cortex: org/ai-journal-review.org annotate

annotate org/ai-journal-review.org @ 545:b2c66ea58c39

changes from athena.

author	Robert McIntyre <rlm@mit.edu>
date	Mon, 28 Apr 2014 12:59:08 -0400
parents	ff0d8955711e
children	ebdedb039cbb

rev	line source
rlm@381	1 #+title:Interesting Papers in Artificial Intelligence
rlm@381	2
rlm@383	3 I decided to read all of the /titles/ in the Artificial Intelligence
rlm@384	4 journal, and found these interesting papers. The entire title-reading
rlm@384	5 process took about 2 hours.
rlm@383	6
rlm@381	7 * Interesting Concept
rlm@381	8
rlm@384	9 - (2002) Jordi Delgado - Emergence of social conventions in complex networks
rlm@384	10
rlm@384	11 Here, "social conventions" means a very specific property of graphs
rlm@384	12 in the context of game theory. Their social networks are groups of
rlm@384	13 mindless automotaons which each have a single opinion that can take
rlm@384	14 the values "A" or "B". They use the "coordination game" payoff
rlm@384	15 matrix that engourages each pair of agents to agree with each other,
rlm@384	16 and study various ways the graph can come to 90% of the agents all
rlm@384	17 believe either "A" or "B". It's probably not useful for actual
rlm@384	18 social worlds, and there's no simulation of any interesting
rlm@384	19 environment, but it might be useful for designing protocols, or as a
rlm@384	20 problem solving method.
rlm@384	21
rlm@384	22 References:
rlm@384	23 + L.A. Nunes Amaral, A. Scala, M. Barthélémy, H.E. Stanley, Classes
rlm@384	24 of small-world networks, Proc. Nat. Acad. Sci. 97 (2000)
rlm@384	25 11149–11152.
rlm@384	26 + D.J Watts, S.H. Strogatz, Collective dynamics of small-world
rlm@384	27 networks, Nature 393 (1998) 440–442.
rlm@384	28 + Y. Shoham, M. Tennenholtz, On the emergence of social conventions:
rlm@384	29 Modeling, analysis and simulations, Artificial Intelligence 94
rlm@384	30 (1997) 139–166.
rlm@384	31
rlm@384	32 - (1997) Yoav Shoham, Moshe Tennenholtz - On the emergence of social
rlm@384	33 conventions: modeling, analysis, and simulations
rlm@384	34
rlm@381	35
rlm@381	36 Marcelo A. Falappa, Gabriele Kern-Isberner, Guillermo R. Simari -
rlm@381	37 Explanations, belief revision and defeasible reasoning
rlm@381	38
rlm@381	39 Claudio Bettini, X.Sean Wang, Sushil Jajodia - Solving
rlm@381	40 multi-granularity temporal constraint networks
rlm@381	41
rlm@381	42 Alberto Maria Segre, Sean Forman, Giovanni Resta, Andrew Wildenberg -
rlm@381	43 Nagging: A scalable fault-tolerant paradigm for distributed search
rlm@381	44
rlm@381	45 Fahiem Bacchus, Xinguang Chen, Peter van Beek, Toby Walsh - Binary
rlm@381	46 vs. non-binary constraints
rlm@381	47
rlm@381	48 Jie Cheng, Russell Greiner, Jonathan Kelly, David Bell, Weiru Liu -
rlm@381	49 Learning Bayesian networks from data: An information-theory based
rlm@381	50 approach
rlm@381	51
rlm@381	52 Kurt Engesser, Dov M. Gabbay - Quantum logic, Hilbert space, revision
rlm@381	53 theory
rlm@381	54
rlm@381	55 J.-D. Fouks, L. Signac - The problem of survival from an algorithmic
rlm@381	56 point of view
rlm@381	57
rlm@381	58 Catherine Carr - The MIT Encyclopedia of the Cognitive Sciences,
rlm@381	59 edited by Robert Wilson and Frank Keil
rlm@381	60
rlm@386	61 - Tim Taylor - Christoph Adami, Introduction to Artificial Life
rlm@386	62 References:
rlm@386	63 + M.A. Boden (Ed.), The Philosophy of Artificial Life, Oxford
rlm@386	64 University Press, Oxford, 1996.
rlm@386	65 + C.G. Langton (Ed.), Artificial Life: An Introduction, MIT Press,
rlm@386	66 Cambridge, MA, 1995.
