Universal Serial Bus 4 (USB4), sometimes erroneously referred to as USB 4.0, is the most recent technical specification of the USB (Universal Serial Bus) data communication standard. The USB Implementers Forum originally announced USB4 in 2019.

USB4
Deprecated USB4 40 Gbps logo
Type USB
Production history
Designer USB Promoter Group
Designed 29 August 2019; 5 years ago (2019-08-29)
Superseded USB 3.2
General specifications
Daisy chain No
Audio signal DisplayPort
Video signal DisplayPort
Pins 24
Connector USB-C
Electrical
Max. voltage 48 V (PD 3.1)
Max. current 5 A (PD)
Data
Data signal USB or PCIe
Bitrate 20 Gbit/s
40 Gbit/s
80 Gbit/s
120/40 Gbit/s asymmetric
USB4 Gen3x2 cable (40 Gbps) with 100 W Power Delivery

USB4 enables multiple devices to dynamically share a single high-speed data link. USB4 devices must support a signaling rate of at least 20 Gbit/s. The current version allows signalling rates of 40 Gbit/s (since USB4, first version) and 80 Gbit/s (since USB4 version 2.0).[1][2] USB4 is only defined for USB-C connectors and its Type-C specification[3] regulates the connector, cables and also power delivery features across all uses of USB-C cables, in part[4] with the USB Power Delivery specification.[5]

The USB4 standard mandates functionally backwards compatibility to USB 3.2 (which supersedes USB 3.0 and USB 3.1) and dedicated backward compatibility with USB 2.0 (and therefore subsequently USB 2.0/1.1).[6] The dynamic sharing of bandwidth of a USB4 connection is achieved by tunneling of other protocols. This includes tunneling of USB 3.2 Gen 2 and DisplayPort. Other optional protocols, such as PCI Express and Ethernet can also be tunneled.

USB4 is based on the Thunderbolt 3 protocol; however, the implementation of Thunderbolt 3 protocol is mandatory only for hubs.[7]

History

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Prior to USB4, Thunderbolt provided a way to dynamically share bandwidth between multiple DP and PCIe connections over a single cable. Thunderbolt originally used the mDP connector and was only backward compatible to DP connections and did not support power transfer.

The introduction of the Type-C connector in 2014 provided a connector that could support both USB data connectivity, power transfer as well as DP connections. It also allowed the static sharing of bandwidth between DP and USB connections over the same cable.

Thunderbolt 3 switched over to using the new Type-C connector and also added backwards compatibility for USB connections and power transfer features.

USB4 was announced in March 2019 by the USB Promoter Group.[8][9] The first version of the USB4 specification, released 29 August 2019, is named "Universal Serial Bus 4" or "USB4". Several news reports before the release of that version sometime use the wrong terminology "USB 4.0" and "USB 4".[10][11]

Goals stated in the USB4 specification are increasing bandwidth, helping to converge the USB-C connector ecosystem, and "minimize end-user confusion". Some of the key areas to achieve this are using a single USB-C connector type, while retaining compatibility with existing USB and Thunderbolt products.[12]

On 18 October 2022 the USB Promoter Group released the USB4 Version 2.0 specification.[13][14] It added 80 Gbit/s signalling rate with optionally asymmetric signaling, a new, optional alternative to the existing "USB3 Gen T tunneling", removed PCIe overhead limitations and updated the support of DisplayPort to the then current Version 2.1.

Around the release of the new USB4 2.0 specification, USB-IF also mandated new logos and marketing names to simplify representing the maximum supported signalling rates and wattages to consumers.[15]

Functionality of USB4 ports

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Similarly to how USB 3.x specifications defined the new SuperSpeed(Plus) protocols for faster signalling rates, but also mandated that USB 3.x physically and architecturally implement USB 2.0 specification with dedicated wires, the USB4 specification describes 2 different aspects. The first one is what type of existing connections and compatibility a USB4 port guarantees. Since USB4 uses the Type-C connector, which was designed to be multifunctional and reversable, the term "host" port does not accurately reflect the situation. This is better denoted as a downward facing port (DFP). The peripheral side can similarly be described as upward facing port (UFP).[verification needed]

Any downward[jargon] facing USB4 port is required to also implement USB 2.0, USB 3.2 and DP Alternative Mode support. Each according to their own specifications. As such a USB4 downward[jargon] facing port is backwards compatible to all previous USB devices.[verification needed]

USB 2.0 DFP features

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USB 2.0 defines 3 different signalling rates (Low-, Full-, High-Speed), all are required to be supported. [16] USB 2.0 abilities uses separate wires on the Type-C connector that are not used by USB 3.2 or USB4.

USB 3.2 DFP features

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USB 3.2 defines 3 different signaling rates ("5 Gbps" a.k.a. SuperSpeed, "10 Gbps" a.k.a. SuperSpeed+, "20 Gbps" a.k.a. SuperSpeed+ 20 Gbps). While USB 3.2 specification[17] has been functionally supported by USB4, only the 2 lower speeds (5 Gbit/s, 10 Gbit/s) are mandatory for USB4 DFPs to support.

