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25 Gigabit Ethernet
25 Gigabit Ethernet
25 Gigabit Ethernet
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25 Gigabit Ethernet and 50 Gigabit Ethernet are standards for Ethernet connectivity in a datacenter environment, developed by IEEE 802.3 task forces 802.3by[1] and 802.3cd[2] and are available from multiple vendors.

History

[edit]

An industry consortium, 25G Ethernet Consortium,[3] was formed by Arista, Broadcom, Google, Mellanox Technologies and Microsoft in July 2014 to support the specification of single-lane 25-Gbit/s Ethernet and dual-lane 50-Gbit/s Ethernet technology. The 25G Ethernet Consortium specification draft was completed in September 2015 and uses technology from IEEE Std. 802.3ba and IEEE Std. 802.3bj.

In November 2014, an IEEE 802.3 task force was formed to develop a single-lane 25-Gbit/s standard,[4][5] and in November 2015, a study group was formed to explore the development of a single-lane 50-Gbit/s standard.[6]

In May 2016, an IEEE 802.3 task force was formed to develop a single-lane 50 Gigabit Ethernet standard.[2]

On June 30, 2016, the IEEE 802.3by standard was approved by The IEEE-SA Standards Board.[7]

On November 12, 2018, the IEEE P802.3cn Task Force started working to define PHY supporting 50-Gbit/s operation over at least 40 km of SMF.[8]

The IEEE 802.3cd standard was approved on December 5, 2018.

On December 20, 2019, the IEEE 802.3cn standard was published. [9]

On April 6, 2020, 25 Gigabit Ethernet Consortium has rebranded to Ethernet Technology Consortium, and it announces 800 Gigabit Ethernet (GbE) specification.[10]

On June 4, 2020, the IEEE approved IEEE 802.3ca which allows for symmetric or asymmetric operation with downstream speeds of 25 or 50 Gbit/s, and upstream speeds of 10, 25, or 50 Gbit/s over passive optical networks.[11][12]

25 Gigabit Ethernet

[edit]

The IEEE 802.3by standard uses technology defined for 100 Gigabit Ethernet implemented as four 25-Gbit/s lanes (IEEE 802.3bj).[13][14] The IEEE 802.3by standard defines several single-lane variations.[15]

Legend for fibre-based PHYs[16]
Fibre type Introduced Performance
MMF FDDI 62.5/125 µm 1987 160 MHz·km @ 850 nm
MMF OM1 62.5/125 µm 1989 200 MHz·km @ 850 nm
MMF OM2 50/125 µm 1998 500 MHz·km @ 850 nm
MMF OM3 50/125 µm 2003 1500 MHz·km @ 850 nm
MMF OM4 50/125 µm 2008 3500 MHz·km @ 850 nm
MMF OM5 50/125 µm 2016 3500 MHz·km @ 850 nm + 1850 MHz·km @ 950 nm
SMF OS1 9/125 µm 1998 1.0 dB/km @ 1300/1550 nm
SMF OS2 9/125 µm 2000 0.4 dB/km @ 1300/1550 nm
Name Standard Status Media Connector Trans­ceiver module Reach (m) #
Media
(⇆) 		#
Lamb­das
(→) 		#
Lanes
(→) 		Notes
25 Gigabit Ethernet (25 GbE) - (Data rate: 25 Gbit/s - Line code: 64b/66b with and without RS-FEC(528,514) × NRZ - Line rate: 25.78125 GBd - Full-Duplex) [17]
25GAUI 802.3by-2016
(CL109A/B) 		current Chip-to-chip/
Chip-to-module interface 		0.25 2 N/A 1 PCBs
25GBASE-KR 802.3by-2016
(CL111) 		current Cu-Backplane 1 1 N/A 1 PCBs
25GBASE-KR-S 802.3by-2016
(CL111) 		current Cu-Backplane 1 1 N/A 1 PCBs;
without RS-FEC (802.3by CL108)
25GBASE-CR
Direct Attach 		802.3by-2016
(CL110) 		current Twinaxial balanced SFP28
(SFF-8402) 		SFP28 5 2 N/A 1 Data centres (inter-rack)
25GBASE-CR-S
Direct Attach 		802.3by-2016
(CL110) 		current Twinaxial balanced SFP28
(SFF-8402) 		SFP28 3 1 N/A 1 Data centres (in-rack);
without RS-FEC (802.3by CL108)
25GBASE-SR 802.3by-2016
(CL112) 		current Fibre
850 nm 		LC SFP28 OM3: 70 2 1 1
OM4: 100
25GBASE-LR 802.3cc-2017
(CL114) 		current Fibre
1295 – 1325 nm 		LC SFP28 OS2: 10k 2 1 1
25GBASE-ER 802.3cc-2017
(CL114) 		current Fibre
1295 - 1310 nm 		LC SFP28 OS2: 40k 2 1 1
25GBASE-T
25GBASE-T, a 25-Gbit/s standard over twisted pair, was approved alongside 40GBASE-T within IEEE 802.3bq.[18][19]
Comparison of twisted-pair-based Ethernet physical transport layers (TP-PHYs)[20]
Name Standard Status Speed (Mbit/s) Pairs re­quir­ed Lanes per direc­tion Bits per hertz Line code Symbol rate per lane (MBd) Band­width Max dist­ance (m) Cable Cable rating (MHz) Usage
25GBASE-T 802.3bq-2016 (CL113) current 25000 4 4 6.25 PAM-16 RS-FEC (192, 186) LDPC 2000 1000 30 Cat 8 2000 LAN, Data centres

