Quadraphonic (or Quadrophonic and sometimes Quadrasonic) sound – equivalent to what is now called 4.0 surround sound – uses four audio channels in which speakers are positioned at the four corners of a listening space. The system allows for the reproduction of sound signals that are (wholly or in part) independent of one another.
Four channel quadraphonic surround sound can be used to recreate the highly realistic effect of a three-dimensional live concert hall experience in the home. It can also be used to enhance the listener experience beyond the directional limitations of ordinary two channel stereo sound. Quadraphonic audio was the earliest consumer product in surround sound. Since it was introduced to the public in the early 1970s many thousands of quadraphonic recordings have been made.
Quadraphonic sound was a commercial failure when first introduced due to a variety of technical issues and format incompatibilities. Four channel audio formats can be more expensive to produce than standard two-channel stereo. Playback requires additional speakers and amplifier channels. It may also require specially designed decoding equipment.
The introduction of home cinema products in the 1990s were first intended for movie sound, but also brought multi-channel music reproduction into popularity again. By this time new digitally based formats had been created. Many four channel recordings from the 1970s have been reissued in modern surround sound systems such as Super Audio CD, DTS, Dolby Digital, DVD-Audio and Blu-ray. Multichannel home audio reproduction has experienced a revival since 2000 and new four channel recordings have also been released to the public since this time.
A quadraphonic system will reproduce left front, left rear, right front, and right rear audio signals in each of four separate speakers. Reproduction in the rear speakers should be of the same quality or almost the same quality as the front speakers. Ideally, it is preferred to use four identical speakers.
The first machines used for 4-channel sound recording were analog reel-to-reel tape recorders. These were developed for use by audio engineers in professional studios during the 1950s in Germany by Telefunken and also by Ampex in the United States. Such machines appeared in some European electronic-music studios by 1954, [ failed verification ] However, while four channel technology was used for this recording in the studio, it was never released to the public in quadraphonic sound, only in stereo.an early example was the tape part of Karlheinz Stockhausen's piece, Kontakte (1958–60).
Early attempts to reproduce four channel sound for home playback began with audio laboratory engineers in the 1960s. A small number of quadraphonic recordings were introduced to the American consumer market by Vanguard Records in June 1969 on reel-to-reel tape. The most popular medium used to market recordings to the public during the 1970s was the vinyl LP phonograph record. Quadraphonic recordings on 8-track tape were also popular in the 1970s, particularly among car audio enthusiasts.
In the 1970s specialized hardware systems were marketed by major electronic manufacturers to the public for decoding 4-channel recordings. These decoders were often sold as separate electronic components. Decoders were also available as built in features of some audio receivers or amplifiers sold during the 1970s.
Many quadraphonic recordings in the 1970s used "matrix" technologies to encode and decode 4-channels of audio information in a 2-channel medium, usually an LP. The poor decode performance of early matrix formats was the main reason for their disappearance once improved matrix systems arrived. The later matrix systems were based on work by Peter Scheiber. His basic formula utilized 90° phase-shift circuitry to enable enhanced 4-2-4 matrix systems to be developed, of which the two main leaders were Columbia's SQ and Sansui's QS Systems.
The 3 most popular quadraphonic LP formats in the 1970s were SQ (Stereo Quadraphonic), QS (Regular Matrix) and CD-4 (Compatible Discrete 4) / Quadradisc.
With Scheiber and Martin Willcocks, Jim Fosgate developed the Tate II 101 SQ decoder, which produced a very accurate sound field by using gain riding and the Haas effect to mask decoding artifacts. It used custom, hand-assembled and ‑calibrated circuitry with components sorted to 1%, for exact performance. Sansui's QSD-series decoders and QRX-series receivers were very good, even synthesizing left-right stereo into a ⋂ horseshoe topology. However, all these came too late in the game and were too expensive or difficult to procure for public purchase, to rescue matrix quad.
By the early 2000s more sophisticated "discrete" multichannel systems had mostly replaced matrix technologies, while providing a higher level of performance and full channel independence.
Today, software can be used to take the place of hardware decoding. Modern software algorithms are capable of more accurate decoding performance than the earlier hardware technologies.
