Music sequencer explained

A music sequencer (or audio sequencer or simply sequencer) is a device or application software that can record, edit, or play back music, by handling note and performance information in several forms, typically CV/Gate, MIDI, or Open Sound Control, and possibly audio and automation data for digital audio workstations (DAWs) and plug-ins.[1] [2]

Overview

Modern sequencers

The advent of Musical Instrument Digital Interface (MIDI) and the Atari ST home computer in the 1980s gave programmers the opportunity to design software that could more easily record and play back sequences of notes played or programmed by a musician. This software also improved on the quality of the earlier sequencers which tended to be mechanical sounding and were only able to play back notes of exactly equal duration. Software-based sequencers allowed musicians to program performances that were more expressive and more human. These new sequencers could also be used to control external synthesizers, especially rackmounted sound modules, and it was no longer necessary for each synthesizer to have its own devoted keyboard.

As the technology matured, sequencers gained more features, such as the ability to record multitrack audio. Sequencers used for audio recording are called digital audio workstations (DAWs).

Many modern sequencers can be used to control virtual instruments implemented as software plug-ins. This allows musicians to replace expensive and cumbersome standalone synthesizers with their software equivalents.

Today the term "sequencer" is often used to describe software. However, hardware sequencers still exist. Workstation keyboards have their own proprietary built-in MIDI sequencers. Drum machines and some older synthesizers have their own step sequencer built in. There are still also standalone hardware MIDI sequencers, although the market demand for those has diminished greatly due to the greater feature set of their software counterparts.

Types of music sequencer

Music sequencers can be categorized by handling data types, such as:

Also, music sequencer can be categorized by its construction and supporting modes.

Analog sequencer

Analog sequencers are typically implemented with analog electronics, and play the musical notes designated by a series of knobs or sliders corresponding to each musical note (step). It is designed for both composition and live performance; users can change the musical notes at any time without regarding recording mode. And also possibly, the time interval between each musical note (length of each step) can be independently adjustable. Typically, analog sequencers are used to generate the repeated minimalistic phrases which may be reminiscent of Tangerine Dream, Giorgio Moroder or trance music.

(step recording mode)

On step sequencers, musical notes are rounded into steps of equal time intervals, and users can enter each musical note without exact timing; Instead, the timing and duration of each step can be designated in several different ways:

In general, step mode, along with roughly quantized semi-realtime mode, is often supported on the drum machines, bass machines and several groove machines.

Realtime sequencer (realtime recording mode)

Realtime sequencers record the musical notes in real-time as on audio recorders, and play back musical notes with designated tempo, quantizations, and pitch. For editing, usually "punch in/punch out" features originated in the tape recording are provided, although it requires sufficient skills to obtain the desired result. For detailed editing, possibly another visual editing mode under graphical user interface may be more suitable. Anyway, this mode provides usability similar to audio recorders already familiar to musicians, and it is widely supported on software sequencers, DAWs, and built-in hardware sequencers.

Software sequencer

A software sequencer is a class of application software providing a functionality of music sequencer, and often provided as one feature of the DAW or the integrated music authoring environments. The features provided as sequencers vary widely depending on the software; even an analog sequencer can be simulated. The user may control the software sequencer either by using the graphical user interfaces or a specialized input devices, such as a MIDI controller.

Audio sequencer

Alternative subsets of audio sequencers include:

History

Early sequencers

The early music sequencers were sound-producing devices such as automatic musical instruments, music boxes, mechanical organs, player pianos, and Orchestrions. Player pianos, for example, had much in common with contemporary sequencers. Composers or arrangers transmitted music to piano rolls which were subsequently edited by technicians who prepared the rolls for mass duplication. Eventually consumers were able to purchase these rolls and play them back on their own player pianos.

