English

Insect-Wing Structured Microfluidic System for Reservoir Computing

Neural and Evolutionary Computing 2025-08-18 v1 Emerging Technologies Machine Learning

Abstract

As the demand for more efficient and adaptive computing grows, nature-inspired architectures offer promising alternatives to conventional electronic designs. Microfluidic platforms, drawing on biological forms and fluid dynamics, present a compelling foundation for low-power, high-resilience computing in environments where electronics are unsuitable. This study explores a hybrid reservoir computing system based on a dragonfly-wing inspired microfluidic chip, which encodes temporal input patterns as fluid interactions within the micro channel network. The system operates with three dye-based inlet channels and three camera-monitored detection areas, transforming discrete spatial patterns into dynamic color output signals. These reservoir output signals are then modified and passed to a simple and trainable readout layer for pattern classification. Using a combination of raw reservoir outputs and synthetically generated outputs, we evaluated system performance, system clarity, and data efficiency. The results demonstrate consistent classification accuracies up to 91%91\%, even with coarse resolution and limited training data, highlighting the viability of the microfluidic reservoir computing.

Keywords

Cite

@article{arxiv.2508.10915,
  title  = {Insect-Wing Structured Microfluidic System for Reservoir Computing},
  author = {Jacob Clouse and Thomas Ramsey and Samitha Somathilaka and Nicholas Kleinsasser and Sangjin Ryu and Sasitharan Balasubramaniam},
  journal= {arXiv preprint arXiv:2508.10915},
  year   = {2025}
}
R2 v1 2026-07-01T04:50:28.195Z