ES2386215A1 - Midi wind controller for wind instruments of the harmonic series - Google Patents

Abstract

The invention relates to a controller comprising a MIDI configuration and communication device (5), and a wind instrument simulator (1). The simulator (1) comprises a casing (11) containing fingering sensors (2) and a mouthpiece (6) with an air flow passage (62) for air blown by the performer, said mouthpiece (6) containing a sensor for detecting the speed of the air flow so that the MIDI configuration and communication device (5) can determine the notes and effects created by said mouthpiece (6) and the sensors (2) that are arranged analogously to a reference acoustic instrument. The sensor for detecting the speed of the air in the mouthpiece (6) is a pressure sensor (3) associated with a canula (31) for measuring the dynamic pressure produced by the air flow during the articulation of a musical note.

Description

Object of the invention

The present invention relates to a MIOI wind controller for wind instruments that use the harmonic series as the basis for obtaining sound, such as flutes, txistus, bagpipes or the like with three or more holes, in which the reproduced note is given by the fingering on the mentioned holes and the articulation on the mouthpiece or nozzles by the interpreter.

Background of the invention.

Various types of harmonic series wind instruments are known which are mainly constituted by a body through which a flow of air impelled in some way by the interpreter passes, being in said body some holes or valves that allow varying the resonance of the instrument itself . The characteristics of the txistu (three-hole flute, spout or not, generation of different sounds with the same fingerings, etc.) are not exclusive to it but rather a series of wind musical instruments of different nature, as they can be:

to)

The whole family of instruments of the txistu (whistle txilibitu, txirula,

etc.)

b)

The trumpet and the entire Wind Metal family (trombone, fliscorno,

tuba, euphonium, etc.) that are characterized by using three or four valves with their different fingering combinations, to produce the sounds of the scales of their corresponding testings. To achieve this they need to repeat finger positions (fingering) to generate different sounds according to a harmonic series (common characteristic of all musical instruments to which this design is intended).

c) In general all the flutes of three or more holes, so common in the European continent, that operate by the principle of harmonic series so that with different fingerings different sounds are produced. Among many of them and by proximity we can cite flaviol in its different variants that, as an example to highlight, use the same exercises as a learning method in the conservatory

or similar that are used for learning txistu.

To delve into the subject it should be known that the three-hole flute is the generic name used for a whole family of flutes played with one hand. The other hand is dedicated to the accompaniment with a percussive instrument with a drum, psaltery or bell.

The three-hole flutes have two anterior fingering holes and one for the thumb. The diatonic scale notes are obtained with different intensities of air flow. In summary, the arrangement of the three lower notes may follow the Semitone-Tone-Tone, Tone-Halftone-Tone, Tone-Tone-Halftone pattern or the Tone-Tone-Tone pattern.

The MIOI protocol arose between 1982 and 1983 due to the need to unify the communication criteria between the numerous electronic instruments that were beginning to emerge. This allowed the connection of different sound units and / or effects of different brands regardless of the keyboard used. This protocol also allows communication with modern computer applications, multimedia presentations and video games.

The MIOI protocol transmits only instructions that tell the synthesizer what it should sound and how it should sound, but not the musical information as in an audio file. This is a great advantage, since a file containing high quality stereo audio needs about 10 Mbytes of data per minute of sound while a typical MIOI sequence requires less than 10 Kbytes of data per minute of sound. All sounds are generated by the controlling instrument, so the better this one, the better the result of the MIOI sequence.

In addition, mastering an instrument for which there is an MIOI controller allows the interpreter to obtain music from any other instrument without having to physically play it, but the original MI DI controller allows to transform its interpretation into the stream of notes and appropriate effects. . The clearest case is the case of the piano, since its interpreters can generate an interpretation of any instrument, for example a violin or saxophone, using a single keyboard and a sequencer or sound module, connected by a data cable and this protocol.