The origin of automatic musical instruments seems remarkably old. As early as the 9th century, the Persian (Iranian) Banū Mūsā brothers invented a hydropowered organ using exchangeable cylinders with pins,[9] and also an automatic flute-playing machine using steam power,[10] [11] as described in their Book of Ingenious Devices. The Banu Musa brothers' automatic flute player was the first programmable music sequencer device,[12] and the first example of repetitive music technology, powered by hydraulics.[13]

In 1206, Al-Jazari, an Arab engineer, invented programmable musical automata,[14] a "robot band" which performed "more than fifty facial and body actions during each musical selection." It was notably the first programmable drum machine. Among the four automaton musicians were two drummers. It was a drum machine where pegs (cams) bump into little levers that operated the percussion. The drummers could be made to play different rhythms and different drum patterns if the pegs were moved around.[15]

In the 14th century, rotating cylinders with pins were used to play a carillon (steam organ) in Flanders, and at least in the 15th century, barrel organs were seen in the Netherlands.[16]

In the late-18th or early-19th century, with technological advances of the Industrial Revolution various automatic musical instruments were invented. Some examples: music boxes, barrel organs and barrel pianos consisting of a barrel or cylinder with pins or a flat metal disc with punched holes; or mechanical organs, player pianos and orchestrions using book music / music rolls (piano rolls) with punched holes, etc. These instruments were disseminated widely as popular entertainment devices prior to the inventions of phonographs, radios, and sound films which eventually eclipsed all such home music production devices. Of them all, punched-paper-tape media had been used until the mid-20th century. The earliest programmable music synthesizers including the RCA Mark II Sound Synthesizer in 1957, and the Siemens Synthesizer in 1959, were also controlled via punch tapes similar to piano rolls.[17] [18] [19]

Additional inventions grew out of sound film audio technology. The drawn sound technique which appeared in the late 1920s, is notable as a precursor of today's intuitive graphical user interfaces. In this technique, notes and various sound parameters are triggered by hand-drawn black ink waveforms directly upon the film substrate, hence they resemble piano rolls (or the 'strip charts' of the modern sequencers/DAWs). Drawn soundtrack was often used in early experimental electronic music, including the Variophone developed by Yevgeny Sholpo in 1930, and the Oramics designed by Daphne Oram in 1957, and so forth.

Analog sequencers

See main article: Analog sequencer.

During the 1940s–1960s, Raymond Scott, an American composer of electronic music, invented various kind of music sequencers for his electric compositions. The "Wall of Sound", once covered on the wall of his studio in New York during the 1940s–1950s, was an electro-mechanical sequencer to produce rhythmic patterns, consisting of stepping relays (used on dial pulse telephone exchange), solenoids, control switches, and tone circuits with 16 individual oscillators.[20] Later, Robert Moog would explain it in such terms as "the whole room would go 'clack – clack – clack', and the sounds would come out all over the place".The Circle Machine, developed in 1959, had incandescent bulbs each with its own rheostat, arranged in a ring, and a rotating arm with photocell scanning over the ring, to generate an arbitrary waveform. Also, the rotating speed of the arm was controlled via the brightness of lights, and as a result, arbitrary rhythms were generated.[21] The first electronic sequencer was invented by Raymond Scott, using thyratrons and relays.[22]

Clavivox, developed since 1952, was a kind of keyboard synthesizer with sequencer. On its prototype, a theremin manufactured by young Robert Moog was utilized to enable portamento over 3-octave range, and on later version, it was replaced by a pair of photographic film and photocell for controlling the pitch by voltage.[23]

In 1968, Ralph Lundsten and Leo Nilsson had a polyphonic synthesizer with sequencer called Andromatic built for them by Erkki Kurenniemi.[24]

Step sequencers

See also: Drum machine and Groovebox.

The step sequencers played rigid patterns of notes using a grid of (usually) 16 buttons, or steps, each step being 1/16 of a measure. These patterns of notes were then chained together to form longer compositions. Sequencers of this kind are still in use, mostly built into drum machines and grooveboxes. They are monophonic by nature, although some are multi-timbral, meaning that they can control several different sounds but only play one note on each of those sounds.

Early computers

See main article: Computer music.

On the other hand, software sequencers were continuously utilized since the 1950s in the context of computer music, including computer-played music (software sequencer), computer-composed music (music synthesis), and computer sound generation (sound synthesis). In June 1951, the first computer music Colonel Bogey was played on CSIRAC, Australia's first digital computer.[25] [26] In 1956, Lejaren Hiller at the University of Illinois at Urbana–Champaign wrote one of the earliest programs for computer music composition on ILLIAC, and collaborated on the first piece, Illiac Suite for String Quartet, with Leonard Issaction.[27] In 1957 Max Mathews at Bell Labs wrote MUSIC, the first widely used program for sound generation, and a 17-second composition was performed by the IBM 704 computer. Subsequently, computer music was mainly researched on the expensive mainframe computers in computer centers, until the 1970s when minicomputers and then microcomputers became available in this field.

