as evoluções possíveis do SMA como um sistema de transição, estabelecendo assim o espaço-de-estados a ser investigado. Neste cálculo, os agentes são levados em conta simulando-os, a fim de determinar, em cada estado do ambiente, quais são suas ações. Cada execução da simulação é uma seqüência de estados nesse espaço-de-estados, que é calculado em tempo de execução, conforme a simulação progride. A hipótese a ser investigada, por sua vez, é dada como um outro sistema de transição, chamado propósito de simulação, o qual define as simulações desejáveis e indesejáveis (e.g., \"sempre que o agente fizer X, ele fará Y depois\"). Em seguida, é possível verificar se o SMA satisfaz o propósito de simulação de acordo com uma série de relações de satisfatibilidade precisamente definidas. Algoritmicamente, isso corresponde a construir um produto síncrono desses dois sistemas de transições (i.e., o do SMA e o do propósito de simulação) em tempo de execução e usá-lo para operar um simulador. Ou seja, o propósito de simulação é usado para guiar o simulador, de modo que somente os estados relevantes sejam efetivamente simulados. Ao terminar, um tal algoritmo pode fornecer um veredito conclusivo ou inconclusivo. Se conclusivo, descobre-se se o SMA satisfaz ou não o propósito de simulação com relação às observações feitas durante as simulações. Se inconclusivo, é possível realizar alguns ajustes e tentar novamente. em resumo, portanto, nesta tese propomos quatro novos elementos: (i) uma arquitetura de agente, (ii) uma especificação formal do ambiente desses agentes, de modo que possam ser compostos em um SMA, (iii) uma estrutura para descrever a propriedade de interesse, a qual chamamos de propósito de simulação, e (iv) uma técnica para se analisar formalmente o SMA resultante com relação a um propósito de simulação. Esses elementos estão implementados em uma ferramenta, denominada Simulador Formalmente Guiado (FGS, do inglês Formally Guided Simulator). Estudos de caso executáveis no FGS são fornecidos para ilustrar a abordagem.Biblioteca Digitais de Teses e Dissertações da USPMelo, Ana Cristina Vieira deSilva, Paulo Salem da2011-11-28info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/doctoralThesisapplication/pdfhttp://www.teses.usp.br/teses/disponiveis/45/45134/tde-10042012-100539/reponame:Biblioteca Digital de Teses e Dissertações da USPinstname:Universidade de São Paulo (USP)instacron:USPLiberar o conteúdo para acesso público.info:eu-repo/semantics/openAccesseng2016-07-28T16:10:31Zoai:teses.usp.br:tde-10042012-100539Biblioteca Digital de Teses e Dissertaçõeshttp://www.teses.usp.br/PUBhttp://www.teses.usp.br/cgi-bin/mtd2br.plvirginia@if.usp.br|| atendimento@aguia.usp.br||virginia@if.usp.bropendoar:27212016-07-28T16:10:31Biblioteca Digital de Teses e Dissertações da USP - Universidade de São Paulo (USP)false |
| dc.title.none.fl_str_mv |
Verification of behaviourist multi-agent systems by means of formally guided simulations Verificação de sistemas multi-agentes comportamentalistas através de simulações formalmente guiadas |
| title |
Verification of behaviourist multi-agent systems by means of formally guided simulations |
| spellingShingle |
Verification of behaviourist multi-agent systems by means of formally guided simulations Silva, Paulo Salem da ambientes behaviourism comportamentalismo environments formal methods formal verification métodos formais model-based testing multi-agent systems simulação simulation sistemas multi-agentes teste baseado em modelos verificação formal |
| title_short |
Verification of behaviourist multi-agent systems by means of formally guided simulations |
| title_full |
Verification of behaviourist multi-agent systems by means of formally guided simulations |
| title_fullStr |
Verification of behaviourist multi-agent systems by means of formally guided simulations |
| title_full_unstemmed |
Verification of behaviourist multi-agent systems by means of formally guided simulations |
| title_sort |
Verification of behaviourist multi-agent systems by means of formally guided simulations |
| author |
Silva, Paulo Salem da |
| author_facet |
Silva, Paulo Salem da |
| author_role |
author |
| dc.contributor.none.fl_str_mv |
Melo, Ana Cristina Vieira de |
| dc.contributor.author.fl_str_mv |
Silva, Paulo Salem da |
| dc.subject.por.fl_str_mv |
ambientes behaviourism comportamentalismo environments formal methods formal verification métodos formais model-based testing multi-agent systems simulação simulation sistemas multi-agentes teste baseado em modelos verificação formal |
| topic |
ambientes behaviourism comportamentalismo environments formal methods formal verification métodos formais model-based testing multi-agent systems simulação simulation sistemas multi-agentes teste baseado em modelos verificação formal |
| description |
