Deliberative agent (also known as intentional agent) is a sort of software agent used mainly in multi-agent system simulations. According to Wooldridge's definition, a deliberative agent is "one that possesses an explicitly represented, symbolic model of the world, and in which decisions (for example about what actions to perform) are made via symbolic reasoning".[1]

Compared to reactive agents, which are able to reach their goal only by reacting reflexively on external stimuli, a deliberative agent's internal processes are more complex. The difference lies in fact, that deliberative agent maintains a symbolic representation of the world it inhabits.[2] In other words, it possesses internal image of the external environment and is thus capable to plan its actions. Most commonly used architecture for implementing such behavior is Belief-Desire-Intention software model (BDI), where an agent's beliefs about the world (its image of a world), desires (goal) and intentions are internally represented and practical reasoning is applied to decide, which action to select.[2]

There has been considerable research focused on integrating both reactive and deliberative agent strategies resulting in developing a compound called hybrid agent, which combines extensive manipulation with nontrivial symbolic structures and reflexive reactive responses to the external events.[2]

How do deliberative agents work?

It has already been mentioned, that deliberative agents possess a) inherent image of an outer world and b) goal to achieve and is thus able to produce a list of actions (plan) to reach the goal. In unfavorable conditions, when the plan is no more applicable, agent is usually able to recompute it.

The process of plan computing (or recomputing) is as follows:[3]

  • a sensory input is received by the belief revision function and agent's beliefs are altered
  • option generation function evaluates altered beliefs and intentions and creates the options available to the agent. Agent's desires are constituted.
  • filter function then considers current beliefs, desires and intentions and produces new intentions
  • action selection function then receives intentions filter function and decides what action to perform

The deliberative agent requires symbolic representation with compositional semantics (e. g. data tree) in all major functions, for its deliberation is not limited to present facts, but construes hypotheses about possible future states and potentially also holds information about past (i.e. memory). These hypothetic states involve goals, plans, partial solutions, hypothetical states of the agent's beliefs, etc. It is evident, that deliberative process may become considerably complex and hardware killing.[4]

History of a concept

Since the early 1970, the AI planning community has been involved in developing artificial planning agent (a predecessor of a deliberative agent), which would be able to choose a proper plan leading to a specified goal.[5] These early attempts resulted in constructing simple planning system called STRIPS. It soon became obvious that STRIPS concept needed further improvement, for it was unable to effectively solve problems of even moderate complexity.[5] In spite of considerable effort to raise the efficiency (for example by implementing hierarchical and non-linear planning), the system remained somewhat weak while working with any time-constrained system.[6]

More successful attempts have been made in late 1980s to design planning agents. For example, the IPEM (Integrated Planning, Execution and Monitoring system) had a sophisticated non-linear planner embedded. Further, Wood's AUTODRIVE simulated a behavior of deliberative agents in a traffic and Cohen's PHOENIX system was construed to simulate a forest fire management.[6]

In 1976, Simon and Newell formulated the Physical Symbol System hypothesis,[7] which claims, that both human and artificial intelligence have the same principle - symbol representation and manipulation.[2] According to the hypothesis it follows, that there is no substantial difference between human and machine in intelligence, but just quantitative and structural - machines are much less complex.[7] Such a provocative proposition must have become the object of serious criticism and raised a wide discussion, but the problem itself still remains unsolved in its merit until these days.[6]

Further development of classical symbolic AI proved not to be dependent on final verifying the Physical Symbol System hypothesis at all. In 1988, Bratman, Israel and Pollack introduced Intelligent Resource-bounded Machine Architecture (IRMA), the first system implementing the Belief-Desire-Intention software model (BDI). IRMA exemplifies the standard idea of deliberative agent as it is known today: a software agent embedding the symbolic representation and implementing the BDI.[1]

Efficiency of deliberative agents compared to reactive ones

Above-mentioned troubles with symbolic AI have led to serious doubts about the viability of such a concept, which resulted in developing a reactive architecture, which is based on wholly different principles. Developers of the new architecture have rejected using symbolic representation and manipulation as a base of any artificial intelligence. Reactive agents achieve their goals simply through reactions on changing environment, which implies reasonable computational modesty.[8]

Even though deliberative agents consume much more system resources than their reactive colleagues, their results are significantly better just in few special situations, whereas it is usually possible to replace one deliberative agent with few reactive ones in many cases, without losing a substantial deal of the simulation result's adequacy.[8] It seems that classical deliberative agents may be usable especially where correct action is required, for their ability to produce optimal, domain-independent solution.[3] Deliberative agent often fails in changing environment, for it is unable to re-plan its actions quickly enough.[3]

See also

Notes

  1. 1 2 Wooldridge, M. "Conceptualising and Developing Agents". In Proceedings of the UNICOM Seminar on Agent Software. 1st ed. London, 1995. Pp. 42.
  2. 1 2 3 4 Hayzelden, A. L.; Bigham J. Software agents for future communication systems. 1st ed. New York: Springer, 1999. Pp. 101.
  3. 1 2 3 Vlahavas, I.; Vrakas, D. Intelligent techniques for planning. 1st ed. Hershey, PA: Idea Group Publishing, c2005. Pp 235.
  4. Scheutz, M.; Brian Logan, B. "Affective vs. Deliberative Agent Control". In Standish, R., K.; Bedau, M., A.; Abbass, H., A. (Eds.). ICAL 2003 Proceedings of the eighth international conference on Artificial life. 1st ed. Boston, MA: MIT Press Cambridge, c2003. Pp 284 - 295.
  5. 1 2 Wooldridge, M.; Jennings N. R. "Agent Theories, Architectures, and Languages: A Survey". Lecture Notes in Computer Science 890 (1995): 1 - 39. Pp. 13.
  6. 1 2 3 Nilsson, N. "The Physical Symbol System Hypothesis: Status and Prospects". In Lungarella, M.; Iida, F.; Bongard, J. (Eds.). 50 Years of Artificial Intelligence. 1st ed. New York: Springer, 2007. Pp. 9 - 17.
  7. 1 2 Newell, A.; Simon, H. A. "Computer science as empirical inquiry: Symbols and search". Communications of the Association for Computing Machinery 19.3 (1976): 113 - 126.
  8. 1 2 Knight, K. "Are many reactive agents better than a few deliberative ones?". In IJCAI'93: Proceedings of the 13th international joint conference on Artificial intelligence. Vol. 1. 1st ed. Chambery: Morgan Kaufmann Publishers Inc., 1993. Pp 432 - 437.
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