100 Gigabit Ethernet
40 Gigabit Ethernet (40GbE) and 100 Gigabit Ethernet (100GbE) are groups of computer networking technologies for transmitting Ethernet frames at rates of 40 and 100 gigabits per second (40 and 100 Gbit/s), respectively. The technology was first defined by the IEEE 802.3ba-2010 standard[1] and later by the 802.3bg-2011, 802.3bj-2014,[2] and 802.3bm-2015 standards.[3]
The standards define numerous port types with different optical and electrical interfaces and different numbers of optical fiber strands per port. Short distances over twinaxial cable are supported. 40GBASE-T uses twisted pair cabling for 40 Gbit/s over up to 30 m.
History
On July 18, 2006, a call for interest for a High Speed Study Group (HSSG) to investigate new standards for high speed Ethernet was held at the IEEE 802.3 plenary meeting in San Diego.[4]
The first 802.3 HSSG study group meeting was held in September 2006.[5]
In June 2007, a trade group called "Road to 100G" was formed after the NXTcomm trade show in Chicago.[6]
On December 5, 2007, the Project Authorization Request (PAR) for the P802.3ba 40 Gbit/s and 100 Gbit/s Ethernet Task Force was approved with the following project scope:[7]
The purpose of this project is to extend the 802.3 protocol to operating speeds of 40 Gb/s and 100 Gb/s in order to provide a significant increase in bandwidth while maintaining maximum compatibility with the installed base of 802.3 interfaces, previous investment in research and development, and principles of network operation and management. The project is to provide for the interconnection of equipment satisfying the distance requirements of the intended applications.
The 802.3ba task force met for the first time in January 2008.[8] This standard was approved at the June 2010 IEEE Standards Board meeting under the name IEEE Std 802.3ba-2010.[9]
The first 40 Gbit/s Ethernet Single-mode Fibre PMD study group meeting was held in January 2010 and on March 25, 2010 the P802.3bg Single-mode Fibre PMD Task Force was approved for the 40 Gbit/s serial SMF PMD.
The scope of this project is to add a single-mode fiber Physical Medium Dependent (PMD) option for serial 40 Gb/s operation by specifying additions to, and appropriate modifications of, IEEE Std 802.3-2008 as amended by the IEEE P802.3ba project (and any other approved amendment or corrigendum).
On June 17, 2010, the IEEE 802.3ba standard was approved [1][10]
In March 2011 the IEEE 802.3bg standard was approved.[11]
On September 10, 2011, the P802.3bj 100 Gbit/s Backplane and Copper Cable task force was approved.[2]
The scope of this project is to specify additions to and appropriate modifications of IEEE Std 802.3 to add 100 Gb/s 4-lane Physical Layer (PHY) specifications and management parameters for operation on backplanes and twinaxial copper cables, and specify optional Energy Efficient Ethernet (EEE) for 40 Gb/s and 100 Gb/s operation over backplanes and copper cables.
On May 10, 2013, the P802.3bm 40 Gbit/s and 100 Gbit/s Fiber Optic Task Force was approved.[3]
This project is to specify additions to and appropriate modifications of IEEE Std 802.3 to add 100 Gb/s Physical Layer (PHY) specifications and management parameters, using a four-lane electrical interface for operation on multimode and single-mode fiber optic cables, and to specify optional Energy Efficient Ethernet (EEE) for 40 Gb/s and 100Gb/s operation over fiber optic cables. In addition, to add 40 Gb/s Physical Layer (PHY) specifications and management parameters for operation on extended reach (>10 km) single-mode fiber optic cables.
Also on May 10, 2013, the P802.3bq 40GBASE-T Task Force was approved.[12]
Specify a Physical Layer (PHY) for operation at 40 Gb/s on balanced twisted-pair copper cabling, using existing Media Access Control, and with extensions to the appropriate physical layer management parameters.
