Cable Matters Connectivity Glossary Page

Category 3

Cat3

Cat3 (Category 3) is a type of twisted pair cable that was commonly used in older Ethernet networks. It is an unshielded twisted pair (UTP) cable that consists of four pairs of 24-gauge copper wires inside a protective sheath.

Cat3 cables have a maximum data transfer rate of 10 Mbps and a maximum bandwidth of 16 MHz, which is sufficient for basic voice and data communication in small networks. However, Cat3 cables are no longer recommended for use in modern networks due to their relatively slow data transfer rates and limited bandwidth.

Cat3 cables have largely been replaced by higher-performance Ethernet cable types such as Cat5e, Cat6, and Cat6a, which offer higher data transfer rates and bandwidths. However, Cat3 cables may still be used in some older systems or for applications that do not require high-speed data transfer, such as for telephone systems or low-bandwidth computer networks.

See also: Ethernet, Ethernet Cable

Category 5

Cat5

Cat5 (Category 5) is a type of twisted pair cable that was widely used in Ethernet networks in the late 1990s and early 2000s. It is an unshielded twisted pair (UTP) cable that consists of four pairs of 24-gauge copper wires inside a protective sheath.

Cat5 cables have a maximum data transfer rate of 100 Mbps and a maximum bandwidth of 100 MHz, which is sufficient for many small and medium-sized networks. They can be used for a wide range of applications, including data and voice communication, video streaming, and online gaming.

Cat5 cables are terminated with RJ-45 connectors on both ends, making them easy to plug into Ethernet ports on devices. They are often used to connect computers, switches, routers, and other network devices together.

Cat5 cables have largely been replaced by higher-performance Ethernet cable types such as Cat5e, Cat6, and Cat6a, which offer higher data transfer rates and bandwidths. However, Cat5 cables may still be used in some older systems or for applications that do not require high-speed data transfer.

See also: Ethernet, Ethernet Cable

Category 5e

Cat5e

Cat5e (Category 5e) is a type of twisted pair cable that is commonly used in Ethernet networks. It is an enhanced version of Cat5 cable, with improved specifications that provide better performance and higher data transfer rates.

Cat5e cables are unshielded twisted pair (UTP) cables that consist of four pairs of 24-gauge copper wires inside a protective sheath. They have a maximum data transfer rate of 1 Gbps and a maximum bandwidth of 100 MHz, which is sufficient for most small and medium-sized networks. They are backwards compatible with Cat5 cables and can be used in the same types of applications.

See also: Category 5

Category 6

Cat6

Cat6 (Category 6) is a type of twisted pair cable that is commonly used in Ethernet networks. It is an improved version of Cat5e cable, with even higher specifications that provide better performance and higher data transfer rates.

Cat6 cables are unshielded twisted pair (UTP) cables that consist of four pairs of copper wires inside a protective sheath. They have a maximum data transfer rate of 10 Gbps and a maximum bandwidth of 250 MHz, which is significantly higher than that of Cat5e cables. They are backwards compatible with Cat5 and Cat5e cables and can be used in the same types of applications.

Cat6 cables are terminated with RJ-45 connectors on both ends, making them easy to plug into Ethernet ports on devices. They are often used to connect computers, switches, routers, and other network devices together.

Cat6 cables are widely used in wired networks where high-speed data transfer is critical, such as in large enterprise networks or data centers. They provide a fast and reliable connection for data transfer, video streaming, and other high-bandwidth applications. They are more expensive than Cat5e cables, but their improved performance makes them a popular choice for businesses and organizations that require high-speed networking capabilities.

See also: Category 5e

Category 6a

Cat6a

Cat6a (Category 6a) is a type of twisted pair cable that is commonly used in Ethernet networks. It is an enhanced version of Cat6 cable, with even higher specifications that provide better performance and higher data transfer rates.

Cat6a cables are unshielded twisted pair (UTP) cables that consist of four pairs of copper wires inside a protective sheath. They have a maximum data transfer rate of 10 Gbps and a maximum bandwidth of 500 MHz, which is twice the bandwidth of Cat6 cables. They are backwards compatible with Cat6 and Cat5e cables and can be used in the same types of applications.

See also: Category 6

Category 7

Cat7

Cat7 (Category 7) is a type of twisted pair cable that is used for Ethernet networking. It is designed to provide faster data transfer rates and better signal quality than previous Ethernet cable standards, such as Cat5, Cat5e, and Cat6.

Cat7 cables are shielded twisted pair (STP) cables that use a specialized shielding design to prevent signal interference and crosstalk. They consist of four individually shielded pairs of copper wires, with each pair wrapped in its own shielding layer, and an overall shielding layer that covers all four pairs. This shielding design provides excellent signal quality and reduces the risk of electromagnetic interference (EMI) and radio frequency interference (RFI).

Cat7 cables use the GG45 or TERA connectors, which are backward compatible with RJ45 connectors but have a different design that allows for faster data transfer rates and better signal quality. They have a maximum data transfer rate of up to 10 Gbps and a maximum bandwidth of 600 MHz, which is higher than previous Ethernet cable standards.

However, Category 7 is not recognized by the TIA/EIA.

See also: Category 6a, Category 8

Category 8

Cat8

Cat8 (Category 8) is a type of twisted pair cable that is used for Ethernet networking. It is the latest and highest performing Ethernet cable standard available on the market as of 2021.

Cat8 cables are designed to support high-speed data transmission over short distances, up to 30 meters (98 feet) for 25Gbps and 40Gbps, and up to 24 meters (79 feet) for 40Gbps and 100Gbps.

