IRENE (technology)

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IRENE (Image, Reconstruct, Erase Noise, Etc.) is a digital imaging technology designed to recover analog audio stored on fragile or deteriorating phonograph cylinders, records, and other grooved audio media. It is in use by several archives and preservation institutions in the United States seeking to preserve and digitize historical audio.

Contents

History

The technology was developed at Lawrence Berkeley National Laboratory by Carl Haber and Vitaliy Fadeyev and was announced in a publication of the Journal of the Audio Engineering Society in 2003. [1] It grew out of Haber's research in particle physics; in the 1990s, he had worked on Higgs boson detection experiments, and realized that the cameras he was using to set the detectors could also be used for detailed imaging of grooved audio recordings. [2] The name IRENE is a backronym of the phrase "Image, Reconstruct, Erase Noise, Etc.", and was chosen because the first audio recovered by the system was a recording of the song "Goodnight, Irene" by The Weavers. [3] By 2005, Haber and Fadeyev had developed two-dimensional and three-dimensional machines, capable of recovering audio from vertically-cut and laterally-cut grooved media. [4] Soon after, Haber and Fadeyev were contacted by the Library of Congress, which began operating its own machine in 2006. [5] [6] In 2013, Haber was awarded a MacArthur Fellowship to continue development of the system. [7] As of 2020, IRENE machines are operated by three institutions – Lawrence Berkeley National Laboratory, the Library of Congress, [3] and the Northeast Document Conservation Center. [8]

Design and operation

The IRENE system uses a high-powered confocal microscope that follows the groove path as the disc or cylinder (i.e. phonograph cylinder) rotates underneath it, thereby obtaining detailed images of the audio information. [9] Depending on whether the groove is cut laterally, vertically, or in a V-shape, the system may make use of tracking lasers or different lighting strategies to make the groove visible to the camera. The resulting images are then processed with software that converts the movement of the groove into a digital audio file. [10]

An advantage of the system over traditional stylus playback is that it is contactless, and so avoids damaging the audio carrier or wearing out the groove during playback. [1] It also allows for the reconstruction of already broken or damaged media such as cracked cylinders or delaminating lacquer discs, which cannot be played with a stylus. Media played on machines which are no longer produced can also be recovered. [6] Many skips or damaged areas can be reconstituted by IRENE without the noises that would be created by stylus playback. [5] However, it can also result in the reproduction of more noise, as imperfections in the groove are also more finely captured than with a stylus.

Uses

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Au clair de la lune
Earliest recognizable recording of human voice, from 9 April 1860, converted into sound by IRENE [11] [12]
Au clair de la lune
The recording slowed down to match what is now believed to be the correct speed; the result reveals a man's voice, presumably Scott's. [13]
Problems playing these files? See media help.

The IRENE system has been used to recover audio such as:

See also

Related Research Articles

<span class="mw-page-title-main">Phonograph</span> Device for the analogue recording of sound

A phonograph, in its later forms also called a gramophone or since the 1940s called a record player, or more recently a turntable, is a device for the mechanical and analogue recording and reproduction of sound. The sound vibration waveforms are recorded as corresponding physical deviations of a spiral groove engraved, etched, incised, or impressed into the surface of a rotating cylinder or disc, called a "record". To recreate the sound, the surface is similarly rotated while a playback stylus traces the groove and is therefore vibrated by it, very faintly reproducing the recorded sound. In early acoustic phonographs, the stylus vibrated a diaphragm which produced sound waves which were coupled to the open air through a flaring horn, or directly to the listener's ears through stethoscope-type earphones.

<span class="mw-page-title-main">Phonograph cylinder</span> Medium for recording and reproducing sound

Phonograph cylinders are the earliest commercial medium for recording and reproducing sound. Commonly known simply as "records" in their era of greatest popularity, these hollow cylindrical objects have an audio recording engraved on the outside surface, which can be reproduced when they are played on a mechanical cylinder phonograph. In the 1910s, the competing disc record system triumphed in the marketplace to become the dominant commercial audio medium.

<span class="mw-page-title-main">Phonograph record</span> Disc-shaped analog sound storage medium

A phonograph record, a vinyl record, or simply a record is an analog sound storage medium in the form of a flat disc with an inscribed, modulated spiral groove. The groove usually starts near the periphery and ends near the center of the disc. For about half a century, the discs were commonly made from shellac, with earlier records having a fine abrasive filler mixed in. Starting in the 1940s polyvinyl chloride became common, the "vinyl records" of the late 20th century.

<span class="mw-page-title-main">Pathé Records</span> French record label

Pathé Records was an international record company and label and producer of phonographs, based in France, and active from the 1890s through the 1930s.

