VCSEL Industry. Babu Dayal Padullaparthi. Читать онлайн. Newlib. NEWLIB.NET

Автор: Babu Dayal Padullaparthi
Издательство: John Wiley & Sons Limited
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Жанр произведения: Техническая литература
Год издания: 0
isbn: 9781119782216
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This was proposed by Kenichi Iga in 1977, and the first paper on its realization, written by Haruhisa Soda, Kenichi Iga, Chiyuki Kitahara, and Yasuharu Suematsu, came out in 1979 [1]. This paper was a key milestone for the birth of the vertical‐cavity surface‐emitting laser, or VCSEL, as we now call it. As a longtime worker in fiber optics communications, I realize that the geometry of “the conventional laser” was deeply ingrained in the mindset of system engineers. The design, alignment, and packaging of an end‐to‐end fiber optics system were by and large catered to the concept that the laser light output is parallel to the wafer surface.

      Following breakthroughs of the first room‐temperature CW operation of VCSELs [2] and the first experimental demonstration of a 2D VCSEL array [3], worldwide VCSEL R&D was kick‐started in the early 1990s. In 2000, DARPA managers Elias Towe, Robert F. Leheny, and Andrew Yang wrote the following about VCSEL in their review paper [4]: “Its size, manufacturability, and potential ease of heterogeneous integration of electronics promise a range of applications that have yet to be explored.” This was the time DARPA invested considerable human and monetary resources in the R&D of VCSELs, in particular the massive integration of VCSELs, detectors, micro‐optics, and driving electronics for optical backplanes, free‐space optical interconnections, and all optical switching. While these applications did not emerge immediately, the DARPA funding impetus did drive widespread commercialization efforts.

      The first commercial VCSELs, offered by Honeywell in 1996, were driven by the emerging demand for global bandwidth [5] that is now fueled by the need for low‐cost data center communications with the worldwide construction of giant data centers by cloud computing companies such as Google, Amazon AWS, Facebook, and Alibaba. First generation VCSELs operated at 1 Gbps and have since evolved to datalink or active optical cables operating at 25 Gb/s NRZ modulation and 50 Gb/s PAM4 modulation for a single channel. Spectral and spatial multiplexing results in bandwidth expansions from 25 Gb/s to more than 400 Gb/s optical networks using multiple channels over a distance of several hundred meters. Another application in optical communications is in the widespread deployment of radio access network (RAN) in 4G and 5G LTE wireless fronthaul networks.

      With VCSELs now representing a multibillion‐dollar global industry and worldwide interest in VCSEL’s commercial usage, it is timely to write a book covering these wide range of applications and help to stimulate other novel applications. We are very fortunate and deeply honored to have Dr. Babu Dayal Padullaparthi, Dr. Jim Tatum, and Professor Kenichi Iga, a team of VCSEL experts who kindly agreed to write the book for Wiley‐IEEE Press. Professor Iga is none other than the original VCSEL pioneer and author of the 1979 paper mentioned earlier. These three outstanding researchers have a collective amount of experience in academic and industrial research as well as commercial productization of VCSEL spanning the past four decades. They will provide the readers with a historical perspective and current state‐of‐the‐art technology and product status of the field. Through the authors’ extensive contacts with leading VCSEL manufacturers worldwide, the book will also present an up‐to‐date picture of R&D and product trends for both researchers and practicing engineers. I am confident that the readers will find this book an enjoyable tutorial and product reference covering the long and exciting journey of VCSELs.

      Nim Cheung

      Series Editor, Wiley‐IEEE Press

      November 23, 2020

      1 1 H. Soda, K. Iga, C. Kitahara, and Y. Suematsu, ‘GaInAsP/InP surface emitting injection lasers’, Jpn. J. App. Phys., Vol. 18, No. 12, Pages 2329–2330 (1979)

      2 2 F. Koyama, S. Kinoshita and K. Iga, ‘Room temperature CW operation of GaAs vertical cavity surface emitting laser’, IEICE Trans., E71, 1089–1090 (1988)

      3 3 Y. H. Lee, J. L. Jewell, A. Scherer et al., ‘Room‐Tempreature, Continuous‐Wave Vertical‐Cavity Single‐Quantum‐Well Microlaser Diodes’, Electronics Letters 25, No. 20 Pages 1377–1378 (1989)

      4 4 E. Towe, R. F. Leheny, and A. Yang, ‘A historical perspective of the development of the vertical‐cavity surface‐emitting laser’, IEEE J. Sel. Top Quantum Electron., Vol. 6, No. 6, Pages 1458–1464 (2000)

      5 5 J. A. Tatum, A. Clark, J. K. Guenter, R. A. Hawthorne, and R. H. Johnson, ‘Commercialization of Honeywell's VCSEL technology,’ Proc. SPIE3946 2–13 (2000)

      6 6 B. D. Padullaparthi, R. Chen, A. Tan et al. ‘High Volume Manufacturing of VCSELs for Datacom & Sensing’, Industry Panel Discussions, Th4, pp: 51, International Nano‐Optoelectronics Workshop (i‐NOW) 2018, UC Berkeley, USA.

      Preface

      A vertical‐cavity surface‐emitting laser (VCSEL) is experiencing rapid growth followed by applications mostly in communication and sensing. This book describes the industrial technologies driven by the rapid expansion of the information age and the extension into rapidly emerging areas of AI (artificial intelligence) and IoT (Internet of Things).

      The VCSEL was first conceived in 1977 by Kenichi Iga, one of the authors and while the device itself is smaller than a sesame seed, its impact on the world is profound. The unique advantages of small size, surface normal emission, and scalability into 1D and 2D arrays are hallmarks of the device. The name VCSEL was chosen because the light is emitted perpendicular to the wafer, and the pronunciation as “viksel” is reminiscent of a pixel in the scalability into large 2D structures.

      Iga has continued basic research on VCSELs ever since its invention and witnessed commercialization in 1996 as the Internet began its rapid expansion. The first VCSEL products were in optical transceivers used in data centers, which support the modern information age. Along with the spread of the Internet, information‐related companies now own huge information storage centers called the cloud (a mechanism for storing information in memory, such as hard disks, to read and use it). High‐speed optical fiber networks exchange large volumes of information to and from data centers. Each of these data centers may contain many hundreds of thousands of VCSEL‐based optical interconnects. In fact, VCSELs today provide more than 50 Mbps of connectivity for every person on earth.

      In addition, many computer users have a mouse, which uses an optical source and a camera to track its position movement. The number of units produced so far is more than 1.1 billion. In 2017, the VCSEL was also adopted by the iPhone X for facial recognition. More recently, a laser RADAR (LiDAR) is being implemented in smartphones and iPads to enable AI and augmented reality. A new era of optical sensing was born taking advantage of the VCSEL’s small volume, low power consumption,