Cat8 cables use shielding to prevent signal interference and crosstalk, which can degrade the signal quality and reduce data transmission speeds. They also have a larger gauge wire, typically 22 or 24 AWG, than previous Ethernet cable standards to support higher data rates.

Cat8 cables are designed for use in data centers and other high-performance computing environments where high-speed data transmission and low latency are critical. They can support data rates of up to 40Gbps or 100Gbps, making them suitable for applications such as high-speed data transfer, video streaming, and online gaming.

See also: Category 6, Ethernet Cable

Component video

Component video is an analog video signal format that separates a video signal into three components: the luminance (brightness) component and two chrominance (color) components. These components are then transmitted separately over three cables or wires.

In a component video signal, the three separate components of the video signal are usually carried on three RCA cables with different colors: red, green, and blue. This is commonly referred to as RGB component video. The green component carries the luminance information, while the red and blue components carry the color information.

Component video is capable of transmitting high-quality video signals, particularly when compared to composite video, which transmits all video information on a single wire or pin. Component video is widely used in professional video production and is also found on many consumer electronics devices such as DVD players, gaming consoles, and HDTVs.

However, component video is an analog video signal and is being phased out in favor of digital video standards like HDMI and DisplayPort, which offer higher quality and more advanced features, such as support for higher resolutions, 3D video, and multi-channel audio.

See also: Composite video, High-Definition Multimedia Interface, RCA

Composite video

Composite video is an analog video signal format that carries all video information on a single wire or pin. It combines the luminance (brightness) and chrominance (color) components of a video signal into a single signal that can be transmitted using a single cable.

In a composite video signal, the luminance and chrominance components are combined by encoding them into a single signal using frequency modulation (FM). The resulting signal is then transmitted over a single cable, which can be a coaxial cable or an RCA cable.

While composite video is a simple and widely used video signal format, it is not capable of transmitting high-quality video signals. Composite video signals are susceptible to interference and noise, which can result in distortion, color bleeding, and other types of image degradation. As a result, composite video has largely been replaced by newer digital video standards like HDMI and DisplayPort.

See also: Super Video

Digital Visual Interface

DVI

DVI (Digital Visual Interface) is a video display standard that was introduced in 1999 as a replacement for the VGA (Video Graphics Array) standard. It is capable of transmitting high-quality digital video signals between a video source, such as a computer or a video card, and a display device, such as a monitor or a projector.

DVI supports several different modes of operation, including single-link and dual-link modes, which determine the maximum resolution and refresh rate that can be transmitted. Single-link DVI supports a maximum resolution of 1920x1200 pixels at 60 Hz, while dual-link DVI can support resolutions of up to 2560x1600 pixels at 60 Hz.

DVI connectors can be either analog or digital, depending on the type of signal that is being transmitted. DVI-I (integrated) connectors support both analog and digital signals, while DVI-D (digital only) connectors support only digital signals. DVI-A (analog only) connectors support only analog signals.

DVI is still used in some applications, particularly in the computer industry, although it has largely been replaced by newer video standards such as HDMI and DisplayPort, which offer even higher resolutions, faster refresh rates, and other advanced features. However, many modern graphics cards and displays still include DVI ports to provide backwards compatibility with older systems.

See also: DisplayPort, Video Graphics Array, High-Definition Multimedia Interface

Digital Visual Interface - Analog

DVI-A

DVI-A (Digital Visual Interface - Analog) is a type of DVI (Digital Visual Interface) connector that transmits only analog signals. It was designed to be compatible with older display devices that use analog signals, such as CRT monitors and some older LCD monitors.

DVI-A connectors have 17 pins and are compatible with VGA (Video Graphics Array) devices, which also transmit only analog signals. This means that a DVI-A connector can be used with a VGA display device, using a simple adapter cable.

DVI-A is capable of transmitting resolutions of up to 1920x1200 pixels, which is suitable for most computer and display applications. However, because it transmits only analog signals, the image quality may not be as sharp or clear as with digital signal formats such as DVI-D or HDMI.

While DVI-A is still used in some applications, it has largely been replaced by newer video standards that support both analog and digital signals, such as DVI-I (integrated), HDMI, and DisplayPort. However, DVI-A is still found on some older computers and display devices, and can be useful for connecting these devices to older display technology that only supports analog signals.

See also: Digital Visual Interface, Video Graphics Array, Digital Visual Interface - Integrated

Digital Visual Interface - Integrated

DVI-I

DVI-I (Digital Visual Interface - Integrated) is a type of DVI (Digital Visual Interface) connector that supports both analog and digital signals. It is capable of transmitting both types of signals simultaneously, which allows it to be used with a wide range of display devices, including CRT monitors, LCD monitors, and projectors.

DVI-I connectors have 24 pins, and the shape of the connector is designed to prevent it from being inserted the wrong way. They are compatible with both DVI-D (digital-only) and DVI-A (analog-only) devices, and can be used with either type of signal.

DVI-I cables can be used to connect a variety of devices, including computers, DVD players, game consoles, and other devices to display devices such as monitors and projectors. DVI-I supports resolutions of up to 1920x1200 pixels, making it suitable for most applications.

While DVI-I is still used in some applications, it has largely been replaced by newer video standards, such as HDMI and DisplayPort, which offer higher bandwidth and more advanced features. However, DVI-I remains a popular choice for many older devices and is still commonly found on many desktop computers and display devices.

See also: Digital Visual Interface, Video Graphics Array

DisplayPort

DP

DisplayPort is a digital interface used to transmit video and audio data from one device to another. It is commonly used to connect computer displays and other video sources to a display device, such as a monitor or TV. DisplayPort was developed by the Video Electronics Standards Association (VESA). . It is designed to be a replacement for older analog interfaces, such as VGA and DVI, and to offer a more versatile and feature-rich alternative to HDMI.

