JP2011159173A - Operation input device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an operation input device which can change the operation load required for sliding a slide member in response to the difference in operating directions. <P>SOLUTION: The operation input device for receiving operation input includes a slide key 30 slid by the operation input, and four coil springs 41-44 whose both ends are fixed. In the initial state that does not undergo the operation input, intermediate parts 41c-44c of respective coil springs 41-44 are, at mutually different contacts, in contact with the outer periphery of the slide plate of the slide key 30 in an energizing state for holding the slide key 30 at the position in the initial state. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an operation input device that receives an operation input.

  2. Description of the Related Art Conventionally, a coordinate signal output device that outputs a coordinate signal corresponding to a sliding movement of an operation member is known (see, for example, Patent Document 1). This coordinate signal output device holds the movable contact driving member at the center by pulling the movable contact driving member interlocked with the operation member outward by a plurality of elastic members arranged at equal intervals in the circumferential direction. The operation member is given a habit of returning to the initial position.

  In addition, a coordinate input device is known in which when a sliding operation of a movable member that can be slid is released, the movable member automatically returns to an initial position by an urging force of an endless coil spring in which both ends are connected (for example, (See Patent Document 2).

Utility model registration No. 3130197 Patent No. 4292103

  However, in the conventional technique such as Patent Document 2, since the automatic return mechanism is realized by a single coil spring in which both ends are connected to each other, the operation load changes regardless of the direction of 360 ° sliding operation. Absent.

  Therefore, an object of the present invention is to provide an operation input device that can change an operation load necessary for sliding a slide member according to a difference in operation direction.

In order to achieve the above object, an operation input device according to the present invention comprises:
An operation input device that receives an operation input,
A slide member that slides according to the operation input;
Comprising at least three or more elastic members fixed at both ends;
In an initial state where the operation input is not received, an intermediate portion of each of the elastic members is in contact with an outer periphery of the slide member at a different contact point.

Moreover, the operation input device according to the present invention includes:
An operation input device that receives an operation input,
A slide member that slides according to the operation input;
Comprising at least two or more elastic members fixed at both ends;
In an initial state in which the operation input is not received, the intermediate portions of the elastic members are in contact with the outer periphery of the slide member in a biased state in which the slide member can be held at the position in the initial state by different contact points. It is characterized by being.

  According to the present invention, the operation load required to slide the slide member can be changed depending on the difference in the operation direction.

It is a perspective view of operation input device 1 which is a 1st embodiment of the present invention. 2 is an exploded perspective view of the operation input device 1 with an upper case 20 removed. FIG. 3 is a cross-sectional view of the operation input device 1. FIG. It is the figure which showed the state which the slide key 30 slid to the X (-) direction. It is the figure which showed the state which the slide key 30 slid to the diagonal direction. FIG. 5 is a relationship diagram between a movement amount W of a slide key 30 and an operation input load F; It is a perspective view of the operation input device 2 which is the 2nd Embodiment of this invention. 3 is an exploded perspective view of the operation input device 2. FIG. 3 is a configuration diagram of a detection unit that detects the movement of a slide key 30. FIG. 3 is a diagram schematically showing a configuration in which two elastic members 46 and 47 are in contact with the outer periphery of a slide key 35. FIG. 3 is a diagram schematically illustrating a configuration in which three elastic members 46 to 48 are in contact with the outer periphery of a slide key 35. FIG. It is the figure which showed typically the structure where the four elastic members 46-49 contact | connect the outer periphery of the slide key 35 (36, 37).

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. An operation input device according to an embodiment of the present invention is an operation interface that receives a force from an operator's finger or the like and outputs an output signal corresponding to the received force. An operation input by the operator is detected based on the output signal. By detecting the operation input, it is possible to make the computer grasp the operation content corresponding to the operation input.

  For example, display items on a display screen (for example, an instruction display such as a cursor or a pointer) provided in an electronic device such as a home or portable game machine, a portable terminal such as a mobile phone or a music player, a personal computer, or an electric appliance. Or a character) can be moved according to the operation content intended by the operator. In addition, when an operator gives a predetermined operation input, a desired function of the electronic device corresponding to the operation input can be exhibited.

  Hereinafter, specific examples of the operation input device according to the embodiment of the present invention will be described.

  FIG. 1 is a perspective view of an operation input device 1 according to the first embodiment of the present invention. FIG. 2 is an exploded perspective view of the operation input device 1 with the upper case 20 removed. FIG. 3 is a cross-sectional view of the operation input device 1.

