On learning limiting programs

Subscribe (Full Service)


	Search: The ACM Digital Library The Guide

	Feedback

On learning limiting programs

Full text

Pdf (878 KB)

Source

Annual Workshop on Computational Learning Theory archive
Proceedings of the fifth annual workshop on Computational learning theory table of contents

Pittsburgh, Pennsylvania, United States

Pages: 193 - 202

Year of Publication: 1992

ISBN:0-89791-497-X

Authors

John Case	Department of CIS, University of Delaware, Newark, DE
Sanjay Jain	Department of CIS, University of Delaware, Newark, DE
Arun Sharma	School of Computer Science and Engineering, The University of New South Wales, Sydney, NSW 2033, Australia

Sponsors

SIGACT: ACM Special Interest Group on Algorithms and Computation Theory
SIGART: ACM Special Interest Group on Artificial Intelligence

Publisher

ACM New York, NY, USA

Bibliometrics

Downloads (6 Weeks): 0, Downloads (12 Months): 14, Citation Count: 0

Additional Information:

abstract references index terms collaborative colleagues peer to peer

Tools and Actions:	Review this Article Save this Article to a Binder Display Formats: BibTeX EndNote ACM Ref

DOI Bookmark:	Use this link to bookmark this Article: http://doi.acm.org/10.1145/130385.130407 What is a DOI?