rlm@381	67
rlm@381	68 A.S d'Avila Garcez, K Broda, D.M Gabbay - Symbolic knowledge
rlm@381	69 extraction from trained neural networks: A sound approach
rlm@381	70
rlm@381	71 José Hernández-Orallo - Truth from Trash. How Learning Makes Sense by
rlm@381	72 Chris Thornton
rlm@381	73
rlm@381	74 Fabio G. Cozman - Credal networks
rlm@381	75
rlm@381	76 Aaron N. Kaplan, Lenhart K. Schubert - A computational model of belief
rlm@381	77
rlm@381	78 Mike Perkowitz, Oren Etzioni - Towards adaptive Web sites: Conceptual
rlm@381	79 framework and case study
rlm@381	80
rlm@381	81 Wilhelm Rödder - Conditional logic and the Principle of Entropy
rlm@381	82
rlm@381	83 Christian Vilhelm, Pierre Ravaux, Daniel Calvelo, Alexandre Jaborska,
rlm@381	84 Marie-Christine Chambrin, Michel Boniface - Think!: A unified
rlm@381	85 numerical–symbolic knowledge representation scheme and reasoning
rlm@381	86 system
rlm@381	87
rlm@381	88 Charles L. Ortiz Jr. - A commonsense language for reasoning about
rlm@381	89 causation and rational action
rlm@381	90
rlm@381	91 Raúl E. Valdés-Pérez - Principles of human—computer collaboration for
rlm@381	92 knowledge discovery in science
rlm@381	93
rlm@381	94 Paul Snow - The vulnerability of the transferable belief model to
rlm@381	95 Dutch books
rlm@381	96
rlm@384	97 Simon Kasif, Steven Salzberg, David Waltz, John Rachlin, David
rlm@384	98 W. Aha - A probabilistic framework for memory-based reasoning
rlm@381	99
rlm@381	100 Geoffrey LaForte, Patrick J. Hayes, Kenneth M. Ford - Why Gödel's
rlm@381	101 theorem cannot refute computationalism
rlm@381	102
rlm@381	103 Hiroshi Motoda, Kenichi Yoshida - Machine learning techniques to make
rlm@381	104 computers easier to use
rlm@381	105
rlm@381	106 Aravind K. Joshi - Role of constrained computational systems in
rlm@381	107 natural language processing
rlm@381	108
rlm@381	109 Moshe Tennenholtz - On stable social laws and qualitative equilibria
rlm@381	110
rlm@381	111 Michael Arbib - The metaphorical brains
rlm@381	112
rlm@381	113 Andrew Gelsey, Mark Schwabacher, Don Smith - Using modeling knowledge
rlm@381	114 to guide design space search
rlm@381	115
rlm@381	116 Márk Jelasity, József Dombi - GAS, a concept on modeling species in
rlm@381	117 genetic algorithms
rlm@381	118
rlm@381	119 Randall H. Wilson - Geometric reasoning about assembly tools
rlm@381	120
rlm@381	121 Kurt Ammon - An automatic proof of Gödel's incompleteness theorem
rlm@381	122
rlm@381	123 Shmuel Onn, Moshe Tennenholtz - Determination of social laws for
rlm@381	124 multi-agent mobilization
rlm@381	125
rlm@381	126 Stuart J. Russell - Rationality and intelligence
rlm@381	127
rlm@381	128 Hidde de Jong, Arie Rip - The computer revolution in science: steps
rlm@381	129 towards the realization of computer-supported discovery environments
rlm@381	130
rlm@381	131 Adnan Darwiche, Judea Pearl - On the logic of iterated belief revision
rlm@381	132
rlm@381	133 R.C. Holte, T. Mkadmi, R.M. Zimmer, A.J. MacDonald - Speeding up
rlm@381	134 problem solving by abstraction: a graph oriented approach
rlm@381	135
rlm@381	136 R. Holte, T. Mkadmi, R.M. Zimmer, A.J. McDonald - Speeding up problem
rlm@381	137 solving by abstraction: a graph oriented approach
rlm@381	138
rlm@381	139 Raúl E. Valdés-Pérez - A new theorem in particle physics enabled by
rlm@381	140 machine discovery
rlm@381	141
rlm@381	142 Dan Roth - On the hardness of approximate reasoning
rlm@381	143
rlm@381	144 Bart Selman, David G. Mitchell, Hector J. Levesque - Generating hard
rlm@381	145 satisfiability problems
rlm@381	146
rlm@381	147 Herbert A. Simon - Artificial intelligence: an empirical science
rlm@381	148
rlm@381	149 John K. Tsotsos - Behaviorist intelligence and the scaling problem
rlm@381	150
rlm@381	151 Shigeki Goto, Hisao Nojima - Equilibrium analysis of the distribution
rlm@381	152 of information in human society
rlm@381	153
rlm@381	154 Raúl E. Valdés-Pérez - Machine discovery in chemistry: new results
rlm@381	155
rlm@381	156 Stephen W. Smoliar - Artificial life: Christopher G. Langton, ed.