  The operation input device 1 includes a slide key 30 and four coil springs 41 to 44. The slide key 30 is a slide member that can slide along a predetermined reference plane parallel to the XY plane of an orthogonal coordinate system determined by the X, Y, and Z axes by applying an operation load as an operation input. Each of the coil springs 41 to 44 is an elastic member fixed as a fixed end at a place where both ends in the longitudinal direction are different. As shown in FIG. 2, the operation input device 1 is in an initial state where the slide key 30 is not receiving operation input, and the intermediate portions of the coil springs 41 to 44 are in contact with the outer periphery of the slide key 30 at different contacts. Yes.

  Since the operation input device 1 has such a configuration, the operation load necessary to slide the slide key 30 can be changed depending on the difference in the operation direction of the slide key 30. That is, “the operation necessary to slide the slide key 30 in the direction in which the intermediate portion of the coil spring and the outer periphery of the slide key 30 are in contact with each other, starting from the position (initial position) of the slide key 30 in the initial state. “Load” and “the operation load necessary to slide the slide key 30 in the direction in which the intermediate portion of the coil spring and the outer periphery of the slide key 30 are not in contact with each other starting from the initial position of the slide key 30” It can be different from each other.

  For example, as shown in FIG. 4, the slide key 30 slid in the X (−) direction on the XY plane mainly deforms one coil spring 43 elastically by a load from the lateral direction, whereas FIG. Thus, the slide key 30 slid in the direction of 45 ° obliquely with respect to the X axis elastically deforms the two coil springs 42 and 43 adjacent to each other by a load from the lateral direction. Therefore, the operation load necessary to slide the slide key 30 by the same movement amount is larger in the case of FIG. 5 than in the case of FIG. 4 because the number of coil springs to be elastically deformed is larger.

  As described above, the operation load necessary for the operator to slide the slide key 30 can be changed depending on the difference in the operation direction of the slide key 30, so that the operation feeling of the operator can be changed according to the operation direction. it can. As a result, for example, even if the operator blindly operates the slide key 30 without looking at the hand, or a blind person operates the slide key 30, the slide key 30 is operated in any direction. Can be perceived intuitively by the operator. Further, it is possible to change the operation feeling according to the operation direction with a simple configuration.

  Next, the configuration of the operation input device 1 will be described in more detail. As illustrated in FIGS. 1 to 3, the operation input device 1 includes a lower case 10, a slide key 30, coil springs 41 to 44, and an upper case 20.

  The lower case 10 is arranged such that the slide key 30 and a plurality of coil springs (four coil springs 41 to 44 in the case of the operation input device 1) supported in contact with the outer periphery of the slide key 30 in the sliding direction are arranged. A base having a surface 10a. The slide key 30 freely slides in each direction in the XY plane along the arrangement surface 10a. The lower case 10 may be made of resin or metal such as iron or aluminum.

  As shown in FIG. 3, the slide key 30 may freely slide in each direction in the XY plane along the slide surface 10b formed as a step surface at the center of the arrangement surface 10a. The arrangement surface 10a and the slide surface 10b are preferably flat in terms of reducing the height.

  By making the height of the slide surface 10b on which the slide key 30 slides in the Z direction (vertical direction in the case of FIG. 3) higher than the arrangement surface 10a on which the coil springs 41 to 44 contacting the slide key 30 are arranged, The thickness of the slide plate 30b of the slide key 30 in the Z direction can be reduced. By reducing the thickness of the slide plate 30b in contact with the slide surface 10b, the slide key 30 can be reduced in weight. Also, the height of the slide surface 10b is arranged so that the thickness center position of the slide plate 30b of the slide key 30 matches the height in the Z direction to the center of the coil spring in which the wire is wound in a coil shape. It is preferable that the height is higher than the surface 10a. By matching the center height of the coil spring with the thickness center position of the slide plate 30b of the slide key 30, the intermediate portion of the coil spring can be stably brought into contact with the outer periphery of the slide plate 30b of the slide key 30.

  The slide key 30 is an operation unit having a protrusion 30a on which an operator's force can act. The slide key 30 is a displacement member that is displaced in the XY plane when the operator's force acts on the protrusion 30a. The slide key 30 is supported by the lower case 10 and the upper case 20 so as to be movable in a direction parallel to the XY plane. The position of the slide key 30 in the standby state (initial state) where the operator's force is not applied to the protrusion 30a is taken as the standby position (initial position). By acting on the part 30a, it is supported so that it can move in the direction parallel to the XY plane from its standby position. The upper case 20 is fixed to the lower case 10.

