JPH0746957Y2 - Electronic musical instrument - Google Patents

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention makes it possible to variably and smoothly control the characteristics of generated musical tones by a simple operation that does not hinder performance.
Regarding electronic musical instruments.

[Prior Art and Problems Thereof] Electronic musical instruments are provided with means for variably controlling the pitch, tone color, volume, etc. relating to the characteristics of generated musical tones. In a conventional electronic wind instrument, the characteristics of generated musical tones are variably controlled by control information from various sensors built in the mouthpiece or its vicinity. For example, regarding the pitch, the CPU that controls the electronic circuit of the entire musical instrument by detecting the strength with which the performer bites the mouthpiece formed of rubber, and the pitch control information (lip information) corresponding to this biting strength is detected. Is provided with a lip sensor for outputting the tone color and volume, the strength or amount of the breath (blowing) of the performer is detected, and the tone color or volume corresponding to the intensity or amount of the breath is detected. Control information (breath information)
A breath sensor that outputs to the CPU is provided.

However, in the electronic wind instrument, as in the above-mentioned prior art, in the case of variably controlling the pitch or the like related to the characteristic of the generated musical tone, with the control information output from the lip sensor or the breath sensor incorporated in the mouthpiece or the vicinity thereof, Since the characteristics of the generated musical tones vary depending on the strength of the performer's mouthpiece biting and the strength or amount of the breath,
The control step of the characteristic becomes narrower, so that it is difficult to control the wide and smooth characteristic.

By the way, in the case of an electronic keyboard instrument such as an electronic synthesizer or an electronic piano, a rotary volume is used as a means for variably controlling the characteristics of the generated musical sound, and a wheel provided on the keyboard instrument body is used on the volume axis of this volume. By connecting and rotating the wheel with one hand during performance, the pitch and modulation related to the characteristics of the generated tone are variably controlled. This method of rotating the wheel to variably control the characteristics of the generated musical sound can widely and smoothly change the characteristics of the generated musical sound. But,
In an electronic wind instrument, both hands are closed to hold the instrument and generate musical sounds (pitch specification keys, etc.), so the wheel that can be rotated with one hand, such as that provided on electronic keyboard instruments, etc. Cannot be provided.

Therefore, in recent years, various electronic wind instruments have been proposed that are capable of variably and smoothly varying the characteristics of generated musical tones with a simple operation that does not hinder performance (for example, Japanese Patent Laid-Open No.
63-5392). However, although each of them can perform variable control of one type of characteristic in the generated tone, it is not possible to perform variable control of a plurality of different types of characteristic in the generated tone.

[Purpose of Invention] This invention was made in view of the above circumstances.
It is therefore an object of the present invention to provide an electronic musical instrument capable of widely and smoothly variably controlling a plurality of types of characteristics of different musical tones by an operation that does not hinder performance.

In order to achieve the above object, the electronic musical instrument of the present invention is provided with a sliding member that is slidable in the axial direction of the mouthpiece mounting portion of the musical instrument body in order to achieve the above object. While being rotatably coupled to the outer end surface of the member by a mounting member, when the mouthpiece is moved and operated with respect to the wind instrument main body, different characteristic control of the generated musical sound is performed according to the moving direction of the mouthpiece. The main point is to do so.

[Embodiment] Hereinafter, an embodiment of the present invention will be specifically and specifically described with reference to the drawings.

FIG. 1 is a side view of the entire electronic wind instrument according to the first embodiment of the present invention, FIG. 2 is an enlarged side sectional view showing the vicinity of the mouthpiece of the electronic wind instrument, and FIG. II
It is sectional drawing which follows the I line.

This electronic wind instrument is a saxophone (alto sax)
The wind instrument body 1 has a bell portion 1a, a main portion 1b, and a mouth pipe portion 1c. In the bell portion 1a of the wind instrument body 1 as described above, a speaker 2 for producing a musical sound is attached with its sound emitting surface 2a facing the bell opening end. Further, a large number of pitch designating keys 3 etc. for designating a pitch are attached to the upper surface (the left end surface in the figure) of the main portion 1b, and the octave is designed to the lower surface (the right end surface in the figure). Octave designating key 4 and right thumb rest part 5 that also functions as a strap locking part
Etc. are attached inside, and a musical tone is generated based on the pitch information designated by the pitch designation key 3 and the breath information from the breath sensor 6 built in the mouthpiece 7 attached to the end of the mouth pipe 1c. A controller 8 and the like for generating and outputting the musical sound signal to a sound system including the speaker 2 and the like are attached. in this case,
The wind instrument main body 1 is made of synthetic resin and is an upper and lower split body. The mouthpiece 7 is made of rubber having appropriate elasticity. The breath blown from the mouthpiece 7a in the mouthpiece 7 is discharged to the outside through a discharge hole 7c provided at the end of the breath passage 7b.