All of the multichannel audio systems in common use today are digital systems. Digital multichannel audio has been available for the home starting with the introduction of surround sound movies using Dolby Digital and DTS in the 1990s. The most common digital media capable of reproducing surround sound music today are Super Audio CD, DVD, and Blu-ray. All of these are capable of playing high-resolution audio with multiple channels.
Quadraphonic audio reproduction on vinyl phonograph records was problematic. As technologies advanced rapidly during the 1970s several different solutions were proposed to reproduce 4 channel sound from LPs. Some of these systems were much more successful than others. The simplest systems were "derived" (2-2-4) formats. These were soon followed by much more sophisticated "matrix" (4-2-4) formats, and finally, by the most advanced "discrete" (4-4-4) formats.
Derived (2-2-4) formats are simple and inexpensive electronic solutions that add or extract rear "ambience" or "reverberation" sound channels from stereo records. There is no precise placement of individual instruments in the rear channels.
With matrix formats four channels are converted (encoded) down to two channels. These are then passed through a two-channel transmission medium (usually an LP record) before being decoded to four channels and presented to four speakers. To transmit four individual audio signals in a stereo-compatible manner, there must be four simultaneous linear equations to reproduce the original four audio signals at the output.
These systems used matrix decoding technology to recover four channels from the two channels recorded on the record. Matrix systems can have a significant level of channel independence but not full channel separation.
Matrix quadraphonic recordings can be played in two channels on conventional stereo record players. There are varying levels of stereo and mono compatibility in these systems. The term compatible indicates that:
This 4:2:4 process could not be accomplished without some information loss. That is to say, the four channels produced at the final stage were not truly identical to those with which the process had begun. In order for the effect to work as intended a recording engineer needed to be specially trained for working in each of these formats. Special mixing rules for matrix recording minimize the technological limitations inherent in matrix formats and mask or eliminate undesired side effects.
The first of these were basic systems with relatively poor performance developed by Electro-Voice ( EV-4/Stereo-4 ) and Dynaco ( Dynaquad (DY) ). A so-called matrix format, it utilized four sound channels which were "encoded" into two stereo album tracks. These were then "decoded" into the original four sound channels. But with poor decode performance, these systems failed to match the accuracy or channel independence of later matrix formats.
The original systems (DY and EV-4) suffered from low front left-right separation (around 12 dB) and a poor rear left-right separation of 2 dB. The decoders were designed more to give an effect rather than accurate decoding, which was mainly due to limitations in both systems. Since both systems were very closely related mathematically, users only needed one decoder of either system to playback albums of both systems.
The differences between the early and late matrix systems were so vast, it made decoding DY/EV-4 with either SQ or QS decoders with accuracy impossible; the results often being a "smeared" or poorly defined sound stage, which could be vastly different from what was intended by the producer or recording engineer.
Improved systems based on Peter Scheiber's work on utilizing 90-degree phase-shift circuitry came later, namely the QS and SQ systems.
The first of these, known as QS, was developed by Sansui Electric. A so-called matrix format, it utilized 4 sound channels, which were "encoded" into two stereo album tracks. These were then "decoded" into the original four sound channels. The QS system debuted in the United States in March 1971 and was improved by their Vario-Matrix system in 1973.[ citation needed ]
The second, SQ, was developed and marketed by Columbia Records and Sony and entered the US market in April 1971. The SQ format was also used by companies such as EMI in Great Britain, who pressed several SQ album releases. The sound separation of the SQ system was greatly improved by the introduction of SQ Full Logic decoding in 1975 using the Motorola chips MC1312, MC1314 & MC1315.[ citation needed ]
Both SQ and QS had significant support from major record companies and hardware manufacturers during the 1970s. They also achieved notable sales and market penetration. Unfortunately, due to the similarities in name and technology these could easily be confused by the public.
Discrete reproduction describes a quadraphonic system in which all four channels are fully independent of each other. As its name suggests, with discrete formats the original four audio channels are passed through a four-channel transmission medium and presented to a four-channel reproduction system and fed to four speakers. This is defined as a 4–4–4 system.
Discrete phonograph systems use a specialized demodulator to decode four fully independent sound channels. This allowed for full channel separation. Such systems could be prone to reduced record life. However, more durable vinyl formulations were quickly developed to work around this problem and nearly all discrete LPs use special vinyl. When discrete quadraphonic LPs are played on conventional stereo record players the entire music program can be heard in stereo.
