Mode Multiplication of Cylindrical Vector Beam Using Raytracing Control

IF 3.5 2区 物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY Chinese Physics Letters Pub Date : 2024-08-31 DOI:10.1088/0256-307x/41/9/094202
Jing Wang, 晶 王, Qingji Zeng, 庆计 曾, Haisheng Wu, 海生 吴, Chuangxin Xie, 创鑫 谢, Huapeng Ye, 华朋 叶, Ze Dong, 泽 董, Dianyuan Fan, 滇元 范, Shuqing Chen and 书青 陈
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Abstract

Cylindrical vector beams (CVBs) hold significant promise in mode division multiplexing communication owing to their inherent vector mode orthogonality. However, existing studies for facilitating CVB channel processing are confined to mode shift conversions due to their reliance on spin-dependent helical modulations, overlooking the pursuit of mode multiplication conversion. This challenge lies in the multiplicative operation upon inhomogeneous vector mode manipulation, which is expected to advance versatile CVB channel switching and routing. Here, we tackle this gap by introducing a raytracing control strategy that conformally maps the light rays of CVB from the whole annulus distribution to an annular sector counterpart. Incorporated with the multifold conformal annulus-sector mappings and polarization-insensitive phase modulations, this approach facilitates the parallel transformation of input CVB into multiple complementary components, enabling the mode multiplication conversion with protected vector structure. Serving as a demonstration, we experimentally implemented the multiplicative operation of four CVB modes with the multiplier factors of N = +2 and N = –3, achieving the converted mode purities over 94.24% and 88.37%. Subsequently, 200 Gbit/s quadrature phase shift keying signals were successfully transmitted upon multiplicative switching of four CVB channels, with the bit-error-rate approaching 1 × 10−6. These results underscore our strategy’s efficacy in CVB mode multiplication, which may open promising prospects for its advanced applications.
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利用光线跟踪控制实现圆柱矢量光束的模式倍增
圆柱矢量波束(CVB)因其固有的矢量模式正交性,在模分复用通信中大有可为。然而,现有的促进 CVB 信道处理的研究仅限于模式偏移转换,因为它们依赖于自旋相关螺旋调制,忽略了对模式乘法转换的追求。这一挑战在于非均质矢量模式操作的乘法运算,它有望推动多功能 CVB 信道切换和路由选择。在此,我们引入了一种光线跟踪控制策略,将 CVB 的光线从整个环面分布保形映射到对应的环形扇面上,从而弥补了这一不足。结合多倍共形环形扇形映射和偏振不敏感的相位调制,这种方法有助于将输入 CVB 并行转换为多个互补分量,从而实现具有保护矢量结构的模式乘法转换。作为演示,我们通过实验实现了乘法因子为 N = +2 和 N = -3 的四种 CVB 模式的乘法运算,转换后的模式纯度分别超过 94.24% 和 88.37%。随后,通过四个 CVB 信道的乘法切换,成功传输了 200 Gbit/s 的正交相移键控信号,误码率接近 1 × 10-6。这些结果凸显了我们的策略在 CVB 模式乘法中的功效,为其高级应用开辟了广阔前景。
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来源期刊
Chinese Physics Letters
Chinese Physics Letters 物理-物理:综合
CiteScore
5.90
自引率
8.60%
发文量
13238
审稿时长
4 months
期刊介绍: Chinese Physics Letters provides rapid publication of short reports and important research in all fields of physics and is published by the Chinese Physical Society and hosted online by IOP Publishing.
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