DisplayPort supports high-definition video, including resolutions up to 8K, as well as multi-channel audio, making it an ideal interface for high-quality audio and visual experiences. DisplayPort also supports daisy-chaining, which allows multiple display devices to be connected in series using a single DisplayPort cable, and it supports the HDCP (High-bandwidth Digital Content Protection) technology, which helps to protect digital content from unauthorized copying. DisplayPort cables and connectors come in various sizes and types, including DisplayPort 1.2, DisplayPort 1.4, DisplayPort 1.4 with HDR, and DisplayPort 2.1.

See also: High-bandwidth Digital Content Protection

DisplayPort 1.2

DP 1.2

DisplayPort 1.2 is a digital display interface standard that was introduced in 2010 as an updated version of the original DisplayPort standard. DisplayPort 1.2 provides a high-bandwidth, low-latency digital interface for transmitting video and audio data between a computer and a display device, such as a monitor, projector, or television.

Some of the key features and improvements of DisplayPort 1.2 over its predecessors include:

Increased bandwidth: DisplayPort 1.2 provides a maximum bandwidth of 17.28 Gbps, which is more than twice the bandwidth of DisplayPort 1.1. This allows for higher resolution displays, faster refresh rates, and support for more color depth and color spaces.

Support for multiple displays: DisplayPort 1.2 supports the Multi-Stream Transport (MST) technology, which allows for the connection of multiple displays to a single DisplayPort output.

Audio capabilities: DisplayPort 1.2 provides support for 8-channel audio and provides a direct audio path from the source device to the display device.

Improved power management: DisplayPort 1.2 provides improved power management capabilities, allowing for the reduction of power consumption and heat generation in devices.

Support for copy protection: DisplayPort 1.2 provides support for High-bandwidth Digital Content Protection (HDCP), which is a form of digital rights management (DRM) that is used to protect copyrighted content.

See also: DisplayPort, High-bandwidth Digital Content Protection, Multiple Stream Transport

DisplayPort 1.4

DP 1.4

DisplayPort 1.4 is a digital display interface standard that was introduced in 2016 as an updated version of DisplayPort 1.2. DisplayPort 1.4 provides a high-bandwidth, low-latency digital interface for transmitting video and audio data between a computer and a display device, such as a monitor, projector, or television.

Some of the key features and improvements of DisplayPort 1.4 over its predecessors include:

Increased bandwidth: DisplayPort 1.4 provides a maximum bandwidth of 32.4 Gbps, which is nearly double the bandwidth of DisplayPort 1.2. This allows for higher resolution displays, faster refresh rates, and support for more color depth and color spaces.

Support for 8K displays: DisplayPort 1.4 provides support for 8K displays, which offer four times the resolution of 4K displays and sixteen times the resolution of standard 1080p displays.

HDR support: DisplayPort 1.4 provides support for High Dynamic Range (HDR) displays, which offer improved color accuracy and contrast, and a wider range of brightness and color levels.

Audio capabilities: DisplayPort 1.4 provides support for 32-channel audio and provides a direct audio path from the source device to the display device.

Support for copy protection: DisplayPort 1.4 provides support for High-bandwidth Digital Content Protection 2.2 (HDCP 2.2), which is a form of digital rights management (DRM) that is used to protect copyrighted content.

DisplayPort 2.1

DP 2.1

DisplayPort 2.1 replacing short-lived DisplayPort 2.0 was introduced in 2020. It is an upgrade to the previous version of DisplayPort, DisplayPort 1.4, and offers a number of improvements and new features over previous versions of DisplayPort.

Some of the key features and improvements of DisplayPort 2.1 over its predecessors include:

Increased bandwidth: DisplayPort 2.1 provides a maximum bandwidth of 80 Gbps, which is more than twice the bandwidth of DisplayPort 1.4. This allows for higher resolution displays, faster refresh rates, and support for more color depth and color spaces.

Support for higher refresh rates: DisplayPort 2.1 provides support for high refresh rates of up to 360Hz, which provides a smoother and more fluid visual experience for fast-paced games and videos.

HDR support: DisplayPort 2.1 provides improved support for High Dynamic Range (HDR) displays, with a wider color gamut and improved brightness and contrast.

Audio capabilities: DisplayPort 2.1 provides support for 64-channel audio and provides a direct audio path from the source device to the display device.

Support for copy protection: DisplayPort 2.1 provides support for High-bandwidth Digital Content Protection 2.3 (HDCP 2.3), which is a form of digital rights management (DRM) that is used to protect copyrighted content.

Enhanced power management: DisplayPort 2.1 provides improved power management capabilities, allowing for the reduction of power consumption and heat generation in devices.

Dolby Vision

Dolby Vision is a proprietary HDR (High Dynamic Range) technology developed by Dolby Laboratories. It is designed to deliver even more impressive image quality than other HDR technologies, such as HDR10, by providing a greater level of control over color, brightness, and contrast.

One of the key features of Dolby Vision is its use of dynamic metadata, which provides additional information about the content being displayed on a frame-by-frame basis. This allows a compatible display to optimize the image quality for each individual frame, resulting in a more accurate and dynamic representation of the original content.

Dolby Vision also uses a 12-bit color depth, which provides an even wider range of colors than the 10-bit color depth used in HDR10. It also supports a higher peak brightness of up to 10,000 nits, although most displays can only reach up to 4,000 nits.

Dolby Vision content is currently available on a variety of streaming platforms, including Netflix, Amazon Prime Video, and Disney+. It is also supported on a growing number of TVs, media players, and other devices. In addition to its technical advantages, Dolby Vision has also become known for its branding and marketing, with many people associating the Dolby Vision logo with high-quality HDR content.

