#import "@preview/bloated-neurips:0.5.1": ( botrule, midrule, neurips2024, paragraph, toprule, url, ) #import "./logo.typ": LaTeX, LaTeXe, TeX #let affls = ( ucsb: ( // department: "AI Center", institution: "University of California, Santa Barbara", country: "United States", ), ) #let authors = ( ( name: "Youwen Wu", affl: "ucsb", email: "youwen@ucsb.edu", equal: true, ), ) #show: neurips2024.with( title: [Towards More Accessible Scientific Infrastructure: A Neural Vision Pipeline to Interface with Experiments], authors: (authors, affls), keywords: ("Machine Learning", "NeurIPS"), abstract: [ Scientific instruments are often designed to be operated by humans. As such, they are outfitted with analog dials and controls which are difficult for machines to understand. In order to ameliorate the inaccessibility of experimental equipment in fundamental disciplines such as quantum physics, we seek a systematic approach to processing existing _analog systems_ into _digital data_ without invasively augmenting them with sensors. In this paper, we explore the state of the art in computer vision and their applications in analyzing experimental instruments through a purely vision based approach. We train a convolutional neural network to triangulate visual fiducials and construct a pipeline to apply perspective warp based corrections to normalize images of measurements. We end by designing _Dendrite_, an end-to-end vision pipeline that can obtain detailed digital readings from a video stream of an analog instrument. ], bibliography: bibliography("main.bib"), bibliography-opts: (title: none, full: true), // Only for example paper. appendix: [ #include "appendix.typ" #include "checklist.typ" ], accepted: true, ) = Introduction The rise of online resources in scientific pedagogy has become increasingly prevalent. Around the world, students use virtual labs that simulate physical phenomena. However, still lacking is the accessibility of real world hardware to obtain real results. Experimental instruments are expensive and difficult to justify for many schools and institutions. One solution to this problem is to provide shared equipment that is accessible and controlled over the internet. This allows equipment located in a single place to be used from anywhere in the world. One way to build these systems is to augment existing devices with the capability to be controlled over the internet. However, many scientific instruments are designed with human operation in mind and contain many analog dials, readouts, and controls. We seek a way to non-invasively digitize these devices. Here non-invasively means that we should not perform any irreversible or drastic changes to the hardware. Digitize refers to obtaining all relevant outputs as digital data that can be processed by computers, and being able to operate relevant controls over digital protocols (such as the internet). In this paper, we focus primarily on obtaining the outputs. We propose a system which uses an end-to-end vision pipeline that can scan readouts and translate them into data. Then, the data can be streamed to virtual simulations which will react exactly as the real life equipment does. == Requirements Our end-to-end pipeline will consist of a component to locate the desired instrument in the image and determine the corrections needed to transform the image into a point of view where it is directly visible. This may be a neural network based model that identifies a key fiducial from which we can extrapolate the perspective transforms needed to bring the image to a normalized state (here normalized refers to a flattened 2D image that can be easily analyzed by computer vision). We then extrapolate from that data to map out all of the various points of interest. From that point, we can run specialized models on readouts such as dials to determine their readings. = The state of the art We first