Recently a progress in computational imaging has been noticed with the potential to improve the capabilities of millimeter-wave imaging systems. Finally, we demonstrate a 38 GHz millimeter-wave imaging system capturing 5G communications signals from a set of independent transmitters, demonstrating the ability to image multiple objects in a scene. We discuss simple solutions to problems of increasing spatial coherence in cases where transmit resources are limited. We present a method for characterizing the imaging efficacy of communications signals in an environment based on new spatiotemporal coherence metrics. In particular, multiple millimeter-wave communications signals generate spatiotemporal incoherence, which enables Fourier-domain sampling and image formation. In contrast to traditional millimeter-wave sensing and imaging approaches, Fourier-domain image formation is improved as more incoherent signals are included in the environment. We present a millimeter-wave imaging system that captures information in the spatial frequency (Fourier) domain, similar to concepts used in radio astronomy. While most research has focused on minimizing interference between sensing and communications, we take a different approach that leverages dense communications signal environments for passive sensing applications. The spectrum of millimeter-wave frequencies is becoming increasingly crowded due to the advances in fifth generation (5G) communications and automotive radar, leading to greater interest in spectrum coexistence for functions like sensing and communications.
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