As shown in FIGS. 2 and 3, the mouthpiece 7 attached to the mouth pipe portion 1c of the wind instrument body 1 slides inside the mouth pipe portion 1c in the axial direction (arrows z, z'directions). Sliding member 9 made of synthetic resin movably fitted
Is connected to the end of the mouse pipe section 1c through. In this case, the sliding member 9 slides in the mouth pipe portion 1c in the axial direction by a certain range (distance). A coil spring 12 is interposed between a flange portion 10 formed on the outer peripheral surface on one end side of the sliding member 9 and a flange portion 11 formed on the inner peripheral surface of the mouth pipe portion 1c.
FIG. 2 shows a case where the coil spring 12 is restored and is in a natural state. In this state, the outer end surface 13 of the sliding member 9 contacts the inner surface of the end wall 14 of the mouth pipe portion 1c and is in the initial position. This position is a reference position (non-operation position) where the mouse pipe 7 is not slid in the mouse pipe portion 1c. When the sliding member 9 in such a state applies a force in the z direction to the mouthpiece 7 in the reference position, the sliding member 9 slides in the z direction until the flange portion 10 thereof compresses the coil spring 12 to the maximum (the mouthpiece 7 Move range). On the other hand, when the z-direction force applied to the mouthpiece 7 is removed, the sliding member 9 slides in the z'direction by the restoring force of the compressed coil spring 12 and returns to the initial position. As a result, the mouthpiece 7 also returns to the reference position.
A hemispherical surface 15 is formed on the axis of the outer end surface 13 of the sliding member 9 as described above.
Are formed. On the other hand, the base end portion 16 of the mouthpiece 7 has a hemispherical shape. The mouthpiece 7 engages the hemispherical base portion 16 with the hemispherical surface 15 of the sliding member 9 in a state in which the hemispherical surface 15 is rotatable in the bending direction with respect to the mouth pipe portion 1c, and A holding member (which is a bellows member in the example, but may be a coil spring or the like) 17 having an ability to follow is held in an engaged state with the sliding member 9 (prevention of disengagement)
By doing so, the connection with the sliding member 9 is made. Therefore, in FIG. 2, the mouthpiece 7 at the reference position (non-operating position) has its base end portion 16 as a fulcrum of rotation to bend in the mouth pipe portion 1c, that is, the arrow X, X'direction and the arrow Y, It is possible to rotate in the Y'direction. One end of the holding member 17 is fixed to the end wall 14 of the mouth pipe portion 1c, and the other end is fixed to a flange portion 18 formed on the outer peripheral surface of the mouthpiece 7.