In Japan

In Japan, experiments in computer music date back to 1962, when Keio University professor Sekine and Toshiba engineer Hayashi experimented with the TOSBAC computer. This resulted in a piece entitled TOSBAC Suite.[28]

Early computer music hardware

In 1965, Max Mathews and L. Rosler developed Graphic 1, an interactive graphical sound system (that implies sequencer) on which one could draw figures using a light-pen that would be converted into sound, simplifying the process of composing computer-generated music.[29] It used PDP-5 minicomputer for data input, and IBM 7094 mainframe computer for rendering sound.

Also in 1970, Mathews and F. R. Moore developed the GROOVE (Generated Real-time Output Operations on Voltage-controlled Equipment) system,[30] a first fully developed music synthesis system for interactive composition (that implies sequencer) and realtime performance, using 3C/Honeywell DDP-24[31] (or DDP-224) minicomputers. It used a CRT display to simplify the management of music synthesis in realtime, 12bit D/A for realtime sound playback, an interface for CV/gate analog devices, and even several controllers including a musical keyboard, knobs, and rotating joysticks to capture realtime performance.[32] [33]

Digital sequencers

In 1971, Electronic Music Studios (EMS) released one of the first digital sequencer products as a module of Synthi 100, and its derivation, Synthi Sequencer series.[34] [35] After then, Oberheim released the DS-2 Digital Sequencer in 1974,[36] and Sequential Circuits released Model 800 in 1977 [37]

In Japan

In 1977, Roland Corporation released the MC-8 MicroComposer, also called computer music composer by Roland. It was an early stand-alone, microprocessor-based, digital CV/gate sequencer,[38] [39] and an early polyphonic sequencer.[40] [41] It equipped a keypad to enter notes as numeric codes, 16 KB of RAM for a maximum of 5200 notes (large for the time), and a polyphony function which allocated multiple pitch CVs to a single Gate.[42] It was capable of eight-channel polyphony, allowing the creation of polyrhythmic sequences.[43] [38] [39] The MC-8 had a significant impact on popular electronic music, with the MC-8 and its descendants (such as the Roland MC-4 Microcomposer) impacting popular electronic music production in the 1970s and 1980s more than any other family of sequencers.[43] The MC-8's earliest known users were Yellow Magic Orchestra in 1978.

Music workstations

See also: Music workstation.

In 1975, New England Digital (NED) released ABLE computer (microcomputer)[44] as a dedicated data processing unit for Dartmouth Digital Synthesizer (1973), and based on it, later Synclavier series were developed.

The Synclavier I, released in September 1977,[45] was one of the earliest digital music workstation product with multitrack sequencer. Synclavier series evolved throughout the late-1970s to the mid-1980s, and they also established integration of digital-audio and music-sequencer, on their Direct-to-Disk option in 1984, and later Tapeless Studio system.

In 1982, renewed the Fairlight CMI Series II and added new sequencer software "Page R", which combined step sequencing with sample playback.[46]

While there were earlier microprocessor-based sequencers for digital polyphonic synthesizers,[47] their early products tended to prefer the newer internal digital buses than the old-style analogue CV/gate interface once used on their prototype system. Then in the early-1980s, they also re-recognized the needs of CV/gate interface, and supported it along with MIDI as options.

In Japan

Yamaha's GS-1, their first FM digital synthesizer, was released in 1980.[48] To program the synthesizer, Yamaha built a custom computer workstation . It was only available at Yamaha's headquarters in Japan (Hamamatsu) and the United States (Buena Park, California).

MIDI sequencers

See main article: MIDI.

See also: Comparison of MIDI standards, Comparison of MIDI editors and sequencers and Groovebox.