<span class="mw-page-title-main">Blue Amberol Records</span> Record label

Blue Amberol Records was the trademark name for cylinder records manufactured by Thomas A. Edison, Inc. in the US from 1912 to 1929. They replaced the 4-minute black wax Amberol cylinders introduced in 1908, which had replaced the 2-minute wax cylinders that had been the standard format since the late 1880s. Blue Amberols can play for as long as 4 minutes and 45 seconds and have a surface layer of the "indestructible" plastic celluloid, which Edison tinted a trademark blue color. Edison brand phonographs designed to play Amberol cylinders were named Amberolas.

<span class="mw-page-title-main">Edison Disc Record</span> Type of phonograph record produced by Edison Inc. from 1912 to 1929

The Edison Diamond Disc Record is a type of phonograph record marketed by Thomas A. Edison, Inc. on their Edison Record label from 1912 to 1929. They were named Diamond Discs because the matching Edison Disc Phonograph was fitted with a permanent conical diamond stylus for playing them. Diamond Discs were incompatible with lateral-groove disc record players, e.g. the Victor Victrola, the disposable steel needles of which would damage them while extracting hardly any sound. Uniquely, they are just under 14 in thick.

<span class="mw-page-title-main">Laser turntable</span> Turntable that plays records using laser beams

A laser turntable is a phonograph that plays standard LP records using laser beams as the pickup instead of using a stylus as in conventional turntables. Although these turntables use laser pickups, the same as Compact Disc players, the signal remains in the analog realm and is never digitized.

<span class="mw-page-title-main">Phonautograph</span> Earliest known device for recording sound

The phonautograph is the earliest known device for recording sound. Previously, tracings had been obtained of the sound-producing vibratory motions of tuning forks and other objects by physical contact with them, but not of actual sound waves as they propagated through air or other mediums. Invented by Frenchman Édouard-Léon Scott de Martinville, it was patented on March 25, 1857. It transcribed sound waves as undulations or other deviations in a line traced on smoke-blackened paper or glass. Intended solely as a laboratory instrument for the study of acoustics, it could be used to visually study and measure the amplitude envelopes and waveforms of speech and other sounds, or to determine the frequency of a given musical pitch by comparison with a simultaneously recorded reference frequency.

<span class="mw-page-title-main">Sound recording and reproduction</span> Recording of sound and playing it back

Sound recording and reproduction is the electrical, mechanical, electronic, or digital inscription and re-creation of sound waves, such as spoken voice, singing, instrumental music, or sound effects. The two main classes of sound recording technology are analog recording and digital recording.

Audio restoration is the process of removing imperfections from sound recordings. Audio restoration can be performed directly on the recording medium, or on a digital representation of the recording using a computer. Record restoration is a particular form of audio restoration that seeks to repair the sound of damaged gramophone records.

The history of sound recording - which has progressed in waves, driven by the invention and commercial introduction of new technologies — can be roughly divided into four main periods:

Record restoration, a particular kind of audio restoration, is the process of converting the analog signal stored on gramophone records into digital audio files that can then be edited with computer software and eventually stored on a hard-drive, recorded to digital tape, or burned to a CD or DVD. The process may be divided into several separate steps performed in the following order:

  1. Cleaning the record, to prevent unwanted audio artifacts from being introduced in the capture that will necessitate correction in the digital domain, and to prevent unnecessary wear and damage to the stylus used in playback.
  2. Transcription of the record to another format on another medium ;
  3. Processing the raw sound file with software in order to remove transient noise resulting from record surface damage ;
  4. Using software to adjust the volume and equalization;
  5. Processing the audio with digital and analogue techniques to reduce surface/wideband noise;
  6. Saving the file in the desired format.
<span class="mw-page-title-main">LP record</span> Vinyl analog sound storage discs

The LP is an analog sound storage medium, a phonograph record format characterized by: a speed of 33+13 rpm; a 12- or 10-inch diameter; use of the "microgroove" groove specification; and a vinyl composition disk. Introduced by Columbia in 1948, it was soon adopted as a new standard by the entire record industry. Apart from a few relatively minor refinements and the important later addition of stereophonic sound, it remained the standard format for record albums until its gradual replacement from the 1980s to the early 2000s, first by cassettes, then by compact discs, and finally by digital music distribution.

This article details a comparison of audio recording mediums.

<span class="mw-page-title-main">Conservation and restoration of vinyl discs</span>

The conservation and restoration of vinyl discs refers to the preventive measures taken to defend against damage and slow degradation, and to maintain fidelity of singles, 12" singles, EP’s, and LP’s in 45 or 33⅓ rpm 10” disc recordings.