Then, the X of the mouthpiece 7 is attached to the sliding member 9,
A rotation sensor 1 that detects the amount of rotation in the X'direction and the amounts of rotation in the Y and Y'directions and outputs a rotation signal corresponding to the amount of rotation.
9 and 20, and a slide type variable resistor 21 for detecting the amount of movement of the mouthpiece 7 in the Z and Z'directions and outputting a movement signal according to the amount of sliding. Rotation signals from each of these rotation sensors 19 and 20 and a slide type variable resistor
The movement signals from 21 are parameters for controlling the characteristics of generated musical tones. A rotation sensor 19 for detecting the amount of rotation of the mouthpiece 7 in the X and X'directions has a rotation shaft 22 of Y and Y '.
It is housed and fixed in a housing recess 23 formed in the outer end surface 13 of the sliding member 9 so as to be parallel to the line. The rotation sensor 20 for detecting the amount of rotation of the mouthpiece 7 in the Y and Y'directions is a storage recess formed in the outer end surface 13 of the sliding member 9 so that the rotation axis 24 thereof is parallel to the X and X'lines. It is stored and fixed in 25. The rotation shafts 22 and 24 of the rotation sensors 19 and 20 are provided with rollers 26 and 27 which are in sliding contact with the hemispherical base end portion 16 of the mouthpiece 7. Each of these rollers
Reference numerals 26 and 27 are for transmitting the rotation of the mouthpiece 7 to the rotation shafts 22 and 24 of the rotation sensors 19 and 20, but at the same time, the base end portion 16 of the mouthpiece 7 is attached to the hemispherical surface 15 of the sliding member 9. It also has a function for positioning. This function is for each roller 2
6 and 27 also serve as guide rollers 28 for supporting the base end portion 16 of the mouthpiece 7 at three points. The guide roller 28 is rotatably housed in a housing recess 29 formed in the outer end surface 13 of the sliding member 9, and is in sliding contact with the base end 16 of the mouthpiece 7. Now, as shown in FIG. 4 (a), the mouthpiece 7
If the base 16 is rotated in the X and X'directions using the base end 16 as a rotation fulcrum, the rotation shaft 22 of the rotation sensor 19 for detecting the rotation amount of the mouthpiece 7 in the X and X'directions has a hemispherical shape. Base part 16
The rotation of the roller 26 in sliding contact with the roller causes rotation in the X direction or the X'direction. Further, as shown in FIG. 4 (b), if the mouthpiece 7 is rotated about the base end portion 16 in the Y and Y'directions, the amount of rotation of the mouthpiece 7 in the Y and Y'directions. Axis of rotation sensor 20 to detect
The rotation of the roller 27 in which 24 slides in contact with the hemispherical base end portion 16 rotates in the Y direction or the Y'direction. At this time, the rotation sensors 19 and 20 output a rotation signal according to the rotation amount of the rotation shafts 22 and 24. When the mouthpiece 7 is rotated in the intermediate direction between the X, X'directions and the Y, Y'directions with the base end portion 16 as the rotation fulcrum, both rotation sensors 19, 20.
Both rotation shafts 22 and 24 of the rotation sensors 22 and 24 rotate in the X and Y directions, or the X and Y'directions, the X'and Y directions, and the X'and Y'directions. Respectively output a rotation signal according to the rotation amount. FIG. 5 shows an output example of the rotation sensors 19 and 20. A in the figure indicates the output when the mouthpiece 7 is rotated to the maximum in the X direction. In this case, the output of the rotation sensor 19 is +100 and the output of the rotation sensor 20 is ± 0. B indicates the output when the mouthpiece 7 is rotated to the maximum in the Y direction. In this case, the rotation sensor 19
Output is ± 0, and the output of the rotation sensor 20 is +100. C shows the output when the mouthpiece 7 is rotated to the maximum in the intermediate direction between the X direction and the Y'direction. In this case, the rotation sensor 19
Output is +100, and the output of the rotation sensor 20 is -100. D: The mouthpiece 7 is X'in the middle direction between the X'direction and the Y direction.
In the case of maximum rotation in the Y direction at the intermediate position in the direction, the output of the rotation sensor 19 is -50, and the output of the rotation sensor 20 is +100. E is mouthpiece 7 X '
In the intermediate direction between the Y-direction and the Y'direction, the case where both the X'direction and the Y'direction are rotated to the intermediate position is shown. In this case, the output of the rotation sensor 19 is -50 and the output of the rotation sensor 20 is -50. .

On the other hand, the slide type variable resistor 21 for detecting the amount of movement of the mouthpiece 7 in the Z and Z'directions is a storage recess 30 formed on the outer peripheral surface of the sliding member 9 so as to be parallel to the Z and Z'lines. It is stored and fixed inside. In this case, the slide shaft 31 of the slide type variable resistor 21 is connected to the flange portion 11 of the mouth pipe portion 1c.
Is engaged with an annular groove 32 provided in the. As shown in FIG. 4 (c), if the mouthpiece 7 moves in the Z and Z'directions, the sliding member 9 slides in the mouth pipe portion 1c in the Z and Z'directions. As a result, the slide shaft 31 of the slide type variable resistor 21 slides in the Z direction or the Z'direction, and the slide type variable resistor 21 outputs a movement signal according to the slide amount of the slide shaft 31.

The rotation signal from each of the rotation sensors 19 and 20 and the movement signal from the slide type variable resistor 21 are sent to a tone generation circuit or an effect addition circuit provided in the controller 8, where they are added. The characteristics of the generated musical tone are controlled based on the output. In the illustrated example, the pitch of the musical tone generated by the rotation signal from the rotation sensor 19, the vibrato of the musical tone generated by the rotation signal from the rotation sensor 20, and the movement signal from the slide type variable resistor 21 are generated. The chorus of musical tones is assigned to be variably controlled according to each output. The rotation signals output from both the rotation sensors 19 and 20 at the same time can be used for another characteristic control, but here, another characteristic control is not assigned. Therefore, when both the rotation sensors 19 and 20 simultaneously output a rotation signal, the pitch and vibrato of the generated musical tone are variably controlled at the same time according to the outputs. The rotation signal of either the rotation sensor 19 or the rotation sensor 20 and the slide type variable resistor 21.
, The pitches or vibrato of the generated musical tones and the chorus are variably controlled at the same time.