rlm@381	157
rlm@381	158 Yoav Shoham, Moshe Tennenholtz - On social laws for artificial agent
rlm@381	159 societies: off-line design
rlm@381	160
rlm@381	161 Barbara Hayes-Roth - An architecture for adaptive intelligent systems
rlm@381	162
rlm@381	163 Bruce Randall Donald - On information invariants in robotics
rlm@381	164
rlm@381	165 Ian P. Gent, Toby Walsh - Easy problems are sometimes hard
rlm@381	166
rlm@381	167 Tad Hogg, Colin P. Williams - The hardest constraint problems: A
rlm@381	168 double phase transition
rlm@381	169
rlm@381	170 Yoram Moses, Yoav Shoham - Belief as defeasible knowledge
rlm@381	171
rlm@381	172 Donald Michie - Turing's test and conscious thought
rlm@381	173
rlm@381	174 John McDermott - R1 (“XCON”) at age 12: lessons from an elementary
rlm@381	175 school achiever
rlm@381	176
rlm@381	177 Takeo Kanade - From a real chair to a negative chair
rlm@381	178
rlm@381	179 Harry G. Barrow, J.M. Tenenbaum - Retrospective on “Interpreting line
rlm@381	180 drawings as three-dimensional surfaces”
rlm@381	181
rlm@381	182 Judea Pearl - Belief networks revisited
rlm@381	183
rlm@381	184 Glenn A. Kramer - A geometric constraint engine
rlm@381	185
rlm@381	186 Fausto Giunchiglia, Toby Walsh - A theory of abstraction
rlm@381	187
rlm@381	188 John L. Pollock - How to reason defeasibly
rlm@381	189
rlm@381	190 Aaron Sloman - The emperor's real mind: Review of Roger Penrose's the
rlm@381	191 emperor's new mind: Concerning computers, minds and the laws of
rlm@381	192 physics
rlm@381	193
rlm@381	194 Olivier Dordan - Mathematical problems arising in qualitative
rlm@381	195 simulation of a differential equation
rlm@381	196
rlm@381	197 Eric Saund - Putting knowledge into a visual shape representation
rlm@381	198
rlm@381	199 Michael Freund, Daniel Lehmann, Paul Morris - Rationality,
rlm@381	200 transitivity, and contraposition
rlm@381	201
rlm@381	202 Anthony S. Maida - Maintaining mental models of agents who have
rlm@381	203 existential misconceptions
rlm@381	204
rlm@381	205 Henry A. Kautz, Bart Selman - Hard problems for simple default logics
rlm@381	206
rlm@381	207 Mark J. Stefik, Stephen Smoliar - Four reviews of The Society of Mind
rlm@381	208 and a response
rlm@381	209
rlm@381	210 Michael G. Dyer - A society of ideas on cognition: Review of Marvin
rlm@381	211 Minsky's The Society of Mind
rlm@381	212
rlm@381	213 Matthew Ginsberg - The society of mind: Marvin Minsky
rlm@381	214
rlm@381	215 George N. Reeke Jr - The society of mind: Marvin Minsky
rlm@381	216
rlm@381	217 Stephen W. Smoliar - The society of mind: Marvin Minsky
rlm@381	218
rlm@381	219 Marvin Minsky - Society of mind: A response to four reviews
rlm@381	220
rlm@381	221 Stephen W. Smoliar - How to build a person: A prolegomenon: John
rlm@381	222 Pollock
rlm@381	223
rlm@381	224 David Makinson, Karl Schlechta - Floating conclusions and zombie
rlm@381	225 paths: Two deep difficulties in the “directly skeptical” approach to
rlm@381	226 defeasible inheritance nets
rlm@381	227
rlm@381	228 Donald A. Norman - Approaches to the study of intelligence
rlm@381	229
rlm@381	230 Rodney A. Brooks - Intelligence without representation
rlm@381	231
rlm@381	232 David Kirsh - Today the earwig, tomorrow man?
rlm@381	233
rlm@381	234 Douglas B. Lenat, Edward A. Feigenbaum - On the thresholds of
rlm@381	235 knowledge
rlm@381	236
rlm@381	237 Jordan B. Pollack - Recursive distributed representations
rlm@381	238
rlm@381	239 R. Bhaskar, Anil Nigam - Qualitative physics using dimensional
rlm@381	240 analysis
rlm@381	241
rlm@381	242 Don F. Beal - A generalised quiescence search algorithm
rlm@381	243
rlm@381	244 Kai-Fu Lee, Sanjoy Mahajan - The development of a world class Othello
rlm@381	245 program
rlm@381	246
rlm@381	247 Helmut Horacek - Reasoning with uncertainty in computer chess
rlm@381	248
rlm@381	249 Jeff Shrager - Induction: Process of inference, learning and
rlm@381	250 discovery: John H. Holland, Keith J. Holyoak, Richard E. Nisbett, and
rlm@381	251 Paul R. Thagard (MIT Press, Cambridge, MA, 1986); 355 pages
rlm@381	252
rlm@381	253 Daniel S. Weld - The psychology of everyday things: Donald A. Norman,
rlm@381	254 (Basic Books, New York, 1988); 257 pages, $19.95
rlm@381	255
rlm@381	256 John R. Anderson - A theory of the origins of human knowledge
rlm@381	257
rlm@381	258 G. Tesauro, T.J. Sejnowski - A parallel network that learns to play
rlm@381	259 backgammon
rlm@381	260
rlm@381	261 G. Priest - Reasoning about truth
rlm@381	262
rlm@381	263 Donald Perlis - Truth and meaning
rlm@381	264
rlm@381	265 Daniel S. Weld - Women, fire, and dangerous things: George Lakoff,
rlm@381	266 (University of Chicago Press, Chicago, IL, 1987); 614 pages, $29.95
rlm@381	267
rlm@381	268 Mark J. Stefik - On book reviews policy and process
rlm@381	269
rlm@381	270 Robert K. Lindsay - The science of the mind: Owen J. Flanagan, Jr.,
rlm@381	271 (MIT Press, Cambridge, MA, 1984); 290 pages
rlm@381	272
rlm@381	273 Sheila Rock - On machine intelligence: Donald Michie, 2nd ed. (Ellis
rlm@381	274 Horwood, Chichester, United Kingdom, 1986); 265 pages, £29.95
rlm@381	275
rlm@381	276 Stephen W. Smoliar - Epistemology and cognition: A.I. Goldman,
rlm@381	277 (Harvard University Press, Cambridge, MA, 1986); ix + 437 pages,
rlm@381	278 $27.50
rlm@381	279
rlm@381	280 David Elliot Shaw - On the range of applicability of an artificial
rlm@381	281 intelligence machine
rlm@381	282
rlm@381	283 Michael Gordon - Machine intelligence and related topics: An
rlm@381	284 information scientist's weekend book: Donald Michie, (Gordon and
rlm@381	285 Breach, New York, 1982); 328 pages, $57.75
rlm@381	286
rlm@381	287 Ryszard S. Michalski, Patrick H. Winston - Variable precision logic
rlm@381	288
rlm@381	289 Martin Herman, Takeo Kanade - Incremental reconstruction of 3D scenes
rlm@381	290 from multiple, complex images
rlm@381	291
rlm@381	292 vision : June 8–11, 1987, London, United Kingdom
rlm@381	293
rlm@381	294 André Vellino - Artificial intelligence: The very idea: J. Haugeland,
rlm@381	295 (MIT Press, Cambridge, MA, 1985); 287 pp.
