100G Components User Survey: Market Outlook
|出版日||ページ情報||英文 20 Pages
個人用ブロードバンド・モバイルデータのデータ帯域幅の急拡大や、ネット接続型ビジネスの急成長に伴い、100Gbit/s (100G) ネットワーク接続の需要が拡大しています。サービスプロバイダーはデータセンターや企業用・都市用・ロングホール向けネットワークに100G接続を設置しています。現在、多くのシステムがラインカード1枚当たり4つ以上の100G向けインターフェースを有しており、デバイス1個当たり32ヶ所もの100Gインターフェースに対応したスイッチ・チップセットを使用しています。調査結果によれば、通信・ネットワーク機器メーカーの60%以上が100G対応のシステムを出荷しています。
The rapidly growing data bandwidth from consumer broadband, mobile data and highly connected businesses is driving demand for 100Gbit/s (100G) network connections. Service providers are installing 100G connections in data center, enterprise, metro and long-haul networks. Many systems have four or more 100G interfaces per line card and use switch chipsets that support up to 32 100G interfaces per device. The survey covered in this report indicates that more than 60 percent of companies that make telecom or networking equipment are shipping systems with 100G interfaces.
Our survey goes beyond gauging the depth and breadth of use for 100G optical modules and PHY semiconductor components by providing insights into which devices telecom equipment manufacturers are using, for which applications and how they rate each vendor. The report includes information about the importance of different Ethernet port types, including new MSA/alliance proposals, the use of PHY devices and 100G optical modules and the most important features when system developers select these modules. It also includes vendor rankings for 100G PHY devices and optical modules, and information on plans for the use of 400G interfaces.
Demand for 100G networking is driven by user demand. Until now, 40G interfaces and multiple 10G interfaces have provided an alternative to 100G that has been more cost effective and readily available. This equation is now changing with lower power, lower cost and higher density 100G solutions for data center, enterprise, metro and long-haul applications.
We have already seen a significant shift from 10x10G to 4x28G for both the optical fiber connections and the serial interfaces from PHY devices on the line card to the optical modules. The speed of this shift may have benefited FPGAs that were early in supporting 4x28G serial interfaces. The next steps are the development of lower cost implementations as 100G volumes grow through 2016/17 and the development of 400G solutions. These developments will include alternative Ethernet port types and the increased use of silicon photonic integration. This is a very competitive market and all the vendors involved need to ensure they deliver on performance as the industry shifts to smaller and lower power optical modules and more advanced modulation technologies.
100G Components User Survey: Market Outlook analyzes the current and projected use of 100G optical modules and PHY semiconductor components by equipment vendors, based on the results of an exclusive worldwide survey of engineers, designers, product managers and sales/marketing personnel that work for telecom and networking system equipment manufacturers and suppliers. The responses to our survey make it clear that these devices are critical components in many types of networking equipment, from long-haul to the access edge, data center and core of the network.
Sample research data from the report is shown in the excerpts below:
The number of 100G ports has grown rapidly. Asked when their company will ship systems with 100G ports, 63 percent of respondents said they were already doing so, as the following excerpt shows. This is in line with our 2013 survey, which indicated that approximately 60 percent of the equipment vendors would be shipping systems with 100G ports by the middle of 2015. Another 20 percent will start within six months to a year.
Companies mentioned in this report include: Acacia Communications Inc.; Achronix Semiconductor Corp.; Altera Corp. (Nasdaq: ALTR); Applied Micro Circuits Corp. (Nasdaq: AMCC); Avago Technologies U.S. Inc. (Nasdaq: AVGO); Broadcom Corp. (Nasdaq: BRCM); Cisco Systems Inc. (Nasdaq: CSCO); Civcom Devices & Systems Ltd.; ClariPhy Communications Inc.; ColorChip Ltd.; Effdon Networks Ltd.; Eoptolink Technology Inc.; Finisar Corp. (Nasdaq: FNSR); Fujitsu Optical Components Ltd., a subsidiary of Fujitsu Ltd. (Pink Sheets: FJTSY); Gigalight (Shenzhen Gigalight Technology Co. Ltd.); InnoLight Technology Corp.; GigOptix Inc. (NYSE: MKT); Inphi Corp. (NYSE: IPHI); JDS Uniphase Corp. (Nasdaq: JDSU; Toronto: JDU); Kaiam Corp.; Luxtera Inc.; M/A-COM Technology Solutions Holdings Inc. (Macom) (Nasdaq: MTSI); Marvell Technology Group Ltd. (Nasdaq: MRVL); Mellanox Technologies Ltd. (Nasdaq: MLNX); Menara Networks Inc.; Microsemi Corp. (Nasdaq: MSCC); Molex Inc.; MoSys Inc. (Nasdaq: MOSY); MultiPhy Ltd.; NTT Electronics Corp. (NEL); NeoPhotonics Corp. (NYSE: NPTN); Oclaro Inc. (Nasdaq: OCLR); OE Solutions Co. Ltd.; Oplink Communications Inc. (Nasdaq: OPLK); Ranovus Inc.; PMC-Sierra Inc. (Nasdaq: PMCS); Semtech Corp. (Nasdaq: SMTC); Reflex Photonics Inc.; Skorpios Technologies Inc.; Socionext Inc.; Source Photonics; Sumitomo Electric Industries Ltd. (TYO: 5802); and Xilinx Inc. (Nasdaq: XLNX).
400G is growing, with 50 percent expecting to ship 400G ports by mid-2017
FPGAs are catching up to merchant silicon and ASICs for 100G PHY devices
100GBase-LR4 is the leading 100GE port type, followed by 100GE port type, followed by 100GBase-SR10
CFP and CFP2 are the most important optical module form factors today
CFP4 and QSFP28 will replace CFP and CFP2 for data center and enterprise over the next two years
CFP and CFP2 ACO are replacing 168-pin for metro
Finisar is still the leading optical module vendor in terms of usage and quality
Performance is the dominant factor in selecting 100G optical modules