FIG. 6 shows an example of a control circuit for variably controlling generated musical tones. The rotation signals from the rotation sensors 19 and 20 provided on the sliding member 9 in the mouth pipe section 1c are sent to the musical tone generating circuit 33 in the controller 8, while the movement signal from the slide type variable resistor 21 is sent. It is sent to the effect adding circuit 34 in the controller 8. The tone generation circuit 33 is supplied with breath information from the breath sensor 6, pitch information designated by each pitch designation key 3, and octave designation information designated by the octave designation key 4. The tone generation circuit 33 uses the breath information from the breath sensor 6 and the pitch designation key 3
A predetermined musical tone is generated based on the pitch information specified by the and the octave specification information specified by the octave specification key 4, and the rotation signals S ₁ and S ₂ from the rotation sensor 19 or the rotation sensor 20 are generated here. When supplied, it produces a pitch or vibrato tone according to its output. on the other hand,
When the movement signal S ₃ from the slide type variable resistor 21 is supplied to the effect adding circuit 34, the tone generating circuit 33 is generated according to the output thereof.
Add a chorus effect to the musical sound generated in. The musical sound to which the chorus effect is added by the effect adding circuit 34 is a sound system composed of an amplifier, a speaker, etc. not shown.
Pronounced by 35.

According to the electronic wind instrument of the embodiment having the above-mentioned configuration, while holding the wind instrument body 1 with both hands and operating the pitch designating key 3 and the octave designating key 4 with the fingers, the breathing operation is carried in the mouth. With the mouthpiece 7 that is running, you can easily change the characteristics of different musical tones (pitch, vibrato, chorus) by simply swinging your head up and down or left and right, or by swinging your head back and forth. Independently and independently, wide and smooth variable control can be performed.

In the first embodiment, the mouthpiece 7 is rotatably connected to the mouthpipe portion 1c, and the rotation amount of the mouthpiece 7 in the X and X'directions and the Y and Y'directions is detected by the rotation sensor 19 respectively. , 20. However, such a method can also be achieved in the configuration of the second embodiment shown in FIGS. 7 and 8.

In the case of the second embodiment shown in FIGS. 7 and 8, the mouthpiece 7'is rotatably connected to the sliding member 9'through a long ball shaft 36. In this case, the ball shaft 36
The screw portion 37 at one end of the ball is screwed to the base end portion 16 'of the mouthpiece 7', and the ball portion 38 at the other end of the ball shaft 36 is slidable member 9 '.
Is coupled to the outer end of the pair of spherical pairs. Mouthpiece 7 '
Can be rotated in the X, X'directions and Y, Y'directions with the ball portion 38 of the ball shaft 36 as a rotation fulcrum. The rotation sensors 19 ', 20' are housed and fixed in housing recesses 39, 40 formed in the peripheral wall of the mouth pipe part 1'c. In this case, the rotation sensors 19 'and 20' are arranged at 90 degrees, and their rotation axes 22 'and 24' are orthogonal to the axis of the mouth pipe section 1c. Rotation axis 2 of each rotation sensor 19 ', 20'
2'and 24 'have arcuate shapes which are rotatable about the rotation shafts 22' and 24 respectively in the mouth pipe portion 1'c in a direction orthogonal to the axis of the mouth pipe portion 1'c. Linkages 41 and 42 made of strips are joined together. Each linkage
One end of 41, 42 is fixed to the rotary shafts 22 ', 24', and the other end is rotatably supported by a bolt 43 screwed to the peripheral wall of the mouth pipe portion 1'c. In this case, both linkages 4
1, 42 are arranged in a crossing state. Each linkage 4
Guide grooves 44, 45 are formed in the portions 1, 42, and the ball shaft 36 is passed through the guide grooves 44, 45.

