Difference between revisions of "Laser turntable"

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[[File:Elp-lt-2xnp.jpg|right]]
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[[File:Goldlt-1200px2.jpg|400px|right|thumb|ELP (Edison Laser Player)]]
A '''laser turntable''' is a [[phonograph]] that plays [[gramophone record]]s using a laser beam as the [[Phonograph#Pickup_systems|pickup]] instead of a conventional diamond-tipped [[stylus]]. This playback system has the unique  advantage of avoiding physical contact with the record during playback; instead, a focused beam of light traces the signal undulations in the vinyl, with zero friction, mass and record wear. Vinyl LPs played with a laser playback system can theoretically "last forever" as there is no deterioration caused by passing a stylus through the grooves.
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A '''laser turntable''' is a [[Wikipedia:en:phonograph|phonograph]] that plays [[Wikipedia:en:gramophone record|gramophone record]]s using a laser beam as the [[Wikipedia:en:Phonograph#Pickup_systems|pickup]] instead of a conventional diamond-tipped [[Wikipedia:en:stylus|stylus]]. This playback system has the unique  advantage of avoiding physical contact with the record during playback; instead, a focused beam of light traces the signal undulations in the vinyl, with zero friction, mass and record wear. Vinyl LPs played with a laser playback system can theoretically "last forever" as there is no deterioration caused by passing a stylus through the grooves.
  
Current laser turntables can play most varieties of phonograph records (45s, 33.3 [[LP album|LPs]], or 78s), and play them with high fidelity. Although quite expensive, they are favored by the record libraries and radio stations for archival use and transcription to digital media.
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Current laser turntables can play most varieties of phonograph records (45s, 33.3 [[Wikipedia:en:LP album|LPs]], or 78s), and play them with high fidelity. Although quite expensive, they are favored by the record libraries and radio stations for archival use and transcription to digital media.
  
 
== History ==
 
== History ==
The laser turntable was first conceived by Robert S. Reis, a graduate student at [[Stanford University]] (his master's thesis was [http://senderogroup.com/text/reis.htm "An Optical Turntable"]). In 1983 Reis and fellow Stanford engineer Robert E. Stoddard founded Finial Technology with $7 million in [[venture capital]]. A year later servo-control expert [[The Bobs|Robert N. Stark]] joined the effort. A non-functioning mock-up of the optical turntable was shown at the 1984 [[Consumer Electronics Show]] (CES), generating much interest and a fair amount of mystery, since the patents had not yet been granted and the details had to be kept secret. The first working model, the Finial LT-1, was completed two years later and presented at the 1986 CES. The prototype had an interesting flaw: it was so accurate that it played every particle of dirt and dust on the record, rather than pushing them aside as a conventional stylus would. The projected $2500 street price (raised to $3786 in 1988) limited the potential market to serious well-heeled audiophiles.
+
The laser turntable was first conceived by Robert S. Reis, a graduate student at [[Wikipedia:en:Stanford University|Stanford University]] (his master's thesis was "An Optical Turntable"). In 1983 Reis and fellow Stanford engineer Robert E. Stoddard founded Finial Technology with $7 million in [[Wikipedia:en:venture capital|venture capital]]. A year later servo-control expert [[Wikipedia:en:The Bobs|Robert N. Stark]] joined the effort. A non-functioning mock-up of the optical turntable was shown at the 1984 [[Wikipedia:en:Consumer Electronics Show|Consumer Electronics Show]] (CES), generating much interest and a fair amount of mystery, since the patents had not yet been granted and the details had to be kept secret. The first working model, the Finial LT-1, was completed two years later and presented at the 1986 CES. The prototype had an interesting flaw: it was so accurate that it played every particle of dirt and dust on the record, rather than pushing them aside as a conventional stylus would. The projected $2500 street price (raised to $3786 in 1988) limited the potential market to serious well-heeled audiophiles.
  
