Polynomial differential equations compute all real computable functions on computable compact intervals

Olivier Bournez; Manuel L. Campagnolo; Daniel S. Graça; Emmanuel Hainry

doi:10.1016/j.jco.2006.12.005

Polynomial differential equations compute all real computable functions on computable compact intervals

Olivier Bournez
, Manuel L. Campagnolo
, Daniel S. Graça
, Emmanuel Hainry

Research output: Contribution to journal › Article › peer-review

Abstract

In the last decade, there have been several attempts to understand the relations between the many models of analog computation. Unfortunately, most models are not equivalent. Euler's Gamma function, which is computable according to computable analysis, but that cannot be generated by Shannon's General Purpose Analog Computer (GPAC), has often been used to argue that the GPAC is less powerful than digital computation. However, when computability with GPACs is not restricted to real-time generation of functions, it has been shown recently that Gamma becomes computable by a GPAC. Here we extend this result by showing that, in an appropriate framework, the GPAC and computable analysis are actually equivalent from the computability point of view, at least in compact intervals. Since GPACs are equivalent to systems of polynomial differential equations then we show that all real computable functions over compact intervals can be defined by such models.

Original language	English
Pages (from-to)	317-335
Number of pages	19
Journal	Journal of Complexity
Volume	23
Issue number	3
DOIs	https://doi.org/10.1016/j.jco.2006.12.005
Publication status	Published - 1 Jan 2007
Externally published	Yes

Keywords

Analog computation
Church-Turing thesis
Computable analysis
Differential equations
General Purpose Analog Computer

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10.1016/j.jco.2006.12.005

Cite this

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title = "Polynomial differential equations compute all real computable functions on computable compact intervals",

abstract = "In the last decade, there have been several attempts to understand the relations between the many models of analog computation. Unfortunately, most models are not equivalent. Euler's Gamma function, which is computable according to computable analysis, but that cannot be generated by Shannon's General Purpose Analog Computer (GPAC), has often been used to argue that the GPAC is less powerful than digital computation. However, when computability with GPACs is not restricted to real-time generation of functions, it has been shown recently that Gamma becomes computable by a GPAC. Here we extend this result by showing that, in an appropriate framework, the GPAC and computable analysis are actually equivalent from the computability point of view, at least in compact intervals. Since GPACs are equivalent to systems of polynomial differential equations then we show that all real computable functions over compact intervals can be defined by such models.",

keywords = "Analog computation, Church-Turing thesis, Computable analysis, Differential equations, General Purpose Analog Computer",

author = "Olivier Bournez and Campagnolo, \{Manuel L.\} and Gra{\c c}a, \{Daniel S.\} and Emmanuel Hainry",

year = "2007",

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doi = "10.1016/j.jco.2006.12.005",

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T1 - Polynomial differential equations compute all real computable functions on computable compact intervals

AU - Bournez, Olivier

AU - Campagnolo, Manuel L.

AU - Graça, Daniel S.

AU - Hainry, Emmanuel

PY - 2007/1/1

Y1 - 2007/1/1

N2 - In the last decade, there have been several attempts to understand the relations between the many models of analog computation. Unfortunately, most models are not equivalent. Euler's Gamma function, which is computable according to computable analysis, but that cannot be generated by Shannon's General Purpose Analog Computer (GPAC), has often been used to argue that the GPAC is less powerful than digital computation. However, when computability with GPACs is not restricted to real-time generation of functions, it has been shown recently that Gamma becomes computable by a GPAC. Here we extend this result by showing that, in an appropriate framework, the GPAC and computable analysis are actually equivalent from the computability point of view, at least in compact intervals. Since GPACs are equivalent to systems of polynomial differential equations then we show that all real computable functions over compact intervals can be defined by such models.

AB - In the last decade, there have been several attempts to understand the relations between the many models of analog computation. Unfortunately, most models are not equivalent. Euler's Gamma function, which is computable according to computable analysis, but that cannot be generated by Shannon's General Purpose Analog Computer (GPAC), has often been used to argue that the GPAC is less powerful than digital computation. However, when computability with GPACs is not restricted to real-time generation of functions, it has been shown recently that Gamma becomes computable by a GPAC. Here we extend this result by showing that, in an appropriate framework, the GPAC and computable analysis are actually equivalent from the computability point of view, at least in compact intervals. Since GPACs are equivalent to systems of polynomial differential equations then we show that all real computable functions over compact intervals can be defined by such models.

KW - Analog computation

KW - Church-Turing thesis

KW - Computable analysis

KW - Differential equations

KW - General Purpose Analog Computer

U2 - 10.1016/j.jco.2006.12.005

DO - 10.1016/j.jco.2006.12.005

M3 - Article

AN - SCOPUS:34249708417

SN - 0885-064X

VL - 23

SP - 317

EP - 335

JO - Journal of Complexity

JF - Journal of Complexity

IS - 3

ER -

Polynomial differential equations compute all real computable functions on computable compact intervals

Abstract

Keywords

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