In the case of such a configuration, when the mouthpiece 7'is rotated in the X and X'directions with the ball portion 38 of the ball shaft 36 as a fulcrum of rotation, its movement is linked via the ball shaft 36.
The rotation shaft 22 'of the rotation sensor 19' for transmitting the rotation amount of the mouthpiece 7'in the X, X'directions is transmitted by the rotation of the linkage 41 in the X, X'directions.
19 'outputs a rotation signal according to the rotation amount of the rotation shaft 22'. In this case, since the ball shaft 36 slides in the guide groove 45 of the other linkage 42, the linkage is
42 does not rotate. On the other hand, the mouthpiece 7'is the ball shaft 36.
When the ball portion 38 is rotated in the Y and Y'directions, the movement is transmitted to the linkage 42 via the ball shaft 36, and the linkage 42 is rotated in the Y and Y'directions. The rotation shaft 24 'of the rotation sensor 20' for detecting the amount of rotation of the mouthpiece 7'in the Y, Y'direction is rotated by the rotation sensor 2 '.
0'will output a rotation signal according to the amount of rotation of the rotary shaft 24 '. In this case, the ball shaft 36 slides in the guide groove 44 of the other linkage 41, so the linkage
41 does not rotate. And the mouthpiece 7'is the ball shaft.
With the ball portion 38 of 36 as the fulcrum of rotation, the X, X'directions and Y,
When it is rotated in the direction intermediate to the Y'direction, the movement is transmitted to both linkages 41, 42 via the ball shaft 36, and the amount of rotation of the mouthpiece 7'in the X, X'directions. Both rotation shafts 22 'and 24' of the rotation sensor 19 'for detecting the rotation amount and the rotation sensor 20' for detecting the amount of rotation in the Y and Y'directions rotate, and the rotation sensors 19 'and 20 respectively rotate the rotation shaft 22'. ′,
A rotation signal corresponding to the amount of rotation of 24 'will be output.

In the second embodiment, the same components as those in the first embodiment are designated by the same reference numerals and the description thereof is omitted.

FIG. 9 shows the mouthpiece 7 ″ in the X, X ′ directions and Y,
A third embodiment is shown in which the light emitting element and the light receiving element detect the amount of rotation in the Y'direction and the amount of movement in the Z, Z'directions.

In the third embodiment, the mouthpiece 7 "is connected to the sliding member 9" by a spherical pair, and is rotatable in the X, X'directions and the Y, Y'directions orthogonal thereto. . A light emitting element 47 such as a light emitting diode is provided on the axis of the spherical base end portion 46 of the mouthpiece 7 ″, and the light emitting element 47 such as a light emitting diode is provided on the spherical surface 48 of the sliding member 9 ″ facing the base end portion 46 end surface. Is provided with a plurality of light receiving elements 49 such as phototransistors. As shown in FIG. 10, the light receiving elements 49 are arranged in a matrix on a flexible resin sheet 50 at predetermined intervals. By adhering the resin sheet 50 to the spherical surface 48, the arrangement of each light receiving element 49 on the spherical surface 48 is made, but at this time, a reference light receiving element that outputs a reference output (enclosed by a broken line in FIG. 10). The light receiving element 49 'is arranged on the axis of the sliding member 9 "(Fig. 9) to face the light emitting element 47 on the side of the mouthpiece 7" at the reference position.

In such a configuration, when the mouthpiece 7 ″ is rotated in the X, X ′ directions or the Y, Y directions with the spherical base end portion 46 as the rotation fulcrum, the base end portion 46 emits light. The light of the light emitting element 47 is received by the light receiving element 49 on the locus of the light emitting element 47 and output.In this case, the output value of each light receiving element 49 is different for each light receiving element 49.
The output value of is based on the output value of the reference light receiving element 49 ',
The output value in the X direction is higher than that in the X'direction,
The output value in the Y direction is set to be higher than that in the Y'direction, and it is determined at which position the light receiving element 49 the output is placed at the set output value.
Therefore, when the controller 8 receives an output from the light receiving element 49 due to the rotation of the mouthpiece 7 ", the rotation direction of the mouthpiece 7" is the X, X'direction or the Y, Y'direction depending on the output value. Whether or not the characteristic of the generated musical sound aligned in that direction is variably controlled according to the output value of the light receiving element 49.

On the other hand, the movement amount of the mouthpiece 7 ″ in the Z and Z ′ directions is detected by the light emitting element 51 provided on the outer peripheral surface of the sliding member 9 ″.
Corresponding to the light emitting element 51, a plurality of light receiving elements 52 are provided on the inner peripheral surface of the mouth pipe portion 1 "c.
The light receiving elements 52 are arranged at a predetermined interval in the axial direction of the mouth pipe portion 1 "c, and emit light as the mouthpiece 7" moves in the X and X'directions.
Outputs when 51 light is received. In this case, each light receiving element 49
The output value of is different for each light receiving element 49, and the controller 8 moves by moving the mouthpiece 7 ″.
When there is an output from, the characteristic of the generated musical tone assigned according to the output value is variably controlled.