DP Alt Mode DFP features

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The USB4 specifications make no reference to a minimum feature set for its DP Alternative Mode, but Thunderbolt 3 does. In practice, Intel's family of TB 3 controllers requires DisplayPort 1.2, it also support up to HBR3 speeds according to the DisplayPort 1.4a specification and DisplayPort Alt Mode specification.[18]

Power transfer features for DFP

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The USB4 specification makes no explicit demands on power output. It outsources all requirements in terms of power to the Type-C[19] specification that underpins all USB, Vesa and other standards that use the USB-C connector. This requires a USB4 DFP to supply at least 7.5W Type-C current. No power consumption features (e.g. charging of a notebook) are required, but can be supported following the USB PD specification.[20] as well as supplying considerably more power. The USB PD protocol must always be supported (exchanging data according to the protocol. This is separate from any functionality of PD to negotiate actual power delivery other than 5V or > 15W).

USB4 hubs & docks

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USB4 hubs and docks are defined as their own category of USB4 devices, that include further requirements. For example, a USB4 hub must also serve as a classic USB 3.2 hub with DP Alternative Mode passthrough with hosts that do not support USB4 connections. See USB4 capabilities by device type for more details.

USB4 protocol/connections

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Every USB4 port must support the USB4 protocol/connections, which is a distinct standard to establish USB4 links / connections between USB4 devices that exists in parallel to previous USB protocols. Unlike USB 2.0 and USB 3.x it does not provide a way to transfer data directly, but rather it is a mere container that can contain multiple "tunnels"/virtual connections.

Other specifications are referenced to define the contents and internal functionality of a tunnel. USB4 defines the following tunnel types:

  • USB3 connections
  • DisplayPort connections
  • PCIe connections
  • Ethernet/network connections according to the included USB4Net and Cross-Domain specifications.[21]

General principles of USB4

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USB4 forms a tree-like topology of USB4 routers (each USB4 device includes a USB4 router to participate in this network). A tunnel can be end-to-end, where the route through the entire network of routers is preconfigured. But tunnels can also be single-hop, where it exists only for a single USB4 link (between 2 routers). In this case the tunnel will be "unpacked" by the recipient and will use some other, tunnel type specific means to identify where the data needs to be sent next. If the next hop is another USB4 router, the data will be ingested again into the next single-hop tunnel until it exits the USB4 network.[22]

Accordingly, single-hop tunnels require specific support in each USB4 router to support even passing them through to further USB4 routers. End-to-end tunnels however only require specific support at the USB4 router where the data is ingested into the tunnel and at the target, the point where the tunnel ends.

Protocol input/output adapters

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A Protocol Input Adapter will ingest a connection according to whatever protocol it is based on and convert the contents into a USB4 tunnel. Protocol Output Adapters do the reverse. They extract a tunnel from the USB4 network and if needed recreate a regular connection from the tunnel contents.

The conversion into a tunnel typically entails removing any Phy/Electrical layer and encoding of the underlying connection standard and potentially losslessly compresses the contents, for example by leaving out empty filler data. A USB4 tunnel itself is virtual and need not conform to any fixed bandwidth or other limitations that stem from the Phy/Electric layer of the underlying connection standard. But since most tunnel types will eventually be converted back to a regular, physical connection again, most of those physical limitations, like max. bandwidth are still likely to apply in the end.

USB3 Gen X tunneling

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This is a single-hop tunnel that essentially can transport any Enhanced SuperSpeed connection according to the USB 3.2 specification. USB3 Gen X follows the Enhanced SuperSpeed Hub topology, where every USB4 router with more than one USB3 endpoint must include a USB3 hub as well. It is the default way USB3 connections through USB4 are made. Supporting it at 10 Gbit/s (SuperSpeed USB 10 Gbps, Gen 2x1) is mandatory on every USB4 DFP. The minimum supported speed for the USB3 connection being tunneled is 10 Gbit/s as every USB4 device already has to support this speed and USB3 hubs handle converting this to 5 Gbit/s devices that may be connected.

This means, that a USB4 hub will share a single upstream USB3 connection and distribute its bandwidth across all its downstream facing ports that make use of USB3 connections.

USB3 Gen T tunneling

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This is an optional alternative to USB3 Gen X tunneling that was introduced in USB4 Version 2.0. It is an end-to-end variant of USB3 Gen X tunnel.

Through this, it eschews the need for USB3 hubs in every USB4 router that can and will limit the throughput. It allows multiple separate USB3 Gen T tunnels even over shared links. Since it is an end-to-end tunnel, every USB4 hub will support passing it through. USB3 Gen T is intended as exclusively virtual, there exists no physical equivalent for it. Thus, it can only be used inside of a USB4 controller. This allows it to leave the limitations to 10 or 20 Gbit/s connections of USB 3.2 behind, while reusing most of the other parts of the Enhanced SuperSpeed protocol.[23]

No known USB4 controller implements support for Gen T tunneling to date (August 2024).

DP tunneling

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DisplayPort is also tunneled as end-to-end connection. There can be multiple independent DP tunnels, but each will be delivered to a single protocol output adapter (at which point DisplayPort MST might be used to further split each connection up).

USB4 Version 1.0 only defines how to tunnel DP connections according to the DisplayPort 1.4a specification (up to HBR3 speeds). USB4 Version 2.0 updates this support to the full DisplayPort 2.1 specification (up to UHBR20 speeds).

