AbstractThe λ-calculus is destructive: its main computational mechanism – beta reduction – destroys the redex and makes it thus impossible to replay the computational steps. Recently, reversible computational models have been studied mainly in the context of quantum computation, as (without measurements) quantum physics is inherently reversible. However, reversibility also changes fundamentally the semantical framework in which classical computation has to be investigated. We describe an implementation of classical combinatory logic into a reversible calculus for which we present an algebraic model based on a generalisation of the notion of group
Reversible logic circuits are beneficial to both classical and quantum computer design. Present-day ...
AbstractWe extend categorical semantics of monadic programming to reversible computing, by consideri...
We extend categorical semantics of monadic programming to reversible computing, by considering monoi...
AbstractThe λ-calculus is destructive: its main computational mechanism – beta reduction – destroys ...
The lambda-calculus is destructive: its main computational mechanism, beta reduction, destroys the r...
AbstractIn this paper we study the relation between reversible and irreversible computation applicab...
This article is an attempt to generalize the classical theory of reversible computing, principally d...
Classical reversible logic and quantum computing share the common feature that all computations are ...
Reversible computation allows computation to proceed not only in the standard, forward direction, bu...
AbstractReversibility is a key issue in the interface between computation and physics, and of growin...
Reversible computation allows computation to proceed not only in the standard, forward direction, bu...
AbstractReversible computation has a growing number of promising application areas such as the model...
AbstractReversible computing is a paradigm where computing models are defined so that they reflect p...
Reversible logic circuits of certain logic width form a group, isomorphic to a symmetric group. Its ...
Reversible computing is a paradigm where computing models are defined so that they reflect physical ...
Reversible logic circuits are beneficial to both classical and quantum computer design. Present-day ...
AbstractWe extend categorical semantics of monadic programming to reversible computing, by consideri...
We extend categorical semantics of monadic programming to reversible computing, by considering monoi...
AbstractThe λ-calculus is destructive: its main computational mechanism – beta reduction – destroys ...
The lambda-calculus is destructive: its main computational mechanism, beta reduction, destroys the r...
AbstractIn this paper we study the relation between reversible and irreversible computation applicab...
This article is an attempt to generalize the classical theory of reversible computing, principally d...
Classical reversible logic and quantum computing share the common feature that all computations are ...
Reversible computation allows computation to proceed not only in the standard, forward direction, bu...
AbstractReversibility is a key issue in the interface between computation and physics, and of growin...
Reversible computation allows computation to proceed not only in the standard, forward direction, bu...
AbstractReversible computation has a growing number of promising application areas such as the model...
AbstractReversible computing is a paradigm where computing models are defined so that they reflect p...
Reversible logic circuits of certain logic width form a group, isomorphic to a symmetric group. Its ...
Reversible computing is a paradigm where computing models are defined so that they reflect physical ...
Reversible logic circuits are beneficial to both classical and quantum computer design. Present-day ...
AbstractWe extend categorical semantics of monadic programming to reversible computing, by consideri...
We extend categorical semantics of monadic programming to reversible computing, by considering monoi...