Polyphony and monophony in instruments

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Template:Short description Template:More citations needed Template:Sister project Script error: No such module "Infobox".Template:Template other Polyphony is a property of musical instruments that means that they can play multiple independent melody lines simultaneously. Instruments featuring polyphony are said to be polyphonic. Instruments that are not capable of polyphony are monophonic or paraphonic.

An intuitively understandable example for a polyphonic instrument is a (classical) piano, on which the player plays different melody lines with the left and the right hand - depending on music style and composition, these may be musically tightly interrelated or may even be totally unrelated to each other, like in parts of Jazz music. An example for monophonic instruments is a trumpet which can generate only one tone (frequency) at a time, except when played by extraordinary musicians.

Synthesizer

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Monophonic

A monophonic synthesizer or monosynth is a synthesizer that produces only one note at a time, making it smaller and cheaper than a polyphonic synthesizer which can play multiple notes at once. This does not necessarily refer to a synthesizer with a single oscillator; the Minimoog, for example, has three oscillators which are settable in arbitrary intervals, but it can play only one note at a time.

Well-known monosynths include the Minimoog, the Roland TB-303, the Korg Prophecy, and the Korg Monologue.

Duophonic

Duophonic synthesizers, such as the ARP Odyssey and Formanta Polivoks built in the 1970s and 1980s respectively, have a capability to independently play two pitches at a time. These synthesizers have at least two oscillators that are separately controllable, and a duophonic keyboard that can generate two control voltage signals for the lowest- and highest-note. When two or more keys are pressed simultaneously, the lowest- and highest-note will be heard. When only one key is pressed, both oscillators are assigned to one note, possibly with a more complex sound.

Paraphonic

Paraphonic synthesizers, such as the Solina String Ensemble or Korg Poly-800, were designed to play multiple pitches at the same time by using multiple oscillators, but with a common filter and/or amplifier circuit shared among all the voices.[1] The result is a synthesizer that can play chords, provided all the notes start and end at the same time (homophony). For example, playing a new note on top of notes already held might retrigger the volume envelope for the entire sound. Monophonic synthesizers with more than one oscillator (such as the ARP 2600) can often be patched to behave in a paraphonic manner, allowing for each oscillator to play an independent pitch which is then routed through a common VCF and VCA.

Polyphonic

The earliest polyphonic synthesizers were built in the late-1930s, but the concept did not become popular until the mid-1970s. Harald Bode's Warbo Formant Orguel, developed in 1937, was an archetype of a voice allocation polyphonic synthesizer.[2] Novachord by Hammond Organ Company, released in 1939, is a forefather product of frequency divider organs and polyphonic synthesizer. It uses octave divider technology to generate polyphony,[3] and about 1,000 Novachords were manufactured until 1942.[4]

Synths using octave divider

Using an octave divider a synthesizer needs only 12 oscillators – one for each note in the musical scale. The additional notes are generated by dividing down the outputs of these oscillators. To produce a note one octave lower, the frequency of the oscillator is divided by two. Polyphony is achieved so long as only one of each note in the scale is played simultaneously.[5]

File:Novachord frontS.jpg File:Moog Polymoog Synthesizer.jpg File:Korg PE-1000 (Univox K4).jpg File:Korg PS-3300 - reduced light spot.JPG
Hammond Novachord (1939)Script error: No such module "Check for unknown parameters".

A forefather of octave divider synth and electronic organs.

Moog Polymoog (1975)Script error: No such module "Check for unknown parameters".

Octave divider technology similar to Novachord was used.

Korg PE-1000 (1976)Script error: No such module "Check for unknown parameters".

Polyphonic ensemble keyboard consists with one synth per key (totally 60 synthesizers), based on octave divider

Korg PS-3300 (1977)Script error: No such module "Check for unknown parameters".

Patchable polyphonic synthesizer consists with three synths per key (totally 144 synthesizers), based on octave divider.