Unfortunately for Finial, its project coincided with the introduction of the Digital [[CD|Compact Disc]], which began flooding the market at prices comparable to LPs (with CD players in the $300 range). Vinyl record sales plummeted, and many turntable manufacturers failed as a result.
+
Unfortunately for Finial, its project coincided with the introduction of the Digital [[Wikipedia:en:CD|Compact Disc]], which began flooding the market at prices comparable to LPs (with CD players in the $300 range). Vinyl record sales plummeted, and many turntable manufacturers failed as a result.
  
The Finial turntable never went into mass production. Tooling delays, component unavailability (in the days before cheap lasers), marketing blunders, and high development costs prevented it. With over US$20 million in venture capital invested, Finial was faced with a [[Morton's Fork|Morton's fork]]: to forge ahead with a selling price that was too high for most consumers, or to gamble on going into mass production at a much lower price at the very moment the bottom was dropping out of the market and the economy was in recession. In late 1989 Finial's investors finally succumbed to their unfortunate timing and liquidated the firm, selling the patents to Japanese turntable maker [[BSR]], which became [[CTI Japan]] which in turn created [[ELPJ|ELP Japan]] for continued development of the "super-audiophile" turntable. It was finally put on sale in 1997 as the ELP LT-1XA Laser Turntable, with a list price of US$20,500 prices start at US$10,000). The device was marketed especially as a tool for professional customers such as radio stations that wished to digitize their vinyl stock during the transition to an all-digital environment.
+
The Finial turntable never went into mass production. Tooling delays, component unavailability (in the days before cheap lasers), marketing blunders, and high development costs prevented it. With over US$20 million in venture capital invested, Finial was faced with a [[Wikipedia:en:Morton's Fork|Morton's fork]]: to forge ahead with a selling price that was too high for most consumers, or to gamble on going into mass production at a much lower price at the very moment the bottom was dropping out of the market and the economy was in recession. In late 1989 Finial's investors finally succumbed to their unfortunate timing and liquidated the firm, selling the patents to Japanese turntable maker, which became CTI Japan which in turn created [[Wikipedia:en:ELPJ|ELP Japan]] for continued development of the "super-audiophile" turntable. It was finally put on sale in 1997 as the ELP LT-1XA Laser Turntable, with a list price of US$20,500 prices start at US$10,000). The device was marketed especially as a tool for professional customers such as radio stations that wished to digitize their vinyl stock during the transition to an all-digital environment.
  
The US [[Library of Congress]] and other US agencies are sponsoring projects to develop two-dimensional (IRENE) and three-dimensional scanners to recover audio information from mechanical recordings. These are [[bespoke]] machines intended to recover historical recordings, rather than intended commercial products.
+
The US [[Wikipedia:en:Library of Congress|Library of Congress]] and other US agencies are sponsoring projects to develop two-dimensional (IRENE) and three-dimensional scanners to recover audio information from mechanical recordings. These are [[Wikipedia:en:bespoke|bespoke]] machines intended to recover historical recordings, rather than intended commercial products.
  
 
== ELPJ laser turntable: technical details ==
 
== ELPJ laser turntable: technical details ==
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* The laser pickup uses five beams—one on each channel to track the sides of the groove, one on each channel to pick up the sound (just below the tracking beams), and a fifth to track the surface of the record and keep the pickup at a constant height, which allows for record thickness and warping.
 
* The laser pickup uses five beams—one on each channel to track the sides of the groove, one on each channel to pick up the sound (just below the tracking beams), and a fifth to track the surface of the record and keep the pickup at a constant height, which allows for record thickness and warping.
 
* The lasers focus on a section of the groove above the level where a conventional stylus will have traveled, and below the typical depth of surface scratches, giving the possibility of like-new reproduction even from worn or scratched records.
 
