95 GHz millimeter wave signal generation using an arrayed waveguide grating dual wavelength semiconductor laser

被引:37
作者
Carpintero, Guillermo [1 ]
Rouvalis, Efthymios [2 ]
Lawniczuk, Katarzyna [3 ,5 ]
Fice, Martyn [2 ]
Renaud, Cyril C. [2 ]
Leijtens, Xaveer J. M. [3 ]
Bente, Erwin A. J. M. [3 ]
Chitoui, Mourad [4 ]
Van Dijk, Frederic [4 ]
Seeds, Alwyn J. [2 ]
机构
[1] Univ Carlos III Madrid, Dept Tecnol Elect, Madrid 28911, Spain
[2] UCL, Dept Elect & Elect Engn, London WC1E 7JE, England
[3] Eindhoven Univ Technol, COBRA Res Inst, PhI Grp, NL-5612 AZ Eindhoven, Netherlands
[4] III V Lab, F-91767 Palaiseau, France
[5] Warsaw Univ Technol, Inst Microelect & Optoelect, Warsaw, Poland
来源
OPTICS LETTERS | 2012年 / 37卷 / 17期
基金
英国工程与自然科学研究理事会;
关键词
TRANSMISSION;
D O I
10.1364/OL.37.003657
中图分类号
O43 [光学];
学科分类号
070207 ; 0803 ;
摘要
We report the generation of a 95 GHz carrier frequency by optical heterodyning of two wavelengths from adjacent channels from an arrayed waveguide grating-based multiwavelength laser. The extended cavity structure of the device provides low phase noise and narrow optical linewidth, further enhanced by the intracavity filter effect of the arrayed waveguide grating. We demonstrate that the generated RF beat note, at 95 GHz, has a -3 dB linewidth of 250 kHz. To the best of our knowledge, this is the narrowest RF linewidth generated from a free-running dual-wavelength semiconductor laser. The device is realized as a photonic integrated circuit using active-passive integration technology, and fabricated on a multiproject wafer run, constituting a novel approach for a compact, low-cost dual-wavelength heterodyne source. (c) 2012 Optical Society of America
引用
收藏
页码:3657 / 3659
页数:3
相关论文
共 10 条
[1]   Optical microwave generation and transmission experiments in the 12- and 60-GHz region for wireless communications [J].
Braun, RP ;
Grosskopf, G ;
Heidrich, H ;
von Helmolt, C ;
Kaiser, R ;
Kruger, K ;
Kruger, U ;
Rohde, D ;
Schmidt, F ;
Stenzel, R ;
Trommer, D .
IEEE TRANSACTIONS ON MICROWAVE THEORY AND TECHNIQUES, 1998, 46 (04) :320-330
[2]   SINGLE LONGITUDINAL-MODE STABILITY VIA WAVE MIXING IN LONG-CAVITY SEMICONDUCTOR-LASERS [J].
DOERR, CR ;
ZIRNGIBL, M ;
JOYNER, CH .
IEEE PHOTONICS TECHNOLOGY LETTERS, 1995, 7 (09) :962-964
[3]   Generation and transmission of millimeter-wave data-modulated optical signals using an optical injection phase-lock loop [J].
Johansson, LA ;
Seeds, AJ .
JOURNAL OF LIGHTWAVE TECHNOLOGY, 2003, 21 (02) :511-520
[4]  
Lawniczuk K., 2011, P 23 INT C IND PHOSP
[5]  
Nagatsuma T., 2007, P 19 INT C APPL EL C, P1
[6]   Dual-wavelength InAlGaAs-InP laterally coupled distributed feedback laser [J].
Pozzi, Francesca ;
De La Rue, Richard M. ;
Sorel, Marc .
IEEE PHOTONICS TECHNOLOGY LETTERS, 2006, 18 (21-24) :2563-2565
[7]   Dual-wavelength InGaAs-GaAs ridge waveguide distributed Bragg reflector lasers with tunable mode separation [J].
Roh, SD ;
Yeoh, TS ;
Swint, RB ;
Huber, AE ;
Woo, CY ;
Hughes, JS ;
Coleman, JJ .
IEEE PHOTONICS TECHNOLOGY LETTERS, 2000, 12 (10) :1307-1309
[8]   High-speed photodiodes for InP-based photonic integrated circuits [J].
Rouvalis, E. ;
Chtioui, M. ;
Tran, M. ;
Lelarge, F. ;
van Dijk, F. ;
Fice, M. J. ;
Renaud, C. C. ;
Carpintero, G. ;
Seeds, A. J. .
OPTICS EXPRESS, 2012, 20 (08) :9172-9177
[9]  
Stoehr A., 2010, P IEEE TOP M MICR PH, P7
[10]  
van Dijk F., 2011, 2011 IEEE International Topical Meeting on Microwave Photonics (MWP 2011) jointly held with the 2011 Asia-Pacific Microwave Photonics Conference (APMP 2011), P73, DOI 10.1109/MWP.2011.6088672
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