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The existence and density of generalized complexity cores

Authors:

Ronald V. Book,

Ding-Zhu DuAuthors Info & Claims

Journal of the ACM (JACM), Volume 34, Issue 3

Pages 718 - 730

https://doi.org/10.1145/28869.28880

Published: 01 July 1987 Publication History

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Abstract

If C is a class of sets and A is not in C, then an infinite set H is a proper hard core for A with respect to C, if H ⊆ A and for every C ε C such that C ⊆ A, C ⋒ H is finite. It is shown that if C is a countable class of sets of strings that is closed under finite union and finite variation, then every infinite set not in C has a proper hard core with respect to C. In addition, the density of such generalized complexity cores is studied.

References

[1]

BALCA, ZAR, J. AND SCHONING, U. Bi-immunity for complexity classes. Math. Syst. Theory 18 (1985), 1-10.

Google Scholar

[2]

BALCAZAR, J., BOOK, R., AND SCHONING, U. Sparse set, lowness, and highness. SlAM J. Comput. 15 (1986), 739-747.

Crossref

Google Scholar

[3]

BERMAN, L. On the structure of complete sets: Almost-everywhere complexity and infinitely often speedup. In Proceedings of the 17th IEEE Symposium on Foundations of Computer Science. IEEE, New York, 1976, 76-80.

Google Scholar

[4]

BERMAN, L., AND HARTMANIS, J. On isomorphism and density of NP and other complete sets. SlAM J. Comput. 6 (1977), 305-322.

Google Scholar

[5]

Du, D.-Z. Generalized complexity cores and levelability of intractable sets. Ph.D. dissertation. Univ. of California, Santa Barbara, Calif., 1985.

Crossref

Google Scholar

[6]

Du, D.-Z., ISAKOWITZ, T., AND RUSSO, D. Structural properties of complexity cores, submitted for publication.

Google Scholar

[7]

EVEN, S., SELMAN, A., AND YACOBI, Y. Hard core theorems for complexity classes. ~ ACM 35, 1 (Jan. 1985), 205-217.

Crossref

Google Scholar

[8]

GROLLMAN, J., AND SELMAN, A. Complexity measures of public-key cryptosystems. In Proceedings of the 15th IEEE Symposium on Foundations of Computer Science. IEEE, New York, 1984, pp. 495-503.

Google Scholar

[9]

HOMER, S., AND MAASS, W. Oracle dependent properties of the lattice of NP sets. Theoret. Comput. Sci. 24 (1983), 279-289.

Google Scholar

[10]

Ko, K., AND MOORE, D. Completeness, approximation, and density. SIAM J. Comput. I 0 ( 1981), 787-796.

Google Scholar

[11]

Ko, K., AND SCHONING, O. On circuit-size complexity and the low hierarchy in NP. SIAM J. Comput. 14 (1984), 41-51.

Google Scholar

[12]

LYNCH, N. On reducibility to complex or sparse sets. J. ACM 22, 3 (July 1975), 341-345.

Crossref

Google Scholar

[13]

MEYER, A., AND PATERSON, i. With what frequency are apparently intractable problems difficult? Tech. Rep. TM-126, Massachusetts Institute of Technology, Cambridge, Mass., 1979.

Google Scholar

[14]

ORPONEN, P. The structure of polynomial complexity cores. Ph.D. dissertation. Univ. of Helsinki, Helsinld, Finland, 1986.

Google Scholar

[15]

ORPONEN, P. A classification of complexity core lattices. Theoret. Comput. Sci. 47 (1986), 121-130.

Crossref

Google Scholar

[16]

ORPONEN, P., AND SCHONING, O. The density and complexity of polynomial cores for intractable sets. Inf. Control 70 (1986), 54-68.

Crossref

Google Scholar

[17]

ORVONEN, P., RUSSO, D., AND SCHONING, U. Optimal approximations and polynomially levelable sets. SIAM J. Comput. 15 (1986), 399-408.

Crossref

Google Scholar

[18]

RtJsso, D. Structural properties of complexity classes. Ph.D. dissertation. Univ. of California, Santa Barbara, Calif., 1985.

Google Scholar

[19]

RtJsso, D., AND ORPONEN, P. On P-subset structures. Submitted for publication.

Google Scholar

[20]

SCrtONING, U. A low and a high hierarchy within NP. J. Comput. Syst. Sci. 27 (1983), 14-28.

Google Scholar

[21]

SCHONING, U. A note on small generators. Theoret. Comput. Sci. 34 (1984), 337-341.

Google Scholar

[22]

SCrIOmNG, U., AND BOOK, R. Immunity, relativizations, and nondeterminism. SIAM J. Comput. 13 (1984), 329-337.

Crossref

Google Scholar

[23]

YAP, C. Some consequences of non-uniform conditions on uniform classes. Theoret. Comput. Sci. 26 (1983), 287-300.