DP tunneling has great understanding of the contents of DP connections, and will efficiently skip/transmit any filler data, reducing the actually utilized bandwidth of a DP tunnel. But since DP connections have real-time requirements, bandwidth must be reserved for them. USB4 mandates that in absence of any other information, the maximum possible bandwidth for the particular DP connection (DP lanes and speed) must be reserved. This reservation only applies to other real-time tunnels though. Reserved, but unused bandwidth can be used by non-real-time tunnels such as PCIe or USB3, but the reservation may still block other DP tunnels from being established.[24]

PCIe tunneling

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Similar to USB3 Gen X tunneling, PCIe tunneling uses single-hop tunnels, requiring PCIe switches in every USB4 router that supports PCIe tunneling. USB4 has, from the start, referenced the PCI Express Specification Revision 4 and with USB4 Version 2.0 added references to PCI Express Specification Revision 5.0.

PCIe tunneling has had a significant limitation in USB4 Version 1.0 and also Thunderbolt 3: PCIe Express has a variable maximum payload size, which applies end-to-end to a transmission. If any one component or PCIe Switch has a limited MPS, all packets passing through must be limited accordingly. Because USB4 uses a payload of up to 256 Byte per USB4 packet and a PCIe tunnel packet contains further PCIe headers and meta data, the MPS for PCIe tunnels was limited to 128 Byte. This limitation can reduce the efficiency of the PCIe connection greatly for all devices and systems that would otherwise support 256 Byte or even larger MPS.

USB4 Version 2.0 removes this bottleneck (mandatory for all implementers), by defining how a larger PCIe packet can be split across multiple USB4 packets. Support for this new feature requires every USB4 component / controller involved in the PCIe tunnel to implement USB4 Version 2.0.[25]

USB4 signaling modes

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Signaling refers to the lowest layer of the OSI Model, also called physical layer or phy. USB4 connections can be expressed with consumer facing names that are also the basis for the official logos used on packaging and products. These are the "20 Gbps", "40 Gbps", "80 Gbps" labels and they do not explicitly indicate how the connection is achieved on the physical layer. There are also more technical names based on the implementation and use of the USB-C cables. These usually consist of a speed per wire-pair expressed as Gen 1/2/3/4 (5 Gbit/s, 10 Gbit/s, 20 Gbit/s, 40 Gbit/s respectively) and some further information on how many wire-pairs are used in which combination.

USB commonly defines a "Lane" as a (bidirectional) connection, which for all recent transmission modes consists of one sending and one receiving wire-pair. The "Gen AxB" notation refers to B Lanes of operation mode A. Since Gen 4 modes also introduced asymmetric connections with uneven numbers of wire-pairs dedicated to sending and receiving, the Lane-notation is no longer applicable.

The USB 3.x family has had the same technical notation retroactively added in the USB 3.1 and USB 3.2 specification versions. Though this shows common principles and the same generations refer to the same nominal speeds, "Gen A" does not have the same exact meaning in both USB 3.x and USB4 specifications. The overlap in naming mainly becomes relevant for cables as shown in Cable Compatibility, which is regulated by the Type-C specification shared across all users of Type-C connector.

Comparison of signaling modes
USB family
Signaling mode name[a] Introduced in Encoding Wire-pairs sending/receiving Raw bit rate
(Gbit/s)
Net data rate[b]
(Gbit/s)
USB-IF
current marketing name[26]
Logo[26]
per wire-pair total (per direction)
USB 2.x
High-Speed USB 2.0 NRZI w/ bit stuffing 1 (shared) 0.480 (half-duplex) 0.480 (half-duplex) ? Hi-Speed USB  
USB 3.x
Gen 1x1 USB 3.0 8b/10b 1/1 5 5 4 USB 5Gbps  
Gen 2x1[c] USB 3.1 128b/132b 1/1 10 10 ~9.7 USB 10Gbps  
Gen 1x2 USB 3.2 8b/10b 2/2 5 10 8 (fallback)[d]
Gen 2x2[c] 128b/132b 2/2 10 20 ~19.39 USB 20Gbps  
USB4
Gen 2x1[c] USB4 v1.0 64b/66b[e] 1/1 10 10 ~9.697 (transient/fallback)[f]
Gen 2x2[c] 2/2 10 20 ~19.39 USB 20Gbps  
Gen 3x1 128b/132b[e] 1/1 20 20 ~19.39 (transient/fallback)[f]
Gen 3x2 2/2 20 40 ~38.79 USB 40Gbps  
Gen 4 symmetric USB4 v2.0 PAM-3[27]

