Algorithms yield upper bounds in differential algebra

Wei Li; Alexey Ovchinnikov; Gleb Pogudin; Thomas Scanlon

doi:10.4153/S0008414X21000560

Algorithms yield upper bounds in differential algebra

Wei Li
, Alexey Ovchinnikov
, Gleb Pogudin
, Thomas Scanlon

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

Abstract

Consider an algorithm computing in a differential field with several commuting derivations such that the only operations it performs with the elements of the field are arithmetic operations, differentiation, and zero testing. We show that, if the algorithm is guaranteed to terminate on every input, then there is a computable upper bound for the size of the output of the algorithm in terms of the size of the input. We also generalize this to algorithms working with models of good enough theories (including, for example, difference fields). We then apply this to differential algebraic geometry to show that there exists a computable uniform upper bound for the number of components of any variety defined by a system of polynomial PDEs. We then use this bound to show the existence of a computable uniform upper bound for the elimination problem in systems of polynomial PDEs with delays.

Original language	English
Pages (from-to)	29-51
Number of pages	23
Journal	Canadian Journal of Mathematics
Volume	75
Issue number	1
DOIs	https://doi.org/10.4153/S0008414X21000560
Publication status	Published - 1 Feb 2023

Keywords

delay PDEs
elimination of unknowns
oracle machine
uniform bounds

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10.4153/S0008414X21000560

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AU - Ovchinnikov, Alexey

AU - Pogudin, Gleb

AU - Scanlon, Thomas

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N2 - Consider an algorithm computing in a differential field with several commuting derivations such that the only operations it performs with the elements of the field are arithmetic operations, differentiation, and zero testing. We show that, if the algorithm is guaranteed to terminate on every input, then there is a computable upper bound for the size of the output of the algorithm in terms of the size of the input. We also generalize this to algorithms working with models of good enough theories (including, for example, difference fields). We then apply this to differential algebraic geometry to show that there exists a computable uniform upper bound for the number of components of any variety defined by a system of polynomial PDEs. We then use this bound to show the existence of a computable uniform upper bound for the elimination problem in systems of polynomial PDEs with delays.

AB - Consider an algorithm computing in a differential field with several commuting derivations such that the only operations it performs with the elements of the field are arithmetic operations, differentiation, and zero testing. We show that, if the algorithm is guaranteed to terminate on every input, then there is a computable upper bound for the size of the output of the algorithm in terms of the size of the input. We also generalize this to algorithms working with models of good enough theories (including, for example, difference fields). We then apply this to differential algebraic geometry to show that there exists a computable uniform upper bound for the number of components of any variety defined by a system of polynomial PDEs. We then use this bound to show the existence of a computable uniform upper bound for the elimination problem in systems of polynomial PDEs with delays.

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KW - oracle machine

KW - uniform bounds

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JO - Canadian Journal of Mathematics

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Algorithms yield upper bounds in differential algebra

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Keywords

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