Remote recovery of audio signals from videos of optical speckle patterns: a comparative study of signal recovery algorithms.

Optical remote sensors are nowadays ubiquitously used, thanks to unprecedented advances in the last decade in photonics, machine learning and signal processing tools. In this work we study experimentally the remote recovery of audio signals from the silent videos of the movement of optical speckle patterns. This technique can be used even when in between the source and the receiver there is a medium that does not allow for the propagation of sound waves. We use a diode laser to generate a speckle pattern on the membrane of a loudspeaker and a low-cost CCD camera to record the video of the movement of the speckle pattern when the loudspeaker plays an audio signal. We perform a comparative analysis of six signal recovery algorithms. In spite of having different complexity and computational requirements, we find that the algorithms have (except for the simplest one) good performance in terms of the quality of the recovered signal. The best trade-off, in terms of computational costs and performance, is obtained with a new method that we propose, which recovers the signal from the weighted sum of the intensities of all the pixels, where the signs of the weights are determined by selecting a reference pixel and calculating the signs of the cross-correlations of the intensity of the reference pixel and the intensities of the other pixels.

[1]  J. Goodman Speckle Phenomena in Optics: Theory and Applications , 2020 .

[2]  Luis Rodriguez-Cobo,et al.  Fiber Specklegram-Multiplexed Sensor , 2015, Journal of Lightwave Technology.

[3]  Bosoon Park,et al.  Rapid and early detection of Salmonella serotypes with hyperspectral microscopy and multivariate data analysis. , 2015, Journal of food protection.

[4]  Frédo Durand,et al.  The visual microphone , 2014, ACM Trans. Graph..

[5]  C Velez Superluminescent LEDs bridge the gap , 2017 .

[6]  V. Klemas,et al.  Fisheries applications of remote sensing: An overview , 2013 .

[7]  Edward H. Adelson,et al.  Shiftable multiscale transforms , 1992, IEEE Trans. Inf. Theory.

[8]  M. Lomer,et al.  Non-contact vibration analysis using speckle-based techniques , 2017, 2017 25th Optical Fiber Sensors Conference (OFS).

[9]  Eero P. Simoncelli,et al.  A Parametric Texture Model Based on Joint Statistics of Complex Wavelet Coefficients , 2000, International Journal of Computer Vision.

[10]  Rosa Lasaponara,et al.  Medieval Archaeology Under the Canopy with LiDAR. The (Re)Discovery of a Medieval Fortified Settlement in Southern Italy , 2018, Remote. Sens..

[11]  Yongxiang Hu,et al.  Spaceborne Lidar in the Study of Marine Systems. , 2018, Annual review of marine science.

[12]  Robert M. Banta,et al.  Doppler Lidar–Based Wind-Profile Measurement System for Offshore Wind-Energy and Other Marine Boundary Layer Applications , 2012 .

[13]  Brian Wyvill,et al.  Robust iso-surface tracking for interactive character skinning , 2014, ACM Trans. Graph..

[14]  Carlo Famoso,et al.  Multi-jump resonance systems , 2018, Int. J. Control.

[15]  LAUS,et al.  Surface-based remote sensing of the mixing-layer height – a review , 2008 .

[16]  Huadong Guo,et al.  Earth observation satellite sensors for biodiversity monitoring: potentials and bottlenecks , 2014 .

[17]  J. Tenenbaum,et al.  A global geometric framework for nonlinear dimensionality reduction. , 2000, Science.

[18]  Zeev Zalevsky,et al.  Simultaneous remote extraction of multiple speech sources and heart beats from secondary speckles pattern. , 2009, Optics express.