Journal of Big Data (May 2024)

Computational 3D topographic microscopy from terabytes of data per sample

  • Kevin C. Zhou,
  • Mark Harfouche,
  • Maxwell Zheng,
  • Joakim Jönsson,
  • Kyung Chul Lee,
  • Kanghyun Kim,
  • Ron Appel,
  • Paul Reamey,
  • Thomas Doman,
  • Veton Saliu,
  • Gregor Horstmeyer,
  • Seung Ah Lee,
  • Roarke Horstmeyer

DOI
https://doi.org/10.1186/s40537-024-00901-0
Journal volume & issue
Vol. 11, no. 1
pp. 1 – 17

Abstract

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Abstract We present a large-scale computational 3D topographic microscope that enables 6-gigapixel profilometric 3D imaging at micron-scale resolution across >110 cm2 areas over multi-millimeter axial ranges. Our computational microscope, termed STARCAM (Scanning Topographic All-in-focus Reconstruction with a Computational Array Microscope), features a parallelized, 54-camera architecture with 3-axis translation to capture, for each sample of interest, a multi-dimensional, 2.1-terabyte (TB) dataset, consisting of a total of 224,640 9.4-megapixel images. We developed a self-supervised neural network-based algorithm for 3D reconstruction and stitching that jointly estimates an all-in-focus photometric composite and 3D height map across the entire field of view, using multi-view stereo information and image sharpness as a focal metric. The memory-efficient, compressed differentiable representation offered by the neural network effectively enables joint participation of the entire multi-TB dataset during the reconstruction process. Validation experiments on gauge blocks demonstrate a profilometric precision and accuracy of 10 µm or better. To demonstrate the broad utility of our new computational microscope, we applied STARCAM to a variety of decimeter-scale objects, with applications ranging from cultural heritage to industrial inspection.

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