ABSTRACT

Machine learning of limit programs (i.e., programs allowed finitely many mind changes about their legitimate outputs) for computable functions is studied. Learning of iterated limit programs is also studied. To partially motivate these studies, it is shown that, in some cases, interesting global properties of computable functions can be proved from suitable (n+1)-iterated limit programs for them which can not be proved from any n-iterated limit programs for them. It is shown that learning power is increased when (n+1)-iterated limit programs rather than n-iterated limit programs are to be learned. Many tradeoff results are obtained regarding learning power, number (possibly zero) of limits taken, program size constraints, and number of errors tolerated in final programs learned.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	AS83	Dana Angluin , Carl H. Smith, Inductive Inference: Theory and Methods, ACM Computing Surveys (CSUR), v.15 n.3, p.237-269, Sept. 1983 [doi>10.1145/356914.356918]
	Bar74	J.M. Barzdin. Two theorems on the limiting synthesis of functions. In Theory of Algorithms and Programs, Latvian State University, Riga, 210:82-88, 1974. In Russian.
	BB75	L. Blum and M. Blum. Toward a mathematical theory of inductive inference. Information and Control, 28:125-155, 1975.
	BCJS92	Ganesh Baliga , John Case , Sanjay Jain , Mandayam Suraj, Machine Learning of Higher Order Programs, Proceedings of the Second International Symposium on Logical Foundations of Computer Science, p.9-20, July 20-24, 1992
	Blu67	Manuel Blum, A Machine-Independent Theory of the Complexity of Recursive Functions, Journal of the ACM (JACM), v.14 n.2, p.322-336, April 1967 [doi>10.1145/321386.321395]
	Cas74	J. Case. Periodicity in generations of automata. Mathematical Systems Theory, 8:15- 32, 1974.
	Cas86	J. Case. Learning machines. In W. Demopoulos and A. Marras, editors, Language Learning and Concept Acquisition. Ablex Publishing Company, 1986.
	CCJ92	John Case , Keh-Jiann Chen , Sanjay Jain, Strong separation of learning classes, Journal of Experimental & Theoretical Artificial Intelligence, v.4 n.4, p.281-293, Oct.–Dec. 1992 [doi>10.1080/09528139208953752]
	Che81	Keh-Jiann Chen, Tradeoffs in machine inductive inference, 1981
	Che82	K. Chen. Tradeoffs in inductive inference of nearly minimal sized programs. Information and Control, 52:68-86, 1982.
	CJS90	J. Case, S. Jain, and A. Sharma. Anomalous learning helps succinctness. In S. Arikawa, S. Goto, S. Ogsuga, and T. Yokomori, editors, Proceedings of the First Workshop on Algorithmic Learning Theory, Tokyo, Japan, pages 282-288. Japanese Society for Artificial Intelligence, October 1990.
	Cra53	W. Craig. On axiomatizability within a system. Journal of Symbolic Logic, 18:30-32, 1953.
	CS83	J. Case and C. Smith. Comparison of identification criteria for machine inductive inference. Theoretical Computer Science, 25:193- 220, 1983.
	Fef60	S. Feferman. Arithmetization of metamathematics in a general setting. Fundamenta Mathematicae, 49:35-92, 1960.
	Fre75	R. Freivalds. Minimal GSdel numbers and their identification in the limit. Lecture Notes in Computer Science, 32:219-225, 1975.
	Ful85	Mark Andrew Fulk, A study of inductive inference machines, State University of New York at Buffalo, Buffalo, NY, 1986
	Gol65	E.M. Gold. Limiting recursion. Journal of Symbolic Logic, 30:28-48, 1965.
	Gol67	E.M. Gold. Language identification in the limit. Information and Control, 10:447-474, 1967.
	HU79	John E. Hopcroft , Jeffrey D. Ullman, Introduction To Automata Theory, Languages, And Computation, Addison-Wesley Longman Publishing Co., Inc., Boston, MA, 1990
	KW80	R. Klette and R. Wiehagen. Research in the theory of inductive inference by GDR mathematicians - A survey. Information Sciences, 22:149-169, 1980.
	LMF76	N. Lynch, A. Meyer, and M. Fischer. Relativization of the theory of computational complexity. Transactions of the American Mathematical Society, 220:243-287, 1976.
	Mar89	Y. Marcoux. Composition is almost as good as s-1-1. In Proceedings, Structure in Complexity Theory-Fourth Annual Conference. IEEE Computer Society Press, 1989.
	Men86	Elliott Mendelson, Introduction to mathematical logic (3rd ed.), Wadsworth Publ. Co., Belmont, CA, 1987
	MY78	Michael Machtey , Paul Young, An Introduction to the General Theory of Algorithms, Elsevier Science Inc., New York, NY, 1978
	OSW86	Daniel N. Osherson , Michael Stob , Scott Weinstein, Systems that learn: an introduction to learning theory for cognitive and computer scientists, MIT Press, Cambridge, MA, 1986
	Put65	H. Putnam. Trial and error predicates and the solution to a problem of Mostowski. Journal of Symbolic Logic, 30:49-57, 1965.
	RC92	J. Royer and J. Case. Intensional Subrecursion and Complexity Theory. Research Notes in Theoretical Science. Pitman Press, being revised for expected publication, 1992.
	Ric80	Gregory Anthony Riccardi, The independence of control structures in abstract programming systems, 1980
	Ric81	G. Riccardi. The independence of control structures in abstract programming systems. Journal of Computer and System Sciences, 22:107-143, 1981.
	Rog58	H. Rogers. GSdel numberings of partial recursive functions. Journal of Symbolic Logic, 23:331-341, 1958.
	Rog67	Hartley Rogers, Jr., Theory of recursive functions and effective computability, MIT Press, Cambridge, MA, 1987
	Roy87	James S. Royer, A connotational theory of program structure, Springer-Verlag New York, Inc., New York, NY, 1987
	Sha71	N. Shapiro. Review of "Limiting recursion" by E.M. Gold and "Trial and error predicates and the solution to a problem of Mostowski" by H. Putnam. Journal of Symbolic Logic, 36:342, 1971.
	Sho59	J. Shoenfield. On degrees of unsolvability. Annals of Mathematics, 69:644-653, 1959.
	Sho71	J. Shoenfield. Degrees of Unsolvability. North-Holland, 1971.
	Soa87	Robert I. Soare, Recursively enumerable sets and degrees, Springer-Verlag New York, Inc., New York, NY, 1987
	Wie78	R. Wiehagen. Zur Therie der Algrithmischen Erkennung. PhD thesis, Humboldt- Universitat, Berlin, 1978.