fbpx
Wikipedia

USB-C

April 13, 2024

USB-C, or USB Type-C, is a 24-pin connector (not a protocol) that supersedes previous USB connectors and can carry audio, video and other data, e.g., to drive multiple displays or to store a backup to an external drive. It can also provide and receive power, such as powering a laptop or a mobile phone. It is applied not only by USB technology, but also by other protocols, including Thunderbolt, PCIe, HDMI, DisplayPort, and others. It is extensible to support future standards.

USB-C
Pins of the USB-C connector
Type Digital audio / video / data / power – connector
Production history
Designer USB Implementers Forum
Designed 11 August 2014 (published)[1]
Superseded All earlier USB connectors (Type-A and -B, and its different sizes: Standard, Mini, and Micro)
DisplayPort
Mini DisplayPort
Lightning
General specifications
Pins 24
USB-C plug
USB-C (SuperSpeed USB 5Gbps) receptacle on an MSI laptop

Design for the USB-C connector was initially developed in 2012 by Apple Inc. and Intel.[2] Type-C Specification 1.0 was published by the USB Implementers Forum (USB-IF) on August 11, 2014.[3] In July 2016, it was adopted by the IEC as "IEC 62680-1-3".[4]

The USB Type-C connector has 24 pins and is reversible.[5][6] The designation "C" is to distinguish it from the various former USB connectors it replaced, all termed either Type-A or Type-B. Whereas earlier every USB cable had a host end A and a peripheral device end B, USB-C replaces both; a USB-C cable connects either way, and for older equipment a legacy cable has a Type-C plug at one end and either a Type-A (host) or a Type-B (peripheral device) plug at the other. The designation "C" refers only to the connector's physical configuration, or form factor, not to be confused with the connector's specific capabilities, such as Thunderbolt 3, DisplayPort 2.0, or USB 3.2 Gen 2x2. Based on the protocols supported by both devices, host and peripheral device, a USB-C connection normally provides (much) higher signaling and therefore data rates than the superseded connectors.

A device with a Type-C connector does not necessarily implement any USB transfer protocol, USB Power Delivery, or any of the Alternate Modes: the Type-C connector is common to several technologies while mandating only a few of them.[7]

USB 3.2, released in September 2017, fully replaced the USB 3.1 specification. It preserves previously called USB 3.1 SuperSpeed and SuperSpeed+ data transfer modes and introduces two additional data transfer modes by newly applying two-lane operations, with signaling rates of 10 Gbit/s (SuperSpeed USB 10Gbps; nominal data rate: 1.212 GB/s) and 20 Gbit/s (SuperSpeed USB 20Gbps; nominal data rate: 2.422 GB/s). They are only applicable with Full-Featured USB-C Fabrics (connectors and cables) on both ends.

USB4, released in 2019, is the first USB transfer protocol standard that is only available exclusively via USB-C Fabrics.

Ease of use edit

The USB-C standard simplifies usage by specifying cables having identical plugs on both ends, which can be inserted without concern about orientation. When connecting two devices, the user can plug either end of the cable into either device. The plugs are flat, but will work if inserted right-side-up or upside-down.

The USB-C plugs have two-fold rotational symmetry because a plug may be inserted into a receptacle in either of two orientations. Electrically, USB-C plugs are not symmetric, as can be seen in the tables of pin layouts. Also the two ends of the USB-C are electrically different, as can be seen in the table of cable wiring. The illusion of symmetry results from how devices respond to the cable. Software makes the plugs and cables behave as though they are symmetric. According to the specifications, "Determination of this host-to-device relationship is accomplished through a Configuration Channel (CC) that is connected through the cable."[8]

The USB-C standard attempts to eliminate the need to have different cables for other communication technologies, such as Thunderbolt, PCIe, HDMI, DisplayPort, and more. USB-C cables can contain circuit boards and processors giving them much more capability than simple circuit connections.

Overview edit

USB-C cables interconnect hosts and peripheral devices, replacing various other electrical cables and connectors, including all earlier (legacy) USB connectors, HDMI connectors, DisplayPort ports, and 3.5 mm audio jacks.[9][10]

Name edit

USB Type-C and USB-C are trademarks of the USB Implementers Forum.[11]

Connectors edit

 
USB-C port on MacBook Pro (middle port)

The 24-pin double-sided connector is slightly larger than the micro-B connector, with a USB-C receptacle measuring 8.4 millimetres (0.33 in) wide, 2.6 millimetres (0.10 in) high, and 6.65 millimetres (0.262 in) deep.

Cables edit

USB 3.1 cables are considered full-featured USB-C cables. They are electronically marked cables that contain a chip with an ID function based on the configuration channel and vendor-defined messages (VDM) from the USB Power Delivery 2.0 specification. Cable length should not exceed 2 metres (6 ft 7 in) for Gen 1, and 1 metre (3 ft 3 in) for Gen 2.[12] The electronic ID chip provides information about product/vendor, cable connectors, USB signaling protocol (2.0, Gen 1, Gen 2), passive/active construction, use of VCONN power, available VBUS current, latency, RX/TX directionality, SOP controller mode, and hardware/firmware version.[7]

USB-C cables that do not have shielded SuperSpeed pairs, sideband use pins, or additional wires for power lines can have increased cable length, up to 4 metres (13 ft). These USB-C cables only support USB 2.0 (up to 480 Mbit/s) and do not support Alternate Modes. Active cables (those with built-in repeaters) can support SuperSpeed USB 5Gbps (= USB 3.2 Gen 1x1 = USB 3.1 Gen 1 = USB 3.0) only over lengths up to 10 metres (33 ft).

All USB-C cables must be able to carry a minimum of 3 A current (at 5 V, for 15 W) but some can carry 5 A current (at 20 V, for 100 W).[13] USB-C to USB-C cables supporting 5 A current must contain e-marker chips (also marketed as E-Mark chips) programmed to identify the cable and its current capabilities. USB charging ports should be clearly marked with power capability.[14]

Full-featured USB-C cables that implement USB 3.1 Gen 2 can provide 10 Gbit/s (full duplex) signalling rate. They are marked with a SuperSpeed USB 10Gbps (previously marketed as SuperSpeed+) logo. There are also cables which can support only USB 2.0 with a nominal data rate of 480 Mbit/s (with maximal effective data rate of ~40MB/s). The USB Implementers Forum certifies valid cables so they can be marked accordingly and users can distinguish them from non-compliant products.[15]

Hosts and peripheral devices edit

For any two pieces of equipment connecting over USB, one is a host (with a downstream-facing port, DFP) and the other is a peripheral device (with an upstream-facing port, UFP). Some products, such as mobile phones, can take either role, whichever is opposite that of the connected equipment. Such equipment is said to have Dual-Role-Data (DRD) capability, which was known as USB On-The-Go in the previous specification.[16] With USB-C, when two such devices are connected, the roles are first randomly assigned, but a swap can be commanded from either end, although there are optional path and role detection methods that would allow equipment to select a preference for a specific role. Furthermore, Dual-Role equipment that implements USB Power Delivery may swap data and power roles independently using the Data Role Swap or Power Role Swap processes. This allows for charge-through hub or docking station applications such as a portable computer acting as a host to connect to peripherals but being powered by the dock, or a computer being powered by a display, through a single USB-C cable.[7]

USB-C devices may optionally provide or consume bus power currents of 1.5 A and 3.0 A (at 5 V) in addition to baseline bus power provision; power sources can either advertise increased USB current through the configuration channel or implement the full USB Power Delivery specification using both the BMC-coded configuration line and the legacy BFSK-coded VBUS line.[7][14]

All older USB connectors (all Type-A and Type-B) are designated legacy. Connecting legacy and modern, USB-C equipment requires either a legacy cable assembly (a cable with any Type-A or Type-B plug on one end and a Type-C plug on the other) or, in very specific cases, a legacy adapter assembly.

An older device can connect to a modern (USB-C) host by using a legacy cable, with a Standard-B, Mini-B, or Micro-B plug on the device end and a USB-C plug on the other. Similarly, a modern device can connect to a legacy host by using a legacy cable with a USB-C plug on the device end and a Standard-A plug on the host end. Legacy adapters with USB-C receptacles are "not defined or allowed" by the specification because they can create "many invalid and potentially unsafe" cable combinations (being any cable assembly with two A ends or two B ends). However, exactly two types of adapter with USB-C plugs are defined: one with a Standard-A receptacle (for connecting a legacy device (such as a flash drive—not a cable) to a modern host, and supporting up to USB 3.1), and one with a Micro-B receptacle (for connecting a modern device to a legacy host, and supporting up to USB 2.0).[17]

Non-USB modes edit

Audio adapter accessory mode edit

A device with a USB-C port may support analog headsets through an audio adapter with a 3.5 mm jack, providing three analog audio channels (left and right output and microphone). The audio adapter may optionally include a USB-C charge-through port to allow 500 mA device charging. The engineering specification states that an analog headset shall not use a USB-C plug instead of a 3.5 mm plug. In other words, headsets with a USB-C plug should always support digital audio (and optionally the accessory mode).[18]

Analog signals use the USB 2.0 differential pairs (Dp and Dn for Right and Left) and the two side-band use pairs for Mic and GND. The presence of the audio accessory is signaled through the configuration channel and VCONN.

Alternate modes edit

See also: USB-C § Alternate Mode partner specifications

An Alternate Mode dedicates some of the physical wires in a USB-C cable for direct device-to-host transmission using non-USB data protocols, such as DisplayPort or Thunderbolt. The four high-speed lanes, two side-band pins, and (for dock, detachable device and permanent-cable applications only) five additional pins can be used for Alternate Mode transmission. The modes are configured using vendor-defined messages (VDM) through the configuration channel.

Specifications edit

USB Type-C cable and connector specifications edit

The USB Type-C specification 1.0 was published by the USB Implementers Forum (USB-IF) and was finalized in August 2014.[10]

It defines requirements for cables and connectors.

  • Rev 1.1 was published 2015-04-03[19]
  • Rev 1.2 was published 2016-03-25[20]
  • Rev 1.3 was published 2017-07-14[21]
  • Rev 1.4 was published 2019-03-29[21]
  • Rev 2.0 was published 2019-08-29[22]
  • Rev 2.1 was published 2021-05-25 (USB PD - Extended Power Range - 48 V - 5 A - 240 W)[23]
  • Rev 2.2 was published 2022-10-18, primarily for enabling USB4 Version 2.0 (80 Gbps) over USB Type-C connectors and cables.[17]
  • Rev 2.3 was published 2023-10-31.

Adoption as IEC specification:

  • IEC 62680-1-3:2016 (2016-08-17, edition 1.0) "Universal serial bus interfaces for data and power – Part 1-3: Universal Serial Bus interfaces – Common components – USB Type-C cable and connector specification"[24]
  • IEC 62680-1-3:2017 (2017-09-25, edition 2.0) "Universal serial bus interfaces for data and power – Part 1-3: Common components – USB Type-C Cable and Connector Specification"[25]
  • IEC 62680-1-3:2018 (2018-05-24, edition 3.0) "Universal serial bus interfaces for data and power – Part 1-3: Common components – USB Type-C Cable and Connector Specification"[26]

Receptacles edit

 
Type-C receptacle pinout (end-on view)

The receptacle features four power and four ground pins, two differential pairs (connected together on devices) for legacy USB 2.0 high-speed data, four shielded differential pairs for Enhanced SuperSpeed data (two transmit and two receive pairs), two Sideband Use (SBU) pins, and two Configuration Channel (CC) pins.

Type-C receptacle A pin layout
Pin Name Description
A1 GND Ground return
A2 SSTXp1 ("TX1+") SuperSpeed differential pair #1, transmit, positive
A3 SSTXn1 ("TX1-") SuperSpeed differential pair #1, transmit, negative
A4 VBUS Bus power
A5 CC1 Configuration channel
A6 D+ USB 2.0 differential pair, position 1, positive
A7 D- USB 2.0 differential pair, position 1, negative
A8 SBU1 Sideband use (SBU)
A9 VBUS Bus power
A10 SSRXn2 ("RX2-") SuperSpeed differential pair #4, receive, negative
A11 SSRXp2 ("RX2+") SuperSpeed differential pair #4, receive, positive
A12 GND Ground return
Type-C receptacle B pin layout
Pin Name Description
B12 GND Ground return
B11 SSRXp1 ("RX1+") SuperSpeed differential pair #2, receive, positive
B10 SSRXn1 ("RX1-") SuperSpeed differential pair #2, receive, negative
B9 VBUS Bus power
B8 SBU2 Sideband use (SBU)
B7 D- USB 2.0 differential pair, position 2, negative[a]
B6 D+ USB 2.0 differential pair, position 2, positive[a]
B5 CC2 Configuration channel
B4 VBUS Bus power
B3 SSTXn2 ("TX2-") SuperSpeed differential pair #3, transmit, negative
B2 SSTXp2 ("TX2+") SuperSpeed differential pair #3, transmit, 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.

Plugs edit

 
Type-C plug pinout (end-on view)

The plug has only one USB 2.0 high-speed differential pair, and one of the CC pins (CC2) is replaced by VCONN, to power optional electronics in the cable, and the other is used to actually carry the Configuration Channel (CC) signals. These signals are used to determine the orientation of the cable, as well as to carry USB Power Delivery communications.