However, there are no MIOI controllers for all instruments. They are known, MIOI controllers for piano, guitar, violin and other less widespread, these controllers being mainly based on the performance of the interpreter on keyboards, piano case, or vibration measurement devices, such as the guitar case .

Within the range of MIOI wind instruments (MIOI wind controllers) or "electronic", there are many models available in the market but none of them can solve the difficulty of producing different sounds with the same fingering (this fingering being the same that of the original or acoustic instrument) without resorting to a key or device of "octave" (device that allows with a certain fingering, select the sound that should sound from among the possible ones, replacing the action that the interpreter does when characterizing the conditions when blowing).

In other words, the "articulation" that the interpreter must make in the mouth when blowing is replaced by an instruction given to a pedal, valve, switch, etc. Therefore, all similarity of interpretation with respect to the original instrument that is not to maintain the original fingering to which the above-mentioned substitute action must be added is eliminated.

Among the known background are:

-

OpenPipe Project: The objective of the project is to create an MIOI controller that looks similar to that of a flute or bagpipe. In this way, a musician used to play these wind instruments (or similar ones: clarinet, oboe ...) may use the OpenPipe for any musical activity mentioned above. The OpenPipe consists mainly of two parts that are: a cylinder about ten centimeters high and about two centimeters in diameter, with eight "sensors" that the musician will cover or uncover to generate a note, plus a "sensor" for additional control; a small processing unit, in which a microcontroller will be responsible for translating the information obtained through the "sensors" into MIOI information. It is about the interpreter typing as in the selected instrument but in no case the "articulation" (way in which the interpreter performs the "blow" on the mouthpiece to obtain the desired sound) is necessary, so it does not stop being a kind of keyboard on which it is typed as in a particular wind instrument, and yet, in no case the driven air is used.

the construction of a MIOI wind instrument, in which it must be blown in order to obtain a sound. However, instead of having only three valves (such as the acoustic trumpet), it has auxiliary buttons (Octave + and Octave-) in order to distinguish which sounds should be produced with the same fingering on the valves, since it is not through air control, how the information is obtained (case of an acoustic instrument).

-

Yamaha wx5 and Akai Ewi 4000: Because of their similarity, these instruments are in the same section. Both have been designed to be digitized as flutes or saxophones in which the air impelled by the interpreter activates the operation so that the fingering is the one that determines the sound to be delivered, that is, it acts merely as an on and off switch. . It is true that through the air some nuances such as vibratos and the intensity of the sound (greater or lesser volume of sound) can be implemented but in no way can different sounds (more than two) be decided by maintaining the same finger positions as This is the case of the trumpet, the txistu, etc.

-

Yamaha EZ-TP: Without a doubt, the only MIOI wind controller on the market that allows three different trumpet valves to distinguish the different sounds that can be obtained from a specific fingering. However, although the goal of respecting the fingering of the acoustic instrument achieves it, not so in the way it does. In this case it is true that the air is used for the realization of the vibrato and the expressions of "piano" and "loud" but any type of "articulation" for obtaining the note is non-existent, since to make it "sound" there is that singing in the mouthpiece, that is, the interpreter must sing the note that is intended to sound in a tuned way and the instrument transforms the voice into a trumpet sound or any MIOI sound of which it has preset.

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Japanese patent JP11 065562 of Sony Corp. In which an electronic flute can be connected to a MIOI device to generate an interpretation from an apparatus that presents sensors or push-buttons in scale like a conventional flute, but without any articulation element direct, executing the corresponding note or notes by varying the pressure in the sensors

Description of the invention

The MIOI wind controller for harmonic series wind instruments, object of this invention, presents technical particularities intended to allow an interpreter of a harmonic series wind instrument to control a musical reproduction instrument by MIOI protocol, as if I was interpreting this wind instrument with "blow" articulation in mouthpiece and fingering.