See also: HDR10, High Dynamic Range

Ethernet

Ethernet is a technology used for wired local area networks (LANs). It is a family of networking technologies that allows devices to communicate with each other over a shared physical network, such as a cable or a set of wires. Ethernet is typically used to connect devices such as computers, printers, and servers to a local network and the internet.

Ethernet is based on a set of standards that specify how devices on a network can communicate with each other. These standards define the physical characteristics of the network, such as the type of cable to use, as well as the rules for how data is transmitted and received over the network.

Ethernet supports a wide range of data transfer rates, from 10 megabits per second (Mbps) to 100 gigabits per second (Gbps) or more, depending on the specific implementation of the technology. Ethernet is also very reliable and is widely used in both home and business environments.

Ethernet has largely replaced older networking technologies such as token ring and ARCnet, and is also being used in combination with wireless networking technologies like Wi-Fi to provide a high-speed, reliable, and flexible network infrastructure.

Ethernet Cable

An Ethernet cable is a type of network cable used to connect devices together in a wired Ethernet network. It is a cable that contains one or more pairs of copper wires inside a protective sheath. The wires are used to transmit data between devices on the network.

Ethernet cables come in different categories, each with different capabilities and speeds. The most common categories of Ethernet cables are Category 5e (Cat5e), Category 6 (Cat6), and Category 6a (Cat6a). Cat5e cables can support speeds up to 1 Gbps, while Cat6 and Cat6a cables can support speeds up to 10 Gbps.

Ethernet cables are typically terminated with RJ-45 connectors on both ends. These connectors are designed to plug into Ethernet ports on devices such as computers, switches, routers, and modems.

Ethernet cables are widely used in wired networks for their reliability, security, and speed. They are a simple and effective way to connect devices together and provide a fast and stable connection for data transfer. Ethernet cables can be used for a wide range of applications, from home networks to large enterprise networks.

See also: Ethernet Network, Ethernet

Ethernet Network

An Ethernet network is a type of computer network that uses Ethernet technology to connect devices together. In an Ethernet network, devices are connected to a central device called a switch, which manages the flow of data between devices on the network.

Ethernet networks can be used to connect devices in a wide variety of environments, including homes, offices, schools, and data centers. They are capable of supporting high-speed data transfer rates and can handle large amounts of data traffic, making them ideal for applications such as file sharing, video streaming, and online gaming.

Ethernet networks are often used in combination with other networking technologies, such as Wi-Fi, to provide a flexible and reliable network infrastructure. Ethernet is also used in wide area networks (WANs), such as the internet, to provide high-speed data transfer between different networks.

See also: Ethernet

Ethernet Patch Cable

An Ethernet patch cable is a type of Ethernet cable that is used to connect network devices together, such as computers, switches, and routers. It is called a "patch" cable because it is typically used to make a temporary connection between two devices, or to "patch" a connection between a device and a network jack or port.

Ethernet patch cables are typically shorter than other Ethernet cables, ranging in length from a few inches to a few meters, and are often used for connections within a rack or cabinet. They are typically terminated with RJ-45 connectors on both ends, making them easy to plug into Ethernet ports on devices.

Patch cables come in different categories, such as Cat5e, Cat6, Cat6a, and Cat8 which offer different speeds and performance capabilities. They can also come in different colors, which can be used to help identify different types of connections in a network.

See also: Ethernet, Ethernet Cable

HDMI 1.4

It was introduced in 2009 and was widely used for several years before being replaced by later versions, such as HDMI 2.0. HDMI 1.4 provides support for the transmission of high-definition video and audio signals between devices, such as a Blu-Ray player, game console, or streaming device, and a display device, such as a TV or monitor. The key features of HDMI 1.4 include:

Bandwidth: HDMI 1.4 has a maximum bandwidth of 10.2 Gbps, which is sufficient for high-definition video and audio transmission.

Resolution Support: HDMI 1.4 supports resolutions up to 4K (3840 x 2160) at 30Hz.

Audio Support: HDMI 1.4 supports up to 8 audio channels, which allows for multi-channel audio experiences.

3D Support: HDMI 1.4 introduced support for 3D video, which allows for the display of 3D content on compatible TVs.

See also: HDMI 2.0

HDMI 2.0

HDMI 2.0 is an upgrade from the previous HDMI 1.4 standard and offers a number of improvements over it, including:

Higher bandwidth: HDMI 2.0 has a maximum bandwidth of 18 Gbps, which is up from 10.2 Gbps in HDMI 1.4. This allows for higher resolution and more data to be transmitted.

4K Resolution Support: HDMI 2.0 supports resolutions up to 4K (3840 x 2160) at 60Hz, making it ideal for use with 4K Ultra HD TVs.

Dynamic HDR Support: HDMI 2.0 supports dynamic HDR (High Dynamic Range), which allows for more accurate and vivid color representation.

More audio channels: HDMI 2.0 supports up to 32 audio channels, compared to 8 channels in HDMI 1.4. This allows for more immersive multi-channel audio experiences.

See also: HDMI 1.4, HDMI 2.1

HDMI 2.1

HDMI 2.1 is a digital interface standard for transmitting high-definition video and audio between devices, such as a Blu-ray player, gaming console, or computer, and a display device, such as a television or monitor. HDMI 2.1 is an updated version of HDMI 2.0 and provides several key improvements over its predecessor.

Some of the key features and improvements of HDMI 2.1 include:

Increased bandwidth: HDMI 2.1 provides a maximum bandwidth of 48 Gbps, which is nearly four times the bandwidth of HDMI 2.0 and enables support for higher resolutions and refresh rates.