Forward Error Correction

[edit]

All fibre and twisted pair versions of 25 Gigabit Ethernet are required to support Reed-Solomon Forward Error Correction, often abbreviated RS-FEC, defined in clause 108 of the IEEE 802.3 standard. This also applies to 25GBASE-CR but not to 25GBASE-CR-S, both of which are variants used in DAC cables. 25GBASE-CR as well as 25GBASE-CR-S are required to support Fire-Code FEC (BASE-R FEC, also FC-FEC, defined in clause 74 of IEEE 802.3).[21] While RS-FEC has to be supported for the mentioned 25 G versions, clause 108 also mandates that it has to be possible to turn FEC off, which makes it possible to not use FEC if desired.

For an Ethernet link to form, the interfaces involved must use the same type of FEC or no FEC.[22]

50 Gigabit Ethernet

[edit]

The IEEE P802.3cd [2] standard defines a Physical Coding Sublayer (PCS) in Clause 133 which after encoding gives a data rate of 51.5625 Gbit/s. 802.3cd also defines an RS-FEC for forward error correction in Clause 134 which after FEC encoding gives a data rate of 53.125 Gbit/s. It is not possible to transmit 53.125 Gbit/s over an electrical interface while maintaining suitable signal integrity so four-level pulse-amplitude modulation (PAM4) is used to map pairs of bits into a single symbol. This leads to an overall baud rate of 26.5625 GBd for 50 Gbit/s per lane Ethernet. PAM4 encoding for 50G Ethernet is defined in Clause 135 of the 802.3 standard.

Legend for fibre-based PHYs[16]
Fibre type Introduced Performance
MMF FDDI 62.5/125 µm 1987 160 MHz·km @ 850 nm
MMF OM1 62.5/125 µm 1989 200 MHz·km @ 850 nm
MMF OM2 50/125 µm 1998 500 MHz·km @ 850 nm
MMF OM3 50/125 µm 2003 1500 MHz·km @ 850 nm
MMF OM4 50/125 µm 2008 3500 MHz·km @ 850 nm
MMF OM5 50/125 µm 2016 3500 MHz·km @ 850 nm + 1850 MHz·km @ 950 nm
SMF OS1 9/125 µm 1998 1.0 dB/km @ 1300/1550 nm
SMF OS2 9/125 µm 2000 0.4 dB/km @ 1300/1550 nm
Name Standard Status Media Connector Trans­ceiver module Reach (m) #
Media
(⇆) 		#
Lamb­das
(→) 		#
Lanes
(→) 		Notes
50 Gigabit Ethernet (50 GbE) - (Data rate: 50 Gbit/s - Line code: 256b/257b × RS-FEC(544,514) × PAM4 - Line rate: 26.5625 GBd - Full-Duplex) [23][24]
LAUI-2 802.3cd-2018
(CL135B/C) 		current Chip-to-chip/
Chip-to-module interface 		0.25 2 N/A 2 PCBs;
Line code: NRZ (no FEC)
Line rate: 2x 25.78125 GBd = 51.5625 GBd
50GAUI-2 802.3cd-2018
(CL135D/E) 		current Chip-to-chip/
Chip-to-module interface 		0.25 2 N/A 2 PCBs;
Line code: NRZ (FEC encoded)
Line rate: 2x 26.5625 GBd = 53.1250 GBd
50GAUI-1 802.3cd-2018
(CL135F/G) 		current Chip-to-chip/
Chip-to-module interface 		0.25 1 N/A 1 PCBs
50GBASE-KR 802.3cd-2018
(CL133/137) 		current Cu-Backplane 1 1 N/A 1 PCBs;
total channel insertion loss ≤ 30 dB at half sampling rate = 13.28125 GHz (Nyquist).
50GBASE-CR 802.3cd-2018
(CL133/136) 		current Twinaxial balanced QSFP28,
microQSFP,
QSFP-DD,
OSFP
(SFF-8635) 		QSFP28 3 1 N/A 1 Data centres (in-rack)
50GBASE-SR 802.3cd-2018
(CL133/138) 		current Fibre
850 nm 		LC QSFP28/SFP56 OM3: 70 2 1 1
OM4: 100
50GBASE-LR 802.3cd-2018
(CL133/139) 		current Fibre
1304.5 – 1317.5 nm 		LC QSFP28/SFP56 OS2: 10k 2 1 1
50GBASE-FR 802.3cd-2018
(CL133/139) 		current Fibre
1304.5 – 1317.5 nm 		LC QSFP28/SFP56 OS2: 2k 2 1 1
50GBASE-ER 802.3cn-2019
(CL133/139) 		current Fibre
1304.5 – 1317.5 nm 		LC QSFP28/SFP56 OS2: 40k 2 1 1

