CD and DVD players

by Chris Woodford. Last updated: February 17, 2022.

It's amazing when you think about it: you can store a movie several hours long on a shiny piece of plastic no bigger than your hand! Although compact discs (CDs) have been around for more than 30 years, they are still one of the most popular ways of storing music and computer data. In the mid-1990s, CDs evolved into digital video/versatile discs (DVDs), which look and work in a similar way but can store about seven times more. And now we have Blu-ray™, which can store six times more than a DVD—or about 40 times more a than CD! Have you ever wondered how CDs, DVDs, and Blu-rays actually work? Let's take a closer look!

Note: Throughout this article, we'll talk about CDs. But almost everything about CDs also holds true for DVDs and Blu-ray discs.

What is a CD?

A compact disc is a thin, circular disc of metal and plastic about 12cm (just over 4.5 inches) in diameter. It's actually made of three layers. Most of a CD is made from a tough, brittle plastic called polycarbonate. Sandwiched in the middle there is a thin layer of aluminum. Finally, on top of the aluminum, is a protective layer of plastic and lacquer. The first thing you notice about a CD is that it is shiny on one side and dull on the other. The dull side usually has a label on it telling you what's on the CD; the shiny side is the important part. It's shiny so that a laser beam can bounce off the disc and read the information stored on it.

Photo: A small portable compact disc player made by Technics. Gadgets like this have now largely been superseded by MP3 players such as iPods, which are much smaller and lighter and pack lots more music into the same space by compressing it digitally. Read more about this in our main article on MP3 players.

How CDs use optical laser technology

Until CDs were invented, music was typically stored on vinyl (plastic) LP (long-playing) records and cassette tapes. LPs scratched easily, while tapes could stretch and distort and sometimes snapped or seized up entirely. Both of these ways of storing music were primitive compared to CDs. LPs were played on turntables with a moving arm that bounced along a groove in the plastic, reading back the music as it went. Record players (or gramophones, as they were sometimes known) used mechanical technology for recording and playing back sound: the moving arm turned the bumps in the plastic into sounds you could hear. Cassette tapes (used in such things as the original Sony Walkmans) worked a different way. They stored sounds using magnetic technology. When you put a cassette into your Walkman, a small electric motor dragged the tape past a little electromagnet. The electromagnet detected the pattern of magnetism on the tape and an electronic circuit changed this back into the sounds that fizzed and popped in your headphones.

Photo: Great music, rotten CD! CDs were billed as virtually indestructible, but some early ones have fallen victim to a problem called disc rot, which comes in various flavors. Some rotten CDs slowly turn brown (a problem known as "bronzing"); in others, bits of the reflective surface pit or disappear, eventually making them unplayable. Often the last track, which is nearest the exposed edge of a compact disc, is affected first.

Photo: A close-up of the rot on the bronzed edge of a CD, where the metal has started to disintegrate and fall away. This disc will eventually become unplayable.

With the invention of CDs, people finally had a more reliable way of collecting music. CD players are neither mechanical nor magnetic but optical: they use flashing laser lights to record and read back information from the shiny metal discs. One of the main problems with LPs and cassettes was the physical contact between the player and the record or tape being played, which gradually wore out. In a CD player, the only thing that touches the CD is a beam of light: the laser beam bounces harmlessly off the surface of the CD, so the disc itself should (in theory) never wear out. Another advantage is that the CD player can move its laser quickly to any part of the disc, so you can instantly flip from track to track or from one part of a movie to another.

How CDs are recorded and played back

Note: In the explanations that follow, I'm deliberately going to simplify how CDs store music as patterns of zeros and ones. It's much more complex than I'm going to make it seem, and it's beyond the scope of an introductory article like this, but I will briefly describe what really happens at the very end.

LP records stored music as bumps on the surface of plastic, while cassettes stored it using patterns of magnetism. These are called analog technologies, because the sound is stored as a continuously varying pattern (of bumps in the plastic of a record or fluctuations in the magnetism on a cassette tape). In a CD, music (or other information) is stored digitally (as a long string of numbers). After the music has been recorded, it is converted into numbers by a process called sampling. Almost 50,000 times a second (44,100 to be exact), a piece of electronic equipment measures the sound, turns the measurement into a number, and stores it in binary format (as a pattern of zeros and ones). The sampling process turns a CD track lasting several minutes into a string of millions of zeros and ones. There's another bit of processing that goes on after sampling (technically, known as modulation—I'll talk about it very briefly, further down this page). But, in very simple terms, the sampled data is essentially the information stored on your CD. In other words, there is no (analog) music on a CD at all—just a huge long list of (digital) numbers.

Illustration: An ordinary CD is a sandwich of plastic (in which bumps have been pressed by a master disc), reflective aluminum, and protective polycarbonate plastic.