Google Scholar

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Index Terms

The existence and density of generalized complexity cores
1. Mathematics of computing
  1. Discrete mathematics
2. Theory of computation
  1. Computational complexity and cryptography
    1. Complexity classes

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Reviews

Reviewer: Daniel M. Leivant

This paper studies a notion of proper hard core (phc), generalizing Lynch's notion of “complexity core.” For a set A and a collection C , an infinite H ? 9T A is a phc of A with respect to C if H :3Wd9T C is finite for all C ? C :3Wd9T P ( A) (where P is the power set operator). The paper's main result is that if C is countable and closed under finite variation and finite union, then every infinite A ? :.KC / C has a phc with respect to C . This is proven as follows: Say C A = Df C :3Wd9T P ( A) = { C i}- i. Set h k = min( C k ? C < k), where C < k = Df :3WD0I i< kC i and min(:3WC = Df 0. Let H = { h k} k. If H is infinite, then it is a phc, since H :3Wd9T C k ? 9T{ h i} i< k for all k. If H is finite, then :3WD9WC A = C < n for some n. A is then the union of n of the C i's and of the set H? = Df A ? :3WDQ C A. H? cannot be finite, for then A ? C by the closure conditions on C . Also, H? :3Wd9T C k = :3WCis finite for all k. So H ? is a phc. Each condition on C is shown to be necessary. Adding the requirement h k + 1 > h k in the proof yields a phc that is recursive in A if C A is an r.e. sequence of recursive sets. Special cases of the main result, for various complexity classes C , are shown to imply theorems on complexity cores by Even, Scho¨ning, Balca´zar, and others. The notion of phc is then related to sparseness, and results of Orponen and Scho¨ning are generalized, relating sparse complexity cores to Meyer-Paterson's notions of approximate polynomial time. Let C and A ? :.KC# / C be as above, with C A :3WC Let B ? 9T A. If every H ? 9T B which is a phc of A is sparse, then B ? 9T C :3WD9T D for some C ? C and sparse D. (This holds for an abstract notion of sparseness.) The work is significant in delineating general concepts and elementary constructions that underlie much of the previous literature on complexity cores.

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Published In

Journal of the ACM Volume 34, Issue 3

July 1987

248 pages

ISSN:0004-5411

EISSN:1557-735X

DOI:10.1145/28869

Issue’s Table of Contents

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Association for Computing Machinery

New York, NY, United States

Publication History

Published: 01 July 1987

Published in JACM Volume 34, Issue 3

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Shimizu AMatsuzaki YUkena A(2013)Necessity of Superposition of Macroscopically Distinct States for Quantum Computational SpeedupJournal of the Physical Society of Japan10.7566/JPSJ.82.05480182:5(054801)Online publication date: 15-May-2013
https://doi.org/10.7566/JPSJ.82.054801
Brandt UWalter H(2013)Cohesiveness in promise problemsRAIRO - Theoretical Informatics and Applications10.1051/ita/201304247:4(351-369)Online publication date: 8-Nov-2013
https://doi.org/10.1051/ita/2013042
Tran N(2011)Characterizations and Existence of Easy Sets without Hard SubsetsFundamenta Informaticae10.5555/2362097.2362119110:1-4(321-328)Online publication date: 1-Jan-2011
https://dl.acm.org/doi/10.5555/2362097.2362119
Karg CSchuler R(2005)Structure in average case complexityAlgorithms and Computations10.1007/BFb0015409(62-71)Online publication date: 9-Jun-2005
https://doi.org/10.1007/BFb0015409
Juedes DLutz J(2005)Completeness and weak completeness under polynomial-size circuitsSTACS 9510.1007/3-540-59042-0_59(26-37)Online publication date: 1-Jun-2005
https://doi.org/10.1007/3-540-59042-0_59
Biehl I(2005)Definition and existence of super complexity coresAlgorithms and Computation10.1007/3-540-58325-4_228(600-606)Online publication date: 3-Jun-2005
https://doi.org/10.1007/3-540-58325-4_228
Schöning U(2005)Complexity cores and hard problem instancesAlgorithms10.1007/3-540-52921-7_72(232-240)Online publication date: 4-Jun-2005
https://doi.org/10.1007/3-540-52921-7_72
Schöning U(2005)Complexity cores and hard-to-prove formulasCSL '8710.1007/3-540-50241-6_43(273-280)Online publication date: 31-May-2005
https://doi.org/10.1007/3-540-50241-6_43
Schindelhauer CJakoby A(2000)The Non-recursive Power of Erroneous ComputationFoundations of Software Technology and Theoretical Computer Science10.1007/3-540-46691-6_32(394-406)Online publication date: 9-Jun-2000
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Juedes DLutz J(1995)The Complexity and Distribution of Hard ProblemsSIAM Journal on Computing10.1137/S009753979223813324:2(279-295)Online publication date: 1-Apr-1995
https://dl.acm.org/doi/10.1137/S0097539792238133
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Recommendations

Generalized complexity cores and levelability of intractable sets (np-complete, polynomial immunity, exponential-time, k-creative, approximation)

On the existence of rook equivalent t-cores

Wimpy or brawny cores: A throughput perspective

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