Availability

[edit]

As of June 2016, 25 Gigabit Ethernet equipment is available on the market using the SFP28 and QSFP28 transceiver form factors. Direct attach SFP28-to-SFP28 copper cables in 1-, 2-, 3- and 5-meter lengths are available from several manufacturers, and optical transceiver manufacturers have announced 1310 nm "LR" optics intended for reach distances of 2 to 10 km over two strands of standard single-mode fiber, similar to existing 10GBASE-LR optics, as well as 850 nm "SR" optics intended for short reach distances of 100 m over two strands of OM4 multimode fiber, similar to existing 10GBASE-SR optics.[citation needed]

See also

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References

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[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

25 Gigabit Ethernet

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25 Gigabit Ethernet (25GbE or 25G Ethernet) is a set of networking standards developed by the IEEE 802.3 working group that enables Ethernet data transmission at a rate of 25 gigabits per second over a single serial lane, serving as a bridge between 10 Gigabit Ethernet and higher-speed variants like 100 Gigabit Ethernet in data center environments. The development of 25GbE was driven by the need for cost-effective, high-bandwidth connectivity in hyperscale data centers, where web-scale operators required faster server-to-network interfaces without the expense of multi-lane 40GbE or 100GbE solutions. In response, the IEEE formed the P802.3by Task Force in 2014 to define media access control parameters, physical layer specifications, and management features for 25 Gb/s Ethernet, culminating in the ratification of IEEE Std 802.3by-2016. This standard reuses signaling technology from 100 Gigabit Ethernet's four-lane 25 Gb/s configuration but optimizes for single-lane operation to reduce complexity and power consumption. Key specifications in IEEE 802.3by include physical coding sublayers operating at a line rate of 25.78125 Gb/s, with support for Reed-Solomon (RS-FEC) to enhance over various media. It defines variants such as 25GBASE-KR and 25GBASE-KR-S for applications up to 1 meter, 25GBASE-CR and 25GBASE-CR-S for direct-attach twinaxial cables up to 5 meters, and 25GBASE-SR for short-reach multimode up to 100 meters. Subsequent amendments have expanded the ecosystem, including IEEE 802.3cc-2017 for 25GBASE-LR over single-mode up to 10 km and IEEE 802.3bq-2016 for 25GBASE-T over twisted-pair up to 30 meters. Additionally, the standard incorporates a 25 Gigabit Attachment Unit Interface (25GAUI) and optional (EEE) for power savings during low activity. In practice, 25GbE is widely deployed for top-of-rack switching, server uplinks, and intra-rack connections in and enterprise centers, offering up to 2.5 times the performance of 10GbE while leveraging existing like SFP28 transceivers. Its single-lane design facilitates seamless migration paths to 50GbE and 100GbE by aggregating multiple 25G links, supporting the explosive growth in traffic from applications like AI, streaming, and .

Introduction

Definition and Scope

25 Gigabit Ethernet (25GbE) is a wired Ethernet communications technology standard that supports full-duplex data transmission at a nominal rate of 25 Gbit/s over a single lane. This standard, developed through the IEEE 802.3by task force and ratified in , leverages specifications originally derived from higher-speed Ethernet implementations to enable efficient single-lane operation. The primary purpose of 25GbE is to meet escalating bandwidth requirements in hyperscale s by providing a cost-effective intermediate step between (10GbE) and the more infrastructure-intensive 40/100 (40/100GbE) solutions. It allows data center operators to upgrade server-to-switch interconnects incrementally, optimizing power, space, and cooling resources while supporting denser computing environments driven by modern processors. In terms of scope, 25GbE focuses on short-reach applications within data centers and enterprise networks, encompassing electrical variants over twinaxial copper cabling (e.g., 25GBASE-CR) for distances up to 5 meters and optical variants including multimode fiber (e.g., 25GBASE-SR) for up to 100 meters on OM4 and single-mode fiber (e.g., 25GBASE-LR) for up to 10 km. It does not address long-haul or applications outside Ethernet protocols.

