AbstractIn this paper, we show that accepting networks of splicing processors (ANSPs) of size 2 are computationally complete. Since, by definition, an ANSP needs at least two nodes to perform non-trivial computations, this completely settles the question of designing complete ANSPs of minimal size. Also, we derive from this result the fact that all the languages in PSPACE can be accepted by ANSPs of size 2, having polynomial length complexity (the ANSP complexity measure for the space used in a computation). However, the construction that we propose, although efficient from the descriptional complexity and space complexity points of view, does not seem to have good properties from the time complexity point of view. In this respect, we prove...
AbstractWe show that any language recognized by an NC1 circuit (fan-in 2, depth O(log n)) can be rec...
This note connects two topics of Complexity Theory: The topic of succinct circuit representations i...
An intriguing question is whether (log n) ~ space is enough to recognize the class 9 ~ of languages...
AbstractIn this paper, we show that accepting networks of splicing processors (ANSPs) of size 2 are ...
AbstractIn this paper we consider a new, bio-inspired computing model: the accepting network of spli...
In this paper, we introduce generating networks of splicing processors (GNSP for short), a...
Networks of splicing processors (NSP for short) embody a subcategory among the new computational mod...
AbstractThis paper proposes a notion of time complexity in splicing systems. The time complexity of ...
In this paper, we present some results regarding the size complexity of Accepting Networks of Evolut...
AbstractThe Accepting Networks of Evolutionary Processors (ANEPs for short) are bio-inspired computa...
This paper presents the model named Accepting Networks of Evolutionary Processors as NP-problem sol...
AbstractThe goal of this paper is twofold. Firstly, to survey in a systematic and uniform way the ma...
Programming languages which express programs for all computable (recursive) functions are called uni...
In this paper we simplify a recent model of computation considered in [Margenstern et al. 2005], nam...
Programming languages which express programs for all computable (recursive) functions are called uni...
AbstractWe show that any language recognized by an NC1 circuit (fan-in 2, depth O(log n)) can be rec...
This note connects two topics of Complexity Theory: The topic of succinct circuit representations i...
An intriguing question is whether (log n) ~ space is enough to recognize the class 9 ~ of languages...
AbstractIn this paper, we show that accepting networks of splicing processors (ANSPs) of size 2 are ...
AbstractIn this paper we consider a new, bio-inspired computing model: the accepting network of spli...
In this paper, we introduce generating networks of splicing processors (GNSP for short), a...
Networks of splicing processors (NSP for short) embody a subcategory among the new computational mod...
AbstractThis paper proposes a notion of time complexity in splicing systems. The time complexity of ...
In this paper, we present some results regarding the size complexity of Accepting Networks of Evolut...
AbstractThe Accepting Networks of Evolutionary Processors (ANEPs for short) are bio-inspired computa...
This paper presents the model named Accepting Networks of Evolutionary Processors as NP-problem sol...
AbstractThe goal of this paper is twofold. Firstly, to survey in a systematic and uniform way the ma...
Programming languages which express programs for all computable (recursive) functions are called uni...
In this paper we simplify a recent model of computation considered in [Margenstern et al. 2005], nam...
Programming languages which express programs for all computable (recursive) functions are called uni...
AbstractWe show that any language recognized by an NC1 circuit (fan-in 2, depth O(log n)) can be rec...
This note connects two topics of Complexity Theory: The topic of succinct circuit representations i...
An intriguing question is whether (log n) ~ space is enough to recognize the class 9 ~ of languages...