rlm@381	296
rlm@381	297 Judea Pearl - Fusion, propagation, and structuring in belief networks
rlm@381	298
rlm@381	299 Daniel G. Bobrow - Scientific debate
rlm@381	300
rlm@381	301 Mark Stefik - The AI business: Commercial uses of artificial
rlm@381	302 intelligence: P.H. Winston and K.A. Prendergast, (MIT Press,
rlm@381	303 Cambridge, MA 1984); 324 pages, $15.95
rlm@381	304
rlm@381	305 Hans Berliner, Carl Ebeling - The SUPREM architecture: A new
rlm@381	306 intelligent paradigm
rlm@381	307
rlm@381	308 Donna Reese - Artificial intelligence: P.H. Winston, (Addison-Wesley,
rlm@381	309 Reading, MA, 2nd ed., 1984); 527 pages
rlm@381	310
rlm@381	311 Kenneth D. Forbus - Structure and interpretation of computer programs:
rlm@381	312 H. Abelson and G.J. Sussman with J. Sussman, (MIT, Cambridge, 1985);
rlm@381	313 503 pages
rlm@381	314
rlm@381	315 Chia-Hoang Lee, Azriel Rosenfeld - Improved methods of estimating
rlm@381	316 shape from shading using the light source coordinate system
rlm@381	317
rlm@381	318 Daniel G. Bobrow, Patrick J. Hayes - Artificial intelligence — Where
rlm@381	319 are we?
rlm@381	320
rlm@381	321 Barbara J. Grosz - Natural-language processing
rlm@381	322
rlm@381	323 Johan De Kleer - How circuits work
rlm@381	324
rlm@381	325 G.D. Ritchie, F.K. Hanna - am: A case study in AI methodology
rlm@381	326
rlm@381	327 Douglas B. Lenat, John Seely Brown - Why am and eurisko appear to work
rlm@381	328
rlm@381	329 Elaine Kant - On the efficient synthesis of efficient programs
rlm@381	330
rlm@381	331 Randall Davis, Reid G. Smith - Negotiation as a metaphor for
rlm@381	332 distributed problem solving
rlm@381	333
rlm@381	334 Patrick H. Winston - Learning new principles from precedents and
rlm@381	335 exercises
rlm@381	336
rlm@381	337 Paul S. Rosenbloom - A world-championship-level Othello program
rlm@381	338
rlm@381	339 Tomas Lozano-Perez - Robotics
rlm@381	340
rlm@381	341 Tom M. Mitchell - Generalization as search
rlm@381	342
rlm@381	343 Dana S. Nau - The last player theorem
rlm@381	344
rlm@381	345 Hans J. Berliner - Backgammon computer program beats world champion
rlm@381	346
rlm@381	347 Gerald Jay Sussman, Guy Lewis Steele Jr. - Constraints—A language for
rlm@381	348 expressing almost-hierarchical descriptions
rlm@381	349
rlm@381	350 Takeo Kanade - A theory of Origami world
rlm@381	351
rlm@381	352 Ria Follett - Synthesising recursive functions with side effects
rlm@381	353
rlm@381	354 John McCarthy - Circumscription—A form of non-monotonic reasoning
rlm@381	355
rlm@381	356 Michael A. Bauer - Programming by examples
rlm@381	357
rlm@381	358 Patrick H. Winston - Learning by creatifying transfer frames
rlm@381	359
rlm@381	360 Alan Bundy - Will it reach the top? Prediction in the mechanics world
rlm@381	361
rlm@381	362 Richard M. Stallman, Gerald J. Sussman - Forward reasoning and
rlm@381	363 dependency-directed backtracking in a system for computer-aided
rlm@381	364 circuit analysis
rlm@381	365
rlm@381	366 D. Marr - Artificial intelligence—A personal view
rlm@381	367
rlm@381	368 Berthold K.P. Horn - Understanding image intensities
rlm@381	369
rlm@381	370 F. Malloy Brown - Doing arithmetic without diagrams
rlm@381	371
rlm@381	372 Azriel Rosenfeld - The psychology of computer vision: Patrick Henry
rlm@381	373 Winston (ed.) McGraw-Hill, New York, 1975, vi+282 pages, $19.50
rlm@381	374
rlm@381	375 R.C.T. Lee - On machine intelligence: D. Michie. Halstead Press, a
rlm@381	376 division of John Wiley & Sons, 1974.
