JP2019133040A - Operating device and electronic musical instrument - Google Patents

Abstract

To provide an operation device and an electronic musical instrument capable of realizing a plurality of instructions by a user such as a modulation and a pitch bender by the operation of one operator.SOLUTION: A first operation element 3 and detection parts 40, 41, and 52 for detecting the operation of the operation element 3, and when a first operation is performed to apply a force in a first direction in the operation element 3, the operation is displaced in the first direction, and when the second operation is performed to hold the displacement state at the time when the operation is stopped, the displacement is displaced in the first direction, furthermore when the second operation is stopped, it is configured to return to an initial state which is not displaced in the second direction, and the detection units 40, 41, and 52 are configured to detect the displacement amount in the first direction and the displacement amount in the second direction.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an operating device and an electronic musical instrument.

2. Description of the Related Art Conventionally, there is known an operation device that performs a predetermined input or the like by sliding an operation element.
For example, Patent Document 1 includes a continuously variable operator and a detection unit that detects an operation amount of the continuously variable operator in an electronic keyboard instrument. A configuration is disclosed in which a slide performance method or a legato performance method can be simulated by converting into discrete pitch changes in semitone units.
Further, in Patent Document 1, an operation unit (for example, a modulation operation unit of an electronic musical instrument) that maintains the state of an operator that has been displaced by the operation of the operator, and an operator that has been displaced by the operation of the operator. It is equipped with both types of operation units that return to the initial state after operation (for example, Pitch Bender for electronic musical instruments), and modulation and pitch bender can be adjusted by operating each operation unit. ing.

JP-A-9-44150

However, in the conventional configuration as described in Patent Document 1, a mechanical structure and a circuit system are required for each of the modulation operation unit and the pitch bender.
For this reason, the mounting volume becomes large, and the mounting position and the mounting form in the entire electronic musical instrument are restricted.
In general, for example, a wheel-like operation element is used for both the modulation operation unit and the pitch bender, and the operation is performed by sliding or rotating the operation element. When two operating elements are provided, it is difficult for the user to know which function has which function, and it is easy to make an operation error.
Furthermore, since the two operating elements are generally similar in shape, there is a possibility that they are erroneously mounted during production.
The same problem occurs when the user gives a plurality of instructions even with an operator other than the operator that instructs the modulation or the pitch bender.

  The present invention has been made in view of the circumstances as described above, and provides, for example, an operating device and an electronic musical instrument capable of realizing a plurality of instructions by a user such as modulation and pitch bender by an operation with a single operator. It is intended to do.

In order to solve the above problems, an operating device according to the present invention includes:
One operation element, and a detection unit that detects an operation of the operation element,
When the first operation that applies force in the first direction is performed, the one operation element is displaced in the first direction and maintains a displacement state at the time when the first operation is stopped. When a second operation is performed to apply a force in a second direction different from the first direction, the displacement is in the second direction, and the second operation is stopped. , Configured to return to an initial state not displaced in the second direction,
The detection unit is configured to be able to detect a displacement amount in the first direction and a displacement amount in the second direction.

  According to the present invention, for example, a plurality of instructions by a user such as modulation and pitch bender can be realized by an operation with a single operator.

It is an operation device concerning this embodiment, and an important section top view of an electronic musical instrument to which this is applied. It is a typical principal part perspective view which shows the internal structure of an operating device. (A) is principal part sectional drawing which shows the detailed structure of a board | substrate and a carbon sheet, (b) is a top view of a carbon sheet. (A) And (b) is sectional drawing which follows the IV-IV line in FIG. It is sectional drawing of the modification of the operating device shown to Fig.4 (a) and FIG.4 (b). It is sectional drawing of the modification of the operating device shown to Fig.4 (a) and FIG.4 (b). It is sectional drawing of the modification of the operating device shown to Fig.4 (a) and FIG.4 (b). (A) And (b) is sectional drawing which follows the VIII-VIII line in FIG. It is sectional drawing of the modification of the operating device shown to Fig.8 (a) and FIG.8 (b). It is sectional drawing of the modification of the operating device shown to Fig.8 (a) and FIG.8 (b). It is sectional drawing of the modification of the operating device shown to Fig.8 (a) and FIG.8 (b). (A) is explanatory drawing which shows typically the structure for detecting a slide operation, (b) is an equivalent circuit schematic in the case shown to (a), (c) is a change of a voltage value. It is a graph which shows. (A) is explanatory drawing which shows typically the structure for detecting a slide operation, (b) is an equivalent circuit schematic in the case shown to (a), (c) is a change of a voltage value. It is a graph which shows. (A) is explanatory drawing which shows typically the structure for detecting tilting operation, (b) is an equivalent circuit diagram in the case shown to (a). (A) is explanatory drawing which shows typically the structure for detecting tilting operation, (b) is an equivalent circuit diagram in the case of (a), (c) is a change of voltage value It is a graph which shows. (A) is explanatory drawing which shows typically the structure for detecting tilting operation, (b) is an equivalent circuit diagram in the case of (a), (c) is a change of voltage value It is a graph which shows. It is explanatory drawing which shows typically the structure in the case of performing the detection of a slide operation, and the detection of an inclination operation by one carbon pattern. It is explanatory drawing which shows typically the structure in the case of performing a detection of a slide operation and a detection of a tilting operation in common with a carbon pattern, an ADC terminal part, and a detection circuit.

  With reference to FIGS. 1 to 16 (a) to 16 (c), an embodiment of an operation device according to the present invention and an electronic musical instrument including the same will be described. The embodiments described below are given various technically preferable limitations for carrying out the present invention, but the scope of the present invention is not limited to the following embodiments and illustrated examples.

<< Mechanical configuration of operation device and electronic musical instrument >>
First, the mechanical configuration of the operating device 2 and the electronic musical instrument including the same according to the present embodiment will be described with reference to FIGS.
FIG. 1 is a main part perspective view showing an external appearance of an operating device and an electronic musical instrument including the operating device according to the present embodiment, and FIG. 2 is a main part perspective view schematically showing an internal configuration of the operating device.
The operating device 2 in the present embodiment includes one operating element 3 and detection units 40, 41, and 52 (see FIGS. 1 and 3A) that detect the operation of the operating element 3.
As shown in FIGS. 1 and 2, the operation device 2 according to the present embodiment is arranged in a housing 1 of an electronic musical instrument 100 (for example, an electronic musical instrument such as an electronic piano or a keyboard), and performs various operations on the electronic musical instrument 100. Input.
In the present embodiment, a case will be described in which the controller device 2 serves as an operation unit that adjusts the modulation of a musical sound and a pitch bender that adjusts the pitch of the musical sound.

