DOCSLIB.ORG

Conference Program

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Conference Program Program & Exhibit Guide AAAI 96 Thirteenth National Conference on Artificial Intelligence IAAI 96 Eighth Conference on Innovative Applications of Artificial Intelligence KDD 96 Second International Conference on Knowledge Discovery and Data Mining Sponsored by the American Association for Artificial Intelligence August 2-8, 1996 • Portland, Oregon IAAI-96 Contents Program Chair: Howard E. Shrobe, Mas- Acknowledgements / 2 sachusetts Institute of Technology AAAI-96 Invited Talks / 26 Program Cochair: Ted E. Senator, National As- AAAI-96 Technical Program / 32 sociation of Securities Dealers Conference at a Glance / 8 Corporate Sponsorship / 2 KDD-96 Exhibition / 38 General Conference Chair: Usama M. Fayyad, Fellows / 2 Microsoft Research General Information / 3 Program Cochairs: Jiawei Han, Simon Fraser IAAI-96 Program / 22 University and Evangelos Simoudis, IBM KDD-96 Program / 9 Almaden Research Center Robot Competition and Exhibition / 43 Publicity Chair: Padhraic Smyth, University of SIGART/AAAI Doctoral Consortium / 30 California, Irvine Special Events/Programs / 30 Sponsorship Chair: Gregory Piatetsky-Shapiro, Special Meetings / 31 GTE Laboratories Technical Program Tuesday / 32 Demo Session and Exhibits Chair: Tej Anand, Technical Program Wednesday / 34 NCR Corporation Technical Program Thursday / 36 A complete listing of the AAAI-96, IAAI-96 Tutorial Program / 20 and KDD-96 Program Committee members Workshop Program / 19 appears in the AAAI-96/IAAI-96 and KDD-96 Proceedings. Thanks to all! Acknowledgements The American Association for Artificial Intelli- Corporate Sponsorship gence wishes to acknowledge and thank the AAAI gratefully acknowledges the generous following individuals for their generous con- contribution of the following corporations tributions of time and energy to the successful and organizations to AAAI-96 and KDD-96: creation and planning of the Thirteenth Na- • General Motors Corporation tional Conference on Artificial Intelligence, the • Microsoft Corporation Eighth Conference on Innovative Applications • NASA/Jet Propulsion Laboratory of Artificial Intelligence, and the Second Inter- • NCR Corporation national Conference on Knowledge Discovery • Silicon Graphics, Inc. and Data Mining. • Sun Microsystems – Barbara Hayes-Roth, Conference Committee Chair, Stanford University AAAI-96 AAAI-96 Fellows Program Cochairs: William J. Clancey, Institute Each year the American Association for Ar- for Research on Learning and Daniel S. tificial Intelligence recognizes a small number Weld, University of Washington of members who have made significant sus- Associate Chair: Ramesh Patil, University of tained contributions to the field of artificial in- Southern California/Information Sciences telligence, and who have attained unusual dis- Institute tinction in the profession. AAAI is pleased to Robot Competition Chair: David Kortenkamp, announce the five newly elected Fellows for NASA Johnson Space Center 1996. (The Fellows Recognition Dinner will be Student Abstract Chair: Maja Mataric, Bran- held Monday, August 5 at 6:00 PM in the Pacific deis University Northwest Ballroom of the Red Lion Lloyd Tutorial Forum Chair: Brian C. Williams, Center.) NASA Ames Research Center Piero P. Bonissone, General Electric Corporation Workshop Chair: Subbarao Kambhampati, Dana S. Nau, University of Maryland Arizona State University Martha E. Pollack, University of Pittsburgh Volunteer Coordinator: Thomas G. Dietterich, Charles E. Thorpe, Carnegie Mellon University Oregon State University Contents / Acknowledgements Acknowledgements / Contents Beverly P. Woolf, University of Massachusetts SIGART/AAAI Doctoral Consortium Organizers: Vibhu O. Mittal, University of Pittsburgh and Loren G. Terveen, AT&T Research 2 SW 6th Avenue. The phone number is 503- General Information General Information 222-2665. Hours: Monday–Friday: 9:00 AM–5:30 PM; Saturday: 9:00 AM–1:00 PM; closed Sundays . AAAI Logo Shirts Major credit cards are accepted in hotels, most restaurants and department stores. Polo shirts with the AAAI logo will be for sale during registration hours in the registration area in Concourse A, main level of the Oregon Business Center Convention Center. Supplies are limited. Price: $20.00 each onsite. A Business Center is available at the Oregon Convention Center, located in the Martin Luther King Jr. Lobby. Hours are 8:00 AM–5:00 PM every Admission day during the AAAI-96/IAAI-96/KDD-96 