CDs are made from an original "master" disc. The master is "burned" with a laser beam that etches bumps (called pits) into its surface. A bump represents the number zero, so every time the laser burns a bump into the disc, a zero is stored there. The lack of a bump (which is a flat, unburned area on the disc, called a land) represents the number one. Thus, the laser can store all the information sampled from the original track of music by burning some areas (to represent zeros) and leaving other areas unburned (to represent ones). Although you can't see it, the disc holds this information in a tight, continuous spiral of about 3–5 billion pits. If you could unwrap the spiral and lay it in a straight line, it would stretch for about 6 km (roughly 3.5 miles)! Each pit occupies an area about two millionths of a millionth of a square meter. That's pretty tiny!

Once the master disc has been made, it is used to stamp out millions of plastic duplicates—the CDs that you buy and put into your music player or computer. Once each disc is pressed, it's coated with a thin aluminum layer (so it will reflect laser light), covered with protective polycarbonate and lacquer, and the label is printed on top.

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Recordable CDs and DVDs

When CDs first became popular in the 1980s, they were sold purely as read-only audio compact discs (CD-DA, ones you could play music from but not record onto). It wasn't long before computer companies realized they could use CDs to distribute software (programs) very cheaply, and ordinary computer users soon saw that CDs would be even better if you could write music and data on them as well as just read from them. That's how recordable CDs (CD-Rs) came to be developed, but the snag was that they could only be written on once; you couldn't erase and reuse them. Soon enough, though, the computer whizzkids developed rewritable CDs (CD-RWs) that you could erase and rewrite any number of times.

Photo: A CD/DVD writer/rewriter has a much more sophisticated laser read/write head than an ordinary CD/DVD player. Depending on the type of player, the read/write head needs to be able to read ordinary CDs and DVDs, recordable discs, and rewritable discs—so it really needs to be capable of several quite different reading and writing operations.

How does a recordable CD (CD-R) work?

In theory, if you wanted to make ordinary CDs in your own home, you'd need to install a huge and expensive CD-pressing machine. Fortunately, you don't need to do this—and that's because recordable CDs (CD-Rs) work in a completely different way. This time, there are no pits and lands imprinted on plastic. Instead, in between the protective polycarbonate and the reflective aluminum, there's a layer of dye. Normally the dye is translucent: laser light zooming into the disk from a CD player will pass straight through it, hit the reflective aluminum, and bounce straight back down again.

So far so good, but how do we store information on a compact disc like this? A CD-R writer has a higher-powered laser than normal, which generates heat when it strikes the disc, "burning" the dye and making a tiny black spot. Later, when a CD reader aims its laser at that spot, the light is completely absorbed and doesn't reflect back. This indicates that a zero ("0") is stored on the disc at that point. In places where the dye is unburned, the laser light reflects straight back again, indicating that a "1" is stored on the disc. See where this is going? By creating areas of "burned" dots, and other places where the dye is left alone, a CD-R writer creates a pattern of binary zeros and ones that can be used to store information. Unfortunately, once the dye is "burned" it's permanently transformed: you can't change it back again. And that's why you can only write a CD-R disc once. Just in passing, we should note that, although CD writers are widely referred to as CD burners, they do not actually burn things (combust them with oxygen): they simply use a laser to change the light-sensitive dye.

Illustration: With a CD-R, binary information is stored as "burned" areas (0) and unburned areas (1) in the dye layer sandwiched between the protective polycarbonate and the reflective aluminum.

How does a rewritable CD (CD-RW) work?

Let's say you're charged with the task of developing a type of compact disc that can be written to or erased over and over again. Clearly you can't use either of the methods we've discussed so far (the pits and lands method from read-only audio CDs or the "burned"-dye method used in CD-Rs). What you really need is a CD made from a substance that can easily be converted back and forth between two different forms, so it can be used to store a pattern of zeros and ones, then erased and used to store a different pattern later on if necessary.

Most of us learned in school that the atoms (or molecules) in solids, liquids, and gases arrange themselves in different positions, with atoms in solids tightly locked together. Some solid materials are more complex than this: their atoms (or molecules) can be arranged in two or more different ways called solid phases. (Solid carbon, for example, can exist in very different phases that include graphite and diamond.) That's just what we need to make a CD-RW disc.

