Elementary derivation of the dissipation-coherence bound for stochastic oscillators
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The dissipation-coherence bound is a conjectured tradeoff between entropy production and the quality of stochastic oscillations. We show that this bound can be derived by combining the higher-order ``thermodynamic uncertainty relation'' with a simple condition on phase-current fluctuations. In one-dimensional cyclic systems, our proposed condition is shown to be equivalent to the dissipation-coherence bound itself. Our approach yields an elementary proof in the weak-noise Gaussian regime and extends naturally to some non-Gaussian systems, as we illustrate with a run-and-tumble particle. Finally, we contrast current-based and spectral formulations of the dissipation-coherence bound.
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Cited by 2 Pith papers
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Oscillatory-nonnormal decomposition of dissipation in Ornstein-Uhlenbeck processes
Decomposition of entropy production in OU processes into oscillatory and nonnormal parts, each associated with a fundamental trade-off demonstrated on a bead-spring model.
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Oscillatory-nonnormal decomposition of dissipation in Ornstein-Uhlenbeck processes
Decomposes entropy production in OU processes into oscillatory and nonnormal parts with associated trade-offs, demonstrated on a bead-spring model.
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