Cables edit

Although plugs have 24 pins, cables have only 18 wires. In the following table, the "No." column shows the wire number.

Full-Featured USB 3.2 and 2.0 Type-C cable wiring
Plug 1, USB Type-C USB Type-C cable Plug 2, USB Type-C
Pin Name Wire color No. Name Description 2.0[a] Pin Name
Shell Shield Braid Braid Shield Cable external braid   Shell Shield
A1, B12,
B1, A12 		GND Tin-plated 1 GND_PWRrt1 Ground for power return   A1, B12,
B1, A12 		GND
16 GND_PWRrt2  
A4, B9,
B4, A9 		VBUS Red 2 PWR_VBUS1 VBUS power   A4, B9,
B4, A9 		VBUS
17 PWR_VBUS2  
B5 VCONN Yellow 18 PWR_VCONN VCONN power, for powered cables[b]   B5 VCONN
A5 CC Blue 3 CC Configuration channel   A5 CC
A6 D+ Green 4 UTP_Dp[c] Unshielded twisted pair, positive   A6 D+
A7 D- White 5 UTP_Dn[c] Unshielded twisted pair, negative   A7 D-
A8 SBU1 Red 14 SBU_A Sideband use A   B8 SBU2
B8 SBU2 Black 15 SBU_B Sideband use B   A8 SBU1
A2 SSTXp1 Yellow[d] 6 SDPp1 Shielded differential pair #1, positive   B11 SSRXp1
A3 SSTXn1 Brown[d] 7 SDPn1 Shielded differential pair #1, negative   B10 SSRXn1
B11 SSRXp1 Green[d] 8 SDPp2 Shielded differential pair #2, positive   A2 SSTXp1
B10 SSRXn1 Orange[d] 9 SDPn2 Shielded differential pair #2, negative   A3 SSTXn1
B2 SSTXp2 White[d] 10 SDPp3 Shielded differential pair #3, positive   A11 SSRXp2
B3 SSTXn2 Black[d] 11 SDPn3 Shielded differential pair #3, negative   A10 SSRXn2
A11 SSRXp2 Red[d] 12 SDPp4 Shielded differential pair #4, positive   B2 SSTXp2
A10 SSRXn2 Blue[d] 13 SDPn4 Shielded differential pair #4, negative   B3 SSTXn2
  1. ^ USB 2.0 Type-C cables do not include wires for SuperSpeed or sideband use.
  2. ^ VCONN must not traverse end-to-end through the cable. Some isolation method must be used.
  3. ^ a b There is only a single differential pair for non-SuperSpeed data in the cable, which is connected to A6 and A7. Contacts B6 and B7 should not be present in the plug.
  4. ^ a b c d e f g h Wire colors for differential pairs are not mandated.

Related USB-IF specifications edit

USB Type-C Locking Connector Specification
The USB Type-C Locking Connector Specification was published 2016-03-09. It defines the mechanical requirements for USB-C plug connectors and the guidelines for the USB-C receptacle mounting configuration to provide a standardized screw lock mechanism for USB-C connectors and cables.[27]
USB Type-C Port Controller Interface Specification
The USB Type-C Port Controller Interface Specification was published 2017-10-01. It defines a common interface from a USB-C Port Manager to a simple USB-C Port Controller.[28]
USB Type-C Authentication Specification
Adopted as IEC specification: IEC 62680-1-4:2018 (2018-04-10) "Universal Serial Bus interfaces for data and power - Part 1-4: Common components - USB Type-C Authentication Specification"[29]
USB 2.0 Billboard Device Class Specification
USB 2.0 Billboard Device Class is defined to communicate the details of supported Alternate Modes to the computer host OS. It provides user readable strings with product description and user support information. Billboard messages can be used to identify incompatible connections made by users. They optionally appear to negotiate multiple Alternate Modes and must appear when negotiation fails between the host (source) and device (sink).
USB Audio Device Class 3.0 Specification
USB Audio Device Class 3.0 defines powered digital audio headsets with a USB-C plug.[7] The standard supports the transfer of both digital and analog audio signals over the USB port.[30]
USB Power Delivery Specification
Main article: USB Power Delivery
While it is not necessary for USB-C compliant devices to implement USB Power Delivery, for USB-C DRP/DRD (Dual-Role-Power/Data) ports, USB Power Delivery introduces commands for altering a port's power or data role after the roles have been established when a connection is made.[31]
USB 3.2 Specification
USB 3.2, released in September 2017, replaces the USB 3.1 standard. It preserves existing USB 3.1 SuperSpeed and SuperSpeed+ data modes and introduces two new SuperSpeed+ transfer modes over the USB-C connector using two-lane operation, doubling the data rates to 10 and 20 Gbit/s (1 and ~2.4 GB/s). USB 3.2 is only supported by USB-C, making micro-USB connectors obsolete.
USB4 Specification
The USB4 specification released in 2019 is the first USB data transfer specification to exclusively use the Type-C connector.

Alternate Mode partner specifications edit

As of 2018, five system-defined Alternate Mode partner specifications exist. Additionally, vendors may support proprietary modes for use in dock solutions. Alternate Modes are optional; Type-C features and devices are not required to support any specific Alternate Mode. The USB Implementers Forum is working with its Alternate Mode partners to make sure that ports are properly labelled with respective logos.[32]

List of Alternate Mode partner specifications
Logo Name Date Protocol Status
  Thunderbolt Alternate Mode Announced in June 2015[33] USB-C is the native (and only) connector for Thunderbolt 3 and later

Thunderbolt 3 (also carries 4× PCI Express 3.0, DisplayPort 1.2, DisplayPort 1.4, USB 3.1 Gen 2),[33][34][35][36]
Thunderbolt 4 (also carries 4× PCI Express 3.0, DisplayPort 2.0, USB4),
Thunderbolt 5 (also carries 4× PCI Express 4.0, DisplayPort 2.1, USB4) 		Current
  DisplayPort Alternate Mode Published in September 2014 DisplayPort 1.2, DisplayPort 1.4,[37][38] DisplayPort 2.0[39] Current
  Mobile High-Definition Link (MHL) Alternate Mode Announced in November 2014[40] MHL 1.0, 2.0, 3.0 and superMHL 1.0[41][42][43][44] Current
  HDMI Alternate Mode Announced in September 2016[45] HDMI 1.4b[46][47][48][49] Not being updated
VirtualLink Alternate Mode Announced in July 2018[50] VirtualLink 1.0[51] Abandoned

Other protocols like Ethernet[52] have been proposed, although Thunderbolt 3 and later are also capable of 10 Gigabit Ethernet networking.[53]

All Thunderbolt 3 controllers support both Thunderbolt Alternate Mode and DisplayPort Alternate Mode.[54] Because Thunderbolt can encapsulate DisplayPort data, every Thunderbolt controller can either output DisplayPort signals directly over DisplayPort Alternative Mode or encapsulated within Thunderbolt in Thunderbolt Alternate Mode. Low-cost peripherals mostly connect via DisplayPort Alternate Mode while some docking stations tunnel DisplayPort over Thunderbolt.[55]

DisplayPort Alternate Mode 2.0: DisplayPort 2.0 can run directly over USB-C alongside USB4. DisplayPort 2.0 can support 8K resolution at 60 Hz with HDR10 color and can use up to 80 Gbps, which is double the amount available to USB data.[56]

The USB SuperSpeed protocol is similar to DisplayPort and PCIe/Thunderbolt, in using packetized data transmitted over differential LVDS lanes with embedded clock using comparable bit rates, so these Alternate Modes are easier to implement in the chipset.[37]

Alternate Mode hosts and sinks can be connected with either regular Full-Featured Type-C cables, or with converter cables or adapters:

USB 3.1 Type-C to Type-C Full-Featured cable
DisplayPort, Mobile High-Definition Link (MHL), HDMI and Thunderbolt (20 Gbit/s, or 40 Gbit/s with cable length up to 0.5 m[citation needed]) Alternate Mode Type-C ports can be interconnected with standard passive Full-Featured USB Type-C cables. These cables are only marked with standard "trident" SuperSpeed USB logo (for Gen 1 cables) or the SuperSpeed+ USB 10 Gbit/s logo (for Gen 2 cables) on both ends.[57] Cable length should be 2.0 m or less for Gen 1 and 1.0 m or less for Gen 2.
Thunderbolt Type-C to Type-C active cable
Thunderbolt 3 (40 Gbit/s) Alternate Mode with cables longer than 0.8 m requires active Type-C cables that are certified and electronically marked for high-speed Thunderbolt 3 transmission, similarly to high-power 5 A cables.[33][36] These cables are marked with a Thunderbolt logo on both ends. They do not support USB 3 backwards compatibility, only USB 2 or Thunderbolt. Cables can be marked for both Thunderbolt and 5 A power delivery at the same time.[58]

Active cables and adapters contain powered electronics to allow for longer cables or to perform protocol conversion. The adapters for video Alternate Modes may allow conversion from native video stream to other video interface standards (e.g., DisplayPort, HDMI, VGA or DVI).

Using Full-Featured Type-C cables for Alternate Mode connections provides some benefits. Alternate Mode does not employ USB 2.0 lanes and the configuration channel lane, so USB 2.0 and USB Power Delivery protocols are always available. In addition, DisplayPort and MHL Alternate Modes can transmit on one, two, or four SuperSpeed lanes, so two of the remaining lanes may be used to simultaneously transmit USB 3.1 data.[59]

Alternate Mode protocol support matrix for Type-C cables and adapters
Mode USB 3.1 Type-C cable[a] Adapter cable or adapter Construction
USB[b] DisplayPort Thunderbolt superMHL HDMI HDMI DVI-D Component video
3.1 1.2 1.4 20 Gbit/s 40 Gbit/s 1.4b 1.4b 2.0b Single-link Dual-link (YPbPr, VGA/DVI-A)
DisplayPort Yes Yes Does not appear No Passive
Does not appear Optional Yes Yes Yes Active
Thunderbolt Yes[c] Yes[c] Yes Yes[d] Does not appear No Passive
Does not appear Optional Optional Yes Yes Yes Yes Active
MHL Yes Does not appear Yes Does not appear Yes No Yes No No Passive
Does not appear Optional Does not appear Yes Does not appear Yes Active
HDMI Does not appear Yes Yes No Yes No No Passive
Optional Does not appear Yes Active
  1. ^ USB 2.0 and USB Power Delivery are available at all times in a Type-C cable
  2. ^ USB 3.1 can be transmitted simultaneously when the video signal bandwidth requires two or fewer lanes.
  3. ^ a b Is only available in Thunderbolt 3 DisplayPort mode
  4. ^ Thunderbolt 3 40 Gbit/s passive cables are only possible <0.8 m due to limitations of current cable technology.

USB-C receptacle pin usage in different modes edit

The diagrams below depict the pins of a USB-C receptacle in different use cases.

USB 2.0/1.1 edit

A simple USB 2.0/1.1 device mates using one pair of D+/D− pins. Hence, the source (host) does not require any connection management circuitry, but it lacks the same physical connector so therefore USB-C is not backward compatible. VBUS and GND provide 5 V up to 500 mA of current.

However, to connect a USB 2.0/1.1 device to a USB-C host, use of Rd[60] on the CC pins is required, as the source (host) will not supply VBUS until a connection is detected through the CC pins.

This means many USB-A–to–USB-C cables will only work in the A to C direction (connecting to a USB-C devices, e.g. for charging) as they do not include the termination resistors needed to work in the C to A direction (from a USB-C host). Adapters or cables from USB-C to a USB-A receptacle usually do work as they include the required termination resistor.

GND TX1+ TX1− VBUS CC1 D+ D− SBU1 VBUS RX2− RX2+ GND
GND RX1+ RX1− VBUS SBU2 D− D+ CC2 VBUS TX2− TX2+ GND

USB Power Delivery edit

The USB Power Delivery specification uses one of CC1 or CC2 pins for power negotiation between source device and sink device, up to 20 V at 5 A. It is transparent to any data transmission mode, and can therefore be used together with any of them as long as the CC pins are intact.

An extension to the specification has added 28V, 36V and 48V to support up to 240W of power for laptops, monitors, hard disks and other peripherals.[61]

GND TX1+ TX1− VBUS CC1 D+ D− SBU1 VBUS RX2− RX2+ GND
GND RX1+ RX1− VBUS SBU2 D− D+ CC2 VBUS TX2− TX2+ GND

USB 3.0/3.1/3.2 edit

In the USB 3.0/3.1/3.2 mode, two or four high speed links are used in TX/RX pairs to provide 5, 10, or 20 Gbit/s (only by USB 3.2 x2 two-lane operations) signalling rates respectively. One of the CC pins is used to negotiate the mode.

VBUS and GND provide 5 V up to 900 mA, in accordance with the USB 3.1 specification. A specific USB-C mode may also be entered, where 5 V at nominal either 1.5 A or 3 A is provided.[62] A third alternative is to establish a USB Power Delivery (USB-PD) contract.

In single-lane mode, only the differential pairs closest to the CC pin are used for data transmission. For dual-lane data transfers, all four differential pairs are in use.

The D+/D− link for USB 2.0/1.1 is typically not used when USB 3.x connection is active, but devices like hubs open simultaneous 2.0 and 3.x uplinks in order to allow operation of both types of devices connected to it. Other devices may have the ability to fall back to 2.0, in case the 3.x connection fails.