At a position corresponding to a portion on the upper surface of the housing 1 where the operating device 2 is disposed, a window portion is provided so that the operating body 31 which is a portion touched by the user's finger on the operating device 3 of the operating device 2 is exposed. 11 is formed. The window part 11 is provided so that it may extend along the X-axis direction which is the 1st direction in which the operation element 3 slides.
In addition, a base 12 on which the operating device 2 is disposed is provided in a position corresponding to a portion in the housing 1 where the operating device 2 is disposed.
In this embodiment, the board | substrate 4 and the carbon sheet 5 are arrange | positioned on the base 12, and the operation element 3 is arrange | positioned on it.

FIG. 3A is an enlarged view of a main part of the substrate 4 and the carbon sheet 5 arranged on the base 12, and is an enlarged view of a region indicated by “III” in FIG.
As shown in FIG. 3A, the substrate 4 disposed on the base 12 is obtained by providing a carbon pattern 41 on a printed circuit board 42.
The carbon pattern 41 is a first resistor made of a resistance film.
The carbon pattern 41 which is a resistance film as the first resistor is provided with a length corresponding to the slidable amount of the operation element 3 in the first direction (X-axis direction).
Further, in the present embodiment, the carbon pattern 41 which is a resistance film as the first resistor is when the operation element 3 is inclined according to the inclination of the operation element 3 in the second direction (Y-axis direction). It is arranged over a range where there is a possibility of contact.
The carbon pattern 41 is formed on the printed circuit board 42 by, for example, screen printing or plating a resin paste to which carbon powder is added. A terminal (not shown) connected to the carbon pattern 41 is provided at the end of the printed circuit board 42.
Further, the carbon pattern 41 is provided in a plurality of parts, and is a schematic configuration diagram to be described later. FIG. 12A, FIG. 13A, FIG. 14A, FIG. As shown in FIGS. 16A, 17 and 18, each carbon pattern 41 is connected to either GND or a power source.
The first resistor disposed on the printed circuit board 42 is not limited to the carbon pattern 41 as long as it is made of a resistance film. A conductive pattern formed of a material other than carbon may be used.

The printed circuit board 42 is provided with a detection circuit 40 (see FIG. 2).
The detection circuit 40 detects the resistance value that changes in accordance with the contact state of the carbon pattern 52 on the carbon sheet 5 that is the second resistor with respect to the carbon pattern 41 that is the first resistor, by converting it into a voltage value. It is a circuit to do.
In the present embodiment, the printed circuit board 42 is provided with an analog-to-digital converter circuit (Analog to Digital Converter, hereinafter referred to as “ADC”). The detection circuit 40 detects a change in resistance value at a terminal portion of the ADC (hereinafter referred to as “ADC terminal portion”, see FIG. 12A and the like), and converts it into a voltage value.
In the present embodiment, the resistance value detected at the ADC terminal portion is a first value such as the presence / absence of contact of the carbon pattern 52 as the second resistor with respect to the carbon pattern 41 as the first resistor, the contact position, and the contact area. It changes according to the contact state of the carbon pattern 52 as the second resistor with respect to the carbon pattern 41 as the resistor.
Then, the contact state of the carbon pattern 52 that is the second resistor with respect to the carbon pattern 41 that is the first resistor changes in accordance with the operation state of the operation element 3 (the pressing portion 311 of the operation element 3 described later). . For this reason, by detecting the resistance value (corresponding voltage value) at the ADC terminal portion by the detection circuit 40, the operation of the operation element 3 (that is, what operation is performed in which direction) is detected. Can do.

As shown in FIGS. 3A and 3B, the carbon sheet 5 has a carbon pattern 52 formed on the surface of a sheet material 51 (PET sheet) formed of PET (Polyethylene terephthalate) or the like. It has been done.
The carbon pattern 52 is a second resistor made of a resistance film.
The carbon sheet 5 is disposed on the sheet material 51 so that the carbon pattern 52 as the second resistor is opposed to the carbon pattern 41 as the first resistor, and the carbon sheet 5 is changed according to the operation of the operation element 3. The contact state between the carbon pattern 41 as the first resistor and the carbon pattern 52 as the second resistor is changed.
Similar to the carbon pattern 41, the carbon pattern 52 is formed on the sheet material 51 by, for example, screen printing or plating a resin paste to which carbon powder is added.
In addition, the 2nd resistor arrange | positioned on the sheet | seat material 51 should just consist of resistance films, and is not limited to the carbon pattern 52. FIG. A conductive pattern formed of a material other than carbon may be used.
Further, since the carbon pattern 41 is connected to the GND or the power source as described above and needs to be a resistor, the carbon pattern 52 is not connected to the GND and the power source. It has mainly the role which conducts between the some carbon patterns 41 provided in the part pushed by. For this reason, the carbon pattern 52 may not be a resistor but may be an electric conductor (conductor), or any conductor.
Further, when a conductor (electrical conductor) is provided instead of the carbon pattern 52, it is not necessary to provide it in a size corresponding to the carbon pattern 41, and it may be provided only on the lower surface portion of the operation element 3.

The carbon pattern 52 as the second resistor may be divided into a plurality of blocks.
By dividing the carbon pattern 52 into a plurality of blocks in this way, it is possible to see how many blocks of the carbon pattern 52 as the second resistor are in contact with the carbon pattern 41 as the first resistor. The presence or absence of contact with the carbon pattern 41 as the first resistor and the change in the contact area can be detected more clearly.

  In the present embodiment, the detection circuit 40, the carbon pattern 41 that is the first resistor, and the carbon pattern 52 that is the second resistor constitute a detection unit that detects the operation of the operation element 3.

Within the housing 1, slightly outside the window portion 11, extends in the first direction (X-axis direction) similarly to the window portion 11, and the first direction (X-axis direction) of the operating element 3. ) Is provided.
The shape and the like of the slide guide portion 13 are not particularly limited, but in the present embodiment, as shown in FIG. 2, the slide guide portion 13 is a rib that is suspended from the upper surface inside the housing 1. The slide guide portion 13 extends slightly above the surface of the base 12 and is not in contact with the surface of the base 12.
In addition, it is preferable that the slide guide part 13 is extended and provided in the whole slide movable range of the operation element 3. FIG.