rlm@381	377
rlm@381	378 W.W. Bledsoe, Peter Bruell - A man-machine theorem-proving system
rlm@381	379
rlm@381	380 Gary G. Hendrix - Modeling simultaneous actions and continuous
rlm@381	381 processes
rlm@381	382
rlm@381	383 Yoshiaki Shirai - A context sensitive line finder for recognition of
rlm@381	384 polyhedra
rlm@381	385
rlm@381	386 Kenneth Mark Colby, Franklin Dennis Hilf, Sylvia Weber, Helena C
rlm@381	387 Kraemer - Turing-like indistinguishability tests for the validation of
rlm@381	388 a computer simulation of paranoid processes
rlm@381	389
rlm@381	390 Aaron Sloman - Interactions between philosophy and artificial
rlm@381	391 intelligence: The role of intuition and non-logical reasoning in
rlm@381	392 intelligence
rlm@381	393
rlm@381	394 * Story related
rlm@381	395
rlm@381	396 Charles B. Callaway, James C. Lester - Narrative prose generation
rlm@381	397
rlm@386	398 - Katja Markert, Udo Hahn :: Understanding metonymies in discourse
rlm@386	399 Metonymies are difficult enough to drive these people to use the
rlm@386	400 context of the sentences around the metonymy to interpret
rlm@386	401 it. They create a set of heuristics which interpret
rlm@386	402 metonomies. The first is obvious violations of sentence rules,
rlm@386	403 such as having a non-agent do something only an agent can do.
rlm@386	404
rlm@386	405 Another rule is that metonomyies should be more "apt", where it's
rlm@386	406 more likely for a T.V. Screen to refer to the T.V. than a small
rlm@386	407 button on the T.V., or a transistor.
rlm@386	408
rlm@386	409 Metonymies should be very difficult for current parsers to
rlm@386	410 understand, and are good examples, since they are short and
rlm@386	411 require context and common sense.
rlm@386	412
rlm@386	413 They have a dumb, ad-hoc "common sense database" that is
rlm@386	414 dissapointing. It contains subclasses and has-a relations.
rlm@386	415
rlm@386	416 References:
rlm@386	417 + D.A. Cruse, On the transitivity of the part-whole relation,
rlm@386	418 J. Linguistics 15 (1979) 29–38.
rlm@386	419 good quotes:
rlm@386	420 - We took the door off its hinges and went through it.
rlm@386	421 - The house has a handle.sources
rlm@386	422
rlm@381	423
rlm@381	424 Kathleen R. McKeown, Steven K. Feiner, Mukesh Dalal, Shih-Fu Chang -
rlm@381	425 Generating multimedia briefings: coordinating language and
rlm@381	426 illustration
rlm@381	427
rlm@381	428 Varol Akman - Formalizing common sense: Papers by John McCarthy:
rlm@381	429 V. Lifschitz, ed., (Ablex Publishing Corporation, Norwood, NJ, 1990);
rlm@381	430 vi+256 pages, hardback, ISBN 0-89391-535-1 (Library of Congress:
rlm@381	431 Q335.M38 1989)
rlm@381	432
rlm@381	433 Akira Shimaya - Interpreting non-3-D line drawings
rlm@381	434
rlm@381	435 Adam J. Grove - Naming and identity in epistemic logic part II: a
rlm@381	436 first-order logic for naming
rlm@381	437
rlm@381	438 Luc Lismont, Philippe Mongin - A non-minimal but very weak
rlm@381	439 axiomatization of common belief
rlm@381	440
rlm@381	441 on integration of natural language and vision processing
rlm@381	442
rlm@381	443 Russell Greiner - Learning by understanding analogies
rlm@381	444
rlm@381	445 * Review Articles
rlm@381	446
rlm@381	447 H.Jaap van den Herik, Jos W.H.M. Uiterwijk, Jack van Rijswijck - Games
rlm@381	448 solved: Now and in the future
rlm@381	449
rlm@381	450 Jonathan Schaeffer, H.Jaap van den Herik - Games, computers, and
rlm@381	451 artificial intelligence
rlm@381	452
rlm@381	453 Peter A. Flach - On the state of the art in machine learning: A
rlm@381	454 personal review
rlm@381	455
rlm@381	456 A.G. Cohn, D. Perlis - “Field Reviews”: A new style of review article
rlm@381	457 for Artificial Intelligence
rlm@381	458
rlm@381	459 James Delgrande, Arvind Gupta, Tim Van Allen - A comparison of
rlm@381	460 point-based approaches to qualitative temporal reasoning
rlm@381	461
rlm@381	462 Weixiong Zhang, Rina Dechter, Richard E. Korf - Heuristic search in
rlm@381	463 artificial intelligence
rlm@381	464
rlm@381	465 Karen Sparck Jones - Information retrieval and artificial intelligence
rlm@381	466
rlm@381	467 Wolfram Burgard, Armin B. Cremers, Dieter Fox, Dirk Hähnel, Gerhard
rlm@381	468 Lakemeyer, Dirk Schulz, Walter Steiner, Sebastian Thrun - Experiences
rlm@381	469 with an interactive museum tour-guide robot
rlm@381	470
rlm@381	471 Minoru Asada, Hiroaki Kitano, Itsuki Noda, Manuela Veloso - RoboCup:
rlm@381	472 Today and tomorrow—What we have learned
rlm@381	473
rlm@381	474 Margaret A. Boden - Creativity and artificial intelligence
rlm@381	475
rlm@381	476 Daniel G. Bobrow, J.Michael Brady - Artificial Intelligence 40 years
rlm@381	477 later
rlm@381	478
rlm@381	479 Fangzhen Lin, Hector J. Levesque - What robots can do: robot programs
rlm@381	480 and effective achievability
rlm@381	481
rlm@381	482 Melanie Mitchell - L.D. Davis, handbook of genetic algorithms
