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Hydraulophone
Other instrument
Other namesWoodwater instrument
Classification
Hornbostel–Sachs classificationNaN
(Hydraulophone)
Playing range
Basic range of a diatonic hydraulophone with 12 water jets:

More detailed ranges and compasses appear below.
Related instruments
Musicians
Waterflute (reedless) hydraulophone with 45 finger-embouchure holes, allowing an intricate but polyphonic embouchure-like control by inserting one finger into each of several of the instrument's 45 mouths at once.

A hydraulophone is a tonal acoustic musical instrument played by direct physical contact with water (sometimes other fluids) where sound is generated or affected hydraulically.[1][2] Typically sound is produced by the same hydraulic fluid in contact with the player's fingers.[3] The term also refers to an acoustic sound-producing mechanism used as an interface or input device involving the monitoring of fluid flow. Examples include hydraulophones for fluid-flow monitoring and measurement applications, such as building automation, equipment monitoring, and the like (for example, determining which faucet or toilet in a building is operating and how much water it is consuming).[4] The hydraulophone in the first sense was invented and named by Steve Mann.

Types of hydraulophone and basic operation

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This article concerns itself with hydraulophones that are musical instruments, or sound sculptures.

The term may be applied based on the interface used to play the instrument, in which a player blocks the flow of water through a particular hole in order to sound a particular note, or based on a hydraulic sound production mechanism. Hydraulophones use water flow sound producing mechanisms. They have a user interface, which is blocking water jets to produce sound. Those described in [2] use water jets striking perforated spinning disks, shafts, or valves, to create a pulsating water flow, similar to a siren disk. A single disk, shaft, or valve assembly can have rings or passages with different numbers of holes for different notes. Some hydraulophones have reeds (one or more reed for each finger hole) and some are reedless, having one or more fipple mechanism [2] associated with each finger hole, thus having no moving parts to wear out.

Blocking flow through a finger hole directs the water instead to one or more of the above-described sound-production mechanisms, or resulting changes in flow or pressure affect a separate sounding mechanism associated with each finger hole.[2]

Some hydraulophones include an underwater hydrophone pickup to allow the sounds produced by the water to be electrically amplified. Electric amplification allows effects to be added (as with an electric guitar) as well as making the hydraulophone a hyper-acoustic instrument (that is, using computation to change the acoustic sound of the water into some other instrument).[5]

Relationship to woodwind instruments

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The hydraulophone is similar to a woodwind instrument, but it runs on incompressible (or less compressible) fluid rather than a compressible gas like air. In this context hydraulophones are sometimes called "woodwater" instruments regardless of whether or not they are made of wood (as woodwind instruments are often not made of wood).

Hydraulophone embouchure

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The water must be "blown" into the hydraulophone by way of a pump which can be hand-operated, wind operated, water powered, or electric. Unlike woodwind instruments in which there is one mouthpiece at the entrance to the flute chamber, hydraulophones have mouthpieces at every exit port from the chamber.

Whereas internal ducted flutes have one fipple mechanism for the mouth of the player, along with several finger holes that share the one fipple mechanism, the hydraulophone has a separate mouth/mouthpiece for each finger hole. A typical park-hydraulophone for installation in public spaces has 12 mouths, whereas a concert hydraulophone typically has 45 mouths.

Embouchure is controlled by way of the instrument's mouths, not the player's mouth such that the player can sing along with the hydraulophone (i.e. a player can sing and play the instrument at the same time). Moreover, the instrument provides the unique capability of polyphonic embouchure, where a player can dynamically "sculpt" each note by the shape and position of each finger inserted into each of the mouths. For example, the sound is different when fingering the center of a water jet than when fingering the water jet near the periphery of the circular mouth's opening.

12-jet diatonic hydraulophones

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Many diatonic hydraulophones are built with 12 water jets, one for each of the 12 notes. The standard compass starts on A, extending up an octave and a half to E. We say 1½ octaves in the sense that the high E has a frequency that is (2 * 1.5 = 3) times as large as that of the low A, i.e. an octave (8va) plus a perfect fifth (P5) higher.

Extended playing ranges for a diatonic 12-water-jet hydraulophone

The standard A to E range, in which it is possible to play with polyphonic embouchure on any or all diatonic notes at the same time, is shown on the left side of the diagram. When playing only monophonically, some additional range is possible on certain hydraulophones, indicated here by small cue notes at the end-points.

Left, the extended notes come from closing key change valves or flexing key change levers, for sharpener, and flattener. To play a low G, one must be playing in C minor (with Ab) and close the flattener valve simultaneously. When playing on the high E jet, closing the sharpener valve produces an F.

With change-valves, the diatonic hydraulophone is polyphonic in the same sense as a so-called "chromatic harmonica" --- you can play chords and move all members of a chord down one semitone or up one semitone together, but the function of the valves is usually not separated to work on a per-note basis, so for example, you can play an A-minor chord, and flex the entire chord down to A-flat minor, but you can't easily play an A major chord without the use of polyphonic embouchure to bend only the middle note to a C# (which requires more skill than the average hydraulist has). Thus the "diatonic" hydraulophone is called "diatonic" conservatively to "under promise and over-deliver".