When the operator 3 (one operator) of the controller device 2 performs a first operation that applies a force in the first direction, the operator 3 is displaced in the first direction and stops the first operation. When the second operation of applying a force in a second direction different from the first direction is performed while the displacement state at the time is maintained, the second operation is performed while displacing in the second direction. When stopped, it is configured to return to an initial state that is not displaced in the second direction. And the detection part of the operating device 2 is comprised so that the displacement amount of the 1st direction of the operation element 3 and the displacement amount of a 2nd direction can be detected.
Specifically, in the operating device 2 of the present embodiment, the operating element 3 (one operating element) performs a first operation that applies a force in the X-axis direction, which is the first direction in the present embodiment. The first slide is slid along the X-axis direction that is the first direction, and the slide position at the time when the first operation is stopped is held, and the force in the Y-axis direction that is the second direction in the present embodiment is maintained. When the second operation is applied, the tilt is in the Y-axis direction, which is the second direction, and when the second operation is stopped, the tilt is in the second direction (Y-axis direction). Not configured to return to the initial state.
In the following embodiments, as described above, the first operation applies a force in the X-axis direction, which is the first direction, to slide the operating element 3 along the X-axis direction. Will be described as an example where the operation element 3 is tilted in the Y-axis direction by applying a force in the Y-axis direction, which is the second direction. The specific operations of the first operation and the second operation are described below. The contents are not limited to those exemplified here. For example, the first operation may tilt the operation element 3 in the X-axis direction, and the second operation may cause the operation element 3 to slide along the Y-axis direction.

4 (a) and 4 (b) are cross-sectional views taken along the line IV-IV in FIG. 1, and a first force is applied to the operation element 3 in the first direction (X-axis direction). The movement of the operation element 3 when the operation is performed is shown. FIGS. 8A and 8B are cross-sectional views taken along the line VIII-VIII in FIG. 1 and apply force to the operation element 3 in the second direction (Y-axis direction). The movement of the operation element 3 when the second operation is performed is shown.
As shown in FIGS. 4 (a), 4 (b), 8 (a), and 8 (b), in this embodiment, the operation element 3 includes an operation element main body 31 that is a part touched by a user's finger. In addition, leg portions 32 provided on both side portions on the installation surface side on the base 12 in the operation element main body 31, and an inclination assisting portion 33 provided in a position connecting the leg portion 32 and the operation element main body 31, respectively. And.
The operation element 3 is made of, for example, rubber or various resins, and has both a certain degree of hardness and appropriate flexibility.
In the present embodiment, when the operator 3 performs a first operation that applies a force in the first direction (the X-axis direction in FIGS. 1 and 2 in this embodiment), the first direction (X When the user stops the first operation as well as slides along the axial direction (see FIGS. 4A and 4B), the slide position when the first operation is stopped (FIG. 4 ( b), and a second direction different from the first direction (X-axis direction) (in this embodiment, the Y-axis direction in FIGS. 1 and 2 and the direction perpendicular to the X-axis direction). When the second operation for applying force is performed, the user tilts in the second direction (Y-axis direction) (see FIGS. 8A and 8B) and the user stops the second operation. Then, the operation element 3 is configured to return to the initial state (see FIG. 4A) where the operation element 3 is not tilted.

The operation element 3 includes an operation element main body 31 that is a part of the operation element 3 that a user operates with a finger.
The side of the operating element body 31 facing the carbon sheet 5 is a pressing portion 311 that presses the carbon sheet 5 toward the substrate 4. The pressing part 311 is elastically deformed when the carbon sheet 5 is pressed.
The shape or the like of the pressing portion 311 is not particularly limited, but the surface of the pressing portion 311 that contacts and presses the carbon sheet 5 is an arc shape that is gently inclined in the Y-axis direction (FIGS. 8A and 8 ( It is preferable that the cross-sectional shape shown in b) is substantially semicircular) and the entire pressing portion 311 is substantially bowl-shaped.
As shown in FIG. 4A and FIG. 4B, the pressing portion 311 is provided with a predetermined length at a substantially central portion in the X-axis direction of the operation body 31. In addition, the range etc. in which the press part 311 is provided are not limited to the example of illustration. For example, the length in the X-axis direction may be longer or shorter than in the illustrated example. Further, the pressing portion 311 may be formed over the entire surface of the operating element body 31 on the side facing the carbon sheet 5.

As shown in FIG. 2, FIG. 8A and FIG. 8B, the leg portion 32 is greatly wide (see FIG. 8A and FIG. 8) so that the operation element 3 (operation element body 31) can operate smoothly. 8 (b) is provided so as to spread in the horizontal and Y-axis directions.
The leg portion 32 is a standing portion 321 in which both outer end portions (both end portions in the Y-axis direction) rise upward (upward in FIGS. 8A and 8B). The main body of the leg portion 32 and the standing portion 321 are substantially L-shaped in cross section as shown in FIGS. 8 (a) and 8 (b). The main body of the leg portion 32 is disposed below the slide guide portion 13 of the housing 1 (between the lower end portion of the slide guide portion 13 and the carbon sheet 5), and the standing portion 321 is outside the slide guide portion 13. Are arranged along the slide guide portion 13.
When the operating element 3 slides in the X-axis direction (first direction), the standing portion 321 is guided along the slide guide portion 13, and the operating element 3 is smoothly moved without being shaken.

The tilt assisting unit 33 supports the tilting operation of the operation element 3 (operation element body 31) in the second direction (Y-axis direction) and stops the second operation (that is, the user stops the operation element body). When the finger is released from 31), the operation element 3 is returned to the initial state that is not inclined.
The tilt assisting portion 33 is, for example, a thin portion formed to be stretchable.
As shown in FIGS. 8A and 8B, when the operation element 3 is tilted to either side in the Y-axis direction (left side in FIG. 8B), the tilt assisting portion 33 on the collapsed side is provided. (Left side tilt assisting portion 33 in FIG. 8B) is compressed, and the opposite side tilt assisting portion 33 (right side tilt assisting portion 33 in FIG. 8B) is extended. The tilt assisting portion 33 has a restoring force, and when the force for tilting the operation element 3 does not act, the tilt assisting portion 33 that has been contracted (the tilt assisting portion 33 on the left side in FIG. 8B) is extended. Due to the restoring force that the tilt assisting portion 33 (the right tilt assisting portion 33 in FIG. 8B) tries to return to the original state, the operation element 3 is operated in the original initial state (the operation shown in FIG. 8A). The child 3 is not tilted).

For example, as shown in FIG. 5, a coating layer 35 is provided on the surface of the pressing portion 311 of the operating element 3 so that the operating element 3 (the pressing portion 311 of the operating element 3) slides more smoothly. A similar coating layer 6 may be provided on the surface of the sheet 5 (the upper surface in contact with the pressing portion 311) to reduce mutual frictional resistance and improve slippage. The coating layer 35 and the coating layer 6 may be any material as long as the surfaces of the coating layer 35 and the coating layer 6 are further reduced to reduce the frictional resistance between them. The material forming the coating layer 35 and the coating layer 6 is not particularly limited. Both may be formed with the same material, and may be formed with a different material.
In addition, as shown in FIG. 6, a metal layer 36 formed of metal or the like may be provided on the surface of the pressing portion 311 of the operation element 3 to reduce the frictional resistance with the surface of the carbon sheet 5. In this case, the metal layer 36 may be formed by adhering a sheet made of metal to the surface of the pressing portion 311, or formed by vapor-depositing a metal film on the surface of the pressing portion 311. But you can. The metal layer 36 may be any material that can reduce the frictional resistance, and the material forming the metal layer 36 is not limited to a specific metal material.
Further, as shown in FIG. 7, a magnet 37 is provided inside the operation element main body 31 of the operation element 3, and the operation is performed on the side facing the operation element 3 such as the lower side surface (right side surface in FIG. 7) of the base 12. A magnet 7 having the same polarity as the magnet 37 on the child 3 side may be provided. Thereby, magnets having the same polarity repel each other, and the frictional resistance between the operation element 3 and the surface of the carbon sheet 5 can be reduced by the repulsive force.

