Increased demand for 1080p HD video requires an innovation in fibre optic video transport tools contends Jim Jachetta, senior vice president of engineering and product development, MultiDyne

By Jim Jachetta,

Jim Jachetta, SVP of Engineering

Senior Vice President of Engineering and Product Development

With the pressure to deliver content in high definition, the world of video transport is dramatically changing. From a broadcast engineer picking out equipment that will save the most time and space in a studio, to a consumer watching a soccer game at home – everyone wants more out of video. Due to this demand, we are seeing the convergence of different video transport methods across industries. High resolution standards that were previously pigeon-holed as “broadcast-only” are now becoming more widely used in every install. We are dealing with a more educated client who is interested in 1080p HD video at home and at work. Manufacturers in this space need to speed up innovation and the range of the solutions they offer in order to give users added value when it comes to HD.

In the past, designers have made a choice early on in system configuration, catering to either a pro A/V, DVI standard as the main backbone to a solution, or a 3G SMPTE broadcast standard. Now, due to customer demand, we are developing tools that have fiber optic video transport capabilities over both standards depending on the application. One such offering, the DVI-6000, which we will be showcasing at IBC 2009, offers breakthroughs in DVI and RGB over a SMPTE compliant 3G data transport.

MultiDyne has been contracted to work on a major hospitality project in Las Vegas which exemplifies the demand for solutions that address both broadcast and pro A/V requirements. Within the 67 acre city-within-a-city campus, there are retail facilities, a condo hotel, casino resort and 300,000 square feet of technologically advanced meeting and convention space. The entire campus features a fiber optic video backbone capable of 1080p 3G HD-SDI transport. The facility is capable of broadcasting live events from any of the meeting rooms or theaters to a broadcast production truck outside, and the convention center features high-tech screens, projectors and digital signage that require a DVI signal. This multi-acre campus is a banner example of how innovations in fiber optic technology must and can be used across many different applications, formats and resolutions due to the new flexibility in fiber optic gear and optical routing switchers. The MultiDyne EOS-4000 switcher is another perfect example of this − as it switches in the light domain, it is able to effortlessly transition between 3G SMPTE and DVI, allowing the user to transport any signal they require.

Fiber optic video transport solutions only continue to be more reliable than competing options. We are actively breaking the constraints of video transport over copper, allowing customers to route and send video further over a single fiber. Fiber optic solutions also allow users to “future proof” their design, with bandwidth potential for innovation over 10G. When designing a complex system using copper, all cabling has to be perfect. If a user squeaked by using copper for 3G, they will be inoperable when the “next big thing” comes along.

It is important to note that MultiDyne’s path to innovation does not end with the advancements made for video transport using the DVI-6000. We are actively designing products that will take advantage of 6G technology, leading to 10G capability. The convergence of video transport demands over several markets also continues to drive us forward. For MultiDyne, the key to not only surviving but thriving in the economic downturn has been to diversify across the broadcast, pro A/V, military and government markets. Our DVI-6000, which can be used across all of these sectors, is in line with this strategy. As IBC is one of our most important shows every year – not only to reach the European market but to meet with U.S. customers, integrators and consultants as well – we’re excited to spend time with our customers, continuing to introduce them to our products which break boundaries when it comes to DVI and 3G HD-SDI video transport.

MultiDyne (Stand 2.A54)

About MultiDyne:

For more than 30 years, MultiDyne has been a leading provider of innovative and outstanding video and fiber optic-based transport and routing systems for the broadcast, cable, satellite, production, digital cinema, pro A/V, corporate, retail, surveillance, teleconferencing, judicial arraignment, transportation, government, military, and healthcare markets. MultiDyne’s fiber optic transport and routing systems for video, SDI, 3G HD, DVB/ASI, VGA, DVI, HDMI, audio, AES, Ethernet, data, CATV, as well as the company’s other broadcast accessories are used worldwide by such industry leaders as ABC, CBS, NBC, CNN, RAI, BBC and the Department of Transportation. MultiDyne provides a seven-year warranty on its core product line. For more information, call MultiDyne at 1-877-MULTIDYNE or 1-516-671-7278, visit the company’s Web site at www.multidyne.com, or send an e-mail to sales@multidyne.com.