The third major format for four-channel vinyl LPs, known as CD-4 or Quadradisc , was devised by the Japanese JVC Corporation along with its US counterpart RCA Records.
This quadraphonic format was first marketed in the United States in May 1972. A fully discrete system, it eschewed matrix technologies in favor of a more sophisticated method.[ citation needed ] As with stereo records, the system uses 2 main left and right audio channels, and this is what allows CD-4 to maintain compatibility with conventional stereo playback. CD-4 also adds 2 additional "difference" audio channels to the main channels. The difference signals are encoded in ultrasonic carrier frequencies in the range of 30 kHz, which is above the audible range. CD-4 requires a specialized phono cartridge with a "Shibata" stylus to read these additional high frequencies. The combined signals are then sent to a special demodulator for 4 channel decoding. The demodulator converts the ultrasonic signals back into the audible range and uses the difference channels to separate rear audio information from the main channels. Because the CD-4 system maintains 4 independent signals throughout the process it can accurately reconstruct the intended 4 channel sound field.
UD-4/UMX was developed by Nippon/Columbia (Denon). This is a hybrid discrete/matrix system. Only 35 to 40 items are encoded in this format and it was marketed only in the UK, Europe, and Japan.
The short-lived system suffered from incompatibility with regular stereo playback due to phase differences between the left and right channels.UD-4 was less critical in its setup than CD-4 because the carriers did not have to handle frequencies as high as those found in the CD-4 system.
Quadraphonic systems based on tape were also introduced, based on new equipment capable of playing four discrete channels. These recordings are all discrete 4-4-4 recordings released in reel-to-reel and 8-track cartridge formats. Specially designed four channel machines were required to play these recordings. They are not compatible with stereo players.
In these systems all four available tracks were recorded on the tape running in the same direction. Pre-recorded 4 channel reel-to-reel tapes were recorded at 7 and 1/2 inches per second (IPS), which is the fastest speed used for consumer grade reel-to-reel machines. By comparison stereo pre-recorded reel-to-reel tapes have 2 different programs with each running the opposite direction. Many stereo tapes were recorded at only 3 and 3/4 IPS, which is half of the full speed. The slower speed results in significantly poorer sound quality.
RCA Records followed, in April 1970, with its announcement of a four-channel version of the 8-track tape, named Quad-8 or Quadraphonic 8-Track Tape (later shortened to just Q8). These eventually appeared in Sept. 1970.There were automobile players as well as home versions.
The format was almost identical in appearance to stereo 8-tracks, except for a small sensing notch in the upper left corner of the cartridge. This signaled a quadraphonic 8-track player to combine the odd tracks as audio channels for program 1, and the even tracks as channels for program 2. The format was not backward-compatible with stereo or mono players; although quadraphonic players would play stereo 8-tracks, playing quadraphonic tapes on stereo players resulted in hearing only one-half the channels at a time.
The last release in the quadraphonic 8-track format was in 1978, although most had stopped appearing by the end of 1976.
There were some experiments done with radio broadcasts (e.g., a Cliff Richard concert by the BBC,whose earliest quadraphonic broadcast was in July 1974 ), but they were short-lived.
One radio series, Double Exposure, was briefly syndicated throughout the United States to various FM stations; it was made up of jazz, rock and pop music which had been commercially released in one of the quadraphonic record or tape systems.
One of the longest-lived radio broadcasts was WQSR-FM "Quad 102½" in Sarasota, Florida.Throughout most of the 1970s this station broadcast a signal which could be tuned as two separate stations with conventional stereo receivers.
San Francisco classical music station KKHI-FM broadcast the San Francisco Opera in "compatible" (that is, matrix-encoded) quadraphonic format during the 1970s,as did Chicago station WFMT's live "Chicago Lyric Opera" broadcasts.
KRMH-FM ("Good Karma Radio")(San Marcos/Austin, Texas) broadcast in "Quad Stereo" in the early 1970s from its studios and transmitter near Buda, Texas.[ citation needed ]
WWWW-FM (W4-QUAD 106.7) (Detroit) broadcast quadraphonic sound in 1974. It also referred to itself as "Quadzilla". Howard Stern was a DJ at W4 early in his career.
