Autonomous Optimization of Fluid Systems at Varying Length Scales
- URL: http://arxiv.org/abs/2105.13553v1
- Date: Fri, 28 May 2021 02:08:03 GMT
- Title: Autonomous Optimization of Fluid Systems at Varying Length Scales
- Authors: Alexander E. Siemenn, Evyatar Shaulsky, Matthew Beveridge, Tonio
Buonassisi, Sara M. Hashmi, Iddo Drori
- Abstract summary: We propose a computer vision-driven Bayesian optimization framework to discover the precise hardware conditions that generate uniform droplets.
This framework is validated on two fluid systems, at the micrometer and millimeter length scales, using microfluidic and inkjet systems.
- Score: 55.41644538483948
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Autonomous optimization is a process by which hardware conditions are
discovered that generate an optimized experimental product without the guidance
of a domain expert. We design an autonomous optimization framework to discover
the experimental conditions within fluid systems that generate discrete and
uniform droplet patterns. Generating discrete and uniform droplets requires
high-precision control over the experimental conditions of a fluid system.
Fluid stream instabilities, such as Rayleigh-Plateau instability and capillary
instability, drive the separation of a flow into individual droplets. However,
because this phenomenon leverages an instability, by nature the hardware must
be precisely tuned to achieve uniform, repeatable droplets. Typically this
requires a domain expert in the loop and constant re-tuning depending on the
hardware configuration and liquid precursor selection. Herein, we propose a
computer vision-driven Bayesian optimization framework to discover the precise
hardware conditions that generate uniform, reproducible droplets with the
desired features, leveraging flow instability without a domain expert in the
loop. This framework is validated on two fluid systems, at the micrometer and
millimeter length scales, using microfluidic and inkjet systems, respectively,
indicating the application breadth of this approach.
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