Moreover, the shape (transverse cross-sectional shape) of the pressing portion 311 of the operation element 3 is not limited to that shown in FIGS. 8A and 8B. For example, as shown in FIG. 9, the pressing portion 311 may have a wedge shape with a substantially central portion in the horizontal direction (Y-axis direction) in the cross-sectional shape thereof.
Further, the shape (transverse cross-sectional shape) of the pressing portion 311 of the operation element 3 may be a quadrangular shape in which R is added to a corner portion in the horizontal direction (Y-axis direction) as shown in FIG.
Furthermore, the operation element 3 is not limited to the case where the pressing portion 311 directly contacts the carbon sheet 5. For example, as illustrated in FIG. 11, the brush portion 315 is provided on the surface of the pressing portion 311 on the contact side with the carbon sheet 5. May be provided. By pressing the pressing portion 311 against the carbon sheet 5 through the brush portion 315 in this way, the carbon pattern 52 of the carbon sheet 5 and the carbon pattern 41 on the substrate 4 side can be brought into contact with each other with a softer feeling.

Further, the electronic musical instrument 100 responds to the amount of slide movement by which the operating element 3 is slid along the first direction (X-axis direction) according to the detection result of the operating device 2 and the detection circuit 40 of the operating device 2. And a control device 400 that controls the pitch of the musical sound in accordance with the amount of inclination by which the operator 3 is tilted in the second direction (Y-axis direction). The control device 400 is a computer including a CPU (not shown) and ROM, RAM, etc. as storage means. The control device 400 performs overall control of each part of the electronic musical instrument 100 in addition to various processes and control related to information input by the operation device 2.
In addition, the electronic musical instrument 100 includes a sound output unit (not shown) that is adjusted by the control device 400 and outputs a musical tone with controlled modulation and pitch. The audio output unit is, for example, a speaker or an audio output terminal.
In addition, the electronic musical instrument 100 includes performance operators (not shown) corresponding to the type of the electronic musical instrument 100. For example, when the electronic musical instrument 100 is an electronic piano, a keyboard including a plurality of keys is provided as a performance operator.

《Circuit configuration of operation device》
Next, the circuit configuration of the operating device will be described with reference to FIGS. 12 to 16A to 16C and the like.
As described above, in the present embodiment, when the first operation for sliding the operation element 3 along the first direction (X-axis direction) is performed (see FIGS. 4A and 4B). ), A change in the position of the operation element 3 due to the slide movement is detected as a change in a resistance value (a voltage value corresponding thereto) in the ADC terminal portion (simply indicated as “ADC” in FIG. Detected in circuit 40.
For example, FIG. 12A schematically shows a configuration for detecting an operation when a first operation for sliding the operation element 3 along the first direction (X-axis direction) is performed. FIG. 12B is an equivalent circuit diagram in this case, and FIG. 12C is a graph showing a change in voltage value in this case.

As shown in FIG. 12A, when the operating element 3 moves along the carbon pattern 41 on the substrate 4 provided extending in the X-axis direction, the pressing portion 311 of the operating element 3 becomes the carbon sheet 5. The upper carbon pattern 52 is pressed, and the carbon pattern 52 comes into contact with the carbon pattern 41 on the substrate 4 side in the region pressed by the pressing portion 311.
In FIG. 12A, this region is referred to as a contact region Ar. By sliding the operating element 3, the distance from the reference position of the operating element 3 becomes longer, and when the contact area Ar moves from the area indicated by the solid line to the area indicated by the two-dot chain line in FIG. Since the distance of the current path flowing through 41 becomes longer, the resistance value on the carbon pattern 41 side is increased by that amount, and the voltage division ratio with the resistance R is changed, so that an intermediate portion between the carbon pattern 41 detected by the ADC and the resistance R The corresponding voltage value also rises correspondingly (see FIG. 12C). On the other hand, if the operating element 3 is slid so that the contact area Ar is located on the opposite side of the area indicated by the two-dot chain line in FIG. 12A, the distance of the current path flowing through the carbon pattern 41 becomes shorter. Will also decrease correspondingly.
It should be noted that such a change in the voltage value accompanying the slide movement is a linear linear change that is substantially proportional to the distance (that is, the distance of the current path, the position of the operation element 3), as shown in FIG. It becomes.
The detection circuit 40 detects such a change in voltage value at the ADC terminal unit, and outputs it to the control device 400 (see FIG. 2).
The control device 400 controls the modulation of the musical sound according to the slide movement amount of the operation element 3 in accordance with the change in the voltage value detected by the detection circuit 40.

  Further, for example, FIG. 13A schematically illustrates a configuration for detecting an operation when a first operation for sliding the operation element 3 along the first direction (X-axis direction) is performed. FIG. 13 is a circuit configuration diagram showing an example in which a resistor R is provided between an ADC terminal and an ADC terminal portion, unlike FIG. FIG. 13B is an equivalent circuit diagram in this case, and FIG. 13C is a graph showing a change in voltage value in this case.

In FIG. 13 (a), by sliding the operating element 3 in the same manner as shown in FIG. 12 (a), the distance from the reference position of the operating element 3 becomes longer, and the contact area Ar becomes the same as that shown in FIG. ), The distance of the current path flowing through the carbon pattern 41 becomes longer, and accordingly, the resistance value on the carbon pattern 41 side increases, and the resistance R increases. The pressure ratio changes, and the voltage value at the intermediate portion between the carbon pattern 41 and the resistance R detected by the ADC also rises correspondingly (see FIG. 13C). On the other hand, if the operating element 3 is slid so that the contact area Ar is on the opposite side of the area indicated by the two-dot chain line in FIG. 13A, the distance of the current path flowing through the carbon pattern 41 becomes shorter. Will also decrease correspondingly.
It should be noted that the change in the voltage value accompanying such a slide movement is linear in proportion to the distance (that is, the distance of the current path, the position of the operation element 3), as shown in FIG. As shown in FIG. 13C, the change in the voltage value with respect to the distance (the distance of the current path and the position of the operation element 3) is nonlinear by providing the resistor R between the ADC terminal portion. It becomes.
The detection circuit 40 detects such a change in voltage value at the ADC terminal unit, and outputs it to the control device 400 (see FIG. 2).
The control device 400 controls the modulation of the musical sound according to the slide movement amount of the operation element 3 in accordance with the change in the voltage value detected by the detection circuit 40. It should be noted that any adjustment can be made when it is desired to change the modulation curve by intentionally making the voltage value change non-linear.