KEXL-FM ("KEXL 104.5") (San Antonio, Texas) broadcast in "Quadraphonic" in the early to mid 1970s from its studios in a high-rise office building off Main Plaza.
Sacramento station KWOD 106.5, named after the format, broadcast briefly beginning in 1977.
Regional station of Polskie Radio in Wroclaw had two experimental broadcasts a week at the end of the 1970.
Matrix H was developed by BBC engineers in 1977 to carry quadraphonic sound via FM radio in a way which would be most compatible with existing mono and stereo receivers.
Quadraphonic test programmes were made for BBC Radio 3 and BBC Radio 4, including plays and The Proms.
The existing matrix formats were tested first. The "H" has no meaning; they called the first matrix assessed Matrix A, and then worked through the alphabet.Matrix H emerged as the best solution for mono compatibility and radio transmission, yet there was no specific commercially available decoder for it.
The BBC later cooperated with the developers of Ambisonics to produce BBC/NRDC System HJ. This was based on tolerance zones designed to include modified versions of both Matrix H and the prototype two-channel encoding of Ambisonics, known as System 45J. Subsequently, the Nippon-Columbia UMX matrix was brought into the standard, leading to the final UHJ name now associated with Ambisonics.
In 1976, Ben Bauer integrated matrix and discrete systems into USQ, or Universal SQ (others had also done this with their quad systems).
It was a hierarchical 4-4-4 discrete matrix which used the SQ matrix as the baseband for discrete quadraphonic FM broadcasts using additional difference signals called "T" and "Q". For a USQ FM broadcast, the additional "T" modulation was placed at 38 kHz in quadrature to the standard stereo difference signal and the "Q" modulation was placed on a carrier at 76 kHz.
For standard two-channel SQ Matrix broadcasts, CBS recommended that an optional pilot-tone be placed at 19 kHz in quadrature to the regular pilot-tone to indicate SQ encoded signals and activate the listener's logic decoder. CBS argued that the SQ system should be selected as the standard for quadraphonic FM because, in FCC listening tests of the various four-channel broadcast proposals, the 4:2:4 SQ system, decoded with a CBS Paramatrix decoder, outperformed 4:3:4 (without logic) as well as all other 4:2:4 (with logic) systems tested, approaching the performance of a discrete master tape within a very slight margin. At the same time, the SQ "fold" to stereo and mono was preferred to the stereo and mono "fold" of 4:4:4, 4:3:4 and all other 4:2:4 encoding systems.
In 1967 the rock group Pink Floyd performed the first-ever surround-sound rock concert at “Games for May”, a lavish affair at London’s Queen Elizabeth Hall, where the band debuted its custom-made quadraphonic speaker system.The control device they had made, the Azimuth Co-ordinator, is now displayed at London's Victoria and Albert Museum, as part of their Theatre Collections gallery.
In 1976, Mike Thorne created the vinyl album Quadrafile , with the same music recorded on all four sides, but in four different quadraphonic formats (QS, SQ, CD-4, and UD-4).
Dolby Digital, originally synonymous with Dolby AC-3, is the name for what has now become a family of audio compression technologies developed by Dolby Laboratories. Originally named Dolby Stereo Digital until 1995, except for Dolby TrueHD, the audio compression is lossy, based on the modified discrete cosine transform (MDCT) algorithm. The first use of Dolby Digital was to provide digital sound in cinemas from 35 mm film prints; today, it is now also used for applications such as TV broadcast, radio broadcast via satellite, digital video streaming, DVDs, Blu-ray discs and game consoles.
The 8-track tape is a magnetic-tape sound recording technology that was popular from the mid-1960s to the early 1980s, when the Compact Cassette tape, which predated 8-track, surpassed it in popularity for pre-recorded music. The format is obsolete and was relatively unknown outside the United States, the United Kingdom, Canada, New Zealand, Australia, Mexico, Spain, France, Germany, Italy, Sweden and Japan. The main advantage of the 8-track tape cartridge is that it does not have to be "flipped over" to play the alternative set of tracks.
Dolby Pro Logic is a surround sound processing technology developed by Dolby Laboratories, designed to decode soundtracks encoded with Dolby Surround.