Support for higher refresh rates: HDMI 2.1 provides support for high refresh rates of up to 120Hz, which provides a smoother and more fluid visual experience for fast-paced games and videos.

HDR support: HDMI 2.1 provides improved support for High Dynamic Range (HDR) displays, with a wider color gamut and improved brightness and contrast.

Audio capabilities: HDMI 2.1 provides support for immersive audio formats, including object-based audio and support for up to 1536kHz audio sample frequency.

Support for copy protection: HDMI 2.1 provides support for High-bandwidth Digital Content Protection 2.3 (HDCP 2.3), which is a form of digital rights management (DRM) that is used to protect copyrighted content.

Enhanced power management: HDMI 2.1 provides improved power management capabilities, allowing for the reduction of power consumption and heat generation in devices.

See also: HDMI 2.0, HDMI 1.4, High-bandwidth Digital Content Protection

HDR10

HDR10 is a popular open standard for High Dynamic Range (HDR) technology used in consumer electronics, such as TVs, monitors, and media players. It was developed by the Consumer Technology Association (CTA) and is now widely adopted by manufacturers and content creators.

HDR10 uses a 10-bit color depth, which means it can display over a billion colors, compared to the 16.7 million colors of a standard 8-bit display. It also has a peak brightness of 1,000 nits, which is significantly brighter than the 100-200 nits of a standard SDR (Standard Dynamic Range) display.

To display HDR10 content, the display must be HDR10 compatible, which means it can receive and process the HDR10 metadata embedded in the content. This metadata provides information about the color and brightness levels of the content, allowing the display to adjust its settings to optimize the image quality.

HDR10 is widely supported by streaming services, such as Netflix and Amazon Prime Video, and is also used for HDR content on Ultra HD Blu-ray discs. It is considered to be the minimum HDR standard for a good HDR experience, with other standards, such as Dolby Vision, offering even higher image quality.

See also: High Dynamic Range

High Dynamic Range

HDR

It is a technology that allows for a greater range of color and brightness to be displayed on a screen or captured in a photograph.

Traditional displays and cameras have a limited dynamic range, which means they can only show a certain range of colors and brightness levels. HDR technology, on the other hand, can capture or display a wider range of colors and brightness levels, resulting in more vibrant, lifelike images.

HDR works by capturing or displaying more information about the brightness of a scene. This is achieved by capturing or displaying multiple exposures of the same scene, with each exposure capturing a different range of brightness levels. These multiple exposures are then combined to create an image with a wider dynamic range.

There are different types of HDR, such as HDR10, Dolby Vision, and HLG (Hybrid Log-Gamma), each with their own specifications and capabilities. HDR is becoming increasingly popular in TVs, monitors, and cameras, and is now a standard feature in many high-end devices.

See also: HDR10

High-bandwidth Digital Content Protection

HDCP

A digital copy protection used to protect digital content as it is transmitted over a digital interface, such as HDMI or DisplayPort. The purpose of HDCP is to prevent unauthorized copying of digital content, such as movies, TV shows, and video games, as it is transmitted from a source device, such as a Blu-ray player, to a display device, such as a TV or monitor.

HDCP works by encrypting the digital content as it is transmitted from the source device to the display device, and only allowing the content to be played if the display device is authorized to receive it. The source device and display device must both support HDCP in order for the content to be transmitted and played securely. If the display device is not authorized, the content may not be played, or it may be played with degraded quality. This helps to prevent piracy and ensure that the rights of content owners are protected.

See also: High-Definition Multimedia Interface, DisplayPort

High-Definition Multimedia Interface

HDMI

A digital interface used to transmit video and audio data from one device to another. It is commonly used to connect devices such as a DVD player, Blu-ray player, video game console, or a computer to a TV or monitor. HDMI supports high-definition video, including resolutions up to 4K, as well as multi-channel audio. This makes it an ideal interface for home theater systems, providing a high-quality audio and visual experience. HDMI cables also support copy protection technologies, such as HDCP, to prevent unauthorized copying of digital content.

See also: High-bandwidth Digital Content Protection, DisplayPort

Hybrid Log-Gamma

HLG

HLG (Hybrid Log-Gamma) is another HDR (High Dynamic Range) technology that was jointly developed by the BBC and NHK, the public broadcasters of the United Kingdom and Japan, respectively. It was designed to provide a simpler solution for broadcasting HDR content that can be received by both HDR and non-HDR displays.

HLG uses a combination of standard dynamic range (SDR) and HDR techniques to encode and display content. Specifically, it uses a logarithmic curve for brightness that allows the HDR content to be viewed on both SDR and HDR displays. This is because the logarithmic curve is compatible with the gamma curve used by SDR displays, while still providing more color and brightness information for HDR displays.

The advantage of HLG is that it can be used for broadcasting HDR content, without requiring a separate broadcast stream for HDR and SDR displays. This is possible because HLG content is backwards compatible with SDR displays, which means that viewers with non-HDR displays can still view the content, albeit with a reduced dynamic range

HLG is also used in some cameras and camcorders for capturing HDR content, as well as in some streaming services, such as the BBC iPlayer and YouTube. While HLG is not as widely used as HDR10 or Dolby Vision, it is gaining popularity as a simpler and more flexible solution for delivering HDR content.

See also: Dolby Vision, High Dynamic Range, HDR10

Multiple Stream Transport

MST

Multiple Stream Transport (MST) is a technology that allows a single DisplayPort output to be split into multiple displays. It enables the connection of multiple monitors to a single DisplayPort port on a computer or device, allowing for the creation of multi-monitor configurations. macOS computers currently do not support MST.