con- ferences. Services include fax, copies, computer Each conference attendee will receive a name rental, laser printing, shipping by FedEx and badge upon registration. This badge is re- UPS, and other general office services. quired for admittance to the technical, tutori- al, exhibit, IAAI, KDD, robot and workshop programs. Tutorial and workshop attendees Career Information will also be checked off a master registration list at individual rooms. Smoking, drinking, A bulletin board for job opportunities in the and eating are not allowed in any of the tech- artificial intelligence industry will be made nical, tutorial, workshop, IAAI, KDD, robot or available in the registration area on the main exhibit sessions. level of the Oregon Convention Center. Atten- dees are welcome to post job descriptions of openings at their company or institution. Baggage Holding There is no baggage holding area at the Oregon Child Care Services Convention Center. Please check your luggage with the bellman at your hotel after you have Care Givers Placement Agency, Inc. offers re- checked out. Neither the AAAI nor the Oregon ferrals of screened childcare providers. These Convention Center accept liability for the loss providers can come to your hotel or take the or theft of any suitcase, briefcase, or other per- child(ren) off property to activities around sonal belongings brought to the site of AAAI- Portland. Please contact Care Givers Place- 96/IAAI-96/KDD-96. ment Agency, Inc. directly at 10211 SW Barbur Blvd, Suite 201A, Portland, OR 97219, phone: 503-244-6370, fax: 503-244-6856. Hours: 7:00 Banking AM–7:00 PM Sunday-Friday, 7:00 AM–5:00 PM Saturdays. Advance scheduling is preferred, The closest bank to the Oregon Convention but same-day temporary service is available. Center is the First Interstate Bank, located at Rates: Sitters are paid $6.75 per hour for 1-2 510 NE Broadway (cross street is Grand). Au- children and $1.00 extra per hour for each ad- tomatic Teller Machines (ATM) are available ditional child, plus parking expenses. A maxi- on the outside of the Oregon Convention Cen- mum of 4 children per caregiver is recom- ter next to the ticket offices. The ATM on the mended. Care Givers Placement Agency MLK Jr. Blvd side is operated by First Interstate charges a $10.00 fee per placement. This refer- Bank. The networks available are VISA, Amer- ral fee is billed to your credit card. ican Express Cash, Mastercard, Cirrus, Excel, (This information is for your convenience, and The Exchange, and Plus Systems. The ATM on does not represent an endorsement of Care the Holladay side is operated by UBank, and Givers Placement Agency, Inc. by AAAI.) the networks available are The Exchange, Star, Excel, Cirrus, VISA, Plus, Amex, Mastercard and Discovery Novus. Coffee Breaks For exchange of all major foreign curren- cies, please use Thomas Cook Agency, Pioneer Coffee will be served in Lobby B, main level of Courthouse Square, Powells Travel Store, 701 the Oregon Convention Center during KDD- 3 96; in Lobby A and B during workshop ses- Information Desk sions; in Lobby A and C during the Tutorial Forum; and outside the technical and invited An information desk/message desk will be talk rooms during AAAI-96/IAAI-96. staffed during registration hours, Friday through Thursday, August 2-8. It is located in the registration area, Concourse A, on the Copy Services main level of the Oregon Convention Center. Messages will be posted on the message boards A 24-hour Kinko’s is located on Martin Luther adjacent to the desk. The telephone number King Jr. Boulevard and Weidler. Copy service is for leaving messages only is 503-731-7981. also available at the Business Center in the Paging attendees is not possible. Oregon Convention Center. Internet Dining AAAI, in cooperation with Microsoft Corpora- A Portland dining guide is available in the reg- tion, will be providing internet access in Room istration area. The Visitor Information Center C121-122 on the main level of the Oregon in the MLK Jr. Lobby can provide further in- Convention Center. The internet room will be formation on Portland dining. Their hours are open during registration hours. As a courtesy, 10:00 AM–3:00 PM daily. Concessions will be please limit your access time to 5–10 minutes if open in Exhibition Hall B during exhibit others are waiting to use the service. hours. Food and coffee carts are located in the MLK Jr. Lobby and Holladay Lobby, street lev- el, which will be open during registration List of Attendees hours. A list of preregistered attendees of the