English

Limits to Energy Conversion

Optimization and Control 2020-06-30 v1

Abstract

A consequence of the Second Law of thermodynamics is that no thermodynamic system with a single heat source at constant temperature can convert heat into mechanical work in a recurrent manner. First we note that this is equivalent to cyclo-passivity at the mechanical port of the thermodynamic system, while the temperature at the thermal port of the system is kept constant. This leads to the general system-theoretic question which systems with two power ports have similar behavior: when is a system cyclo-passive at one of its ports, while the output variable at the other port (such as the temperature in the thermodynamic case) is kept constant? This property is called `one-port cyclo-passivity', and entails, whenever it holds, a fundamental limitation to energy transfer from one port (where the output is kept constant) to the other port. Sufficient conditions for one-port cyclo-passivity are derived for systems formulated in general port-Hamiltonian form. This is illustrated by a variety of examples from different {(multi-)}physical domains; from coupled inductors and capacitor microphones to synchronous machines.

Cite

@article{arxiv.2006.15953,
  title  = {Limits to Energy Conversion},
  author = {Arjan van der Schaft and Dimitri Jeltsema},
  journal= {arXiv preprint arXiv:2006.15953},
  year   = {2020}
}

Comments

11 pages, 7 figures

R2 v1 2026-06-23T16:41:46.494Z