GND TX1+ TX1− VBUS CC1 D+ D− SBU1 VBUS RX2− RX2+ GND
GND RX1+ RX1− VBUS SBU2 D− D+ CC2 VBUS TX2− TX2+ GND

Alternate Modes edit

In Alternate Modes one of up to four high speed links are used in whatever direction is needed. SBU1, SBU2 provide an additional lower speed link. If two high speed links remain unused, then a USB 3.0/3.1 link can be established concurrently to the Alternate Mode.[38] One of the CC pins is used to perform all the negotiation. An additional low band bidirectional channel (other than SBU) may share that CC pin as well.[38][46] USB 2.0 is also available through D+/D− pins.

In regard to power, the devices are supposed to negotiate a Power Delivery contract before an Alternate Mode is entered.[63]

GND TX1+ TX1− VBUS CC1 D+ D− SBU1 VBUS RX2− RX2+ GND
GND RX1+ RX1− VBUS SBU2 D− D+ CC2 VBUS TX2− TX2+ GND

Debug Accessory Mode edit

The external device test system (DTS) signals to the target system (TS) to enter debug accessory mode via CC1 and CC2 both being pulled down with an Rd resistor value or pulled up as Rp resistor value from the test plug (Rp and Rd defined in Type-C specification).

After entering debug accessory mode, optional orientation detection via the CC1 and CC2 is done via setting CC1 as a pullup of Rd resistance and CC2 pulled to ground via Ra resistance (from the test system Type-C plug). While optional, orientation detection is required if USB Power Delivery communication is to remain functional.

In this mode, all digital circuits are disconnected from the connector, and the 14 bold pins can be used to expose debug related signals (e.g. JTAG interface). USB IF requires for certification that security and privacy consideration and precaution has been taken and that the user has actually requested that debug test mode be performed.

GND TX1+ TX1− VBUS CC1 D+ D− SBU1 VBUS RX2− RX2+ GND
GND RX1+ RX1− VBUS SBU2 D− D+ CC2 VBUS TX2− TX2+ GND

If a reversible Type-C cable is required but Power Delivery support is not, the test plug will need to be arranged as below, with CC1 and CC2 both being pulled down with an Rd resistor value or pulled up as Rp resistor value from the test plug:

GND TS1 TS2 VBUS CC1 TS6 TS7 TS5 VBUS TS4 TS3 GND
GND TS3 TS4 VBUS TS5 TS7 TS6 CC2 VBUS TS2 TS1 GND

This mirroring of test signals will only provide 7 test signals for debug usage instead of 14, but with the benefit of minimizing extra parts count for orientation detection.

Audio Adapter Accessory Mode edit

In this mode, all digital circuits are disconnected from the connector, and certain pins become reassigned for analog outputs or inputs. The mode, if supported, is entered when both CC pins are shorted to GND. D− and D+ become audio output left L and right R, respectively. The SBU pins become a microphone pin MIC, and the analog ground AGND, the latter being a return path for both outputs and the microphone. Nevertheless, the MIC and AGND pins must have automatic swap capability, for two reasons: firstly, the USB-C plug may be inserted either side; secondly, there is no agreement, which TRRS rings shall be GND and MIC, so devices equipped with a headphone jack with microphone input must be able to perform this swap anyway.[64]

This mode also allows concurrent charging of a device exposing the analog audio interface (through VBUS and GND), however only at 5 V and 500 mA, as CC pins are unavailable for any negotiation.

GND TX1+ TX1− VBUS CC1 R L MIC VBUS RX2− RX2+ GND
GND RX1+ RX1− VBUS AGND L R CC2 VBUS TX2− TX2+ GND

Plug insertions detection is performed by the TRRS plug's physical plug detection switch. On plug insertions, this will pull down both CC and VCONN in the plug (CC1 and CC2 in the receptacle). This resistance must be less than 800 ohms which is the minimum "Ra" resistance specified in the USB Type-C specification). This is essentially a direct connection to USB digital ground.

TRRS rings wiring to Type-C plug (Figure A-2 of USB Type-C Cable and Connector Specification Release 1.3)
TRRS socket Analog audio signal USB Type-C plug
Tip L D−
Ring 1 R D+
Ring 2 Microphone/ground SBU1 or SBU2
Sleeve Microphone/ground SBU2 or SBU1
DETECT1 Plug presence detection switch CC, VCONN
DETECT2 Plug presence detection switch GND

Software support edit

Authentication edit

USB Type-C Authentication is an extension to the USB-C protocol which can add security to the protocol.[74][75][76]

Hardware support edit

 
A Samsung Galaxy S8 plugged into a DeX docking station: The monitor is displaying the PowerPoint and Word Android applications.

USB-C devices edit

An increasing number of motherboards, notebooks, tablet computers, smartphones, hard disk drives, USB hubs and other devices released from 2014 onwards include the USB-C receptacles. However, the initial adoption of USB-C was limited by the high cost of USB-C cables[77] and the wide use of Micro-USB chargers.[citation needed]

Video output edit

Currently, DisplayPort is the most widely implemented alternate mode, and is used to provide video output on devices that do not have standard-size DisplayPort or HDMI ports, such as smartphones and laptops. All Chromebooks with a USB-C port are required to support DisplayPort alternate mode in Google's hardware requirements for manufacturers.[78] A USB-C multiport adapter converts the device's native video stream to DisplayPort/HDMI/VGA, allowing it to be displayed on an external display, such as a television set or computer monitor.

It is also used on USB-C docks designed to connect a device to a power source, external display, USB hub, and optional extra (such as a network port) with a single cable. These functions are sometimes implemented directly into the display instead of a separate dock,[79] meaning a user connects their device to the display via USB-C with no other connections required.

Compatibility issues edit

Power issues with cables edit

Many cables claiming to support USB-C are actually not compliant to the standard. Using these cables would have a potential consequence of damaging devices that they are connected to.[80][81][82] There are reported cases of laptops being destroyed due to the use of non-compliant cables.[83]

Some non-compliant cables with a USB-C connector on one end and a legacy USB-A plug or Micro-B receptacle (receptacles also being invalid on cables) on the other end incorrectly terminate the Configuration Channel (CC) with a 10 kΩ pull-up to VBUS instead of the specification mandated 56 kΩ pull-up,[84] causing a device connected to the cable to incorrectly determine the amount of power it is permitted to draw from the cable. Cables with this issue may not work properly with certain products, including Apple and Google products, and may even damage power sources such as chargers, hubs, or PC USB ports.[85][86]

When a defective USB-C cable or power source is used, the voltage seen by a USB-C device can be different from the voltage expected by the device. This may result in an overvoltage on the VBUS pin. Also due to the fine pitch of the USB-C receptacle, the VBUS pin from the cable may contact with the CC pin of the USB-C receptacle resulting in a short-to-VBUS electrical issue due to the fact that the VBUS pin is rated up to 20 V while the CC pins are rated up to 5.5 V. To overcome these issues, USB Type-C port protection must be used between a USB-C connector and a USB-C Power Delivery controller.[87]

Compatibility with audio adapters edit

The USB-C port can be used to connect wired accessories such as headphones.

There are two modes of audio output from devices: digital and analog. There are primarily two types of USB-C audio adapters: active, e.g. those with digital-to-analog converters (DACs), and passive, without electronics.[88][89]

When an active set of USB-C headphones or adapter is used, digital audio is sent through the USB-C port. The conversion by the DAC and amplifier is done inside of the headphones or adapter, instead of on the phone. The sound quality is dependent on the headphones/adapter's DAC. Active adapters with a built-in DAC have near-universal support for devices that output digital and analog audio, adhering to the Audio Device Class 3.0 and Audio Adapter Accessory Mode specifications.

Examples of such active adapters include external USB sound cards and DACs that do not require special drivers,[90] and USB-C to 3.5 mm headphone jack adapters by Apple, Google, Essential, Razer, HTC, and Samsung.[91]

On the other hand, when a passive adapter is used, digital-to-analog conversion is done on the host device and analog audio is sent through the USB-C port. The sound quality is dependent on the phone's onboard DAC. Passive adapters are only compatible with devices that output analog audio, adhering to the Audio Adapter Accessory Mode specification.

USB-C to 3.5 mm audio adapters and USB sound cards compatibility
Output mode Specification Devices USB-C adapters
Active Passive, without DACs
Digital audio Audio Device Class 3.0 (digital audio) Apple iPhone 15, Google Pixel 2, HTC U11, Essential Phone, Razer Phone,
Samsung Galaxy Note 10, Samsung Galaxy S10 Lite, Sharp Aquos S2, Asus ZenFone 3, Bluedio T4S, Lenovo Tab 4, GoPro, MacBook etc. 		No conversion Conversion unavailable
Analog audio
  • Audio Device Class 3.0 (digital audio)
  • Audio Adapter Accessory Mode (analog audio)
 Apple iPhone 15, Moto Z/Z Force, Moto Z2/Z2 Force/Z2 Play, Moto Z3/Z3 Play, Sony Xperia XZ2, Huawei Mate 10 Pro, Huawei P20/P20 Pro, Honor Magic2, LeEco,
Xiaomi phones, OnePlus 6T, OnePlus 7/7 Pro/7T/7T Pro,
Oppo Find X/Oppo R17/R17 Pro, ZTE Nubia Z17/Z18 etc. 		Conversion by adapter Pass-through

Compatibility with other fast-charging technology edit

In 2016, Benson Leung, an engineer at Google, pointed out that Quick Charge 2.0 and 3.0 technologies developed by Qualcomm are not compatible with the USB-C standard.[92] Qualcomm responded that it is possible to make fast-charge solutions fit the voltage demands of USB-C and that there are no reports of problems; however, it did not address the standard compliance issue at that time.[93] Later in the year, Qualcomm released Quick Charge 4, which it claimed was – as an advancement over previous generations – "USB Type-C and USB PD compliant".[94]

Regulations for compatibility edit

Further information: Radio Equipment Directive (2022)

In 2021, the European Commission proposed the use of USB-C as a universal charger.[95][96][97] On 4 October 2022, the European Parliament voted in favor of the new law, Radio Equipment Directive 2022/2380, with 602 votes in favor, 13 against and 8 abstentions.[98] The regulation requires that all new mobile phones, tablets, cameras, headphones, headsets, handheld video game consoles, portable speakers, e-readers, keyboards, mice, portable navigation systems, and earbuds sold in the European Union and supporting wired charging, would have to be equipped with a USB-C port and charge with a standard USB-C to USB-C cable by the end of 2024. Additionally, if these devices support fast charging, they must support USB Power Delivery. These regulations will extend to laptops by early 2026.[99] To comply with these regulations, Apple Inc. replaced its proprietary Lightning connector with USB-C beginning with the iPhone 15 and AirPods Pro second generation, released in 2023.[100]