Historical Context

The development of 25 Gigabit Ethernet (25GbE) emerged from the escalating bandwidth demands of hyperscale data centers in the early 2010s, where traditional 10 Gigabit Ethernet (10GbE) links were becoming insufficient for server-to-switch interconnects, yet the multi-lane complexity and higher costs of 40 Gigabit Ethernet (40GbE) were impractical for widespread adoption. This need was catalyzed by advancements in silicon serializer/deserializer (SerDes) technology, which enabled reliable single-lane operation at 25 Gbit/s rates, derived from the four-lane architecture of 100GbE. To accelerate industry alignment on these single-lane solutions, the 25 Gigabit Ethernet Consortium was established on July 1, 2014, by founding members Arista Networks, Broadcom, Google, Mellanox Technologies, and Microsoft, with the goal of promoting specifications for 25 Gbit/s and 50 Gbit/s Ethernet tailored to cloud-scale networks. In parallel with the consortium's efforts, the IEEE 802.3 Working Group advanced formal standardization through a Call for Interest presentation in July 2014, which highlighted the market viability of 25GbE for server interconnects and prompted the formation of the 25 Gb/s Ethernet Study Group later that month. The study group produced a consensus report in November 2014, advocating for new standards to support 25 Gbit/s and 50 Gbit/s rates over backplanes, copper cables, and multimode fiber, addressing the limitations of prior Ethernet speeds in high-density environments. This culminated in the approval of the Project Authorization Request (PAR) for the IEEE P802.3by 25 Gb/s Ethernet Task Force on December 10, 2014, marking the transition to detailed specification development. As Ethernet speeds continued to evolve, the consortium underwent a significant transformation in April 2020, rebranding to the Ethernet Technology Consortium to better reflect its broadened scope beyond 25GbE and 50GbE, including contributions to higher-speed interfaces such as 800 Gigabit Ethernet. This shift underscored the ongoing momentum in networking, where initial 25GbE innovations laid foundational technologies for subsequent multi-terabit-scale advancements.

Technical Specifications

Data Rates and Encoding

25 Gigabit Ethernet operates at a nominal data rate of 25 Gbit/s, corresponding to the MAC layer rate defined in Clause 106. This rate is achieved through a combination of block encoding and , ensuring reliable transmission across various physical media. The (PCS) employs 64b/66b block coding, which converts 64 bits of data into 66-bit blocks by appending a 2-bit sync header for and . This encoding results in a line rate of 25.78125 Gbit/s (or GBd for signaling) for electrical interfaces such as (25GBASE-KR) and direct-attach copper (25GBASE-CR), calculated as the rate adjusted for the encoding overhead: 25×6664=25.7812525 \times \frac{66}{64} = 25.78125 Gbit/s. The 64b/66b scheme provides sufficient transition density for reliable while minimizing overhead to approximately 3.125%. To support transmission over legacy twisted-pair cabling like Category 8, 25GBASE-T utilizes with 4 levels (PAM4), which encodes 2 bits per to double the effective data rate per compared to binary signaling. This allows a of 25 GBd to deliver the required 50 Gbps raw before encoding and correction overheads, enabling 25 Gbit/s net over distances up to 30 meters. Forward error correction is implemented via Reed-Solomon (RS-FEC) as specified in Clause 108, mandatory for fiber (25GBASE-SR/LR) and copper interfaces to meet requirements. The RS(528,514) code operates over GF(2^{10}), processing 514 10-bit symbols of data into a 528-symbol codeword by appending 14 parity symbols, providing correction for up to 7 symbol errors per block. When FEC is enabled, the PCS 64b/66b blocks are transcoded to 256b/257b blocks before RS encoding. The combination of , 256b/257b transcoding, and RS(528,514) FEC results in a net coding efficiency equivalent to 64b/66b alone, preserving the 25 Gbit/s MAC rate at the 25.78125 Gbit/s line rate. This structure ensures robust performance while preserving bandwidth efficiency.

