Title :
Capacity of a noisy function
Author_Institution :
Inst. TELECOM, Telecom SudParis, Evry, France
fDate :
Aug. 30 2010-Sept. 3 2010
Abstract :
This paper presents an extension of the memoryless channel coding theorem to noisy functions, i.e. unreliable computing devices without internal states. It is shown that the concepts of equivocation and capacity can be defined for noisy computations in the simple case of memoryless noisy functions. Capacity is the upper bound of input rates allowing reliable computation, i.e. decodability of noisy outputs into expected outputs. The proposed concepts are generalizations of these known for channels: the capacity of a noisy implementation of a bijective function has the same expression as the capacity of a communication channel. A lemma similar to Feinstein´s one is stated and demonstrated. A model of reliable computation of a function thanks to a noisy device is proposed. A coding theorem is stated and demonstrated.
Keywords :
channel capacity; channel coding; decoding; interference; memoryless systems; telecommunication network reliability; bijective function; coding theorem; communication channel capacity; equivocation; memoryless channel coding; noisy function capacity; noisy output decodability; reliable computation; Bismuth; Computational modeling; Decoding; Encoding; Noise measurement; Redundancy; Reliability theory;
Conference_Titel :
Information Theory Workshop (ITW), 2010 IEEE
Conference_Location :
Dublin
Print_ISBN :
978-1-4244-8262-7
Electronic_ISBN :
978-1-4244-8263-4
DOI :
10.1109/CIG.2010.5592779
