Characterization of Micro-optics

doi:10.1017/CBO9781139506052.011

11 - Characterization of Micro-optics

from Part III - Systems and Applications

Published online by Cambridge University Press: 05 December 2015

Heidi Ottevaere ,

Lien Smeesters and

Hugo Thienpont

Edited by

Hans Zappe and

Claudia Duppé

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Heidi Ottevaere: Affiliation:
Vrije Universiteit Brussel, Brussels, Belgium
Lien Smeesters: Affiliation:
Vrije Universiteit Brussel, Brussels, Belgium
Hugo Thienpont: Affiliation:
Vrije Universiteit Brussel, Brussels, Belgium
Hans Zappe: Affiliation:
Albert-Ludwigs-Universität Freiburg, Germany
Claudia Duppé: Affiliation:
Albert-Ludwigs-Universität Freiburg, Germany

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Summary

Introduction

In today's world of information processing, the role of optics and opto-electronics is expected to become increasingly important as the performance of communication, processing, sensing and display technologies is continuously evolving. Making these photonics technologies faster, less power consuming and smaller requires at the same time the introduction of parallelism, integration and miniaturization. As a result, high-quality, high-precision and low-cost micro-optical components are becoming indispensable components. Moreover the introduction of tunable micro-optics provides new degrees of freedom for the system design and, therefore, also for the functionality. It allows solutions which are not possible with purely conventional optics, such as the integration of different functionalities. Hence, it reduces the additional mechanical assembly cost as required in conventional optics.

Tunable optical lenses in particular are becoming important optical devices for a wide variety of applications ranging from biology to laser material processing, machine vision, microscopy, ophthalmology and mobile-phone cameras (Casut 2013). Among others, their foremost advantage is the possibility to have variable focusing without mechanical translation (Commander et al. 2000). The tunability can be effectively used to obtain a different radius of curvature and consequently a varying optical power. In traditional optical designs, the focal length is changed by mechanical translation of the entire optical lens system which requires expensive mechanical actuators. With tunable lenses, such systems quickly become more compact. On top, the number of required lenses may often be reduced, too. Therefore the overall system can be designed with both an improved robustness and less weight.

Over the last fifteen years several research groups and industrial research labs have been focusing their attention on the development of fabrication techniques for tunable optics. A broad spectrum of tunable micro-optical components using a wide variety of physical effects has been proposed and demonstrated (Friese et al. 2007). Depending on the state of the material and the tuning mechanism, they can be classified as thermally tunable solid state lenses (Lee et al. 2006), liquid crystal tunable lenses (Ren et al. 2007, Kim et al. 2014) and mechanically tunable (Ren et al. 2006) or electrically tunable (Shian et al. 2013) liquid lenses. Different types of these tunable lenses are already commercially available (Berge & Peseux 2000). Chapter 5 provides a more detailed overview of tunable lenses.

Type: Chapter
Information: Tunable Micro-optics , pp. 265 - 292

DOI: https://doi.org/10.1017/CBO9781139506052.011 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2015

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References

Berge, B. & Peseux, J. (2000), ‘Variable focal lens controlled by an external voltage: an application of electrowetting’, European Physical Journal E 3, 159–163.CrossRef Google Scholar

Boreman, G. D. (2001), Modulation Transfer Function in Optical and ElectroOptical Systems, SPIE Press Vol. TT52.CrossRef Google Scholar

Born, M. & Wolf, E. (1999), Principles of Optics, Cambridge University Press.CrossRef Google Scholar

Casut, S. (2013), ‘Electrically tunable polymer lenses for fast and compact focusing solutions’, Photonik International 1, 79–82.Google Scholar

Commander, L. G., Day, S. E. & Selviah, D. R. (2000), ‘Variable focal length microlenses’, Optics Communications 17, 157–170.Google Scholar

de Angelis, M., Nicola, S. D., Ferraro, P., Finizio, A. & Pierattini, G. (1998), ‘Analysis of moiré fringes for measuring the focal length of lenses’, Optics and Lasers in Engineering 30, 279–286.

Friese, C., Werber, A., Krogmann, F., Mönch, W. & Zappe, H. (2007), ‘Materials, effects and components for tunable micro-optics’, IEEJ Transactions on Electrical and Electronic Engineering 2, 232–248.CrossRef Google Scholar

Goodwin, E. & Wyant, J. C. (2006), Field Guide to Interferometric Optical Testing, SPIE Field Guide Series Vol. FG10.CrossRef

Hecht, E. (1998), Optics, Addison Wesley, New York, USA.Google Scholar

J. M. Huntley, H. S. (1993), ‘Temporal phase-unwrapping algorithm for automated interferogram analysis’, Applied Optics 32(17), 3047–3052.CrossRef Google Scholar

Kim, J., Kim, J., Na, J., Lee, B. & Lee, S. (2014), ‘Liquid crystal-based square lens array with tunable focal length’, Optics Express 22, 3316–3324.

