Abstract
Optical imaging through diffusive, visually-opaque barriers and around corners is an important challenge in many fields, ranging from defense to medical applications. Recently, novel techniques that combine time-of-flight (TOF) measurements with computational reconstruction have allowed breakthrough imaging and tracking of objects hidden from view. These light detection and ranging (LiDAR)-based approaches require active short-pulsed illumination and ultrafast time-resolved detection. Here, bringing notions from passive radio detection and ranging (RADAR) and passive geophysical mapping approaches, we present an optical TOF technique that allows passive localization of light sources and reflective objects through diffusive barriers and around corners. Our approach retrieves TOF information from temporal cross-correlations of scattered light, via interferometry, providing temporal resolution that surpasses state-of-the-art ultrafast detectors by three orders of magnitude. While our passive approach is limited by signal-to-noise to relatively sparse scenes, we demonstrate passive localization of multiple white-light sources and reflective objects hidden from view using a simple setup.
Highlights
Optical imaging through diffusive, visually-opaque barriers and around corners is an important challenge in many fields, ranging from defense to medical applications
While the localization resolution of our approach is superior to what is possible with ultrafast detectors, due to the passive nature of our approach and its reliance on lowcoherence interferometry, it is fundamentally limited by signalto-noise (SNR) considerations to the localization of a relatively small number of sources or reflectors, and it requires relatively long-exposure times
Consider a small light source, or a reflective object hidden behind a diffusive barrier (Fig. 1a)
Summary
Visually-opaque barriers and around corners is an important challenge in many fields, ranging from defense to medical applications. Novel techniques that combine time-of-flight (TOF) measurements with computational reconstruction have allowed breakthrough imaging and tracking of objects hidden from view These light detection and ranging (LiDAR)-based approaches require active short-pulsed illumination and ultrafast time-resolved detection. TOF-based approaches have recently allowed threedimensional (3D) tracking and reconstruction of macroscopic scenes hidden from view[9,13,15,16] These approaches utilize the principle of light detection and ranging (LiDAR) to obtain 3D spatial information from temporal measurements of reflected light that experienced several reflections (bounces). Short-pulsed illumination is not a fundamental requirement: it is possible to obtain high-resolution temporal information from temporal cross-correlations of ambient broadband noise, without any active or controlled source This principle is put to use in helioseismology[23], ultrasound[24], geophysics[25], passive RADAR26, and recently in optical studies of complex media[27]. We present localization results obtained through highly scattering diffusers, having a scattering angle of 80°, and using light scattered off a whitepainted surface, using a simple, completely passive setup
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