confer- ence will be available for review at the AAAI Fax Machine Desk in the registration area, main level of the Oregon Convention Center. Attendee lists will Fax service is available at the Oregon Conven- not be distributed. tion Center Business Center, located in the MLK Jr. Lobby. Hours are 8:00 AM–5:00 PM ev- ery day during the AAAI-96/IAAI-96/KDD-96 Message Center conferences. See Information Desk. Handicapped Facilities General Information Parking The Oregon Convention Center, the Red Lion Lloyd Center, the Holiday Inn Portland Down- There is outdoor parking available at the Ore- town, the Best Western Inn at the Convention gon Convention Center. The daily rate is Center, the Best Western Rose Garden Hotel, $5.00/day. the Travelodge Hotel and the Vagabond Inn are all equipped with handicapped facilities. Press Housing All members of the media are requested to reg- ister in the Press Room on the main level of the For information regarding hotel reservations, Oregon Convention Center, Room A103. Press please contact the hotels directly. For student badges will only be issued to individuals with housing reservations assistance, please contact approved credentials.
Load more

Recommended publications
  • John Mccarthy – Father of Artificial Intelligence
    Asia Pacific Mathematics Newsletter John McCarthy – Father of Artificial Intelligence V Rajaraman Introduction I first met John McCarthy when he visited IIT, Kanpur, in 1968. During his visit he saw that our computer centre, which I was heading, had two batch processing second generation computers — an IBM 7044/1401 and an IBM 1620, both of them were being used for “production jobs”. IBM 1620 was used primarily to teach programming to all students of IIT and IBM 7044/1401 was used by research students and faculty besides a large number of guest users from several neighbouring universities and research laboratories. There was no interactive computer available for computer science and electrical engineering students to do hardware and software research. McCarthy was a great believer in the power of time-sharing computers. John McCarthy In fact one of his first important contributions was a memo he wrote in 1957 urging the Director of the MIT In this article we summarise the contributions of Computer Centre to modify the IBM 704 into a time- John McCarthy to Computer Science. Among his sharing machine [1]. He later persuaded Digital Equip- contributions are: suggesting that the best method ment Corporation (who made the first mini computers of using computers is in an interactive mode, a mode and the PDP series of computers) to design a mini in which computers become partners of users computer with a time-sharing operating system. enabling them to solve problems. This logically led to the idea of time-sharing of large computers by many users and computing becoming a utility — much like a power utility.
    [Show full text]
  • HUMAN-TYPE COMMON SENSE NEEDS EXTENSIONS to LOGIC John Mccarthy, Stanford University
    HUMAN-TYPE COMMON SENSE NEEDS EXTENSIONS TO LOGIC John McCarthy, Stanford University • Logical AI (artificial intelligence) is based on programs that represent facts about the world in languages of mathematical logic and decide what actions will achieve goals by logical rea- soning. A lot has been accomplished with logic as is. • This was Leibniz’s goal, and I think we’ll eventually achieve it. When he wrote Let us calculate, maybe he imagined that the AI prob- lem would be solved and not just that of a logical language for expressing common sense facts. We can have a language adequate for expressing common sense facts and reasoning before we have the ideas needed for human- level AI. 1 • It’s a disgrace that logicians have forgotten Leibniz’s goal, but there’s an excuse. Non- monotonic reasoning is needed for common sense, but it can yield conclusions that aren’t true in all models of the premises—just the preferred models. • Almost 50 years work has gone into logical AI and its rival, AI based on imitating neuro- physiology. Both have achieved some success, but neither is close to human-level intelligence. • The common sense informatic situation, in contrast to bounded informatic situations, is key to human-level AI. • First order languages will do, especially if a heavy duty axiomatic set theory is included, e.g. A × B, AB, list operations, and recur- sive definition are directly included. To make reasoning as concise as human informal set- theoretic reasoning, many theorems of set the- ory need to be taken as axioms.
