Blum’s speedup theorem is a major theorem in computational com-plexity, showing the existence of computable functions for which no optimal program can exist: for any speedup function r there ex-ists a function fr such that for any program computing fr we can find an alternative program computing it with the desired speedup r. The main corollary is that algorithmic problems do not have, in general, a inherent complexity. Traditional proofs of the speedup theorem make an essential use of Kleene’s fix point theorem to close a suitable diagonal argument. As a consequence, very little is known about its validity in subrecursive settings, where there is no universal machine, and no fixpoints. In this article we discuss an alternative, formal proo...
A central goal of algorithmic research is to determine how fast computational problems can be solved...
AbstractA resource-bounded version of the statement “no algorithm recognizes all non-halting Turing ...
AbstractWe analyze the inherent complexity of implementing Lévy's notion of optimal evaluation for t...
ABSTRACT. This paper is concerned with the nature of speedups. Let f be any recursive func-tion. We ...
Abstract. A classic result known as the speed-up theorem in machineindependent complexity theory sho...
AbstractThis note contains a proof that there is no recursive function of the initial index that giv...
AbstractProblems of the effective synthesis of fastest programs (modulo a recursive factor) for recu...
The constant speedup theorem, so well known from Tur-ing machine based complexity theory, is shown f...
The aim of this discussion paper is to stimulate (or perhaps to provoke) stronger in-teractions amon...
In this paper, the methods of recursive function theory are used to study the size (or cost or compl...
Suppose the fastest algorithm that we can design for some problem runs in time O(n^2). However, we w...
AbstractTwo “folk theorems” that permeate the parallel computation literature are reconsidered in th...
We show in this article that uncomputability is also a relative property of subrecursive classes bui...
In this thesis, we address the following question: Are parallel machines always faster than sequenti...
We are concerned with programs for computing functions, and the running times of these programs as m...
A central goal of algorithmic research is to determine how fast computational problems can be solved...
AbstractA resource-bounded version of the statement “no algorithm recognizes all non-halting Turing ...
AbstractWe analyze the inherent complexity of implementing Lévy's notion of optimal evaluation for t...
ABSTRACT. This paper is concerned with the nature of speedups. Let f be any recursive func-tion. We ...
Abstract. A classic result known as the speed-up theorem in machineindependent complexity theory sho...
AbstractThis note contains a proof that there is no recursive function of the initial index that giv...
AbstractProblems of the effective synthesis of fastest programs (modulo a recursive factor) for recu...
The constant speedup theorem, so well known from Tur-ing machine based complexity theory, is shown f...
The aim of this discussion paper is to stimulate (or perhaps to provoke) stronger in-teractions amon...
In this paper, the methods of recursive function theory are used to study the size (or cost or compl...
Suppose the fastest algorithm that we can design for some problem runs in time O(n^2). However, we w...
AbstractTwo “folk theorems” that permeate the parallel computation literature are reconsidered in th...
We show in this article that uncomputability is also a relative property of subrecursive classes bui...
In this thesis, we address the following question: Are parallel machines always faster than sequenti...
We are concerned with programs for computing functions, and the running times of these programs as m...
A central goal of algorithmic research is to determine how fast computational problems can be solved...
AbstractA resource-bounded version of the statement “no algorithm recognizes all non-halting Turing ...
AbstractWe analyze the inherent complexity of implementing Lévy's notion of optimal evaluation for t...