Each monitor in the configuration is treated as a separate display, and the computer's operating system can configure the desktop and windows to span across multiple monitors. This allows for increased productivity and a larger display area, which can be useful in various applications, such as graphic design, video editing, and gaming.

MST works by using the DisplayPort 1.2 standard and requires a device with MST support, such as a graphics card or a laptop with a built-in DisplayPort output. The device splits the DisplayPort signal into multiple streams, each of which is sent to a separate monitor.

See also: DisplayPort

PCI Express

PCIe

PCI Express (PCIe) is a high-speed serial computer expansion bus standard that provides a connection between a computer and peripheral devices, such as graphics cards, sound cards, network adapters, and solid-state drives (SSDs).

PCIe was designed as a replacement for the older parallel bus standards, such as Peripheral Component Interconnect (PCI) and AGP (Accelerated Graphics Port), and provides a number of advantages over these older standards, including:

Increased bandwidth: PCIe provides a high-bandwidth, low-latency connection between the computer and peripheral devices, with bandwidths ranging from 250 MB/s to 128 GB/s.

Scalability: PCIe provides a scalable bus architecture that allows for the addition of new devices and the expansion of existing devices.

Improved reliability: PCIe uses a point-to-point connection between the computer and peripheral devices, reducing the potential for data errors and improving reliability.

Improved power management: PCIe provides improved power management capabilities, allowing for the reduction of power consumption and heat generation in devices.

PCIe has become the standard for connecting peripheral devices to computers and is widely used in both desktop and laptop computers. The latest version of PCIe is PCIe 6.0, which was introduced in 2021 and provides a bandwidth of up to 128 GB/s.

See also: Thunderbolt 1, Thunderbolt 2, Thunderbolt 3, Thunderbolt 4

RCA

Radio Corporation of America

RCA (Radio Corporation of America) is a type of connector used for analog audio and video signals. It is commonly known as the "phono connector" or "phono plug" and is recognizable by its distinctive design, which consists of a cylindrical plug with a small metal pin at the center and a surrounding metal ring.

The RCA connector is often used for connecting analog audio and video devices such as DVD players, game consoles, and home theater systems to TVs, monitors, and speakers. RCA connectors are typically color-coded to help users distinguish between different types of connectors. For example, yellow RCA connectors are commonly used for composite video, while red and white RCA connectors are often used for stereo audio.

While RCA connectors are still in use, they are gradually being replaced by newer digital standards like HDMI and DisplayPort, which offer higher quality video and audio signals.

See also: Composite video

Standard Dynamic Range

SDR

SDR stands for Standard Dynamic Range. It is the traditional format used for displaying images on most TVs, computer monitors, and other display devices. SDR content typically has a limited range of colors and brightness levels, with a peak brightness of around 100-200 nits. SDR displays typically have a color depth of 8 bits, which means they can display up to 16.7 million colors.

In SDR, the brightness levels of an image are represented on a linear scale, where each increase in brightness is represented by an equal step in the signal. This means that the signal levels for the brighter parts of an image are relatively close together, which can result in a loss of detail and contrast.

In contrast, HDR (High Dynamic Range) technology, uses a non-linear scale that allows for a wider range of brightness levels and a greater number of colors to be displayed. This results in more lifelike and vibrant images.

While SDR is still the most common format for displaying content, HDR technology is becoming increasingly popular, particularly for high-end devices and for streaming services that offer HDR content. Some newer displays are designed to support both SDR and HDR content, allowing viewers to enjoy the best of both formats.

See also: High Dynamic Range

Super Video

Separate Video

S-Video

S-Video, also known as Separate Video or Super Video, is a video signal format that transmits video data as two separate signals: one for luminance (brightness) and one for chrominance (color information).

In an S-Video signal, the luminance information is carried on one channel, usually a single pin or wire, while the chrominance information is carried on another channel. This separation of the two types of video information results in a higher-quality video signal compared to composite video, which carries all the video information on a single channel.

S-Video was widely used in the late 1990s and early 2000s for connecting DVD players, gaming consoles, and other video devices to TVs and monitors. However, it has largely been replaced by newer digital video formats like HDMI and DisplayPort.

Super Video Graphics Array

SVGA

SVGA (Super Video Graphics Array) is an extension of the VGA (Video Graphics Array) standard that was introduced by IBM in 1987. SVGA was developed in response to the need for higher resolution and better color quality in computer graphics and video displays.

SVGA supports resolutions that are higher than the maximum 640x480 resolution supported by VGA. SVGA resolutions can range from 800x600 pixels to 1920x1080 pixels or higher, depending on the specific implementation. SVGA also supports a greater number of colors than VGA, typically up to 16 million colors, which allows for more detailed and realistic images.

To support the higher resolutions and color depths of SVGA, the standard also requires higher bandwidth and faster signal transmission. To achieve this, SVGA typically uses a digital signal rather than the analog signal used by VGA. This allows for sharper, more accurate images with less interference and noise.

SVGA uses the same 15-pin connector as VGA, and is backwards compatible with VGA displays, which means that a VGA display can display an SVGA signal, although at a lower resolution and color depth. SVGA cables can be used to connect a video source, such as a computer or a video card, to a display device, such as a monitor or a projector.

While SVGA is an older video standard, it is still used in some applications, particularly in industries such as graphics design and gaming, where high-quality graphics and images are important. However, newer video standards such as HDMI and DisplayPort have largely replaced SVGA for most consumer and commercial applications, due to their support for even higher resolutions and refresh rates, as well as other advanced features.