Thus, the MIOI wind controller for a harmonic series wind instrument object of the invention comprises a MIOI configuration and communication device and a wind instrument simulator comprising a housing with fingering sensors configured to detect the position of some fingering means of arrangement analogous to those of the wind instrument (ie of a conventional instrument). The simulator comprises a nozzle with a passage of a flow of air impelled by the articulation of the interpreter and a means of detecting flow to detect said air flow and because the MIOI configuration and communications device can determine the notes and effects executed by the interpreter from the air flow and the position of the fingering means, obtained by the flow detection means and fingering sensors. With this nozzle it is possible that the controller can determine the note executed by the interpreter and differentiate the notes that being different are executed with the same fingering. With this configuration the controller allows to determine the notes and effects in an identical way to the interpretation in a conventional acoustic wind instrument, thus allowing to control a sequencer, sound module or computer in which the performance is being played with any type of instrument, as is done with the MIOI controller pianos.

In a preferred embodiment it is provided that the flow detection means comprise a pressure sensor associated with a cannula facing the air inlet flow in the nozzle for measuring the dynamic pressure produced by said air flow in the articulation of a musical note ..

temperature, humidity, etc., constituting a module of low-cost sensors that obtain a reliable result, taking into account the numerous variables that can occur in the articulation of the note in the nozzle, such as humidity, temperature and others. Furthermore, said sensor module allows to capture the effects introduced in the execution, such as vibratos, pianos or fortes as variations of the dynamic pressure and other thermotechnical variables such as those mentioned above.

The nozzle has an air flow passage regulating device through the passage duct. This regulating device allows to adjust the resistance to the passage of the air through the nozzle, "softening" more or less the effort of articulation of the note, according to the taste of the interpreter.

In a basic form, the controller simulator is constituted by an outer housing in which the articulation nozzle and the fingering sensors are generally located. Special mention will be made in this report that the simulator has a traditional txistu shape (although it could have other different shapes, corresponding to any harmonic series wind instrument, such as flutes, trumpets, etc.) with the mouthpiece at the top end of the housing, two fingering sensors on its front, a fingering sensor on its back and a fingering sensor on its lower end, opposite the nozzle. This constitution is totally applicable to other flutes of three holes or more, and even to bagpipes and in general to wind instruments that use the harmonic series as the basis for obtaining the sound, with specialization in those in which the note executed depends on nozzle articulation and simultaneous fingering.

The simulator may have a drain or drain hole of the saliva connected to the nozzle outlet, preferably performed, but not necessarily on the back of the housing.

The MIOI configuration and communications device can comprise a microcontroller directly associated with the fingering sensors and the sensor module of the simulator nozzle, so that in a single device the detection of the note and effect executed is performed, and its conversion to the MIOI protocol for

In a practical embodiment, the MIOI configuration and communications device is arranged in a separate case or housing of the simulator, which allows the simulator to have a reduced weight and shape, which further resembles the real acoustic instrument, without the penalty of having to house all the components of the device, avoiding the experienced interpreter of the acoustic instrument problems of adaptation to the MIOI instrument.

The MIOI configuration and communications device and the simulator can be connected by a data and power cable or by a wireless data device and powered by batteries or solar energy. Said configuration and communications device have a display and operating controls to configure the MIOI data output, such as choosing the instrument bank, the instrument to be played, volume, semitone transpositions and other conventional parameters in a MIOI controller.

The fingering sensors can be constituted by photocells or any other pressure device or similar arranged at the height or behind corresponding holes of the simulator housing. These photocells measure the external luminosity to determine if the hole or fingering hole is totally or partially free or blocked by the finger of the interpreter according to the light intensity that arrives or if they are pressure sensors, depending on this and the position of the fingering on the corresponding hole. In general, all types of sensors can be used to establish the fingering order according to the clear fingering positions of the acoustic instrument. It is envisaged that the simulator has at least one reference sensor, configured by a photocell, for the calibration of the photocells of the fingering sensors, whereby the examination of the shutter state of the corresponding hole or hole is performed as a difference between the fingering sensor signal and the reference sensor signal. In this way, the fingering examination is stable regardless of the intensity of the ambient light in a high range of variation. In the event that the wind instrument comprises valves for fingering, the sensors will be configured to detect the movement of said valves.