    [Show full text]
  • Cyc: a Midterm Report
    AI Magazine Volume 11 Number 3 (1990) (© AAAI) Articles The majority of work After explicating the need for a large common- We have come a in knowledge repre- sense knowledge base spanning human consen- long way in this . an sentation has dealt sus knowledge, we report on many of the lessons time, and this article aversion to with the technicali- learned over the first five years of attempting its presents some of the ties of relating predi- construction. We have come a long way in terms lessons learned and a addressing cate calculus to of methodology, representation language, tech- description of where the problems niques for efficient inferencing, the ontology of other formalisms we are and briefly the knowledge base, and the environment and that arise in and with the details infrastructure in which the knowledge base is discusses our plans of various schemes being built. We describe the evolution of Cyc for the coming five actually for default reason- and its current state and close with a look at our years. We chose to representing ing. There has almost plans and expectations for the coming five years, focus on technical been an aversion to including an argument for how and why the issues in representa- large bodies addressing the prob- project might conclude at the end of this time. tion, inference, and of knowledge lems that arise in ontology rather than actually represent- infrastructure issues with content. ing large bodies of knowledge with content. such as user interfaces, the training of knowl- However, deep, important issues must be edge enterers, or existing collaborations and addressed if we are to ever have a large intelli- applications of Cyc.
    [Show full text]
  • Some Alternative Formulations of the Event Calculus
    In: "Computational Logic: Logic Programming and Beyond - Essays in Honour of Robert A. Kowalski", Lecture Notes in Artificial Intelligence, Vol. 2408, pub. Springer Verlag, 2002, pages 452–490. Some Alternative Formulations of the Event Calculus Rob Miller1 and Murray Shanahan2 1 University College London, London WC1E 6BT, U.K. [email protected] http://www.ucl.ac.uk/~uczcrsm/ 2 Imperial College of Science, Technology and Medicine, London SW7 2BT, U.K. [email protected] http://www-ics.ee.ic.ac.uk/~mpsha/ Abstract. The Event Calculus is a narrative based formalism for rea- soning about actions and change originally proposed in logic program- ming form by Kowalski and Sergot. In this paper we summarise how variants of the Event Calculus may be expressed as classical logic ax- iomatisations, and how under certain circumstances these theories may be reformulated as “action description language” domain descriptions using the Language . This enables the classical logic Event Calculus to E inherit various provably correct automated reasoning procedures recently developed for . E 1 Introduction The “Event Calculus” was originally introduced by Bob Kowalski and Marek Ser- got [33] as a logic programming framework for representing and reasoning about actions (or events) and their effects, especially in database applications. Since then many alternative formulations, implementations and applications have been developed. The Event Calculus has been reformulated in various logic program- ming forms (e.g. [11], [12], [21], [23], [29], [53], [58], [71], [72], [73],[74]), in classical logic (e.g. [62], [42], [43]), in modal logic (e.g. [2], [3], [4], [5], [6], [7]) and as an “action description language” ([21], [22]).