  Next, FIG. 14A schematically shows a configuration for detecting an operation when a second operation for tilting the operation element 3 along the second direction (Y-axis direction) is performed. It is explanatory drawing and FIG.14 (b) is an equivalent circuit schematic in this case.

As shown in FIG. 14A, when the operation element 3 is tilted (tilted) in the Y-axis direction at any position of the carbon pattern 41 on the substrate 4, the pressing portion 311 of the operation element 3 becomes the carbon sheet 5. The range in which the upper carbon pattern 52 is pressed increases. That is, in the example shown in FIG. 14A, a plurality of carbon patterns 41 are arranged in the Y-axis direction, the left three are connected to GND, the center left one is connected to the power source, and the center right one is connected. When the operator 3 is tilted by connecting to the GND and connecting the right three to the power supply, the carbon pattern 52 comes into contact with the plurality of carbon patterns 41 in the area pressed by the pressing portion 311. The state changes.
Accordingly, as shown in FIG. 14A, for example, when the operation element 3 is tilted to the left side, the contact area Ar with the carbon pattern 41 on the left side is increased as compared with the state in which the manipulator 3 is not tilted. If the contact area Ar with the three carbon patterns 41 on the left side is increased by tilting the operation element 3 to the left side, the resistance value on the GND side decreases with respect to the ADC terminal portion, and the voltage when this is converted into a voltage value The value also decreases. Similarly, when the operation element 3 is tilted to the right side, the contact area Ar with the three carbon patterns 41 on the right side increases, the resistance value on the power source side with respect to the ADC terminal portion decreases, and the voltage value increases. That is, the voltage changes between the voltage of the power source and GND depending on which side the operator 3 is tilted along the Y-axis direction.
Note that the change in the voltage value associated with the tilting of the operation element 3 is different from the linear change during the sliding movement shown in FIG. Alternatively, a large change appears instantaneously due to contact with the carbon pattern 41 closer to the center of the three on the right side.
The detection circuit 40 detects such a change in voltage value at the ADC terminal unit, and outputs it to the control device 400 (see FIG. 2).
The control device 400 controls the pitch of the musical sound according to the amount of inclination of the operation element 3 in accordance with the change in the voltage value detected by the detection circuit 40.

  15A and 16A show the case where the second operation for tilting the operation element 3 along the second direction (Y-axis direction) is performed in the same manner as in FIG. 14A. It is explanatory drawing which shows typically the structure for detecting the operation, FIG.15 (b) and FIG.16 (b) are equivalent circuit diagrams in this case, FIG.15 (c) and FIG.16 (c) ) Is a graph showing a change in voltage value in this case.

In the example shown in FIG. 15A and FIG. 16A, unlike FIG. 14A, the two carbon patterns 41 in the center and widths in the Y-axis direction on both sides (both sides in the Y-axis direction). An example is shown in which one wide carbon pattern 41 is arranged.
In this case, as shown in FIGS. 15C and 16C, when the operator 3 is tilted in any of the Y-axis directions from a state where the tilt of the operator 3 is zero, the carbon pattern 41 on the left side is Alternatively, the contact area Ar increases at a stroke due to contact with the carbon pattern 41 on the right side, and the voltage value changes greatly. The difference from the example shown in FIGS. 14A and 14B is that in the example of FIG. 14A and the like, the voltage value is not only in the moment when the operation element 3 is tilted but also in the process of further tilting. In the example shown in FIGS. 15 and 16, the voltage value changes stepwise at the moment when the operation element 3 is tilted, but the voltage value is nonlinear in the process of further tilting. However, it is a point that changes smoothly.
As shown in FIG. 16A, the carbon pattern 41 is arranged on both sides in the Y-axis direction or a wide carbon pattern 41 with a resistor R (resistor R1 on the right side and resistor R2 on the left side in FIG. 16A). By adding a fixed resistor other than the pattern 41, as shown in FIGS. 15 (c) and 16 (c), the change rate of the voltage value when the operating element 3 is displaced at a predetermined speed, or steplessly It is possible to change the way of change such as smooth change or step-by-step change (when the change rate is very high).
The detection circuit 40 detects such a change in voltage value at the ADC terminal unit, and outputs it to the control device 400 (see FIG. 2).
The control device 400 controls the pitch of the musical sound according to the amount of inclination of the operation element 3 in accordance with the change in the voltage value detected by the detection circuit 40.

In such a configuration, when the operation element 3 is moved in the sliding direction at an average operation speed, the maximum value of the change rate of the voltage value is inclined at the average operation speed in the direction in which the operation element 3 is inclined. It is possible to set so as not to exceed the maximum value of the change rate of the voltage value.
The detection circuit 40 can detect how the voltage value changes, that is, the change rate of the voltage value, the presence or absence of a step change, and the like at the ADC terminal unit.
As a result, the detection circuit 40 performs the average operation in the direction in which the operation element 3 is tilted, depending on how the voltage value changes, in the case where the operation element 3 is moved in the slide direction at an average operation speed. It is possible to specify the operation direction of the operation element 3 such as whether it is tilted at a speed of.

  As shown in FIGS. 12 (a) to 12 (c) to 16 (a) and 16 (c), the operation element 3 is slid along the X-axis direction (in the case of the first operation). In which the change in voltage value can be detected (that is, the configuration shown in FIGS. 12A and 13A) and when the operation element 3 is tilted in the Y-axis direction (in the case of the second operation). A configuration (a configuration shown in FIGS. 14A, 15A, and 16A) that can detect a change in voltage value is provided, and the detection circuit 40 has a voltage value ( By detecting the resistance value, in the electronic musical instrument 100 of this embodiment, the control of the modulation of the musical tone based on the slide movement amount when the operation element 3 is slid (in the case of the first operation), and the operation element 3 are detected. Music based on the amount of tilt when the is tilted (in the second operation) And control of the pitch, can be carried out according to the operation of the single operation element 3.

