A fast optical propagation technique for modeling micro-optical systems

Author

Kurzweg, Timothy P. ; Levitan, Steven P. ; Martinez, Jose A. ; Kahrs, Mark ; Chiarulli, Donald M.

Author_Institution

Dept. of Electr. Eng., Pittsburgh Univ., PA, USA

fYear

2002

fDate

2002

Firstpage

236

Lastpage

241

Abstract

As designers become more aggressive in introducing optical components to micro-systems, rigorous optical models are required for system-level simulation tools. Common optical modeling techniques and approximations are not valid for most optical micro-systems, and those techniques that provide accurate simulation are computationally slow. In this paper, we introduce an angular frequency optical propagation technique that greatly reduces computation time while achieving the accuracy of a full scalar formulation. We present simulations of a diffractive optical MEM grating light valve to show the advantages of this optical propagation method and the integration of the technique into a system-level multi-domain CAD tool.

Keywords

CAD; diffractive optical elements; light propagation; light valves; micro-optics; optical engineering computing; angular frequency optical propagation technique; computation time reduction; diffractive optical MEM grating light valve; fast optical propagation technique; full scalar formulation; micro-optical system modeling; optical MEMS; rigorous optical models; system-level multi-domain CAD tool; system-level simulation tools; Computational modeling; Diffraction gratings; Frequency; Integrated optics; Optical computing; Optical design; Optical devices; Optical diffraction; Optical propagation; Valves;

fLanguage

English

Publisher

ieee

Conference_Titel

Design Automation Conference, 2002. Proceedings. 39th

ISSN

0738-100X

Print_ISBN

1-58113-461-4

Type

conf

DOI

10.1109/DAC.2002.1012627

Filename

1012627