On June 12, 2014, the IEEE 802.3bj standard was approved.[2]
On February 16, 2015, the IEEE 802.3bm standard was approved.[13]
On May 12, 2016, the IEEE P802.3cd Task Force started working to define next generation two-lane 100 Gb/s PHY.[14]
Standards
The IEEE 802.3 working group is concerned with the maintenance and extension of the Ethernet data communications standard. Additions to the 802.3 standard[15] are performed by task forces which are designated by one or two letters. For example, the 802.3z task force drafted the original Gigabit Ethernet standard.
802.3ba is the designation given to the higher speed Ethernet task force which completed its work to modify the 802.3 standard to support speeds higher than 10 Gbit/s in 2010.
The speeds chosen by 802.3ba were 40 and 100 Gbit/s to support both end-point and link aggregation needs. This was the first time two different Ethernet speeds were specified in a single standard. The decision to include both speeds came from pressure to support the 40 Gbit/s rate for local server applications and the 100 Gbit/s rate for internet backbones. The standard was announced in July 2007[16] and was ratified on June 17, 2010.[9]
The 40/100 Gigabit Ethernet standards encompass a number of different Ethernet physical layer (PHY) specifications. A networking device may support different PHY types by means of pluggable modules. Optical modules are not standardized by any official standards body but are in multi-source agreements (MSAs). One agreement that supports 40 and 100 Gigabit Ethernet is the C Form-factor Pluggable (CFP) MSA[17] which was adopted for distances of 100+ meters. QSFP and CXP connector modules support shorter distances.[18]
The standard supports only full-duplex operation.[19] Other electrical objectives include:
- Preserve the 802.3 / Ethernet frame format utilizing the 802.3 MAC
- Preserve minimum and maximum FrameSize of current 802.3 standard
- Support a bit error rate (BER) better than or equal to 10−12 at the MAC/PLS service interface
- Provide appropriate support for OTN
- Support MAC data rates of 40 and 100 Gbit/s
- Provide physical layer specifications (PHY) for operation over single-mode optical fiber (SMF), laser optimized multi-mode optical fiber (MMF) OM3 and OM4, copper cable assembly, and backplane.
The following nomenclature is used for the physical layers:[2][3][20]
Physical layer | 40 Gigabit Ethernet | 100 Gigabit Ethernet |
---|---|---|
Backplane | 100GBASE-KP4 | |
Improved Backplane | 40GBASE-KR4 | 100GBASE-KR4 |
7 m over twinax copper cable | 40GBASE-CR4 | 100GBASE-CR10 100GBASE-CR4 |
30 m over "Cat.8" twisted pair | 40GBASE-T | |
100 m over OM3 MMF | 40GBASE-SR4 | 100GBASE-SR10 100GBASE-SR4 |
125 m over OM4 MMF[18] | ||
2 km over SMF, serial | 40GBASE-FR | 100GBASE-CWDM4[21] |
10 km over SMF | 40GBASE-LR4 | 100GBASE-LR4 |
40 km over SMF | 40GBASE-ER4 | 100GBASE-ER4 |
The 100 m laser optimized multi-mode fiber (OM3) objective was met by parallel ribbon cable with 850 nm wavelength 10GBASE-SR like optics (40GBASE-SR4 and 100GBASE-SR10). The backplane objective with 4 lanes of 10GBASE-KR type PHYs (40GBASE-KR4). The copper cable objective is met with 4 or 10 differential lanes using SFF-8642 and SFF-8436 connectors. The 10 and 40 km 100 Gbit/s objectives with four wavelengths (around 1310 nm) of 25 Gbit/s optics (100GBASE-LR4 and 100GBASE-ER4) and the 10 km 40 Gbit/s objective with four wavelengths (around 1310 nm) of 10 Gbit/s optics (40GBASE-LR4).[22]
In January 2010 another IEEE project authorization started a task force to define a 40 Gbit/s serial single-mode optical fiber standard (40GBASE-FR). This was approved as standard 802.3bg in March 2011.[11] It used 1550 nm optics, had a reach of 2 km and was capable of receiving 1550 nm and 1310 nm wavelengths of light. The capability to receive 1310 nm light allows it to inter-operate with a longer reach 1310 nm PHY should one ever be developed. 1550 nm was chosen as the wavelength for 802.3bg transmission to make it compatible with existing test equipment and infrastructure.[23]
In December 2010, a 10x10 multi-source agreement (10x10 MSA) began to define an optical Physical Medium Dependent (PMD) sublayer and establish compatible sources of low-cost, low-power, pluggable optical transceivers based on 10 optical lanes at 10 Gbit/s each.[24] The 10x10 MSA was intended as a lower cost alternative to 100GBASE-LR4 for applications which do not require a link length longer than 2 km. It was intended for use with standard single mode G.652.C/D type low water peak cable with ten wavelengths ranging from 1523 to 1595 nm. The founding members were Google, Brocade Communications, JDSU and Santur.[25] Other member companies of the 10x10 MSA included MRV, Enablence, Cyoptics, AFOP, oplink, Hitachi Cable America, AMS-IX, EXFO, Huawei, Kotura, Facebook and Effdon when the 2 km specification was announced in March 2011.[26] The 10X10 MSA modules were intended to be the same size as the C Form-factor Pluggable specifications.