<< Operation device and operation of electronic musical instrument including the same >>
In the present embodiment, as shown in FIG. 1, a base 12 is provided in the housing 1 of the electronic musical instrument 100, and a substrate 4 having a carbon pattern 41 as a first resistor formed on the base 12 is provided. Deploy. Then, the carbon sheet 5 in which the carbon pattern 52 as the second resistor is formed on the substrate 4 is arranged so that the carbon pattern 41 and the carbon pattern 52 face each other.
Examples of the carbon pattern 41 include those capable of detecting the slide of the operation element 3 in the X-axis direction, such as FIGS. 12 (a) and 13 (a), and FIGS. 14 (a), 15 (a), and FIG. 16 (a) or the like that can detect the inclination of the operation element 3 in the Y-axis direction is provided, and an ADC terminal portion is provided for each, and a change in voltage value (resistance value) at each ADC terminal portion is detected. A separate detection circuit 40 is provided.

When the performer (user) wants to adjust the modulation of the musical sound during the performance of the electronic musical instrument 100, the performer slides the operation element 3 by an arbitrary amount in the direction to change along the X-axis direction. The slide movement of the operation element 3 and its movement amount are detected by the detection circuit 40 capable of detecting the slide of the operation element 3 in the X-axis direction, and the detection result is output to the control device 400. Thus, the control device 400 controls the modulation of the musical sound based on the detection result by the detection circuit 40.
As long as the player does not change the position of the operation element 3 in the X-axis direction, the modulation adjustment corresponding to the position after the movement of the operation element 3 is maintained.

When the performer (user) wants to adjust the pitch of the musical sound, the performer tilts the operation element 3 in a desired direction in the Y-axis direction by an arbitrary amount. The tilting operation and the tilt amount of the operation element 3 are detected by the detection circuit 40 that can detect the tilt of the operation element 3 in the Y-axis direction, and the detection result is output to the control device 400. Thereby, the control apparatus 400 controls the pitch of a musical sound based on the detection result by the detection circuit 40.
The tilt of the operator in the Y-axis direction is such that when the player releases his / her hand from the operator 3, the operator 3 returns to the initial state with no tilt. Therefore, the player tilts the operator 3 to adjust the pitch. Only maintained for a while.
In this way, the electronic musical instrument 100 can adjust the modulation of the musical tone and the pitch of the musical tone by sliding the operation element 3 of the controller device 2 in the X-axis direction or tilting it in the Y direction. For this reason, by performing an intuitive operation such as whether the performer slides one side 3 or tilts it sideways during the performance, the musical sound can be easily modulated and the pitch adjusted by an arbitrary amount. .

<< Effects of operating device and electronic musical instrument including the same >>
As described above, according to the present embodiment, the operation element 3 has the detection circuit 40, the carbon pattern 41, and the carbon pattern 52 as the detection unit that detects the operation of the operation element 3. When the first operation that applies force in the first direction (X-axis direction) is performed, the slide slides along the first direction and maintains the slide position when the first operation is stopped. However, when the second operation for applying a force in the second direction (Y-axis direction) different from the first direction is performed, the second operation is stopped while tilting in the second direction. Are configured to return to an initial state that is not tilted, and the detection unit is configured to be able to detect the slide amount in the first direction and the tilt amount in the second direction.
Thus, if the slide amount of the operation element 3 is associated with the modulation of the musical sound and the inclination amount of the operation element 3 is associated with the pitch of the musical sound, the modulation of the musical sound depends on how one operation element 3 is operated. And the pitch of the musical sound can be adjusted by one operator 3.
For this reason, the operating device 2 can be reduced in size and can be arranged compactly even when mounted on the electronic musical instrument 100. Also, the user can easily adjust the modulation of the musical sound and the pitch of the musical sound by an intuitive operation of sliding or tilting the single operation element 3 during the performance.
Furthermore, the number of parts can be reduced to provide a simple configuration, and productivity can be improved by eliminating mounting errors at the manufacturing stage as compared with the case where a plurality of similar operators are provided.

  Moreover, in this embodiment, the slide guide part 13 extended in the 1st direction (X-axis direction) and guiding the slide along the 1st direction of the operation element 3 is provided. Thereby, the operation element 3 can be slid and moved smoothly and stably.

In the present embodiment, the tilt assisting unit that supports the tilting operation of the operating element 3 in the second direction (Y-axis direction) and returns the operating element 3 to the initial state when the second operation is stopped. I have.
For this reason, when the pitch adjustment for producing a temporary effect is performed, the user can return to the original state where the pitch adjustment is not performed only by releasing the operator 3 without releasing the setting. Can do.

In the present embodiment, the detection unit is provided with a first resistor made of the carbon pattern 41 that is a resistance film and the first resistor so as to face the first resistor. A second resistor made of a carbon pattern 52, which is a resistive film provided so that the contact state with the body changes, and a resistance that changes in accordance with the contact state of the second resistor with respect to the first resistor A detection circuit that converts the value into a voltage value and detects the voltage value.
Thereby, operation of the operation element 3 can be detected with a relatively simple configuration.

Further, in the present embodiment, the carbon pattern 41 that is the first resistor is provided to extend in the first direction (X-axis direction) in a range that is the same as or wider than the slidable movable range of the operation element 3. It is done.
For this reason, it is possible to appropriately detect where the operating element 3 is located within the movable range.

In the present embodiment, the carbon pattern 41 that is the first resistor is widely provided in the second direction (Y-axis direction) in a range that is the same as or wider than the range in which the operation element 3 can be tilted.
For this reason, it can be detected appropriately wherever the operation element 3 is located within the tiltable range.

In the present embodiment, the electronic musical instrument 100 is equipped with an operating device capable of distinguishing between the sliding operation and the tilting operation of one operating element 3 and detecting the operation, and the operating element 3 is moved along the first direction. A control device is provided that controls the modulation of the musical sound in accordance with the amount of slide movement to be slid and controls the pitch of the musical sound in accordance with the amount of inclination by which the operation element 3 is tilted in the second direction.
For this reason, in the electronic musical instrument 100, it is possible to easily adjust the modulation of the musical tone and the pitch of the musical tone using the single operator 3.

<Modification>
Although the embodiments of the present invention have been described above, the present invention is not limited to such embodiments, and various modifications can be made without departing from the scope of the present invention.

  For example, in the above-described embodiment, which operation is performed according to the rate of change of one voltage value (resistance value) detected by the detection circuit 40, the modulation control of the musical tone and the pitch control of the musical tone. In the above example, the operation is performed by one operation element 3 and one detection circuit. However, the operation can be performed by one operation element 3 and two detection circuits.