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AMSTERDAM, NETHERLANDS, AUGUST 24, 2009 – MultiDyne Video & Fiber Optic Systems, a premier provider of fiber optic-based video and audio transport solutions for broadcast and pro A/V applications, is bringing its LiGHTBoX™ fiber optic field transport system with brand new features to IBC 2009 (Stand 2.A54).

Addressing industry demands for fiber transport applications where battery-powered equipment is required, new features on the popular LiGHTBoX product include 3G capability, a boon for users working with high definition video. The LiGHTBoX is also now compatible with two of MultiDyne’s flagship products, the DVI-6000 and COMMS-2000. Both products can be integrated into the LiGHTBoX, with the COMMS-2000 for use anywhere to provide a two to four wire bridge for intercom. Applications for the LiGHTBoX with DVI-6000, a product designed for the transport of DVI-I, RGB-HV and DVI-D over ONE fiber, include outdoor digital signage and common area video display at a stadium or ball park. This solution ensures that fans do not miss a second of the game when watching the concession-area displays due to the efficiency and high resolution of the DVI display.

“MultiDyne is focused on providing fiber solutions for any requirement, including field and harsh-environment applications,” says Frank Jachetta, senior vice president of sales and operations. “The LiGHTBoX addresses a need for a road-ready, robust fiber solution that serves the needs of our ENG and sports customers.”

The LiGHTBoX is fully customizable offering virtually any signal configuration and can be linked via tactical fiber cable to the MultiDyne DVM-2500, HD-1500, HD-3000 and HEMC-4000.

About MultiDyne:

For more than 30 years, MultiDyne has been a leading provider of innovative and outstanding video and fiber-optic-based transport systems for the broadcast, cable, satellite, production, digital cinema, pro A/V, corporate, retail, surveillance, teleconferencing, judicial arraignment, transportation, government, military, and healthcare markets. MultiDyne’s fiber optic transport systems for video, SDI, 3G HD, DVB/ASI, VGA, DVI, HDMI, audio, AES, Ethernet, data, CATV, as well as the company’s other broadcast accessories are used worldwide by such industry leaders as ABC, CBS, NBC, CNN, RAI, BBC and the Department of Transportation. MultiDyne provides a seven-year warranty on its core product line. For more information, call MultiDyne at 1-877-MULTIDYNE or 1-516-671-7278, visit the company’s Web site at www.multidyne.com, or send an e-mail to sales@multidyne.com.

# # #

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Frank Jachetta of MultiDyne Video & Fiber Optic Systems

Frank Jachetta – Senior VP of Sales and Operations
MultiDyne Video and Fiber Optic Systems

Frank, can you first fill us in on your background?

I hold a Bachelors degree in computer science and started in the industry as a circuit board designer and firmware developer. I have transitioned into a sales and operations position, but still enjoy being involved in product development.

What is the history of MultiDyne?

My father Vincent started MultiDyne in 1977 by building the first portable colour bar generator. MultiDyne then went on to create the first hand held signal generator. Our signal distribution background started with long-haul, cable equalizing DAs and has now evolved into a full line of fibre optic transport products.

What are the main product lines of MultiDyne?

MultiDyne comes from a broadcast background, but as convergence becomes a reality, many of our products carry over or focus on pro-AV, high end surveillance, intelligent traffic systems, military, government and simulation.

Our focus is high quality, point to point fibre optic transport. We can transport virtually any signal over fibre optic cable including composite, component and HDSDI video, high resolution graphics such as DVI dual link and RGB, AES and analogue audio, and much more.  Another product line is the field rugged, fibre optic transport working in conjunction with our tactical cable assemblies. In fact, the LiGHTBoX 1150 won two awards at IBC in 2008.

