OpenVNT: An Open Platform for VIS-NIR Technology

Kulko, Roman-David; Pletl, Alexander; Mempel, Heike; Wahl, Florian; Elser, Benedikt

doi:10.3390/s23063151

Cited by 4 publications

(5 citation statements)

References 35 publications

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“…Table 2 provides a means to determine the optimal combination of N-PK52A and HZF6 materials, which minimizes the secondary spectrum of the system while also satisfying the tolerable focus color shift. By utilizing Equations ( 5)- (7), the optical power of lenses made from these materials can be determined, with values of Φ 1 = 0.01 and Φ 2 = −0.0038 assigned to each, respectively. Utilizing only two lenses in the system will not correct for all aberrations.…”

Section: Methods and Processesmentioning

confidence: 99%

“…The widening of the working spectral range of the imaging spectrometer has led to serious axial chromatic aberration and secondary spectrum in the system, which affects the imaging quality of the system [7]. As shown in Figure 1, tilting the image plane can improve the imaging quality, but this structure is not conducive to later installation and adjustment, and there is axial chromatic aberration that causes spectral crosstalk during detection.…”

Section: Wide-spectral-band Achromatic Reduction Principlementioning

confidence: 99%

“…Based on Equations ( 5)- (7), and (10), it is evident that the Abbe numbers of the chosen glass materials should differ considerably, while the relative dispersion coefficients should have only minor differences to minimize the secondary spectral coefficient and eliminate the secondary spectrum within the system. Therefore, it is possible to correct the axial chromatic aberration and secondary spectrum of the transmissive optical system by selecting appropriate materials with low chromatic aberration and distributing the optical focal power of the combined lenses reasonably.…”

Section: Wide-spectral-band Achromatic Reduction Principlementioning

confidence: 99%

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Design of a Prism-Grating Wide Spectral Range Transmittance Imaging Spectrometer

Xue

et al. 2023

Sensors

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As spectroscopic detection technology rapidly advances, back-illuminated InGaAs detectors with a wider spectral range have emerged. Compared to traditional detectors such as HgCdTe, CCD, and CMOS, InGaAs detectors offer a working range of 400–1800 nm and exhibit a quantum efficiency of over 60% in both the visible and near-infrared bands. This is leading to the demand for innovative designs of imaging spectrometers with wider spectral ranges. However, the widening of the spectral range has led to the presence of significant axial chromatic aberration and secondary spectrum in imaging spectrometers. Additionally, there is difficulty in aligning the system optical axis perpendicular to the detector image plane, resulting in increased challenges during post-installation adjustment. Based on chromatic aberration correction theory, this paper presents the design of a wide spectral range transmission prism-grating imaging spectrometer with a working range of 400–1750 nm using Code V. The spectral range of this spectrometer covers both the visible and near-infrared regions, which is beyond the capability of traditional PG spectrometers. In the past, the working spectral range of transmission-type PG imaging spectrometers has been limited to 400–1000 nm. This study’s proposed chromatic aberration correction process involves selecting optical glass materials that match the design requirements and correcting the axial chromatic aberration and secondary spectrum, ensuring that the system axis is perpendicular to the detector plane and easy to adjust during installation. The results show that the spectrometer has a spectral resolution of 5 nm, a root-mean-square spot diagram less than 8 μm over the full field of view, and an optical transfer function MTF greater than 0.6 at a Nyquist frequency of 30 lp/mm. The system size is less than 90 mm. Spherical lenses are employed in the system design to reduce manufacturing costs and complexity while meeting the requirements of wide spectral range, miniaturization, and easy installation.

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Section: Methods and Processesmentioning

confidence: 99%

Section: Wide-spectral-band Achromatic Reduction Principlementioning

confidence: 99%

Section: Wide-spectral-band Achromatic Reduction Principlementioning

confidence: 99%

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Design of a Prism-Grating Wide Spectral Range Transmittance Imaging Spectrometer

Xue

et al. 2023

Sensors

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show abstract

“…It offers a full wavelength range (380nm to 1100nm) of spectral matching with high spectral power. The source can be a valuable tool for ambient sensor or image sensor calibration [8,15,23,24], display calibration, hyperspectral imaging, spectroscopy [3,4,16,24], healthcare [12,14], radiometry [2,18,19,21], diagnostics and biomedical-related applications [7,9,12,20,22], which also need to consider the ambient light or NIR light effects and simulate the detailed spectral profiles of arbitrary light sources with more extended wavelength range and high fidelity.…”

Section: Applicationsmentioning

confidence: 99%

“…Energetiq's broadband spectrum matching light source (Chromatic Spectral Engine (CSE)) with the visible range of 380nm to 800nm has been successful in unlimited spectral profile matching in the visible range [1]. With new requirements from applications and customers [2,3,4,5,6,7,8,9,10], the wavelength range is extended from the range of 380nm ~ 800nm to 1100nm. This wavelength range extension makes it possible for spectral matching in silicon detectors sensitive range of both Visible and NIR with reasonable flux and spectral resolution.…”

Section: Introductionmentioning

confidence: 99%

A 380-1100nm spectrum matching light source with high spectral resolution, throughput, speed, and stability

Wang,

Saito,

Zhou

et al. 2023

Novel Optical Systems, Methods, and Applications XXVI

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A broadband spectrum matching light source with a visible to near-infrared (NIR) wavelength range is a valuable tool for broad applications. Based on Energetiq's early version of spectrum matching light source covering the visible wavelength range (380 to 800nm), we extended the range of spectral matching to 1100nm. The new source has two input beam channels for the visible and NIR light from a single Energetiq LDLS light source. The two beams share the same grating, the digital mirror device (DMD), and the optical path. This innovative design extends the wavelength range with a smooth spectral transition. The new system has a compact system size with a 6.5mm diameter liquid light guide output.The light source has a 5.3nm full-width-half-maximum (FWHM) linewidth from 380 to 800nm and about 11nm FWHM between 680 and 1100nm, based on the input fiber size selection. With its high resolution, the source can be a valuable tool for sensor calibration, hyperspectral imaging, spectroscopy, and biomedical-related applications, which also need to consider the ambient light or NIR light effects and simulate the detailed spectral profiles of arbitrary light sources with more extended wavelength range and high fidelity. The source throughput, switching speed, and output stability will also be discussed.

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Evaluating the shelf life of strawberries using a portable Vis-NIR spectrophotometer and a Reflectance Quality Index (RQI)

Rabasco-Vílchez,

Jiménez-Jiménez,

Possas

et al. 2024

Postharvest Biology and Technology

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OpenVNT: An Open Platform for VIS-NIR Technology

Cited by 4 publications

References 35 publications

Design of a Prism-Grating Wide Spectral Range Transmittance Imaging Spectrometer

Design of a Prism-Grating Wide Spectral Range Transmittance Imaging Spectrometer

A 380-1100nm spectrum matching light source with high spectral resolution, throughput, speed, and stability

Evaluating the shelf life of strawberries using a portable Vis-NIR spectrophotometer and a Reflectance Quality Index (RQI)

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