JPH0823747B2 - Electronic brass instrument - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an electronic brass instrument that utilizes vibration of the lips to switch pitches.

[Conventional technology]

The brass instrument is a general term for lip-and-lead type instruments that vibrate both lips of the player to produce a sounding body. In a brass instrument such as a trumpet, selective operation of three valves and low-pitched operation of lips and expiratory pressure are combined to produce a musical sound having a desired pitch.

Therefore, in an electronic brass instrument imitating such a brass instrument, since the pitch is specified by three valve switches, it is necessary to switch the pitch as in the brass instrument as a natural musical instrument.

Conventionally, in an electronic brass instrument, for example, as shown in FIG. 9, a valve switch 41, 42, 43 is arranged in a musical instrument body 2 and a mouthpiece 6 is provided, and a harmonic overtone is switched on the opposite side of the mouthpiece 6. The rotary switch 8 for is attached. In such an electronic brass instrument, the mouthpiece 6 is used in the same manner as a brass instrument which is a natural musical instrument.
Put your forefinger on your mouth, put your index finger on the valve switch 41, your middle finger on the valve switch 42, and your ring finger on the valve switch 43, and selectively operate the valve switches 41 to 43, and rotate the rotary switch 8 with your left hand as necessary. The desired pitch is obtained.

[Problems to be Solved by the Invention]

By the way, as described above, switching of the overtones by the rotary switch 8 requires an operation completely different from that of a brass instrument as a natural musical instrument, so that the operation requires skill and there is a possibility that the operation interferes with the performance.

Conventionally, as an electronic musical instrument imitating a wind instrument
There is No. 1 "Electronic Wind Instrument". In such a recorder-type electronic musical instrument having a plurality of push buttons, since both hands are used for playing, it is not possible to play with one hand like a trumpet.

Therefore, it is a first object of the present invention to provide an electronic brass instrument in which the pitch is switched according to the vibration of the lip with respect to the mouthpiece.

When the player vibrates his lips, the resonance tube coupled to the mouthpiece produces a resonance sound corresponding to the intensity of the applied vibration of the lips.

Therefore, a second object of the present invention is to provide an electronic brass instrument that realizes musical tone control by using the level of resonance sound as control data.

[Means for solving the problem]

(Claim 1) In order to achieve the first object, the electronic brass instrument of the present invention has a pitch designating means (valve switch 41-
43), a resonance tube (10) which is coupled to the mouthpiece (6) and resonates with the vibration of the lip with respect to the mouthpiece, and a resonance sound detecting means (vibration sensor 12) for detecting the resonance tube generated in the resonance tube. And pitch information for generating pitch information indicating the pitch of the musical tone signal to be generated according to the pitch designated by the pitch designating means and the pitch of the resonance sound detected by the resonance sound detecting means. It is provided with a generating means (musical sound control section 20).

(Claim 2) In order to achieve the second object of the electronic brass instrument of the present invention, in addition to the configuration of claim 1, the resonance sound detecting means (vibration sensor 12, breath sensor 30) detects the resonance sound. Volume detection means for detecting the volume of the resonance sound (volume information detection section 18, 3
2) and volume information generating means (tone control section 20) for generating volume information indicating the volume of the musical tone signal to be generated according to the volume of the resonance sound detected by the volume detecting means. is there.

[Action]

(Claim 1) This electronic brass instrument is provided with a pitch designating means corresponding to a brass instrument as a natural musical instrument such as a trumpet, and the pitch designating means is used to designate a pitch by a fingering method similar to that of a natural musical instrument. Be seen.

A resonance tube that resonates with the vibration is connected to the mouthpiece on which the player applies vibrations of the lip, and a resonance sound corresponding to the vibration of the lip is obtained by the resonance tube.

Therefore, the resonance sound is detected by the resonance sound detecting means, and the pitch information generating means generates the resonance sound according to the pitch specified by the pitch specifying means and the pitch of the resonance sound detected by the resonance sound detecting means. Pitch information indicating the pitch of the musical tone signal to be generated is generated.

