High-Speed Focus Inspection System Using a Position-Sensitive Detector

Cao, Binh Xuan; Hoang, Phuong Le; Ahn, Sanghoon; Kang, Hee-Shin; Kim, Jeng-o

doi:10.3390/s17122842

Cited by 12 publications

(6 citation statements)

References 20 publications

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“…Another approach is adding an extra light source as the detective light and introducing an autofocusing system that have been realized based on confocal scheme, [81,82] contrast measurement on a pattern illumination, [83] or PSF engineering including astigmatism method, [84][85][86] bisected beam method, [87] and double-spot focus detection. [88] In the PSF engineering-based techniques, the PSF of the detective laser beam is modulated to have different shapes or positions in different focusing positions.…”

Section: Interface Positioning Methodsmentioning

confidence: 99%

3D Sub‐Diffraction Printing by Multicolor Photoinhibition Lithography: From Optics to Chemistry

Zhang

Cao

et al. 2021

Laser & Photonics Reviews

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Photoinhibition lithography (PIL) is a nanoscale fabrication technique that uses multicolor visible light to enable the printing of arbitrary 3D structures beyond the diffraction limit. Photoinhibition allows the control and confinement of the exposed region for photoinitiation during the photolithographic process, thus improving the resolution of existing lithographic techniques, such as direct laser writing. Because PIL enables super-resolution 3D printing, it has a multitude of applications. In this review, practical applications of PIL in the areas of photonics, data storage, and biotechnology are highlighted; in addition, its unique features are revealed. The theory and recent advances in PIL for sub-diffraction printing and high-throughput fabrication are also discussed. Besides, challenges and tentative solutions are discussed with the hope of providing a preliminary roadmap for technological breakthroughs in PIL to enable developments of resolution and throughput.

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Section: Interface Positioning Methodsmentioning

confidence: 99%

3D Sub‐Diffraction Printing by Multicolor Photoinhibition Lithography: From Optics to Chemistry

Zhang

Cao

et al. 2021

Laser & Photonics Reviews

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“…Available as two-dimensional sensors with sizes up to 20 mm × 20 mm, they are capable of measuring the laser spot’s weighted center of intensity with micrometer uncertainties. These sensors have been used in the past for similar applications such as fast autofocus inspections [ 9 ] as well as angle measurements of the relative story displacement [ 10 ]. The dynamic potential of the PSD has also been observed in the past [ 11 ], which showed that dynamic measurements with speeds up to 104.72 m/s (=ca.…”

Section: Introductionmentioning

confidence: 99%

“…Measurements of mirror-inclination angles or MEMS steering angles with PSDs have been performed by [ 8 , 12 , 13 , 14 ]. Nishibori and Nishibori [ 9 ] focused on a static measurement in a range of ±8° with a measurement uncertainty of 0.5°. Fujita et al [ 8 ] designed a controlling system with an rms error of 0.21° in an angular range between ±6° for a two-dimensional MEMS mirror and a holed PSD, which showed that the dynamic characterization of MEMS with PSDs is possible.…”

Section: Introductionmentioning

confidence: 99%

MEMS-Scanner Testbench for High Field of View LiDAR Applications

Baier

Schardt²,

Fink

et al. 2021

Sensors

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LiDAR sensors are a key technology for enabling safe autonomous cars. For highway applications, such systems must have a long range, and the covered field of view (FoV) of >45° must be scanned with resolutions higher than 0.1°. These specifications can be met by modern MEMS scanners, which are chosen for their robustness and scalability. For the automotive market, these sensors, and especially the scanners within, must be tested to the highest standards. We propose a novel measurement setup for characterizing and validating these kinds of scanners based on a position-sensitive detector (PSD) by imaging a deflected laser beam from a diffuser screen onto the PSD. A so-called ray trace shifting technique (RTST) was used to minimize manual calibration effort, to reduce external mounting errors, and to enable dynamical one-shot measurements of the scanner’s steering angle over large FoVs. This paper describes the overall setup and the calibration method according to a standard camera calibration. We further show the setup’s capabilities by validating it with a statically set rotating stage and a dynamically oscillating MEMS scanner. The setup was found to be capable of measuring LiDAR MEMS scanners with a maximum FoV of 47° dynamically, with an uncertainty of less than 1%.

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“…Position-sensitive detector (PSD), a kind of optical inspection systems for the precise measurement of position, distance, displacement, angle, and other relevant physical variables, is a crucial component for diverse applications, including optical engineering, aerospace, real-time tracking and nanorobotics [1][2][3][4]. In tracking or remote measurement systems, high sensitivity and ultra-weak light detection capability are crucial, which determine the accuracy and operating distance of the systems.…”

Section: Introductionmentioning

confidence: 99%

Ultrasensitive graphene position-sensitive detector induced by synergistic effects of charge injection and interfacial gating

Wang

Sun

et al. 2020

Nanophotonics

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AbstractPosition-sensitive detectors (PSDs) are essential components to the realization of displacement and vibration detection, optical remote control, robot vision, etc. The light sensitivity of PSDs is a crucial parameter, which determines the operating range or detection accuracy of the measurement systems. Here, we devise an ultrasensitive PSD based on graphene/Si hybrid structure by using the synergistic effect of charge injection and interfacial gating. Photogenerated carriers in Si are separated by the built-in electric field at the surface. Holes diffuse laterally in inversion layer and then inject into graphene to form photoresponse. Meanwhile, the electrons in bulk Si that move to the area under graphene cause a gating effect, thus introducing a high gain. With the benefit of synergistic effect, the detection limit power of our device can be pushed to pW level, which is reduced by two orders of magnitude compared to previously reported graphene based PSD. Furthermore, even for infrared light of 1064 nm, the PSD still retains position sensitivity to 1 nW weak light, as well as fast response speed at the μs level. This work provides the potential of graphene as a promising material for ultraweak light position sensitive detection.

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High-Speed Focus Inspection System Using a Position-Sensitive Detector

Cited by 12 publications

References 20 publications

3D Sub‐Diffraction Printing by Multicolor Photoinhibition Lithography: From Optics to Chemistry

3D Sub‐Diffraction Printing by Multicolor Photoinhibition Lithography: From Optics to Chemistry

MEMS-Scanner Testbench for High Field of View LiDAR Applications

Ultrasensitive graphene position-sensitive detector induced by synergistic effects of charge injection and interfacial gating

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