Abstract. This paper deals with balanced leaf language complexity classes, introduced independently in [1] and [14]. We propose the seed concept for leaf languages, which allows us to give “short ” representations for leaf words. We then use seeds to show that leaf languages A with NP ⊆ BLeaf P (A) cannot be polylog-sparse (i.e. censusA ∈ O(log O(1))), unless P H collapses. We also generalize balanced ≤ P,bit m-reductions, which were introduced in [6], to other bit-reductions, for example (balanced) truth-table- and Turing-bit-reductions. Then, similarly to above, we prove that NP and Σ P 2 cannot have polylog-sparse hard sets under those balanced truthtable-and Turing-bit-reductions, if the polynomial-time hierarchy is infinite
This paper proves that the complexity class Ef)P, parity polynomial time [PZ83], contains the class ...
Introduction One of the important questions in computational complexity theory is whether every NP ...
AbstractLadner (J. Assoc. Comput. Mach. 22 (1975) 155) showed that there are no minimal recursive se...
Unger studied the balanced leaf languages defined via poly-logarithmically sparse leaf pattern sets....
Abstract We introduce the polynomial-time tree reducibility (ptt-reducibility). Our main result stat...
This note connects two topics of Complexity Theory: The topic of succinct circuit representations i...
In this paper, we present stronger results in the theory of succinct problem representation and esta...
AbstractWe study (i) regular languages that are polylog-time reducible to languages of dot-depth 1/2...
AbstractThe computation tree of a nondeterministic machineMwith inputxgives rise to aleaf stringform...
AbstractTight connections between leaf languages and strings compressed by straight-line programs (S...
In the early nineties of the previous century, leaf languages were introduced as a means for the uni...
Tight connections between leafs languages and strings compressed via straight-line programs (SLPs) a...
This paper connects two topics of Complexity Theory: The topic of succinct circuit representations i...
For a nondeterministic polynomial time Turing machine M and an input string x, the leaf string of M ...
AbstractIn this article, the following results are shown: 1. For succinctly encoded problemss(A), co...
This paper proves that the complexity class Ef)P, parity polynomial time [PZ83], contains the class ...
Introduction One of the important questions in computational complexity theory is whether every NP ...
AbstractLadner (J. Assoc. Comput. Mach. 22 (1975) 155) showed that there are no minimal recursive se...
Unger studied the balanced leaf languages defined via poly-logarithmically sparse leaf pattern sets....
Abstract We introduce the polynomial-time tree reducibility (ptt-reducibility). Our main result stat...
This note connects two topics of Complexity Theory: The topic of succinct circuit representations i...
In this paper, we present stronger results in the theory of succinct problem representation and esta...
AbstractWe study (i) regular languages that are polylog-time reducible to languages of dot-depth 1/2...
AbstractThe computation tree of a nondeterministic machineMwith inputxgives rise to aleaf stringform...
AbstractTight connections between leaf languages and strings compressed by straight-line programs (S...
In the early nineties of the previous century, leaf languages were introduced as a means for the uni...
Tight connections between leafs languages and strings compressed via straight-line programs (SLPs) a...
This paper connects two topics of Complexity Theory: The topic of succinct circuit representations i...
For a nondeterministic polynomial time Turing machine M and an input string x, the leaf string of M ...
AbstractIn this article, the following results are shown: 1. For succinctly encoded problemss(A), co...
This paper proves that the complexity class Ef)P, parity polynomial time [PZ83], contains the class ...
Introduction One of the important questions in computational complexity theory is whether every NP ...
AbstractLadner (J. Assoc. Comput. Mach. 22 (1975) 155) showed that there are no minimal recursive se...