Finally, on the right, the additional extended range comes from the two octave-change valves (all notes can be shifted as many as two octaves down, or one octave up).

45-jet chromatic hydraulophones (concert hydraulophones)

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Playing range of a 45-jet hydraulophone

Whereas park and pool hydraulophones are usually 12-jet diatonic, concert-hydraulophones are usually 45-jet chromatic.

45-jet hydraulophones have a 3½ octave range of A to E, chromatic, plus an additional A-flat below the lowest A. The playing compass (45 water jets) is the same as the sounding range (45 notes).

12-jet hydraulophones are installed in public spaces, but there is a 45-jet south hydraulophone at the Ontario Science Centre, a concert-hydraulophone having this precise range and compass.

Cold weather hydraulophones

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Hot tub hydraulophone
Hydraulists performing for Canada's National Capital Commission in Ottawa, at Winterlude 2010, on a hydraulophone built into a SpaBerry
Hydraulist performing for Canada's National Capital Commission in Ottawa, at Winterlude 2010, during a daytime winter concert.

Hydraulophones may be built into hot tubs for use in cold weather. This solves the problem of keeping the hydraulist warm, as well as keeping the hydraulic fluid (e.g. water) heated by way of standard pumping and heating equipment. In this kind of hydraulophone (e.g. balnaphone, from the Greek "balnea" meaning "bath") the hydraulist is immersed in the hydraulic fluid used by the instrument.

Video from EyeTap wearable camera system; song is Huron Carol; Une Jeune Pucelle

Relationship to other musical instruments in the orchestra

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Musical instrument classification by physics-based organology

The hydraulophone does not fit in a standard musical instrument classifications scheme (that was in existence before the invention of the hydraulophone). To relate the Hydraulophone to other instruments, a physics-based organology has been introduced, subsequent to the invention of the hydraulophone. In this scheme, the top-level category of classification is the state-of-matter of that which initially produces the sound in the instrument.[6]

The first three-categories of the Hornbostel Sachs system fall under the first category of the physical organology system, as they all produce sound from matter in its solid state.

This physical organology is as follows:

  • 1 Gaiaphones (Earth/Solid), instruments in which the initial sound-production medium is by matter in its solid-state, e.g. the piano.
    • 1.1 Chordophones: sound produced by solids that are essentially 1-dimensional (having a cross-section much smaller than their length, i.e. strings), e.g. violin, guitar, electric guitar, electric bass, etc.;
    • 1.2 Membranophones: sound produced by solids that are essentially 2-dimensional (much thinner than their surface area) membranes, e.g. drums;
    • 1.3 Idiophones: sound produced by bulk 3-dimensional solid matter, e.g. crystallophone, glass harmonica, xylophone, metallophone, etc., regardless of whether the instrument is operated underwater or in air;
  • 2 Hydraulophones (Water/Liquid): sound produced by matter in its liquid state; instrument itself may be played underwater or played in a surrounding medium of air, with water supplied only to the internal workings of the instrument:
    • 2.0 Waterflutes (reedless hydraulophones);
    • 2.1 Single-reed hydraulophones (typically having 1 reed for each finger hole);
    • 2.2 Double-reed hydraulophones (typically having 2 reeds for each finger hole);
    • 2.3 Polyreed hydraulophones (typically having 3 or more reeds for each finger hole);
  • 3 Aerophones (Air/Gas): sound produced by matter in its gaseous state, e.g. woodwind instruments and brass instruments;
  • 4 Plasmaphones/Ionophones (Fire/Plasma): sound produced by matter in a high-energy state such as plasma, e.g. plasmaphone, etc.;
  • 5 Quintephones (Quintessence/Idea): sound produced informatically, by electrical, optical, mechanical, or other computational/algorithmic means.[6]

Classifications based on surrounding media

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Solid, Liquid, and Gas (left-to-right) instruments, all three immersed in Liquid. The immersional (surrounding) media does not dictate the primary top-level musical instrument classification, although it greatly changes the sound (i.e. dampens the guitar without changing the fact it is a chordophone, and silences the recorder).

At the International Computer Music Conference in 2007, the conference theme was Immersed Music and featured some immersed performances and concerts. This raised some important questions regarding the role of the surrounding medium (air or water) in which a musical instrument is played, as well as the role of water in other non-hydraulophonic instruments.

For example, Benjamin Franklin's glass (h)armonica remains a friction idiophone regardless of the fact that it is played by wet fingers. A version of the armonica designed to be played underwater was recently created. This version is still a friction idiophone, not a hydraulophone.

Likewise, arrays of drinking glasses tuned with water are still idiophones, as the water is not what produces the initial sound, but is merely a tuning element.

Relationship between hydraulophone and the "strings, percussion, wind" taxonomy

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Traditionally the orchestra is divided into three sections, strings, percussion, and wind. With strings and percussion instruments, the sound is produced by matter in its solid state, as for example, with a piano (which is both a string and a percussion instrument). With wind instruments sound is produced by matter in its gaseous state.