Physical Media and Interfaces

25 Gigabit Ethernet supports a variety of to accommodate different deployment scenarios, including for longer distances and electrical cabling for shorter, cost-effective links within data centers. The standard defines specific (PHY) variants that leverage single-lane 25 Gb/s transmission, ensuring compatibility with existing infrastructure where possible. These media types are specified in amendments, such as 802.3by for electrical interfaces ( and twinax) and 802.3cc for variants, focusing on balanced performance, power efficiency, and reach. Optical implementations utilize transceivers operating at defined wavelengths over multimode or single-mode fiber. The 25GBASE-SR variant employs 850 nm wavelength over multimode fiber (MMF), supporting reaches of up to 70 m on OM3 fiber and 100 m on OM4 or OM5 fiber, making it suitable for short intra-rack or rack-to-rack connections in data centers. For longer distances, 25GBASE-LR uses 1310 nm wavelength over single-mode fiber (SMF, such as ), achieving up to 10 km reach for inter-building or campus links. Electrical variants cater to -based connections for high-density, low-latency environments. 25GBASE-CR operates over twinaxial direct-attach cables (DAC), providing reaches up to 5 m for rack-level interconnects, with cable assemblies categorized by (e.g., CA-N for 1-2 m, CA-L for 3-5 m). The 25GBASE-KR specification targets applications, supporting up to 1 m over traces with an budget accommodating typical server or switch designs. Additionally, 25GBASE-T enables twisted-pair cabling, achieving up to 30 m over Category 8 (Cat 8) for enterprise LAN extensions.
VariantMedia TypeWavelength/ReachStandard Reference
25GBASE-SRMultimode fiber (OM4)850 nm / up to 100 mIEEE 802.3by Clause 112
25GBASE-LRSingle-mode fiber ()1310 nm / up to 10 kmIEEE 802.3cc Clause 114
25GBASE-CRTwinaxial copper (DAC)N/A / up to 5 mIEEE 802.3by Clause 110
25GBASE-KR (PCB traces)N/A / up to 1 mIEEE 802.3by Clause 109
25GBASE-T (Cat 8)N/A / up to 30 mIEEE 802.3bq Clause 113
Interfaces for 25 Gigabit Ethernet primarily use the SFP28 (Small Form-factor Pluggable 28) transceiver form factor for single-lane 25G connections, which is backward compatible with SFP+ for 10G operation and supports hot-pluggable insertion into switches and NICs. For multi-lane configurations, such as breaking out to four 25G lanes in a 100G link, QSFP28 modules provide compatibility, allowing flexible port aggregation. Power consumption for SFP28 modules is typically low, with maximum ratings up to 3.5 W per the SFP28 MSA, though operational values often range from 1.0 W to 1.5 W depending on the variant (e.g., 1.2 W for SR, 1.3 W for LR). These interfaces incorporate 25GBASE-R encoding for , as detailed in related specifications.

Forward Error Correction

In 25 Gigabit Ethernet, Forward Error Correction (FEC) is implemented to ensure reliable data transmission over potentially noisy channels, with the mandatory Reed-Solomon FEC (RS-FEC) specified in Clause 108 of IEEE Std 802.3by-2016. This RS-FEC employs a shortened Reed-Solomon code denoted as RS(528,514) over the Galois field GF(2^{10}), where each symbol consists of 10 bits, providing 514 data symbols and 14 parity symbols per code block. The code is capable of correcting up to 7 symbol errors per 528-symbol block, equivalent to approximately 70 bit errors assuming random distribution, thereby enhancing link reliability without retransmission. The RS-FEC sublayer is integrated between the Physical Coding Sublayer (PCS) and the Physical Medium Attachment (PMA) sublayer, operating on scrambled 66-bit blocks from the PCS to form the codewords. For configurations requiring FEC, it is mandatory for most 25G PHY variants, such as 25GBASE-SR, 25GBASE-LR, and 25GBASE-CR, to support error correction over distances limited by signal degradation. However, Clause 108 also includes provisions for optional disablement of RS-FEC on links with inherently low bit error rates (BER), such as short-reach copper cables, to reduce latency and overhead when not needed. For legacy compatibility, particularly with 25GBASE-CR implementations derived from 10GBASE-CR, an optional Fire-Code FEC based on Clause 74 of IEEE Std 802.3-2015 may be used instead of or alongside RS-FEC. This BASE-R FEC, a shortened , offers lighter error correction suitable for lower-noise environments but with less capability than RS-FEC, correcting burst errors up to 16 bits in length. The RS-FEC introduces no net additional overhead beyond the due to the balancing effect of 256b/257b and RS(528,514) parity, maintaining the 25.78125 Gbit/s line rate and 25 Gbit/s MAC rate. This enables robust performance by achieving a post-FEC BER of 10^{-13} even with a pre-FEC BER as high as 10^{-5}, supporting transmission over media with higher or .

Standards and Development

IEEE Task Forces and Timelines

The development of 25 Gigabit Ethernet standards was primarily driven by the IEEE 802.3 working group through dedicated task forces addressing specific physical layer specifications for various media types. The IEEE P802.3by Task Force, formed following the approval of its Project Authorization Request (PAR) on December 10, 2014, focused on defining physical layer specifications and management parameters for 25 Gb/s and 50 Gb/s Ethernet operation over copper backplanes, twinaxial copper cables, and short-reach optical fiber links. This effort built on prior backplane Ethernet advancements to enable cost-effective, high-speed interconnects in data centers and enterprise environments. The task force completed its work with the ratification of IEEE Std 802.3by-2016 by the IEEE Standards Association (SA) Standards Board on June 30, 2016, integrating it as an amendment to IEEE Std 802.3-2015. In parallel, the IEEE P802.3cc Task Force was established to extend 25 Gb/s Ethernet capabilities to single-mode fiber, targeting longer-reach applications in metropolitan and campus networks. Its PAR was approved on May 12, 2016, emphasizing serial 25 Gb/s transmission over single-mode fiber with wavelengths suitable for extended distances. The task force addressed interoperability with existing fiber infrastructure while incorporating forward error correction for reliable performance. The project culminated in the approval of IEEE Std 802.3cc-2017 by the IEEE-SA Standards Board on December 6, 2017. Another key contributor was the IEEE P802.3bq Task Force, which specified 25 Gb/s and 40 Gb/s Ethernet over balanced twisted-pair copper cabling, including support for applications and emerging uses in environments. PAR approved on September 3, 2015, it focused on achieving these speeds over distances up to 30 meters using Category 8 cabling, with an emphasis on energy efficiency and compatibility with prior Ethernet standards. The task force finalized its specifications, leading to the approval of IEEE Std 802.3bq-2016 on June 30, 2016. The overall timeline for 25 Gigabit Ethernet standardization began with the formation of the IEEE 802.3 25 Gb/s Ethernet Study Group in July 2014, following a call for interest that garnered strong support for single-lane 25 Gb/s solutions to bridge the gap between 10 Gb/s and 100 Gb/s Ethernet. This study group progressed to task force formation after PAR approval in December 2014, with initial working group ballots commencing in mid-2015. The sponsor ballot for the core 802.3by amendment passed in May 2016, enabling rapid advancement to IEEE-SA approval. Subsequent task forces like 802.3cc and 802.3bq aligned their schedules to leverage shared technical foundations, resulting in the publication of these amendments to IEEE Std 802.3-2015 by late 2017.