11b/7t

2/2 ~40.58[g] ~81.15 ~80.46 USB 80Gbps  
Gen 4 asymmetric 3:1 3/1 3x:
~121.725
1x:
~40.58
3x:
~120.69
1x:
~40.23
[h]
Gen 4 asymmetric 1:3 1/3 [h]
TB3 Gen 2x2 64b/66b 2/2 10.3125 20.625 20
TB3 Gen 3x2 128b/132b 2/2 20.625 41.25 40
  1. ^ Names according to the newest specifications.
  2. ^ Total data rate (1 direction) with encoding overhead removed.
  3. ^ a b c d USB4 Gen 2 is different from USB3 Gen 2. They both signify the same signal rate of 10 Gbit/s, but use different encoding and differ on the electrical layer. They also have different requirements for signal quality.
  4. ^ USB3 Gen 1x2 connection requires both sides to be USB3 "20 Gbps" / Gen 2x2 capable, but fail to establish Gen 2 / 10 Gbit/s per wire-pair connections.
  5. ^ a b USB4 Gen 2 & 3 can use optional Reed–Solomon forward error correction (RS FEC). In this mode, 12 × 16 B (128 bit) symbols are assembled together with 2 B (12 bit + 4 bit reserved) synchronisation bits indicating the respective symbol types and 4 B of RS FEC to allow to correct up to 1 B of errors anywhere in the total 198 B block.
  6. ^ a b USB4 is required to support dual-lane modes, but it uses single-lane operations during initialization of a dual-lane link; single-lane link can also be used as a fallback mode in case of a lane bonding error.
  7. ^ Per spec, lines run at 25.6 GBaud. One symbol contains 1 trit of information. Encoding transforms each group of 11 bits into 7 trits. 7 trits give 2187 different values or   bits/trit. USB4 Version 2.0 Specification 2023, p84, sec. 3.2
  8. ^ a b Optional features of USB 80Gbps connections and devices.

Thunderbolt 3 Gen 2 and Gen 3 and the USB4 Gen 2 and Gen 3 modes use very similar signaling, however, Thunderbolt 3 runs at slightly higher speeds called legacy speeds compared to rounded speeds of USB4.[28] It is driven slightly faster at 10.3125 Gbit/s (for Gen 2) and 20.625 Gbit/s (for Gen 3), as required by Thunderbolt specifications.

USB4 Gen 4 is normally referred to as a speed of "40 Gbps" or 40 Gbit/s, with the full connections based on it being referred to as 80, 120/40, 40/120 Gbit/s. But since the actual signaling no longer is binary, the actual raw bit rates no longer match those numbers exactly.

USB4 capabilities by device type

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USB4 hub

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A USB4 hub is defined by having 1 USB4 UFP and one or more USB4 DFP.

USB4-based dock

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A USB4-based dock is defined as a USB4 hub that also has more specialized outputs like HDMI or DP, but still keeping some USB4 DFP.

USB4 peripheral device

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A USB4 peripheral device is defined by not having any USB4 DFP. This means devices that are colloquially called "USB-C hubs" may use USB4 to support the dynamic bandwidth sharing or higher bandwidths of USB4. But they are not USB4 hubs if they do not have any USB4 DFP. Not having any USB4 DFP allows the peripheral to only support exactly those USB4 features that it has uses for, potentially simplifying its implementation considerably.

USB4 feature support[29]
Feature Host Hub (dock) Peripheral device
Type
USB4

connection

"20 Gbps" (Gen 2x2) Yes Yes Yes
"40 Gbps" (Gen 3x2) Optional Yes Optional
"80 Gbps" (Gen 4 symm.) Optional Optional Optional
"120/40 Gbps" (Gen 4 3:1) Optional Optional[a] Optional
"40/120 Gbps" (Gen 4 1:3) Optional Optional[a] Optional
Tunneled USB3 "10 Gbps" (Gen 2x1) Yes Yes Optional
USB3 "20 Gbps" (Gen 2x2) Optional Optional Optional
USB3 Gen T (variable bandwidth)[b] Optional Optional Optional
DisplayPort Yes Yes Optional
PCI Express Optional[c] Yes Optional
Host-to-host communications/

USB4 networking

Yes Yes
Native USB3 "5 Gbps" (Gen 1x1) Yes Yes Optional
USB3 "10 Gbps" (Gen 2x1) Yes Yes Optional
USB3 "20 Gbps" (Gen 2x2) Optional Optional Optional
USB 2.0

(Low-, Full-, High-Speed)[d]

Yes Yes Optional
DisplayPort Alternate Mode[e] Yes Yes Optional
Thunderbolt Alternate Mode Optional[c] Yes Optional
Other alternate modes Optional Optional Optional
  1. ^ a b Even for "80 Gbps" USB4 hubs, supporting asymmetric connections (in either direction) is optional, but 80 Gbit/s support is a prerequisite for any asymmetric support.
  2. ^ USB3 Gen T tunneling has defined bandwidth options. They match the total USB4 speed numbers 10,20,40,80 and even asymmetric 40/120,120/40 connections. USB4 v2 specification, p536, tab.9-19
  3. ^ a b Windows HLK requires any USB4 port support PCIe tunneling and TB3 compatibility. No minimum PCIe bandwidth requirements.[30]
  4. ^ As with USB3, USB2 connection runs on separate wires from main (USB3/USB4) connection. Tunneling is not required as it runs in parallel on the cable.
  5. ^ The USB4 specification makes no requirements on the minimum speed or capabilities of any DP output.

Cable compatibility

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The Type-C standard supports cable backward / downward compatibility in many situations. The compatibility typically only breaks between the different families of standards (USB&2.0, USB 3.2, USB4). The USB4 standard mandates that classic active or hybrid active cables still have vast backward compatibility support, so as to behave as if they were regular, passive cables in the eyes of the consumer.[31] But forward compatibility is limited for active cables. Only Optically Isolated Active Cables (OIAC), that should be clearly distinguishable (price, design, cable thickness, advertising) is allowed to strip most of the backwards compatibility away.

