- Zhou, Kevin;
- Harfouche, Mark;
- Cooke, Colin;
- Park, Jaehee;
- Konda, Pavan;
- Kreiss, Lucas;
- Kim, Kanghyun;
- Jönsson, Joakim;
- Doman, Thomas;
- Reamey, Paul;
- Saliu, Veton;
- Cook, Clare;
- Zheng, Maxwell;
- Bechtel, John;
- Bègue, Aurélien;
- Bagwell, Jennifer;
- Horstmeyer, Gregor;
- Bagnat, Michel;
- Horstmeyer, Roarke;
- Mccarroll, Matthew
Wide field of view microscopy that can resolve 3D information at high speed and spatial resolution is highly desirable for studying the behaviour of freely moving model organisms. However, it is challenging to design an optical instrument that optimises all these properties simultaneously. Existing techniques typically require the acquisition of sequential image snapshots to observe large areas or measure 3D information, thus compromising on speed and throughput. Here, we present 3D-RAPID, a computational microscope based on a synchronized array of 54 cameras that can capture high-speed 3D topographic videos over an area of 135 cm2, achieving up to 230 frames per second at spatiotemporal throughputs exceeding 5 gigapixels per second. 3D-RAPID employs a 3D reconstruction algorithm that, for each synchronized snapshot, fuses all 54 images into a composite that includes a co-registered 3D height map. The self-supervised 3D reconstruction algorithm trains a neural network to map raw photometric images to 3D topography using stereo overlap redundancy and ray-propagation physics as the only supervision mechanism. The resulting reconstruction process is thus robust to generalization errors and scales to arbitrarily long videos from arbitrarily sized camera arrays. We demonstrate the broad applicability of 3D-RAPID with collections of several freely behaving organisms, including ants, fruit flies, and zebrafish larvae.