In June 1981, Roland Corporation founder Ikutaro Kakehashi proposed the concept of standardization between different manufacturers' instruments as well as computers, to Oberheim Electronics founder Tom Oberheim and Sequential Circuits president Dave Smith. In October 1981, Kakehashi, Oberheim and Smith discussed the concept with representatives from Yamaha, Korg and Kawai.[49] In 1983, the MIDI standard was unveiled by Kakehashi and Smith.[50] [51] The first MIDI sequencer was the Roland MSQ-700, released in 1983.[52]

It was not until the advent of MIDI that general-purpose computers started to play a role as sequencers. Following the widespread adoption of MIDI, computer-based MIDI sequencers were developed. MIDI-to-CV/gate converters were then used to enable analogue synthesizers to be controlled by a MIDI sequencer.[39] Since its introduction, MIDI has remained the musical instrument industry standard interface through to the present day.[53]

Personal computers

See also: MIDI, Computer music, Sampler (musical instrument) and Music tracker.

In 1987, software sequencers called trackers were developed to realize the low-cost integration of sampling sound and interactive digital sequencer as seen on Fairlight CMI II "Page R". They became popular in the 1980s and 1990s as simple sequencers for creating computer game music, and remain popular in the demoscene and chiptune music.

Modern computer digital audio software after the 2000s, such as Ableton Live, incorporates aspects of sequencers among many other features.

In Japan

In 1978, Japanese personal computers such as the Hitachi Basic Master equipped the low-bit D/A converter to generate sound which can be sequenced using Music Macro Language (MML).[54] This was used to produce chiptune video game music.[28]

It was not until the advent of MIDI, introduced to the public in 1983, that general-purpose computers really started to play a role as software sequencers.[39] NEC's personal computers, the PC-88 and PC-98, added support for MIDI sequencing with MML programming in 1982.[28] In 1983, Yamaha modules for the MSX featured music production capabilities,[55] real-time FM synthesis with sequencing, MIDI sequencing,[56] [57] and a graphical user interface for the software sequencer.[58] [57] Also in 1983, Roland Corporation's CMU-800 sound module introduced music synthesis and sequencing to the PC, Apple II,[59] and Commodore 64.[60]

The spread of MIDI on personal computers was facilitated by Roland's MPU-401, released in 1984. It was the first MIDI-equipped PC sound card, capable of MIDI sound processing and sequencing.[61] [62] After Roland sold MPU sound chips to other sound card manufacturers,[63] it established a universal standard MIDI-to-PC interface.[64] Following the widespread adoption of MIDI, computer-based MIDI software sequencers were developed.[39]

Visual timeline of rhythm sequencers

See main article: Drum machine, Groovebox, Beat slicing and Sampler (musical instrument).

Drum machine
(1959–)|


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Transistorized drum machine (1964–)|


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Step drum machine (1972–)|


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Digital drum machine (1980–)|


|style="width:100px;"|
Groove machine (1981–)|


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"Page R" on Fairlight (1982)|


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Tracker (1987–)|


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Beat slicer (1990s–)|Loop sequencer (1998–)|


|style="width:140px;"|
Note manipulation on audio tracks (2009–)|}

See also

Further reading

List of papers sharing a similar perspective with this Wikipedia article:

External links

Notes and References

  1. On WhatIs.com of TechTarget, an author seems to define a term "Sequencer" as an abbreviation of "MIDI sequencer".
  2. Book: Pejrolo, Andrea. 1.7.1 The Primary Goals You Want to Achieve with Your Audio Sequencer. Creative Sequencing Techniques for Music Production: A Practical Guide to Pro Tools, Logic, Digital Performer, and Cubase. https://books.google.com/books?id=k-vFPYjwpW0C&q=Music%20sequencer%20analog%20step%20digital%20realtime&pg=PR5. Taylor & Francis. 2011. 978-0-240-52216-6. 48. Note: an example of section title containing "Audio Sequencer"
  3. Book: Rothstein, Joseph . MIDI: A Comprehensive Introduction . Computer Music and Digital Audio Series . 7 . A-R Editions, Inc. . 1995 . 978-0-89579-309-6 . 77, 122 .
  4. Book: Pinch . Trevor. J. . Trocco . Frank . Buchla's Box . https://books.google.com/books?id=CoUs2SSvG4EC&pg=PT48 . Analog Days: The Invention and Impact of the Moog Synthesizer . reprint . Harvard University Press . 2009 . 978-0-674-04216-2 . 55–56 .

