The inverted pendulum as a classical analog of the EFT paradigm

Martin Beneke; Matthias König; Martin Link

doi:10.1088/1402-4896/ad4184

The inverted pendulum as a classical analog of the EFT paradigm

Martin Beneke
, Matthias König
, Martin Link

Chair of Theoretical Elementary Particle Physics

Technical University of Munich

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

1 Scopus citations

Abstract

The inverted pendulum is a mechanical system with a rapidly oscillating pivot point. Using techniques similar in spirit to the methodology of effective field theories, we derive an effective Lagrangian that allows for the systematic computation of corrections to the so-called Kapitza equation. The derivation of the effective potential of the system requires non-trivial matching conditions, which need to be determined order by order in the power-counting of the problem. The convergence behavior of the series is investigated on the basis of high-order results obtained by this method. The results from this analysis can be used to determine the regions of parameter space, in which the inverted position of the pendulum is stable or unstable to high precision.

Original language	English
Article number	065240
Journal	Physica Scripta
Volume	99
Issue number	6
DOIs	https://doi.org/10.1088/1402-4896/ad4184
State	Published - 1 Jun 2024

Keywords

convergence behavior
effective lagrangians
inverted pendulum
power-corrections

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10.1088/1402-4896/ad4184

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abstract = "The inverted pendulum is a mechanical system with a rapidly oscillating pivot point. Using techniques similar in spirit to the methodology of effective field theories, we derive an effective Lagrangian that allows for the systematic computation of corrections to the so-called Kapitza equation. The derivation of the effective potential of the system requires non-trivial matching conditions, which need to be determined order by order in the power-counting of the problem. The convergence behavior of the series is investigated on the basis of high-order results obtained by this method. The results from this analysis can be used to determine the regions of parameter space, in which the inverted position of the pendulum is stable or unstable to high precision.",

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AU - König, Matthias

AU - Link, Martin

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N2 - The inverted pendulum is a mechanical system with a rapidly oscillating pivot point. Using techniques similar in spirit to the methodology of effective field theories, we derive an effective Lagrangian that allows for the systematic computation of corrections to the so-called Kapitza equation. The derivation of the effective potential of the system requires non-trivial matching conditions, which need to be determined order by order in the power-counting of the problem. The convergence behavior of the series is investigated on the basis of high-order results obtained by this method. The results from this analysis can be used to determine the regions of parameter space, in which the inverted position of the pendulum is stable or unstable to high precision.

AB - The inverted pendulum is a mechanical system with a rapidly oscillating pivot point. Using techniques similar in spirit to the methodology of effective field theories, we derive an effective Lagrangian that allows for the systematic computation of corrections to the so-called Kapitza equation. The derivation of the effective potential of the system requires non-trivial matching conditions, which need to be determined order by order in the power-counting of the problem. The convergence behavior of the series is investigated on the basis of high-order results obtained by this method. The results from this analysis can be used to determine the regions of parameter space, in which the inverted position of the pendulum is stable or unstable to high precision.

KW - convergence behavior

KW - effective lagrangians

KW - inverted pendulum

KW - power-corrections

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JO - Physica Scripta

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ER -

The inverted pendulum as a classical analog of the EFT paradigm

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Keywords

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