AbstractThis paper studies the classification of recursive sets by the number of tape reversals required for their recognition on a two-tape Turing machine with a one-way input tape.This measure yields a rich hierarchy of tape-reversal limited complexity classes and their properties and ordering are investigated. The most striking difference between this and the previously studied complexity measures lies in the fact that the “speed-up” theorem does not hold for slowly growing tape-reversal complexity classes. These differences are discussed, and several relations between the different complexity measures and languages are established
Given a number of tape symbols, we define the state complexity of a partial-recursive function f as ...
The model of Turing machines has been studied since its birth in 1936. Researchers have continuously...
AbstractWe study a generalized version of reversal bounded Turing machines where, apart from several...
AbstractThis paper studies the classification of recursive sets by the number of tape reversals requ...
AbstractFor off-line one-tape Turing machines the number of tape reversals required for various comp...
IN computations by abstract computing devices such as the Turing machine, head reversals are require...
The number of tape reversals required for the recognition of a set of inputs by a 1-tape Turing mach...
AbstractIt is known that, for one-tape nondeterministic Turing machines, S(n)-space and S(n)-reversa...
AbstractYamamoto and Noguchi raised the question of whether every recursively enumerable set can be ...
Let L be a language recognized by a nondeterministic (single-tape) Turing machine of time complexity...
The different concepts involved in “reversal complexity”counting reversals (sweeps), visits to a squ...
Several classes of multihead and auxiliary stack automata are introduced and are used to characteriz...
We investigate the relationship between the time and the reversal complexity measure for determinist...
It is shown that for any real constants b>a≥0, multitape Turing machines operating in space L1(n)=[b...
AbstractWe study the power of reversal-bounded ATMs (alternating Turing machines). The results obtai...
Given a number of tape symbols, we define the state complexity of a partial-recursive function f as ...
The model of Turing machines has been studied since its birth in 1936. Researchers have continuously...
AbstractWe study a generalized version of reversal bounded Turing machines where, apart from several...
AbstractThis paper studies the classification of recursive sets by the number of tape reversals requ...
AbstractFor off-line one-tape Turing machines the number of tape reversals required for various comp...
IN computations by abstract computing devices such as the Turing machine, head reversals are require...
The number of tape reversals required for the recognition of a set of inputs by a 1-tape Turing mach...
AbstractIt is known that, for one-tape nondeterministic Turing machines, S(n)-space and S(n)-reversa...
AbstractYamamoto and Noguchi raised the question of whether every recursively enumerable set can be ...
Let L be a language recognized by a nondeterministic (single-tape) Turing machine of time complexity...
The different concepts involved in “reversal complexity”counting reversals (sweeps), visits to a squ...
Several classes of multihead and auxiliary stack automata are introduced and are used to characteriz...
We investigate the relationship between the time and the reversal complexity measure for determinist...
It is shown that for any real constants b>a≥0, multitape Turing machines operating in space L1(n)=[b...
AbstractWe study the power of reversal-bounded ATMs (alternating Turing machines). The results obtai...
Given a number of tape symbols, we define the state complexity of a partial-recursive function f as ...
The model of Turing machines has been studied since its birth in 1936. Researchers have continuously...
AbstractWe study a generalized version of reversal bounded Turing machines where, apart from several...