Realization of All-Optical Full Adder and Subtractor Circuit based on Cross-Phase Modulation in a Phase-Shifted Fiber Bragg Grating

被引:0
作者
Singh, Raj Ranjan [1 ]
Kumar, Ajay [1 ]
Singh, Shiva Nand [2 ]
Yadav, Ajay [1 ]
机构
[1] Natl Inst Technol Jamshedpur, Dept Elect & Commun Engn, Fiber Opt Lab, Jamshedpur 831014, Jharkhand, India
[2] Natl Inst Technol Jamshedpur, Dept Elect & Commun Engn, Jamshedpur 831014, Jharkhand, India
关键词
Fiber Bragg Grating; Cross-phase modulation; phase-shifted FBG; Full adder and subtractor; MACH-ZEHNDER INTERFEROMETER; LOGIC GATES; FLIP-FLOP; DESIGN; IMPLEMENTATION; SWITCH; TEMPERATURE;
D O I
10.56042/ijpap.v62i6.7996
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
This study presents a technique for implementing all-optical Full Adder (FA) and Full Subtractor (FS) functionalities utilizing a Fiber Bragg Grating (FBG) structure. The proposed method exploits the cross-phase modulation (XPM) mechanism within a phase-shifted FBG (PSFBG) configuration. An analysis of basic gate operations and corresponding switching phenomena is provided, along with the optimization and implementation of FA and FS circuits using the PSFBG structure. Extensive simulations, validated against conventional circuits and truth tables, demonstrate the efficacy of the proposed approach. The coupled-mode theory governing FBG behavior as an optical switching element is elucidated, along with mathematical descriptions of FBG and PSFBG functionalities for switching applications. MATLAB simulations are employed for comprehensive analysis and validation of the proposed all-optical FA and FS schemes. This work contributes to the advancement of all-optical computing techniques, facilitating efficient high-speed data processing with notable optical communication benefits.
引用
收藏
页码:464 / 477
页数:14
相关论文
共 50 条
  • [21] Optical computation of the Laplace operator using phase-shifted Bragg grating
    Bykov, Dmitry A.
    Doskolovich, Leonid L.
    Bezus, Evgeni A.
    Soifer, Victor A.
    OPTICS EXPRESS, 2014, 22 (21): : 25084 - 25092
  • [22] Tunable phase-shifted fiber Bragg grating based on a microchannel fabricated by a femtosecond laser
    Zeng, Li
    Sun, Xiaoyan
    Chang, Zikun
    Hu, Youwang
    Duan, Ji'an
    CHINESE OPTICS LETTERS, 2021, 19 (03)
  • [23] Study of a single longitudinal fiber ring laser with a π phase-shifted fiber Bragg grating
    Wang, Weitao
    Song, Zhigiang
    Qi, Haifeng
    Zhang, Xiaolei
    Ni, Jiasheng
    Guo, Jian
    Wang, Chang
    Peng, Gangding
    OPTICS COMMUNICATIONS, 2017, 396 : 88 - 91
  • [24] Fabrication of Phase-Shifted Fiber Bragg Grating by Femtosecond Laser Shield Method
    Du, Yong
    Chen, Tao
    Zhang, Yueli
    Wang, Ruize
    Cao, Houjun
    Li, Kaidi
    IEEE PHOTONICS TECHNOLOGY LETTERS, 2017, 29 (24) : 2143 - 2146
  • [25] Fiber optic transverse load sensor based on polarization properties of π-phase-shifted fiber Bragg grating
    Wang, Yiping
    Li, Na
    Huang, Xiaoqin
    Wang, Ming
    OPTICS COMMUNICATIONS, 2015, 342 : 152 - 156
  • [26] Fiber-optic refractometer based on a phase-shifted fiber Bragg grating on a side-hole fiber
    Zhang, Qi
    Hu, Lingling
    Qi, Yuefeng
    Liu, Guigen
    Ianno, Natale
    Han, Ming
    OPTICS EXPRESS, 2015, 23 (13): : 16750 - 16759
  • [27] Analysis of Raman assisted all-optical wavelength conversion by cross-phase modulation in high nonlinear fiber
    Wang, Lili
    Xin, Xiangjun
    Liu, Hai
    OPTICAL ENGINEERING, 2013, 52 (10)
  • [28] Silicon-Based All-Optical Fredkin Gate Using Cross-Phase Modulation Effect
    Yu Ruolan
    Li Jun
    Chen Weiwei
    Wang Pengjun
    ACTA OPTICA SINICA, 2021, 41 (09)
  • [29] All-optical wavelength conversion based on cascaded effect of cross-gain modulation and cross-phase modulation in SOAs
    Wu Zhaoxi
    Huang Yuanqing
    Weng Zihua
    Ye Ruifang
    INTERNATIONAL SYMPOSIUM ON PHOTOELECTRONIC DETECTION AND IMAGING 2007: RELATED TECHNOLOGIES AND APPLICATIONS, 2008, 6625
  • [30] Spatial optical integrator based on phase-shifted Bragg gratings
    Golovastikov, Nikita V.
    Bykov, Dmitry A.
    Doskolovich, Leonid L.
    Bezus, Evgeni A.
    OPTICS COMMUNICATIONS, 2015, 338 : 457 - 460