  The inner diameter of the through hole 20 a of the upper case 20 is smaller than the outer diameter of the circular slide plate 30 b of the slide key 30. As a result, the slide plate 30b of the slide key 30 can be sandwiched between the lower case 10 and the upper case 20 and supported so as to be displaceable in a direction parallel to the XY plane (see FIG. 3). Further, foreign matter such as dust can be prevented from entering the operation input device 1. The protrusion 30a is formed on the slide plate 30b of the slide key 30 so that the protrusion 30a protrudes from the through hole 20a. This makes it easier for the operator to operate the slide key 30 in the sliding direction.

  Each of the coil springs 41 to 44 is an elastic member having both ends as fixed ends. Both ends of each coil spring are fixed by convex mounting portions (bosses) formed on the arrangement surface 10a of the lower case 10 so that each coil spring contacts the outer periphery of the slide plate 30b of the slide key 30 with different contacts. (See FIGS. 4 and 5). For example, one fixed end 41a of the coil spring 41 is fixed by the mounting portion 11a, and the other fixed end 41b is fixed by the mounting portion 11b. The same applies to the other coil springs. Coil portions 41c to 44c having a length equal to or longer than a predetermined value are formed by winding a wire in a coil shape at an intermediate portion sandwiched between fixed ends on both sides of each coil spring.

  FIG. 4 is a diagram illustrating a state in which the slide key 30 is slid in the X (−) direction. FIG. 5 is a view showing a state in which the slide key 30 is slid in an oblique direction. The coil springs 41 to 44 are arranged in a circumferential direction of a virtual circle formed by connecting points having the same distance from the origin O, which is the reference point of the orthogonal coordinate system. The coil springs 41 to 44 are equally spaced in the circumferential direction in that the coil springs 41 to 44 make it easy to detect the positions of the reference points of the slide key 30 (for example, the center point or the center of gravity of the slide key 30). Preferably they are arranged. The coil springs 41 to 44 are arranged in contact with the outside of the outer peripheral edge of the slide key 30, and are in the X (+) direction that is the X axis positive direction and the X (−) direction that is the X axis negative direction. , Y (+) direction, which is the Y axis positive side direction, and Y (−) direction, which is the Y axis negative side direction, are arranged every 90 ° in the circumferential direction outside the slide plate 30b of the slide key 30. ing. The X (−) direction is a direction opposite to the X (+) direction by 180 ° on the XY plane, and the Y (−) direction is 180 ° opposite to the Y (+) direction on the XY plane. The direction of the direction. The coil spring 41 is disposed on the X axis on the positive side with respect to the origin O, the coil spring 42 is disposed on the Y axis on the positive side with respect to the origin O, and the coil spring 43 is disposed on the origin O. The coil spring 44 is disposed on the negative X-axis, and the coil spring 44 is disposed on the negative Y-axis with respect to the origin O. The origin O corresponds to the initial position of the slide key 30 in the initial state where no operation load is received. When the operation load applied to the slide key 30 is released, the position of the slide key 30 returns to the initial position by the action of the elastic force of the coil spring arranged in contact with the outer periphery of the slide key 30.

  As apparent from FIGS. 4 and 5, each coil spring is bent by a lateral load and elastically deformed (that is, each of X (+), X (−), Y (+), and Y (−)). Compared to the operation load required to slide the slide key 30 in the four directions of the shaft), the two coil springs are bent by the lateral load and elastically deformed (that is, sandwiched between the X axis and the Y axis). Since the operation load necessary to slide the slide key 30 in the four directions of 45 ° diagonally is large, the sense of operating in the four directions of the XY axes and when operating in the four diagonal directions sandwiched between these directions Can change the sense of

  When the operation load in the four directions of the XY axes is desired to be larger than the operation load in the four directions of 45 ° obliquely, the arrangement position of the coil spring may be shifted by 45 ° in the circumferential direction. Further, the elastic coefficients of the coil springs are the same, but may be different. For example, the elastic coefficient of one coil spring is the same as the elastic coefficient of the coil spring disposed at a position facing the one coil spring with the slide key 30 interposed therebetween, and is adjacent to the one coil spring in the circumferential direction. Different from the elastic coefficient of the coil spring. For example, the coil springs 41 and 43 facing each other across the slide key 30 have the same elastic coefficient, and the coil springs 42 and 44 facing in the other direction across the slide key 30 are coil springs 41 and 43. The elastic modulus is different from the elastic modulus. Thus, according to this invention, the magnitude | size of an operation load can be freely changed according to an operation direction by changing the arrangement position and elastic coefficient in the circumferential direction of each coil spring. Even if the outer peripheral shape of the slide plate 30b of the slide key 30 is changed (for example, it is not limited to a circle but a polygon), the magnitude of the operation load can be freely changed according to the operation direction.