On June 12, 2014, the 802.3bj standard was approved. The 802.3bj standard specifies 100 Gbit/s 4x25G PHYs - 100GBASE-KR4, 100GBASE-KP4 and 100GBASE-CR4 - for backplane and twin-ax cable.
On February 16, 2015, the 802.3bm standard was approved. The 802.3bm standard specifies a lower-cost optical 100GBASE-SR4 PHY for MMF and a four-lane chip-to-module and chip-to-chip electrical specification (CAUI-4). The detailed objectives for the 802.3bm project can be found on the 802.3 website.
100G Port Types
Name | Clause | Media | Media count |
Lanes | Gigabaud per lane | Notes |
---|---|---|---|---|---|---|
100GBASE-CR10 | 85 (802.3ba)[1] | Twin-ax copper cable | 10 | 10.3125 | CXP connector, center 10 out of 12 channels | |
100GBASE-CR4 | 92 (802.3bj)[2] | 4 | 25.78125, RS-FEC | |||
100GBASE-SR10 | 86 (802.3ba)[1] | Multi-mode fiber, 850 nm | 10 | 10.3125 | MPO/MTP connector, center 10 out of 12 channels | |
100GBASE-SR4 | 95 (802.3bm)[3] | 4 | 25.78125, RS-FEC | |||
100GBASE-LR4 | 88 (802.3ba)[1] | Single-mode fiber, WDM: 1295.56 nm, 1300.05 nm, |
1 | 4 | 25.78125 | 10 km reach |
100GBASE-ER4 | 30–40 km reach | |||||
100GBASE-CWDM4 | non-IEEE[27] | Single-mode fiber, WDM: 1271 nm, 1291 nm, |
25.78125, RS-FEC | 2 km reach, multi-vendor non-IEEE Standard | ||
100GBASE-PSM4 | non-IEEE[28] | 4×Single-mode fiber 1310 nm | 4 | 25.78125 | 500m, multi-vendor non-IEEE Standard | |
100GBASE-ZR | non-IEEE[29] | Single-mode fiber, 1546.119 nm | 1 | 120.579, DP-QPSK | 80+ km reach, non-IEEE Standard | |
100GBASE-KR4 | 93 (802.3bj)[2] | Copper backplane | 4 | 25.78125, RS-FEC | ||
100GBASE-KP4 | 94 (802.3bj)[2] | additional four level amplitude modulation |
All variants listed in the table share the 64b/66b Physical Coding Sublayer, and the media count is given per direction (i.e. double the count is required to form a link.) RS-FEC refers to the Reed-Solomon Layer defined in Clause 91, introduced in IEEE 802.3bj. DP-QPSK refers to Dual polarization-quadrature phase shift keying.