See also edit

References edit

  1. ^ Universal Serial Bus Type-C Cable and Connector Specification Revision 1.3 (14 July 2017), Revision History, page 14.
  2. ^ Weintaub, Seth (2015). "Did Apple invent USB Type-C? Maybe a little bit".{{cite news}}: CS1 maint: url-status (link)
  3. ^ "Universal Serial Bus Type-C Cable and Connector Specification" (PDF). USB 3.0 Promoter Group. 2014.
  4. ^ "IEC Formally Adopts USB Type-C, USB Power Delivery and USB 3.1 Specifications" (Press release). 2016-07-13. from the original on 2021-01-30. Retrieved 2022-09-10.
  5. ^ "USB Type-C Cable and Connector : Language Usage Guidelines from USB-IF" (PDF). Usb.org. (PDF) from the original on 2018-11-05. Retrieved 2018-12-15.
  6. ^ Hruska, Joel (2015-03-13). "USB-C vs. USB 3.1: What's the difference?". ExtremeTech. from the original on 2015-04-11. Retrieved 2015-04-09.
  7. ^ a b c d e (PDF). usb.org. USB-IF. 2016-10-20. Archived from the original (PDF) on 2016-12-20.
  8. ^ "Universal Serial Bus Type-C Cable and Connector Specification" (PDF). August 2019. p. 30. Retrieved 2023-12-23.
  9. ^ Ngo, Dong. "USB Type-C: One cable to connect them all". CNET. from the original on 2017-05-11. Retrieved 2015-06-18.
  10. ^ a b Howse, Brett (2014-08-12). "USB Type-C Connector Specifications Finalized". from the original on 2014-12-28. Retrieved 2014-12-28.
  11. ^ "USB Type-C Cable and Connector Specification". USB Implementers Forum, Inc. from the original on 2018-11-03. Retrieved 2019-12-19.
  12. ^ Universal Serial Bus Type-C Cable and Connector Specification Revision 1.2 (25 March 2016), table 3–1, page 37.
  13. ^ (PDF). 2014-08-12. Archived from the original (PDF) on 2014-08-14.
  14. ^ a b (PDF). usb.org. USB-IF. 2016-10-20. Archived from the original (PDF) on 2017-08-16. Retrieved 2018-01-03.
  15. ^ (PDF). usb.org. USB-IF. 2016-10-20. Archived from the original (PDF) on 2016-12-20.
  16. ^ "Transition existing products from USB 2.0 OTG to USB Type-C" (PDF). (PDF) from the original on 2017-10-24. Retrieved 2017-10-23.
  17. ^ a b "Universal Serial Bus Type-C Cable and Connector Specification, Release 2.2, October 2022". from the original on 2023-10-02. Retrieved 2023-10-04.
  18. ^ Universal Serial Bus Type-C Cable and Connector Specification Release 1.3 (14 July 2017), section A.1, page 213.
  19. ^ "USB Type-C Specification Release 1.1" (PDF). GitHub. 2015-07-13. (PDF) from the original on 2019-07-11. Retrieved 2018-11-03.
  20. ^ "USB Type-C Connectors and Cable Assemblies Compliance Document, v1.2 | USB-IF". usb.org. from the original on 2020-03-19. Retrieved 2019-05-02.
  21. ^ a b "USB Type-C Cable and Connector Specification Revision 1.4, March 29, 2019" (PDF). (PDF) from the original on 2020-03-20. Retrieved 2020-03-20.
  22. ^ "Universal Serial Bus Type-C Cable and Connector Specification, September 21, 2019" (PDF). (PDF) from the original on 2019-09-14. Retrieved 2019-09-21.
  23. ^ "USB Type-C Cable and Connector Specification Revision 2.1, May, 2021". from the original on 2021-05-27. Retrieved 2021-05-27.
  24. ^ "IEC 62680-1-3:2016 | IEC Webstore | energy, multimedia, cable, USB, LVDC". webstore.iec.ch. from the original on 2018-11-04. Retrieved 2018-11-03.
  25. ^ "IEC 62680-1-3:2017 | IEC Webstore | energy, multimedia, cable, USB, LVDC". webstore.iec.ch. from the original on 2018-11-04. Retrieved 2018-11-03.
  26. ^ "IEC 62680-1-3:2018 | IEC Webstore | energy, multimedia, cable, USB, LVDC". webstore.iec.ch. from the original on 2022-05-01. Retrieved 2018-11-03.
  27. ^ "USB Type-C Locking Connector Specification | USB-IF". www.usb.org. from the original on 2018-11-03. Retrieved 2018-11-03.
  28. ^ "USB Type-C Port Controller Interface Specification | USB-IF". www.usb.org. from the original on 2018-11-03. Retrieved 2018-11-03.
  29. ^ "IEC 62680-1-4:2018 | IEC Webstore". webstore.iec.ch. from the original on 2022-05-01. Retrieved 2018-11-03.
  30. ^ Shilov, Anton. "USB-IF Publishes Audio over USB Type-C Specifications". from the original on 2018-12-09. Retrieved 2018-11-03.
  31. ^ Universal Serial Bus Type-C Cable and Connector Specification Release 1.3 (14 July 2017), section 4.5.2, page 144.
  32. ^ Cunningham, Andrew (2015-01-09). "USB 3.1 and Type-C: The only stuff at CES that everyone is going to use | Ars Technica UK". ArsTechnica.co.uk. from the original on 2015-06-18. Retrieved 2015-06-18.
  33. ^ a b c "Thunderbolt 3 – The USB-C That Does It All | Thunderbolt Technology Community". Thunderbolttechnology.net. from the original on 2015-09-05. Retrieved 2015-06-18.
  34. ^ "One port to rule them all: Thunderbolt 3 and USB Type-C join forces". from the original on 2015-06-02. Retrieved 2015-06-02.
  35. ^ "Thunderbolt 3 is twice as fast and uses reversible USB-C". 2015-06-02. from the original on 2015-06-03. Retrieved 2015-06-02.
  36. ^ a b Anthony, Sebastian (2015-06-02). "Thunderbolt 3 embraces USB Type-C connector, doubles bandwidth to 40Gbps". Ars Technica UK. from the original on 2015-06-03. Retrieved 2015-06-02.
  37. ^ a b "VESA Brings DisplayPort to New USB Type-C Connector". DisplayPort. 2014-09-22. from the original on 2015-10-05. Retrieved 2015-06-18.
  38. ^ a b c (PDF). usb.org. USB-IF. 2016-10-20. Archived from the original (PDF) on 2016-12-20.
  39. ^ "VESA Releases Updated DisplayPort Alt Mode Spec to Bring DisplayPort 2.0 Performance to USB4 and New USB Type-C Devices". VESA - Interface Standards for The Display Industry. 2020-04-29. from the original on 2021-11-23. Retrieved 2020-10-01.
  40. ^ "MHL – Expand Your World". MHLTech.org. from the original on 2015-10-02. Retrieved 2015-06-18.
  41. ^ "MHL Alternate Mode reference design for superMHL over USB Type-C". AnandTech.com. 2016-03-15. from the original on 2017-06-04. Retrieved 2015-06-18.
  42. ^ "MHL Releases Alternate Mode for New USB Type-C Connector". MHLTech.org. 2014-11-17. from the original on 2014-11-29. Retrieved 2015-06-18.
  43. ^ "MHL Alternate Mode over USB Type-C to support superMHL". www.mhltech.org. 2015-01-06. from the original on 2016-11-15. Retrieved 2016-11-15.
  44. ^ (PDF). usb.org. MHL, LLC. 2015-11-18. Archived from the original (PDF) on 2016-09-14.
  45. ^ "HDMI Press Release: HDMI Releases Alternate Mode for USB Type-C Connector". hdmi.org. from the original on 2018-12-24. Retrieved 2016-09-10.
  46. ^ a b (PDF). usb.org. HDMI LLC. 2016-10-20. Archived from the original (PDF) on 2017-02-18.
  47. ^ "HDMI Alt Mode for USB Type-C Announced". anandtech.com. from the original on 2016-09-15. Retrieved 2016-09-10.
  48. ^ "A new standard will allow your USB-C devices to connect to HDMI". neowin.net. from the original on 2016-09-24. Retrieved 2016-09-10.
  49. ^ "HDMI Alt Mode for USB Type-C Connector". hdmi.org. from the original on 2016-09-19. Retrieved 2016-09-10.
  50. ^ "New Open Industry Standard Introduced for Connecting Next-Generation VR Headsets to PCs, Other Devices". GlobeNewswire News Room (Press release). 2018-07-17. from the original on 2019-02-20. Retrieved 2019-03-12.
  51. ^ Smith, Ryan (2018-07-17). "VirtualLink USB-C Alt Mode Announced: Standardized Connector for VR Headsets". AnandTech. from the original on 2018-08-21. Retrieved 2018-08-21.
  52. ^ "[802.3_DIALOG] USB-C Ethernet Alternate Mode". ieee. 2015-03-26. from the original on 2016-10-03. Retrieved 2015-11-06.
  53. ^ "Thunderbolt - the USB-C that does it all". from the original on 2022-09-10. Retrieved 2021-01-17.
  54. ^ "TECHNOLOGY BRIEF Thunderbolt 3" (PDF). 2018-09-21. (PDF) from the original on 2018-12-24. Retrieved 2018-09-20.
  55. ^ "Node Pro". 2018-09-21. from the original on 2018-09-21. Retrieved 2018-09-20.
  56. ^ "VESA RELEASES UPDATED DISPLAYPORT ALT MODE SPEC TO BRING DISPLAYPORT 2.0 PERFORMANCE TO USB4 AND NEW USB TYPE-C DEVICES". Vesa. 2020-04-29. from the original on 2021-11-23. Retrieved 2021-08-09.
  57. ^ (PDF). usb.org. USB-IF. 2016-03-11. Archived from the original (PDF) on 2016-12-20.
  58. ^ "CalDigit USB-C Cable". 2018-09-21. from the original on 2018-09-21. Retrieved 2018-09-21.
  59. ^ "VESA Brings DisplayPort to New USB Type-C Connector". www.vesa.org. from the original on 2017-02-02. Retrieved 2016-12-11.
  60. ^ "Termination Resistors Required for the USB Type-C Connector – KBA97180". 2015-04-17. from the original on 2019-07-19. Retrieved 2019-07-19.
  61. ^ "USB Charger (USB Power Delivery) | USB-IF".
  62. ^ Universal Serial Bus Type-C Cable and Connector Specification Revision 1.3 (14 July 2017), section 2.4, page 26.
  63. ^ Universal Serial Bus Type-C Cable and Connector Specification Revision 1.3 (14 July 2017), section 5.1.2, page 203.
  64. ^ Universal Serial Bus Type-C Cable and Connector Specification Revision 1.3 (14 July 2017), section A, page 213.
  65. ^ "Android – Marshmallow". from the original on 2019-06-09. Retrieved 2015-10-12.
  66. ^ "Charge your Chromebook Pixel (2015)". from the original on 2019-07-11. Retrieved 2015-10-31.
  67. ^ "FreeBSD 8.2 Release Notes". www.freebsd.org. 2011-04-22. from the original on 2018-02-17. Retrieved 2018-02-05.
  68. ^ "NetBSD 7.2 Released". from the original on 2019-01-15. Retrieved 2019-01-14.
  69. ^ "OpenBSD 5.7". from the original on 2018-09-27. Retrieved 2019-06-27.
  70. ^ "Using the USB-C port and adapters on your MacBook (Retina, 12-inch, Early 2015) - Apple Support". Support.Apple.com. 2015-05-28. from the original on 2015-09-19. Retrieved 2015-06-18.
  71. ^ Microsoft. "Update for USB Type-C billboard support and Kingston thumb drive is enumerated incorrectly in Windows". from the original on 2015-12-10. Retrieved 2015-12-08.
  72. ^ Microsoft. "Windows support for USB Type-C connectors". Microsoft MSDN. from the original on 2017-06-24. Retrieved 2015-09-30.
  73. ^ "USB Dual Role Driver Stack Architecture - Windows drivers". docs.microsoft.com. from the original on 2018-11-01. Retrieved 2019-06-21.
  74. ^ Shilov, Anton. "USB-C Authentication Tech to Restrict Usage of Uncertified USB-C Accessories and Cables". AnandTech. Retrieved 2022-06-12.
  75. ^ Hollister, Sean (2022-06-06). "Apple will make USB-C accessories ask for your permission to pass data". The Verge. Retrieved 2022-06-12.
  76. ^ Li, Abner (2019-01-02). "USB-C Authentication Program could let OEMs clampdown on 'non-compliant' USB chargers". 9to5Google. Retrieved 2022-06-12.
  77. ^ Burke, Steve (2019-03-25). "Why USB 3.1 Type-C Isn't on More Cases & Cable Factory Tour in Dongguan, China". Gamers Nexus. from the original on 2019-06-26. Retrieved 2019-06-26.
  78. ^ "Are all USB-C ports for both charging and data?". 2019-09-15. from the original on 2022-09-10. Retrieved 2022-05-07.
  79. ^ "DisplayPort over USB-C". DisplayPort. from the original on 2019-11-27. Retrieved 2019-10-28.
  80. ^ Mills, Chris (2015-11-16). "A Google Engineer Is Publicly Shaming Crappy USB-C Cables". from the original on 2017-10-24. Retrieved 2017-10-23.
  81. ^ Opam, Kwame (2015-11-05). "A Google Engineer is Testing USB Type-C Cables So You Don't Have To". The Verge. from the original on 2017-10-24. Retrieved 2017-10-23.
  82. ^ "Be careful about which USB-C cables you buy off the Internet". TechnoBuffalo. 2015-11-16. from the original on 2019-12-16. Retrieved 2019-12-16.
  83. ^ Bohn, Dieter (2016-02-04). "Laptops are getting destroyed by cheap USB-C cables". The Verge. from the original on 2017-10-24. Retrieved 2017-10-23.
  84. ^ Universal Serial Bus Type-C Cable and Connector Specification Revision 1.1 (3 April 2015), page 60, table 3–13, note 1.
  85. ^ Leswing, Kif (2015-11-05). "Google Engineer Reviews Defective USB Cables on Amazon - Fortune". Fortune. from the original on 2017-05-02. Retrieved 2015-11-08.
  86. ^ "In response to the Type-C cable discussions". OnePlus Community. from the original on 2019-12-16. Retrieved 2019-12-16.
  87. ^ "TCPP01-M12 Type-C Port Protection" (PDF). (PDF) from the original on 2019-12-03. Retrieved 2019-12-03.
  88. ^ "USB-C audio: Everything you need to know". Android Central. 2018-05-02. from the original on 2019-02-24. Retrieved 2019-02-24.
  89. ^ "Bring back the headphone jack: Why USB-C audio still doesn't work". PCWorld. 2018-09-10. from the original on 2019-03-02. Retrieved 2019-03-12.
  90. ^ T, Nick (2015-02-26). "Android 5.0 Lollipop supports USB DAC audio devices, we go ears-on". Phone Arena. from the original on 2019-02-25. Retrieved 2019-02-25.
  91. ^ Schoon, Ben (2018-11-01). "Hands-on: Apple's new USB-C headphone adapter is your cheapest option for analog audio on Pixel". from the original on 2019-02-25. Retrieved 2019-02-25.
  92. ^ "Google engineer warns USB-C, Qualcomm Quick Charge are incompatible - ExtremeTech". 2016-04-25. from the original on 2017-10-26. Retrieved 2017-10-23.
  93. ^ "Qualcomm says it's fine to fast-charge your phone over USB-C". Engadget. 2016-04-25. from the original on 2017-10-24. Retrieved 2017-10-23.
  94. ^ "Qualcomm Quick Charge 4: Five minutes of charging for five hours of battery life". Qualcomm. 2016-11-17. from the original on 2017-10-24. Retrieved 2017-10-23.
  95. ^ "Apple opposes EU plans to make common charger port for all devices". The Guardian. 2021-09-23. from the original on 2021-10-18. Retrieved 2021-10-19.
  96. ^ Peltier, Elian (2021-09-23). "In a setback for Apple, the European Union seeks a common charger for all phones". The New York Times. from the original on 2022-09-10. Retrieved 2021-10-19.
  97. ^ "One common charging solution for all". Internal Market, Industry, Entrepreneurship and SMEs - European Commission. 2016-07-05. from the original on 2021-10-19. Retrieved 2021-10-19.
  98. ^ Riley, Duncan (2022-10-04). "European Parliament votes to compel USB-C charging on all portable devices". SiliconANGLE. Retrieved 2022-10-06.
  99. ^ "Long-awaited common charger for mobile devices will be a reality in 2024". European Parliament News. European Parliament. 2022-10-04. Retrieved 2022-10-06.
  100. ^ Porter, Jon (2022-10-04). "When will the iPhone be forced to use USB-C?". The Verge. The Verge. Retrieved 2022-10-06.