    [Show full text]
  • Applications of Circumscription to Formalizing Common Sense Knowledge
    APPLICATIONS OF CIRCUMSCRIPTION TO FORMALIZING COMMON SENSE KNOWLEDGE John McCarthy Computer Science Department Stanford University Stanford, CA 94305 [email protected] http://www-formal.stanford.edu/jmc/ 1986 Abstract We present a new and more symmetric version of the circumscrip- tion method of nonmonotonic reasoning first described in (McCarthy 1980) and some applications to formalizing common sense knowledge. The applications in this paper are mostly based on minimizing the abnormality of different aspects of various entities. Included are non- monotonic treatments of is-a hierarchies, the unique names hypothe- sis, and the frame problem. The new circumscription may be called formula circumscription to distinguish it from the previously defined domain circumscription and predicate circumscription. A still more general formalism called prioritized circumscription is briefly explored. 1 INTRODUCTION AND NEW DEFINITION OF CIRCUMSCRIPTION (McCarthy 1980) introduces the circumscription method of nonmonotonic reasoning and gives motivation, some mathematical properties and some ex- 1 amples of its application. The present paper is logically self-contained, but motivation may be enhanced by reading the earlier paper. We don't repeat its arguments about the importance of nonmonotonic reasoning in AI, and its examples are instructive. Here we give a more symmetric definition of circumscription and appli- cations to the formal expression of common sense facts. Our long term goal (far from realized in the present paper) is to express these facts in a way that would be suitable for inclusion in a general purpose database of com- mon sense knowledge. We imagine this database to be used by AI programs written after the initial preparation of the database.
    [Show full text]
  • The Frame Problem, Then and Now
    The Frame Problem, Then and Now Vladimir Lifschitz University of Texas at Austin My collaboration with John McCarthy started in 1984. He was interested then in what he called the commonsense law of inertia. That idea is related to actions, such as moving an object to a different location, or, for instance, toggling a light switch. According to this law, whatever we know about the state of affairs before executing an action can be presumed, by default, to hold after the action as well. Formalizing this default would resolve the difficulty known in AI as the frame problem. Reasoning with defaults is nonmonotonic. John proposed a solution to the frame problem based on the method of nonmonotonic reasoning that he called circumscription [1]. And then something unpleasant happened. Two researchers from Yale University discovered that John's proposed solution was incorrect [2]. Their counterexample involved the actions of loading a gun and shooting, and it became known as the \Yale Shooting Scenario." Twenty years later their paper received the AAAI Classic Paper Award [3]. But that was not all. Automated reasoning is notoriously difficult, and the presence of defaults adds yet another level of complexity. Even assuming that the problem with Yale Shooting is resolved, was there any hope, one could ask, that the commonsense law of inertia would ever become part of usable software? So John's proposal seemed unsound and non-implementable. It also seemed unnecessary, because other researchers have proposed approaches to the frame problem that did not require nonmonotonic reasoning [4, 5, 6]. There were all indications that his project just wouldn't fly.
    [Show full text]
  • The Event Calculus Explained Murray Shanahan
    The Event Calculus Explained Murray Shanahan Department of Electrical and Electronic Engineering, Imperial College, Exhibition Road, London SW7 2BT, England. Email: [email protected] Abstract This article presents the event calculus, a logic-based formalism for representing actions and their effects. A circumscriptive solution to the frame problem is deployed which reduces to monotonic predicate completion. Using a number of benchmark examples from the literature, the formalism is shown to apply to a variety of domains, including those featuring actions with indirect effects, actions with non-deterministic effects, concurrent actions, and continuous change. Introduction Central to many complex computer programs that take decisions about how they or other agents should act is some form of representation of the effects of actions, both their own and those of other agents. To the extent that the design of such programs is to be based on sound engineering principles, rather than ad hoc methods, it’s vital that the subject of how actions and their effects are represented has a solid theoretical basis. Hence the need for logical formalisms for representing action, which, although they may or may not be realised directly in computer programs, nevertheless offer a theoretical yardstick against which any actually deployed system of representation can be measured. This article presents one such formalism, namely the event calculus. There are many others, the most prominent of which is probably the situation calculus [McCarthy & Hayes, 1969], and the variant of the event calculus presented here should be thought of as just one point in a space of possible action formalisms which the community has yet to fully understand.