Lee, S., Tung, H., Chen, W. & Fang, W. (2006), ‘Thermal actuated solid tunable lens’, IEEE Photonics Technology Letters 18(21), 2191–2193.CrossRef Google Scholar

Mahajan, V. N. (1982), ‘Strehl ratio for primary aberrations: some analytical results for circular and annular pupils’, Journal of the Optical Society of America 72, 1258–1266.CrossRef Google Scholar

Mahajan, V. N. (1994), ‘Symmetry properties of aberrated point-spread functions’, Journal of the Optical Society of America A11, 1993–2003.Google Scholar

Malacara, D. & Malacara, Z. (1994), Handbook of Lens Design, Marcel Dekker INC.Google Scholar

Malacara, D., Servin, M. & Malacara, Z. (1998), Interferogram Analysis for Optical Testing, Marcel Dekker Inc, Boca Raton, FL.Google Scholar

Marimont, D. H. & Wandell, B. A. (1994), ‘Matching color images: The effects of axial chromatic aberration’, Journal of the Optical Society of America 11(12), 3113.CrossRef Google Scholar

Miccio, L., Finizio, A., Grilli, S., Vespini, V., Paturzo, M., Nicola, S. D. & Ferraro, P. (2009), ‘Tunable liquid microlens arrays in electrode-less configuration and their accurate characterization by interference microscopy’, Optics Express 17, 2487–2499.CrossRef Google Scholar PubMed

Ottevaere, H. & Thienpont, H. (2004), ’Refractive optical microlenses: an introduction to nomenclature and characterization techniques’, in R. D., Guenther, D. G., Steel & L., Bayvel, eds, Encyclopedia of Modern Optics, Elsevier, Oxford, Vol. 4, pp. 21–43, ISBN 0-12-227600-0.Google Scholar

Pedrotti, F. & Pedrotti, L. (1993), Introduction to Optics, Prentice Hall International.

Ren, H., Fox, D., Anderson, P., Wu, B. & Wu, S. (2006), ‘Tunable-focus liquid lens controlled using a servo motor’, Optics Express 14(18), 8031–8036.CrossRef Google Scholar PubMed

Ren, H., Fox, D., Wu, B. & Wu, S. (2007), ‘Liquid crystal lens with large focal length tunability and low operating voltage’, Optics Express 15(18), 11328–11335.CrossRef Google Scholar PubMed

Schreiber, H. & Bruning, J. H. (2006), Optical Shop Testing, John Wiley & Sons, Inc.Google Scholar

Schwider, J. (1998), Twyman-Green Interferometer for Testing Microlens Surfaces; User's Guide, University Erlangen-Nürnberg Erlangen, Germany.Google Scholar

Shamai, R., Andelman, D., Berge, B. & Hayes, R. (2008), ‘Water, electricity, and between… on electrowetting and its applications’, Soft Matter 4, 38–45.CrossRef Google Scholar

Shannon, R. (1997), The Art and Science of Optical Design, Cambridge University Press.CrossRef Google Scholar

Shian, S., Diebold, R. & Clarke, D. (2013), ‘Tunable lenses using transparent dielectric elastomer actuators’, Optics Express 21(7), 8669–8676.CrossRef Google Scholar PubMed

Sinzinger, S. & Jahns, J. (1999), Microoptics, “Optical Components with Small Dimensions”, Wiley-VCH.Google Scholar

Sinzinger, S. & Jahns, J. (2003), Microoptics, Wiley-VCH, Weinheim (FRG), Germany.CrossRef Google Scholar

Smith, W. J. (1997), Practical Optical System Layout and Use of Stock Lenses, McGraw-Hill.Google Scholar

Smith, W. J. (2000), Modern Optical Engineering, McGraw-Hill.Google Scholar

Tan, M. (2006), ‘Varioptic unveils arctic 320 camera phone liquid lens’, Mobile magazine (http://www.mobilemag.com/2006/01/24/varioptic-unveils-arctic-320-camera-phone-liquidlens/).

Wilson, M. (2008), ‘Varioptic liquid lenses debut in webcams’, Gizmodo (http://gizmodo.com/50 19642/varioptic-liquid-lenses-debut-in-webcams).

Zhang, X., Kashti, T., Kella, D., Frank, T., Shaked, D., Ulichney, R., Fischer, M. & Allebach, J. P. (2012), ‘Measuring the modulation transfer function of image capture devices: what do the numbers really mean?’, Proceedings of SPIE 8293, 829307.Google Scholar