It is envisioned that the controller may have at least one control of the sensitivity of the fingering sensors with respect to the reference sensor, such as a potentiometer in the simulator housing, whereby it is possible to set the points at which determines that a fingering hole is open or closed. In this way it is possible to regulate the controller for a more or less precise fingering, depending on whether the user is a student or an expert interpreter.

Other important functions of the MIOI controller are the ability to control the output volume, the inclusion of effects such as echoes or reverberations, a wider range of possible notes to play and many others.

With this invention it is desired to develop a traditional instrument and thus be able to bring advances in electronic music to the world of those who do not know how to play a standard piano keyboard, but rather a txistu or other instruments that they use as the basis for obtaining the sound. harmonic series Finally, create an instrument with clear didactic purposes. The txistu MIOI allows the student to see the score of what he plays and thus know his progress, use a wide range of sounds different from the instrument itself, rehearse with headphones to not disturb anyone or amplify the sound and thus equalize its volume to those of other instruments within a set.

Description of the figures.

To complement the description that is being made and in order to facilitate the understanding of the characteristics of the invention, a set of drawings is attached to the present specification in which, for illustrative and non-limiting purposes, the following has been represented:

Figure 1 shows a perspective view of the controller, showing the front face of the simulator.

Figure 2 shows a rear view of the controller simulator.

Figure 3 shows a view from the bottom end of the simulator.

Figure 4 shows a longitudinal section of the nozzle.

Figure 5 shows a detail of the section of one of the fingering sensors. Figure 6 shows a block diagram of the electronics of the

Preferred Embodiment of the Invention

As can be seen in the referenced figures, the MIOI wind controller for wind instruments is constituted by a simulator (1) with an outer shell (11) in the form of a traditional txistu and a series of sensors (2, 3) connected by means of a cable (4) or wireless device to a MIOI configuration and communications device (5) for connection via one or more ports

(51) to a sound module, sequencer, computer or analog that can be controlled by MIOI protocol.

The housing (11) of the simulator (1) has a hollow cylindrical shape, with a nozzle (6) arranged at the upper end, two holes (12a) in the front for the arrangement of two fingering sensors (2) and a reference sensor

(21) for calibration. On the back of the housing (11) there is another hole (12b) for a fingering sensor (2), and a corresponding second reference sensor (21). In said rear part of the housing (11) there is a drain hole (13) or drain of the saliva, connected with the nozzle (6). At the lower end of the simulator (1) there is a last fingering sensor (2), referenced to the reference sensor (21) of the previous part.

The nozzle (6) of the simulator consists of a body (61) in which an air passage (62) has been made between an inlet (63) through which the interpreter "blows" and an opposite outlet. On one side of the body there is a pressure sensor (3) associated with a transverse cannula (31) at one end, while the opposite end of the cannula (31) is bevelled and faces the inlet (63) of the air flow duct (62) for measuring the dynamic pressure. Inside the duct (62) there will be a series of sensors (not shown in the figures) that together with the pressure sensor (3) form a sensor module that will determine the conditions of speed, temperature, pressure, etc. of said air flow upon articulation of the note or "blow" by the interpreter, thus obtaining all the information required for the correct musical performance. The nozzle (6) has a screw passage regulator device (64), operable from the outside.

Each fingering sensor (2) or reference sensor (21) is constituted by a photocell disposed inside the housing (11) of the simulator (1) and faced with a hole (12a, 12b) of the housing, being the holes (12a, 1b) of the fingering sensors (2) suitable for sealing by the interpreter during the execution of a note in the use of the controller. The reference sensors (21) must always have the corresponding holes free for the correct capture of the ambient lighting intensity.

In this case, said photocells used are LOR photoresistors, arranged on a printed circuit board (not shown) housed inside the housing (11).