rlm@381	483
rlm@381	484 Russell Greiner, Adam J. Grove, Alexander Kogan - Knowing what doesn't
rlm@381	485 matter: exploiting the omission of irrelevant data
rlm@381	486
rlm@381	487 W. Whitney, S. Rana, J. Dzubera, K.E. Mathias - Evaluating
rlm@381	488 evolutionary algorithms
rlm@381	489
rlm@381	490 David S. Touretzky - Neural networks in artificial intelligence:
rlm@381	491 Matthew Zeidenberg
rlm@381	492
rlm@381	493 Mark J. Stefik, Stephen W. Smoliar - The commonsense reviews
rlm@381	494
rlm@381	495 Peter Szolovits, Stephen G. Pauker - Categorical and probabilistic
rlm@381	496 reasoning in medicine revisited
rlm@381	497
rlm@381	498 Daniel G. Bobrow - Artificial intelligence in perspective: a
rlm@381	499 retrospective on fifty volumes of the Artificial Intelligence Journal
rlm@381	500
rlm@381	501 David Kirsh - Foundations of AI: The big issues
rlm@381	502
rlm@381	503 Hector J. Levesque - All I know: A study in autoepistemic logic
rlm@381	504
rlm@381	505 J.T. Schwartz, M. Sharir - A survey of motion planning and related
rlm@381	506 geometric algorithms
rlm@381	507
rlm@381	508 Larry S. Davis, Azriel Rosenfeld - Cooperating processes for low-level
rlm@381	509 vision: A survey
rlm@381	510
rlm@381	511 Hans J. Berliner - A chronology of computer chess and its literature
rlm@381	512
rlm@381	513 John McCarthy - Artificial intelligence: a paper symposium: Professor
rlm@381	514 Sir James Lighthill, FRS. Artificial Intelligence: A General
rlm@381	515 Survey. In: Science Research Council, 1973
rlm@381	516 * Cortex related (sensory fusion / simulated worlds)
rlm@381	517
rlm@381	518 Alfonso Gerevini, Jochen Renz - Combining topological and size
rlm@381	519 information for spatial reasoning
rlm@381	520
rlm@381	521 John Slaney, Sylvie Thiébaux - Blocks World revisited
rlm@381	522
rlm@381	523 Wai K. Yeap, Margaret E. Jefferies - Computing a representation of the
rlm@381	524 local environment
rlm@381	525
rlm@381	526 R.P. Loui - On the origin of objects: B.C. Smith's MIT Press,
rlm@381	527 Cambridge, MA, 1996. $37.50 (cloth). $17.50 (paper). 440 pages. ISBN
rlm@381	528 0-262-69209-0
rlm@381	529
rlm@381	530 Tze Yun Leong - Multiple perspective dynamic decision making
rlm@381	531
rlm@381	532 Cristiano Castelfranchi - Modelling social action for AI agents
rlm@381	533
rlm@381	534 Luc Steels - The origins of syntax in visually grounded robotic agents
rlm@381	535
rlm@381	536 Sebastian Thrun - Learning metric-topological maps for indoor mobile
rlm@381	537 robot navigation
rlm@381	538
rlm@381	539 John Haugeland - Body and world: a review of What Computers Still
rlm@381	540 Can't Do: A critique of artificial reason (Hubert L. Dreyfus): (MIT
rlm@381	541 Press, Cambridge, MA, 1992); liii + 354 pages, $13.95
rlm@381	542
rlm@381	543 David J. Musliner, Edmund H. Durfee, Kang G. Shin - World modeling for
rlm@381	544 the dynamic construction of real-time control plans
rlm@381	545
rlm@381	546 Jozsef A. Toth - Reasoning agents in a dynamic world: The frame
rlm@381	547 problem: Kenneth M. Ford and Patrick J. Hayes, eds., (JAI Press,
rlm@381	548 Greenwich, CT, 1991); 290+xiv pages
rlm@381	549
rlm@381	550 Michael A. Arbib, Jim-Shih Liaw - Sensorimotor transformations in the
rlm@381	551 worlds of frogs and robots
rlm@381	552
rlm@381	553 Ingemar J. Cox, John J. Leonard - Modeling a dynamic environment using
rlm@381	554 a Bayesian multiple hypothesis approach
rlm@381	555
rlm@381	556 on integration of natural language and vision processing
rlm@381	557
rlm@381	558 Demetri Terzopoulos, Andrew Witkin, Michael Kass - Constraints on
rlm@381	559 deformable models:Recovering 3D shape and nonrigid motion
rlm@381	560
rlm@381	561 Bruce R. Donald - A search algorithm for motion planning with six
rlm@381	562 degrees of freedom
rlm@381	563
rlm@381	564 Yorick Wilks - Making preferences more active
rlm@381	565
rlm@381	566 * Vision Related
rlm@381	567
rlm@381	568 Azriel Rosenfeld - B. Jähne, H. Haussecker, and P. Geissler, eds.,
rlm@381	569 Handbook of Computer Vision and Applications. 1. Sensors and
rlm@381	570 Imaging. 2. Signal Processing and Pattern Recognition. 3. Systems and
rlm@381	571 Applications
rlm@381	572
rlm@381	573 Thomas F. Stahovich, Randall Davis, Howard Shrobe - Qualitative
rlm@381	574 rigid-body mechanics
rlm@381	575
rlm@381	576 Tzachi Dar, Leo Joskowicz, Ehud Rivlin - Understanding mechanical
rlm@381	577 motion: From images to behaviors
rlm@381	578
rlm@381	579 Minoru Asada, Eiji Uchibe, Koh Hosoda - Cooperative behavior
rlm@381	580 acquisition for mobile robots in dynamically changing real worlds via
rlm@381	581 vision-based reinforcement learning and development
rlm@381	582
rlm@381	583 Thomas F. Stahovich, Randall Davis, Howard Shrobe - Generating
rlm@381	584 multiple new designs from a sketch
rlm@381	585
rlm@381	586 Ernst D. Dickmanns - Vehicles capable of dynamic vision: a new breed
rlm@381	587 of technical beings?
