Some Principles in Designing Cooperative Architectures of Autonomous Agents

Abstract

This work introduces some principles for designing agents architectures, which provide design guidelines concerning agent and group structuring, communication, decision making, and computational aspects for agent cooperation. They generate requirements and constraints for cooperative agent~ develupment. The principles have been derived fr~n a long experience in designing and implementing architectural frameworks for agent cooperation, the Coope~A project (Sommaruga et al 1995). In particular, basic characteristics of autonomous agents have been formnli.q~d in a computational model This model consists of two elements: the agent itself and its environment (Figure 1). The model of an agent is expressed as a dynamic system in a flotation (T) with inputs (I) outputs (O), a conlrol function (Sel) for the selection of best action to do according to a set of cooperative behavionrs (B), and an input function (In), which changes the current situation according to the input. In the environment, we distinguish two general sets, common for a whole group of agents, and independent from the agent: R and C. R is the real world, which can receive outputs from the agents, e.g. the execution of an agent action, and can provide inputs to the agents, e.g. data/observations of the real world. C represents the communication channel between the agents. The conswJctive aggregation of agents within an environment generates a cooperative architectm’e. This computational model has been abstracted in order to define a formal roferenee model for our principles. Some of the principles are dictated by very general constraints on computational (intelligent) systems. Others are influenced by more specific DAI and cooperative requi.,-ements. Due to the limited space, it is not possible to present here the complete formalization, and the principles will he only mentioned. They include: the Communality Requirement (P.1), i.e. the need for overlapping skills mid needs among agents; Action Selection (P,2), which maps a situation and a bchaviour of an agent to a new situation with a possible output action; Communication Requirement (P.3), which states the usefulness of a communication protocol, a common dictionary, and a message passing mechanism; Group Dynamics (PA), which allows the composition the set of skills and needs of the whole group of agents to be varied; Self Initialisation (P.5), which permits integrate a new agent into a group and hence makes the group of agents open; Principle of Patience (P.6), expressing the agent ability to wait for some change; Goal Induction (P.7) of the possible agent actions, based on act-based semantics; Cooperative Heuristics (P.8), which express programmable micro-bchavionrs of an agent, and are explicitly defined in the form of rules; Compositionallty of Local micro-bchavionr (P.9), which determines the global agent behaviour; and Compositionality of Global Behaviour (P.10) of a group, which is determined by the composition of the behaviours of each agent in the group.

Extracted Key Phrases

1 Figure or Table

Cite this paper

@inproceedings{Sommaruga1995SomePI, title={Some Principles in Designing Cooperative Architectures of Autonomous Agents}, author={Lorenzo Sommaruga and Nadia Catenazzi}, booktitle={ICMAS}, year={1995} }