External links edit

 
Wikimedia Commons has media related to USB-C.
  • The Universal Serial Bus Type-C Cable and Connector Specification is included in a set of USB documents which can be downloaded from USB.org.
  • Introduction to USB Type-C, by Andrew Rogers, Microchip Technology, 2015

April 13, 2024
type, connector, protocol, that, supersedes, previous, connectors, carry, audio, video, other, data, drive, multiple, displays, store, backup, external, drive, also, provide, receive, power, such, powering, laptop, mobile, phone, applied, only, technology, als. USB C or USB Type C is a 24 pin connector not a protocol that supersedes previous USB connectors and can carry audio video and other data e g to drive multiple displays or to store a backup to an external drive It can also provide and receive power such as powering a laptop or a mobile phone It is applied not only by USB technology but also by other protocols including Thunderbolt PCIe HDMI DisplayPort and others It is extensible to support future standards USB CPins of the USB C connectorTypeDigital audio video data power connectorProduction historyDesignerUSB Implementers ForumDesigned11 August 2014 published 1 SupersededAll earlier USB connectors Type A and B and its different sizes Standard Mini and Micro DisplayPortMini DisplayPortLightningGeneral specificationsPins24USB C plugUSB C SuperSpeed USB 5Gbps receptacle on an MSI laptopDesign for the USB C connector was initially developed in 2012 by Apple Inc and Intel 2 Type C Specification 1 0 was published by the USB Implementers Forum USB IF on August 11 2014 3 In July 2016 it was adopted by the IEC as IEC 62680 1 3 4 The USB Type C connector has 24 pins and is reversible 5 6 The designation C is to distinguish it from the various former USB connectors it replaced all termed either Type A or Type B Whereas earlier every USB cable had a host end A and a peripheral device end B USB C replaces both a USB C cable connects either way and for older equipment a legacy cable has a Type C plug at one end and either a Type A host or a Type B peripheral device plug at the other The designation C refers only to the connector s physical configuration or form factor not to be confused with the connector s specific capabilities such as Thunderbolt 3 DisplayPort 2 0 or USB 3 2 Gen 2x2 Based on the protocols supported by both devices host and peripheral device a USB C connection normally provides much higher signaling and therefore data rates than the superseded connectors A device with a Type C connector does not necessarily implement any USB transfer protocol USB Power Delivery or any of the Alternate Modes the Type C connector is common to several technologies while mandating only a few of them 7 USB 3 2 released in September 2017 fully replaced the USB 3 1 specification It preserves previously called USB 3 1 SuperSpeed and SuperSpeed data transfer modes and introduces two additional data transfer modes by newly applying two lane operations with signaling rates of 10 Gbit s SuperSpeed USB 10Gbps nominal data rate 1 212 GB s and 20 Gbit s SuperSpeed USB 20Gbps nominal data rate 2 422 GB s They are only applicable with Full Featured USB C Fabrics connectors and cables on both ends USB4 released in 2019 is the first USB transfer protocol standard that is only available exclusively via USB C Fabrics Contents 1 Ease of use 2 Overview 2 1 Name 2 2 Connectors 2 3 Cables 2 4 Hosts and peripheral devices 2 5 Non USB modes 2 5 1 Audio adapter accessory mode 2 5 2 Alternate modes 3 Specifications 3 1 USB Type C cable and connector specifications 3 1 1 Receptacles 3 1 2 Plugs 3 1 3 Cables 3 2 Related USB IF specifications 3 3 Alternate Mode partner specifications 4 USB C receptacle pin usage in different modes 4 1 USB 2 0 1 1 4 2 USB Power Delivery 4 3 USB 3 0 3 1 3 2 4 4 Alternate Modes 4 5 Debug Accessory Mode 4 6 Audio Adapter Accessory Mode 5 Software support 6 Authentication 7 Hardware support 7 1 USB C devices 7 1 1 Video output 7 2 Compatibility issues 7 2 1 Power issues with cables 7 2 2 Compatibility with audio adapters 7 2 3 Compatibility with other fast charging technology 7 2 4 Regulations for compatibility 8 See also 9 References 10 External linksEase of use editThe USB C standard simplifies usage by specifying cables having identical plugs on both ends which can be inserted without concern about orientation When connecting two devices the user can plug either end of the cable into either device The plugs are flat but will work if inserted right side up or upside down The USB C plugs have two fold rotational symmetry because a plug may be inserted into a receptacle in either of two orientations Electrically USB C plugs are not symmetric as can be seen in the tables of pin layouts Also the two ends of the USB C are electrically different as can be seen in the table of cable wiring The illusion of symmetry results from how devices respond to the cable Software makes the plugs and cables behave as though they are symmetric According to the specifications Determination of this host to device relationship is accomplished through a Configuration Channel CC that is connected through the cable 8 The USB C standard attempts to eliminate the need to have different cables for other communication technologies such as Thunderbolt PCIe HDMI DisplayPort and more USB C cables can contain circuit boards and processors giving them much more capability than simple circuit connections Overview editUSB C cables interconnect hosts and peripheral devices replacing various other electrical cables and connectors including all earlier legacy USB connectors HDMI connectors DisplayPort ports and 3 5 mm audio jacks 9 10 Name edit USB Type C and USB C are trademarks of the USB Implementers Forum 11 Connectors edit nbsp USB C port on MacBook Pro middle port The 24 pin double sided connector is slightly larger than the micro B connector with a USB C receptacle measuring 8 4 millimetres 0 33 in wide 2 6 millimetres 0 10 in high and 6 65 millimetres 0 262 in deep Cables edit USB 3 1 cables are considered full featured USB C cables They are electronically marked cables that contain a chip with an ID function based on the configuration channel and vendor defined messages VDM from the USB Power Delivery 2 0 specification Cable length should not exceed 2 metres 6 ft 7 in for Gen 1 and 1 metre 3 ft 3 in for Gen 2 12 The electronic ID chip provides information about product vendor cable connectors USB signaling protocol 2 0 Gen 1 Gen 2 passive active construction use of VCONN power available VBUS current latency RX TX directionality SOP controller mode and hardware firmware version 7 USB C cables that do not have shielded SuperSpeed pairs sideband use pins or additional wires for power lines can have increased cable length up to 4 metres 13 ft These USB C cables only support USB 2 0 up to 480 Mbit s and do not support Alternate Modes Active cables those with built in repeaters can support SuperSpeed USB 5Gbps USB 3 2 Gen 1x1 USB 3 1 Gen 1 USB 3 0 only over lengths up to 10 metres 33 ft All USB C cables must be able to carry a minimum of 3 A current at 5 V for 15 W but some can carry 5 A current at 20 V for 100 W 13 USB C to USB C cables supporting 5 A current must contain e marker chips also marketed as E Mark chips programmed to identify the cable and its current capabilities USB charging ports should be clearly marked with power capability 14 Full featured USB C cables that implement USB 3 1 Gen 2 can provide 10 Gbit s full duplex signalling rate They are marked with a SuperSpeed USB 10Gbps previously marketed as SuperSpeed logo There are also cables which can support only USB 2 0 with a nominal data rate of 480 Mbit s with maximal effective data rate of 40MB s The USB Implementers Forum certifies valid cables so they can be marked accordingly and users can distinguish them from non compliant products 15 Hosts and peripheral devices edit For any two pieces of equipment connecting over USB one is a host with a downstream facing port DFP and the other is a peripheral device with an upstream facing port UFP Some products such as mobile phones can take either role whichever is opposite that of the connected equipment Such equipment is said to have Dual Role Data DRD capability which was known as USB On The Go in the previous specification 16 With USB C when two such devices are connected the roles are first randomly assigned but a swap can be commanded from either end although there are optional path and role detection methods that would allow equipment to select a preference for a specific role Furthermore Dual Role equipment that implements USB Power Delivery may swap data and power roles independently using the Data Role Swap or Power Role Swap processes This allows for charge through hub or docking station applications such as a portable computer acting as a host to connect to peripherals but being powered by the dock or a computer being powered by a display through a single USB C cable 7 USB C devices may optionally provide or consume bus power currents of 1 5 A and 3 0 A at 5 V in addition to baseline bus power provision power sources can either advertise increased USB current through the configuration channel or implement the full USB Power Delivery specification using both the BMC coded configuration line and the legacy BFSK coded VBUS line 7 14 All older USB connectors all Type A and Type B are designated legacy Connecting legacy and modern USB C equipment requires either a legacy cable assembly a cable with any Type A or Type B plug on one end and a Type C plug on the other or in very specific cases a legacy adapter assembly An older device can connect to a modern USB C host by using a legacy cable with a Standard B Mini B or Micro B plug on the device end and a USB C plug on the other Similarly a modern device can connect to a legacy host by using a legacy cable with a USB C plug on the device end and a Standard A plug on the host end Legacy adapters with USB C receptacles are not defined or allowed by the specification because they can create many invalid and potentially unsafe cable combinations being any cable assembly with two A ends or two B ends However exactly two types of adapter with USB C plugs are defined one with a Standard A receptacle for connecting a legacy device such as a flash drive not a cable to a modern host and supporting up to USB 3 1 and one with a Micro B receptacle for connecting a modern device to a legacy host and supporting up to USB 2 0 17 Non USB modes edit Audio adapter accessory mode edit A device with a USB C port may support analog headsets through an audio adapter with a 3 5 mm jack providing three analog audio channels left and right output and microphone The audio adapter may optionally include a USB C charge through port to allow 500 mA device charging The engineering specification states that an analog headset shall not use a USB C plug instead of a 3 5 mm plug In other words headsets with a USB C plug should always support digital audio and optionally the accessory mode 18 Analog signals use the USB 2 0 differential pairs Dp and Dn for Right and Left and the two side band use pairs for Mic and GND The presence of the audio accessory is signaled through the configuration channel and VCONN Alternate modes edit See also USB C Alternate Mode partner specifications An Alternate Mode dedicates some of the physical wires in a USB C cable for direct device to host transmission using non USB data protocols such as DisplayPort or Thunderbolt The four high speed lanes two side band pins and for dock detachable device and permanent cable applications only five additional pins can be used for Alternate Mode transmission The modes are configured using vendor defined messages VDM through the configuration channel Specifications editUSB Type C cable and connector specifications edit The USB Type C specification 1 0 was published by the USB Implementers Forum USB IF and was finalized in August 2014 10 It defines requirements for cables and connectors Rev 1 1 was published 2015 04 03 19 Rev 1 2 was published 2016 03 25 20 Rev 1 3 was published 2017 07 14 21 Rev 1 4 was published 2019 03 29 21 Rev 2 0 was published 2019 08 29 22 Rev 2 1 was published 2021 05 25 USB PD Extended Power Range 48 V 5 A 240 W 23 Rev 2 2 was published 2022 10 18 primarily for enabling USB4 Version 2 0 80 Gbps over USB Type C connectors and cables 17 Rev 2 3 was published 2023 10 31 Adoption as IEC specification IEC 62680 1 3 2016 2016 08 17 edition 1 0 Universal serial bus interfaces for data and power Part 1 3 Universal Serial Bus interfaces Common components USB Type C cable and connector specification 24 IEC 62680 1 3 2017 2017 09 25 edition 2 0 Universal serial bus interfaces for data and power Part 1 3 Common components USB Type C Cable and Connector Specification 25 IEC 62680 1 3 2018 2018 05 24 edition 3 0 Universal serial bus interfaces for data and power Part 1 3 Common components USB Type C Cable and Connector Specification 26 Receptacles edit nbsp Type C receptacle pinout end on view The receptacle features four power and four ground pins two differential pairs connected together on devices for legacy USB 2 0 high speed data