2021
DOI: 10.1101/2021.09.01.458583
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Wide-Angle, Monocular Head Tracking using Passive Markers

Abstract: Camera images can encode large amounts of visual information of an animal and its environment, enabling high fidelity 3D reconstruction of the animal and its environment using computer vision methods. Most systems, both markerless (e.g. deep learning based) and marker-based, require multiple cameras to track features across multiple points of view to enable such 3D reconstruction. However, such systems can be expensive and are challenging to set up in small animal research apparatuses. We present an open-sourc… Show more

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Cited by 2 publications
(5 citation statements)
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“…For experimental sessions, instead of the single large marker attached to the body harness, a set of smaller (3mm, 4 mm) markers were placed in a rigid arrangement around the recording headstage. This allowed our custom algorithm to track the 3D position and orientation of the constellation of markers with higher accuracy and robustness 49 . Thus, the rat did not need to wear the harness during sessions.…”
Section: Methodsmentioning
confidence: 99%
See 1 more Smart Citation
“…For experimental sessions, instead of the single large marker attached to the body harness, a set of smaller (3mm, 4 mm) markers were placed in a rigid arrangement around the recording headstage. This allowed our custom algorithm to track the 3D position and orientation of the constellation of markers with higher accuracy and robustness 49 . Thus, the rat did not need to wear the harness during sessions.…”
Section: Methodsmentioning
confidence: 99%
“…A near-infrared camera (GS3-U3-41C6NIR-C, FLIR, OR, USA; 2048x2048 px, 45 fps) with a wide-field lens (NMV-6M1, 6mm, F1.8, Navitar, NY, USA) provided an overhead view of the experiment. The 3D position and orientation of the head of the rat were detected in real-time (45 fps) through single-camera tracking 49 of a set of markers mounted on the rat's neural recording implant. The central rotating pillar of the dome was mounted on bearings.…”
Section: Dome Apparatusmentioning
confidence: 99%
“…In order to prevent this, we hide the camera from the rat by placing it behind the ‘brim’ of the top hat. In the Current version, we track the head position of the rat in real-time using the camera [ 24 ]. To enable this, the neural recording headstage attached to the head of the rat supports a lightweight three-dimensional pattern of retro-reflective markers (the ‘crown’).…”
Section: Design Overview and Subsystemsmentioning
confidence: 99%
“…Arbitrary shapes can be displayed through OpenGL at high frame rates by the use of pre-compiled display lists. Computer 3 (Ubuntu 18.04) receives the camera signal through a USB3.0 interface and runs a custom-developed ROS node that tracks the position and orientation of the animal’s head [ 24 ]. In addition, it also records high-resolution video at full frame rate (45–90 fps) for post-experiment processing.…”
Section: Design Overview and Subsystemsmentioning
confidence: 99%
See 1 more Smart Citation