Abstract
Optical time-reversal techniques are being actively developed to focus light through or inside opaque scattering media. When applied to biological tissue, these techniques promise to revolutionize biophotonics by enabling deep-tissue non-invasive optical imaging, optogenetics, optical tweezing, and phototherapy. In all previous optical time-reversal experiments, the scattered light field was well-sampled during wavefront measurement and wavefront reconstruction, following the Nyquist sampling criterion. Here, we overturn this conventional practice by demonstrating that even when the scattered field is under-sampled, light can still be focused through or inside scattering media. Even more surprisingly, we show both theoretically and experimentally that the focus achieved by under-sampling can be one order of magnitude brighter than that achieved under the well-sampling conditions used in previous works, where 3×3 to 5×5 pixels were used to sample one speckle grain on average. Moreover, sub-Nyquist sampling improves the signal-to-noise ratio and the collection efficiency of the scattered light. We anticipate that this newly explored under-sampling scheme will transform the understanding of optical time reversal and boost the performance of optical imaging, manipulation, and communication through opaque scattering media.
Highlights
Optical time-reversal techniques are being actively developed to focus light through or inside opaque scattering media
We proved that under-sampling speckle grains improves the signal-to-noise ratio (SNR) by at least 3 times
By analyzing the time-reversal process, we present a relatively simple argument to show that the expected peak-to-background ratio (PBR) can be increased to the spatial light modulator (SLM) pixel count NP when speckle grains are under-sampled in optical time-reversal experiments
Summary
Optical time-reversal techniques are being actively developed to focus light through or inside opaque scattering media. In all previous time-reversal–based optical focusing experiments, speckle grains are magnified (Fig. 1c) and are well-sampled by PCM pixels (Fig. 1d), to correctly measure the wavefront of the scattered light [26, 33, 41,42,43]. We theoretically predict and experimentally verify that by under-sampling speckle grains, we can focus light through scattering media, and significantly increase the PBR by 9 – 25 times, compared with that achieved with the conventional wellsampling conditions (3×3 to 5×5 pixels to sample one speckle grain on average).
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