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Mueller matrix analysis for all optical fiber co-existence of birefringence-polarization dependent gain-mode coupling at a single wavelength |
| Shang Chao(尚超), Wu Chong-Qing(吴重庆)†, Li Zheng-Yong(李政勇), Yang Shuang-Shou(杨双收), Gao Kai-Qiang(高凯强), Yu Kuang-Lu(余贶琭), and Feng Zhen(冯震) |
| Key Laboratory of Education Ministry on Luminescence and Optical Information Technology, Institute of Optical Information, Beijing Jiaotong University, Beijing 100044, China |
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Abstract Birefringence (polarization-related phase-shift), polarization dependent gain (PDG) and mode coupling are three factors that may synchronously influence the transmission of single-wavelength polarized light in optical fibers. This paper obtains a new Mueller matrix analysis, which can be used under conditions that all these three factors are existing and changing. According to our transmission model, the state of polarization (SOP) changes along an optical microstructure fiber with co-existence of birefringence-PDG-mode coupling were simulated. The simulated results, which show the phenomena of SOP constringency, are in good agreement with previous theoretical analyses.
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Received: 14 January 2011
Revised: 05 May 2011
Accepted manuscript online:
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PACS:
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02.10.Yn
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(Matrix theory)
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42.81.-i
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(Fiber optics)
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| Fund: Project supported by the National Natural Science Foundation of China (Grants Nos. 60877057 and 60907027). |
Cite this article:
Shang Chao(尚超), Wu Chong-Qing(吴重庆), Li Zheng-Yong(李政勇), Yang Shuang-Shou(杨双收), Gao Kai-Qiang(高凯强), Yu Kuang-Lu(余贶琭), and Feng Zhen(冯震) Mueller matrix analysis for all optical fiber co-existence of birefringence-polarization dependent gain-mode coupling at a single wavelength 2011 Chin. Phys. B 20 110201
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