Cooperative Monitoring to Diagnose Multiagent Plans

Micalizio, Roberto; Torasso, Pietro

doi:10.1613/jair.4339

Cited by 22 publications

(16 citation statements)

References 41 publications

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“…Researchers in multi-agent systems and deontic logic have addressed the concept of responsibility as the problem of assigning blame for failures of group plans or norms [25][26][27][28][29][30][31][32][33][34][35][36]. This problem has been well studied in the literature, and as determining responsibility is a process performed by a principal, it is largely orthogonal to our focus in this paper: the capabilities needed for an accountable agent to play its role in an accountability relationship with a principal.…”

Section: Related Conceptsmentioning

confidence: 99%

Accountability for Practical Reasoning Agents

Cranefield

Oren

Vasconcelos

2019

Agreement Technologies

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Artificial intelligence has been increasing the autonomy of man-made artefacts such as software agents, self-driving vehicles and military drones. This increase in autonomy together with the ubiquity and impact of such artefacts in our daily lives have raised many concerns in society. Initiatives such as transparent and ethical AI aim to allay fears of a "free for all" future where amoral technology (or technology amorally designed) will replace humans with terrible consequences. We discuss the notion of accountable autonomy, and explore this concept within the context of practical reasoning agents. We survey literature from distinct fields such as management, healthcare, policy-making, and others, and differentiate and relate concepts connected to accountability. We present a list of justified requirements for accountable software agents and discuss research questions stemming from these requirements. We also propose a preliminary formalisation of one core aspect of accountability: responsibility.

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Section: Related Conceptsmentioning

confidence: 99%

Accountability for Practical Reasoning Agents

Cranefield

Oren

Vasconcelos

2019

Agreement Technologies

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“…Specifically, physical conflicts such as a lack of temporal or spatial synchronization, collisions, or the excessive build-up of internal stresses or forces of shared workpieces are likely the result of errors or uncertainty in the robots’ software coordination. At the team level, performance metrics have been proposed to evaluate system-wide errors in multi-robot planning (e.g., Sellner et al (2006), Korsah et al (2013), and Micalizio and Torasso (2014)), communications (Kalech 2012), and conflict negotiations (Kalech and Kaminka 2007). Alternatively, at the individual robot level, performance errors may result from shortcomings in software agility, possibly inferred based on the robot’s measured efficiency and effectiveness (Downs et al 2016).…”

Section: Scheduling and Synchronizing Robotsmentioning

confidence: 99%

Multi-Robot Assembly Strategies and Metrics

2018

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We present a survey of multi-robot assembly applications and methods and describe trends and general insights into the multi-robot assembly problem for industrial applications. We focus on fixtureless assembly strategies featuring two or more robotic systems. Such robotic systems include industrial robot arms, dexterous robotic hands, and autonomous mobile platforms, such as automated guided vehicles. In this survey, we identify the types of assemblies that are enabled by utilizing multiple robots, the algorithms that synchronize the motions of the robots to complete the assembly operations, and the metrics used to assess the quality and performance of the assemblies.

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“…The framework proposed by Micalizio et al [20,21,24] can be considered atemporal, as well, but it differs from the previous one in the action models used during the diagnostic inferences, which are represented as relations defined over a set of state variables. Relational action models, thus, do not represent only the nominal behavior, but one or more faulty behaviors.…”

Section: Related Workmentioning

confidence: 99%

“…An explanation can be given just in terms of actions labeled as failed [38], or in terms of faults representing the root causes for the action failures [21]. In [24] a diagnosis is given in terms of a set of trajectories, defined over the state variables of a given agent, each of which describes a possible (i.e., consistent) explanation for the agent's observed behavior.…”

Section: Introductionmentioning

confidence: 99%

Explaining interdependent action delays in multiagent plans execution

Micalizio

Torta

2015

Auton Agent Multi-Agent Syst

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In this paper we address the problem of diagnosing the execution of Multiagent Plans with interdependent action delays. To this end, we map our problem to the Model-Based Diagnosis setting, and solve it by devising a novel modeling and reasoning method to infer preferred diagnoses based on partial observation of the start and end times of plan actions. Interestingly, we show that the kind of problem we address can be seen as an extension to the well known disjunctive temporal problem with preferences, augmented with a (qualitative) Bayesian network that models dependencies among action delays. An extensive set of tests performed with a prototype implementation on two different problem domains proves the feasibility of the proposed methodology.

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Cooperative Monitoring to Diagnose Multiagent Plans

Cited by 22 publications

References 41 publications

Accountability for Practical Reasoning Agents

Accountability for Practical Reasoning Agents

Multi-Robot Assembly Strategies and Metrics

Explaining interdependent action delays in multiagent plans execution

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