Which applications represent the current “sweet spot”?

I would have to say the optical router (EOS-4000) in conjunction with the DVI/RGB Fibre Link (DVI-6000).   When these two are installed in concert, it is no longer just a point to point device, we can distribute from one point to many points, such as multiple screens with the same content. Or, with a touch of the remote control, different images can be displayed on each of those same screens. DVI, DVI-DL, NTSC, PAL, RGB or YPbPr can be transported over the same link, so regardless of the source and destination signal requirements, one device can carry any of these signals. Audio also comes along for the ride and soon, USB!

Fibre optics is clearly a main component, how has this evolved in recent years?

With the advent of HDSDI and its tremendous proliferation, fibre has moved from being a luxury to becoming a necessity. Depending on cable types, HDSDI can only travel a few hundred feet over copper. This removes the option of copper from even a large room, not to mention a building, campus or metro area.

Does fibre compete favourably with copper?

Until it became a necessity, copper was more favourable due to fibre’s higher cost and fibre frailty. Fibre also had a stigma of being too difficult to terminate. However, with the increasing cost of copper, rugged tactical fibre and field termination kits, fibre has become more favourable than copper. In fact I was onsite for a railroad installation, standing in a tent on a windy winter day while the technician there terminated ST connectors onto fibre in a matter of seconds!

What future do you see for 3G transport?

Of course one day 3G will go the way of the VCR and vinyl records, but for now, the future of 3G transport is bright. The higher resolution 3G or 1080p HDTV is supported by many consumer displays and has proliferated into broadcast productions. 3G can be used to transport dual link HDSDI by multiplexing two 1.5G HDSDI streams into one 3G stream for digital cinema.  3G or HDTV 1080P is also used in sports and television productions. The 3G HD signal format is often used as the transport format of choice. Various types of signals are converted to and from the 3G format. This holds true for our DVI/RGB fibre link which converts DVI to 3G for transport or cross conversion. This way the 3G can pass through other 3G devices and routers easily, before it is converted back to DVI or simply left in its new 3G form.

How has the current business climate affected you?

I feel as an industry, even outside of fibre, we are all very blessed by the explosive growth of high resolution video content and the need to distribute it. With the mandates of changing over to HD, all the new video services that consumers have available and are willing to purchase and the proliferation of multimedia into all aspects of life, I am cautiously optimistic that our industry will not just weather these difficult times, but thrive.

Would you like to make a few predictions about the future of the media industry once the financial crisis is behind us?

Although the word convergence has become a cliché, I feel this is our future. When a single broadband conduit is brought to the home it will not just bring voice data and video, but will bring on demand services of very specialized content as easily as accessing a web site. When you can access various HD camera views at will, while watching baseball; when you can shop interactively, or take a real-time virtual walk through the summerhouse you are about to rent 3000 miles away, this is the future.

Current on demand and fibre to the home are a glimpse of what’s to come, but as the economy improves and the infrastructure is expanded, these services will quickly become reality. Of course, the broadband conduit to the home will be fibre.

Edition 71

2nd quarter 2009

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Booth SU6917

• Economical solution for fiber optic transport of multi-rate HD-SDI signals ranging from 5Mb/sec to 3.0Gb/sec plus 2 AES or 4 audio, bi-directional data, & 2 return audio over a single fiber.
• Two models; one supports SMPTE 424M 3G HD-SDI standard or
• One supports SMPTE 292M 1.485G HD-SDI standard
• Also supports embedded audio & data.
• Looping inputs, Dual re-clocked & EQ outputs
• Convenient modules for field applications or frame mount.
• Battery operation, field applicable.