Synths using voice allocation

In the early-to-mid-1970s, the voice allocation technology with digital keyboard scanning was independently developed by several engineers and musical instrument manufacturers, including Yamaha,[6] E-mu Systems,[7][8] and Armand Pascetta (Electro Group).[9][10] The Oberheim Polyphonic Synthesizer[11][12] and Sequential Circuits Prophet-5[13][8] were both developed in collaboration with Dave Rossum of E-mu Systems.[14][15]

File:Yamaha GX-1 (clip) @ Yamaha Design Masterworks.png File:E-mu Modular System @ Cantos.jpg File:Oberheim 4 voice.jpg File:Don Lewis' LEO (Live Electronic Orchestra) synthesizer organ, Museum of Making Music.jpg File:Sequential Circuits Prophet 5.jpg
Yamaha GX-1 (1973/1975)Script error: No such module "Check for unknown parameters".

Voice allocation technology was used to assign the limited 8-voices per manual into the notes.[6] It was succeeded by the portable Yamaha CS-80 (1976), which was successful[16] and became one of the most popular polyphonic analog synths.[17][18]

E-mu Modular System (1974)Script error: No such module "Check for unknown parameters".

In 1974, Dave Rossum and E-mu developed the polyphonic technologies,[14] and in 1977, released the 4060 Polyphonic Keyboard and Sequencer.[7]

Oberheim Four Voice (FVS-1) (1975)Script error: No such module "Check for unknown parameters".

It was developed under the collaboration with E-mu Systems.[7][12][14][11]

Live Electronic Orchestra (LEO)
by Don Lewis (1977)Script error: No such module "Check for unknown parameters".

LEO used Armand Pascetta's polyphonic keyboard (Template:Circa) to control the multiple synthesizers.[19]

Sequential Circuits Prophet-5 (1978)Script error: No such module "Check for unknown parameters".

One of the most popular polyphonic synth featuring patch memories, also used E-mu's technology.[8][15][13]

Number of voices

One notable early polyphonic synthesizer, the Prophet 5 released in 1978, had five-voice polyphony. Another notable polyphonic synth, the Yamaha CS-80 released in 1976, had eight-voice polyphony,[20] as did the Yamaha GX-1 with total 18 voice polyphony, released in 1973.[21] Six-voice polyphony was standard by the mid-1980s. With the advent of digital synthesizers, 16-voice polyphony became standard by the late 1980s. 64-voice polyphony was common by the mid-1990s and 128-note polyphony arrived shortly after. There are several reasons for providing such large numbers of simultaneous notes:

  • Even with only ten fingers, it is possible to play more than ten notes at once. Notes may continue to sound even after a key is released. The synthesizer's resources may still be in use to produce the sound of the previously struck notes tapering off, especially when a sustain pedal is used.
  • A "sound" (also called a "timbre" or "patch") may be generated by more than one oscillator or sound-source to allow more complicated sounds to be produced. A synthesizer with 16 oscillators may be capable of 16-note polyphony only when simple, single-oscillator sounds are produced. If a particular patch requires four oscillators, then the synthesizer is only capable of four-note polyphony.
  • Synthesizers may be configured to produce multiple timbres (multitimbral), particularly necessary when sounds are layered or sequenced. Multitimbral instruments are always polyphonic but polyphonic instruments are not necessarily multitimbral. Some multitimbral instruments have a feature which allows the user to specify the amount of polyphony reserved or allowed for each timbre.

Note priority of synthesizer

File:Korg Monologue Synthesizer.jpg
The Korg Monologue is a monophonic synthesizer with two oscillators and programmable note priority.

Synthesizers generally use oscillators to generate the electric signal that forms the basis of the sound, often with a keyboard to trigger the oscillators. However, multiple oscillators working independently are a considerable challenge to implement. To double the polyphony, not only must the number of oscillators be doubled but the electronics must also function as a switch connecting keys to free oscillators instantaneously, implementing an algorithm that decides which notes are turned off if the maximum number of notes is already sounding when an additional key is pressed. There are several ways to implement this:

  • Turn off the first note sounded and use the newly freed oscillator to play the new note. With last note priority, priority is based on the order in which keys are played. When new notes are triggered while all voices are playing, the synthesizer frees up polyphony by ending the earliest played sounding note. This is the default mode on most synthesizers.
  • Ignore the newly depressed note. With first note priority, earlier notes are not cut off to make room for later ones, and once maximum polyphony has been reached, the person playing the instrument must stop playing one or more notes in order to trigger new ones.
  • In highest note priority, new notes that are higher in pitch than ones being already played replace currently playing notes from the lowest on up.
  • Lowest note priority works in the same way, but cuts notes from the highest down.

