On the capacity of noisy computations

François Simon

doi:10.1109/ITW.2011.6089373

On the capacity of noisy computations

François Simon

CNRS SAMOVAR UMR 5157

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

This paper presents an analysis of the concept of capacity for noisy computations, i.e. algorithms implemented by unreliable computing devices (e.g. noisy Turing Machines). The capacity of a noisy computation is defined and justified by companion coding theorems. Under some constraints on the encoding process, capacity is the upper bound of input rates allowing reliable computation, i.e. decodability of noisy outputs into expected outputs. A model of noisy computation of a perfect function f thanks to an unreliable device F is given together with a model of reliable computation based on input encoding and output decoding. A coding lemma (extending the Feinstein's theorem to noisy computations), a joint source-computation coding theorem and its converse are proved. They apply if the input source, the function f, the noisy device F and the cascade f ^-1F induce AMS and ergodic one-sided random processes.

Original language	English
Title of host publication	2011 IEEE Information Theory Workshop, ITW 2011
Pages	185-189
Number of pages	5
DOIs	https://doi.org/10.1109/ITW.2011.6089373
Publication status	Published - 21 Dec 2011
Externally published	Yes
Event	2011 IEEE Information Theory Workshop, ITW 2011 - Paraty, Brazil Duration: 16 Oct 2011 → 20 Oct 2011

Publication series

Name	2011 IEEE Information Theory Workshop, ITW 2011

Conference

Conference	2011 IEEE Information Theory Workshop, ITW 2011
Country/Territory	Brazil
City	Paraty
Period	16/10/11 → 20/10/11

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10.1109/ITW.2011.6089373

Cite this

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title = "On the capacity of noisy computations",

abstract = "This paper presents an analysis of the concept of capacity for noisy computations, i.e. algorithms implemented by unreliable computing devices (e.g. noisy Turing Machines). The capacity of a noisy computation is defined and justified by companion coding theorems. Under some constraints on the encoding process, capacity is the upper bound of input rates allowing reliable computation, i.e. decodability of noisy outputs into expected outputs. A model of noisy computation of a perfect function f thanks to an unreliable device F is given together with a model of reliable computation based on input encoding and output decoding. A coding lemma (extending the Feinstein's theorem to noisy computations), a joint source-computation coding theorem and its converse are proved. They apply if the input source, the function f, the noisy device F and the cascade f -1F induce AMS and ergodic one-sided random processes.",

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year = "2011",

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doi = "10.1109/ITW.2011.6089373",

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N2 - This paper presents an analysis of the concept of capacity for noisy computations, i.e. algorithms implemented by unreliable computing devices (e.g. noisy Turing Machines). The capacity of a noisy computation is defined and justified by companion coding theorems. Under some constraints on the encoding process, capacity is the upper bound of input rates allowing reliable computation, i.e. decodability of noisy outputs into expected outputs. A model of noisy computation of a perfect function f thanks to an unreliable device F is given together with a model of reliable computation based on input encoding and output decoding. A coding lemma (extending the Feinstein's theorem to noisy computations), a joint source-computation coding theorem and its converse are proved. They apply if the input source, the function f, the noisy device F and the cascade f -1F induce AMS and ergodic one-sided random processes.

AB - This paper presents an analysis of the concept of capacity for noisy computations, i.e. algorithms implemented by unreliable computing devices (e.g. noisy Turing Machines). The capacity of a noisy computation is defined and justified by companion coding theorems. Under some constraints on the encoding process, capacity is the upper bound of input rates allowing reliable computation, i.e. decodability of noisy outputs into expected outputs. A model of noisy computation of a perfect function f thanks to an unreliable device F is given together with a model of reliable computation based on input encoding and output decoding. A coding lemma (extending the Feinstein's theorem to noisy computations), a joint source-computation coding theorem and its converse are proved. They apply if the input source, the function f, the noisy device F and the cascade f -1F induce AMS and ergodic one-sided random processes.

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DO - 10.1109/ITW.2011.6089373

M3 - Conference contribution

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BT - 2011 IEEE Information Theory Workshop, ITW 2011

T2 - 2011 IEEE Information Theory Workshop, ITW 2011

Y2 - 16 October 2011 through 20 October 2011

ER -

On the capacity of noisy computations

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