That is, FIG. 17 shows a set of a first carbon pattern part and a first detection circuit for detecting the sliding direction of the operation element 3, a carbon pattern part for detecting the inclination direction of the operation element, and a second one. This shows an example in which the set with the detection circuit is provided separately and independently.
In the example shown in FIG. 17, the two carbon patterns 41 in the middle (this is referred to as the “first carbon pattern portion”) and the ADC 1 are for detecting the sliding direction, and the detection circuit 40 (first Detection circuit) detects a change in voltage value at ADC1 (ADC terminal section) and outputs the change to the control device 400 (see FIG. 2).
The control device 400 controls the modulation of the musical sound according to the slide movement amount of the operation element 3 in accordance with the change in the voltage value detected by the detection circuit 40 (first detection circuit).
In FIG. 17, the five carbon patterns 41 on the left side, the five carbon patterns 41 on the right side (the five carbon patterns 41 on the left and right sides are referred to as the “second carbon pattern portion”), and the ADC 2 are inclined. The detection circuit 40 (second detection circuit) detects a change in voltage value at the ADC 2 (ADC terminal unit) and outputs the change to the control device 400 (see FIG. 2).
The control device 400 controls the pitch of the musical tone according to the amount of inclination of the operation element 3 in accordance with the change in the voltage value detected by the detection circuit 40 (second detection circuit).

In the example shown in FIG. 17, the region where the operator 3 presses the carbon pattern 41 is also made independent, so that even if a part of the pressing portion 311 of the operator 3 is pressed against the carbon sheet 5, no contact is made. A case where two gap portions 311a are provided is illustrated.
Thereby, the pressing part 311 can be divided into three parts, that is, a central part and parts arranged on both sides of the gap part 311a.
When the operation element 3 is tilted, the pressing portion 311 is elastically deformed while being pressed against the carbon sheet 5 side. For this reason, when the operating element 3 is tilted, the central portion of the pressing portion 311 is kept in contact with the peripheral portion on the tilted side, and the carbon pattern 41 and the carbon pattern 52 are in wide contact with each other. (That is, the contact area Ar becomes wider.)
In the example shown in FIG. 17, as described above, two ADC terminal portions of ADC1 and ADC2 are provided, and independent detection circuits 40 (that is, the first detection circuit and the second detection circuit) are respectively provided in the two ADC terminal portions. Circuit), and one detection circuit 40 (first detection circuit) detects a change in voltage value when the operation element 3 is slid (in the case of the first operation), and the other detection circuit 40 ( The second detection circuit detects a change in voltage value when the operation element 3 is tilted (in the case of the second operation).
The change in the voltage value when the operation element 3 is tilted is corrected using the detection result of the voltage value when the operation element 3 is slid, so that the operation element 3 moves in the X-axis direction (slide direction). It is possible to detect a change in the voltage value when the operation element 3 is appropriately tilted regardless of the position.
In the case of such a circuit configuration, when the operation element 3 is slid and moved (in the case of the first operation), the modulation control of the musical sound based on the slide movement amount and when the operation element 3 is inclined (the first operation) The control of the pitch of the musical sound based on the amount of inclination in the case of operation 2) can be realized by the operation of one operation element 3 and the arrangement of one type of carbon pattern 41.

Further, FIG. 18 shows another example in which the operation in the sliding direction and the operation in the tilt direction are identified and detected by the operation of one operation element 3 and one detection circuit. It is determined which operation has been performed according to the change range of one voltage value (resistance value). Further, only one ADC terminal portion is provided in common, and the detection circuit 40 is also provided with one detection circuit 40 that detects a change in voltage value (resistance value) in this one ADC terminal portion.
In this example, the pressing portion 311 is not divided as shown in FIG.
In this case, the detection voltage when the control 3 is not tilted (when the second operation is not performed) does not exceed V1−V1 × R1 / (R1 + R3 + R2) and does not fall below V1 × R2 / (R1 + R3 + R2). Are set to the resistance values of the resistors R1, R2 and R3, respectively.
In this case, as described above, the contact state of the carbon pattern 52 as the second resistor with respect to the carbon pattern 41 as the first resistor when the operation element 3 slides in the X-axis direction that is the first direction. The change range of the resistance value that changes according to the first change range is the second change range for the carbon pattern 41 that is the first resistor when the operation element 3 is tilted in the Y-axis direction, which is the second direction. The carbon pattern 41 as the first resistor so that the change range of the resistance value that changes according to the contact state of the carbon pattern 52 as the resistor is a second change range that is larger than the first change range, and A carbon pattern 52 which is a second resistor is set (setting of the resistance value of each resistor). Then, the detection circuit 40 performs a first operation (sliding operation) in the first direction (X-axis direction) on the operation element 3 depending on whether or not the detected resistance value exceeds the first change range. It acts as a determination unit that determines whether the second operation (tilting operation) in the second direction (Y-axis direction) has been performed.

That is, the resistance that changes in accordance with the contact state of the carbon pattern 52 that is the second resistor with respect to the carbon pattern 41 that is the first resistor when the operation element 3 slides in the first direction (X-axis direction). The value change range is the first change range, and the carbon that is the second resistor with respect to the carbon pattern 41 that is the first resistor when the operation element 3 is tilted in the second direction (Y-axis direction). The first resistor and the second resistor are set so that the change range of the resistance value that changes in accordance with the contact state of the pattern 52 is a second change range that is larger than the first change range. The detection circuit 40 determines whether the first operation in the first direction has been performed on the operation element 3 or the second in the second direction depending on whether or not the detected resistance value exceeds the first change range. It is determined whether the second operation has been performed.
By setting the voltage range in this way, when the set voltage range is exceeded, the operating element 3 is tilted to the right side (the right side in FIG. 18), and when the set voltage range is below the set voltage range, It is determined that the operation element 3 is tilted to the left side (left side in FIG. 18). As a result, the musical tone is modulated based on the amount of slide movement when the operation element 3 is slid (in the case of the first operation) while the operation element 3, the carbon pattern 41, the ADC terminal unit, and the detection circuit 40 are all united. And the control of the pitch of the musical tone based on the amount of inclination when the operation element 3 is tilted (in the case of the second operation), the operation of one operation element 3 and one type of carbon pattern 41 It can be realized by arrangement.

Moreover, although the case where modulation and a pitch bender were implement | achieved by operation by one operation element 3 was illustrated in the said embodiment, the instruction | indication implement | achieved by operation by one operation element 3 is not limited to modulation and a pitch bender.
The configuration of the operation device and the electronic musical instrument of the present invention can be widely applied to a case where a plurality of instructions by a user are realized by an operation with one operator.