• 1.5Gb/sec digital video, 4 audio, or 2 AES & bi-directional data
• 3.0 Gb/sec digital video, 4 audio, or 2 AES & bi-directional video
• Multirate video from 5Mb/sec up to either 1.5 Gb, or 3.0 Gb depending on card
• Equalized and reclocked video at SMPTE standards
• 2RU frame, 10 cards or 20 cards
• Independent rear modules for connectivity

• Uncompressed DVI Single & Dual Link over ONE fiber
• Supports up to WQXGA 2560 x 1600
• Supports Stereo Audio and Data
• Fully un-compressed, 100% transparent, No Frame Dropping
• The system provides a pixel-for-pixel image transport
• 100% 24 Bits for all scan rates with no contouring or bit reduction at high scan rate
• Shipping NOW!

• Frame sizes of 16, 32, 64, 144, and 288
• 16 I/O’s per switch card
• CWDM coarse wave division multiplexing optics supported
• Signal independence, DVI, 3GB, RGB
• Control via Ethernet, intuitive GUI
• External serial port. (Crestron, AMX)
• Pathological testing compliance

• HD-SDI repeater / optical transport, HD-SDI fan out DA with HDMI & Audio monitoring.
• Available in 3Gb, or 1.5Gb versions for a cost effective solution.
• Optical input and reclocked optical output.
• Compatible with other SMPTE compliant devices including MultiDyne’s HD-1500, and HD-3000.
• Three copper HD-SDI outputs.
• HDMI output for cost effective local monitoring
• Audio de-embedding from HD-SDI stream for output on HDMI, or on separate RCA connectors.

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Digital Visual Interface for DVI-I and DVI-D Fiber Transport

Digital Visual Interface (DVI)
A male DVI-D (single link) connector.
Type	Digital and analog computer video connector
Production history
Designer	Digital Display Working Group
Designed	April 1999
Produced	1999 to present
Specifications
Hot pluggable	Unknown
External	Yes
Video signal	Digital video stream. (Single) WUXGA 1920 × 1200 @ 60 Hz (Dual) WQXGA (2560 × 1600) @ 60 Hz Analog RGB video (-3 db at 400 MHz)
Data signal	R,G,B data + clock and display data channel
	Bandwidth	(Single Link) 3.96 Gbit/s (Dual Link) 7.92 Gbit/s
	Max devices	1
	Protocol	3 × Transition Minimized Differential Signaling data + clock
Pins	29
Pin out
A female DVI-I socket from the front
Pin 1	TMDS Data 2-	Digital red – (Link 1)
Pin 2	TMDS Data 2+	Digital red + (Link 1)
Pin 3	TMDS Data 2/4 shield
Pin 4	TMDS Data 4-	Digital green – (Link 2)
Pin 5	TMDS Data 4+	Digital green + (Link 2)
Pin 6	DDC clock
Pin 7	DDC data
Pin 8	Analog vertical sync
Pin 9	TMDS Data 1-	Digital green – (Link 1)
Pin 10	TMDS Data 1+	Digital green + (Link 1)
Pin 11	TMDS Data 1/3 shield
Pin 12	TMDS Data 3-	Digital blue – (Link 2)
Pin 13	TMDS Data 3+	Digital blue + (Link 2)
Pin 14	+5 V	Power for monitor when in standby
Pin 15	Ground	Return for pin 14 and analog sync
Pin 16	Hot plug detect
Pin 17	TMDS data 0-	Digital blue – (Link 1) and digital sync
Pin 18	TMDS data 0+	Digital blue + (Link 1) and digital sync
Pin 19	TMDS data 0/5 shield
Pin 20	TMDS data 5-	Digital red – (Link 2)
Pin 21	TMDS data 5+	Digital red + (Link 2)
Pin 22	TMDS clock shield
Pin 23	TMDS clock+	Digital clock + (Links 1 and 2)
Pin 24	TMDS clock-	Digital clock – (Links 1 and 2)
C1	Analog red
C2	Analog green
C3	Analog blue
C4	Analog horizontal sync
C5	Analog ground	Return for R, G and B signals

The Digital Visual Interface (DVI) is a video interface standard designed to maximize the visual quality of digital display devices such as flat panel LCD computer displays and digital projectors. It was developed by an industry consortium, the Digital Display Working Group (DDWG). It is designed for carrying uncompressed digital video data to a display. It is partially compatible with the High-Definition Multimedia Interface (HDMI) standard in digital mode (DVI-D), and VGA in analog mode (DVI-A).