See also: DisplayPort, Video Graphics Array, High-Definition Multimedia Interface

Thunderbolt 1

The first generation of Thunderbolt was introduced in 2011 and was a significant improvement over previous interface standards, such as USB and FireWire. Thunderbolt was developed by Intel and Apple and it combined high-speed data transfer and video and audio transmission in a single cable.

One of the key features of Thunderbolt 1 was its speed, with support for data transfer rates of up to 10 Gbps, which was much faster than most other interface standards at the time. This allowed for fast transfers of large files, as well as support for high-definition video and audio transmission, and the connection of multiple displays.. The first-generation Thunderbolt also introduced support for DisplayPort, which allowed for the connection of high-resolution displays with a single cable. This was a major improvement over previous standards, such as DVI and VGA, which required separate cables for video and audio transmission.

Another important feature of the first-generation Thunderbolt was its support for PCI Express, which allowed for the use of high-performance devices, such as external graphics cards and RAID arrays, over a single cable. This made it possible to connect and use a wide range of high-performance devices with a single cable, making it a more efficient and convenient interface for demanding applications.

Despite its advantages, Thunderbolt 1 faced some challenges in terms of its adoption and availability, as it was initially limited to high-end devices and Mac computers, and not widely supported by the PC industry. Nevertheless, Thunderbolt 1 laid the foundation for the future development of the Thunderbolt interface standard, and it remains a significant milestone in the history of the interface.

See also: DisplayPort

Thunderbolt 2

Thunderbolt 2 is a version of the Thunderbolt interface standard that was introduced in 2013. It is an upgrade to the previous version of Thunderbolt, which was released in 2011, and offers a number of improvements and new features over the original Thunderbolt. One of the key features of Thunderbolt 2 is its speed, which supports data transfer rates of up to 20 Gbps. This high speed allows for fast transfers of large files, as well as support for high-definition video and audio transmission, and the connection of multiple displays.

Another feature of Thunderbolt 2 is its versatility, as it supports a wide range of protocols, including DisplayPort, PCI Express, and FireWire, among others. This allows for the use of a single Thunderbolt 2 port for multiple functions, making it a convenient and efficient interface for a wide range of devices. Thunderbolt 2 also introduces support for daisy-chaining, which allows for the connection of multiple devices to a single Thunderbolt port. This makes it possible to connect a chain of devices, such as external hard drives, displays, and other peripherals, all using a single cable, making it a more convenient and organized solution for connecting a large number of devices.

One of the key improvements of Thunderbolt 2 over the original Thunderbolt is its support for DisplayPort 1.2, which allows for the connection of high-resolution displays with a single cable, as well as support for Multi-Stream Transport (MST), which allows for the use of multiple displays with a single cable.

See also: Thunderbolt 1, DisplayPort

Thunderbolt 3

Thunderbolt 3 is a version of the Thunderbolt interface standard that was introduced in 2015. It is an upgrade to the previous version of Thunderbolt, Thunderbolt 2, and offers a number of improvements and new features over previous versions of Thunderbolt. One of the key features of Thunderbolt 3 is its speed, which supports data transfer rates of up to 40 Gbps, making it one of the fastest interfaces available for consumer devices. This high speed allows for fast transfers of large files, as well as support for high-definition video and audio transmission, and the connection of multiple displays.

Another feature of Thunderbolt 3 is its versatility, as it supports a wide range of protocols, including DisplayPort, PCI Express, and USB, among others. This allows for the use of a single Thunderbolt 3 port for multiple functions, including data transfer, video output, and charging, making it a convenient and efficient interface for a wide range of devices.

One of the key improvements of Thunderbolt 3 over previous versions of Thunderbolt is its support for the USB-C connector, which is becoming increasingly common on a wide range of devices. This allows for easy and convenient connectivity with a wide range of devices, as well as the ability to use a single cable for multiple functions, such as charging, data transfer, and video output.

See also: Thunderbolt 4, Thunderbolt 2, PCI Express, DisplayPort

Thunderbolt 4

Thunderbolt 4 was introduced in 2021. It offers a number of improvements and new features over Thunderbolt 3, the previous version of the Thunderbolt standard.

Here are some of the key differences between Thunderbolt 4 and Thunderbolt 3:

Performance: Thunderbolt 4 supports data transfer rates of up to 40 Gbps, the same as Thunderbolt 3. However, Thunderbolt 4 offers additional performance benefits, such as improved support for multiple displays, with up to four 4K displays supported, compared to two 4K displays supported by Thunderbolt 3.

PC Requirements: Thunderbolt 4 requires PC platforms to include certain security and performance features, such as support for Direct Memory Access (DMA) protection and the ability to wake up from sleep states, ensuring that Thunderbolt 4 devices are reliable and secure.

Certification Requirements: Thunderbolt 4 has stricter certification requirements, ensuring that devices that carry the Thunderbolt 4 logo meet a certain set of standards in terms of performance, security, and compatibility.

USB-C Support: Thunderbolt 4 provides additional support for USB-C, with mandatory support for USB 4.0, as well as support for Power Delivery and DisplayPort Alt Mode over USB-C.

Improved Support for External Graphics Cards: Thunderbolt 4 provides improved support for external graphics cards, making it easier to connect and use high-performance graphics cards for demanding applications, such as gaming and video editing.

Overall, Thunderbolt 4 offers a number of improvements over Thunderbolt 3, including improved performance, stricter certification requirements, and better support for USB-C and external graphics cards. These improvements make Thunderbolt 4 a more reliable, secure, and versatile interface for a wide range of devices and applications.

See also: Thunderbolt 3, PCI Express, DisplayPort, Thunderbolt 5, USB4

Thunderbolt 5

Thunderbolt 5 is the latest generation of Thunderbolt technology, which was officially announced by Intel in September 2023.

