Helical Nanostructures of Ferroelectric Liquid Crystals as Fast Phase Retarders for Spectral Information Extraction Devices: A Comparison with the Nematic Liquid Crystal Phase Retarders

Abuleil, Marwan J.; Pasha, Doron; August, Isaac; Pozhidaev, E. P.; Barbashov, Vadim A.; Tkachenko, T. P.; Kuznetsov, A. V.; Abdulhalim, Ibrahim

doi:10.3390/ma14195540

Cited by 6 publications

(3 citation statements)

References 82 publications

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“…Spectral imaging systems allow the capture of a scene with several objects and perform spectral analysis at every point in space for all objects simultaneously, therefore improving the capabilities and performances of such systems. For many applications, the essential spectral information resides in a few discrete wavelengths that are known in advance, hence, an application-oriented multispectral system can collect the information more efficiently and provide better performance than a hyperspectral system [3].…”

Section: Introductionmentioning

confidence: 99%

Faster narrowband multi-spectral liquid crystal-based imaging modules tailored to the specific application

Pasha,

Abu Aisheh,

Abu Leil

et al. 2024

Liquid Crystals Optics and Photonic Devices

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The most common configuration of liquid crystal devices incorporated within spectral imaging systems is using LCTFs. Usually, these filters suffer from low light throughput or slow response times which may not meet the growing demands of industry and research. However, in most applications multispectral imaging is adequate, and no need for hyperspectral imaging. In this work, we implemented a discrete tunable Lyot-based filter in such systems to obtain spectral images more efficiently. The filter consists of 3 LC cells combined with 9 narrow bands of passive filter covering the VIS and NIR, which makes it a potential candidate for various applications. A system with a smaller number of bands designed for oximetry imaging is even faster and shows higher light throughput. Experimental results show that our system holds a relatively faster response time with high light throughput while providing reliable spectral information.

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Section: Introductionmentioning

confidence: 99%

Faster narrowband multi-spectral liquid crystal-based imaging modules tailored to the specific application

Pasha,

Abu Aisheh,

Abu Leil

et al. 2024

Liquid Crystals Optics and Photonic Devices

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“…Other cases are in scenarios where the examined objects can be characterized based on only few or several spectral bands in a known accurate spectral location and a known spectral width. [ 14 ] For these reasons, a multispectral system would be preferable over a system with a higher spectral separation, which can lead to higher acquisition rates, signal‐to‐noise ratio (SNR) improvement, higher spatial resolution, processing, and storage size reduction. In what follows we give a short summary of the advantages and limitations of compressive sensing versus deep learning approaches, while for more detailed discussion the reader is referred to the Supporting Information.…”

Section: Introductionmentioning

confidence: 99%

Faster Multispectral Imager Based on Thin Liquid Crystal Modulator and 3D Neural Network Lattice

Pasha

Abuleil

August

et al. 2023

Laser & Photonics Reviews

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Computational spectral imaging using reconstruction methods such as compressed sensing and deep learning is becoming popular. Despite the great progress, for multispectral imaging, only few expectations are realized due to various constraints. Here, a new method is proposed for multispectral sensing based on use of the following: (i) dual spectral modules, one defining the working spectral bands while the other as spectral modulator, and (ii) distributed 3D neural network algorithm. The method shows fast and accurate sensing, avoids a complicated calibration process, and can directly access any wavelength at any point. Experimental demonstration is presented using thin liquid crystal cells showing high peak signal-to-noise ratio.

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“…August et al [29] proposed an approach using a single LCVR to modulate and achieve the reconstruction of hyperspectral images. Alternatively, AbuLeil et al [30] explored the parallel spectroscopic extraction using spectral modulation and computational algorithms formed by LCVRs or multi-band pass filters. However, the drawback of this means is that it inadequately compresses the hyperspectral image data in the spatial domain.…”

Section: Introductionmentioning

confidence: 99%

High Light Efficiency Spectral Polarization Imaging Method Based on Mach–Zehnder Structured Liquid Crystal Tunable Filters and Variable Retarders

et al. 2023

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Liquid crystal tunable filters (LCTFs) are extensively used in hyperspectral imaging systems to obtain spectral information of target scenes. However, a typical LCTF can only filter linearly polarized light, greatly reducing the transmittance of the system and limiting its application in spectral and polarization imaging. In this paper, a spectropolarimeter using Mach–Zehnder structured LCTFs (MZ-LCTFs) combined with liquid crystal variable retarders (LCVRs) is proposed. The polarized beam splitter (PBS) can make full use of the two polarization components of the incident light to improve the transmittance of the system. Specifically, the results show that the mean pixel intensity (MPI) of spectral images is improved by 93.48% compared to a typical LCTF. Subsequently, the average signal to noise ratio (SNR) of filtered and unfiltered images when simultaneously using polarization S and P channels is increased by 2.59 dB compared to a single channel. In addition, the average Standard Deviations (STDs) of DoLP and DoCP are 0.016 and 0.018, respectively. The proposed method has the potential to be applied to obtain polarization information with high optical efficiency and a full spectrum in a wide band.

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Helical Nanostructures of Ferroelectric Liquid Crystals as Fast Phase Retarders for Spectral Information Extraction Devices: A Comparison with the Nematic Liquid Crystal Phase Retarders

Cited by 6 publications

References 82 publications

Faster narrowband multi-spectral liquid crystal-based imaging modules tailored to the specific application

Faster narrowband multi-spectral liquid crystal-based imaging modules tailored to the specific application

Faster Multispectral Imager Based on Thin Liquid Crystal Modulator and 3D Neural Network Lattice

High Light Efficiency Spectral Polarization Imaging Method Based on Mach–Zehnder Structured Liquid Crystal Tunable Filters and Variable Retarders

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