Superresolution Linear Optical Imaging in the Far Field

Pushkina, Anastasia A.; Maltese, G.; Costa-Filho, J. I.; Patel, P. K.; Lvovsky, A. I.

doi:10.1103/physrevlett.127.253602

Cited by 38 publications

(12 citation statements)

References 40 publications

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“…The path from resolving two sources to obtaining a more complex spectrum with super-resolved features is challenging, yet some knowledge can be drawn from imaging problems considered so far. Various groups have considered the cases of three sources in two dimensions 56 , 57 , or two sources with arbitrary brightness 58 , and practical frameworks for multi-pixel images are being developed as well 59 . For the spectroscopic case discussed here, different operations in the quantum memory will be needed to prepare measurements optimal for multi-source scenarios.…”

Section: Discussionmentioning

confidence: 99%

Optical-domain spectral super-resolution via a quantum-memory-based time-frequency processor

2022

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Existing super-resolution methods of optical imaging hold a solid place as an application in natural sciences, but many new developments allow for beating the diffraction limit in a more subtle way. One of the recently explored strategies to fully exploit information already present in the field is to perform a quantum-inspired tailored measurements. Here we exploit the full spectral information of the optical field in order to beat the Rayleigh limit in spectroscopy. We employ an optical quantum memory with spin-wave storage and an embedded processing capability to implement a time-inversion interferometer for input light, projecting the optical field in the symmetric-antisymmetric mode basis. Our tailored measurement achieves a resolution of 15 kHz and requires 20 times less photons than a corresponding Rayleigh-limited conventional method. We demonstrate the advantage of our technique over both conventional spectroscopy and heterodyne measurements, showing potential for application in distinguishing ultra-narrowband emitters, optical communication channels, or signals transduced from lower-frequency domains.

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Section: Discussionmentioning

confidence: 99%

Optical-domain spectral super-resolution via a quantum-memory-based time-frequency processor

2022

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“…Nevertheless, various scientific and practical aspects of superresolution still attract the attention of researchers in optics, as reported in numerous publications, 10 – 16 including those devoted to the problem of overcoming the diffraction limit in its classical meaning, i.e., implying the Abbe–Rayleigh criterion 12 , 15 , 16 . However, the concept of resolution/superresolution is not always applied in its classical interpretation, treated as the possibility of separate observation of two closely spaced point objects in the image formed by a device.…”

Section: Introductionmentioning

confidence: 99%

“…First, this applies to such already well-developed and commercially available techniques, such as stimulated emission depletion (STED) microscopy, 5 structured illumination microscopy, 6 and single molecule localization microscopy. [7][8][9] Nevertheless, various scientific and practical aspects of superresolution still attract the attention of researchers in optics, as reported in numerous publications, [10][11][12][13][14][15][16] including those devoted to the problem of overcoming the diffraction limit in its classical meaning, i.e., implying the Abbe-Rayleigh criterion. 12,15,16 However, the concept of resolution/superresolution is not always applied in its classical interpretation, treated as the possibility of separate observation of two closely spaced point objects in the image formed by a device.…”

Section: Introductionmentioning

confidence: 99%

Superresolution in phase image of π-phase step on plasmonic metasurface using differential heterodyne microscope

2023

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We investigated the scanning differential heterodyne microscope response for a plasmonic metasurface-dielectric film system. Superresolution effect for microscope phase response with 6.5 superresolution coefficient in the vicinity of π optical phase increment was observed. Use of an additional dielectric film allowed local adjustment of the optical phase increment over a wide range (0 deg to 100 deg). The ability to adjust the width of the phase response function by changing the microscope heterodyne frequency has been demonstrated experimentally.

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“…A large body of theoretical work followed that incorporated important concepts such as the point spread function for analyzing optical lens systems, and mode engineering such as SPADE for optimal detection modes [8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25], reminiscent of the engineering of a "detector mode" for single-parameter estimation of light sources [26]. Experimental work in recent years validated this new approach to imaging [27][28][29][30]. Optical interferometers were investigated in [21,[31][32][33].…”

Section: Introductionmentioning

confidence: 99%

Quantum-enhanced passive remote sensing

2022

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We investigate theoretically the ultimate resolution that can be achieved with passive remote sensing in the microwave regime used, e.g., on board of satellites observing Earth, such as the soil moisture and ocean salinity (SMOS) mission. We give a fully quantum mechanical analysis of the problem, starting from thermal distributions of microscopic currents on the surface to be imaged that lead to a mixture of coherent states of the electromagnetic field which are then measured with an array of antennas. We derive the optimal detection modes and measurement schemes that allow one to saturate the quantum Cramér-Rao bound for the chosen parameters that determine the distribution of the microscopic currents. For parameters comparable to those of SMOS, a quantum enhancement of the spatial resolution by more than a factor of 20 should be possible with a single measurement and a single detector, and a resolution down to the order of 1 m and less than a 1 10 K for the theoretically possible maximum number of measurements.

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Superresolution Linear Optical Imaging in the Far Field

Cited by 38 publications

References 40 publications

Optical-domain spectral super-resolution via a quantum-memory-based time-frequency processor

Optical-domain spectral super-resolution via a quantum-memory-based time-frequency processor

Superresolution in phase image of π-phase step on plasmonic metasurface using differential heterodyne microscope

Quantum-enhanced passive remote sensing

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