Dolby Laboratories, Inc. is an American company specializing in audio noise reduction and audio encoding/compression. Dolby licenses its technologies to consumer electronics manufacturers.
Matrix decoding is an audio technology where a small number of discrete audio channels are decoded into a larger number of channels on play back. The channels are generally, but not always, arranged for transmission or recording by an encoder, and decoded for playback by a decoder. The function is to allow multichannel audio, such as quadraphonic sound or surround sound to be encoded in a stereo signal, and thus played back as stereo on stereo equipment, and as surround on surround equipment – this is "compatible" multichannel audio.
DTS, Inc. is an American company that makes multichannel audio technologies for film and video. Based in Calabasas, California, the company introduced its DTS technology in 1993 as a competitor to Dolby Laboratories, incorporating DTS in the film Jurassic Park (1993). The DTS product is used in surround sound formats for both commercial/theatrical and consumer-grade applications. It was known as The Digital Experience until 1995. DTS licenses its technologies to consumer electronics manufacturers.
Dolby Stereo is a sound format made by Dolby Laboratories. There are two basic Dolby Stereo systems: the Dolby SVA 1976 system used with optical sound tracks on 35mm film, and Dolby Stereo 70mm which refers to Dolby noise reduction on 6-channel magnetic soundtracks on 70mm prints.
Lotus is a 1974 live album by the Latin rock band Santana, recorded at the Osaka Kōsei Nenkin Kaikan, Osaka, Japan in July 1973, during their Caravanserai Tour. The Welcome album recording sessions were completed shortly before this concert, and that album was later released in November. Lotus was originally released in 1974 as a triple vinyl LP in Japan only. This version of the album was later released internationally.
Ambisonic UHJ format is a development of the Ambisonic surround sound system designed to be compatible with mono and stereo media. It is a hierarchy of systems in which the recorded soundfield will be reproduced with a degree of accuracy that varies according to the available channels. Although UHJ permits the use of up to four channels, only the 2-channel variant is in current use. In Ambisonics, UHJ is also known as "C-Format".
SQ Quadraphonic was a matrix 4-channel quadraphonic sound system for vinyl LP records. It was introduced by CBS Records in 1971. Many recordings using this technology were released on LP during the 1970s.
Quadrafile was an LP recording released in 1976 intended as a demonstration of four different systems of quadraphonic sound reproduction on phonograph records.
Peter Scheiber is considered to be the originator of the matrix format, a basic mathematical formula used to convert four channels into two which is what most matrix four channel systems are based on. He is also a musician and audio engineer.
Quadraphonic Sound was a matrix 4-channel quadraphonic sound system for phonograph records. The system was based on technology created by Peter Scheiber, but further developed by engineer Ryosuke Ito of Sansui in the early 1970s.
Compatible Discrete 4, also known as Quadradisc or CD-4 was as a discrete four-channel quadraphonic system for phonograph records. The system was created by JVC and RCA in 1971 and introduced in May 1972. Many recordings using this technology were released on LP during the 1970s.
The Hafler circuit is a passive electronics circuit with the aim of getting derived surround sound or ambiophony from regular stereo recordings without using costly electronics. Such circuits are generally known as matrix decoders. The Dynaquad system works using similar principles.
Stereo-4, also known as EV or EV-4, was a matrix 4-channel quadraphonic sound system developed in 1970 by Leonard Feldman and Jon Fixler.
Dynaquad, or DY, was a matrix decoder 4-channel quadraphonic sound system developed by Dynaco in 1969.
UD-4 was a discrete four-channel quadraphonic sound system for phonograph records introduced by Nippon Columbia (Denon) in 1974. This system had some similarities with the more successful CD-4 process introduced by JVC and RCA in 1972.
Matrix H was developed by BBC engineers in the late 1970s to carry quadraphonic sound via FM radio in a way that would be most compatible with existing mono and stereo receivers.
Quadraphonic open reel tape or Q4 was the first consumer format for quadraphonic sound recording and playback. Pre-recorded tapes in this format were introduced in the United States by the Vanguard Recording Society in June 1969. Specialized machines to play these tapes were introduced by electronics manufacturers such as TEAC Corporation at about the same time.