The Gen 4 transmission mode, with PAM-3 uses very different signaling to previous modes. Every active components needs to explicitly support this new signaling. But it stays within all signal quality requirements of existing, passive Gen 3 cables (USB4 and TB3).

Cable naming and relation to specification versions

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USB-IF intends only for the new, bandwidth-based logos and names to be used with consumers.[32] And for cables, the type (passive, active) and the highest supported bandwidth are usually enough to uniquely identify a cable and its supported features. Although some active types make clear distinctions where further details on the type are required. Formally, a cable type and properties are defined by a specific specification version, which was used during the development / design of said cable model, so each cable would be a valid and possibly certified cable according to a specific set of USB specification versions like "Type-C 2.3, USB 3.2, USB4 Version 2.0". But the standard is also designed to be interoperable, in that a newer specification version typically adds new modes of operation, new cable types, but does not restrict previously existing things. Because that would make existing things incompatible with new products. For this purpose even the older USB logos and labels did not include a specification version, but only stated "Certified USB SuperSpeed+ 10 Gbps". This logo identified cables that could support the 10 Gbit/s connection speeds of USB3 across both the USB 3.1 and USB 3.2 version, because the requirements for the cables have not changed. Thus the precise specification version is usually not relevant and would not make a difference.

Transmission modes such as Gen2x2 are also irrelevant to cables, as valid cables are either full-featured, having all the high speed wire-pairs for up to dual-lane connections at the stated speed or they are USB2-only or some other specific and restrictive type as listed below.

USB4 cable compatibility

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Overview of passive[33][34] and active Type-C cables[35] and their USB4 support
Cable type Speed Marketing names Max. USB4 bit rate Expected max. cable length[a] Other support Power
Remarks USB2 USB3 TB3 DP
USB2
Hi-Speed USB   ≤ 4m Yes No No No USB PD:

60W

or

100W

or

240W

Full-Featured passive
Gen 1 USB 5Gbps 20 Gbit/s[b] ≤ 2m Yes 5 Gbit/s No Yes[c]
Gen 2 USB 20Gbps

(USB 10Gbps deprecated)

20 Gbit/s ≤ 1m Yes Yes 20 Gbit/s
(incl. passive TB4 & TB5) Gen 3 & Gen 4 USB 40Gbps

USB 80Gbps

80 Gbit/s

(or asymm.)

≤ 0.8m Yes Yes Yes[d] Yes[c][e]
Full-Featured active (also optical hybrid)
Gen 2 USB 20Gbps

(USB 10Gbps deprecated)

20 Gbit/s < 5m Yes Yes Yes Optional[f]
(incl. active TB4) Gen 3 USB 40Gbps 40 Gbit/s Yes Yes Yes Optional[f]

TB up to 2m[e]

(incl. active TB5) Gen 4 USB 80Gbps 80 Gbit/s

(or asymm.)

Yes Yes Yes
USB3 active Gen 2 ?   Yes Yes No Optional
OIAC
USB3 Gen 2 ?   ? only if optical Gen 2 only (10 / 20 Gbit/s) No Optional
USB4 Gen 3 ? 40 Gbit/s Optional
Gen 4 ? 80 Gbit/s

(asymm. optional)

Thunderbolt 3
passive Gen 2 TB Logo without "3" 20 Gbit/s ≤ 2m Yes only 5 Gbit/s when > 1m[36] 20 Gbit/s Yes[c] USB PD:

60W

or

100W

Gen 3 TB Logo + "3" 80 Gbit/s

(or asymm.)[37]

≤ 0.8m Yes Yes Yes
active Gen 3 TB Logo + "3"  [g] (longest available: 3m) Yes (mostly no)[38] Yes (mostly no)[39]
optical[40] Gen 3 TB Logo + "3"   ? No No Yes No
  1. ^ Maximum cable lengths are not normative, but simply estimates of the USB specification, based on the expected physical limits of conventional copper cables.
  2. ^ USB4 Gen 2 has less strict signal requirements than USB 3 Gen 2. Spec compliant USB3 Gen 1 cables should support USB4 Gen 2 / 20 Gbit/s connections
  3. ^ a b c No specific max. DP speed guaranteed by Type-C specification
  4. ^ USB4 launched with passive Gen 3 cables supporting TB3 40 Gbit/s on an electrical level, but where not mandated to identify in the historical way TB3 identified those cables (because that predates the existence of "Gen 3"). Early passive USB4 cables may thus not be identified as TB3 40 Gbit/s capable by old TB3 equipment predating the existence of USB4. This was fixed with a later revision.Leung, Benson (May 2023). "ECN to ensure full compatibility of USB4 cables with TB3 specification". Retrieved 2024-06-08.[citation needed]
  5. ^ a b TB4 & TB5 cables up to 2m length (active & passive) are "universal cables", including DP support. DP guarantees may only include the highest speeds covered by DP 1.4 for TB4 (HBR3) or DP 2.1 for TB5 (UHBR20).
  6. ^ a b No specific max. DP speed guaranteed by Type-C specification. There are different implementations of active cable implementations that may behave differently.
  7. ^ The Apple TB3 Pro cable is one of the few active TB3 cables that supports DP and USB3. It is unclear if that is special behavior or the cable would be compatible to USB4 as well."Apple now sells a $129 Thunderbolt 3 Pro cable". theverge.com. The Verge. 2020-07-27. Retrieved 2024-08-09.

