本征广义琼斯矩阵方法

宋东升; 郑远林; 刘虎; 胡维星; 张志云; 陈险峰

doi:doi:10.3788/CO.2019-0163

中国光学, 2020, 13 (3): 637, 网络出版: 2020-08-17

本征广义琼斯矩阵方法下载： 690次

Eigen generalized Jones matrix method

宋东升 ^1,2,3,*郑远林 ^2,3刘虎 ¹胡维星 ¹张志云 ¹陈险峰 ^2,3

作者单位

¹ 中国洛阳电子对抗试验中心，河南洛阳 471000

² 上海交通大学物理与天文学院先进光通讯网络与系统国家重点实验室，上海 200240

³ 上海交通大学激光等离子体重点实验室 IFSA协作创新中心，上海 200240

图 & 表

图 1.

Fig. 1. Schematic diagram of the three coordinate systems. The black, blue, and red axes represent the laboratory, principal, and eigen coordinates, respectively. z₁ and z₂ are the optical axes.

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图 2.

Fig. 2. Spatial distributions of the polarization state. (a) Original linear polarization. (b) Left(right) polarization. (c) Circular polarization. (d) Right(left) polarization. (e) Opposite linear polarization.

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图 3.

Fig. 3. Change in walk-off angle with θ_z.

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图 4.

Fig. 4. Spatial distributions of the polarization state with a right direction walk-off effect. (a) Original linear polarization. (b) Left (right) polarization. (c) Circular polarization. (d) Right (left) polarization. (e) Opposite linear polarization.

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图 5.

Fig. 5. Change in walk-off angle with (θ, φ)

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图 6.

Fig. 6. Spatial distributions of the polarization state with a upward-right direction walk-off effect. (a) Original linear polarization. (b) Left(right) polarization. (c) Circular polarization. (d) Right(left) polarization. (e) Opposite linear polarization.

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图 7.

Fig. 7. Phase difference and polarization. (a) Phase difference of the refracted light beam in birefringent crystals. (b) Polarization of reflection and refracted light beam at the interface in birefringent crystals.

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图 8.

Fig. 8. (a) Experimental image and (b) simulation results of proposed method.

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宋东升, 郑远林, 刘虎, 胡维星, 张志云, 陈险峰. 本征广义琼斯矩阵方法[J]. 中国光学, 2020, 13(3): 637. Dong-sheng SONG, Yuan-lin ZHENG, Hu LIU, Wei-xing HU, Zhi-yun ZHANG, Xian-feng CHEN. Eigen generalized Jones matrix method[J]. Chinese Optics, 2020, 13(3): 637.

本征广义琼斯矩阵方法下载： 690次

图 1.

Fig. 1. Schematic diagram of the three coordinate systems. The black, blue, and red axes represent the laboratory, principal, and eigen coordinates, respectively. z₁ and z₂ are the optical axes.

图 2.

Fig. 2. Spatial distributions of the polarization state. (a) Original linear polarization. (b) Left(right) polarization. (c) Circular polarization. (d) Right(left) polarization. (e) Opposite linear polarization.

图 3.

Fig. 3. Change in walk-off angle with θ_z.

图 4.

Fig. 4. Spatial distributions of the polarization state with a right direction walk-off effect. (a) Original linear polarization. (b) Left (right) polarization. (c) Circular polarization. (d) Right (left) polarization. (e) Opposite linear polarization.

图 5.

Fig. 5. Change in walk-off angle with (θ, φ)

图 6.

Fig. 6. Spatial distributions of the polarization state with a upward-right direction walk-off effect. (a) Original linear polarization. (b) Left(right) polarization. (c) Circular polarization. (d) Right(left) polarization. (e) Opposite linear polarization.

图 7.

Fig. 7. Phase difference and polarization. (a) Phase difference of the refracted light beam in birefringent crystals. (b) Polarization of reflection and refracted light beam at the interface in birefringent crystals.

图 8.

Fig. 8. (a) Experimental image and (b) simulation results of proposed method.

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图 1.

Fig. 1. Schematic diagram of the three coordinate systems. The black, blue, and red axes represent the laboratory, principal, and eigen coordinates, respectively. z1 and z2 are the optical axes.

图 2.

Fig. 2. Spatial distributions of the polarization state. (a) Original linear polarization. (b) Left(right) polarization. (c) Circular polarization. (d) Right(left) polarization. (e) Opposite linear polarization.

图 3.

Fig. 3. Change in walk-off angle with θz.

图 4.

Fig. 4. Spatial distributions of the polarization state with a right direction walk-off effect. (a) Original linear polarization. (b) Left (right) polarization. (c) Circular polarization. (d) Right (left) polarization. (e) Opposite linear polarization.

图 5.

Fig. 5. Change in walk-off angle with (θ, φ)

图 6.

Fig. 6. Spatial distributions of the polarization state with a upward-right direction walk-off effect. (a) Original linear polarization. (b) Left(right) polarization. (c) Circular polarization. (d) Right(left) polarization. (e) Opposite linear polarization.

图 7.

Fig. 7. Phase difference and polarization. (a) Phase difference of the refracted light beam in birefringent crystals. (b) Polarization of reflection and refracted light beam at the interface in birefringent crystals.

图 8.

Fig. 8. (a) Experimental image and (b) simulation results of proposed method.

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本征广义琼斯矩阵方法下载： 690次

Fig. 1. Schematic diagram of the three coordinate systems. The black, blue, and red axes represent the laboratory, principal, and eigen coordinates, respectively. z₁ and z₂ are the optical axes.

Fig. 3. Change in walk-off angle with θ_z.