In this work, we demonstrate theoretically and experimentally the ability to classify and reconstruct subwavelength acoustic images from far field measurements using a machine learning approach, combined with a locally resonant metamaterial lens placed in the near field. In contrast to other near and far field microscopy techniques that also overcomes the diffraction limit but often uses invasive markers or complicated image post-processing, the proposed deep learning approach, once trained, represents a rapid, noninvasive method. Importantly, we show that the relatively large amount of absorption losses present in the resonant metamaterial largely favors the learning and imaging process. With a learning experiment using airborne sound, we ...
The resolution of acoustic imaging suffers from diffraction limit due to the loss of evanescent fiel...
Navigating and sensing the world through echolocation in air is an innate ability in many animals fo...
Detecting small, subwavelength defect has known to be a challenging task mainly due to the diffracti...
Seeing and recognizing an object whose size is much smaller than the illumination wavelength is a ch...
In this work, we discuss our recent research advances in the field of subwavelength image recognitio...
We introduce a non-intrusive far-field optical microscopy, which reveals the fine structure of an ob...
We report the experimental demonstration of deeply subwavelength far-fieldoptical imaging of unlabel...
A nonintrusive far-field optical microscopy resolving structures at the nanometer scale would revolu...
We report the experimental demonstration of deeply subwavelength far-field optical microscopy of unl...
We demonstrate experimentally label-free far-field imaging of subwavelength objects at resolution gr...
International audienceAccessing subwavelength information about a scene from the far-field without i...
Super-resolution acoustic imaging with state-of-the-art spatial resolution (lambda/50), with lambda ...
Anisotropic zero-mass acoustic metamaterials are able to transmit evanescent waves without decaying ...
The resolution of acoustic imaging suffers from diffraction limit due to the loss of evanescent fiel...
Navigating and sensing the world through echolocation in air is an innate ability in many animals fo...
Detecting small, subwavelength defect has known to be a challenging task mainly due to the diffracti...
Seeing and recognizing an object whose size is much smaller than the illumination wavelength is a ch...
In this work, we discuss our recent research advances in the field of subwavelength image recognitio...
We introduce a non-intrusive far-field optical microscopy, which reveals the fine structure of an ob...
We report the experimental demonstration of deeply subwavelength far-fieldoptical imaging of unlabel...
A nonintrusive far-field optical microscopy resolving structures at the nanometer scale would revolu...
We report the experimental demonstration of deeply subwavelength far-field optical microscopy of unl...
We demonstrate experimentally label-free far-field imaging of subwavelength objects at resolution gr...
International audienceAccessing subwavelength information about a scene from the far-field without i...
Super-resolution acoustic imaging with state-of-the-art spatial resolution (lambda/50), with lambda ...
Anisotropic zero-mass acoustic metamaterials are able to transmit evanescent waves without decaying ...
The resolution of acoustic imaging suffers from diffraction limit due to the loss of evanescent fiel...
Navigating and sensing the world through echolocation in air is an innate ability in many animals fo...
Detecting small, subwavelength defect has known to be a challenging task mainly due to the diffracti...