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Bibliographic Details
Main Authors: Burzyński, Tomasz, Brzeski, Piotr, Perlikowski, Przemysław
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2502.10461
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author Burzyński, Tomasz
Brzeski, Piotr
Perlikowski, Przemysław
author_facet Burzyński, Tomasz
Brzeski, Piotr
Perlikowski, Przemysław
contents This study explores the impact of parameter mismatch on the stability of cross-well motion in energy harvesters, using a basin stability metric. Energy harvesters, essential for converting ambient energy into electricity, increasingly incorporate multi-well systems to enhance efficiency. However, these systems are sensitive to initial conditions and parameter variations, which can affect their ability to sustain optimal cross-well motion -- a state associated with maximum power output. Our analysis compared four harvester types under varying levels of parameter mismatch, assessing resilience of the devices to parameter variations. By identifying safe operating ranges within the excitation parameter space, this study provides practical guidance for designing robust, stable harvesters capable of maintaining cross-well motion despite parameter uncertainties. These insights contribute to advancing the reliability of energy harvesting devices in real-world applications where parameter mismatches are inevitable.
format Preprint
id arxiv_https___arxiv_org_abs_2502_10461
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Performance of energy harvesters with parameter mismatch
Burzyński, Tomasz
Brzeski, Piotr
Perlikowski, Przemysław
Systems and Control
This study explores the impact of parameter mismatch on the stability of cross-well motion in energy harvesters, using a basin stability metric. Energy harvesters, essential for converting ambient energy into electricity, increasingly incorporate multi-well systems to enhance efficiency. However, these systems are sensitive to initial conditions and parameter variations, which can affect their ability to sustain optimal cross-well motion -- a state associated with maximum power output. Our analysis compared four harvester types under varying levels of parameter mismatch, assessing resilience of the devices to parameter variations. By identifying safe operating ranges within the excitation parameter space, this study provides practical guidance for designing robust, stable harvesters capable of maintaining cross-well motion despite parameter uncertainties. These insights contribute to advancing the reliability of energy harvesting devices in real-world applications where parameter mismatches are inevitable.
title Performance of energy harvesters with parameter mismatch
topic Systems and Control
url https://arxiv.org/abs/2502.10461