Contents [hide] 1 Overview 2 Technical discussion 3 Connector 4 Specifications 4.1 Digital 4.1.1 Clock and data relationship 4.2 Analog 5 Proposed successors 6 References

Overview

The DVI interface uses a digital protocol in which the desired illumination of pixels is transmitted as binary data. When the display is driven at its native resolution, it will read each number and apply that brightness to the appropriate pixel. In this way, each pixel in the output buffer of the source device corresponds directly to one pixel in the display device, whereas with an analog signal the appearance of each pixel may be affected by its adjacent pixels as well as by electrical noise and other forms of analog distortion.

Previous standards such as the analog VGA were designed for CRT-based devices and thus did not use discrete time display addressing. As the analog source transmits each horizontal line of the image, it varies its output voltage to represent the desired brightness. In a CRT device, this is used to vary the intensity of the scanning beam as it moves across the screen.

DVI cable connectors are designed in such a way as not to allow the user to connect the cable in an incorrect position or orientation. DVI connectors are available in five models, differing in the way they handle analog or digital transfers.

In the digital transfer one or two channels are present. Video and monitor cards which are exclusively digital cannot be connected to analog, but can be connected to equipment that handles both analog and digital signals. The DVI standard also supports the Display Data Channel (DDC) and the Extended Display Identification Data (EDID), which allows computers to communicate with different monitor extensions.

“DVI-I” stands for “DVI-Integrated” and supports both digital and analog transfers, so it works with both digital and analog Visual Display Units. “DVI-D” stands for “DVI-Digital” and supports digital transfers only.

Unlike HDMI, DVI carries no audio data.

 

Technical discussion

The data format used by DVI is based on the PanelLink serial format devised by the semiconductor manufacturer Silicon Image Inc. This uses Transition Minimized Differential Signaling (TMDS). A single DVI link consists of four twisted pairs of wires (red, green, blue, and clock) to transmit 24 bits per pixel. The timing of the signal almost exactly matches that of an analog video signal. The picture is transmitted line by line with blanking intervals between each line and each frame, and without packetization. No compression is used and there is no support for only transmitting changed parts of the image. This means that the whole frame is constantly re-transmitted. The specification (see below for link) does, however, include a paragraph on “Conversion to Selective Refresh” (under 1.2.2), suggesting this feature for future devices.

With a single DVI link, the largest resolution possible at 60 Hz is 2.75 megapixels (including blanking interval). For practical purposes, this allows a maximum screen resolution at 60 Hz of 1915 x 1436 pixels (standard 4:3 ratio), 1854 x 1483 pixels (5:4 ratio) or 2098 x 1311 (widescreen 8:5 ratio). The DVI connector therefore has provision for a second link, containing another set of red, green, and blue twisted pairs. When more bandwidth is required than is possible with a single link, the second link is enabled, and alternate pixels may be transmitted on each, allowing resolutions up to 4 megapixels at 60 Hz. The DVI specification mandates a fixed single link maximum pixel clock frequency of 165 MHz, where all display modes that require less than this must use single link mode, and all those that require more must switch to dual link mode. When both links are in use, the pixel rate on each may exceed 165 MHz. The second link can also be used when more than 24 bits per pixel is required, in which case it carries the least significant bits. The data pairs carry binary data at ten times the pixel clock reference frequency, for a maximum data rate of 1.65 Gbit/s x 3 data pairs for a single DVI link.

