A Machine Learning and Computer Vision Approach to Rapidly Optimize Multiscale Droplet Generation.

Generating droplets from a continuous stream of fluid requires precise tuning of a device to find optimized control parameter conditions. It is analytically intractable to compute the necessary control parameter values of a droplet-generating device that produces optimized droplets. Furthermore, as the length scale of the fluid flow changes, the formation physics and optimized conditions that induce flow decomposition into droplets also change. Hence, a single proportional integral derivative controller is too inflexible to optimize devices of different length scales or different control parameters, while classification machine learning techniques take days to train and require millions of droplet images. Therefore, the question is posed, can a single method be created that universally optimizes multiple length-scale droplets using only a few data points and is faster than previous approaches? In this paper, a Bayesian optimization and computer vision feedback loop is designed to quickly and reliably discover the control parameter values that generate optimized droplets within different length-scale devices. This method is demonstrated to converge on optimum parameter values using 60 images in only 2.3 h, 30× faster than previous approaches. Model implementation is demonstrated for two different length-scale devices: a milliscale inkjet device and a microfluidics device.

[1]  Ruipeng Li,et al.  A data fusion approach to optimize compositional stability of halide perovskites , 2021, Matter.

[2]  Smadar Cohen,et al.  High throughput microfluidic system with multiple oxygen levels for the study of hypoxia in tumor spheroids , 2021, Biofabrication.

[3]  D. Densmore,et al.  Machine learning enables design automation of microfluidic flow-focusing droplet generation , 2021, Nature Communications.

[4]  Qianxiao Li,et al.  Machine Learning and High-Throughput Robust Design of P3HT-CNT Composite Thin Films for High Electrical Conductivity , 2020, 2011.10382.

[5]  Collin B Eaker,et al.  Overcoming Rayleigh–Plateau instabilities: Stabilizing and destabilizing liquid-metal streams via electrochemical oxidation , 2020, Proceedings of the National Academy of Sciences.

[6]  Mohamed Gibril Bah,et al.  Fabrication and application of complex microcapsules: a review. , 2019, Soft matter.

[7]  A. deMello,et al.  Recent Advances in Droplet Microfluidics. , 2019, Analytical chemistry.

[8]  W. Ohnesorge The formation of drops by nozzles and the breakup of liquid jets , 2019 .

[9]  V. Gnyawali,et al.  Microneedle-assisted microfluidic flow focusing for versatile and high throughput water-in-water droplet generation. , 2019, Journal of colloid and interface science.

[10]  Alán Aspuru-Guzik,et al.  Beyond Ternary OPV: High‐Throughput Experimentation and Self‐Driving Laboratories Optimize Multicomponent Systems , 2019, Advanced materials.

[11]  Alan D. Kaplan,et al.  Image classification and control of microfluidic systems , 2019, Optical Engineering + Applications.

[12]  Qianxiao Li,et al.  Embedding physics domain knowledge into a Bayesian network enables layer-by-layer process innovation for photovoltaics , 2019, npj Computational Materials.

[13]  Brian L. DeCost,et al.  Accelerated Development of Perovskite-Inspired Materials via High-Throughput Synthesis and Machine-Learning Diagnosis , 2018, Joule.

[14]  Alexandre Pouget,et al.  Learning optimal decisions with confidence , 2018, Proceedings of the National Academy of Sciences.

[15]  E. Leclerc,et al.  Water-in-oil droplet formation in a flow-focusing microsystem using pressure- and flow rate-driven pumps , 2017 .

[16]  Tuncay Alan,et al.  Droplet control technologies for microfluidic high throughput screening (μHTS). , 2017, Lab on a chip.

[17]  O. B. Usta,et al.  Generation and manipulation of hydrogel microcapsules by droplet-based microfluidics for mammalian cell culture. , 2017, Lab on a chip.

[18]  Yuanjin Zhao,et al.  Emerging Droplet Microfluidics. , 2017, Chemical reviews.

[19]  M. Loewenberg,et al.  Soft microcapsules with highly plastic shells formed by interfacial polyelectrolyte-nanoparticle complexation. , 2015, Soft matter.

[20]  Leon A. Gatys,et al.  A Neural Algorithm of Artistic Style , 2015, ArXiv.

[21]  Gareth H. McKinley,et al.  Wolfgang von Ohnesorge , 2011 .

[22]  Philipp Hennig,et al.  Entropy Search for Information-Efficient Global Optimization , 2011, J. Mach. Learn. Res..

[23]  Brian Derby,et al.  Inkjet printing ceramics: from drops to solid , 2011 .

[24]  F. Mugele,et al.  Droplets Formation and Merging in Two-Phase Flow Microfluidics , 2011, International journal of molecular sciences.

[25]  Xia Sheng,et al.  Bayesian design of synthetic biological systems , 2011, Proceedings of the National Academy of Sciences.

[26]  Nando de Freitas,et al.  A Tutorial on Bayesian Optimization of Expensive Cost Functions, with Application to Active User Modeling and Hierarchical Reinforcement Learning , 2010, ArXiv.

[27]  Charles N Baroud,et al.  Dynamics of microfluidic droplets. , 2010, Lab on a chip.

[28]  B. Derby Inkjet Printing of Functional and Structural Materials: Fluid Property Requirements, Feature Stability, and Resolution , 2010 .

[29]  Mario Rotea,et al.  Microfluidic device incorporating closed loop feedback control for uniform and tunable production of micro-droplets. , 2010, Lab on a chip.

[30]  Y. Liang,et al.  Control of Droplet Formation in Inkjet Printing Using Ohnesorge Number Category: Materials and Processes , 2008, 2008 10th Electronics Packaging Technology Conference.

[31]  T. Cubaud,et al.  Capillary threads and viscous droplets in square microchannels , 2008 .

[32]  E. Villermaux,et al.  Physics of liquid jets , 2008 .

[33]  D. Weitz,et al.  Dripping to jetting transitions in coflowing liquid streams. , 2007, Physical review letters.

[34]  William Graebel,et al.  Advanced Fluid Mechanics , 2007 .

[35]  Hans C. Mayer,et al.  Microscale tipstreaming in a microfluidic flow focusing device , 2006 .

[36]  G. Whitesides,et al.  Mechanism for flow-rate controlled breakup in confined geometries: a route to monodisperse emulsions. , 2005, Physical review letters.

[37]  M. D. McKay,et al.  A Comparison of Three Methods for Selecting Values of Input Variables in the Analysis of Output From a Computer Code , 2000, Technometrics.

[38]  Christophe Clanet,et al.  Transition from dripping to jetting , 1999, Journal of Fluid Mechanics.

[39]  M. Hasselmo,et al.  Gaussian Processes for Regression , 1995, NIPS.

[40]  D. Papageorgiou ON THE BREAKUP OF VISCOUS LIQUID THREADS , 1995 .