Key Amendments and Extensions

Following the initial ratification of 25 Gigabit Ethernet in IEEE 802.3by-2016, subsequent have expanded its applicability across diverse media and environments, enhancing reach, compatibility, and specialized use cases. These extensions build on the baseline specifications to address evolving demands in s, enterprise networks, and emerging sectors like automotive. The IEEE 802.3cd , approved on December 5, 2018, introduced support for 50 Gb/s electrical interfaces alongside 50 Gb/s and higher options over multimode , enabling higher-density interconnects in short-reach applications. This included new specifications for 50GBASE-SR variants using PAM4 modulation over OM4 multimode up to 100 meters, as well as 50GBASE-CR and 50GBASE-KR for twinaxial copper and cabling up to 30 meters and 1 meter, respectively, improving scalability for server-to-switch links. Subsequently, the IEEE 802.3cn amendment, published on December 20, 2019, focused on extending 25 Gb/s operation over single-mode fiber for longer distances, specifying interfaces capable of reaches up to 40 km. It added Physical Layer parameters for 25GBASE-LR and 25GBASE-ER using serial 25.78125 GBd PAM4 signaling at wavelengths around 1310 nm, supporting metro and deployments where multimode limitations proved insufficient. The IEEE 802.3cz amendment, approved on , 2023, incorporated 25 Gb/s and 50 Gb/s capabilities tailored for automotive Ethernet using , enabling high-bandwidth in-vehicle networking for advanced driver-assistance systems and . This extension defined specifications for 25G operation in harsh automotive environments, including robust error correction and EMC compliance over multimode fiber media up to 40 m with multiple connectors. The IEEE 802.3cp amendment, approved on July 16, 2021, introduced physical layer specifications for 25 Gb/s bidirectional interfaces optimized for enterprise and access settings, facilitating seamless integration in campus and building-scale networks. It emphasizes low-latency, power-efficient for reaches up to 10 km over single-mode using a single strand, with enhanced management parameters for multi-vendor .

Applications and Use Cases

Data Center Deployments

In data centers, 25 Gigabit Ethernet is commonly deployed in server-to-top-of-rack (ToR) switch topologies to enable low-latency interconnects between servers and aggregation layers. These connections typically utilize 25GBASE-CR for short-reach twinaxial copper cables up to 5 meters or 25GBASE-SR for multimode fiber links up to 70-100 meters on OM3/OM4 cabling, allowing compatibility with existing SFP28 ports without requiring full infrastructure overhauls. This approach integrates seamlessly into leaf-spine architectures, where 25G serves as the access layer for server endpoints while uplinks to spine switches operate at 100G or higher via lane breakout configurations. The primary benefits of 25G Ethernet in these environments include a 2.5 times increase in bandwidth over at approximately 40% of the cost per gigabit, making it an efficient upgrade for handling patterns prevalent in cloud-scale networks. It also delivers lower power consumption per gigabit—roughly half that of 10G equivalents—enhancing overall energy efficiency in high-density racks. These advantages stem from the single-lane standardized by IEEE 802.3by, which supports higher densities and reduces capital and operational expenditures compared to multi-lane 40G alternatives. Hyperscale providers such as and have adopted 25G Ethernet for critical use cases like virtual machine migrations and high-speed storage access, leveraging its scalability in massive infrastructures. In leaf-spine setups, it facilitates efficient east-west flows for workloads including NVMe over Fabrics and clustered databases, enabling up to 5 million in storage acceleration scenarios. This deployment supports overlays like VXLAN, optimizing resource pooling across distributed server farms in environments demanding rapid transfer and low latency. As of 2025, 25GbE continues to be used for cost-effective server uplinks amid migrations to 50G and higher speeds for AI-driven workloads. Despite these gains, challenges persist in achieving power efficiency within dense racks, where 25G transceivers must balance high throughput with sub-1.5W consumption to mitigate cooling demands. Migration from 10G networks also requires careful planning to avoid cabling disruptions, though with SFP+ modules and existing multimode fiber minimizes rework.

