Abstract
Interest in autonomous transport has led to a demand for 3D imaging technologies capable of resolving fine details at long range. Light detection and ranging (LiDAR) systems have become a key technology in this area, with depth information typically gained through time-of-flight photon-counting measurements of a scanned laser spot. Single-pixel imaging methods offer an alternative approach to spot-scanning, which allows a choice of sampling basis. In this work, we present a prototype LiDAR system, which compressively samples the scene using a deep learning optimized sampling basis and reconstruction algorithms. We demonstrate that this approach improves scene reconstruction quality compared to an orthogonal sampling method, with reflectivity and depth accuracy improvements of 57% and 16%, respectively, for one frame per second acquisition rates. This method may pave the way for improved scan-free LiDAR systems for driverless cars and for fully optimized sampling to decision-making pipelines.
Highlights
To obtain millimetric precision for Light detection and ranging (LiDAR), subnanosecond temporal resolutions are required, ruling out the use of conventional cameras
Light detection and ranging (LiDAR) systems have become a key technology in this area, with depth information typically gained through time-offlight photon-counting measurements of a scanned laser spot
Typical LiDAR systems are currently more usually based on spot-scanning techniques, requiring mechanical scanning systems with a reconstruction resolution and acquisition rates limited by scan speed
Summary
To obtain millimetric precision for LiDAR, subnanosecond temporal resolutions are required, ruling out the use of conventional cameras. Light detection and ranging (LiDAR) systems have become a key technology in this area, with depth information typically gained through time-offlight photon-counting measurements of a scanned laser spot.
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