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Cooperating Intelligent Systems

Cooperating Intelligent Systems. Intelligent Agents Chapter 2, AIMA. Percepts. Sensors. ?. Environment. Agent. Actions. Effectors. An agent. Image borrowed from W. H. Hsu, KSU. An agent perceives its environment through sensors and acts upon that environment through actuators .

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Cooperating Intelligent Systems

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  1. Cooperating Intelligent Systems Intelligent Agents Chapter 2, AIMA

  2. Percepts Sensors ? Environment Agent Actions Effectors An agent Image borrowed from W. H. Hsu, KSU An agent perceives its environment through sensors and acts upon that environment through actuators. Percepts x Actions a Agent function f

  3. Percepts Sensors ? Environment Agent Actions Effectors An agent Image borrowed from W. H. Hsu, KSU An agent perceives its environment through sensors and acts upon that environment through actuators. Percepts x Actions a Agent function f ”Percept sequence”

  4. A B Example: Vacuum cleaner world Image borrowed from V. Pavlovic, Rutgers Percepts:x1(t)  {A, B}, x2(t)  {clean, dirty} Actions:a1(t) = suck, a2(t) =right, a3(t) = left

  5. A B Example: Vacuum cleaner world Image borrowed from V. Pavlovic, Rutgers Percepts:x1(t)  {A, B}, x2(t)  {clean, dirty} Actions:a1(t) = suck, a2(t) =right, a3(t) = left This is an example of a reflex agent

  6. A rational agent A rational agent does ”the right thing”: For each possible percept sequence, x(t)...x(0),should a rational agent select the action thatis expected to maximize its performancemeasure, given the evidence provided by thepercept sequence and whatever built-inknowledge the agent has. We design the performance measure, S

  7. Rationality • Rationality ≠ omniscience • Rational decision depends on the agent’s experiences in the past (up to now), not expected experiences in the future or others’ experiences (unknown to the agent). • Rationality means optimizing expected performance, omniscience is perfect knowledge.

  8. A B Vacuum cleaner world performance measure Image borrowed from V. Pavlovic, Rutgers State definedperf. measure Does notreally leadto goodbehavior Action definedperf. measure

  9. Task environment = problem to which the agent is a solution. Task environment

  10. Some basic agents • Random agent • Reflex agent • Model-based agent • Goal-based agent • Utility-based agent • Learning agents

  11. The reflex agent The action a(t) is selected based on only the most recent percept x(t) No consideration of percept history. Can end up in infinite loops. The random agent The action a(t) is selected purely at random, without any consideration of the percept x(t) Not very intelligent.

  12. Simple Reflex Agent sensors What the world is like now Environment What action I should do now Condition - action rules effectors function SIMPLE-REFLEX-AGENT(percept) returns action static: rules, a set of condition-action rules state  INTERPRET-INPUT (percept) rule  RULE-MATCH (state,rules) action  RULE-ACTION [rule] returnaction First match. No further matches sought. Only one level of deduction. A simple reflex agent works by finding a rule whose condition matches the current situation (as defined by the percept) and then doing the action associated with that rule. Slide borrowed from Sandholm @ CMU

  13. Simple reflex agent… • Table lookup of condition-action pairs defining all possible condition-action rules necessary to interact in an environment • e.g. if car-in-front-is-breaking then initiate breaking • Problems • Table is still too big to generate and to store (e.g. taxi) • Takes long time to build the table • No knowledge of non-perceptual parts of the current state • Not adaptive to changes in the environment; requires entire table to be updated if changes occur • Looping: Can’t make actions conditional Slide borrowed from Sandholm @ CMU

  14. The goal based agent The action a(t) is selected based on the percept x(t), the current state q(t), and the future expected set of states. One or more of the states is the goal state. The model based agent The action a(t) is selected based on the percept x(t) and the current state q(t). The state q(t) keeps track of the past actions and the percept history.

  15. Reflex agent with internal state sensors State How the world evolves What the world is like now What my actions do Environment What action I should do now Condition - action rules effectors Model based agent Slide borrowed from Sandholm @ CMU

  16. sensors State How the world evolves What the world is like now What my actions do Environment What it will be like if I do action A What action I should do now Goals effectors Agent with explicit goals Goal based agent Slide borrowed from Sandholm @ CMU

  17. The learning agent The learning agent is similar to the utility based agent. The difference is that the knowledge parts can now adapt (i.e. The prediction of future states, the utility, ...etc.) The utility based agent The action a(t) is selected based on the percept x(t), and the utility of future, current, and past states q(t). The utility function U(q(t)) expresses the benefit the agent has from being in state q(t).

  18. sensors State How the world evolves What the world is like now What my actions do What it will be like if I do action A Environment How happy I will be in such as a state Utility What action I should do now effectors Utility-based agent Slide borrowed from Sandholm @ CMU

  19. Discussion Exercise 2.2: Both the performance measure and the utility function measure how well an agent is doing. Explain the difference between the two. They can be the same but do not have to be. The performance function is used externally to measure the agent’s performance. The utility function is used internally to measure (or estimate) the performance. There is always a performance function but not always an utility function.