By doing so, the pitch can be easily switched by an operation similar to the operation of the natural musical instrument, and an arbitrary pitch can be designated.

(Claim 2) Further, the resonance sound obtained by the resonance tube has a level corresponding to the vibration of the player's lips. Therefore, in the volume information generating means,
The volume information indicating the volume of the musical tone signal to be generated is generated according to the volume of the resonance sound detected by the volume detecting means.By adjusting the vibration of the lips, the musical tone of the level intended by the player can be obtained. To be

〔Example〕

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the drawings.

1 to 4 show one embodiment of the electronic brass instrument of the present invention. FIG. 1 is the overall configuration of the electronic brass instrument, FIG. 2 is the configuration of the instrument main body, and FIG. Specific configurations of the mouthpiece, the resonance tube, and the resonance sound detecting means, and FIG. 4 shows a specific configuration example of the valve switch.
Each item will be described with reference to the drawings.

a. Overall configuration of electronic brass instrument As shown in FIG. 1, the instrument body 2 has a resonance tube 10 (third part) in response to vibration of a lip applied to a mouthpiece 6 by a player.
A vibration sensor 12 is installed as a resonance sound detecting means for detecting the resonance sound obtained in FIG. The vibration sensor 12
It is composed of a vibrating electric conversion means such as a condenser microphone for detecting sound or vibration obtained through the resonance tube 10, and generates a resonance sound signal V _L representing sound / vibration.

By the way, this resonance sound signal V _L has a waveform depending on the characteristics determined by the shape of the resonance tube 10 such as the diameter and the length,
Since the frequency component thereof depends on the vibration of the lips and the amplitude thereof corresponds to the vibration amplitude of the lips, it is controlled by adjusting the vibration of the lips of the player.

The resonance sound signal V _L is amplified by the amplifier 14 and then added to the pitch information detector 16 and the volume information detector 18. The pitch information detecting section 16 is installed as means for detecting pitch data D _f representing the height of the resonance tone from the resonance tone signal V _L as switching data for pitch switching, and the volume information detecting section 18 determines the volume level of the musical tone. It is installed as a means for detecting the volume data D _v for controlling the above.

Therefore, the pitch information detecting unit 16 is provided with a fundamental wave extracting unit 162 including a filter and the like, and the fundamental wave signal S _L1 is extracted from the resonance sound signal V _L. This fundamental wave signal S _L1 is frequency-divided by a frequency divider 164 installed for simplification of signal processing by an arbitrary frequency division ratio N, and then added to an analog-digital converter (ADC) 166. It is converted into a digital signal to obtain pitch data D _f . This pitch data D
_f is added to the tone control section 20 as pitch switching data.

Further, in the volume information detection unit 18, a noise filter 182 is installed, and after the resonance signal _VL is passed through the noise filter 182 to remove unnecessary components, it is added to the analog / digital converter (ADC) 184. It is converted into a digital signal and the volume data D _v is detected. The volume data D _v obtained by the ADC 184 is added as the tone control data to the tone control unit 20 which controls the tone generation of the tone and its volume level.

Further, the musical instrument body 2 is provided with first, second and third valve switches 41, 42 and 43 as pitch specifying means. The switch signals S ₁ , S ₂ and S ₃ representing the pitch obtained by the selective operation of each of the valve switches 41 to 43 are converted into digital signals by the analog-digital converter (ADC) 22 and then the musical tone is generated. It is added to the control unit 20.

The musical tone control unit 20 is provided with a memory for storing a musical tone control program for controlling musical tones, an arithmetic processing unit, and a memory for storing data in the process of calculation, pitch selection, pitch from the pitch information detecting unit 16 Control of pitch switching, musical tone generation and volume control thereof is performed according to the data D _f . Note that the tone control section 20 is added with tone change data D _i obtained by operating a tone change switch (not shown) to perform tone change control.

