Concept for a new approach to realize complex optical systems in high volume

Grüger, Heinrich; Knobbe, Jens; Pügner, Tino; Leuckefeld, Michael; Reinig, Peter; Meyer, Sebastian

doi:10.1117/12.2279782

Cited by 4 publications

(3 citation statements)

References 10 publications

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“…Different integration strategies for miniaturized MEMS based systems have been developed and investigated. Throughout this work the so-called "Place and Bend Assembly" [9,10] or the principle of "stacking of subassemblies [11] are considered as favorable options.…”

Section: System Realization and Characterizationmentioning

confidence: 99%

Applications for a broadband NIR spectrometer with scanning mirror device

Grüger

Knobbe

Kruse

et al. 2023

MOEMS and Miniaturized Systems XXII

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Spectral analysis has gained a lot of interest throughout the last decades. Nondestructive and non-contact evaluations can provide multiple information: appearance and composition, but also more complex details, which can be accessed by means of sophisticated methods like fluorescence or Raman scattering. Spectrometers have been widely used for the UV to NIR spectral range. There are applications, where a broad spectral range is beneficial. Typically, the spectral range of a grating based system is limited by higher diffraction orders. Either one decade can be detected or order filters have to be applied to discriminate different orders. A novel concept for a broadband spectrometer is the use of a scanning mirror device to illuminate a fixed grating. Due to the optical path inside, the double wavelength range can be addressed for the identical MEMS deflection. Two or more detectors, each optimized for the relevant spectral range, can be placed in the setup. A first sample of a scanning mirror micro spectrometer (“SMMS”) has been realized and tested successfully. In the NIR spectral range from 1000 nm to 1900 nm a resolution of 10 nm (FWHM) has been achieved. Application examples can be found in the field of agriculture - soil, plant growth and watering, directly leading to food, e.g. ripeness and freshness. Spectrometer with broad spectral range enable simultaneous detection of appearance (color) and composition (NIR); also fungus and aflatoxins can be detected by means of UV to VIS fluorescence. Similar task arise in textile, recycling and other fields where color, composition and conditions are of interest.

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Section: System Realization and Characterizationmentioning

confidence: 99%

Applications for a broadband NIR spectrometer with scanning mirror device

Grüger

Knobbe

Kruse

et al. 2023

MOEMS and Miniaturized Systems XXII

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show abstract

“…A new concept called “place and bend assembly” [ 18 ] uses a mostly planar substrate where the components are placed by standard 2D assembly tools. Afterwards the substrate is folded along previously designed bending [ 19 ] lines and the 3D body is generated with the optical path inside. Applying this technology a first spectrometer has been realized recently ( Figure A4 ).…”

Section: Miniaturized Optical Spectrometermentioning

confidence: 99%

SmartSpectrometer—Embedded Optical Spectroscopy for Applications in Agriculture and Industry

Krause

Grüger

Gebauer

et al. 2021

Sensors

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The ongoing digitization of industry and agriculture can benefit significantly from optical spectroscopy. In many cases, optical spectroscopy enables the estimation of properties such as substance concentrations and compositions. Spectral data can be acquired and evaluated in real time, and the results can be integrated directly into process and automation units, saving resources and costs. Multivariate data analysis is needed to integrate optical spectrometers as sensors. Therefore, a spectrometer with integrated artificial intelligence (AI) called SmartSpectrometer and its interface is presented. The advantages of the SmartSpectrometer are exemplified by its integration into a harvesting vehicle, where quality is determined by predicting sugar and acid in grapes in the field.

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“…In order to facilitate volume production of such complex optical systems a new concept has been presented in 2017 [1]. The basic idea is to generate foldable quasi-planar substrates with integrated optical components.…”

Section: Introductionmentioning

confidence: 99%

Place and bend assembly: towards production of substrates in high volume technologies

Grüger,

Knobbe,

Pügner

et al. 2024

Advanced Fabrication Technologies for Micro/Nano Optics and Photonics XVII

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A new approach named "place and bend assembly" for the efficien t integration of complex optical systems in high volume has been developed by Fraunhofer IPMS. The concept has been proven using 3D printed components. Rece nt developments aim at applying injection molding for the fabrication of substrates optionally in high volume, as well as the integration of functional and optical active surfaces into the substrate. Design, material, process parameters and their optimization for the injection molding have to be analyzed in fine detail. Results of the substrate characterization and system integration will be presented.

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Concept for a new approach to realize complex optical systems in high volume

Cited by 4 publications

References 10 publications

Applications for a broadband NIR spectrometer with scanning mirror device

Applications for a broadband NIR spectrometer with scanning mirror device

SmartSpectrometer—Embedded Optical Spectroscopy for Applications in Agriculture and Industry

Place and bend assembly: towards production of substrates in high volume technologies

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