  20. Discussion Exercise 2.2: Both the performance measure and the utility function measure how well an agent is doing. Explain the difference between the two. They can be the same but do not have to be. The performance function is used externally to measure the agent’s performance. The utility function is used internally (by the agent) to measure (or estimate) it’s performance. There is always a performance function but not always an utility function (cf. random agent).

  21. Exercise Exercise 2.4: Let’s examine the rationality of various vacuum-cleaner agent functions. • Show that the simple vacuum-cleaner agent function described in figure 2.3 is indeed rational under the assumptions listed on page 36. • Describe a rational agent function for the modified performance measure that deducts one point for each movement. Does the corresponding agent program require internal state? • Discuss possible agent designs for the cases in which clean squares can become dirty and the geography of the environment is unknown. Does it make sense for the agent to learn from its experience in these cases? If so, what should it learn?

  22. Exercise Exercise 2.4: Let’s examine the rationality of various vacuum-cleaner agent functions. • Show that the simple vacuum-cleaner agent function described in figure 2.3 is indeed rational under the assumptions listed on page 36. • Describe a rational agent function for the modified performance measure that deducts one point for each movement. Does the corresponding agent program require internal state? • Discuss possible agent designs for the cases in which clean squares can become dirty and the geography of the environment is unknown. Does it make sense for the agent to learn from its experience in these cases? If so, what should it learn?

  23. What should bethe performancemeasure?

  24. Table-driven agent function TABLE-DRIVEN-AGENT (percept) returns action static: percepts, a sequence, initially empty table, a table, indexed by percept sequences, initially fully specified append percept to the end of percepts action LOOKUP(percepts, table) return action An agent based on a pre-specified lookup table. It keeps track of percept sequence and just looks up the best action • Problems • Huge number of possible percepts (consider an automated taxi with a camera as the sensor) => lookup table would be huge • Takes long time to build the table • Not adaptive to changes in the environment; requires entire table to be updated if changes occur Slide borrowed from Sandholm @ CMU

  25. What should bethe performancemeasure?

  26. Possible states of the world: [A, Clean] & [B, Clean] [A, Clean] & [B, Dirty] [A, Dirty] & [B, Dirty] [A, Dirty] & [B, Clean] How long will it take for the agent to clean the world? Possible states of the world: [A, Clean] & [B, Clean]  world is clean after 0 steps [A, Clean] & [B, Dirty]  world is clean after 2 steps if agent is in A and... [A, Dirty] & [B, Dirty]  world is clean after 3 steps [A, Dirty] & [B, Clean]  world is clean after 1 step if agent is in A and... Can any agent do it faster (in fewer steps)?

  27. A B Exercise 2.4 • If (square A dirty & square B clean) then the world is clean after one step. No agent can do this quicker.If (square A clean & square B dirty) then the world is clean after two steps. No agent can do this quicker.If (square A dirty & square B dirty) then the world is clean after three steps. No agent can do this quicker.The agent is rational (elapsed time is our performance measure). Image borrowed from V. Pavlovic, Rutgers

  28. Exercise Exercise 2.4: Let’s examine the rationality of various vacuum-cleaner agent functions. • Show that the simple vacuum-cleaner agent function described in figure 2.3 is indeed rational under the assumptions listed on page 36. • Describe a rational agent function for the modified performance measure that deducts one point for each movement. Does the corresponding agent program require internal state? • Discuss possible agent designs for the cases in which clean squares can become dirty and the geography of the environment is unknown. Does it make sense for the agent to learn from its experience in these cases? If so, what should it learn?

  29. A B Exercise 2.4 • The reflex agent will continue moving even after the world is clean. An agent that has memory would do better than the reflex agent if there is a penalty for each move. Memory prevents the agent from visiting squares where it has already cleaned.(The environment has no production of dirt; a dirty square that has been cleaned remains clean.) Image borrowed from V. Pavlovic, Rutgers

  30. Exercise Exercise 2.4: Let’s examine the rationality of various vacuum-cleaner agent functions. • Show that the simple vacuum-cleaner agent function described in figure 2.3 is indeed rational under the assumptions listed on page 36. • Describe a rational agent function for the modified performance measure that deducts one point for each movement. Does the corresponding agent program require internal state? • Discuss possible agent designs for the cases in which clean squares can become dirty and the geography of the environment is unknown. Does it make sense for the agent to learn from its experience in these cases? If so, what should it learn?

  31. A B Exercise 2.4 • If the agent has a very long lifetime (infinite) then it is better to learn a map. The map can tell where the probability is high for dirt to accumulate. The map can carry information about how much time has passed since the vacuum cleaner agent visited a certain square, and thus also the probability that the square has become dirty.If the agent has a short lifetime, then it may just as well wander around randomly (there is no time to build a map). Image borrowed from V. Pavlovic, Rutgers

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