    [Show full text]
  • 1956 and the Origins of Artificial Intelligence Computing
    Building the Second Mind: 1956 and the Origins of Artificial Intelligence Computing Rebecca E. Skinner copyright 2012 by Rebecca E. Skinner ISBN 978-0-9894543-1-5 Building the Second Mind: 1956 and the Origins of Artificial Intelligence Computing Chapter .5. Preface Chapter 1. Introduction Chapter 2. The Ether of Ideas in the Thirties and the War Years Chapter 3. The New World and the New Generation in the Forties Chapter 4. The Practice of Physical Automata Chapter 5. Von Neumann, Turing, and Abstract Automata Chapter 6. Chess, Checkers, and Games Chapter 7. The Impasse at End of Cybernetic Interlude Chapter 8. Newell, Shaw, and Simon at the Rand Corporation Chapter 9. The Declaration of AI at the Dartmouth Conference Chapter 10. The Inexorable Path of Newell and Simon Chapter 11. McCarthy and Minsky begin Research at MIT Chapter 12. AI’s Detractors Before its Time Chapter 13. Conclusion: Another Pregnant Pause Chapter 14. Acknowledgements Chapter 15. Bibliography Chapter 16. Endnotes Chapter .5. Preface Introduction Building the Second Mind: 1956 and the Origins of Artificial Intelligence Computing is a history of the origins of AI. AI, the field that seeks to do things that would be considered intelligent if a human being did them, is a universal of human thought, developed over centuries. Various efforts to carry this out appear- in the forms of robotic machinery and more abstract tools and systems of symbols intended to artificially contrive knowledge. The latter sounds like alchemy, and in a sense it certainly is. There is no gold more precious than knowledge. That this is a constant historical dream, deeply rooted in the human experience, is not in doubt.
    [Show full text]
  • On John Mccarthy's 80Th Birthday, in Honor Of
    On John McCarthy’s 80th Birthday, in Honor of his Contributions Patrick J. Hayes and Leora Morgenstern Abstract John McCarthy’s contributions to computer science and artificial intelligence are legendary. He invented Lisp, made substantial contributions to early work in timesharing and the theory of computation, and was one of the founders of artificial intelligence and knowl- edge representation. This article, written in honor of McCarthy’s 80th birthday, presents a brief biography, an overview of the major themes of his research, and a discussion of several of his major papers. Introduction Fifty years ago, John McCarthy embarked on a bold and unique plan to achieve human-level intelligence in computers. It was not his dream of an intelligent com- puter that was unique, or even first: Alan Turing (Tur- ing 1950) had envisioned a computer that could con- verse intelligently with humans back in 1950; by the mid 1950s, there were several researchers (including Herbert Simon, Allen Newell, Oliver Selfridge, and Marvin Min- sky) dabbling in what would be called artificial intelli- gence. What distinguished McCarthy’s plan was his emphasis on using mathematical logic both as a lan- guage for representing the knowledge that an intelligent machine should have, and as a means for reasoning with that knowledge. This emphasis on mathematical logic was to lead to the development of the logicist approach to artificial intelligence, as well as to the development of the computer language Lisp. John McCarthy’s contributions to computer science and artificial intelligence are legendary. He revolution- ized the use of computers with his innovations in time- sharing; he invented Lisp, one of the longest-lived com- puter languages in use; he made substantial contribu- tions to early work in the mathematical theory of com- putation; he was one of the founders of the field of artifi- cial intelligence; and he foresaw the need for knowledge Figure 1: John McCarthy representation before the field of AI was even properly born.
    [Show full text]
  • Rigor Mortis: a Response to Nilsson's "Logic and Artificial Intelligence"
    Artificial Intelligence 47 (199l) 57-77 57 Elsevier Rigor mortis: a response to Nilsson's "Logic and artificial intelligence" Lawrence Birnbaum The Institute for the Learning Sciences and Department of Electrical Engineering and Computer Science, Northwestern University, Evanston, 1L 60201, USA Received June 1988 Revised December 1989 Abstract Birnbaum, L., Rigor mortis: a response to Nilsson's "Logic and artificial intelligence", Artificial Intelligence 47 (1991) 57-77. Logicism has contributed greatly to progress in AI by emphasizing the central role of mental content and representational vocabulary in intelligent systems. Unfortunately, the logicists' dream of a completely use-independent characterization of knowledge has drawn their attention away from these fundamental AI problems, leading instead to a concentration on purely formalistic issues in deductive inference and model-theoretic "semantics". In addi- tion, their failure to resist the lure of formalistic modes of expression has unnecessarily curtailed the prospects for intellectual interaction with other AI researchers. 1. Introduction A good friend recently told me about a discussion he had with one of his colleagues about what to teach in a one-semester introductory artificial intellig- ence course for graduate students, given the rather limited time available in such a course. He proposed what he assumed were generally agreed to be central issues and techniques in AI--credit assignment in learning, means-ends analysis in problem-solving, the representation and use of abstract planning knowledge in the form of critics, and so on. Somewhat to his surprise, in his colleague's view one of the most important things for budding AI scientists to learn was..