four shielded differential pairs for Enhanced SuperSpeed data two transmit and two receive pairs two Sideband Use SBU pins and two Configuration Channel CC pins Type C receptacle A pin layout Pin Name DescriptionA1 GND Ground returnA2 SSTXp1 TX1 SuperSpeed differential pair 1 transmit positiveA3 SSTXn1 TX1 SuperSpeed differential pair 1 transmit negativeA4 VBUS Bus powerA5 CC1 Configuration channelA6 D USB 2 0 differential pair position 1 positiveA7 D USB 2 0 differential pair position 1 negativeA8 SBU1 Sideband use SBU A9 VBUS Bus powerA10 SSRXn2 RX2 SuperSpeed differential pair 4 receive negativeA11 SSRXp2 RX2 SuperSpeed differential pair 4 receive positiveA12 GND Ground returnType C receptacle B pin layout Pin Name DescriptionB12 GND Ground returnB11 SSRXp1 RX1 SuperSpeed differential pair 2 receive positiveB10 SSRXn1 RX1 SuperSpeed differential pair 2 receive negativeB9 VBUS Bus powerB8 SBU2 Sideband use SBU B7 D USB 2 0 differential pair position 2 negative a B6 D USB 2 0 differential pair position 2 positive a B5 CC2 Configuration channelB4 VBUS Bus powerB3 SSTXn2 TX2 SuperSpeed differential pair 3 transmit negativeB2 SSTXp2 TX2 SuperSpeed differential pair 3 transmit positiveB1 GND Ground return a b There is only a single non SuperSpeed differential pair in the cable This pin is not connected in the plug cable Plugs edit nbsp Type C plug pinout end on view The plug has only one USB 2 0 high speed differential pair and one of the CC pins CC2 is replaced by VCONN to power optional electronics in the cable and the other is used to actually carry the Configuration Channel CC signals These signals are used to determine the orientation of the cable as well as to carry USB Power Delivery communications Cables edit Although plugs have 24 pins cables have only 18 wires In the following table the No column shows the wire number Full Featured USB 3 2 and 2 0 Type C cable wiring Plug 1 USB Type C USB Type C cable Plug 2 USB Type CPin Name Wire color No Name Description 2 0 a Pin NameShell Shield Braid Braid Shield Cable external braid nbsp Shell ShieldA1 B12 B1 A12 GND Tin plated 1 GND PWRrt1 Ground for power return nbsp A1 B12 B1 A12 GND16 GND PWRrt2 nbsp A4 B9 B4 A9 VBUS Red 2 PWR VBUS1 VBUS power nbsp A4 B9 B4 A9 VBUS17 PWR VBUS2 nbsp B5 VCONN Yellow 18 PWR VCONN VCONN power for powered cables b nbsp B5 VCONNA5 CC Blue 3 CC Configuration channel nbsp A5 CCA6 D Green 4 UTP Dp c Unshielded twisted pair positive nbsp A6 D A7 D White 5 UTP Dn c Unshielded twisted pair negative nbsp A7 D A8 SBU1 Red 14 SBU A Sideband use A nbsp B8 SBU2B8 SBU2 Black 15 SBU B Sideband use B nbsp A8 SBU1A2 SSTXp1 Yellow d 6 SDPp1 Shielded differential pair 1 positive nbsp B11 SSRXp1A3 SSTXn1 Brown d 7 SDPn1 Shielded differential pair 1 negative nbsp B10 SSRXn1B11 SSRXp1 Green d 8 SDPp2 Shielded differential pair 2 positive nbsp A2 SSTXp1B10 SSRXn1 Orange d 9 SDPn2 Shielded differential pair 2 negative nbsp A3 SSTXn1B2 SSTXp2 White d 10 SDPp3 Shielded differential pair 3 positive nbsp A11 SSRXp2B3 SSTXn2 Black d 11 SDPn3 Shielded differential pair 3 negative nbsp A10 SSRXn2A11 SSRXp2 Red d 12 SDPp4 Shielded differential pair 4 positive nbsp B2 SSTXp2A10 SSRXn2 Blue d 13 SDPn4 Shielded differential pair 4 negative nbsp B3 SSTXn2 USB 2 0 Type C cables do not include wires for SuperSpeed or sideband use VCONN must not traverse end to end through the cable Some isolation method must be used a b There is only a single differential pair for non SuperSpeed data in the cable which is connected to A6 and A7 Contacts B6 and B7 should not be present in the plug a b c d e f g h Wire colors for differential pairs are not mandated Related USB IF specifications edit USB Type C Locking Connector Specification The USB Type C Locking Connector Specification was published 2016 03 09 It defines the mechanical requirements for USB C plug connectors and the guidelines for the USB C receptacle mounting configuration to provide a standardized screw lock mechanism for USB C connectors and cables 27 USB Type C Port Controller Interface Specification The USB Type C Port Controller Interface Specification was published 2017 10 01 It defines a common interface from a USB C Port Manager to a simple USB C Port Controller 28 USB Type C Authentication Specification Adopted as IEC specification IEC 62680 1 4 2018 2018 04 10 Universal Serial Bus interfaces for data and power Part 1 4 Common components USB Type C Authentication Specification 29 USB 2 0 Billboard Device Class Specification USB 2 0 Billboard Device Class is defined to communicate the details of supported Alternate Modes to the computer host OS It provides user readable strings with product description and user support information Billboard messages can be used to identify incompatible connections made by users They optionally appear to negotiate multiple Alternate Modes and must appear when negotiation fails between the host source and device sink USB Audio Device Class 3 0 Specification USB Audio Device Class 3 0 defines powered digital audio headsets with a USB C plug 7 The standard supports the transfer of both digital and analog audio signals over the USB port 30 USB Power Delivery Specification Main article USB Power Delivery While it is not necessary for USB C compliant devices to implement USB Power Delivery for USB C DRP DRD Dual Role Power Data ports USB Power Delivery introduces commands for altering a port s power or data role after the roles have been established when a connection is made 31 USB 3 2 Specification USB 3 2 released in September 2017 replaces the USB 3 1 standard It preserves existing USB 3 1 SuperSpeed and SuperSpeed data modes and introduces two new SuperSpeed transfer modes over the USB C connector using two lane operation doubling the data rates to 10 and 20 Gbit s 1 and 2 4 GB s USB 3 2 is only supported by USB C making micro USB connectors obsolete USB4 Specification The USB4 specification released in 2019 is the first USB data transfer specification to exclusively use the Type C connector Alternate Mode partner specifications edit As of 2018 update five system defined Alternate Mode partner specifications exist Additionally vendors may support proprietary modes for use in dock solutions Alternate Modes are optional Type C features and devices are not required to support any specific Alternate Mode The USB Implementers Forum is working with its Alternate Mode partners to make sure that ports are properly labelled with respective logos 32 List of Alternate Mode partner specifications Logo Name Date Protocol Status nbsp Thunderbolt Alternate Mode Announced in June 2015 33 USB C is the native and only connector for Thunderbolt 3 and laterThunderbolt 3 also carries 4 PCI Express 3 0 DisplayPort 1 2 DisplayPort 1 4 USB 3 1 Gen 2 33 34 35 36 Thunderbolt 4 also carries 4 PCI Express 3 0 DisplayPort 2 0 USB4 Thunderbolt 5 also carries 4 PCI Express 4 0 DisplayPort 2 1 USB4 Current nbsp DisplayPort Alternate Mode Published in September 2014 DisplayPort 1 2 DisplayPort 1 4 37 38 DisplayPort 2 0 39 Current nbsp Mobile High Definition Link MHL Alternate Mode Announced in November 2014 40 MHL 1 0 2 0 3 0 and superMHL 1 0 41 42 43 44 Current nbsp HDMI Alternate Mode Announced in September 2016 45 HDMI 1 4b 46 47 48 49 Not being updatedVirtualLink Alternate Mode Announced in July 2018 50 VirtualLink 1 0 51 AbandonedOther protocols like Ethernet 52 have been proposed although Thunderbolt 3 and later are also capable of 10 Gigabit Ethernet networking 53 All Thunderbolt 3 controllers support both Thunderbolt Alternate Mode and DisplayPort Alternate Mode 54 Because Thunderbolt can encapsulate DisplayPort data every Thunderbolt controller can either output DisplayPort signals directly over DisplayPort Alternative Mode or encapsulated within Thunderbolt in Thunderbolt Alternate Mode Low cost peripherals mostly connect via DisplayPort Alternate Mode while some docking stations tunnel DisplayPort over Thunderbolt 55 DisplayPort Alternate Mode 2 0 DisplayPort 2 0 can run directly over USB C alongside USB4 DisplayPort 2 0 can support 8K resolution at 60 Hz with HDR10 color and can use up to 80 Gbps which is double the amount available to USB data 56 The USB SuperSpeed protocol is similar to DisplayPort and PCIe Thunderbolt in using packetized data transmitted over differential LVDS lanes with embedded clock using comparable bit rates so these Alternate Modes are easier to implement in the chipset 37 Alternate Mode hosts and sinks can be connected with either regular Full Featured Type C cables or with converter cables or adapters USB 3 1 Type C to Type C Full Featured cable DisplayPort Mobile High Definition Link MHL HDMI and Thunderbolt 20 Gbit s or 40 Gbit s with cable length up to 0 5 m citation needed Alternate Mode Type C ports can be interconnected with standard passive Full Featured USB Type C cables These cables are only marked with standard trident SuperSpeed USB logo for Gen 1 cables or the SuperSpeed USB 10 Gbit s logo for Gen 2 cables on both ends 57 Cable length should be 2 0 m or less for Gen 1 and 1 0 m or less for Gen 2 Thunderbolt Type C to Type C active cable Thunderbolt 3 40 Gbit s Alternate Mode with cables longer than 0 8 m requires active Type C cables that are certified and electronically marked for high speed Thunderbolt 3 transmission similarly to high power 5 A cables 33 36 These cables are marked with a Thunderbolt logo on both ends They do not support USB 3 backwards compatibility only USB 2 or Thunderbolt Cables can be marked for both Thunderbolt and 5 A power delivery at the same time 58 Active cables and adapters contain powered electronics to allow for longer cables or to perform protocol conversion The adapters for video Alternate Modes may allow conversion from native video stream to other video interface standards e g DisplayPort HDMI VGA or DVI Using Full Featured Type C cables for Alternate Mode connections provides some benefits Alternate Mode does not employ USB 2 0 lanes and the configuration channel lane so USB 2 0 and USB Power Delivery protocols are always available In addition DisplayPort and MHL Alternate Modes can transmit on one two or four SuperSpeed lanes so two of the remaining lanes may be used to simultaneously transmit USB 3 1 data 59 Alternate Mode protocol support matrix for Type C cables and adapters Mode USB 3 1 Type C cable a Adapter cable or adapter ConstructionUSB b DisplayPort Thunderbolt superMHL HDMI HDMI DVI D Component video3 1 1 2 1 4 20 Gbit s 40 Gbit s 1 4b 1 4b 2 0b Single link Dual link YPbPr VGA DVI A DisplayPort Yes Yes Does not appear No PassiveDoes not appear Optional Yes Yes Yes ActiveThunderbolt Yes c Yes c Yes Yes d Does not appear No PassiveDoes not appear Optional Optional Yes Yes Yes Yes ActiveMHL Yes Does not appear Yes Does not appear Yes No Yes No No PassiveDoes not appear Optional Does not appear Yes Does not appear Yes ActiveHDMI Does not appear Yes Yes No Yes No No PassiveOptional Does not appear Yes Active USB 2 0 and USB Power Delivery are available at all times in a Type C cable USB 3 1 can be transmitted simultaneously when the video signal bandwidth requires two or fewer lanes a b Is only available in Thunderbolt 3 DisplayPort mode Thunderbolt 3 40 Gbit s passive cables are only possible lt 0 8 m due to limitations of current cable technology USB C receptacle pin usage in different modes editThe diagrams below depict the pins of a USB C receptacle in different use cases USB 2 0 1 1 edit A simple USB 2 0 1 1 device mates using one pair of D D pins Hence the source host does not require any connection management circuitry but it lacks the same physical connector so therefore USB C is not backward compatible VBUS and GND provide 5 V up to 500 mA of current However to connect a USB 2 0 1 1 device to a USB C host use of Rd 60 on the CC pins is required as the source host will not supply VBUS until a connection is detected through the CC pins This means many USB A to USB C cables will only work in the A to C direction connecting to a USB C devices e g for charging as they do not include the termination resistors needed to work in the C to A direction from a USB C host Adapters or cables from USB C to a USB A receptacle usually do work as they include the required termination resistor GND TX1 TX1 VBUS CC1 D D SBU1 VBUS RX2 RX2 GNDGND RX1 RX1 VBUS SBU2 D D CC2 VBUS TX2 TX2 GNDUSB Power Delivery edit The USB Power Delivery specification uses one of CC1 or CC2 pins for power negotiation between source device and sink device up to 20 V at 5 A It is transparent to any data transmission mode and can therefore be used together with any of them as long as the CC pins are intact An extension to the specification has added 28V 36V and 48V to support up to 240W of power for laptops monitors hard disks and other peripherals 61 GND TX1 TX1 VBUS CC1 D D SBU1 VBUS RX2 RX2 GNDGND RX1 RX1 VBUS SBU2 D D CC2 VBUS TX2 TX2 GNDUSB 3 0 3 1 3 2 edit In the USB 3 0 3 1 3 2 mode two or four high speed links are used in TX RX pairs to provide 5 10 or 20 Gbit s only by USB 3 2 x2 two lane operations signalling rates respectively One of the CC pins is used to negotiate the mode VBUS and GND provide 5 V up to 900 mA in accordance with the