DP Alt Mode support of USB4 cables

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The Type-C specification does not name specific DP speeds that it considers supported for passive cables and support is optional for active cables. The USB-C presentation on DP Alt mode[41] calls out passive full-featured USB-C cables for their DisplayPort support and headroom for future DP speed increases. HBR3 was the highest available DP speed at this time.

Active cables may have additional complications, because the active electronics do not need to operate all high speed wire-pairs in the same direction for normal USB operations (but "80 Gbps" cables are mandated to support asymmetric connections, which includes at least some of the wire-pairs operating in either direction). Active cables can have further limitations as the active electronics may only support specific signaling modes. There are 2 variants of active electronics. Linear ReDrivers only amplify the signal without any particular signaling mode or encoding in mind. ReTimers explicitly reconstruct the incoming signal for a higher quality result.

TB4 cables, even active ones, at least up to 2m in length are guaranteed to support DP Alt mode. A specific max. speed is also not mentioned, but the other requirements for TB4 all refer to DP 1.4 and its max. speed of HBR3.[42] TB5 renews the same guarantee[43] for "80 Gbps" cables while referencing the DP 2.1 specification (up to UHBR20 speeds).

DP 2.1 aligned itself to the USB4 PHY layer according to Vesa, the creator of DisplayPort.[44] It is unclear how complete this alignment is, however the UHBR10 DP speed matches USB4 Gen 2 in bit rate and encoding and UHBR20 DP Speed matches USB4 Gen 3 in bit rate and encoding. A USB and DP certification service lists USB Gen 1 cables ("5 Gbps") as supporting UHBR10 speeds, which would fit for having the same requirements as USB4 "20 Gbps" connections.[45]

Anandtech reports[46] that "this also means that DP Alt Mode 2.0 should largely work with USB4-compliant cables, although VESA is being careful to avoid promising compatibility with all cables".

There are linear redrivers[47] and retmers[48] available that are advertised for USB4 Gen 3 speeds and all current DP speeds up to UHBR20 and including UHBR13.5.

Thunderbolt compatibility

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Thunderbolt 3

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The USB4 specification states that a design goal is to "Retain compatibility with existing ecosystem of USB and Thunderbolt products." Compatibility with Thunderbolt 3 is required for USB4 hubs; it is optional for USB4 hosts and USB4 peripheral devices.[49] Compatible products need to implement 40 Gbit/s mode, at least 15 W of supplied power, and the different clock; implementers need to sign the license agreement and register a Vendor ID with Intel.[50]

Thunderbolt 4

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During CES 2020, USB-IF and Intel stated their intention to allow USB4 products that optionally support any or all of the same functionality as Thunderbolt 4 products. The first products compatible with USB4 were Intel's Tiger Lake processors, with more devices appearing around the end of 2020.[51][52]

Thunderbolt 4 is an implementation of USB4 "40 Gbps". Thunderbolt 4 mandates some features that are optional in USB4 including: backwards compatibility to Thunderbolt 3, minimum PCIe ("32 Gbps") and DP capabilities (2 DP tunnels, "4K60 each", HBR3+DSC).[53]

Thunderbolt 5

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Thunderbolt 5 is an implementation of USB4 "80 Gbps". It mandates even higher minimum PCIe ("64 Gbps") and DP capabilities (2 DP tunnels, "6K60 each", unclear min. DP speed). It also mandates support for asymmetric 120 / 40 Gbit/s connections from hosts to docks but does not mention the reverse.[54]

Pinout

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Type-C receptacle pinout (end-on view)

USB4 has 24 pins in a symmetrical USB type C shell. USB4 has 12 A pins on the top and 12 B pins on the bottom.[55]

USB4 has two lanes of differential SuperSpeed pairs. Lane one uses TX1+, TX1−, RX1+, RX1− and lane two uses TX2+, TX2−, RX2+, RX2−. USB4 transfers signals at 20 Gbit/s per lane. USB4 also keeps the differential D+ and D− for USB 2.0 transfer.[56]

The CC configuration channels have the roles of creating a relationship between attached ports, detecting plug orientation due to the reversible USB type C shell, discovering the VBUS power supply pins, determining the lane ordering of the SuperSpeed lanes, and finally the USB protocol makes the CC configuration channel responsible for entering USB4 operation.[57]

