1 / 27

Automated Negotiation

Automated Negotiation Lecture 1: Introduction and Background Knowledge Introduction: Motivation Agents search & make contracts -- Through peer-to-peer negotiation or a mediated marketplace . -- Agents can be real-world parties or software agents that work on behalf of real-world parties .

niveditha
Download Presentation

Automated Negotiation

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Automated Negotiation Lecture 1: Introduction and Background Knowledge

  2. Introduction: Motivation • Agents search & make contracts-- Through peer-to-peer negotiation or a mediated marketplace.-- Agents can be real-world parties or software agents that work on behalf of real-world parties. • Increasingly important from a practical perspective-- Developing communication infrastructure (Internet, WWW, NII, EDI, KQML, FIPA, Concordia, Voyager, Odyssey, Aglets, AgentTCL, Java Applets, ...)-- Electronic commerce on the Internet: Goods, services,information, bandwidth, computation, storage...-- Industrial trend toward virtual enterprises & outsourcing-- Automated negotiation allows dynamically formed alliances on a per order basis in order to capitalize on economies of scale, and allow the parties to stay separate when there are diseconomies of scale

  3. Introduction: Motivation • Fertile, timely research area-- Deep theories from game-theory & CS merge.Started together in the 1940’s [Morgenstern & von Neumann].There were a few decades of little interplay.Upswing of interplay in the last few years.-- The intersection is a very fruitful, relatively open research area. • It is in this setting that the prescriptive power of game theory really comes into play.-- Market rules need to be explicitly specified-- Software agents designed so as to act optimally-- Computational capabilities can be quantitativelycharacterized, and prescriptions can be made about how the agents should use their computation optimally

  4. System with Self-Interested Agents • Includes computational or human agents • Mechanism (e.g., rules of an auction) specifies legal actions for each agent & how the outcome is determined as a function of the agents’ strategies • Strategy (e.g., bidding strategy), Agent’s mapping from known history to action • Rational self-interested agent chooses its strategy to maximize its own expected utility given the mechanism-- strategic analysisrequired for robustness -- noncooperative game theory

  5. System with Self-Interested Agents • Computational ComplexityIn executing the mechanism In determining the optimal strategyIn executing the optimal strategy • Has significant impact on prescriptions.Has received little attention in game theory.

  6. Ecommerce Process • 1. Interest generation • 2. Finding • 3. Negotiating • 4. Contract execution • 5. After sales

  7. MAS in Different EC Stages • 1. Interest generation-- Funded adlets that coordinate-- Avatars for choosing which ads to read-- Customer models for choosing who to send ads and how much $ to offer • 2. Finding-- Simple current systems: BargainFinder, Jango-- Meta-data, XML-- Standardized feature lists on goods to allow comparison-- How do these get (re)negotiatedDifferent vendors prefer different feature listsShopper agents need to understand the new listsHow do algorithms cope with new features?-- Want to get a bundle: need to find many vendors

  8. MAS in Different EC Stages • 3. Negotiating-- Advantages of dynamic pricing: Right things sold to (and bought from) right parties at right time. So, world becomes a better place (social welfare increases)-- Further advantages from discriminatory pricing: Can increase social welfare.-- Fixed-menu take-it-or-leave-it offers -> negotiationCost of generating & disseminating catalogs?Other customers see the price?Negotiation overhead?Personalized menus (check customer’s web page, links to & from it, what other similar customers did, customer profiles)Generating/printing the menu may be intractable,Negotiation will focus the generation, but vendor may bias prices & offerings based on path-- Preferences over bundles-- Coalition formation

  9. MAS in Different EC Stages • 4. Contract execution-- Digital payment schemes-- Safe exchange • 5. After sales

  10. Outline • Utility----Quantification of Decision Result • Game Theory----Modelling of Decision

  11. Quantification • Reason:Some concepts, like ‘Good’, ‘Bad’ is hard to comprehend by computer. • Method:Use real numbers (utility) to instead.

  12. Decision Making S: a set on environment states D: a set of possible decisions R: a set of achievable results Result is influenced by both decision and environment state.

  13. Decision Making • M: S x D ----> R • R = M (s, d), s∈S, d∈D

  14. Decision Making • ∵Environment state is usually uncertain.∴For each s∈S there is a probability of occurrence of s.∴With the mapping M this distribution for each d ∈ D induces a distribution on R.∴So making the best decision mean choosing the "best" distribution on R among those available.

  15. Decision Making • Example: A Picnic DecisionD={I, O}I: Picnic IndoorO: Picnic Outdoor S={T, C}T: Thunderstorm Weather Forecast: P(T)=0.3C: Clear P(C)=0.7R={A, B, G, E}A: AwfulB: BadG: GoodE: Excellent

  16. Decision Making • Example: A Picnic DecisionDefinition of M:M(T, O) = AM(T, I) = BM(C, I) = GM(C, O) = E

  17. Decision Making • Example: A Picnic DecisionFor Indoor: 30% Bad 70% GoodFor Outdoor: 30% Awful 70% Excellent

  18. Decision Making • Utility Function & Expected UtilityUtility Function: U(ri), ri∈Re.g.:U(A)=0, U(B)=2, U(G)=5, U(E)=10Expected Utility: u(d), d∈Du(d) = ∑ P(ri) * U(ri)

  19. Decision Making • Example:u(I) = 0.3 * 2 + 0.7 * 5 = 4.1u(O) = 0.7 * 10 = 7

  20. Game Theory • Problem: In a game, players will get different outcomes by using different strategies. What strategies should they choose for improving their outcomes?

  21. Play1 A B A B Play2 Play1’s Income Play2’s Income Game Theory • Matrix Form:

  22. Game Theory • Extensive Form: Play 1 A B Play 2 A B A B 3, 3 0, 5 5, 0 1, 1

  23. Game Theory • Dominant Strategy:In some games, a player can choose a strategy that "dominates" all other strategies in his strategy set: Regardless of what he expects his opponents to do, this strategy always yields a better payoff than any other of his strategies.

  24. Game Theory • Dominant Strategy Equilibrium:It is a strategy profile where each agent has picked its dominant strategy.

  25. Play1 A B A B Play2 Play1’s Income Play2’s Income Nash Equilibrium Point Game Theory • Nash Equilibrium:No players can increase their utility by changing their strategies.

  26. Game Theory • Criticisms of Nash Equilibrium-Not unique in all games.-Does not exist in all games.-May be hard to compute.

  27. Game Theory • Existence of Nash EquilibriumAny finite gamewhere each action node is alone in its information set, i.e. at every point in the game, the agent whose turn it is to move knows what moves have been played so far. And the game is dominance solvable by backward induction.

More Related