* The lasers focus on a section of the groove above the level where a conventional stylus will have traveled, and below the typical depth of surface scratches, giving the possibility of like-new reproduction even from worn or scratched records.
* The pickup output is [[analog electronics|analogue]]: the signal path is never [[digitized]].
+
* The pickup output is [[Wikipedia:en:analogue electronics|analogue]]: the signal path is never [[Wikipedia:en:Digitizing|digitized]].
* Using a laser pickup eliminates many problems associated with physical styli: record wear, horizontal tracking angle error, [[rumble measurement|turntable rumble]], leveling adjustment inaccuracies, inner groove distortion, channel-balance error, stereo [[crosstalk]], anti-skating compensation, [[acoustic feedback]], skipping, locked-groove problems, problems tracking warped, cracked, or eccentric records and cartridge hum pickup.
+
* Using a laser pickup eliminates many problems associated with physical styli: record wear, horizontal tracking angle error, [[Wikipedia:en:rumble measurement|turntable rumble]], leveling adjustment inaccuracies, inner groove distortion, channel-balance error, stereo [[Wikipedia:en:Crosstalk (electronics)|crosstalk]], anti-skating compensation, [[Wikipedia:en:Audio feedback|acoustic feedback]], skipping, locked-groove problems, problems tracking warped, cracked, or eccentric records and cartridge hum pickup.
 +
[[File:Elp-rme-02.jpg|200px|thumb|right|Digitizing: ELP Laser turntable and RME Fireface 800]]
 
* The laser turntable is extraordinarily sensitive to record cleanliness and will play exactly what it sees—a speck of dirt is treated as if it were part of the record surface.
 
* The laser turntable is extraordinarily sensitive to record cleanliness and will play exactly what it sees—a speck of dirt is treated as if it were part of the record surface.
 
* When an LP is inserted into the tray drawer and the drawer closed, the turntable reads the surface of the LP, displaying the number of tracks. Users can then program which tracks to play, or repeat, much as a CD player operates.
 
* When an LP is inserted into the tray drawer and the drawer closed, the turntable reads the surface of the LP, displaying the number of tracks. Users can then program which tracks to play, or repeat, much as a CD player operates.
* The [[laser diode]] has a typical life of 10,000 hours of use, compared to the 500 hours of playback recommended for a diamond stylus or 50 hours for a sapphire one.
+
* The [[Wikipedia:en:laser diode|laser diode]] has a typical life of 10,000 hours of use, compared to the 500 hours of playback recommended for a diamond stylus or 50 hours for a sapphire one.
 
* Versions of the ELPJ laser turntable will play back analogue disc records at any speed from 30 to 90 RPM (+/- 0.1 RPM) and of any size from.
 
* Versions of the ELPJ laser turntable will play back analogue disc records at any speed from 30 to 90 RPM (+/- 0.1 RPM) and of any size from.
 
* The record must be black; coloured, transparent or translucent records cannot be played<ref>[http://www.elpj.com/customer/qa.html ELP FAQ]</ref>.
 
* The record must be black; coloured, transparent or translucent records cannot be played<ref>[http://www.elpj.com/customer/qa.html ELP FAQ]</ref>.
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== External links ==
 
== External links ==
*[http://www.elpj.com/about/ ELPJ - About the laser turntable]
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* [http://www.elpj.com/about/ ELPJ - About the laser turntable]
 
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* [http://www.elpj.com/about/history.php History of the Laser turntable and ELP Corporation]
  
 
[[Category:1986 introductions]]
 
[[Category:1986 introductions]]

Latest revision as of 22:25, 23 February 2022

ELP (Edison Laser Player)

A laser turntable is a phonograph that plays gramophone records using a laser beam as the pickup instead of a conventional diamond-tipped stylus. This playback system has the unique advantage of avoiding physical contact with the record during playback; instead, a focused beam of light traces the signal undulations in the vinyl, with zero friction, mass and record wear. Vinyl LPs played with a laser playback system can theoretically "last forever" as there is no deterioration caused by passing a stylus through the grooves.

Current laser turntables can play most varieties of phonograph records (45s, 33.3 LPs, or 78s), and play them with high fidelity. Although quite expensive, they are favored by the record libraries and radio stations for archival use and transcription to digital media.

