Compressive Time-of-Flight 3D Imaging Using Block-Structured Sensing Matrices
Abstract
Spatially and temporally highly resolved depth information enables numerous applications including human-machine interaction in gaming or safety functions in the automotive industry. In this paper, we address this issue using Time-of-flight (ToF) 3D cameras which are compact devices providing highly resolved depth information. Practical restrictions often require to reduce the amount of data to be read-out and transmitted. Using standard ToF cameras, this can only be achieved by lowering the spatial or temporal resolution. To overcome such a limitation, we propose a compressive ToF camera design using block-structured sensing matrices that allows to reduce the amount of data while keeping high spatial and temporal resolution. We propose the use of efficient reconstruction algorithms based on l^1-minimization and TV-regularization. The reconstruction methods are applied to data captured by a real ToF camera system and evaluated in terms of reconstruction quality and computational effort. For both, l^1-minimization and TV-regularization, we use a local as well as a global reconstruction strategy. For all considered instances, global TV-regularization turns out to clearly perform best in terms of evaluation metrics including the PSNR.
Cite
@article{arxiv.1710.10444,
title = {Compressive Time-of-Flight 3D Imaging Using Block-Structured Sensing Matrices},
author = {Stephan Antholzer and Christoph Wolf and Michael Sandbichler and Markus Dielacher and Markus Haltmeier},
journal= {arXiv preprint arXiv:1710.10444},
year = {2018}
}
Comments
According to a suggestion, we changed the old title "A Framework for Compressive Time-of-Flight 3D Sensing" to "Compressive Time-of-Flight 3D Imaging Using Block-Structured Sensing Matrices"