rlm@381	588
rlm@381	589 Thomas G. Dietterich, Richard H. Lathrop, Tomás Lozano-Pérez - Solving
rlm@381	590 the multiple instance problem with axis-parallel rectangles
rlm@381	591
rlm@381	592 Rajesh P.N. Rao, Dana H. Ballard - An active vision architecture based
rlm@381	593 on iconic representations
rlm@381	594
rlm@381	595 John K. Tsotsos, Scan M. Culhane, Winky Yan Kei Wai, Yuzhong Lai, Neal
rlm@381	596 Davis, Fernando Nuflo - Modeling visual attention via selective tuning
rlm@381	597
rlm@381	598 Roger Mohr, Boubakeur Boufama, Pascal Brand - Understanding
rlm@381	599 positioning from multiple images
rlm@381	600
rlm@381	601 Andrew Zisserman, David Forsyth, Joseph Mundy, Charlie Rothwell, Jane
rlm@381	602 Liu, Nic Pillow - 3D object recognition using invariance
rlm@381	603
rlm@381	604 Naresh C. Gupta, Laveen N. Kanal - 3-D motion estimation from motion
rlm@381	605 field
rlm@381	606
rlm@381	607 Damian M. Lyons - Vision, instruction, and action: David Chapman, (MIT
rlm@381	608 Press Cambridge, MA, 1991); 295 pages, $35.00, (paperback)
rlm@381	609
rlm@381	610 Yoshinori Suganuma - Learning structures of visual patterns from
rlm@381	611 single instances
rlm@381	612
rlm@381	613 Dana H. Ballard - Animate vision
rlm@381	614
rlm@381	615 Raymond Reiter, Alan K. Mackworth - A logical framework for depiction
rlm@381	616 and image interpretation
rlm@381	617
rlm@381	618 Ellen Lowenfeld Walker, Martin Herman - Geometric reasoning for
rlm@381	619 constructing 3D scene descriptions from images
rlm@381	620
rlm@381	621 Michele Barry, David Cyrluk, Deepak Kapur, Joseph Mundy, Van-Duc
rlm@381	622 Nguyen - A multi-level geometric reasoning system for vision
rlm@381	623
rlm@381	624 Alex P. Pentland - Shading into texture
rlm@381	625
rlm@381	626 Brady - Parallelism in Vision
rlm@381	627
rlm@381	628 Jon A. Webb, J.K. Aggarwal - Structure from motion of rigid and
rlm@381	629 jointed objects
rlm@381	630
rlm@381	631 Michael Brady - Computer vision
rlm@381	632
rlm@381	633 Takeo Kanade - Recovery of the three-dimensional shape of an object
rlm@381	634 from a single view
rlm@381	635
rlm@381	636 Rodney A. Brooks - Symbolic reasoning among 3-D models and 2-D images
rlm@381	637
rlm@381	638 H.K. Nishihara - Intensity, visible-surface, and volumetric
rlm@381	639 representations
rlm@381	640
rlm@381	641 Thomas O. Binford - Inferring surfaces from images
rlm@381	642
rlm@381	643 Larry S. Davis, Azriel Rosenfeld - Cooperating processes for low-level
rlm@381	644 vision: A survey
rlm@381	645
rlm@384	646 - (1980) Berthold K.P. Horn, Brian G. Schunck - Determining optical
rlm@384	647 flow
rlm@384	648
rlm@384	649 Optical flow is an estimation of the movement of brightness
rlm@384	650 patterns. If the image is "smooth" then optical flow is also an
rlm@384	651 estimate of the movement of objects in the image (projected onto the
rlm@384	652 plane of the image). They get some fairly good results on some very
rlm@384	653 contrived examples. Important point is that calculating optical flow
rlm@384	654 involves a relaxation process where the velocities of regions of
rlm@384	655 constant brightness are inferred from the velocities of the edges of
rlm@384	656 those regions.
rlm@384	657
rlm@384	658 This paper is a lead up to Horn's book, Robot Vision.
rlm@384	659
rlm@384	660 Hexagonal sampling may be a good alternative to rectangular
rlm@384	661 sampling.
rlm@384	662
rlm@384	663 A reduced version of this algorithm is implemented in hardware in
rlm@384	664 optical mice to great effect.
rlm@384	665
rlm@384	666 + Hamming, R.W., Numerical Methods for Scientists and Engineers
rlm@384	667 (McGraw-Hill, New York, 1962).