Although several embodiments of the present invention have been described above, the scope of the present invention is not limited to the above-described embodiments, but includes the scope of the invention described in the claims and equivalents thereof. .
The invention described in the scope of claims attached to the application of this application will be added below. The item numbers of the claims described in the appendix are as set forth in the claims attached to the application of this application.
[Appendix]
<Claim 1>
One operation element, and a detection unit that detects an operation of the operation element,
When the first operation that applies force in the first direction is performed, the one operation element is displaced in the first direction and maintains a displacement state at the time when the first operation is stopped. When a second operation is performed to apply a force in a second direction different from the first direction, the displacement is in the second direction, and the second operation is stopped. , Configured to return to an initial state not displaced in the second direction,
The operation device configured to detect the displacement amount in the first direction and the displacement amount in the second direction.
<Claim 2>
When the first operation is performed, the one operation element slides along the first direction, holds the slide position at the time when the first operation is stopped, and performs the second operation. When the second operation is performed, it is tilted in the second direction, and when the second operation is stopped, the initial state is not tilted in the second direction. The operating device according to claim 1.
<Claim 3>
The operating device according to claim 2, further comprising a slide guide portion that extends in the first direction and guides the slide of the operating element along the first direction.
<Claim 4>
The tilt assisting unit that supports the tilting operation of the manipulator in the second direction and returns the manipulator to the initial state when the second operation is stopped. Item 4. The operating device according to Item 3.
<Claim 5>
The detector is
A resistor composed of a resistive film;
A conductor provided to face the resistor, and provided to change a contact state with the resistor according to the operation of the operation element;
An operation device according to any one of claims 1 to 4, further comprising: a detection circuit that converts a resistance value that changes in accordance with a contact state of the conductor to the resistor into a voltage value and detects the voltage value. .
<Claim 6>
The operating device according to claim 5, wherein the resistor is provided to extend in the first direction in a range that is the same as or wider than a range in which the operating element can be displaced in the first direction.
<Claim 7>
The operating device according to claim 5 or 6, wherein the resistor is widely provided in the second direction in a range that is the same as or wider than a range in which the operating element can be displaced in the second direction. .
<Claim 8>
The detection circuit is provided to detect a voltage value at one position of the resistor, and the operation element is moved in the first direction according to a detection state of the voltage value at the one position. The operating device according to any one of claims 5 to 7, wherein it is determined whether the first operation has been performed or the second operation in the second direction has been performed.
<Claim 9>
The change range of the resistance value that changes in accordance with the contact state of the conductor with the resistor when the operation element is displaced in the first direction is the first change range, and the operation element is the second change value. The resistor and the resistor so that a change range of a resistance value that changes according to a contact state of the conductor with respect to the resistor when displaced in the direction of is a second change range that is larger than the first change range. The conductor is set,
The detection circuit determines whether the first operation in the first direction has been performed on the operator according to whether the detected resistance value exceeds the first change range, or whether the second operation is performed. The operating device according to claim 5, wherein it is determined whether the second operation in the direction has been performed.
<Claim 10>
The rate of change of the resistance value that changes according to the contact state of the conductor with the resistor when the operator is displaced in the first direction at a predetermined speed, and the operator is in the second direction. The resistor and the conductor are set so that the rate of change of the resistance value that changes according to the contact state of the conductor with respect to the resistor when displaced at the predetermined speed is different,
The detection circuit determines whether the first operation in the first direction has been performed on the operation element or the second operation in the second direction is performed on the operation element according to the detected change rate of the resistance value. The operating device according to any one of claims 5 to 8, wherein it is determined whether it has been performed.
<Claim 11>
The operating device according to any one of claims 1 to 10,
Control for controlling the modulation of the musical sound according to the amount of slide movement that slides the operating element along the first direction, and for controlling the pitch of the musical sound according to the amount of inclination for tilting the operating element in the second direction Equipment,
An electronic musical instrument characterized by comprising:

2 Operating device 3 Operating element 13 Slide guide portion 33 Tilt assisting portion 40 Detection circuit 41 Carbon pattern 52 Carbon pattern 100 Electronic musical instrument 311 Pressing portion 400 Control device

Claims (11)

One operation element, and a detection unit that detects an operation of the operation element,
When the first operation that applies force in the first direction is performed, the one operation element is displaced in the first direction and maintains a displacement state at the time when the first operation is stopped. When a second operation is performed to apply a force in a second direction different from the first direction, the displacement is in the second direction, and the second operation is stopped. , Configured to return to an initial state not displaced in the second direction,
The operation device configured to detect the displacement amount in the first direction and the displacement amount in the second direction.   When the first operation is performed, the one operation element slides along the first direction, holds the slide position at the time when the first operation is stopped, and performs the second operation. When the second operation is performed, it is tilted in the second direction, and when the second operation is stopped, the initial state is not tilted in the second direction. The operating device according to claim 1.   The operating device according to claim 2, further comprising a slide guide portion that extends in the first direction and guides the slide of the operating element along the first direction.   The tilt assisting unit that supports the tilting operation of the manipulator in the second direction and returns the manipulator to the initial state when the second operation is stopped. Item 4. The operating device according to Item 3. The detector is
A resistor composed of a resistive film;
A conductor provided to face the resistor, and provided to change a contact state with the resistor according to the operation of the operation element;
An operation device according to any one of claims 1 to 4, further comprising: a detection circuit that converts a resistance value that changes in accordance with a contact state of the conductor to the resistor into a voltage value and detects the voltage value. .   The operating device according to claim 5, wherein the resistor is provided to extend in the first direction in a range that is the same as or wider than a range in which the operating element can be displaced in the first direction.   The operating device according to claim 5 or 6, wherein the resistor is widely provided in the second direction in a range that is the same as or wider than a range in which the operating element can be displaced in the second direction. .   The detection circuit is provided to detect a voltage value at one position of the resistor, and the operation element is moved in the first direction according to a detection state of the voltage value at the one position. The operating device according to any one of claims 5 to 7, wherein it is determined whether the first operation has been performed or the second operation in the second direction has been performed. The change range of the resistance value that changes in accordance with the contact state of the conductor with the resistor when the operation element is displaced in the first direction is the first change range, and the operation element is the second change value. The resistor and the resistor so that a change range of a resistance value that changes according to a contact state of the conductor with respect to the resistor when displaced in the direction of is a second change range that is larger than the first change range. The conductor is set,
The detection circuit determines whether the first operation in the first direction has been performed on the operator according to whether the detected resistance value exceeds the first change range, or whether the second operation is performed. The operating device according to claim 5, wherein it is determined whether the second operation in the direction has been performed. The rate of change of the resistance value that changes according to the contact state of the conductor with the resistor when the operator is displaced in the first direction at a predetermined speed, and the operator is in the second direction. The resistor and the conductor are set so that the rate of change of the resistance value that changes according to the contact state of the conductor with respect to the resistor when displaced at the predetermined speed is different,
The detection circuit determines whether the first operation in the first direction has been performed on the operation element or the second operation in the second direction is performed on the operation element according to the detected change rate of the resistance value. The operating device according to any one of claims 5 to 8, wherein it is determined whether it has been performed. The operating device according to any one of claims 1 to 10,
Control for controlling the modulation of the musical sound according to the amount of slide movement that slides the operating element along the first direction, and for controlling the pitch of the musical sound according to the amount of inclination for tilting the operating element in the second direction Equipment,
An electronic musical instrument characterized by comprising:

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