40G port types
- 40GBASE-CR4
- 40GBASE-CR4 ("copper") is a port type for twin-ax copper cable. Its 64b/66b PCS is defined in IEEE 802.3 Clause 82 and its PMD in Clause 85. It uses four lanes of twin-axial cable delivering serialized data at a rate of 10.3125 Gbit/s per lane.[15]
- CR4 involves two clauses: CL73 for auto-negotiation, and CL72 for link training. CL73 allows communication between the two PHYs to exchange technical capability pages, and both PHYs come to a common speed and media type. Once CL73 has been completed, CL72 starts. CL72 allows each of the four lanes' transmitters to adjust pre-emphasis via feedback from the link partner.
- 40GBASE-KR4
- 40GBASE-KR4 is a port type for backplanes. Normally backplanes are board traces, such as Megtron6 or FR4 materials. Its Physical Coding Sublayer 64b/66b PCS is defined in IEEE 802.3 Clause 82 and its Physical Medium Dependent PMD in Clause 84. It uses four lanes of backplane delivering serialized data at a rate of 10.3125 Gbit/s per lane.[15]
- As in CR4 case, KR4 involves 2 clauses, first CL73 for autoneg, followed by CL72 for link training. CL73 allows the communication between the 2 PHY's to exchange tech ability pages, and both PHYs come to a common speed and media type. Once CL73 has been completed, CL72 starts. CL72 allows each of the 4 lanes transmitter to adjust its preemphasis by way of feedback from the link partner.
- 40GBASE-SR4
- 40GBASE-SR4 ("short range") is a port type for multi-mode fiber and uses 850 nm lasers. Its Physical Coding Sublayer 64b/66b PCS is defined in IEEE 802.3 Clause 82 and its Physical Medium Dependent PMD in Clause 86. It uses four lanes of multi-mode fiber delivering serialized data at a rate of 10.3125 Gbit/s per lane. 40GBASE-SR4 has a reach of 100 m on OM3 and 150m on OM4. There is a longer range variant 40GBASE-eSR4 with a reach of 300 m on OM3 and 400 m on OM4. This extended reach is equivalent to the reach of 10GBASE-SR.[30]
- 40GBASE-LR4
- 40GBASE-LR4 ("long range") is a port type for single-mode fiber and uses 1300 nm lasers. Its Physical Coding Sublayer 64b/66b PCS is defined in IEEE 802.3 Clause 82 and its Physical Medium Dependent PMD in Clause 87. It uses four wavelengths delivering serialized data at a rate of 10.3125 Gbit/s per wavelength.[15]
- 40GBASE-ER4
- 40GBASE-ER4 ("extended range") is a port type for single-mode fiber being defined in P802.3bm and uses 1300 nm lasers. Its Physical Coding Sublayer 64b/66b PCS is defined in IEEE 802.3 Clause 82 and its Physical Medium Dependent PMD in Clause 87. It uses four wavelengths delivering serialized data at a rate of 10.3125 Gbit/s per wavelength.[3]
- 40GBASE-FR
- 40GBASE-FR is a port type for single-mode fiber. Its Physical Coding Sublayer 64b/66b PCS is defined in IEEE 802.3 Clause 82 and its Physical Medium Dependent PMD in Clause 89. It uses 1550 nm optics, has a reach of 2 km and is capable of receiving 1550 nm and 1310 nm wavelengths of light. The capability to receive 1310 nm light allows it to inter-operate with a longer reach 1310 nm PHY should one ever be developed. 1550 nm was chosen as the wavelength transmission to make it compatible with existing test equipment and infrastructure.[15]
- 40GBASE-T
- 40GBASE-T is a port type for 4-pair balanced twisted-pair Cat.8 copper cabling up to 30 m defined in IEEE 802.3bq.[31] IEEE 802.3bq-2016 standard was approved by The IEEE-SA Standards Board on June 30, 2016.[32]
Chip-to-chip/chip-to-module interfaces
- CAUI-10
- CAUI-10 is a 100 Gbit/s 10 lane electrical interface defined in 802.3ba.[1]
- CAUI-4
- CAUI-4 is a 100 Gbit/s 4 lane electrical interface defined in 802.3bm.[3]
Connectors
- QSFP+
- The QSFP+ connector is specified for use with the 40GBASE-CR4/SR4, can be copper direct attached cable (DAC) or optical module, see Figure 85–20 in the 802.3 spec. QSFP modules at 40Gbps can also be used to provide four independent ports of 10 gigabit ethernet.[1]
- MPO
- The 40GBASE-SR4 and 100GBASE-SR10 PHYs use the Multiple-Fiber Push-On/Pull-off (MPO) connector, see subclause 86.10.3.3 of the 802.3 spec.[1]
100G optical module standards
- CFP
- The CFP MSA defines hot-pluggable optical transceiver form factors to enable 40 Gbit/s and 100 Gbit/s applications.[33] CFP modules use the 10-lane CAUI-10 electrical interface.