Hydraulophones add a new category of instruments in which sound is produced by water, unlike previously known instruments like the glass harmonica and the crystallophone which are idiophones that merely use the water to tune them or to enhance the friction. For example, the glass (h)armonica is a friction idiophone in which sound is produced by solid matter (glass), not liquid, even though liquid (water) is often present on the fingers of the armonist. The crystallophone is also an idiophone, in which water is used to change the tuning, but not to produce the actual sound. Thus hydraulophones form a unique class of instruments in which sound is actually produced by the water itself.

Relationship to the pipe organ

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Many hydraulophones include a separate water-filled pipe for each note, and have sound-production means similar to pipe organs (but with water rather than air), while maintaining the flutelike user-interface (finger embouchure holes).

This form of hydraulophone is similar to an organ, but has water flowing through the pipes instead of air flowing through the pipes.

Relationship to the piano

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On a concert hydraulophone, the finger holes are arranged like the keys on a piano, i.e. there is a row of uniformly spaced holes close to the player, and a row of holes that are in groups of 2, 3, 2, 3, ..., a little further from the player. Whereas the piano and organ both have a similar kind of keyboard layout, the response ("key action") is different. Pianos tend to respond to velocity (how quickly a key is struck), whereas organs tend to respond to displacement (whether or not a key is pressed down). Hydraulophones tend to respond to absement (the time-integral of displacement), as well as to displacement, velocity, and to some degree jerk and jounce [1].

Relationship to instruments that use other states of H2O

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Pagophone uses H2O in its solid state (i.e. ice), in contrast to the hydraulophone which typically uses H2O in its liquid state (i.e. water)

The hydraulophone uses liquid, typically water, H2O. It is thus related to the pagophone, an instrument that uses H2O in its solid state (i.e. ice), and the calliope, an instrument that uses H2O in its gaseous state (steam).

World's largest hydraulophone

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World's largest outdoor hydraulophone that's publicly accessible 24 hours-a-day at Ontario Science Centre Toronto Canada

Presently the world's largest hydraulophone is the main architectural centerpiece out in front of the Ontario Science Centre, one of Canada's landmark architecture sites. It is also Toronto's only freely accessible aquatic play facility that runs 24 hours a day.

Markings on standard 12-jet hydraulophone

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Braille markings above finger holes on a classroom hydraulophone used for teaching visually impaired students. The letter "L" denotes jet number 12 (rightmost in the sequence of 12 water jets).

Because the water-spray from hydraulophones obscures vision (or because hydraulophones are played underwater where visibility is poor), finger holes are sometimes encoded in Braille. Braille has the added advantage that the one-to-one correspondence between letters and numbers is the same as the standard A-minor hydraulophone, i.e. jet 1 is A, jet 2 is B, jet 3 is C, etc.. The skill (intricate sense of tactility) needed to play a hydraulophone well is also similar to the skill needed to read Braille.

A, 1 B, 2 C, 3 D, 4 E, 5 F, 6 G, 7 H, 8 I, 9 J, 0 K L

(12 sets of dots typically made from brass pins above each finger hole)

Manufacturers

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Hydraulophones are currently manufactured by:

  • WhiteWater West in British Columbia, manufacturers of the AquaTune cylindrical-bore hydraulophone, and of the "Nessie" tapered-bore instrument;
  • SCS Interactive, in Ogden, UT (business offices in Denver CO), manfacturers of the tapered-bore instrument called the "Hydrophone";
  • FUNtain Corporation in Toronto, Ontario, Canada, manufacturers of a wide variety of hydraulophones and hydraulophone-related products.

See also

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References and notes

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  1. ^ "Fluid Melodies: The hydraulophones of Professor Steve Mann" In WaterShapes, Volume 10, Number 2, Pp36–44, New York, NY, USA
  2. ^ a b c d Mann, S. Hydraulophone design considerations: absement, displacement, and velocity-sensitive music keyboard in which each key is a water jet, International Multimedia Conference archive, Proceedings of 14th annual ACM international conference on Multimedia, Pp 519–528, Santa Barbara, CA, USA Cite error: The named reference "absement" was defined multiple times with different content (see the help page).
  3. ^ Mann, S. flUId Streams: Fountains that are keyboards with nozzle spray as keys..., Proceedings of ACM Multimedia 2005, Pp. 181–190, Singapore
  4. ^ Janzen, R. and Mann, S. Arrays of water jets as user interfaces: Detection and estimation of flow by listening to turbulence signatures using hydrophones. Proceedings of the 15th International Conference on Multimedia, Pp. 505–508, Augsburg, Germany, 2007
  5. ^ The Electric Hydraulophone: An acoustic hyperinstrument with feedback, International Computer Music Conference, Pp. 162, Copenhagen, Denmark
  6. ^ a b Natural Interfaces for Musical Expression: Physiphones and a physics-based organology, in Proceedings of the 2007 Conference on New Interfaces for Musical Expression (NIME07), Pages 118–123, New York, NY, USA
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