Type-C receptacle A pin layout
Pin Name Description
A1 GND Ground return
A2 SSTXp1 ("TX1+") SuperSpeed differential pair #1, TX, positive
A3 SSTXn1 ("TX1-") SuperSpeed differential pair #1, TX, negative
A4 VBUS Bus power
A5 CC1 Configuration channel
A6 Dp1 USB 2.0 differential pair, position 1, positive
A7 Dn1 USB 2.0 differential pair, position 1, negative
A8 SBU1 Sideband use (SBU)
A9 VBUS Bus power
A10 SSRXn2 ("RX2-") SuperSpeed differential pair #4, RX, negative
A11 SSRXp2 ("RX2+") SuperSpeed differential pair #4, RX, positive
A12 GND Ground return
Type-C receptacle B pin layout
Pin Name Description
B12 GND Ground return
B11 SSRXp1 SuperSpeed differential pair #2, RX, positive
B10 SSRXn1 SuperSpeed differential pair #2, RX, negative
B9 VBUS Bus power
B8 SBU2 Sideband use (SBU)
B7 Dn2 USB 2.0 differential pair, position 2, negative[a]
B6 Dp2 USB 2.0 differential pair, position 2, positive[a]
B5 CC2 Configuration channel
B4 VBUS Bus power
B3 SSTXn2 SuperSpeed differential pair #3, TX, negative
B2 SSTXp2 SuperSpeed differential pair #3, TX, positive
B1 GND Ground return
  1. ^ a b There is only a single non-SuperSpeed differential pair in the cable. This pin is not connected in the plug/cable.

Software support

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USB4 is supported by:

Hardware support

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Brad Saunders, CEO of the USB Promoter Group, anticipates that most PCs with USB4 will support Thunderbolt 3, but for phones the manufacturers are less likely to implement Thunderbolt 3 support.[62]

On 3 March 2020, Cypress Semiconductor announced new Type-C power (PD) controllers supporting USB4, CCG6DF as dual port and CCG6SF as single-port.[63]

In November 2020, Apple unveiled MacBook Air (M1, 2020), MacBook Pro (13-inch, M1, 2020), and Mac mini (M1, 2020) featuring two USB4 ports.

AMD also stated that Zen 3+ (Rembrandt) processors will support USB4[64] and released products do have this feature after a chipset driver update.[65] However, AMD has only announced support for USB 3.2 Gen 2x2 in Zen 4 processors that were released in September 2022.[66][67] Intel supports Thunderbolt 3 and USB-C with the mobile 9th generation processors in 2019.

