English

XR-RF Imaging Enabled by Software-Defined Metasurfaces and Machine Learning: Foundational Vision, Technologies and Challenges

Signal Processing 2022-11-09 v1 Emerging Technologies Image and Video Processing

Abstract

We present a new approach to Extended Reality (XR), denoted as iCOPYWAVES, which seeks to offer naturally low-latency operation and cost-effectiveness, overcoming the critical scalability issues faced by existing solutions. iCOPYWAVES is enabled by emerging PWEs, a recently proposed technology in wireless communications. Empowered by intelligent (meta)surfaces, PWEs transform the wave propagation phenomenon into a software-defined process. We leverage PWEs to i) create, and then ii) selectively copy the scattered RF wavefront of an object from one location in space to another, where a machine learning module, accelerated by FPGAs, translates it to visual input for an XR headset using PWEdriven, RF imaging principles (XR-RF). This makes for an XR system whose operation is bounded in the physical layer and, hence, has the prospects for minimal end-to-end latency. Over large distances, RF-to-fiber/fiber-to-RF is employed to provide intermediate connectivity. The paper provides a tutorial on the iCOPYWAVES system architecture and workflow. A proof-of-concept implementation via simulations is provided, demonstrating the reconstruction of challenging objects in iCOPYWAVES produced computer graphics.

Keywords

Cite

@article{arxiv.2209.15436,
  title  = {XR-RF Imaging Enabled by Software-Defined Metasurfaces and Machine Learning: Foundational Vision, Technologies and Challenges},
  author = {C. Liaskos and A. Tsioliaridou and K. Georgopoulos and G. Morianos and S. Ioannidis and I. Salem and D. Manessis and S. Schmid D. Tyrovolas and S. A. Tegos and P. -V. Mekikis and P. D. Diamantoulakis and A. Pitilakis and N. Kantartzis and G. K. Karagiannidis A. Tasolamprou and O. Tsilipakos and M. Kafesaki and I. F. Akyildiz and A. Pitsillides and M. Pateraki and M. Vakalellis and I. Spais},
  journal= {arXiv preprint arXiv:2209.15436},
  year   = {2022}
}
R2 v1 2026-06-28T02:27:20.768Z