rlm@384	668 + Limb, J.O. and Murphy, J.A., Estimating the velocity of moving
rlm@384	669 images in television signals, Computer Graphics and Image
rlm@384	670 Processing 4 (4) (1975) 311-327.
rlm@384	671 + Mersereau, R.M., The processing of hexagonally sampled
rlm@384	672 two-dimensional signals, Proc. of the IEEE 67 (6) (1979) 930-949.
rlm@384	673
rlm@384	674
rlm@384	675 - (1993) Berthold K.P. Horn, B.G. Schunck - “Determining optical flow”: a
rlm@384	676 retrospective
rlm@384	677
rlm@384	678 Very useful read where Horn criticies his previous paper.
rlm@384	679
rlm@384	680 - Whishes that he distinguished "optical flow" form "motion
rlm@384	681 field". "Optical flow" is an image property, whilc the "motion
rlm@384	682 field" is the movement of objects in 3D space. "Optical flow" is a
rlm@384	683 2D vector field; the "motion field" is 3D.
rlm@384	684 - Wished he made the limitations of his algorithm more clear.
rlm@384	685 - His original paper didn't concern itself with flow segmentation,
rlm@384	686 which is required to interpret real world images with objects and
rlm@384	687 a background.
rlm@384	688 - Thinks that the best thing about the original paper is that it
rlm@384	689 introduced variational calculus methods into computer vision.
rlm@384	690
rlm@384	691 References:
rlm@384	692
rlm@384	693 + R. Courant and D. Hilbert, Methods of Mathematical Physics
rlm@384	694 (Interscience, New York, 1937/1953).
rlm@384	695 + D. Mart, Vision (Freeman, San Francisco, CA, 1982).
rlm@384	696 + C.M. Thompson, Robust photo-topography by fusing
rlm@384	697 shape-from-shading and stereo,Ph.D. Thesis, Mechanical Engineering
rlm@384	698 Department, MIT, Cambridge, MA (1993).
rlm@384	699 + K. Ikeuchi and B.K.P. Horn, Numerical shape from shading and
rlm@384	700 occluding boundaries, Artif lntell. 17 (1981) 141-184.
rlm@381	701
rlm@381	702 Katsushi Ikeuchi, Berthold K.P. Horn - Numerical shape from shading
rlm@381	703 and occluding boundaries
rlm@381	704
rlm@381	705 Andrew P. Witkin - Recovering surface shape and orientation from
rlm@381	706 texture
rlm@381	707
rlm@381	708 Irwin Sobel - On calibrating computer controlled cameras for
rlm@381	709 perceiving 3-D scenes
rlm@381	710
rlm@381	711 P.M. Will, K.S. Pennington - Grid coding: A preprocessing technique
rlm@381	712 for robot and machine vision
rlm@381	713
rlm@381	714 M.B. Clowes - On seeing things
rlm@381	715
rlm@381	716 Claude R. Brice, Claude L. Fennema - Scene analysis using regions
rlm@383	717
rlm@383	718 * Cryo!
rlm@383	719
rlm@384	720 - (1999) Kenneth D. Forbus, Peter B. Whalley, John O. Everett, Leo
rlm@384	721 Ureel, Mike Brokowski, Julie Baher, Sven E. Kuehne - CyclePad: An
rlm@384	722 articulate virtual laboratory for engineering thermodynamics
rlm@384	723
rlm@384	724 Should learn about thermodynamics, and about "thermal cycles."
rlm@384	725 http://www.qrg.northwestern.edu/projects/NSF/cyclepad/cyclepad.htm
rlm@384	726
rlm@384	727 This system is more about expressing models and assumtions than
rlm@384	728 automatically generating them, and as such is similiar to our "math
rlm@384	729 language" idea.
rlm@384	730
rlm@384	731 It's like a simple circuit modeller, and similar to Dylan's idea of
rlm@384	732 an online circuit modeler.
rlm@384	733
rlm@384	734 #+begin_quote
rlm@384	735 We found that if CyclePad did not do the “obvious” propagation in
rlm@384	736 preference to interpolation, students trusted it less.
rlm@384	737 #+end_quote
rlm@384	738
rlm@384	739 It's too bad that the paper doesn't mention the shortcommings of the
rlm@384	740 system.
rlm@384	741
rlm@384	742 + J.O. Everett, Topological inference of teleology: Deriving
rlm@384	743 function from structure via evidential reasoning, Artificial
rlm@384	744 Intelligence 113 (1999) 149–202.
rlm@384	745 + P. Hayes, Naive physics 1: Ontology for liquids, in: J. Hobbs,
rlm@384	746 R. Moore (Eds.), Formal Theories of the Commonsense World, Ablex,
rlm@384	747 Norwood, NJ, 1985.
rlm@384	748 + P. Nayak, Automated modeling of physical systems, Ph.D. Thesis,
rlm@384	749 Computer Science Department, Stanford University, 1992.
rlm@384	750 + R.W. Haywood, Analysis of Engineering Cycles: Power, Refrigerating
rlm@384	751 and Gas Liquefaction Plant, Pergamon Press, 1985.
rlm@384	752 + R.M. Stallman, G.J. Sussman, Forward reasoning and
rlm@384	753 dependency-directed backtracking in a system for computer-aided
rlm@384	754 circuit analysis, Artificial Intelligence 9 (1977) 135–196.
rlm@384	755 + Dylan should read this, since it concerns his online circuit
rlm@384	756 analysis idea.
rlm@384	757
rlm@384	758

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