  Further, in the case of the operation input device 1, in an initial state where no operation input is received, each of the coil portions 41c to 44c is urged so that the slide key 30 can be held at the initial position in the initial state with different contacts. In this state, the slide key 30 is in contact with the outer periphery of the slide plate 30b. Thus, the slide key 30 can be prevented from starting to slide from the initial position unless an operation load of a certain value or more is applied to the slide key 30.

  FIG. 6 is a relationship diagram between the movement amount (slide amount) W of the slide key 30 and the operation load F of the operation input. A dotted straight line L1 indicates a case where each coil spring is in contact with each contact point without being urged inward with respect to the outer periphery of the slide key 30, and a solid straight line L2 indicates that each coil spring is a slide key at each contact point. The case where it has contact | connected in the state urged | biased with respect to the outer periphery of 30 is shown. In the case of the solid straight line L2, a constant initial load f1 by the slide key 30 is applied to each coil spring from the lateral direction in an initial state where no operation input is applied. Since each coil spring is elastically deformed in a bent state so that the slide plate 30b of the slide key 30 is inscribed in the middle portion of each coil spring by the initial load from the lateral direction, the elasticity of each coil spring is A force (repulsive force) acts inward with respect to the outer periphery of the slide key 30. Therefore, as shown by the solid line L2, by applying the load f1 to each coil spring in advance (by applying the preload f1), the slide key 30 reacts sensitively to the operation load by the operator. Can be prevented from sliding.

  In the case of the operation input device 1, in order to generate the preload f1, as shown in FIGS. 4 and 5, each coil spring is moved from the outer periphery of the slide plate 30b of the slide key 30 in the initial state where no operation input is received. The fixed ends of the coil springs are positioned by a plurality of attachment portions such as 11a so that they come into contact with each other while being bent along the outer periphery of the slide plate 30b of the slide key 30.

  FIG. 7 is a perspective view of the operation input device 2 according to the second embodiment of the present invention. FIG. 8 is an exploded perspective view of the operation input device 2. The description of the same parts as those in the above embodiment is omitted.

  The lower case 60 is arranged such that the slide key 30 and a plurality of coil springs (four coil springs 41 to 44 in the case of the operation input device 2) supported in contact with the outer periphery of the slide key 30 in the sliding direction are arranged. A base having a surface 60a. The slide key 30 slides freely in each direction along the arrangement surface 60a. The lower case 60 may be made of resin or metal such as iron or aluminum.

  The slide key 30 is supported by the lower case 60 and the upper case 70 so as to be movable in a direction parallel to the XY plane. The lower surface of the upper case 70 is in contact with the upper surface of the slide plate of the slide key 30, and the arrangement surface 60 a of the lower case 60 is in contact with the lower surface of the slide plate of the slide key 30, whereby the slide key 30 is connected to the lower case 60 and the upper case 70. Can be supported so as to be displaceable in a direction parallel to the XY plane. The protrusion 30 a passes through a hole 70 a formed in the center portion of the upper case 70, and also passes through an XY displacement separation mechanism (details will be described later) housed in the upper case 70, and is formed in the upper cover 100. And is exposed from the upper surface of the upper cover 100. The lower cover 80 is fixed with the upper case 70 and the lower case 60 interposed therebetween. Further, in order to improve the operability for the operator, a contact portion 50 having a curved contact surface is attached to the upper portion of the protrusion 30a.

  Both ends of each of the coil springs 41 to 44 are fixed by convex mounting portions (bosses) formed on the upper case 70. For example, one fixed end 41a of the coil spring 41 is fixed by a mounting portion 76a, and the other fixed end 41b is similarly fixed by a mounting portion (not shown in the perspective view) formed on the upper case 70. The same applies to the other coil springs.

  The XY displacement separation mechanism includes a Y-direction displacement portion 71 that is movably attached in the Y direction, an X-direction displacement portion 72 that is movably attached in the X direction, and a stopper 73. An X direction displacement portion 72 extending in the Y direction is disposed above the Y direction displacement portion 71 extending in the X direction, and a stopper 73 extending in the Y direction is disposed above the X direction displacement portion 72. ing. The protrusion 30a of the slide key 30 includes a slide groove 71a formed in the X direction at the center of the Y direction displacement portion 71, a slide groove 72a formed in the Y direction at the center of the X direction displacement portion 72, and a stopper. It penetrates through a slide groove 73 a formed in the Y direction in the center of 73. Since the protrusion 30a penetrates the XY displacement separation mechanism in this way, the slide direction and the slide amount on the XY plane of the slide key 30 can be extracted as the X-direction displacement amount and the Y-direction displacement amount.