    [Show full text]
  • Reasoning, Nonmonotonic Logics, and the Frame Problem
    From: AAAI-86 Proceedings. Copyright ©1986, AAAI (www.aaai.org). All rights reserved. Default geasoning, Nonmonotonic Logics, and the Frame Problem Steve Hanks and Drew McDermott’ Department of Computer Science, Yale University Box 2158 Yale Station New Haven, CT 06520 Abstract we must jump to the conclusion that an observed situation or object ia typical. For example, I may know that I typically meet with my Nonmonotonic formal systems have been proposed as an exten- advisor on Thursday afternoons, but I can’t deduce that I will ac- sion to classical first-order logic that will capture the process of hu- tually have a meeting nezt Thursday because I don’t know whether man “default reasoning” or “plausible inference” through their infer- next Thursday is typical. While certain facts may allow me to de- ence mechanisms just as modus ponena provides a model for deduc- duce that next Thursday is not typical (e.g. if I learn he will be out tive reasoning. But although the technical properties of these logics of town all next week), in general there will be no way for me to have been studied in detail and many examples of human default deduce that it ia. What we want to do in cases like this is to jump to reasoning have been identified, for the most part these logics have the conclusion that next Thursday is typical based on two pieces of not actually been applied to practical problems to see whether they information: first that most Thursdays are typical, and second that produce the expected results.
    [Show full text]
  • Foundational Issues in Artificial Intelligence and Cognitive Science Impasse and Solution
    FOUNDATIONAL ISSUES IN ARTIFICIAL INTELLIGENCE AND COGNITIVE SCIENCE IMPASSE AND SOLUTION Mark H. Bickhard Lehigh University Loren Terveen AT&T Bell Laboratories forthcoming, 1995 Elsevier Science Publishers Contents Preface xi Introduction 1 A PREVIEW 2 I GENERAL CRITIQUE 5 1 Programmatic Arguments 7 CRITIQUES AND QUALIFICATIONS 8 DIAGNOSES AND SOLUTIONS 8 IN-PRINCIPLE ARGUMENTS 9 2 The Problem of Representation 11 ENCODINGISM 11 Circularity 12 Incoherence — The Fundamental Flaw 13 A First Rejoinder 15 The Necessity of an Interpreter 17 3 Consequences of Encodingism 19 LOGICAL CONSEQUENCES 19 Skepticism 19 Idealism 20 Circular Microgenesis 20 Incoherence Again 20 Emergence 21 4 Responses to the Problems of Encodings 25 FALSE SOLUTIONS 25 Innatism 25 Methodological Solipsism 26 Direct Reference 27 External Observer Semantics 27 Internal Observer Semantics 28 Observer Idealism 29 Simulation Observer Idealism 30 vi SEDUCTIONS 31 Transduction 31 Correspondence as Encoding: Confusing Factual and Epistemic Correspondence 32 5 Current Criticisms of AI and Cognitive Science 35 AN APORIA 35 Empty Symbols 35 ENCOUNTERS WITH THE ISSUES 36 Searle 36 Gibson 40 Piaget 40 Maturana and Varela 42 Dreyfus 42 Hermeneutics 44 6 General Consequences of the Encodingism Impasse 47 REPRESENTATION 47 LEARNING 47 THE MENTAL 51 WHY ENCODINGISM? 51 II INTERACTIVISM: AN ALTERNATIVE TO ENCODINGISM 53 7 The Interactive Model 55 BASIC EPISTEMOLOGY 56 Representation as Function 56 Epistemic Contact: Interactive Differentiation and Implicit Definition 60 Representational
    [Show full text]