Dispersion-tolerant millimeter-wave photonic link using polarization-dependent modulation

被引：12

作者：

Wiberg, Andreas ^{[1
]}

Olsson, Bengt-Erik

Hedekvist, Per Olof

Andrekson, Peter A.

机构：

[1] Chalmers, Photon Lab, Dept Microtechnol & Nanosci, S-41281 Gothenburg, Sweden

[2] Ericcson AB, Ericcson Res, SE-43164 Molndal, Sweden

[3] SP Tech Res Inst Sweden, Measurement Technol Commun Labs, S-50115 Boras, Sweden

来源：

JOURNAL OF LIGHTWAVE TECHNOLOGY | 2007年 / 25卷 / 10期

关键词：

analog systems; fiber-optic millimeter-wave (nun-wave) link; microwave photonics; mm-wave communications; optical fiber communication; phase modulation; polarization modulation; wireless communication;

D O I：

10.1109/JLT.2007.904935

中图分类号：

TM [电工技术]; TN [电子技术、通信技术];

学科分类号：

0808 ; 0809 ;

摘要：

A novel technique to modulate one carrier in a millimeter-wave (mm-wave) photonic system is presented and experimentally evaluated. The technique utilizes the polarization dependence of an optical phase modulator and the properties of optical heterodyning and is demonstrated for both amplitude- and phase-modulated mm-wave signal outputs. Experimental verification of the technique is presented with transmission of up to 2.5-Gb/s nonreturn-to-zero data, multilevel quadratic-amplitude modulation, and IEEE 802.11a WLAN data signals on a 40-GHz carrier over optical fiber and wireless transmission. The tolerance for fiber dispersion is investigated, and penalty-free transmission over 44 km is verified. The linearity of the system is evaluated by measuring the spurious-free dynamic range.

引用

页码：2984 / 2991

页数：8

共 50 条

[11] Energy efficient photonic millimeter-wave generation using cascaded polarization modulators
Gazi Mahamud Hasan
Mehedi Hasan
Hongpeng Shang
DeGui Sun
Karin Hinzer
Peng Liu
Trevor Hall
Optical and Quantum Electronics, 2019, 51
[12] Energy efficient photonic millimeter-wave generation using cascaded polarization modulators
Hasan, Gazi Mahamud
Hasan, Mehedi
Shang, Hongpeng
Sun, DeGui
Hinzer, Karin
Liu, Peng
Hall, Trevor
OPTICAL AND QUANTUM ELECTRONICS, 2019, 51 (07)
[13] Simultaneous Improvements of Gain and Linearity in Dispersion-Tolerant Phase-Modulated Analog Photonic Link
Xie, Zhipeng
Yu, Song
Cai, Shanyong
Gu, Wanyi
IEEE PHOTONICS JOURNAL, 2017, 9 (01):
[14] Millimeter-wave imaging using photonic techniques
Sasaki, A
Nagatsuma, T
NTT REVIEW, 2002, 14 (06): : 32 - 41
[15] Polarization-dependent two-color dispersion wave generation and evolution in polarization-maintaining photonic crystal fiber
Wang, Helin
Leng, Yuxin
Xu, Zhizhan
Hu, Ming-lie
Wang, Ching-yue
LASER PHYSICS, 2009, 19 (05) : 993 - 1001
[16] Polarization-dependent or -independent Two-color Dispersion Wave generation in Polarization-maintaining Photonic Crystal Fiber
Wang, Helin
Leng, Yuxin
Xu, Zhizhan
2009 LASERS & ELECTRO-OPTICS & THE PACIFIC RIM CONFERENCE ON LASERS AND ELECTRO-OPTICS, VOLS 1 AND 2, 2009, : 682 - 683
[17] Photonic generation of frequency-quadrupling millimeter-wave signals using polarization property
Zhu, Min
Tang, Xianfeng
Xi, Lixia
Zhang, Wenbo
Zhang, Xiaoguang
OPTICAL ENGINEERING, 2016, 55 (03)
[18] Photonic generation of phase-coded millimeter-wave signal using a polarization modulator
Chi, Hao
Yao, Jianping
IEEE MICROWAVE AND WIRELESS COMPONENTS LETTERS, 2008, 18 (05) : 371 - 373
[19] Photonic generation of millimeter-wave and multi-waveform signals based on external modulation and polarization control
Yuan, Jin
Zhang, Mengsi
Mei, Ying
Liu, Qisong
Liu, Jinbo
APPLIED OPTICS, 2022, 61 (30) : 8967 - 8973
[20] An 80 Gbps multi-band access radio over fiber link with single side band optical millimeter-wave dispersion-tolerant transmission without FBG and optical filter
Asha, R. S.
Jayasree, V. K.
Mhatli, S.
OPTO-ELECTRONICS REVIEW, 2017, 25 (04) : 311 - 317

← 1 2 3 4 5 →