Performance optimization in mass production of volume holographic optical elements (vHOEs) using Bayfol HX photopolymer film

Volume Holographic Optical Elements (vHOEs) gained wide attention as optical combiners for the use in smart glasses and augmented reality (SG and AR, respectively) consumer electronics and automotive head-up display applications. The unique characteristics of these diffractive grating structures – being lightweight, thin and flat – make them perfectly suitable for use in integrated optical components like spectacle lenses and car windshields. While being transparent in Off-Bragg condition, they provide full color capability and adjustable diffraction efficiency. The instant developing photopolymer Bayfol® HX film provides an ideal technology platform to optimize the performance of vHOEs in a wide range of applications. Important for any commercialization are simple and robust mass production schemes. In this paper, we present an efficient and easy to control one-beam recording scheme to copy a so-called master vHOE in a step-and-repeat process. In this contact-copy scheme, Bayfol® HX film is laminated to a master stack before being exposed by a scanning laser line. Subsequently, the film is delaminated in a controlled fashion and bleached. We explain working principles of the one-beam copy concept, discuss the opto-mechanical construction and outline the downstream process of the installed vHOE replication line. Moreover, we focus on aspects like performance optimization of the copy vHOE, the bleaching process and the suitable choice of protective cover film in the re-lamination step, preparing the integration of the vHOE into the final device.

[1]  D B Brumm Copying holograms. , 1966, Applied optics.

[2]  Clark N. Kurtz Copying Reflection Holograms , 1968 .

[3]  J. Palais,et al.  Scanned beam holography. , 1970, Applied optics.

[4]  Sylvia H. Stevenson,et al.  Improved process of reflection holography replication and heat processing , 1994, Electronic Imaging.

[5]  Friedrich-Karl Bruder,et al.  Reaction-diffusion model applied to high resolution Bayfol HX photopolymer , 2010, OPTO.

[6]  Y. Hwang,et al.  Time-sequential autostereoscopic 3-D display with a novel directional backlight system based on volume-holographic optical elements. , 2014, Optics express.

[7]  Douglas F. Tipton,et al.  Machine for continuous hologram production , 1993, Electronic Imaging.

[8]  Friedrich-Karl Bruder,et al.  Holographic recordings with high beam ratios on improved Bayfol® HX photopolymer , 2013, Europe Optics + Optoelectronics.

[9]  Andrea Bianco,et al.  Photopolymer based VPHGs: from materials to sky results , 2016, Astronomical Telescopes + Instrumentation.

[10]  Bernard Kress,et al.  Restocking the optical designers' toolbox for next-generation wearable displays (Presentation Recording) , 2015, SPIE Optical Engineering + Applications.

[11]  Friedrich-Karl Bruder,et al.  Precision holographic optical elements in Bayfol HX photopolymer , 2016, SPIE OPTO.

[12]  Izabela Naydenova,et al.  Using acrylamide-based photopolymers for fabrication of holographic optical elements in solar energy applications. , 2014, Applied optics.

[13]  Sheridan,et al.  Nonlocal-response diffusion model of holographic recording in photopolymer , 2000, Journal of the Optical Society of America. A, Optics, image science, and vision.

[14]  Thomas Rölle,et al.  Holographic recording aspects of high-resolution Bayfol HX photopolymer , 2011, OPTO.

[15]  Raymond K. Kostuk,et al.  Thermal effects of the extended holographic regions for holographic planar concentrator , 2011 .

[16]  Petr Vojtíšek,et al.  Impact of overmodulation on spectral response in high efficient transmission gratings , 2015, Other Conferences.

[17]  Douglas F. Tipton New hologram replicator for volume holograms and holographic optical elements , 1998, Electronic Imaging.

[18]  Friedrich-Karl Bruder,et al.  Bayfol HX photopolymer for full-color transmission volume Bragg gratings , 2014, Photonics West - Optoelectronic Materials and Devices.