    "Subotnick suggested that using a light source to control sound might be promising. ... Later he [Buchla] turned this into an electro mechanical sequencer by introducing step relays and a dial. ... Buchla, like Moog, realized that voltage control ... But Buchla was after something different; ... Buchla was led to the electronic sequencer—a device that later was used to make much influential pop, rock, and dance music. A sequencer produces predetermined control voltages in a cycle or sequence and can endlessly recycle ..."

    Note: for a sequencer using a light source, see "Circle Machine" on

    1. Analog sequencers
    and Raymond Scott#Electronics and research.

  5. Automation parameters in DAWs are often interoperable with MIDI messages, i.e. Control Changes (CC) or System Exclusive (SysEx); in that case, it can be controlled in real-time via pre-assigned MIDI messages generated by MIDI controllers or MIDI sequencers, etc.   And even more so, in several DAWs, automation parameters are explicitly recorded as MIDI messages on their embedded MIDI sequencers. (See)
  6. . Price . Simon . Using Mixer Automation In Reason – Reason Tips & Techniques . Technique: Reason Notes . Sound on Sound . September 2006 . live . https://web.archive.org/web/20160310132431/http://www.soundonsound.com/sos/sep06/articles/reasontech_0906.htm . 2016-03-10.

    "Controller Data Vs. Automation / ... sequencer package such as Logic or Pro Tools, ... are akin to automation on professional hardware mixing consoles, ... This type of automation system is different to using MIDI Continuous Controller [Control Changes] (CC) data, ... In Reason, automation is MIDI Controller [Control Changes] data, but with some specialised tools for handling the data and playing it back. ...",
    "Recording Mixer Automation / As automation in Reason is MIDI CC data, it must be recorded on a sequencer track."