USB 3 1 specification A specific USB C mode may also be entered where 5 V at nominal either 1 5 A or 3 A is provided 62 A third alternative is to establish a USB Power Delivery USB PD contract In single lane mode only the differential pairs closest to the CC pin are used for data transmission For dual lane data transfers all four differential pairs are in use The D D link for USB 2 0 1 1 is typically not used when USB 3 x connection is active but devices like hubs open simultaneous 2 0 and 3 x uplinks in order to allow operation of both types of devices connected to it Other devices may have the ability to fall back to 2 0 in case the 3 x connection fails GND TX1 TX1 VBUS CC1 D D SBU1 VBUS RX2 RX2 GNDGND RX1 RX1 VBUS SBU2 D D CC2 VBUS TX2 TX2 GNDAlternate Modes edit In Alternate Modes one of up to four high speed links are used in whatever direction is needed SBU1 SBU2 provide an additional lower speed link If two high speed links remain unused then a USB 3 0 3 1 link can be established concurrently to the Alternate Mode 38 One of the CC pins is used to perform all the negotiation An additional low band bidirectional channel other than SBU may share that CC pin as well 38 46 USB 2 0 is also available through D D pins In regard to power the devices are supposed to negotiate a Power Delivery contract before an Alternate Mode is entered 63 GND TX1 TX1 VBUS CC1 D D SBU1 VBUS RX2 RX2 GNDGND RX1 RX1 VBUS SBU2 D D CC2 VBUS TX2 TX2 GNDDebug Accessory Mode edit The external device test system DTS signals to the target system TS to enter debug accessory mode via CC1 and CC2 both being pulled down with an Rd resistor value or pulled up as Rp resistor value from the test plug Rp and Rd defined in Type C specification After entering debug accessory mode optional orientation detection via the CC1 and CC2 is done via setting CC1 as a pullup of Rd resistance and CC2 pulled to ground via Ra resistance from the test system Type C plug While optional orientation detection is required if USB Power Delivery communication is to remain functional In this mode all digital circuits are disconnected from the connector and the 14 bold pins can be used to expose debug related signals e g JTAG interface USB IF requires for certification that security and privacy consideration and precaution has been taken and that the user has actually requested that debug test mode be performed GND TX1 TX1 VBUS CC1 D D SBU1 VBUS RX2 RX2 GNDGND RX1 RX1 VBUS SBU2 D D CC2 VBUS TX2 TX2 GNDIf a reversible Type C cable is required but Power Delivery support is not the test plug will need to be arranged as below with CC1 and CC2 both being pulled down with an Rd resistor value or pulled up as Rp resistor value from the test plug GND TS1 TS2 VBUS CC1 TS6 TS7 TS5 VBUS TS4 TS3 GNDGND TS3 TS4 VBUS TS5 TS7 TS6 CC2 VBUS TS2 TS1 GNDThis mirroring of test signals will only provide 7 test signals for debug usage instead of 14 but with the benefit of minimizing extra parts count for orientation detection Audio Adapter Accessory Mode edit In this mode all digital circuits are disconnected from the connector and certain pins become reassigned for analog outputs or inputs The mode if supported is entered when both CC pins are shorted to GND D and D become audio output left L and right R respectively The SBU pins become a microphone pin MIC and the analog ground AGND the latter being a return path for both outputs and the microphone Nevertheless the MIC and AGND pins must have automatic swap capability for two reasons firstly the USB C plug may be inserted either side secondly there is no agreement which TRRS rings shall be GND and MIC so devices equipped with a headphone jack with microphone input must be able to perform this swap anyway 64 This mode also allows concurrent charging of a device exposing the analog audio interface through VBUS and GND however only at 5 V and 500 mA as CC pins are unavailable for any negotiation GND TX1 TX1 VBUS CC1 R L MIC VBUS RX2 RX2 GNDGND RX1 RX1 VBUS AGND L R CC2 VBUS TX2 TX2 GNDPlug insertions detection is performed by the TRRS plug s physical plug detection switch On plug insertions this will pull down both CC and VCONN in the plug CC1 and CC2 in the receptacle This resistance must be less than 800 ohms which is the minimum Ra resistance specified in the USB Type C specification This is essentially a direct connection to USB digital ground TRRS rings wiring to Type C plug Figure A 2 of USB Type C Cable and Connector Specification Release 1 3 TRRS socket Analog audio signal USB Type C plugTip L D Ring 1 R D Ring 2 Microphone ground SBU1 or SBU2Sleeve Microphone ground SBU2 or SBU1DETECT1 Plug presence detection switch CC VCONNDETECT2 Plug presence detection switch GNDSoftware support editAndroid from version 6 0 Marshmallow onwards works with USB 3 1 and USB C 65 ChromeOS starting with the Chromebook Pixel 2015 supports USB 3 1 USB C Alternate Modes Power Delivery and USB Dual Role support 66 FreeBSD released the Extensible Host Controller Interface supporting USB 3 0 with release 8 2 67 iOS from version 12 1 iPad Pro 3rd generation or later iPad Air 4th generation or later iPad Mini 6th generation iPad 10th generation iPhone 15 onwards works with USB C NetBSD began supporting USB 3 0 with release 7 2 68 Linux has supported USB 3 0 since kernel version 2 6 31 and USB version 3 1 since kernel version 4 6 OpenBSD began supporting USB 3 0 in version 5 7 69 OS X Yosemite macOS version 10 10 2 starting with the MacBook Retina early 2015 supports USB 3 1 USB C Alternate Modes and Power Delivery 70 Windows 8 1 added USB C and billboard support in an update 71 Windows 10 and Windows 10 Mobile support USB 3 1 USB C alternate modes billboard device class Power Delivery and USB Dual Role 72 73 Authentication editUSB Type C Authentication is an extension to the USB C protocol which can add security to the protocol 74 75 76 Hardware support edit nbsp A Samsung Galaxy S8 plugged into a DeX docking station The monitor is displaying the PowerPoint and Word Android applications USB C devices edit An increasing number of motherboards notebooks tablet computers smartphones hard disk drives USB hubs and other devices released from 2014 onwards include the USB C receptacles However the initial adoption of USB C was limited by the high cost of USB C cables 77 and the wide use of Micro USB chargers citation needed Video output edit Currently DisplayPort is the most widely implemented alternate mode and is used to provide video output on devices that do not have standard size DisplayPort or HDMI ports such as smartphones and laptops All Chromebooks with a USB C port are required to support DisplayPort alternate mode in Google s hardware requirements for manufacturers 78 A USB C multiport adapter converts the device s native video stream to DisplayPort HDMI VGA allowing it to be displayed on an external display such as a television set or computer monitor It is also used on USB C docks designed to connect a device to a power source external display USB hub and optional extra such as a network port with a single cable These functions are sometimes implemented directly into the display instead of a separate dock 79 meaning a user connects their device to the display via USB C with no other connections required Compatibility issues edit Power issues with cables edit Many cables claiming to support USB C are actually not compliant to the standard Using these cables would have a potential consequence of damaging devices that they are connected to 80 81 82 There are reported cases of laptops being destroyed due to the use of non compliant cables 83 Some non compliant cables with a USB C connector on one end and a legacy USB A plug or Micro B receptacle receptacles also being invalid on cables on the other end incorrectly terminate the Configuration Channel CC with a 10 kW pull up to VBUS instead of the specification mandated 56 kW pull up 84 causing a device connected to the cable to incorrectly determine the amount of power it is permitted to draw from the cable Cables with this issue may not work properly with certain products including Apple and Google products and may even damage power sources such as chargers hubs or PC USB ports 85 86 When a defective USB C cable or power source is used the voltage seen by a USB C device can be different from the voltage expected by the device This may result in an overvoltage on the VBUS pin Also due to the fine pitch of the USB C receptacle the VBUS pin from the cable may contact with the CC pin of the USB C receptacle resulting in a short to VBUS electrical issue due to the fact that the VBUS pin is rated up to 20 V while the CC pins are rated up to 5 5 V To overcome these issues USB Type C port protection must be used between a USB C connector and a USB C Power Delivery controller 87 Compatibility with audio adapters edit The USB C port can be used to connect wired accessories such as headphones There are two modes of audio output from devices digital and analog There are primarily two types of USB C audio adapters active e g those with digital to analog converters DACs and passive without electronics 88 89 When an active set of USB C headphones or adapter is used digital audio is sent through the USB C port The conversion by the DAC and amplifier is done inside of the headphones or adapter instead of on the phone The sound quality is dependent on the headphones adapter s DAC Active adapters with a built in DAC have near universal support for devices that output digital and analog audio adhering to the Audio Device Class 3 0 and Audio Adapter Accessory Mode specifications Examples of such active adapters include external USB sound cards and DACs that do not require special drivers 90 and USB C to 3 5 mm headphone jack adapters by Apple Google Essential Razer HTC and Samsung 91 On the other hand when a passive adapter is used digital to analog conversion is done on the host device and analog audio is sent through the USB C port The sound quality is dependent on the phone s onboard DAC Passive adapters are only compatible with devices that output analog audio adhering to the Audio Adapter Accessory Mode specification USB C to 3 5 mm audio adapters and USB sound cards compatibility Output mode Specification Devices USB C adaptersActive Passive without DACsDigital audio Audio Device Class 3 0 digital audio Apple iPhone 15 Google Pixel 2 HTC U11 Essential Phone Razer Phone Samsung Galaxy Note 10 Samsung Galaxy S10 Lite Sharp Aquos S2 Asus ZenFone 3 Bluedio T4S Lenovo Tab 4 GoPro MacBook etc No conversion Conversion unavailableAnalog audio Audio Device Class 3 0 digital audio Audio Adapter Accessory Mode analog audio Apple iPhone 15 Moto Z Z Force Moto Z2 Z2 Force Z2 Play Moto Z3 Z3 Play Sony Xperia XZ2 Huawei Mate 10 Pro Huawei P20 P20 Pro Honor Magic2 LeEco Xiaomi phones OnePlus 6T OnePlus 7 7 Pro 7T 7T Pro Oppo Find X Oppo R17 R17 Pro ZTE Nubia Z17 Z18 etc Conversion by adapter Pass throughCompatibility with other fast charging technology edit In 2016 Benson Leung an engineer at Google pointed out that Quick Charge 2 0 and 3 0 technologies developed by Qualcomm are not compatible with the USB C standard 92 Qualcomm responded that it is possible to make fast charge solutions fit the voltage demands of USB C and that there are no reports of problems however it did not address the standard compliance issue at that time 93 Later in the year Qualcomm released Quick Charge 4 which it claimed was as an advancement over previous generations USB Type C and USB PD compliant 94 Regulations for compatibility edit Further information Radio Equipment Directive 2022 In 2021 the European Commission proposed the use of USB C as a universal charger 95 96 97 On 4 October 2022 the European Parliament voted in favor of the new law Radio Equipment Directive 2022 2380 with 602 votes in favor 13 against and 8 abstentions 98 The regulation requires that all new mobile phones tablets cameras headphones headsets handheld video game consoles portable speakers e readers keyboards mice portable navigation systems and earbuds sold in the European Union and supporting wired charging would have to be equipped with a USB C port and charge with a standard USB C to USB C cable by the end of 2024 Additionally if these devices support fast charging they must support USB Power Delivery These regulations will extend to laptops by early 2026 99 To comply with these regulations Apple Inc replaced its proprietary Lightning connector with USB C beginning with the iPhone 15 and AirPods Pro second generation released in 2023 100 See also editUSB hardware Host and device interface receptacles Thunderbolt interface HDMI Version 2 1References edit Universal Serial Bus Type C Cable and Connector Specification Revision 1 3 14 July 2017 Revision History page 14 Weintaub Seth 2015 Did Apple invent USB Type C Maybe a little bit a href Template Cite news html title Template Cite news cite news a CS1 maint url status link Universal Serial Bus Type C Cable and Connector Specification PDF USB 3 0 Promoter Group 2014 IEC Formally Adopts USB Type C USB Power Delivery and USB 3 1 Specifications Press release 2016 07 13 Archived from the original on 2021 01 30 Retrieved 2022 09 