Instead of having a layer of dye, a CD-RW has a layer of metallic alloy that can exist in two different solid forms and change back and forth between them. It's called a phase-change or phase-shift material. Sometimes it's crystalline, with its atoms/molecules arranged in orderly ways, so it's translucent and light can pass straight through it; other times, its atoms/molecules are jumbled up in a much more random and disorderly form called an amorphous solid, which is opaque and blocks light. When a CD-RW laser hits this material, it changes tiny little areas of it back and forth between the crystalline and amorphous forms. When it creates a crystalline area, it's making part of the CD reflective and effectively writing a one ("1"); when it makes an amorphous area, it's making the CD non-reflective and writing a zero ("0"). Because this process can be repeated any number of times, you can write and rewrite a CD-RW pretty much as many times as you like!

Illustration: With a CD-RW, binary information is stored as areas of metal alloy that are either crystalline or amorphous. Crystalline areas have a regular structure that lets light pass through to the aluminum area and reflect back down again, thus storing ones. Amorphous areas have a random structure that scatters incoming laser light, so it can't reflect back, thus storing zeros. A CD-rewriter can change the metal alloy on the CD from one form to the other and back again, which is why this kind of disc can be erased and rewritten many times over.

Other types of CDs

CDs were originally used just for storing music. Each disc could store 74 minutes of stereo sound—more than enough for a typical LP record. During the 1990s, CD technology also became popular for storing computer programs, games, and other information. Kodak's PhotoCD system (a way of storing up to 100 photos on a compact disc), was also launched in the 1990s.

The original form of computer CD was called CD-ROM (CD-Read Only Memory), because most computers could only read information from them (and not store any information on them). In those days, you needed a separate piece of equipment called a "burner" to write your own CDs, which were often called WORMs (Write Once Read Many). It's now more common for computers to have CD-R or CD/RW drives for burning their own CDs, although most new computers now have DVD drives instead.

The difference between CDs and DVDs is the amount of information they can store. A CD can hold 650 megabytes (million characters) of data, whereas a DVD can cram in at least 4.7 gigabytes (thousand megabytes)—which is roughly seven times more. Because DVDs are the same size as CDs, and are storing seven times more information, the zeros and ones (or pits and lands) on a DVD have to be correspondingly smaller than those on a CD. The latest optical discs use a technology called Blu-ray to store six times more data than DVDs or 40 times more than CDs (see the box at the bottom for a full explanation).

Photo: CDs introduced us to digital music, but they're now being superseded by MP3 players and digital downloads. Why? Look how hard it is to hold just a dozen CDs in your hand. Even a 20GB Apple iPod MP3 player can hold something like 400-500 CDs worth of music without even blinking—and it fits in your shirt pocket! Having said that, a music track on CD will always sound better than than the equivalent MP3, for reasons we explain in our article on MP3 players and digital music.

More about those zeros and ones

It's nice and easy to explain CDs by saying that pits correspond to zeros and lands to ones, but it's not really true. The information on a CD is encoded in a much more subtle way that uses complex and clever data encoding techniques, including eight-to-fourteen modulation (EFM) and non-return to zero inverted (NRZI) coding. That sounds extremely technical, but it's not too hard to understand. EFM essentially just means converting short patterns of data into longer ones (paradoxically) to store them more efficiently with less risk of error. NRZI means that instead of reading individual lands and pits, the laser is looking out for changes between a pit and a land, or long strings of pits and lands, and converting those into ones and zeros instead. So, for example, if it reads a long pit and suddenly comes across a land, that is interpreted as a one. If it reads a land and suddenly comes across a pit, that's also interpreted as a one. On the other hand, unchanging areas of land or pit are both interpreted as zeros.

Artwork: How pits and lands encode zeros and ones on a CD's surface. The transition from pit to land, or land to pit, encodes a one; a length of uninterrupted pit or land encodes a zero.

Why use these sorts of techniques instead of the simple "pit equals zero, land equals one" method I described above? It uses the disc space more efficiently (so we can pack more data on a disc), avoids the need for very short or long pits or lands, and minimizes the importance of bits that get lost due to scratches or dirt (so it helps correct against errors). Unless you're building your own CD player or monkeying around with data communication, you really don't need to know precisely how your data is stored on a CD or DVD, so if you want to think of pits being zeros and lands one, that's a perfectly good approximation to what's happening—and all most of us care to know. (For much more detail, check out the section on Data Encoding in The Compact Disc Handbook by Ken C. Pohlmann, from page 74 onward.)

Who invented CDs?

The technology behind CDs was invented in the late 1960s by James T. Russell (1931–). An avid music fan, he longed for a sound-recording system that would reproduce music more exactly than LP records and cassette tapes. He patented the first ever optical sound recording system in 1970, refining it over the years that followed. Audio CDs finally made their commercial debut in Europe in 1982, launched by the Sony and Philips electronics corporations, and appeared in the United States the following year. CD-ROMs became popular in the 1990s, when publishers such as Encyclopedia Britannica, Broderbund, and Dorling Kindersley released popular "multimedia" encyclopedias containing written text, sound, pictures, animations, and videos. CD-ROMs are less popular today, thanks to the World Wide Web (WWW), which makes it easier to publish and update information instantly and link together pages from lots of different sources.