  7. Book: Pejrolo, Andrea . 1.7.1 The Primary Goals You Want to Achieve with Your Audio Sequencer . Creative Sequencing Techniques for Music Production: A Practical Guide to Pro Tools, Logic, Digital Performer, and Cubase . https://books.google.com/books?id=k-vFPYjwpW0C&q=Music%20sequencer%20analog%20step%20digital%20realtime&pg=PR5 . Taylor & Francis . 2011 . 978-0-240-52216-6 . 48. (sub-section title contains the expression "Audio Sequencer")
  8. The term audio sequencer seems to be relatively new expression and seems to be not clearly defined, yet. For example, "DAW integrated with MIDI sequencer" is often referred as "Audio and MIDI sequencer". However, in this usage, the term "audio sequencer" is just a synonym for the "DAW", and beyond the scope of this article. In that case, please check Digital audio workstation.
  9. Charles B. . Fowler . October 1967 . The Museum of Music: A History of Mechanical Instruments . Music Educators Journal . 54 . 2 . 45–49 . 10.2307/3391092 . 3391092 . 190524140 .
  10. Koetsier . Teun . 2001 . On the prehistory of programmable machines: musical automata, looms, calculators . Mechanism and Machine Theory . 36 . 5 . 589–603 . 10.1016/S0094-114X(01)00005-2.
  11. Book: . . 1979 . The book of ingenious devices (Kitāb al-ḥiyal) . . 9027708339 . 76–7.
  12. Long . Jason . Murphy . Jim . Carnegie . Dale . Kapur . Ajay . Loudspeakers Optional: A history of non-loudspeaker-based electroacoustic music . . 12 July 2017 . 22 . 2 . 195–205 . . 10.1017/S1355771817000103. free .
  13. Levaux . Christophe . The Forgotten History of Repetitive Audio Technologies . . 12 July 2017 . 22 . 2 . . 187–194 . 10.1017/S1355771817000097. free .
  14. The Museum of Music: A History of Mechanical Instruments. Charles B.. Fowler. Music Educators Journal. 54. 2. October 1967. 45–49. 10.2307/3391092. 3391092. 190524140.
  15. [Noel Sharkey]
  16. Barrel-organ . 3 . 432–434 . Kathleen . Schlesinger.
  17. Web site: The RCA Synthesiser . 120 Years of Electronic Music (120years.net) . live . https://archive.wikiwix.com/cache/20111026223002/http://120years.net/machines/rca/ . 2011-10-26. 2014-02-11 . —(PDF version is available)
  18. Web site: Das Siemens-Studio für elektronische Musik von Alexander Schaaf und Helmut Klein . de . . dead . https://web.archive.org/web/20130930175905/http://www.deutsches-museum.de/sammlungen/ausgewaehlte-objekte/meisterwerke-vi/siemens-studio . 2013-09-30.
  19. Book: Holmes , Thom . Early Synthesizers and Experimenters . https://books.google.com/books?id=aT5nAQAAQBAJ&pg=PA175 . Electronic and Experimental Music: Technology, Music, and Culture . 4th . Routledge . 2012 . 978-1-136-46895-7 . 190192. See also excerpt from pp. 157-160 in Chapter 6 of Early Synthesizers and Experimenters.
  20. Web site: Wall of Sound (sequencer) . RaymondScott.com . dead . https://web.archive.org/web/20111113023228/http://raymondscott.com/1946.htm . 2011-11-13.
  21. Web site: Circle Machine . RaymondScott.com . dead . https://web.archive.org/web/20110927232227/http://raymondscott.com/circle.html . 2011-09-27. —includes 2 sound files: Raymond Scott's demonstration, and commercial soundtrack for new batteries of Ford Motors.
  22. https://www.raymondscott.net/docs/RS-Artifacts.pdf Raymond Scott Artifacts
  23. Web site: Moog . Robert . Memories of Raymond Scott . RaymondScott.com . dead . https://web.archive.org/web/20111106035451/http://raymondscott.com/moog.html . 2011-11-06.
  24. Web site: Städje . Jörgen . 2012-10-06 . Andromatic, den automatiska andromedaren . International Data Group (IDG) . live . https://web.archive.org/web/20121007224640/http://www.idg.se/2.1085/1.445306/andromatic-den-automatiska-andromedaren . 2012-10-07.
  25. Web site: CSIRAC: Australia's first computer . Commonwealth Scientific and Industrial Research Organisation (CSIRO) . Australia . 2007-12-21 . live . https://web.archive.org/web/20071116112251/http://www.csiro.au/science/ps4f.html . 2007-11-16.
  26. News: Fildes . Jonathan . 2008-06-17 . 'Oldest' computer music unveiled . . 2008-06-18 . live . https://web.archive.org/web/20090111225358/http://news.bbc.co.uk/1/hi/technology/7458479.stm . 2009-01-11. —another oldest known recording of computer realized music played by the Ferranti Mark 1, captured by BBC in Autumn, 1951; the songs Baa Baa Black Sheep and In the Mood.
  27. Hiller . Lejaren . Winter 1981 . Composing with Computer: A Progress Report . Computer Music Journal . 5 . 4. 7–21 . 10.2307/3679501 . 3679501 .
    also available inBook: Curtis Roads . The Music Machine: Selected Readings from Computer Music Journal . 75 . MIT Press (1989/1992) . 978-0-262-68078-3. 1992-10-08 .
  28. Shimazu . Takehito . The History of Electronic and Computer Music in Japan: Significant Composers and Their Works . Leonardo Music Journal . 1994 . 4 . 102–106 . 10.2307/1513190 . 1513190 . 193084745 .