<span class="mw-page-title-main">Dictation machine</span> Device for recording human speech

A dictation machine is a sound recording device most commonly used to record speech for playback or to be typed into print. It includes digital voice recorders and tape recorder.

<span class="mw-page-title-main">Volta Laboratory and Bureau</span> U.S. National Historic research laboratory

The Volta Laboratory and the Volta Bureau were created in Georgetown, Washington, D.C., by Alexander Graham Bell.(19/20th-century scientist and inventor best known for his work on the telephone)

<span class="mw-page-title-main">Vertical cut recording</span> Record groove with varying depth and constant separation between grooves

The vertical cut recording process is an early method of audio recording by which a stylus cuts a vertical groove into a phonograph record. This is in contrast to the lateral recording system which uses a stylus that cuts side-to-side across a record. The vertical recording process, also known as the hill and dale process, was used to record phonograph cylinder records as well as Edison Disc Records, Pathé disc records, and disc records made by numerous smaller companies. Vertical cut recording was also used as a means of copyright protection by the early Muzak 16-inch background music discs.

<span class="mw-page-title-main">Music technology (electric)</span> Musical instruments and recording devices that use electrical circuits

Electric music technology refers to musical instruments and recording devices that use electrical circuits, which are often combined with mechanical technologies. Examples of electric musical instruments include the electro-mechanical electric piano, the electric guitar, the electro-mechanical Hammond organ and the electric bass. All of these electric instruments do not produce a sound that is audible by the performer or audience in a performance setting unless they are connected to instrument amplifiers and loudspeaker cabinets, which made them sound loud enough for performers and the audience to hear. Amplifiers and loudspeakers are separate from the instrument in the case of the electric guitar, electric bass and some electric organs and most electric pianos. Some electric organs and electric pianos include the amplifier and speaker cabinet within the main housing for the instrument.

VisualAudio is a project that retrieves sound from a picture of a phonograph record. It originated from a partnership between the Swiss National Sound Archives and the School of Engineering and Architecture of Fribourg.

References

  1. 1 2 Vitaliy Fadeyev and Carl Haber, Reconstruction of Mechanically Recorded Sound by Image Processing. Journal of the Audio Engineering Society, 2003. (PDF)
  2. New Sounds, Old Voices. The New Yorker , February 26, 2014.
  3. 1 2 3 The Machine That's Saving the History of Recorded Sound. The Atlantic , June 13, 2014.
  4. Fadeyev, Vitaliy; Haber, Carl; Maul, Christian; Mcbride, John W.; Golden, Mitchell. Reconstruction of Recorded Sound from an Edison Cylinder Using Three-Dimensional Noncontact Optical Surface Metrology. Journal of the Audio Engineering Society 53 (2005), pp. 485–508.
  5. 1 2 Greenfieldboyce, Nell (15 July 2007). "You Can Play the Record, but Don't Touch". NPR.
  6. 1 2 3 Marsh, Allison (30 April 2018). "Particle Physics Resurrects Alexander Graham Bell's Voice". IEEE Spectrum.
  7. A Voice from the Past. The New Yorker , May 19, 2014.
  8. 1 2 3 Ghostly Voices From Thomas Edison’s Dolls Can Now Be Heard. New York Times , May 4, 2015.
  9. The Digitization Process. Project IRENE, University of California, Berkeley Libraries.
  10. Dead Media Beat: IRENE, reviving and restoring lost sounds. Wired , December 26, 2013.
  11. "FirstSounds.ORG".
  12. Rosen, Jody (27 March 2008). "Researchers Play Tune Recorded Before Edison". The New York Times . Retrieved 27 March 2008. The audio excavation could give a new primacy to the phonautograph, once considered a curio, and its inventor, Édouard-Léon Scott de Martinville, a Parisian typesetter and tinkerer who went to his grave convinced that credit for his breakthroughs had been improperly bestowed on Edison.
  13. "Earliest Known Sound Recordings Revealed". U.S. News & World Report.
  14. National Science Foundation (NSF) (8 August 2017). "Rare audio recordings of #indigenous California languages, recorded more than 100 years ago, are now being saved by an #NSFfunded UC" via Facebook.
  15. "How Edison Got His Groove Back". KQED, July 30, 2008. (video)
  16. Rare Stanley Brothers disc one step closer to restoration. Bluegrass Today, July 31, 2018.
  17. At Harvard, Technology Resurrects Long-Silent Voices Of Poets. WBUR, November 28, 2014.

Bibliography

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