Thunderbolt 5 will deliver 80 gigabits per second (Gbps) of bi-directional bandwidth, and with Bandwidth Boost it will provide up to 120 Gbps for the best display experience. These improvements will provide up to three times more bandwidth than the best existing connectivity solution, providing outstanding display and data connections. Thunderbolt 5 will meet the high bandwidth needs of content creators and gamers. Built on industry standards – including USB4 V2 – Thunderbolt 5 will be broadly compatible with previous versions of Thunderbolt and USB.

See also: Thunderbolt 4, USB4

Universal Serial Bus

USB

USB stands for Universal Serial Bus, and it is a type of interface used to connect devices to a computer or other host device. USB is a versatile and widely used interface that supports a wide range of devices, including external hard drives, printers, keyboards, mice, flash drives, smartphones, and many other types of peripheral devices. USB was designed to be a fast, reliable, and low-cost way to connect devices to a computer, and it has become the most widely used interface for connecting peripheral devices.

One of the key benefits of USB is its plug-and-play capability, which allows devices to be easily connected and disconnected without the need to restart the computer or manually configure drivers.

There have been several versions of USB, with the latest being USB4 , which was released in 2021. Each new version of USB has improved upon the previous one, offering increased speeds, improved power management, and additional features. USB is also backwards compatible, which means that newer devices can be connected to older computers, and older devices can be connected to newer computers, as long as the computer has a USB port that supports the appropriate version of USB.

See also: USB Type-C, USB4

Unshielded Twisted Pair

UTP

UTP stands for Unshielded Twisted Pair, which is a type of cable used for network connections. It is a popular cable type for Ethernet networks, as it is relatively inexpensive and easy to install. UTP cable consists of several pairs of twisted copper wires that are surrounded by a flexible plastic insulation. The twisted pair configuration helps to reduce electromagnetic interference (EMI) and crosstalk between the wires, which can degrade signal quality.

UTP cable comes in various categories, such as Cat5, Cat5e, and Cat6, which indicate the cable's data transmission capabilities. The higher the category, the higher the data transmission speed and bandwidth. UTP cable is often used for local area networks (LANs), where it connects computers, printers, and other devices to a central switch or router.

See also: Category 6, Category 5e, Category 5

USB Type-C

USB-C

USB-C, also known as USB Type-C, is a type of USB (Universal Serial Bus) interface that was introduced in 2014. It is characterized by its small, reversible plug design, which makes it easier to connect devices compared to earlier USB types, which have a specific orientation and can only be plugged in one way.

One of the key advantages of USB-C is its versatility, as it can be used for a wide range of functions, including charging devices, transferring data, and connecting to displays. In some cases, a single USB-C port can support multiple functions, such as power delivery, video output, and data transfer, all over the same cable. This makes it a convenient and versatile interface for a variety of devices, including laptops, smartphones, and tablets.

One of the key features of USB-C is its ability to support a wide range of protocols and technologies, including USB 3.1 and later versions, DisplayPort, and Thunderbolt. Another advantage of USB-C is its high data transfer speeds, which can reach up to 40 Gbps in some cases, depending on the version of USB and the connected devices. Additionally, USB-C supports several charging standards, including USB Power Delivery (USB-PD), which allows for fast and efficient charging of compatible devices.

Additionally, USB-C supports several charging standards, including USB Power Delivery (USB-PD), which allows for fast and efficient charging of compatible devices.

See also: DisplayPort, Universal Serial Bus

USB4

USB4 is the latest version of the Universal Serial Bus (USB) interface standard, released in 2019. It is an upgrade to the previous version of USB, USB 3.2, and offers a number of improvements and new features over previous versions of USB.

One of the key features of USB4 is its increased speed, which supports data transfer rates of up to 40 Gbps, making it one of the fastest interfaces available for consumer devices. This increased speed makes USB4 well-suited for demanding applications, such as transferring large amounts of data, connecting high-resolution displays, and charging devices quickly.

Another feature of USB4 is its support for the DisplayPort 2.0 display standard, which allows for high-definition video and audio transmission, as well as support for multiple displays. This makes USB4 a versatile interface for a wide range of devices, including laptops, tablets, and smartphones.

USB4 is also backwards compatible with previous versions of USB, including USB 3.2, USB 3.0, and USB 2.0, which means that devices that support earlier versions of USB can still be connected to USB4 ports and will work as expected.

Overall, USB4 is designed to provide a fast and versatile interface for connecting and communicating with a wide range of devices, and it is expected to become increasingly popular in the coming years as more and more devices adopt this technology.

See also: Universal Serial Bus, DisplayPort, USB Type-C, Thunderbolt 4

Video Graphics Array

VGA

VGA (Video Graphics Array) is a video display standard that was first introduced by IBM in 1987. It is one of the oldest video standards still in use today, although it has largely been replaced by newer standards, such as DVI and HDMI.

VGA was designed to provide a high-quality video display for computer monitors and other display devices. It uses an analog signal to transmit video information, which means that the video information is converted into a continuous electrical signal that can be sent to the display device. The maximum resolution supported by VGA is 640x480 pixels, although some VGA displays can support higher resolutions with lower refresh rates.

The VGA standard uses an analog signal to transmit video, which means that the signal is susceptible to degradation over long cable lengths and can be affected by interference. However, it also means that VGA signals can be easily converted to other analog video standards, such as composite video or S-Video, using simple adapters.

While VGA is no longer the standard for high-quality video displays, it is still used in some older computer systems, and many newer displays and video cards still include a VGA port to provide backwards compatibility.

See also: High-Definition Multimedia Interface