The MIOI configuration and communication device (5), comprises in a box a microcontroller (52) associated by the cable (4) with the sensors (2, 3) of the simulator (1) for continuous examination and presents an operating program with a part dedicated to determining the note and effect to reproduce according to the examination of the sensors (2, 3) and another part dedicated to the conversion of said note to communication in the MIOI protocol.

For the operation of the MIOI configuration and communication device (5) it is provided that it has a screen (53) and control knobs (54). The MIOI wind controller of this invention presents in said device (5) an electrical power source (55) that allows its operation.

In this case, a communications module (56) has been arranged between the microcontroller (7) and the port (51) MIOI.

Once the nature of the invention has been sufficiently described, as well as a preferred embodiment, it is stated for the appropriate purposes that the materials, shape, size and arrangement of the described elements may be modified, provided that this does not imply an alteration. of the characteristics

Claims (13)

1.-MIOI wind controller for a harmonic series wind instrument, comprising a MIOI configuration and communications device (5) and a wind instrument simulator (1), this simulator (1) comprising a housing (11) with fingering sensors (2) configured to detect the position of a fingering means of arrangement similar to those of a reference acoustic wind instrument, characterized in that the simulator (1) comprises a nozzle (6) with a passage (62) of a flow of air impelled by the articulation of the interpreter and a means of detecting flow (3) to detect said air flow and because the device (5) configuration and communications MIOI can determine the notes and effects executed by the interpreter from the air flow and the position of the fingering means, obtained by the flow detection means (3) and fingering sensors (2). 2. Controller according to claim 1, characterized in that the flow detection means (3) comprise a pressure sensor associated with a cannula (31) facing the air inlet flow in the nozzle (6) for the measurement of the dynamic pressure produced by said air flow in the articulation of a musical note. 3.-Controller, according to any of the preceding claims, characterized in that the nozzle (6) has a regulating device (64) for the passage of air flow through the passage duct (62). 4. Controller according to claim 1, according to any of the preceding claims, characterized in that the simulator (1) comprises a nozzle (6) at the upper end of the housing (11), two holes (12a) in the part front of the housing (11), a hole (12b) in the back of the housing (11), two fingering sensors (2) in correspondence with the holes (12a) in the front part of the housing, a sensor fingering (2) in correspondence with the hole (12b) on the back of the housing and a fingering sensor (2) at its lower end, opposite the nozzle (6). 5.-Controller according to claim 4, characterized in that the simulator 6.-Controller, according to any of the preceding claims, characterized in that the simulator (1) has a drain hole (13) or saliva drain, connected to the outlet of the nozzle (6). 7.-Controller, according to any of the preceding claims, characterized in that the fingering sensors (2) are constituted by photocells. 8. Controller according to any of the preceding claims, characterized in that the simulator (1) comprises at least one reference sensor (21) configured by a photocell for calibration of the photocells of the fingering sensors (2). 9.-Controller, according to any of the preceding claims, characterized in that it comprises a control regulating the sensitivity of the fingering sensors (2) with respect to the reference sensor (21). 10. Controller according to any of the preceding claims, characterized in that the MIOI configuration and communications device (5) comprises a microcontroller (52) directly associated with the fingering sensors (2) and the flow detection means (3) of the nozzle (6) of the simulator (1). 11.-Controller according to claim 10, characterized in that the device (5) configuration and communications MIOI is arranged in a box or case independent of the simulator (1). 12. Controller according to claim 10, characterized in that the MIOI configuration and communications device (5) and the simulator (1) are connected by a data and power cable (4). 13. Controller according to claim 10, characterized in that the device (5) MIOI configuration and communication and the simulator (1) is connected by wireless methods and the power supply is done by an autonomous device 14.-Controller, according to claim 10, characterized in that the device (5) configuration and communications have a screen (53) and controls (54) of 5 operation to configure the MIOI data output, such as choosing the instrument bank, the instrument to be played, volume, semitone transpositions and other parameters of the MIOI standard.