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Exploring Benchmarks for Self-Driving Labs using Color Matching

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arxiv 2310.00510 v1 pith:IYT37IXU submitted 2023-09-30 cs.RO

Exploring Benchmarks for Self-Driving Labs using Color Matching

classification cs.RO
keywords colormatchingautonomousanalysisexperimentlabsproblemrobotic
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Self Driving Labs (SDLs) that combine automation of experimental procedures with autonomous decision making are gaining popularity as a means of increasing the throughput of scientific workflows. The task of identifying quantities of supplied colored pigments that match a target color, the color matching problem, provides a simple and flexible SDL test case, as it requires experiment proposal, sample creation, and sample analysis, three common components in autonomous discovery applications. We present a robotic solution to the color matching problem that allows for fully autonomous execution of a color matching protocol. Our solution leverages the WEI science factory platform to enable portability across different robotic hardware, the use of alternative optimization methods for continuous refinement, and automated publication of results for experiment tracking and post-hoc analysis.

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  1. Building an Affordable Self-Driving Lab: Practical Machine Learning Experiments for Physics Education Using Internet-of-Things

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    An affordable Arduino-based IoT setup generates real-time optical data for students to compare traversal, Bayesian, and deep learning methods in a self-driving experimental workflow.