Enterprise and Other Environments

In enterprise environments, 25 Gigabit Ethernet serves as a cost-effective upgrade path from in campus networks, delivering 2.5 times the throughput to support bandwidth-intensive applications such as streaming and server . This transition enables organizations to handle increased data demands from virtualized workloads and multimedia distribution without requiring a complete overhaul, as 25GbE leverages existing 10GbE-compatible hardware where possible. The 25GBASE-T variant extends this applicability to twisted-pair copper cabling in enterprise settings, allowing upgrades over Category 8 cabling for distances up to 30 meters, which facilitates retrofitting in office and campus deployments targeting data centers and edge facilities. Although primarily designed for new installations, it supports phased upgrades in environments where deployment is impractical, reducing the need for extensive rewiring in legacy twisted-pair infrastructures. Beyond traditional enterprise networks, 25GbE finds use in sectors, where its ultra-low latency—achieved through optimized optics and avoidance of overhead—enables switching in the hundreds of nanoseconds for time-sensitive links. In broadcast media, the standard supports uncompressed transport of 4K and 8K video workflows over IP, adhering to SMPTE ST 2110 protocols via 25GbE interfaces on monitors and media processors, ensuring high-bandwidth, low-jitter delivery for live production environments. Automotive applications integrate 25GbE through standards such as 802.3cy and 802.3cz, providing single-pair twisted copper or links up to 25 Gb/s for in-vehicle networking, supporting advanced driver-assistance systems and with reach exceeding 15 meters. Key advantages in these environments include with 10GbE via auto-negotiation on dual-rate and ports, allowing seamless integration and speed adaptation without hardware replacement. Additionally, the single-lane design of 25GbE simplifies cabling compared to multi-lane higher-speed alternatives, lowering deployment costs in distributed setups by reducing port complexity and expenses.

50 Gigabit Ethernet

50 Gigabit Ethernet is an extension of 25 Gigabit Ethernet that doubles the data rate to 50 Gbit/s full-duplex while leveraging compatible technologies for cost-effective deployment in data centers. Defined in the IEEE 802.3cd , it employs a single physical lane with four-level (PAM4) to achieve this bandwidth, building on 25G advancements to reduce development costs by reusing components like transceivers and . The standard uses Reed-Solomon (RS-FEC) with RS(544,514) code to ensure reliable transmission over noisy channels, paired with 256b/257b block encoding for efficient data mapping and . The (PCS) for 50GBASE-R operates at a nominal MAC rate of 50 Gbit/s, with the physical medium attachment (PMA) providing a of 53.125 Gbit/s per to account for encoding and FEC overhead; this translates to a of 26.5625 GBd under PAM4 modulation, where each symbol encodes two bits. Unlike 25G Ethernet, which relies on (NRZ) signaling at 25.78125 Gbps per , 50 shifts to PAM4 for higher in a single , enabling symmetric bandwidth upgrades without doubling the number of lanes in many cases—though multi-lane configurations using two 25G-equivalent channels are supported for and applications to maintain NRZ compatibility where needed. This shared FEC and encoding framework with higher-speed PAM4 variants minimizes implementation complexity, allowing 50G to serve as a transitional between 25G and 100G deployments. Key physical medium dependent (PMD) variants defined in IEEE 802.3cd include 50GBASE-SR for short-reach multimode fiber links up to 100 meters over OM4 or OM5 cable at 850 nm wavelength, suitable for intra-data-center connections. For longer distances, 50GBASE-LR supports up to 10 km over single-mode fiber () using 1310 nm wavelength, while a subsequent amendment, IEEE 802.3cn, defines 50GBASE-ER extending reach to 40 km on fiber, both employing the same PAM4 signaling for consistent performance across environments.

