Guidestar-free image-guided wavefront-shaping
- URL: http://arxiv.org/abs/2007.03956v1
- Date: Wed, 8 Jul 2020 08:26:14 GMT
- Title: Guidestar-free image-guided wavefront-shaping
- Authors: Tomer Yeminy and Ori Katz
- Abstract summary: We present a new concept, image-guided wavefront-shaping, allowing non-invasive, guidestar-free, widefield, incoherent imaging through highly scattering layers, without illumination control.
Most importantly, the wavefront-correction is found even for objects that are larger than the memory-effect range, by blindly optimizing image-quality metrics.
- Score: 7.919213739992463
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Optical imaging through scattering media is a fundamental challenge in many
applications. Recently, substantial breakthroughs such as imaging through
biological tissues and looking around corners have been obtained by the use of
wavefront-shaping approaches. However, these require an implanted guide-star
for determining the wavefront correction, controlled coherent illumination, and
most often raster scanning of the shaped focus. Alternative novel computational
approaches that exploit speckle correlations, avoid guide-stars and wavefront
control but are limited to small two-dimensional objects contained within the
memory-effect correlations range. Here, we present a new concept, image-guided
wavefront-shaping, allowing non-invasive, guidestar-free, widefield, incoherent
imaging through highly scattering layers, without illumination control. Most
importantly, the wavefront-correction is found even for objects that are larger
than the memory-effect range, by blindly optimizing image-quality metrics. We
demonstrate imaging of extended objects through highly-scattering layers and
multi-core fibers, paving the way for non-invasive imaging in various
applications, from microscopy to endoscopy.
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