Structure Design and Finite Element Analysis of Receiving System for Optical Communication

Shu Bin Liu; Tian Yuan Gao; Ya Bo Wu

doi:10.4028/www.scientific.net/KEM.552.548

Paper Titles

Distorted Target Recognition Based on Prewitt Operator Combined with MACH Filter
p.523

Optical Correlation Recognition Research of Low Light Level Target Based on Lifting Wavelet Transform
p.529

Optical Correlation Recognition Technology of Small Moving Target Based on Wavelet Multi-Scale Edge Fusion
p.536

Fast Tracking of Moving Target Combining SURF and Cluster Analysis
p.542

Structure Design and Finite Element Analysis of Receiving System for Optical Communication
p.548

Design Calculation of Micro-Displacement Amplifier Mechanism Based on Bridge Flexure Hinge
p.554

Research on the Technology of Partial Masked Target Recognition
p.560

On-Machine Measurementand Characterization of V-Groove Structure Pattern on Precision Rollers
p.567

A Study of Effect of Cutting Strategy on Surface Generation in Ultra-Precision Machining of Micro-Structured Pattern Rollers
p.575

HomeKey Engineering MaterialsKey Engineering Materials Vol. 552Structure Design and Finite Element Analysis of...

Structure Design and Finite Element Analysis of Receiving System for Optical Communication

Abstract:

Along with the rapid development of science and technology, and due to the special advantage of laser communication, such as big traffic and good secrecy, the application of optical communication is more and more wide. One of key technologies is the structure design of receiving system. In this paper, a structure of receiving system for optical communication based on Cassegrain system is introduced. Consist of the support structure of primary mirror and secondary mirror, adjustment structure of secondary mirror, structure design of reflectors, etc. FEM is used to analyze the distortion of primary mirror which is based on this structure. The distortion is caused by pressure, self-weight and temperature change, etc. And the stress deformation of primary mirror tube is analysed particularly. Analysis and test results demonstrate that the design project is reasonable.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Key Engineering Materials (Volume 552)

Pages:

548-553

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.552.548

Citation:

Cite this paper

Online since:

May 2013

Authors:

Shu Bin Liu, Tian Yuan Gao, Ya Bo Wu

Keywords:

Distortion, Finite Element Analysis (FEA), Optical Communication, Structure of Cassegrain System

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] CHEN Jian-wen. Design and realization for space optical communication syatem. Opto-Electronic Engineering. 2004, Vol.31, No.9

Google Scholar

[2] Zhang Lei. Design of supporting structure for cassegrain system used in space optical communication. Chinese Journal of Scientific Instrument. June, 2006.

Google Scholar

[3] ZHANG Xue-jun. Space telescope aspherical mirror structure design based on SiC material. Infrared and Laser Engineering. Oct, 2007.

Google Scholar

[4] Paul R.Yoder,Jr. Optical-Mechanical Systems Design. China Machine Press.

Google Scholar

[5] Luc Arnold. Optimized axial support topologies for thin telescope mirrors [J]. OPTICAL ENGINEERING, 1995, 34( 2) : 567-574.

DOI: 10.1117/12.194034

Google Scholar

[6] Liu Zhiying, Fu Yuegang, New Optical System Design for Laser Communication in Space, 2005.10 ISTM[C] 2005.

Google Scholar

[7] Zhang Lei. Design of supporting structure for cassegrain system used in space optical communication. Chinese Journal of Scientific Instrument, June. (2006)

Google Scholar

[8] ZHANG Si-yao. Structure design of base station for fixed wireless wireless laser communications. Journal of Applied Optics, Dec.(2011)

Google Scholar

[9] Information on http://www.cnki.net/

Google Scholar