Like modern analog VGA connectors, the DVI connector includes pins for the display data channel (DDC). DDC2 (a newer version of DDC) allows the graphics adapter to read the monitor’s extended display identification data (EDID). If a display supports both analog and digital signals in one input, each input can host a distinct EDID. If both receivers are active, analog EDID is used.

The maximum length of DVI cables is not included in the specification since it is dependent on bandwidth requirements (the resolution of the image being transmitted). In general, cable lengths up to 4.5 m (15 ft) will work for displays at resolutions of 1920 x 1200. Cable lengths up to 15 m (50 ft) can be used with displays at resolutions up to 1280 x 1024. For longer distances, the use of a DVI booster is recommended to mitigate signal degradation. DVI boosters may or may not use an external power supply.

 

Connector

Male DVI connector pins (view of plug)

Color coded female DVI connector with pin descriptions

The DVI connector usually contains pins to pass the DVI-native digital video signals. In the case of dual-link systems, additional pins are provided for the second set of data signals.

As well as digital signals, the DVI connector includes pins providing the same analog signals found on a VGA connector, allowing a VGA monitor to be connected with a simple plug adapter. This feature was included in order to make DVI universal, as it allows either type of monitor (analog or digital) to be operated from the same connector.

The DVI connector on a device is therefore given one of three names, depending on which signals it implements:

• DVI-D (digital only)
• DVI-A (analog only)
• DVI-I (integrated, digital & analog)

The connector also includes provision for a second data link for high resolution displays, though many devices do not implement this. In those that do, the connector is sometimes referred to as DVI-DL (dual link).

The long flat pin on a DVI-I connector is wider than the same pin on a DVI-D connector, so it is not possible to connect a male DVI-I to a female DVI-D by removing the 4 analog pins. It is possible, however, to connect a male DVI-D cable to a female DVI-I connector. Many flat panel LCD monitors have only the DVI-D connection so that a DVI-D male to DVI-D male cable will suffice when connecting the monitor to a computer’s DVI-I female connector.

DVI is the only widespread video standard that includes analog and digital transmission options in the same connector.^[1] Competing standards are exclusively digital: these include a system using low-voltage differential signaling (LVDS), known by its proprietary names FPD (for Flat-Panel Display) Link and FLATLINK; and its successors, the LVDS Display Interface (LDI) and OpenLDI.

Some new DVD players, TV sets (including HDTV sets) and video projectors have DVI/HDCP connectors; these are physically the same as DVI connectors but transmit an encrypted signal using the HDCP protocol for copy protection. Computers with DVI video connectors can use many DVI-equipped HDTV sets as a display; however, due to Digital Rights Management, it is not clear whether such systems will eventually be able to play protected content, as the link is not encrypted.

USB signals are not incorporated into the connector, but were earlier incorporated into the VESA Plug and Display connector used by InFocus on their projector systems, and in the Apple Display Connector, which was used by Apple Computer until 2005.

The DMS-59 connector is a way to combine two analog and two digital signals in one plug. It is commonly used when a single graphics card has two outputs.

M1-DA connectors are sometimes labeled as DVI-M1; they are used for the VESA Enhanced Video Connector and VESA Plug and Display schemes.

Specifications

Digital

• Minimum clock frequency: 25.175 MHz
• Maximum clock frequency in single link mode: Capped at 165 MHz (up to 3.96 Gbit/s)
• Maximum clock frequency in dual link mode: Limited only by cable quality (up to 7.92 Gbit/s)
• Pixels per clock cycle: 1 (single link) or 2 (dual link)
• Bits per pixel: 24 (single and dual link) or 48 (dual link only)