The musical tone data D _o obtained by the musical tone control unit 20 is added to a tone generator 24 which generates a musical tone signal and converted into a musical tone signal V _M. The musical tone signal V _M is applied to the sound system 26 connected to the musical instrument body 2, converted into a musical tone through the amplifier and the speaker forming the sound system 26, and is produced.

b. Instrument body As shown in FIG. 2, the instrument body 2 has a rectangular tube shape, and a hook 200 for hanging a thumb on the lower surface side thereof.
And a hook 202 for hanging the little finger is formed on the upper surface thereof. The hook 200 can be provided with a key change switch operated by the thumb.

A support cylinder 204 is provided at one end of the musical instrument body 2 with a mouthpiece 6 for attaching vibration and expiratory pressure of the lips attached to the support cylinder 204. , 202, the first, second and third valve switches 41 to 43 are installed so as to be operable by the index finger, the middle finger and the ring finger. In addition, the instrument body 2
On the opposite side of the mouthpiece 6, a drain 206 for discharging saliva that has entered the mouthpiece 6 is formed, and a connector 208 for taking out an output signal of the musical sound control unit 20 is provided.

c. Mouthpiece and resonance sound detecting means As shown in FIG. 3, the mouthpiece 6 is inserted into a support tube 204 provided in the musical instrument main body 2 together with a bowl-shaped contact portion 602 for putting a lip on it. A portion 604 is formed. The insertion portion 604 has a cylindrical shape corresponding to the insertion hole 216 formed in the support cylinder 204, and a ventilation hole 606 for causing an expiratory pressure to act therein is formed therein. The end portion of the insertion portion 604 is coupled to the resonance tube 10 installed inside the musical instrument body 2. The resonance tube 10 vibrates on the mouthpiece 6 side to input the vibration.
2, the inner diameter of the vibration input section 102 side is matched with the ventilation hole 606, and the inner diameter is gradually increased to increase the musical instrument body 2.
The vent hole 104 is opened to the outside from the lower surface side of the instrument, and the vent hole 104 resonates with the vibration of the lips of the player, and has a suitable form in which the pitch of the resonance sound is changed by adjusting the vibration.

A resonance sound extraction hole 106 for extracting resonance sound is formed on the wall surface of the resonance tube 10.
A vibration sensor 12 for electrically detecting the sound or vibration of the resonance sound is fitted in 06.

Therefore, when the player applies the mouthpiece 6 to the lips and vibrates the lips facing the inside of the mouthpiece 6 by the expiratory pressure, the vibration acts on the resonance tube 10 through the vent holes 606 of the mouthpiece 6, and A resonance sound corresponding to the vibration component is obtained. Therefore, the vibration sensor 12 detects the resonance sound generated by the resonance tube 10 and obtains the resonance sound signal V _L representing the pitch and volume level thereof.

d. Valve switch In the valve switches 41 to 43, for example, as shown in FIG. 4A, a shaft 402 is integrally attached to the central portion of a disk-shaped switch button 400 to be operated by a finger. A rubber switch 404 that is opened and closed by the vertical movement of the shaft 402 is installed.

A guide portion 406 for guiding the vertical movement of the shaft 402 is formed on the outer surface portion of the musical instrument body 2, and a cylindrical case portion 408 corresponding to the guide portion 406 is formed on the inner surface portion thereof. 408 is a coil-shaped spring 41 facing the downward movement of the shaft 402 to exert an elastic force.
Contains 0. A pressing plate 412 attached to the shaft 402 is installed between the upper surface of the spring 410 and the inner wall surface of the musical instrument body 2. Also, the case part 4
A guide portion 414 for guiding the vertical movement of the shaft 402 is provided on the bottom surface of 08, and a disc-shaped contact end portion 416 is attached to the tip end portion of the shaft 402 corresponding to the rubber switch 404. .