  29. Book: Holmes, Thom . 2008 . Digital Synthesis and Computer Music . Electronic and experimental music: technology, music, and culture . 254 . Taylor & Francis . 978-0-415-95781-6.
  30. Mathews . Max V. . Moore . F.R. . 1970 . GROOVE—a program to compose, store, and edit functions of time . Communications of the ACM . 13 . 12.
  31. Web site: Nyssim Lefford . Eric D. Scheirer . Barry L. Vercoe . amp . An Interview with Barry Vercoe . Experimental Music Studio 25 . Machine Listening Group, MIT Media Laboratory . live . https://web.archive.org/web/20120331173352/http://www.media.mit.edu/events/EMS/bv-interview.html . 2012-03-31 .
  32. Book: Bogdanov, Vladimir . 2001 . All music guide to electronica: the definitive guide to electronic music . 320 . Backbeat Books . 978-0-87930-628-1.
  33. Roads . Curtis . Interview with Max Mathews . Winter 1980 . Computer Music Journal . 4 . 4 .
    inBook: Curtis Roads . The Music Machine: Selected Readings from Computer Music Journal . 5 . MIT Press (1989/1992) . 978-0-262-68078-3. 1992-10-08 .
  34. Web site: Hinton . Graham . 2001 . Synthi 100 (1971, formerly Digitana, aka the Delaware) . Electronic Music Studios (Cornwall) . live . https://web.archive.org/web/20131031040324/http://www.ems-synthi.demon.co.uk/emsprods.html#synthi100 . 2013-10-31 .
  35. Web site: Hinton . Graham . 2001 . Synthi Sequencer 256 (1971, formerly Synthi Moog Sequencer) . Electronic Music Studios (Cornwall) . live . https://web.archive.org/web/20131031040324/http://www.ems-synthi.demon.co.uk/emsprods.html#seq256 . 2013-10-31 .
  36. Book: J.Michmerhuizen . Thomas E. Oberheim . June 1974 . DS-2 Digital Sequencer Instruction and Service Manual . https://web.archive.org/web/20111218194017/http://www.cem3374.com/docs/Manuals/Oberheim/DS2_O%26SM.pdf . dead . 2011-12-18 . 2017-12-06.
  37. Web site: Model 800 Sequencer . SynthMuseum.com . live . https://web.archive.org/web/20111011114838/http://synthmuseum.com/sequ/seqseq80001.html . 2011-10-11.
  38. Book: Russ , Martin . 2008 . Sound Synthesis and Sampling . . 978-0240521053 . 346 . 21 June 2011.
  39. Book: Russ , Martin . 2012. Sound Synthesis and Sampling. CRC Press. 978-1136122149. 192 . 26 April 2017.
  40. Paul Théberge (1997), Any Sound You Can Imagine: Making Music/Consuming Technology, page 223, Wesleyan University Press
  41. Herbert A. Deutsch (1985), Synthesis: an introduction to the history, theory & practice of electronic music, page 96, Alfred Music
  42. Reid . Gordon . The History Of Roland Part 1: 1930–1978 . Nov 2004 . . 2011-06-19 . live . https://web.archive.org/web/20110629214447/http://www.soundonsound.com/sos/nov04/articles/roland.htm . 2011-06-29.
  43. [Chris Carter (British musician)|Chris Carter]
  44. Web site: Synclavier Early History . Synclavier European Services . live . https://web.archive.org/web/20161114050731/http://www.500sound.com/synclavierhistory.html . 2016-11-14.
  45. Chadabe . Joel . May 1, 2001 . The Electronic Century Part IV: The Seeds of the Future . Electronic Musician . In September 1977, I bought the first Synclavier... . dead . https://web.archive.org/web/20091002070017/http://emusician.com/tutorials/electronic_century4/ . October 2, 2009.
  46. Fairlight – The Whole Story . . January 1996 . Fairlight launched the CMI Series II in 1982, which incorporated their now legendary Page R, the first serious music sequencer, which, according to Paine, "simply blew people away". . live . https://web.archive.org/web/20170504030342/http://www.anerd.com/fairlight/fairlightstory.htm . 2017-05-04.
  47. In 1974–1975, Australian computer music engineer Tony Furse developed the MC6800-based Qasar M8 with a software sequencer MUSEQ 8, with a minimum price of $8,000. In 1976, it was licensed to Fairlight Instruments Pty Ltd., and eventually Fairlight CMI was released in 1979 (for details, see Fairlight CMI).
    Also in 1975, New England Digital released original microprocessor-based ABLE computer (utilizing mini-computer architecture) as a future migration target of Dartmouth Digital Synthesizer. Their commercial version of digital synthesizer, Synclavier I was first shipped in 1977 (for details, see Synclavier).
  48. Book: Roads , Curtis . 1996 . The computer music tutorial . . 226 . 0-262-68082-3 . 2011-06-05.
  49. Chadabe. Joel. Joel Chadabe. 1 May 2000. Part IV: The Seeds of the Future. Electronic Musician. Penton Media. XVI. 5. dead. https://web.archive.org/web/20120928230435/http://www.emusician.com/gear/0769/the-electronic-century-part-iv-the-seeds-of-the-future/145415. 28 September 2012.
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  51. Web site: Ikutaro Kakehashi, Dave Smith: Technical GRAMMY Award Acceptance. 9 February 2013. live. https://web.archive.org/web/20141209022049/http://www.grammy.com/videos/technical-grammy-award-recipients-ikutaro-kakehashi-and-dave-smith-at-special-merit-awards. 9 December 2014.
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