Centimeter-wave Free-space Neural Time-of-Flight Imaging

Abstract: Depth sensors have emerged as a cornerstone sensor modality with diverse applications in personal hand-held devices, robotics, scientific imaging, autonomous vehicles, and more. In particular, correlation Time-of-Flight (ToF) sensors have found widespread adoption for meter-scale indoor applications such as object tracking and pose estimation. While they offer high depth resolution at competitive costs, the precision of these indirect ToF sensors is fundamentally limited by their modulation contrast, which is … Show more

“…LiDAR is a depth-scanning technology that determines the distance by analyzing the reflected light from target objects used for autonomous vehicles, unmanned aerial vehicles, or intelligent robots. Two representative depth scanning methods have been used for LiDAR: (1) indirect 221 , 222 or direct-ToF, and (2) structured light (SL). The direct ToF technique estimates the distance by analyzing the round-trip flight time t laser of the laser pulse, and the distance is then calculated as ct laser /2, where c is the speed of light.…”

Integrated metasurfaces for re-envisioning a near-future disruptive optical platform

“…LiDAR is a depth-scanning technology that determines the distance by analyzing the reflected light from target objects used for autonomous vehicles, unmanned aerial vehicles, or intelligent robots. Two representative depth scanning methods have been used for LiDAR: (1) indirect 221 , 222 or direct-ToF, and (2) structured light (SL). The direct ToF technique estimates the distance by analyzing the round-trip flight time t laser of the laser pulse, and the distance is then calculated as ct laser /2, where c is the speed of light.…”

Integrated metasurfaces for re-envisioning a near-future disruptive optical platform

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