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Find out more

On this website

• History of communication
• LP record players
• MP3 players

On other sites

• James T. Russell: A short biography from the Lemelson-MIT inventor program. (Archived page via the Wayback Machine.) There's also a brief biography on Wikipedia.
• How the CD was developed: This BBC News article from 2007 celebrates the 25th birthday of CD technology with a timeline explaining how the invention progressed.

Books

Technical

• Digital Audio Technology: A Guide to CD, MiniDisc, SACD, DVD(A), MP3 and DAT by Jan Maes, Marc Vercammen. Taylor & Francis, 2017. An up-to-date technical guide that covers some of the common principles of digital music, including sampling, compression, error correction, and so on.
• Blu-ray Disc Demystified by Jim Taylor et al. McGraw-Hill, 2009. A comprehensive introduction that covers the history of Blu-ray, the technology behind it, disc formats, and practical applications.
• The Book of Nero 7: CD and DVD Burning Made Easy by Wally Wang. No Starch Press, 2006. This covers everything you'd possibly want to know about CD and DVD burning, from storing files to designing attractive labels.
• The Compact Disc Handbook by Ken C. Pohlmann. A-R Publications, 1989/1992. A technical introduction to CD technology that explains the difference between analog and digital, the basics of digital audio, how CD players work (in much more detail than we go into here), the various CD formats, and how CDs are manufactured. It might seem a dated book now, but it's still very relevant and useful.
• The CD-ROM Handbook by Chris Sherman. Intertext Publications, 1994. Another old but very useful resource for CD-ROM developers.

General/historical

• How Music Got Free: The End of an Industry, the Turn of the Century, and the Patient Zero of Piracy by Stephen Witt. Penguin, 2015. How digital downloads spelled the end of the CD.
• America on Record: A History of Recorded Sound by Andre Millard. Cambridge University Press, 2005. Compares and contrasts the three eras of music: acoustical, electrical, and digital.

Articles

Practical tips

• Digitize Your CDs and Reclaim Your Closet by J. D. Biersdorfer. The New York Times, 9 February 2017. I'm not sure I necessarily agree with the advice here—CDs are better quality than MP3s—but it's worth considering if you're short of space.
• DVD Burning Tips: How to Avoid the Top Five Disc-Burning Mistakes by Jon L. Jacobi. PC World. 22 November 2006. Some simple but good advice that includes using the right disk, verifying a burn, and choosing the correct burn speed.
• Disc Goal: Pain-Free Burning by Wilson Rothman. The New York Times, 24 July 2003. A comparison of different burner software.
• Basics: Burn-Your-Own DVDs: First, Mind the Format by Wilson Rothman. The New York Times, 5 September 2002. A simple introduction to DVD burning.
• Sound: Brush aside the idea of painting CDs by Hans Fantel. The New York Times, 3 June 1990. An interesting article from the archive exploring the myth that painting CDs makes them last longer.

News

• Oh for the Days of the Making-Of Featurette—Seriously by Fabrice Robinet. The New York Times, April 6, 2018. Streaming movies have killed off DVD extras that helped film-makers learn their craft.
• How the compact disc lost its shine by Dorian Lynskey. The Guardian, May 28, 2015. A fascinating look at the rise and fall of the compact disc.
• Goodbye, DVD. Hello, Future. by Dave Kehr. The New York Times, March 4, 2011. Will services like Netflix and Amazon Video spell the end of DVDs?
• Blu-ray's Fuzzy Future by Matt Richtel and Brad Stone. The New York Times, January 5, 2009. What does the future hold for Blu-Ray?
• Compact disc hits 25th birthday: BBC News, 17 August 2007. Looking back on the first quarter century of the CD.
• Record Biz Has Burning Question by Brad King. Wired, 14 June 2002. Does it make more sense to allow some music sharing?
• At Last, CD Players That D-D-D-Don't Skip by Michael Marriott. The New York Times, 15 March 2000. Sony introduces anti-jump features, called "quick focus search" and "fine access," which stop CD players from jumping when they're bumped or jolted.

Patents

For much more technical detail, try:

• US Patent 4,512,006: Optical type information read/write apparatus by Teruo Murakami et al, Tokyo Shibaura Denki Kabushiki Kaisha. 16 April 1985.
• US Patent 5,161,150: Optical Recording Medium by Kenryo Namba, TDK Corporation. 3 November 1992.
• US Patent 5,060,221: Digital data recording/reproduction apparatus by Yoichiro Sako et al, Sony Corporation. 22 October 1991.