Analog sequencer
An analog sequencer is a music sequencer constructed from analog (analogue) electronics, invented in the first half of the 20th century.
Raymond Scott designed and constructed some of the first electro-mechanical music sequencers during the 1940s. In 1951, computer music (including music sequence, music composition and sound generation) was started. However, the RCA Mark II Sound Synthesizer was still indirectly controlled via punch-tape system in 1957, similar to piano rolls.
Also, in earlier electronic music, sound-on-film technology was used for generating sound waves as well as controlling sequence of notes.
In addition, cylinder with pins typically used on music box has at least several hundreds years of history on music sequences. Their peculiarities and limitations left a lasting stylistic imprint on Berlin School electronic music, and hence, indirectly, in many later rhythmic synthesizer-driven music genres such as techno, trance music, 1980s synthpop, house, ...
At its most basic, an analog sequencer consists of a bank of potentiometers and a "clock" (pulse generator) connected to a sequencer, which steps through these potentiometers one at a time and then cycles back to the beginning. The output of the sequencer is fed (as a control voltage and gate pulse) to a synthesizer. By "tuning" the potentiometers, a short repetitive rhythmic motif or riff can be set up.
The most commonly used analog sequencer was the Moog 960, which was a module of the Moog modular synthesizer. It consisted of three parallel banks of eight potentiometers: the three banks could either steer three different Voltage-controlled oscillators (VCOs) to allow three-note chords in the sequence, or (for example) one row could steer pitch while the second row is patched through to the filter cutoff or VCA volume, and a third steers filter cutoff for a white noise generator (thus creating an extremely primitive electronic drum track).
Under each of the eight steps, a switch offered three options: play this step, skip this step, or loop back to the beginning. In order to avoid the monotony of endlessly repeated sequences, pioneering e-musicians like Chris Franke of Tangerine Dream and Michael Hoenig would manipulate these switches in real time during performance, adding and dropping notes and beats from a sequence. Also, the "pitch" row can be patched to two or more oscillators tuned to intervals, and the oscillators mixed in and out one at a time.
Good examples of all these techniques can be heard on the Phaedra, Rubycon, Ricochet, and Encore albums of Tangerine Dream, as well as on Departure from the Northern Wasteland by Michael Hoenig.
By synchronizing two sequencers, and manipulating them individually, swirling polyrhythmic phasing patterns (as introduced in minimalist music by Steve Reich) can be set up. The title track of the Michael Hoenig album (mentioned above) is an excellent example.
An additional module (Moog 962) allowed "daisy-chaining" the three rows to form one longer 24-step sequence. In addition, a switch on the 960 itself allowed the third (bottom) row to be used for note lengths.
The output voltage of the sequencer can be added to the output voltage of a keyboard controller, and the latter used to transpose the sequence on the fly. Klaus Schulze was particularly fond of this technique, which lays the musical foundation for tracks like "Bayreuth Return" from Timewind, "Floating" from Moondawn, and indeed pretty much any rhythmic piece from Klaus Schulze's "analog" years. Vangelis and Jean-Michel Jarre likewise availed themselves of this technique.
Apart from a temperature-controlled environment after warmup, pitch stability could be problematic. On the famous opening of Phaedra, the sequencer had drifted out of tune, and one can clearly hear Chris Franke retuning the sequence by ear in real time.
In addition to the 1027 module, which is a conventional 3x10 step sequencer, the ARP 2500 was often equipped with the 1050 Mix-Sequencer module. Unlike contemporary sequencers which could only generate voltages, the 1050 could also sequence audio signals. This allowed each step of the sequence to come from a completely different sound source. The 8 positions could run in sequence or be split into two independent 4 step sequencers. It's easily identified by its vertical column of 8 square white buttons which light up to indicate the active step(s).
Analog sequencers, have in some respects, been replaced by digital devices and software implementations. However, there is a continued interest by modular analog synthesists, who appreciate the real time control offered by the analog sequencer as evidenced by the 'Oberkorn' machine by Analog Solutions, amongst others.
- Various analog sequencers
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One of the 1st commercially available analog sequencer (front, 3×8 step and 3×16 step) on Buchla 100 (1964/1966) [1]
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Earlier Moog sequencer (left, possibly later added) on the 1st commercially sold Moog Modular prototype (c.1964)
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EML Sequencer 400 (top ×2, 6×16 step) on EML ElectroComp modular synthesizer (1970)
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Buchla 250e Arbitrary Function Generator
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A Moog 960 clone,
Synthesizers.com Q960 Sequential Controller -
Roland System 100M Model 182 Sequencer
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Doepfer MAQ16-3 MIDI Analog Sequencer
- ^ Holmes, Thom (2008). Electronic and experimental music: technology, music, and culture. Taylor & Francis. p. 222. ISBN 978-0-415-95781-6.
Moog admired Buchla's work, recently stating that Buchla designed a system not only for “making new sounds but [for] making textures out of these sounds by specifying when these sounds could change and how regular those change would be.”
- ^ "close encounters of the ARP kind - ARP 2500 MODULAR ANALOGUE SYNTHESIS SYSTEM". Sound on Sound (Aug. 1996).
See also
Notes
External links
- Silicon sequences, a video clip demonstrating realtime sequence(r) manipulation
- Images and specifications of Moog 960 clone