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COMPLEXITY OF EQUIVALENCE RELATIONS AND PREORDERS FROM COMPUTABILITY THEORY

Published online by Cambridge University Press:  18 August 2014

EGOR IANOVSKI ,
RUSSELL MILLER ,
KENG MENG NG  and
ANDRÉ NIES
EGOR IANOVSKI
Affiliation:
DEPARTMENT OF COMPUTER SCIENCE UNIVERSITY OF OXFORD WOLFSON BUILDING, PARKS ROAD OXFORD OX1 3QD, UK.Email: [email protected]
RUSSELL MILLER
Affiliation:
DEPARTMENT OF MATHEMATICS, QUEENS COLLEGE 65-30 KISSENA BLVD., FLUSHING NY 11367 USA; & PH.D. PROGRAMS IN MATHEMATICS & COMPUTER SCIENCE CUNY GRADUATE CENTER, 365 FIFTH AVENUE, NEW YORK, NY 10016, USAE-mail: [email protected]
KENG MENG NG
Affiliation:
DIVISION OF MATHEMATICAL SCIENCES SCHOOL OF PHYSICAL & MATHEMATICAL SCIENCES NANYANG TECHNOLOGICAL UNIVERSITY 21 NANYANG LINK, SINGAPOREE-mail: [email protected]
ANDRÉ NIES
Affiliation:
DEPARTMENT OF COMPUTER SCIENCE, UNIVERSITY OF AUCKLAND PRIVATE BAG 92019, AUCKLAND, NEW ZEALANDE-mail: [email protected]
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Abstract

We study the relative complexity of equivalence relations and preorders from computability theory and complexity theory. Given binary relations R, S, a componentwise reducibility is defined by

RS ⇔ ∃fx, y [x R yf (x) S f (y)].

Here, f is taken from a suitable class of effective functions. For us the relations will be on natural numbers, and f must be computable. We show that there is a ${\rm{\Pi }}_1^0$-complete equivalence relation, but no ${\rm{\Pi }}_k^0$-complete for k ≥ 2. We show that ${\rm{\Sigma }}_k^0$ preorders arising naturally in the above-mentioned areas are ${\rm{\Sigma }}_k^0$-complete. This includes polynomial time m-reducibility on exponential time sets, which is ${\rm{\Sigma }}_2^0$, almost inclusion on r.e. sets, which is ${\rm{\Sigma }}_3^0$, and Turing reducibility on r.e. sets, which is ${\rm{\Sigma }}_4^0$.

Keywords

Primary 03D78Secondary 03D32computable reducibilitycomputability theoryequivalence relationsm-reducibilityrecursion theory
Type
Articles
Information
The Journal of Symbolic Logic , Volume 79 , Issue 3 , September 2014 , pp. 859 - 881
Copyright
Copyright © The Association for Symbolic Logic 2014 

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