Revision as of 00:09, 1 November 2023 edit Tom.Reding (talk \| contribs) Autopatrolled, Extended confirmed users, Page movers, Template editors 4,364,437 edits m +{{Authority control}} (3 IDs from Wikidata); WP:GenFixes & cleanup on Tag: AWB ← Previous edit		Revision as of 16:45, 10 March 2024 edit undo Calalee (talk \| contribs) 136 edits →Relation to thermodynamics Next edit →
Line 13: ==Relation to thermodynamics== As was first argued by [[Rolf Landauer]] while working at [[IBM]],<ref>{{cite journal \|last1=Landauer \|first1=R. \|title=Irreversibility and Heat Generation in the Computing Process \|journal=IBM Journal of Research and Development \|date=July 1961 \|volume=5 \|issue=3 \|pages=183–191 \|doi=10.1147/rd.53.0183 }}</ref> in order for a computational process to be physically reversible, it must also be ''logically reversible''. [[Landauer's principle]] is the ~~rigorously valid~~ observation that the oblivious erasure of ''n'' bits of known information must always incur a cost of {{Math\|''nkT'' ln(2)}} in thermodynamic [[entropy]]. A discrete, deterministic computational process is said to be logically reversible if the transition function that maps old computational states to new ones is a [[one-to-one function]]; i.e. the output logical states uniquely determine the input logical states of the computational operation. For computational processes that are nondeterministic (in the sense of being probabilistic or random), the relation between old and new states is not a [[single-valued function]], and the requirement needed to obtain physical reversibility becomes a slightly weaker condition, namely that the size of a given ensemble of possible initial computational states does not decrease, on average, as the computation proceeds forwards.

Reversible computing: Difference between revisions