- CFP2
- CFP2 modules use the 10-lane CAUI-10 electrical interface or the 4-lane CAUI-4 electrical interface.
- QSFP28
- QSFP28 modules use the CAUI-4 electrical interface.
- CPAK
- Cisco has the CPAK optical module that uses the four lane CEI-28G-VSR electrical interface.[34][35]
- CXP
- There are also CXP and HD module standards.[36] CXP modules use the CAUI-10 electrical interface.
Products
- Backplane
- NetLogic Microsystems announced backplane modules in October 2010.[37]
- Copper cables
- Quellan announced a test board in 2009.[38]
- Multimode fiber
- In 2009, Mellanox[39] and Reflex Photonics[40] announced modules based on the CFP agreement.
- Single mode fiber
- Finisar,[41] Sumitomo Electric Industries,[42] and OpNext[43] all demonstrated singlemode 40 or 100 Gbit/s Ethernet modules based on the C Form-factor Pluggable agreement at the European Conference and Exhibition on Optical Communication in 2009.
- Compatibility
- Optical fiber IEEE 802.3ba implementations were not compatible with the numerous 40 and 100 Gbit/s line rate transport systems because they had different optical layer and modulation formats as the IEEE 802.3ba Port Types show. In particular, existing 40 Gbit/s transport solutions that used dense wavelength-division multiplexing to pack four 10 Gbit/s signals into one optical medium were not compatible with the IEEE 802.3ba standard, which used either coarse WDM in 1310 nm wavelength region with four 25 Gbit/s or four 10 Gbit/s channels, or parallel optics with four or ten optical fibers per direction.
- Test and measurement
-
- Ixia developed Physical Coding Sublayer Lanes[44] and demonstrated a working 100GbE link through a test setup at NXTcomm in June 2008.[45] Ixia announced test equipment in November 2008.[46][47]
- Discovery Semiconductors introduced optoelectronics converters for 100 Gbit/s testing of the 10 km and 40 km Ethernet standards in February 2009.[48]
- JDS Uniphase introduced test and measurement products for 40 and 100 Gbit/s Ethernet in August 2009.[49]
- Spirent Communications introduced test and measurement products in September 2009.[50]
- EXFO demonstrated interoperability in January 2010.[51]
- Xena Networks demonstrated test equipment at the Technical University of Denmark in January 2011.[52][53]
- Calnex Solutions introduced 100GbE Synchronous Ethernet synchronisation test equipment in November 2014.[54]
- Spirent Communications introduced the Attero-100G for 100GbE and 40GbE impairment emulation in April 2015.[55][56]
Commercial trials and deployments
Unlike the "race to 10Gbps" that was driven by the imminent need to address growth pains of the Internet in the late 1990s, customer interest in 100 Gbit/s technologies was mostly driven by economic factors. The common reasons to adopt the higher speeds were:[57]
- to reduce the number of optical wavelengths ("lambdas") used and the need to light new fiber
- to utilize bandwidth more efficiently than 10 Gbit/s link aggregate groups
- to provide cheaper wholesale, internet peering and data center connectivity
- to skip the relatively expensive 40 Gbit/s technology and move directly from 10 to 100 Gbit/s
Optical transport systems
Optical signal transmission over a nonlinear medium is principally an analog design problem. As such, it has evolved slower than digital circuit lithography (which generally progressed in step with Moore's law.) This explains why 10 Gbit/s transport systems existed since the mid-1990s, while the first forays into 100 Gbit/s transmission happened about 15 years later – a 10x speed increase over 15 years is far slower than the 2x speed per 1.5 years typically cited for Moore's law.