In the third embodiment, the same components as those in the first embodiment are designated by the same reference numerals and the description thereof is omitted.

[Effects of the Invention] As described above, according to the electronic musical instrument of the present invention, the sliding member that is slidable in the axial direction of the mouthpiece mounting portion of the musical instrument body is provided inside the musical instrument body, While being rotatably coupled to the outer end surface of the sliding member by a mounting member, when the mouthpiece is moved and operated with respect to the musical instrument body, characteristic control of different musical sounds generated according to the moving direction of the mouthpiece can be performed. I am trying to do it.
Therefore, it is possible to widely and smoothly variably control a plurality of types of characteristics having different musical tones by an operation that does not hinder the performance.

[Brief description of drawings]

The drawings each show an embodiment of the present invention, and FIG. 1 is a side view of the entire electronic wind instrument according to the first embodiment of the present invention, and FIG.
The figure is an enlarged side sectional view showing the vicinity of the mouthpiece of the electronic wind instrument, FIG. 3 is a sectional view taken along the line III-III in FIG. 2, and FIGS. 4 (a), (b) and (c). Is an operation explanatory view of the mouthpiece in the electronic wind instrument, FIG. 5 is a diagram showing an output example when the mouthpiece is rotated in the electronic wind instrument, and FIG. 6 is a control circuit diagram of a musical tone in the electronic wind instrument,
FIG. 7 is a side sectional view showing an essential part of an electronic wind instrument according to a second embodiment of the present invention, and FIG. 8 is a VIII-VIII in FIG.
9 is a sectional view taken along the line, FIG. 9 is a side sectional view showing an essential part of an electronic wind instrument according to a third embodiment of the present invention, and FIG. 10 is a facing part of a mouthpiece of a sliding member of the electronic wind instrument. It is the front view which showed the light receiving element arrange | positioned at the surface. 1 ... wind instrument body, 1c, 1'c, 1 "c ... mouth pipe part, 7, 7 ', 7" ... mouthpiece, 9, 9',
9 "... sliding member, 16, 16 ', 46 ... base end, 19, 1
9 ', 20, 20' ... Rotation sensor, 21 ... Sliding type variable resistor, 47,51 ... Light emitting element, 49,49 ', 52 ... Light receiving element.

Claims (5)

[Scope of utility model registration request] 1. A sliding member which is slidable in the axial direction of a mouthpiece mounting portion of the musical instrument body is provided inside the musical instrument body.
The mouthpiece is rotatably coupled to the outer end surface of the sliding member by a mounting member, and when the movement detecting means detects that the mouthpiece is moved with respect to the musical instrument body, the movement detecting means. The electronic musical instrument is characterized in that the musical tone characteristic control means controls the characteristic of the generated musical tone differently according to the moving direction of the mouthpiece detected by. 2. The slide member is provided with a slide type variable resistor for detecting the amount of movement of the mouthpiece, and a musical tone characteristic control means produces a musical tone based on the output of the slide type variable resistor. 2. The electronic musical instrument according to claim 1, wherein further different characteristic control is performed. 3. A light emitting element is provided on an outer peripheral surface of the sliding member, and a plurality of light receiving elements, which are output when light from the light emitting element is received, are provided on an inner peripheral surface of the musical instrument body. Multiple pieces are provided in the axial direction of the piece attachment part,
The electronic musical instrument according to claim 1, wherein the musical tone characteristic control means controls the characteristic of the generated musical tone differently based on the output of each of the light receiving elements. 4. The musical instrument body is provided with a plurality of rotation sensors for detecting the rotation amount of the mouthpiece for each rotation direction of the mouthpiece, and the musical tone characteristics are based on the output of each rotation sensor. The electronic musical instrument according to claim 1, wherein the control means controls different characteristics of the generated musical tones. 5. A light emitting element is provided on the end face of the base end portion of the mouthpiece, and an output is provided when light from the light emitting device is received on the surface of the musical instrument body facing the end face of the base end portion of the musical instrument body. The plurality of light receiving elements are provided in a matrix form, and the tone characteristic control means controls the characteristics of different musical tones based on the output of each of the light receiving elements. Electronic musical instrument.