The rubber switch 404 is attached to the fixed contact 420 on the substrate 418 installed in the musical instrument body 2 and the inner surface of the movable portion 422 formed in a semicircular shape with an elastic body such as rubber with respect to the fixed contact 420. And a movable contact 424.

Then, as shown in FIG. 4 (B), a force is applied to the elastic force of the spring 410 by a finger to apply the force to the switch button 400.
Lower the contact end 4 on the tip of the shaft 402.
The movable portion 422 of the rubber switch 404 is pushed down by 16 and the gap between the movable contact 424 and the fixed contact 420 is closed, and the switch signals S _{1 to} S ₃ are obtained to the selected valve switches 41 to 43.

When the force of the finger is released, the switch button 400 is pushed up by the spring 410, the movable portion 422 of the rubber switch 404 returns to its original shape by its elasticity, and the movable contact 424 separates from the fixed contact 420.

e. Description of operation The operation of the above configuration will be described.

The thumb 2 is hooked on the hook 200, the little finger is hooked on the hook 202, the index finger is placed on the valve switch 41, the middle finger is placed on the switch button 400 of the valve switch 43, and the ring finger is placed on the switch button 400 of the valve switch 43 to support the instrument body 2. Then, the player puts his lips on the mouthpiece 6, vibrates the lips by the action of the expiratory pressure, and selectively operates each of the valve switches 41 to 43 from the fully opened state, whereby the pitch of the resonance sound obtained according to the vibration of the lips. Depending on the data D _f ,
As shown in FIG. 5, the pitches of C ^{# to} G are designated by the overtones. In this case, as shown in FIG. 6, the valve switch
41 represents a whole tone (♭♭), valve switch 42 represents a half tone (♭), and valve switch 43 represents one tone and a half (♭♭♭).

Further, when the player increases the vibration of the lips, the sound is switched to the third harmonic according to the pitch data D _f of the resonance sound obtained by the vibration, and G ^# is operated by selectively operating the valve switches 41 to 43 from the fully open state. The pitches of ~ C are specified.

Further, when the player further increases the vibration of the lips, the harmonic overtone is further increased according to the pitch data D _f of the resonance sound obtained by the vibration, and C ^# ~ E is selectively operated by the valve switches 41-43. The pitch of is specified. In FIG. 5, (2), (3), ... (12) represent overtone magnifications.

In addition, when the expiratory pressure is applied according to the specified pitch, the musical tone is generated by the action of the expiratory pressure, and the musical tone is generated by the volume level of the resonant sound obtained through the resonance tube 10 by the vibration of the lips. The volume level of is controlled.

Then, the musical tone control section 20 obtains musical tone data D _o having elements such as pitch and volume, and this musical tone data D _o is the musical tone control section.
Added from 20 to the tone generator 24. Therefore, the tone signal V _M corresponding to factors such as pitch and volume is read from the tone generator 24, and the sound system 26
In addition to the pitch specified by the player, and if necessary, the musical tone of the level is pronounced.

Further, for example, if a key change switch is installed on the hook 200, this key change switch can be made to function as a brass instrument having four valve switches in addition to the valve switches 41 to 43. For example, the electronic brass instrument described in 1. can be used as the F to B ♭ tubes.

f. Other Embodiments In the electronic brass instrument of the present invention, for example, as shown in FIG. 7, a branch pipe 108 is formed in the vibration input section 102 that does not affect the resonance characteristic of the resonance pipe 10, and the branch pipe 108 is formed. The breath pressure is applied to the breath sensor 30 through the ventilation pipe 110 from 108,
The breath data obtained by the breath sensor 30 can be used for controlling the volume of a musical sound.

Then, for example, as shown in FIG. 8, if the volume information detecting section 32 is configured, the breath signal V _B obtained by the breath sensor 30 is amplified by the amplifier 322 and then converted into an analog signal.
It is converted into a digital signal by a digital converter (ADC) 324 and added to the tone control section 20. Therefore, in the tone control unit 20, the breath data D _B obtained by the volume information detection unit 32
The volume of the musical sound to be generated can be controlled according to the magnitude of the breath pressure represented by, and the required volume can be adjusted by the breath.