• Example display modes (single link):
  • HDTV (1920 × 1080) @ 60 Hz with CVT-RB blanking (139 MHz)
  • UXGA (1600 × 1200) @ 60 Hz with GTF blanking (161 MHz)
  • WUXGA (1920 × 1200) @ 60 Hz with CVT-RB blanking (154 MHz)
  • SXGA (1280 × 1024) @ 85 Hz with GTF blanking (159 MHz)
  • WXGA+ (1440 x 900) @ 60 Hz (107 MHz)
  • WQUXGA (3840 × 2400) @ 17 Hz (164 MHz)

• Example display modes (dual link):
  • QXGA (2048 × 1536) @ 75 Hz with GTF blanking (2 × 170 MHz)
  • HDTV (1920 × 1080) @ 85 Hz with GTF blanking (2 × 126 MHz)
  • WQXGA (2560 × 1600) @ 60 Hz with GTF blanking (2 × 174 MHz) (30-inch (762 mm) Apple, Dell, Gateway, HP, NEC, Quinux, and Samsung LCDs)
  • WQXGA (2560 × 1600) @ 60 Hz with CVT-RB blanking (2 × 135 MHz) (30-inch (762 mm) Apple, Dell, Gateway, HP, NEC, Quinux, and Samsung LCDs)
  • WQUXGA (3840 × 2400) @ 33 Hz with GTF blanking (2 × 159 MHz)

GTF (Generalized Timing Formula) is a VESA standard which can easily be calculated with the Linux gtf utility.

CVT-RB (Coordinated Video Timing-Reduced Blanking) is a VESA standard which offers reduced horizontal and vertical blanking for non-CRT based displays.^[2]

Clock and data relationship

The DVI data channel operates at a bit-rate multiple of 10 times the frequency of the clock signal. In other words, for every DVI clock there are 10 bits provided on each of the three data channels. The data is encoded using a standard 8b/10b encoding to provide a minimum transition density in which there are no more than five consecutive bits of the same value, which is necessary to provide reference edges for clock/data recovery circuits. As indicated in version 1.0 of the specification, the clock rate is the same as the pixel rate plus framing overhead, while there are usually 24 bits per pixel. For example, a (640 × 480) @ 60 Hz display has a pixel rate of 18.4 MHz (plus blanking overhead) so this is the minimum needed clock. But the data is actually (640 × 480) @ 60 Hz × 24 bits per pixel which is 442 Mbit/s, or 147 Mbit/s per channel. Include 8B10B overhead and you need a 184 Mbit/s data stream on each of the three data channels.

Since the data is switching at 10 times the clock rate, a receiver must recover the faster bit clock from the data lines itself (using a PLL or DLL, for instance) in a process known as clock/data recovery. The DVI clock is effectively a 1/10th frequency reference clock that is useful for the clock/data recovery circuitry to synchronize to the bitstream. DVI provides a reference clock while other serial data interfaces such as PCI Express and SATA do not because the bit rate carried by the DVI interface may vary across a wide frequency range depending on the video format being rendered. Serial interfaces that do not explicitly carry the reference clock are typically defined to run at a specific known frequency or several derivative frequencies that are related by whole number multiples (for example 2.5 Gbit/s and 5.0 Gbit/s for successive generations of PCI Express and 1.5 Gbit/s and 3.0 Gbit/s for successive generations of SATA), so in these cases a fixed frequency reference clock can be generated locally at the receiver that performs the clock/data recovery.

Analog

• RGB bandwidth: 400 MHz at -3 dB

Proposed successors

IEEE 1394 is proposed by High Definition Audio-Video Network Alliance (HANA Alliance) for all cabling needs, including video, over CoAx and/or 1394 cable as a combined data stream.

High-Definition Multimedia Interface (HDMI), a forward-compatible standard, that also includes digital audio transmission.

Unified Display Interface (UDI) was proposed by Intel to replace both DVI and HDMI, but was deprecated in favor of DisplayPort.

DisplayPort is a license-free standard proposed by VESA to succeed DVI, which also has DRM capabilities.

References

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