Modern synthesizers and samplers may use additional, multiple, or user-configurable criteria to decide which notes sound.

Inside of an acoustic piano
Each key on an acoustic piano is connected to its own hammer-and-string sound-producing mechanism.

Other instruments

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Keyboard instruments

Acoustic keyboard instruments

Almost all classical keyboard instruments are polyphonic. Examples include the piano, harpsichord, organ and clavichord. These instruments feature a complete sound-generating mechanism for each key in the keybed (e.g., a piano has a string and hammer for every key, and an organ has at least one pipe for each key.) When any key is pressed, the note corresponding to that key will be heard as the mechanism is activated.

Some clavichords do not have a string for each key. Instead, they will have a single string which will be fretted by several different keys. Out of the keys that share a single string, only one may sound at a time.

Electric keyboard instruments

The electric piano and clavinet rely on the same principles to achieve polyphonic operation. An electric piano has a separate hammer, vibrating metal tine and electrical pickup for each key.

With a few exceptions, electric organs consist of two parts: an audio-generating system and a mixing system. The audio-generating system may be electronic (consisting of oscillators and octave dividers) or it may be electromechanical (consisting of tonewheels and pickups), and it sends a large number of audio outputs to a mixer. The stops or drawbars on the organ modify the signal sent from the audio-generating system, and the keyboard switches the mixer's channels on and off. Those channels which are switched on are heard as notes corresponding to the depressed keys.

Stringed instruments

Classical instruments

In classical music, a definition of polyphony does not only mean just playing multiple notes at once but an ability to make audiences perceive multiple lines of independent melodies. Playing multiple notes as a whole, such as a rhythm from a chord pattern, is not polyphony but homophony.

A classical violin has multiple strings and indeed is polyphonic but harder for some beginners to play multiple strings by bowing. One needs to control the pressure, speed and angle well for one note before having an ability to play the multiple notes at acceptable quality expected by the composers.

Therefore, even though the violin family of instruments are misleadingly considered (when bowing) by general untrained musicians to be primarily monophonic, it can be polyphony by both pizzicato (plucking) and bowing techniques for standard trained soloists and orchestra players. The evidence can be seen in compositions since the 17th century such as Bach sonatas and partitas for unaccompanied solo violin.

Newer instruments

The electric guitar, just like the classical guitar, is polyphonic, as are various guitar derivatives (including the harpejji and the Chapman stick).

Wind instruments

Multiphonics can be used with many regular wind instruments to produce two or more notes at once, although this is considered an extended technique. Explicitly polyphonic wind instruments are relatively rare, but do exist.

The standard harmonica can easily produce several notes at once.

Multichambered ocarinas are manufactured in a number of varieties, including double, triple, and quadruple ocarinas, which use multiple chambers to extend the ocarina's otherwise limited range, but also enable the musician to play more than one note simultaneously. Harmonic ocarinas are specifically designed for polyphony, and in these instruments the ranges of the chambers usually overlap to some extent (typically at the unison, third, fourth, fifth, seventh or octave). Cross-fingering enables a single chamber to span an entire octave or more.

Recorders can also be doubled for polyphony. There are two types of double recorder; drone and polyphonic. In the drone type, one tube is tuned exactly like a regular recorder with a range of approximately two octaves, and the other tube is a drone and plays the tonic note of the scale. The polyphonic recorder has two tubes with a range of one major sixth. With overblowing, some notes can be played an octave higher, but it is not possible to achieve the range of an entire octave in one tube with these instruments.

