Johannes H. Jensen scite author profile

Artificial spin ice (ASI) are systems of coupled nanomagnets arranged on a 2D lattice. ASIs are promising computing substrates due to the rich variety of emergent behavior, accompanied by considerable control and flexibility. Computational models may exploit the small-scale dynamics of the individual elements, or large-scale emergent behavior of the resulting metamaterial. We investigate the computational capabilities of "pinwheel" ASI, whose emergent ferromagnetic patterns can be observed at different scales. Within a reservoir computing framework, we examine how key system parameters affect performance using well-established reservoir quality metrics. As reservoir output, we consider system state at different granularities, ranging from individual magnets to the collective state of multiple magnets. Our results show that pinwheel ASI exhibits excellent computing capacity, including evidence of fading memory. Interestingly, a wide range of output granularities result in good performance, offering new insights into the scalability and robustness of reservoirs based on self-organized collective behavior. The apparent flexibility in output granularity show that ASIs have computational properties at different abstraction levels, from the small-scale dynamics of simple elements, to the large-scale spatial patterns of the metamaterial.

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Reservoir computing with a chaotic circuit

Jensen¹,

Tufte²

2017

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Reservoir Computing has been highlighted as a promising methodology to perform computation in dynamical systems. This makes Reservoir Computing particularly interesting for exploiting physical systems directly as computing substrates, where the computation happens "for free" in the rich physical domain. In this work we consider a simple chaotic circuit as a reservoir: the Driven Chua's circuit. Its rich variety of available dynamics makes it versatile as a reservoir. At the same time, its simplicity offers insight into what physical properties can be useful for computation. We demonstrate both through simulation and in-circuit experiments, that such a simple circuit can be readily exploited for computation. Our results show excellent performance on two non-temporal tasks. The fact that such a simple nonlinear circuit can be used, suggests that a wide variety of physical systems can be viewed as potential reservoirs.

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Experimental and computational study of N-methylacetamide

Jensen¹,

Christiansen²,

Skovgaard³

et al. 1986

Physics Letters A

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Chaos in the Beeler-Reuter system for the action potential of ventricular myocardial fibres

Jensen¹,

Christiansen²,

Scott³

et al. 1984

Physica D: Nonlinear Phenomena

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