10 USB Type C Cable and Connector Language Usage Guidelines from USB IF PDF Usb org Archived PDF from the original on 2018 11 05 Retrieved 2018 12 15 Hruska Joel 2015 03 13 USB C vs USB 3 1 What s the difference ExtremeTech Archived from the original on 2015 04 11 Retrieved 2015 04 09 a b c d e USB Type C Overview PDF usb org USB IF 2016 10 20 Archived from the original PDF on 2016 12 20 Universal Serial Bus Type C Cable and Connector Specification PDF August 2019 p 30 Retrieved 2023 12 23 Ngo Dong USB Type C One cable to connect them all CNET Archived from the original on 2017 05 11 Retrieved 2015 06 18 a b Howse Brett 2014 08 12 USB Type C Connector Specifications Finalized Archived from the original on 2014 12 28 Retrieved 2014 12 28 USB Type C Cable and Connector Specification USB Implementers Forum Inc Archived from the original on 2018 11 03 Retrieved 2019 12 19 Universal Serial Bus Type C Cable and Connector Specification Revision 1 2 25 March 2016 table 3 1 page 37 USB 3 0 Promoter Group Announces USB Type C Connector Ready for Production PDF 2014 08 12 Archived from the original PDF on 2014 08 14 a b USB Power Delivery PDF usb org USB IF 2016 10 20 Archived from the original PDF on 2017 08 16 Retrieved 2018 01 03 USB Compliance and Certification PDF usb org USB IF 2016 10 20 Archived from the original PDF on 2016 12 20 Transition existing products from USB 2 0 OTG to USB Type C PDF Archived PDF from the original on 2017 10 24 Retrieved 2017 10 23 a b Universal Serial Bus Type C Cable and Connector Specification Release 2 2 October 2022 Archived from the original on 2023 10 02 Retrieved 2023 10 04 Universal Serial Bus Type C Cable and Connector Specification Release 1 3 14 July 2017 section A 1 page 213 USB Type C Specification Release 1 1 PDF GitHub 2015 07 13 Archived PDF from the original on 2019 07 11 Retrieved 2018 11 03 USB Type C Connectors and Cable Assemblies Compliance Document v1 2 USB IF usb org Archived from the original on 2020 03 19 Retrieved 2019 05 02 a b USB Type C Cable and Connector Specification Revision 1 4 March 29 2019 PDF Archived PDF from the original on 2020 03 20 Retrieved 2020 03 20 Universal Serial Bus Type C Cable and Connector Specification September 21 2019 PDF Archived PDF from the original on 2019 09 14 Retrieved 2019 09 21 USB Type C Cable and Connector Specification Revision 2 1 May 2021 Archived from the original on 2021 05 27 Retrieved 2021 05 27 IEC 62680 1 3 2016 IEC Webstore energy multimedia cable USB LVDC webstore iec ch Archived from the original on 2018 11 04 Retrieved 2018 11 03 IEC 62680 1 3 2017 IEC Webstore energy multimedia cable USB LVDC webstore iec ch Archived from the original on 2018 11 04 Retrieved 2018 11 03 IEC 62680 1 3 2018 IEC Webstore energy multimedia cable USB LVDC webstore iec ch Archived from the original on 2022 05 01 Retrieved 2018 11 03 USB Type C Locking Connector Specification USB IF www usb org Archived from the original on 2018 11 03 Retrieved 2018 11 03 USB Type C Port Controller Interface Specification USB IF www usb org Archived from the original on 2018 11 03 Retrieved 2018 11 03 IEC 62680 1 4 2018 IEC Webstore webstore iec ch Archived from the original on 2022 05 01 Retrieved 2018 11 03 Shilov Anton USB IF Publishes Audio over USB Type C Specifications Archived from the original on 2018 12 09 Retrieved 2018 11 03 Universal Serial Bus Type C Cable and Connector Specification Release 1 3 14 July 2017 section 4 5 2 page 144 Cunningham Andrew 2015 01 09 USB 3 1 and Type C The only stuff at CES that everyone is going to use Ars Technica UK ArsTechnica co uk Archived from the original on 2015 06 18 Retrieved 2015 06 18 a b c Thunderbolt 3 The USB C That Does It All Thunderbolt Technology Community Thunderbolttechnology net Archived from the original on 2015 09 05 Retrieved 2015 06 18 One port to rule them all Thunderbolt 3 and USB Type C join forces Archived from the original on 2015 06 02 Retrieved 2015 06 02 Thunderbolt 3 is twice as fast and uses reversible USB C 2015 06 02 Archived from the original on 2015 06 03 Retrieved 2015 06 02 a b Anthony Sebastian 2015 06 02 Thunderbolt 3 embraces USB Type C connector doubles bandwidth to 40Gbps Ars Technica UK Archived from the original on 2015 06 03 Retrieved 2015 06 02 a b VESA Brings DisplayPort to New USB Type C Connector DisplayPort 2014 09 22 Archived from the original on 2015 10 05 Retrieved 2015 06 18 a b c DisplayPort Alternate Mode on USB C Technical Overview PDF usb org USB IF 2016 10 20 Archived from the original PDF on 2016 12 20 VESA Releases Updated DisplayPort Alt Mode Spec to Bring DisplayPort 2 0 Performance to USB4 and New USB Type C Devices VESA Interface Standards for The Display Industry 2020 04 29 Archived from the original on 2021 11 23 Retrieved 2020 10 01 MHL Expand Your World MHLTech org Archived from the original on 2015 10 02 Retrieved 2015 06 18 MHL Alternate Mode reference design for superMHL over USB Type C AnandTech com 2016 03 15 Archived from the original on 2017 06 04 Retrieved 2015 06 18 MHL Releases Alternate Mode for New USB Type C Connector MHLTech org 2014 11 17 Archived from the original on 2014 11 29 Retrieved 2015 06 18 MHL Alternate Mode over USB Type C to support superMHL www mhltech org 2015 01 06 Archived from the original on 2016 11 15 Retrieved 2016 11 15 MHL Alt Mode Optimizing Consumer Video Transmission PDF usb org MHL LLC 2015 11 18 Archived from the original PDF on 2016 09 14 HDMI Press Release HDMI Releases Alternate Mode for USB Type C Connector hdmi org Archived from the original on 2018 12 24 Retrieved 2016 09 10 a b HDMI LLC HDMI Over USB Type C PDF usb org HDMI LLC 2016 10 20 Archived from the original PDF on 2017 02 18 HDMI Alt Mode for USB Type C Announced anandtech com Archived from the original on 2016 09 15 Retrieved 2016 09 10 A new standard will allow your USB C devices to connect to HDMI neowin net Archived from the original on 2016 09 24 Retrieved 2016 09 10 HDMI Alt Mode for USB Type C Connector hdmi org Archived from the original on 2016 09 19 Retrieved 2016 09 10 New Open Industry Standard Introduced for Connecting Next Generation VR Headsets to PCs Other Devices GlobeNewswire News Room Press release 2018 07 17 Archived from the original on 2019 02 20 Retrieved 2019 03 12 Smith Ryan 2018 07 17 VirtualLink USB C Alt Mode Announced Standardized Connector for VR Headsets AnandTech Archived from the original on 2018 08 21 Retrieved 2018 08 21 802 3 DIALOG USB C Ethernet Alternate Mode ieee 2015 03 26 Archived from the original on 2016 10 03 Retrieved 2015 11 06 Thunderbolt the USB C that does it all Archived from the original on 2022 09 10 Retrieved 2021 01 17 TECHNOLOGY BRIEF Thunderbolt 3 PDF 2018 09 21 Archived PDF from the original on 2018 12 24 Retrieved 2018 09 20 Node Pro 2018 09 21 Archived from the original on 2018 09 21 Retrieved 2018 09 20 VESA RELEASES UPDATED DISPLAYPORT ALT MODE SPEC TO BRING DISPLAYPORT 2 0 PERFORMANCE TO USB4 AND NEW USB TYPE C DEVICES Vesa 2020 04 29 Archived from the original on 2021 11 23 Retrieved 2021 08 09 USB Logo Usage Guidelines PDF usb org USB IF 2016 03 11 Archived from the original PDF on 2016 12 20 CalDigit USB C Cable 2018 09 21 Archived from the original on 2018 09 21 Retrieved 2018 09 21 VESA Brings DisplayPort to New USB Type C Connector www vesa org Archived from the original on 2017 02 02 Retrieved 2016 12 11 Termination Resistors Required for the USB Type C Connector KBA97180 2015 04 17 Archived from the original on 2019 07 19 Retrieved 2019 07 19 USB Charger USB Power Delivery USB IF Universal Serial Bus Type C Cable and Connector Specification Revision 1 3 14 July 2017 section 2 4 page 26 Universal Serial Bus Type C Cable and Connector Specification Revision 1 3 14 July 2017 section 5 1 2 page 203 Universal Serial Bus Type C Cable and Connector Specification Revision 1 3 14 July 2017 section A page 213 Android Marshmallow Archived from the original on 2019 06 09 Retrieved 2015 10 12 Charge your Chromebook Pixel 2015 Archived from the original on 2019 07 11 Retrieved 2015 10 31 FreeBSD 8 2 Release Notes www freebsd org 2011 04 22 Archived from the original on 2018 02 17 Retrieved 2018 02 05 NetBSD 7 2 Released Archived from the original on 2019 01 15 Retrieved 2019 01 14 OpenBSD 5 7 Archived from the original on 2018 09 27 Retrieved 2019 06 27 Using the USB C port and adapters on your MacBook Retina 12 inch Early 2015 Apple Support Support Apple com 2015 05 28 Archived from the original on 2015 09 19 Retrieved 2015 06 18 Microsoft Update for USB Type C billboard support and Kingston thumb drive is enumerated incorrectly in Windows Archived from the original on 2015 12 10 Retrieved 2015 12 08 Microsoft Windows support for USB Type C connectors Microsoft MSDN Archived from the original on 2017 06 24 Retrieved 2015 09 30 USB Dual Role Driver Stack Architecture Windows drivers docs microsoft com Archived from the original on 2018 11 01 Retrieved 2019 06 21 Shilov Anton USB C Authentication Tech to Restrict Usage of Uncertified USB C Accessories and Cables AnandTech Retrieved 2022 06 12 Hollister Sean 2022 06 06 Apple will make USB C accessories ask for your permission to pass data The Verge Retrieved 2022 06 12 Li Abner 2019 01 02 USB C Authentication Program could let OEMs clampdown on non compliant USB chargers 9to5Google Retrieved 2022 06 12 Burke Steve 2019 03 25 Why USB 3 1 Type C Isn t on More Cases amp Cable Factory Tour in Dongguan China Gamers Nexus Archived from the original on 2019 06 26 Retrieved 2019 06 26 Are all USB C ports for both charging and data 2019 09 15 Archived from the original on 2022 09 10 Retrieved 2022 05 07 DisplayPort over USB C DisplayPort Archived from the original on 2019 11 27 Retrieved 2019 10 28 Mills Chris 2015 11 16 A Google Engineer Is Publicly Shaming Crappy USB C Cables Archived from the original on 2017 10 24 Retrieved 2017 10 23 Opam Kwame 2015 11 05 A Google Engineer is Testing USB Type C Cables So You Don t Have To The Verge Archived from the original on 2017 10 24 Retrieved 2017 10 23 Be careful about which USB C cables you buy off the Internet TechnoBuffalo 2015 11 16 Archived from the original on 2019 12 16 Retrieved 2019 12 16 Bohn Dieter 2016 02 04 Laptops are getting destroyed by cheap USB C cables The Verge Archived from the original on 2017 10 24 Retrieved 2017 10 23 Universal Serial Bus Type C Cable and Connector Specification Revision 1 1 3 April 2015 page 60 table 3 13 note 1 Leswing Kif 2015 11 05 Google Engineer Reviews Defective USB Cables on Amazon Fortune Fortune Archived from the original on 2017 05 02 Retrieved 2015 11 08 In response to the Type C cable discussions OnePlus Community Archived from the original on 2019 12 16 Retrieved 2019 12 16 TCPP01 M12 Type C Port Protection PDF Archived PDF from the original on 2019 12 03 Retrieved 2019 12 03 USB C audio Everything you need to know Android Central 2018 05 02 Archived from the original on 2019 02 24 Retrieved 2019 02 24 Bring back the headphone jack Why USB C audio still doesn t work PCWorld 2018 09 10 Archived from the original on 2019 03 02 Retrieved 2019 03 12 T Nick 2015 02 26 Android 5 0 Lollipop supports USB DAC audio devices we go ears on Phone Arena Archived from the original on 2019 02 25 Retrieved 2019 02 25 Schoon Ben 2018 11 01 Hands on Apple s new USB C headphone adapter is your cheapest option for analog audio on Pixel Archived from the original on 2019 02 25 Retrieved 2019 02 25 Google engineer warns USB C Qualcomm Quick Charge are incompatible ExtremeTech 2016 04 25 Archived from the original on 2017 10 26 Retrieved 2017 10 23 Qualcomm says it s fine to fast charge your phone over USB C Engadget 2016 04 25 Archived from the original on 2017 10 24 Retrieved 2017 10 23 Qualcomm Quick Charge 4 Five minutes of charging for five hours of battery life Qualcomm 2016 11 17 Archived from the original on 2017 10 24 Retrieved 2017 10 23 Apple opposes EU plans to make common charger port for all devices The Guardian 2021 09 23 Archived from the original on 2021 10 18 Retrieved 2021 10 19 Peltier Elian 2021 09 23 In a setback for Apple the European Union seeks a common charger for all phones The New York Times Archived from the original on 2022 09 10 Retrieved 2021 10 19 One common charging solution for all Internal Market Industry Entrepreneurship and SMEs European Commission 2016 07 05 Archived from the original on 2021 10 19 Retrieved 2021 10 19 Riley Duncan 2022 10 04 European Parliament votes to compel USB C charging on all portable devices SiliconANGLE Retrieved 2022 10 06 Long awaited common charger for mobile devices will be a reality in 2024 European Parliament News European Parliament 2022 10 04 Retrieved 2022 10 06 Porter Jon 2022 10 04 When will the iPhone be forced to use USB C The Verge The Verge Retrieved 2022 10 06 External links edit nbsp Wikimedia Commons has media related to USB C The Universal Serial Bus Type C Cable and Connector Specification is included in a set of USB documents which can be downloaded from USB org Introduction to USB Type C by Andrew Rogers Microchip Technology 2015 Retrieved from https en wikipedia org w index php title USB C amp oldid 1217908829, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.