Conference Papers

Results: 281
Created on: Wed, 27 Mar 2024 23:08:06 +0100 in 0.0795 sec


Lenk, Leonhard; Mitschunas, Beate; Sinzinger, Stefan
Zoom systems with tunable lenses and linear lens movements. - In: Journal of the European Optical Society, ISSN 1990-2573, Bd. 15 (2019), 1, 9, S. 1-10

Background: Classical zoom lenses are based on movements of sub-modules along the optical axis. Generally, a constant image plane position requires at least one nonlinear sub-module movement. This nonlinearity poses a challenge for the mechanical implementation. Tuneable lenses can change their focal length without moving along the optical axis. This offers the possibility of small system lengths. Since the focal range of tuneable lenses with significant aperture diameters is still limited, the use of tuneable optics in zoom lenses is usually restricted to miniaturized applications. Methods: To solve the challenge of the nonlinear movement in classical zoom lenses and the limitations of tuneable lenses for macroscopic applications we propose a combination of both concepts. The resulting 'Hybrid Zoom Lens' involves linear movements of sub modules as well as changing the focal length of a tuneable lens. The movements of the sub-modules and the focal length tuning of the lens are already determined by the collinear layout of the zoom lens. Therefore, we focus on collinear considerations and develop a method that allows a targeted choice of specific collinear layouts for our 'Hybrid zoom lenses'. Results: Based on examples and an experimental setup we demonstrate the feasibility of our approach. We apply the proposed method to examples of classical zoom lenses and zoom lenses based exclusively on tuneable lenses. Thereby we are able to show possible advantages of our 'Hybrid zoom lenses' over these widespread system types. Conclusions: We demonstrate important collinear considerations for the integration of tuneable lenses into a zoom lens. We show that the combination of classical zoom lens concepts with tuneable lenses offers the possibility to reach smaller system lengths for macroscopic zoom lenses while requiring only a small focal tuning range of the tuneable lens.



https://doi.org/10.1186/s41476-019-0106-3
Kirchner, Johannes; Mohr-Weidenfeller, Laura; Gerhardt, Uwe; Mastylo, Rostyslav; Kühnel, Michael; Sinzinger, Stefan; Manske, Eberhard
A combined laser scanning and DLW tool for measuring and fabrication tasks with NPMM. - In: Advanced Fabrication Technologies for Micro/Nano Optics and Photonics XII, (2019), S. 1093017-1-1093017-6

In view of the increasing demands on precision optics, microelectronics and precision mechanics nanoscale structuring processes are of great interest. It is becoming more and more important to apply a large number of structures that are as small as possible to ever larger areas with high reliability and to increase the number of structures per area element (packing density). The straightness and uniformity of these structures, as well as the positioning accuracy during the fabrication of such narrow lines and points are at the center of the increase of the packing density. A further decisive role is played by the development of suitable sensors and tools for the production and measurement of these structures. The development and the combination of a new laser based probe for the measurement and a direct laser writing (DLW) tool for the creation of sub-micro structures forms the core of this topic. The new sensor is based on a confocal measuring principle. A fiber coupling is used to avoid thermal influences. At the same time, the fiber end itself serves as a confocal pinhole. For the process tool, comprehensive investigations of laser and resist parameters are necessary. The first results are shown. These two parts are investigated separately and combined at the end of the work. In order to achieve the necessary positioning accuracy, the tool is integrated into the Nanopositioning and Measurement Machine (NPMM).



https://doi.org/10.1117/12.2508263
Supreeti, Shraddha; Kirchner, Johannes; Hofmann, Martin; Mastylo, Rostyslav; Rangelow, Ivo W.; Manske, Eberhard; Hoffmann, Martin; Sinzinger, Stefan
Integrated soft UV-nanoimprint lithography in a nanopositioning and nanomeasuring machine for accurate positioning of stamp to substrate. - In: Novel Patterning Technologies for Semiconductors, MEMS/NEMS, and MOEMS 2019, (2019), S. 1095819-1-1095819-7

https://doi.org/10.1117/12.2514832
Bichra, Mohamed; Meinecke, Thomas; Sinzinger, Stefan
In-Line Verfahren zur Charakterisierung von Freiform Oberflächen :
In-line setup for the characterization of optical freeform surfaces. - In: DGaO-Proceedings, ISSN 1614-8436, Bd. 119 (2018), P45, insges. 2 S.

https://nbn-resolving.org/urn:nbn:de:0287-2018-P045-0
Koch, Felix; Schönbrodt, Oliver; Burkhardt, Matthias; Lehr, Dennis; Glaser, Tilman; Sinzinger, Stefan
Optimization and manufacturing of gold gratings for pulse compression. - In: DGaO-Proceedings, ISSN 1614-8436, Bd. 119 (2018), A27, insges. 2 S.

https://nbn-resolving.org/urn:nbn:de:0287-2018-A027-3
Speck, Henri; Cao, Xinrui; Meinecke, Thomas; Sinzinger, Stefan
Phase-Retrieval mit Hilfe verstimmbarer Optiken für die Fourier-Ptychographie. - In: DGaO-Proceedings, ISSN 1614-8436, Bd. 119 (2018), A26, insges. 2 S.

https://nbn-resolving.org/urn:nbn:de:0287-2018-A026-8
Lenk, Leonhard; Mitschunas, Beate; Sinzinger, Stefan
Zoomoptiken mit verstimmbarer Optik und linearer Verschiebung der Einzelmodule. - In: DGaO-Proceedings, ISSN 1614-8436, Bd. 119 (2018), B17, insges. 2 S.

https://nbn-resolving.org/urn:nbn:de:0287-2018-B017-3
Fischer, David; Sinzinger, Stefan
Maskenlose Lithographie für die dreidimensionale Mikrostrukturierung. - In: DGaO-Proceedings, ISSN 1614-8436, Bd. 119 (2018), B12, insges. 2 S.

https://nbn-resolving.org/urn:nbn:de:0287-2018-B012-1
Kreismann, Jakob; Behrens, Arne; Weigel, Christoph; Sinzinger, Stefan; Hentschel, Martina; Yang, Lan
Mesoscopic optics. - In: Mikro-Nano-Integration, (2018), S. 55-57

Bourgin, Yannick; Nagel, Falk; Feßer, Patrick; Bergmann, Jean Pierre; Sinzinger, Stefan
High power laser beam shaping for welding applications by means of diffractive elements. - In: Laser Beam Shaping XVIII, (2018), 107440X, insges. 7 S.

Laser welding by means of multi-kilowatt solid state lasers can be considerably improved if the focused welding spot is embedded in a pre-heating spot generated e.g. by an additional laser. To improve the compactness of the optical system, the same functionality can be effectively achieved by means of diffractive diffusers. Because such a diffractive optical solution may suffer from the presence of speckles, a comprehensive characterization of the laser source is performed. The paper includes the design, the compensation of the difference in the intensity levels, the fabrication and the optical performances of the fabricated DOEs. We furthermore present the functionality of the DOEs in the welding process.



https://doi.org/10.1117/12.2320579