Nevertheless, at least five firms (Ciena, Alcatel-Lucent, MRV, ADVA Optical and Huawei) made customer announcements for 100 Gbit/s transport systems[58] by August 2011 – with varying degrees of capabilities. Although vendors claimed that 100 Gbit/s light paths could use existing analog optical infrastructure, deployment of high-speed technology was tightly controlled and extensive interoperability tests were required before moving them into service.
Products
Designing routers or switches which support 100 Gbit/s interfaces is difficult. The need to process a 100 Gbit/s stream of packets at line rate without reordering within IP/MPLS microflows is one reason for this.
As of 2011[update], most components in the 100 Gbit/s packet processing path (PHY chips, NPUs, memories) were not readily available off-the-shelf or require extensive qualification and co-design. Another problem is related to the low-output production of 100 Gbit/s optical components, which were also not easily available – especially in pluggable, long-reach or tunable laser flavors.
Alcatel-Lucent
In November 2007, Alcatel-Lucent held the first field trial of 100 Gbit/s optical transmission. Completed over a live, in-service 504 kilometre portion of the Verizon network, it connected the Florida cities of Tampa and Miami.[59]
100GbE interfaces for the 7450 ESS/7750 SR service routing platform were first announced in June 2009, with field trials with Verizon,[60] T-Systems and Portugal Telecom taking place in June–September 2010. In September 2009, Alcatel-Lucent combined the 100G capabilities of its IP routing and optical transport portfolio in an integrated solution called Converged Backbone Transformation.[61]
In June 2011, Alcatel-Lucent introduced a packet processing architecture known as FP3, advertised for 400 Gbit/s rates.[62]Alcatel-Lucent announced the XRS 7950 core router (based on the FP3) in May 2012.[63][64]
Mellanox Technologies
Mellanox Technologies introduced the ConnectX-4 100GbE single and dual port adapter in November 2014.[65] In the same period, Mellanox introduced availability of 100GbE copper and fiber cables. [66] In June 2015, Mellanox introduced the Spectrum 10, 25, 40, 50 and 100GbE switch models.[67]
Aitia
Aitia International introduced the C-GEP FPGA-based switching platform in February 2013.[68] Aitia also produce 100G/40G Ethernet PCS/PMA+MAC IP cores for FPGA developers and academic researchers.[69]
Arista
Arista Networks introduced the 7500E switch (with up to 96 100GbE ports) in April 2013.[70] In July 2014, Arista introduced the 7280E switch (the world's first top-of-rack switch with 100G uplink ports).[71]
Brocade
Brocade Communications Systems introduced their first 100GbE products (based on the former Foundry Networks MLXe hardware) in September 2010.[72] In June 2011, the new product went live at the AMS-IX traffic exchange point in Amsterdam.[73]
Cisco
Cisco Systems and Comcast announced their 100GbE trials in June 2008.[74] However, it is doubtful that this transmission could approach 100 Gbit/s speeds when using a 40 Gbit/s per slot CRS-1 platform for packet processing. Cisco's first deployment of 100GbE at AT&T and Comcast took place in April 2011.[75] In the same year, Cisco tested the 100GbE interface between CRS-3 and a new generation of their ASR9K edge router model.[76]
Extreme Networks
Extreme Networks introduced a four-port 100GbE module for the BlackDiamond X8 core switch in November 2012.[77]
Huawei
In October 2008, Huawei presented their first 100GbE interface for their NE5000e router.[78] In September 2009, Huawei also demonstrated an end-to-end 100 Gbit/s link.[79] It was mentioned that Huawei's products had the self-developed NPU "Solar 2.0 PFE2A" onboard and was using pluggable optics in CFP form-factor.
