He has served as program committee chair for ACM Symposium on Principles of Database Systems 1984, Theoretical Aspects of Reasoning about Knowledge 1994, ACM Symposium on Theory of Computing 2005, and the International Conference on Database Theory 2009.
Fagin has received numerous professional awards for his work. He is a Member of the National Academy of Sciences, National Academy of Engineering, and American Academy of Arts and Sciences. He is an IBM Fellow, ACM Fellow, IEEE Fellow, Fellow of the American Association for the Advancement of Science, and Fellow of Asia-Pacific Artificial Intelligence Association. One of his papers [2] won the Gödel Prize. He received a Docteur Honoris Causa from the University of Paris, and a Laurea Honoris Causa from the University of Calabria in Italy. The IEEE granted him the IEEE W. Wallace McDowell Award and the IEEE Technical Achievement Award [3] (now known as the Edward J. McCluskey Technical Achievement Award [4]); and the ACM granted him the ACM SIGMOD Edgar F. Codd Innovations Award The European Association for Theoretical Computer Science (in conjunction with the ACM Special Interest Group for Logic and Computation, the European Association for Computer Science Logic, and the Kurt Gödel Society) granted him and the co-authors of two of his papers,[5][6] the Alonzo Church Award for Logic and Computation. IBM granted him eight IBM Outstanding Innovation Awards, two IBM supplemental Patent Issue Awards, given for key IBM patents, three IBM Outstanding Technical Achievement Awards, and two IBM Corporate Awards. He won Best Paper awards at the 1985 International Joint Conference on Artificial Intelligence, the 2001 ACM Symposium on Principles of Database Systems, the 2010 International Conference on Database Theory, and the 2015 International Conference on Database Theory. He won 10-year Test-of-Time Awards at the 2011 ACM Symposium on Principles of Database Systems, the 2013 International Conference on Database Theory, and the 2014 ACM Symposium on Principles of Database Systems.
Work
Fagin's theorem
Fagin's theorem, which he proved in his PhD thesis, states that existential second-order logic coincides with the complexity class NP in the sense that a decision problem can be expressed in existential second-order logic if and only if it can be solved by a non-deterministic Turing machine in polynomial time. This work helped found the area of finite model theory.[7][8]
Other contributions
Another result that he proved in his PhD thesis is that first-order logic has a zero-one law, which says that if S is a first-order sentence with only relational symbols (no function or constant symbols), then the fraction of n-node structures that satisfy S converges as n goes to infinity, and in fact converges to 0 or 1.[9] This result was proved independently by Glebskiĭ and co-authors earlier (1969) in Russia,[10] with a very different proof.
Besides Fagin's theorem, other concepts named after Fagin are "Fagin's algorithm" for score aggregation,[11] the "Fagin-inverse" for data exchange,[12] and "Fagin games"[13] and "Ajtai–Fagin games"[14] for proving inexpressibility results in logic.
Publications
Fagin has authored or co-authored numerous articles,[15][16] and a book:
Ronald Fagin, Joseph Y. Halpern, Yoram Moses, and Moshe Y. Vardi. Reasoning about knowledge. MIT press (1995). Paperback edition (2003).
Articles, a selection:
Ronald Fagin. "Generalized first-order spectra and polynomial-time recognizable sets". Complexity of Computation, ed. R. Karp, SIAM-AMS Proceedings, Vol. Vol. 7 (1974):43-73.
Ronald Fagin, Jurg Nievergelt, Nicholas J. Pippenger, and H. Raymond Strong. "Extendible hashing—a fast access method for dynamic files." ACM Transactions on Database Systems (TODS) 4.3 (1979): 315–344.
Ronald Fagin, Amnon Lotem, and Moni Naor. "Optimal aggregation algorithms for middleware." Journal of Computer and System Sciences 66 (2003): 614–656. (Special issue for selected papers from the 2001 ACM Symposium on Principles of Database Systems).
Ronald Fagin, Phokion G. Kolaitis, Renee J Miller, and Lucian Popa. "Data exchange: semantics and query answering", Theoretical Computer Science 336 (2005): 89-124. (Special issue for selected papers from the 2003 International Conference on Database Theory).
References
^Ronald Fagin, Joseph Y. Halpern, Yoram Moses, and Moshe Y. Vardi, Reasoning about Knowledge, MIT Press, 1995. Paperback edition, 2003.
^Ronald Fagin, Amnon Lotem, and Moni Naor., "Optimal aggregation algorithms for middleware". Journal of Computer and System Sciences 66 (2003): 614-656. Extended abstract appeared in Proc. 2001 ACM Symposium on Principles of Database Systems, pp. 102-113.
^Ronald Fagin, Phokion Kolaitis, Renee J Miller, and Lucian Popa, “Data exchange: semantics and query answering”, Theoretical Computer Science 336 (2005): 89-124. (Special issue for selected papers from the 2003 International Conference on Database Theory).
^Ronald Fagin, Phokion G. Kolaitis, Lucian Popa, and Wang-Chiew Tan, “Composing schema mappings: Second-order dependencies to the rescue”, ACM Trans. on Database Systems 30, 4 (Dec. 2005), pp. 994-1055. (Special issue for selected papers from the 2004 ACM SIGMOD/PODS Conference).
^Ronald Fagin: "Probabilities on Finite Models". Journal of Symbolic Logic, 41(1):50-58, 1976
^Glebskiĭ, Y. V.; Kogan, D. I.; Liogonkiĭ, M. I.; Talanov, V. A. (1969). "Range and degree of realizability of formulas in the restricted predicate calculus". Kibernetika. 5 (2): 17–28. doi:10.1007/bf01071084. S2CID121409759.
^Ronald Fagin. "Combining fuzzy information from multiple systems." Journal of Computer and System Sciences 58 (1999): 83-99. (Special issue for selected papers from the 1996
ACM Symposium on Principles of Database Systems).
^Ronald Fagin, "Inverting schema mappings". ACM Trans. on Database Systems 32, 4, Nov. 2007. (Special issue for selected papers from the 2006
ACM Symposium on Principles of Database Systems.)
^Ronald Fagin, "Monadic generalized spectra". Zeitschr. f. math. Logik und Grundlagen d. Math. 21, 1975, pp. 89-96.
^Miklos Ajtai and Ronald Fagin, "Reachability is harder for directed than for undirected finite graphs". Journal of Symbolic Logic 55, 1, March 1990, pp. 113-150. Preliminary version appeared in Proc. 29th IEEE Symposium on Foundations of Computer Science, 1988, pp. 358-367.