History

The laser turntable was first conceived by Robert S. Reis, a graduate student at Stanford University (his master's thesis was "An Optical Turntable"). In 1983 Reis and fellow Stanford engineer Robert E. Stoddard founded Finial Technology with $7 million in venture capital. A year later servo-control expert Robert N. Stark joined the effort. A non-functioning mock-up of the optical turntable was shown at the 1984 Consumer Electronics Show (CES), generating much interest and a fair amount of mystery, since the patents had not yet been granted and the details had to be kept secret. The first working model, the Finial LT-1, was completed two years later and presented at the 1986 CES. The prototype had an interesting flaw: it was so accurate that it played every particle of dirt and dust on the record, rather than pushing them aside as a conventional stylus would. The projected $2500 street price (raised to $3786 in 1988) limited the potential market to serious well-heeled audiophiles.

Unfortunately for Finial, its project coincided with the introduction of the Digital Compact Disc, which began flooding the market at prices comparable to LPs (with CD players in the $300 range). Vinyl record sales plummeted, and many turntable manufacturers failed as a result.

The Finial turntable never went into mass production. Tooling delays, component unavailability (in the days before cheap lasers), marketing blunders, and high development costs prevented it. With over US$20 million in venture capital invested, Finial was faced with a Morton's fork: to forge ahead with a selling price that was too high for most consumers, or to gamble on going into mass production at a much lower price at the very moment the bottom was dropping out of the market and the economy was in recession. In late 1989 Finial's investors finally succumbed to their unfortunate timing and liquidated the firm, selling the patents to Japanese turntable maker, which became CTI Japan which in turn created ELP Japan for continued development of the "super-audiophile" turntable. It was finally put on sale in 1997 as the ELP LT-1XA Laser Turntable, with a list price of US$20,500 prices start at US$10,000). The device was marketed especially as a tool for professional customers such as radio stations that wished to digitize their vinyl stock during the transition to an all-digital environment.

The US Library of Congress and other US agencies are sponsoring projects to develop two-dimensional (IRENE) and three-dimensional scanners to recover audio information from mechanical recordings. These are bespoke machines intended to recover historical recordings, rather than intended commercial products.

ELPJ laser turntable: technical details

    • LT-1LRC - US$12,000 - 33, 45 - 7", 10", 12"
    • LT-1XRC - US$15,300 - 33, 45, 78 - 7", 10", 12"
    • LT-2XRC - US$16,400 - 33, 45, 78 - 7", 8", 9", 10", 11", 12"
  • The laser pickup uses five beams—one on each channel to track the sides of the groove, one on each channel to pick up the sound (just below the tracking beams), and a fifth to track the surface of the record and keep the pickup at a constant height, which allows for record thickness and warping.
  • The lasers focus on a section of the groove above the level where a conventional stylus will have traveled, and below the typical depth of surface scratches, giving the possibility of like-new reproduction even from worn or scratched records.
  • The pickup output is analogue: the signal path is never digitized.
  • Using a laser pickup eliminates many problems associated with physical styli: record wear, horizontal tracking angle error, turntable rumble, leveling adjustment inaccuracies, inner groove distortion, channel-balance error, stereo crosstalk, anti-skating compensation, acoustic feedback, skipping, locked-groove problems, problems tracking warped, cracked, or eccentric records and cartridge hum pickup.
Digitizing: ELP Laser turntable and RME Fireface 800
  • The laser turntable is extraordinarily sensitive to record cleanliness and will play exactly what it sees—a speck of dirt is treated as if it were part of the record surface.
  • When an LP is inserted into the tray drawer and the drawer closed, the turntable reads the surface of the LP, displaying the number of tracks. Users can then program which tracks to play, or repeat, much as a CD player operates.
  • The laser diode has a typical life of 10,000 hours of use, compared to the 500 hours of playback recommended for a diamond stylus or 50 hours for a sapphire one.
  • Versions of the ELPJ laser turntable will play back analogue disc records at any speed from 30 to 90 RPM (+/- 0.1 RPM) and of any size from.
  • The record must be black; coloured, transparent or translucent records cannot be played[1].
  • ELP state that they had sold 1300 units by 2007

References

  1. ELP FAQ

External links