References

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  1. ^ USB4 Version 2.0 Specification 2023
  2. ^ "USB-IF Announces Publication of New USB4 Specification to Enable USB 80Gbps Performance" (PDF). 2022-10-18.
  3. ^ Type-C Cable and Connector Specification 2023
  4. ^ Type-C Cable and Connector Specification, p216f, sec. 4.6
  5. ^ USB Power Delivery Specification 2023
  6. ^ USB4 Version 2.0 Specification 2023, p1, sec. 1.5, p12, sec. 2
  7. ^ USB4 Version 2.0 Specification 2023, p15, sec. 2.1.5
  8. ^ Hill, Brandon (2019-03-04). "USB4 Leverages Thunderbolt 3 Protocol Doubling Speeds To 40Gbps". HotHardware. Archived from the original on 2021-10-23. Retrieved 2020-04-28.
  9. ^ "USB4 announced with 40Gbps bandwidth, it's based on Thunderbolt 3". GSMArena.com. Archived from the original on 2022-01-15. Retrieved 2020-04-29.
  10. ^ "With USB 4, Thunderbolt and USB will converge". 2019-03-04. Archived from the original on 2022-09-10. Retrieved 2020-05-01.
  11. ^ Hagedoorn, Hilbert (2019-06-13). "USB 4.0 Will Arrive in Late 2020". Guru3D. Archived from the original on 2021-10-26. Retrieved 2020-04-30.
  12. ^ USB4 Spec. p.1
  13. ^ "USB Promoter Group Announces USB4 Version 2.0". www.businesswire.com. 2022-09-01. Archived from the original on 2022-09-02. Retrieved 2022-09-02.
  14. ^ "USB-IF Announces Publication of New USB4 Specification to Enable USB 80Gbps Performance" (PDF). USB-IF. USB Implementers Forum. 2022-10-18. Retrieved 2023-01-19.
  15. ^ Porter, Jon (2022-09-30). "USB kills off SuperSpeed branding as it tries to simplify its ubiquitous connector". The Verge. Retrieved 2024-08-05.
  16. ^ USB 2.0 Specification 2024
  17. ^ USB 3.1 Specification 2022
  18. ^ "Intel® JHL8540 Thunderbolt™ 4 Controller Product Specifications". www.intel.com. Retrieved 2024-08-06.
  19. ^ Type-C Cable and Connector Specification 2023, p244 sec. 5.3
  20. ^ USB Power Delivery Specification 2023
  21. ^ USB4 Version 2.0 Specification Inter-Domain Service 2023
  22. ^ USB4 Version 2.0 Specification 2023, p13
  23. ^ USB4 Version 2.0 Specification 2023, p487
  24. ^ USB4 Version 2.0 Specification Connection Manager Guide 2023, p59, sec. 6.1
  25. ^ USB4 Version 2.0 Specification 2023, p660, sec. 11.1.1.1.3
  26. ^ a b USB Trademark Requirements Chart from USB-IF
  27. ^ Team GraniteRiverLabs (2023-01-17). "Welcome to the 80Gpbs Ultra-High Speed Era of USB4". www.graniteriverlabs.com. GraniteRiverLabs Taiwan. Archived from the original on 2023-02-21. Retrieved 2023-02-21.
  28. ^ "How to Test and Troubleshoot USB4" (PDF). Archived (PDF) from the original on 2022-09-10. Retrieved 2022-07-25.
  29. ^ USB4 Version 2.0 Specification 2023, p17ff, sec. 2.1.1.4
  30. ^ windows-driver-content (2022-05-18). "USB4 Systems PCIe Tunneling Support". learn.microsoft.com. Retrieved 2024-08-05.
  31. ^ Type-C Cable and Connector Specification 2023, p261 para. 3
  32. ^ "USB Branding Session 2019" (PDF). usb.org. 2020-02-07. p16. Retrieved 2024-07-08.
  33. ^ Type-C Cable and Connector Specification 2023, p42, Tab 3-1
  34. ^ "How to Beat the Maximum USB Cable Length Limit". blog.tripplite.com. Retrieved 2024-03-14.
  35. ^ Type-C Cable and Connector Specification 2023, p261 sec. 6
  36. ^ "Cable Matters 107002 40 Gbps / 20 Gbps Thunderbolt 3 Cable". kb.cablematters.com. 2024-10-09. Retrieved 2024-08-12. When connected to USB-C devices, the data rate can reach 10 Gbps (0.5m & 1m) and 5 Gbps (2m).
  37. ^ Type-C Cable and Connector Specification 2023, p246, fig. 5-1
  38. ^ "USB-C Cables, Thunderbolt 3 Cables - How to tell them apart". archive.caldigit.com. CalDigit. Retrieved 2024-08-08.
  39. ^ "How to select a Thunderbolt 3 cable?". chargerlab.com. 2019-05-11. Retrieved 2024-08-08.
  40. ^ "Corning Thunderbolt™ 3 Optical Cable (40 Gb/s)" (PDF). Corning. Retrieved 2024-08-08.
  41. ^ "VESA – DisplayPortTM Alternate Mode on USB-C®" (PDF). 2019-11-19. p23. Retrieved 2024-08-08.
  42. ^ "Intel Thunderbolt 4™ Announcement Press Deck" (PDF). Intel. p9, p13. Retrieved 2024-08-08.
  43. ^ "Thunderbolt 5™ Press Deck" (PDF). thunderbolttechnology.net. Intel. Retrieved 2024-08-09.
  44. ^ "VESA Releases DisplayPort 2.1 Specification". Retrieved 2024-08-06.
  45. ^ "Specification and Test Overview of DisplayPort™ 2.1". Granite River Labs. Ultra High Bit Rate in DisplayPort™ 2.1. Retrieved 2024-08-08.
  46. ^ "DisplayPort Alt Mode 2.0 Spec Released: Defining Alt Mode for USB4". Anandtech. Retrieved 2024-08-08.
  47. ^ "PI2DPX2020". Diodes. 2011-03-02. Retrieved 2024-08-08.
  48. ^ "KM864742". Nuvoton. Retrieved 2024-08-09.
  49. ^ USB4 Specification V1.0 August 2019 Chapter 13: "A USB4 host and USB4 peripheral device may optionally support TBT3-Compatibility. If a USB4 host or USB4 peripheral device supports TBT3-Compatibility, it shall do so as defined in this chapter".
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  53. ^ "Intel Thunderbolt 4 Announcement Press Deck" (PDF). thunderbolttechnology.net. Intel. p4. Retrieved 2024-08-08.
  54. ^ "Thunderbolt 5™ Press Deck" (PDF). thunderbolttechnology.net. Intel. p19. Retrieved 2024-08-09.
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  56. ^ "USB4 Specification". www.usb.org. Archived from the original on 2022-04-14. Retrieved 2022-04-05.
  57. ^ Leung, Benson (2018-11-19). "USB Type-C's Configuration Channel". Medium. Archived from the original on 2022-04-05. Retrieved 2022-04-05.
  58. ^ "Linux 5.6 Kernel Released With WireGuard, USB4, New AMD + Intel Hardware Support – Phoronix". Phoronix.com. Archived from the original on 2021-11-02. Retrieved 2020-04-28.
  59. ^ "Introducing the next generation of Mac". apple.com. 2020-11-10. Archived from the original on 2021-03-01. Retrieved 2020-11-13.
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  61. ^ "February 29, 2024—KB5034848 (OS Builds 22621.3235 and 22631.3235) Preview - Microsoft Support". support.microsoft.com. Retrieved 2024-08-05.
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  63. ^ Shilov, Anton. "Cypress Announces USB 3.2 & USB4-Ready Controllers: EZ-PD CCG6DF & CCG6SF". www.anandtech.com. Archived from the original on 2021-12-06. Retrieved 2020-04-28.
  64. ^ Cutress, Ian (2022-01-04). "AMD Announces Ryzen 6000 Mobile CPUs for Laptops: Zen3+ on 6nm with RDNA2 Graphics". Anandtech. Archived from the original on 2022-06-25. Retrieved 2022-07-26.
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  66. ^ Bonshor, Gavin (2022-05-23). "AMD Ryzen 7000 Announced: 16 Cores of Zen 4, Plus PCIe 5 and DDR5 for Socket AM5, Coming This Fall". Anandtech. Archived from the original on 2022-07-26. Retrieved 2022-07-26.
  67. ^ "AMD confirms Zen4 & Ryzen 7000 series lineup: Raphael in 2022, Dragon Range and Phoenix in 2023". VideoCardz.com. Retrieved 2022-11-29.

Specification References

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