In a mid-2010 product brief, the NE5000e linecards were given the commercial name LPUF-100 and credited with using two Solar-2.0 NPUs per 100GbE port in opposite (ingress/egress) configuration.[80] Nevertheless, in October 2010, the company referenced shipments of NE5000e to Russian cell operator "Megafon" as "40Gbps/slot" solution, with "scalability up to" 100 Gbit/s.[81]
In April 2011, Huawei announced that the NE5000e was updated to carry 2x100GbE interfaces per slot using LPU-200 linecards.[82] In a related solution brief, Huawei reported 120 thousand Solar 1.0 integrated circuits shipped to customers, but no Solar 2.0 numbers were given.[83] Following the August 2011 trial in Russia, Huawei reported paying 100 Gbit/ DWDM customers, but no 100GbE shipments on NE5000e.[84]
Juniper
Juniper Networks announced 100GbE for its T-series routers in June 2009.[85] The 1x100GbE option followed in Nov 2010, when a joint press release with academic backbone network Internet2 marked the first production 100GbE interfaces going live in real network.[86]
In the same year, Juniper demonstrated 100GbE operation between core (T-series) and edge (MX 3D) routers.[87] Juniper, in March 2011, announced first shipments of 100GbE interfaces to a major North American service provider (Verizon[88]).
In April 2011, Juniper deployed a 100GbE system on the UK education network JANET.[89] In July 2011, Juniper announced 100GbE with Australian ISP iiNet on their T1600 routing platform.[90] Juniper started shipping the MPC3E line card for the MX router, a 100GbE CFP MIC, and a 100GbE LR4 CFP optics in March 2012[citation needed]. In Spring 2013, Juniper Networks announced the availability of the MPC4E line card for the MX router that includes 2 100GbE CFP slots and 8 10GbE SFP+ interfaces[citation needed].
In June 2015, Juniper Networks announced the availability of its CFP-100GBASE-ZR module which is a plug & play solution that brings 80 km 100GbE to MX & PTX based networks.[91] The CFP-100GBASE-ZR module uses DP-QPSK modulation and coherent receiver technology with an optimized DSP and FEC implementation. The low-power module can be directly retrofitted into existing CFP sockets on MX and PTX routers.
Dell
Dell's Force10 switches support 40 Gbit/s interfaces. These 40 Gbit/s fiber-optical interfaces using QSFP+ transceivers can be found on the Z9000 distributed core switches, S4810 and S4820[92] as well as the blade-switches MXL and the IO-Aggregator. The Dell PowerConnect 8100 series switches also offer 40 Gbit/s QSFP+ interfaces.[93]
Chelsio
Chelsio Communications introduced 40 Gbit/s Ethernet network adapters (based on the fifth generation of its Terminator architecture) in June 2013.[94]
Telesoft Technologies Ltd
Telesoft Technologies announced the dual 100G PCIe accelerator card, part of the MPAC-IP series.[95] Telesoft also announced the STR 400G (Segmented Traffic Router)[96] and the 100G MCE (Media Converter and Extension).[97]
See also
References
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Further reading
- Overview of Requirements and Applications for 40 Gigabit Ethernet and 100 Gigabit Ethernet Technology Overview White Paper (Archived 2009-08-01) – Ethernet Alliance
- 40 Gigabit Ethernet and 100 Gigabit Ethernet Technology Overview White Paper – Ethernet Alliance
External links
- Ethernet Alliance
- "100G Ethernet cheat sheet: A collection of articles, slideshows, multimedia content on 100G Ethernet". Network World. November 19, 2009. Retrieved 2016-08-24.
- IEEE P802.3ba 40Gb/s and 100Gb/s Ethernet Task Force
- IEEE P802.3ba 40Gb/s and 100Gb/s Ethernet Task Force public area
- Higher Speed Study Group documents