Multi-agent systems (MASs) can be used to model phenomena that can be decomposed into several interacting agents which exist within an environment. In particular, they can be used to model human and animal societies, for the purpose of analysing their properties by computational means. This thesis is concerned with the automated analysis of a particular kind of such social models, namely, those based on behaviourist principles, which contrasts with the more dominant cognitive approaches found in the MAS literature. The hallmark of behaviourist theories is the emphasis on the definition of behaviour in terms of the interaction between agents and their environment. In this manner, not merely re exive actions, but also learning, drives, and emotions can be defined. More specifically, in this thesis we introduce a formal agent architecture (specified with the Z Notation) based on the Behaviour Analysis theory of B. F. Skinner, and provide a suitable formal notion of environment (based on the pi-calculus process algebra) to bring such agents together as an MAS. Simulation is often used to analyse MASs. The techniques involved typically consist in implementing and then simulating a MAS several times to either collect statistics or see what happens through animation. However, simulations can be used in a more verification-oriented manner if one considers that they are actually explorations of large state-spaces. In this thesis we propose a novel verification technique based on this insight, which consists in simulating a MAS in a guided way in order to check whether some hypothesis about it holds or not. To this end, we leverage the prominent position that environments have in the MASs of this thesis: the formal specification of the environment of a MAS serves to compute the possible evolutions of the MAS as a transition system, thereby establishing the state-space to be investigated. In this computation, agents are taken into account by being simulated in order to determine, at each environmental state, what their actions are. Each simulation execution is a sequence of states in this state-space, which is computed on-the-fly, as the simulation progresses. The hypothesis to be investigated, in turn, is given as another transition system, called a simulation purpose, which defines the desirable and undesirable simulations (e.g., \"every time the agent does X, it will do Y later\"). It is then possible to check whether the MAS satisfies the simulation purpose according to a number of precisely defined notions of satisfiability. Algorithmically, this corresponds to building a synchronous product of these two transitions systems (i.e., the MAS\'s and the simulation purpose) on-the-fly and using it to operate a simulator. That is to say, the simulation purpose is used to guide the simulator, so that only the relevant states are actually simulated. By the end of such an algorithm, it delivers either a conclusive or an inconclusive verdict. If conclusive, it becomes known whether the MAS satisfies the simulation purpose with respect to the observations made during simulations. If inconclusive, it is possible to perform some adjustments and try again. In summary, then, in this thesis we provide four novel elements: (i) an agent architecture; (ii) a formal specification of the environment of these agents, so that they can be composed into an MAS; (iii) a structure to describe the property of interest, which we named simulation purpose; and (iv) a technique to formally analyse the resulting MAS with respect to a simulation purpose. These elements are implemented in a tool, called Formally Guided Simulator (FGS). Case studies executable in FGS are provided to illustrate the approach. |
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2011 |
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2011-11-28 |
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info:eu-repo/semantics/publishedVersion |
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info:eu-repo/semantics/doctoralThesis |
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doctoralThesis |
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publishedVersion |
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http://www.teses.usp.br/teses/disponiveis/45/45134/tde-10042012-100539/ |
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http://www.teses.usp.br/teses/disponiveis/45/45134/tde-10042012-100539/ |
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eng |
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eng |
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Liberar o conteúdo para acesso público. info:eu-repo/semantics/openAccess |
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Liberar o conteúdo para acesso público. |
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Biblioteca Digitais de Teses e Dissertações da USP |
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Biblioteca Digitais de Teses e Dissertações da USP |
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Biblioteca Digital de Teses e Dissertações da USP - Universidade de São Paulo (USP) |
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