Compatibility with Higher-Speed Ethernet

25 Gigabit Ethernet (25GbE) supports breakout configurations that enhance its interoperability with () infrastructure. Specifically, a single QSFP28 port can be configured to support four independent 25G SFP28 lanes using breakout cables, enabling flexible scaling from higher-speed uplinks to multiple lower-speed server or device connections without requiring dedicated 25GbE ports. This lane-based architecture extends to even higher-speed Ethernet standards, where 25G lanes serve as building blocks for aggregation in 200GbE, 400GbE, and 800GbE systems. For instance, 400GbE implementations in IEEE 802.3bs utilize 16 lanes operating at 25 Gb/s each for the (PCS), allowing 25G electrical interfaces to interface directly with 400G optical modules. Similarly, the 200GBASE-R PCS in IEEE 802.3bs uses eight 25 Gb/s lanes, though PMA and PMD configurations may aggregate higher-rate lanes (e.g., 4x50G PAM4 or 2x100G) for certain media, with 25G lanes incorporated in electrical and backplane setups for compatibility; 800GbE primarily uses higher-rate lanes (e.g., 8x100G) but shares foundational technologies. Auto-negotiation protocols ensure seamless integration across speed tiers. 25GbE employs Clause 73 auto-negotiation, which supports speed selection among 10GbE, 25GbE, and 50GbE rates, providing with existing 10GbE infrastructure through shared SFP28/SFP+ form factors and PCS alignment. Looking ahead, 25G lanes play a foundational role in the Ethernet Alliance's 2025 roadmap for 1.6 Tb/s Ethernet, where aggregated 25G electrical interfaces underpin multi-lane optical systems to meet escalating bandwidth demands in AI-driven data centers. This positions 25GbE as an enabler for terabit-scale Ethernet evolution, with 50GbE serving as an intermediate aggregation step.

Market Adoption and Availability

Hardware and Vendor Support

25 Gigabit Ethernet hardware primarily utilizes the SFP28 transceiver form factor for single-lane 25 Gbps connections, with major vendors including , which offers SFP28 modules compatible with 25G Ethernet standards for short-reach multimode fiber applications up to 100 meters. Finisar (now part of ) provides SFP28 transceivers supporting 25GBASE-SR for interconnects over multimode fiber. Lumentum supplies 25G SFP28 optical modules, including those for extended reach single-mode fiber up to 10 km, ensuring low power consumption and high density in network deployments. For multi-lane configurations, QSFP28 transceivers enabling 4x25 Gbps breakout modes are available from , which supports these in its series switches for flexible 100G-to-25G scaling. offers QSFP28 optics compatible with 25G Ethernet, including short-reach variants for top-of-rack connectivity in environments. Network interface cards (NICs) and switches provide robust support for 25G Ethernet. NVIDIA's Mellanox ConnectX-6 Lx series adapters feature dual SFP28 ports for 25 Gbps Ethernet, delivering low-latency performance suitable for cloud and storage applications. Intel's E810 Ethernet adapters include quad-port SFP28 configurations supporting 25G speeds via PCIe 4.0, with features like adaptive virtual functions for . Top-of-rack (ToR) switches from , such as the QFX5120 series, incorporate 25G SFP28 ports for spine-leaf architectures in data centers. Huawei's CloudFabric 6000 series ToR switches support 25G Ethernet interfaces, enabling high-density port configurations for enterprise networks. Common form factors for 25G Ethernet connections include direct attach copper (DAC) cables, which support passive variants up to 5 meters for cost-effective short-distance links between switches and servers. Active optical cables (AOC) extend reach further, with SFP28 AOC assemblies achieving up to 100 meters over for intra-rack or inter-rack cabling without significant signal degradation. These media types align with standard and single-mode interfaces specified for 25G Ethernet. The Ethernet Alliance has facilitated conformance testing for 25G Ethernet since 2017, including multi-vendor plugfests that validate of SFP28 transceivers and PHY devices under IEEE 802.3by standards.

Current Status and Future Outlook

25 Gigabit Ethernet has seen widespread adoption in s since its commercialization in 2016, following the ratification of the IEEE 802.3by standard, which enabled its deployment for server interconnects and top-of-rack switching. By 2024, the global 25G Ethernet market reached approximately USD 4.2 billion, reflecting strong penetration in hyperscale environments where it serves as a cost-effective upgrade from 10G Ethernet for handling growing data workloads. According to the Ethernet Alliance's 2025 Roadmap, hyperscalers began integrating 25G servers in the , and it remains a key component in architectures supporting AI and applications, with over a billion Ethernet ports shipped annually across enterprise networks. Commercial availability expanded with optical transceivers standardized under IEEE 802.3cc-2017, allowing 25G transmission over single-mode fiber up to 10 km, and further supported by amendments in the IEEE 802.3-2022 revision for enhanced enterprise interoperability. These developments have made 25G Ethernet viable for both short-reach multimode fiber in data centers and longer-reach single-mode applications in enterprise settings. Despite its established role, 25G Ethernet faces challenges from competition with 100G and higher-speed standards, which offer greater bandwidth for center traffic, as well as power consumption and cost concerns when deploying in edge environments versus high-density setups. These factors limit its expansion in power-sensitive or budget-constrained deployments, though its efficiency in 4x25G configurations for 100G ports helps mitigate some issues. Looking ahead, 25G Ethernet is expected to maintain stability for mid-tier network upgrades through 2030, serving as a foundational lane technology in Ethernet roadmaps that scale to 800G and 1.6T speeds, particularly in hybrid architectures balancing and for AI-driven centers. Its role in supporting Ultra Ethernet Consortium efforts for AI scalability underscores its ongoing relevance, even as higher per-lane rates emerge.

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