In this case, in the tone control section 20, even if the volume information detection section 18 shown in FIG. 1 is provided with the volume information detection section 32 shown in FIG. 8 and both data D _V and D _B are used for tone control. Well again
Either one is installed and volume data D _V or breath data D _B
Any of the above may be used to control the volume of the musical sound to be generated.

In each of the examples, the data obtained by the vibration sensor 12 can be used for floating type data processing in which the change in the vibration level is added to the initial value data, and a slight increase or decrease in pitch due to resonance does not occur. , And can be used as pitch bend data for adding an effect such as vibrato or slur to a musical sound.

In the embodiment, the vibration sensor 12 is described as an example that converts pressure into an electric signal.
A material that can be detected by a change in inductance according to the resonance sound of the resonance tube 10 may be used as the material 12. Further, the pitch switching is not limited to each overtone, but may be every five degrees, for example.

〔The invention's effect〕

As described above, according to the present invention, the following effects can be obtained.

(A) It is possible to switch to any pitch by adjusting the vibration of the lips, and it is possible to realize any pitch in combination with the designation of the pitch designating means, and moreover, it is possible to perform with one hand operation. Therefore, it is possible to perform with the same operation as a natural musical instrument, and it is possible to increase the degree of freedom of performance.

(B) Also, since the level of the resonance sound obtained by the resonance tube changes depending on the adjustment of the vibration of the lips, the volume level of the musical sound to be generated can be adjusted, and the performance can be performed with a natural feeling like a natural musical instrument. it can.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of the electronic brass instrument of the present invention, FIG. 2 is a perspective view showing a concrete configuration example of the musical instrument body of the electronic brass instrument shown in FIG. 1, and FIG. FIG. 4 is a vertical cross-sectional view showing a specific configuration example of a mouthpiece, a resonance tube and a resonance sound detecting means in the musical instrument body of the electronic brass instrument shown in FIG. 2, and FIG. 4 is a valve switch in the instrument body shown in FIG. FIG. 5 is a sectional view showing a concrete configuration example and its operation, FIG. 5 is a diagram showing a pitch in response to fingering and pressing in the electronic brass instrument shown in FIG. 1, and FIG. 6 is shown in FIG. FIG. 7 is a view showing the pitch of a valve switch in an electronic brass instrument, FIG. 7 is a sectional view showing a resonance tube portion of a musical instrument body in another embodiment of the electronic brass instrument of the present invention, and FIG. 8 is an electronic brass instrument of the present invention. FIG. 9 is a block diagram showing another embodiment of FIG. Is a perspective view showing the instrument. 2 ... Instrument body 6 ... Mouthpiece 10 ... Resonance tube 12 ... Vibration sensor 16 ... Pitch information detecting section (resonance sound detecting means) 18 ... Volume information detecting section (volume detecting means) 20 ... Music tone control section (pitch information generating means) , Volume information generating means) 41 to 43 ... Valve switch (pitch specifying means)

Claims (2)

[Claims] 1. A pitch designating means for designating a pitch, a resonance tube coupled to a mouthpiece for resonating with a vibration of a lip relative to the mouthpiece, and a resonance sound detection for detecting a resonance sound generated in the resonance tube. Means, and pitch for generating pitch information indicating the pitch of the musical tone signal to be generated according to the pitch designated by the pitch designating means and the pitch of the resonance sound detected by the resonance sound detecting means. An electronic brass instrument characterized by being provided with an information generating means. 2. The electronic brass instrument according to claim 1, further comprising volume detecting means for detecting a volume of the resonance sound detected by the resonance detecting means, and volume of the resonance sound detected by the volume detecting means. Depending on,
An electronic brass instrument, comprising: volume information generating means for generating volume information indicating the volume of a tone signal to be generated.