Double zhaleikas (a type of hornpipe) also exist, native to southern Russia.

Launeddas are an Italian instrument, native to Sardinia that has both a drone pipe and two pipes capable of polyphony, for a total of three pipes.

See also

Formal classification system

References

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Bibliography

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  6. a b Script error: No such module "citation/CS1".
  7. a b c Script error: No such module "Footnotes"., "The first step was to use the new logic chips for monophonic, and then polyphonic keyboards. This was a major advance thanks to the use of digital scanning circuitry ... Tom Oberheim [was ?] licensed the [polyphonic] design as the basis for his Four Voice and Eight Voice polyphonic analogue synths of 1974.", "Emu first applied the new technology to keyboard and sequencer design with the 4060 Polyphonic Keyboard and Sequencer of March 1977"
  8. a b c Script error: No such module "Footnotes"., "Dave Smith, ... He called in at the Emu office in the summer of 1977 to discuss product ideas, and the advice was clear the killer product everyone was looking for at the time was an affordable programmable polyphonic analogue synth. Emu were already working towards such a synth, and had pioneered two of the three design concepts (the microprocessor keyboard, and the analogue chip voice card). All that remained was the microprocessor control of patches. ... Whilst Dave Rossum developed the operating system and oversaw the analog circuit design, Dave Smith focused on making patches programmable and designing the control surface. ... Emu agreed a royalty from Sequential that provided strong revenues once the Prophet 5 took off like a rocket in late 1978 and 1979."
  9. Template:Cite magazine
    abstract: "Features Armand Pascetta, a technician who developed the first polyphonic keyboard in the U.S. Reason behind the development of a content-addressable memory; List of clients of Pascetta, including synthesist Malcolm Cecil; Views of musician Don Lewis on playing the Pascetta keyboard again during a benefit concert."Script error: No such module "Check for unknown parameters". (quoted from Script error: No such module "citation/CS1".)
  10. Script error: No such module "Footnotes"., "The musician/technician Armand Pascetta was among the first to tackle synthesizer polyphony. Doing business as Electro Group, Pascetta wired Pratt-Reed keyboards to a unique processor (before microprocessors were commonly available) ... develop keyboards that responded to note velocity, release velocity, and aftertouch, and also allowed advanced functionality including keyboard splits and polyphony portamento. By the mid-1970s he's created pre-MIDI keyboard controllers capable of transmitting more than twelve separate channels of gate and voltage-control data and handling multiple synth modules, even across multiple networked keyboards."
  11. a b Script error: No such module "citation/CS1".
  12. a b Script error: No such module "Footnotes"., "... 1975. Tom subsequently licensed the polyphonic scanning keyboard developed by E-mu's Dave Rossum and paired it with multiple SEMs. By June 1975 he'd completed his Two Voice and Four Voice synths "
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  14. a b c Script error: No such module "Footnotes"., "JL: Your influence in the design of both the Prophet 5 and the equipment of Oberheim Electronics have been grossly overlooked. Would you care to comment on what you've done for both companies? / DR: Let me talk first about Tom Oberheim, whom I met at an AES convention in the spring of 1974. ... Towards the fall of that same year he visited E-mu to see our prototype polyphonic keyboard, and decided that he liked that design too. He felt that it too was patentable, and wanted to use it in a product. So we worked out an arrangement whereby he'd pay us royalties, and could use the circuit, and we would share in them benefits of the patent."
  15. a b Script error: No such module "Footnotes"., "JL: Your influence in the design of both the Prophet 5 and the equipment of Oberheim Electronics have been grossly overlooked. Would you care to comment on what you've done for both companies? / DR: ... The involvement with the Prophet 5 was very similar. Dave Smith had come to us for design help with other projects, when he decided to get into a synthesizer, he came over and basically started picking our brains from the beginning, which was an intelligent thing to do. We did some specific circuit designs for the Prophet 5, reviewed virtually everything in it, and gave him access to lots of E-mu documentation. Again, we had a royalty arrangement, the product went over well, and we made a lot of money...
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