  Since the movement of the slide key 30 changes according to the operation input, the operation input corresponding to the movement of the slide key 30 can be detected by detecting the movement of the slide key 30. By detecting the operation input, it is possible to make a predetermined computer grasp the operation content corresponding to the detected operation input.

  FIG. 9 is a configuration diagram of the detection unit 90 that detects the movement of the slide key 30. The detection unit 90 includes a contact terminal 95 disposed on the lower surface of the Y-direction displacement unit 71 (see FIG. 8), and two conductor patterns 91 that run in parallel in the Y direction provided at positions where the contact terminal 95 can be contacted. , 92, a contact terminal 96 disposed on the lower surface of the X-direction displacement portion 72 (see FIG. 8), and two conductor patterns 93, 94 running in parallel in the X direction provided at positions where the contact terminal 96 can be contacted. And. The conductor patterns 91 to 94 are preferably formed on a substrate such as a flexible substrate. As shown in the figure, the substrate is formed with a hole through which the protrusion 30a of the slide key 30 can pass.

  The conductor pattern 91 is further formed with a resistance film 91b, and the conductor pattern 93 is further formed with a resistance film 93b. In addition, an electrode 91 a is formed at one end of the conductor pattern 91, and an electrode 92 a is formed at one end of the conductor pattern 92. Similarly, an electrode 93 a is formed at one end of the conductor pattern 93, and an electrode 94 a is formed at one end of the conductor pattern 94.

  The contact terminal 95 slides in the same Y direction while contacting the conductor patterns 91 and 92 in conjunction with the sliding movement of the slide key 30 in the Y direction, so that the resistance value between the electrode 91a and the electrode 92a is set. By detecting, the displacement amount of the slide key 30 in the Y direction can be detected. Similarly, the contact terminal 96 slides and moves in the same X direction while contacting the conductor patterns 93 and 94 in conjunction with the slide movement of the slide key 30 in the X direction, and therefore, between the electrode 93a and the electrode 94a. By detecting the resistance value, the displacement amount of the slide key 30 in the X direction can be detected. These resistance value detection means may be provided in an external device of the operation input device 2 or may be provided in the operation input device 2.

  Therefore, since the position of the slide key 30 on the XY plane can be detected, the operation content intended by the operator who operates the slide key 30 can be recognized by a predetermined computer.

  In the case of the operation input device 2, the “key return mechanism” composed of the slide key 30, the coil springs 41 to 44 and the lower case 60 is the “sensor mechanism” composed of the detection unit 90 and the XY displacement separation mechanism. Since it is located at the lower part, even if a large vertical load is applied to the slide key 30 via the protrusion 30a that penetrates in the vertical direction without contacting the sensor mechanism, the load on the sensor mechanism is suppressed. be able to. The positional relationship between the key return mechanism and the sensor mechanism may be upside down with respect to the operation input device 2.

  The operation input device 2 detects the movement of the slide key 30 by detecting a resistance value that changes with the movement of the slide key 30, but the detection method for detecting the movement of the slide key 30 is as follows. The method is not limited to that described above. For example, the movement of the slide key 30 may be detected by detecting the electric field intensity that changes with the movement of the slide key 30 using a magnetic sensor such as a Hall element or an MR element. The movement of the slide key 30 may be detected by detecting the changing capacitance.

  The preferred embodiments of the present invention have been described in detail above, but the present invention is not limited to the above-described embodiments, and various modifications, improvements, and modifications can be made to the above-described embodiments without departing from the scope of the present invention. Substitutions can be added.

  For example, as the elastic member in contact with the outer periphery of the slide key 30, the coil spring is exemplified in the above embodiment, but a rubber or a leaf spring may be used.

  Further, the operation input device is not limited to fingers and may be operated with a palm. Moreover, you may operate with a toe or a sole. The surface touched by the operator may be a flat surface, a concave surface, or a convex surface.

  Moreover, in the above-mentioned embodiment, although the example using four coil springs was shown, you may use 2 or 3 or 5 or more elastic members. FIGS. 10-12 is the figure which showed typically the contact state of the outer periphery of a slide member and an elastic member.

  For example, as shown in FIG. 10, the intermediate portions 46 c and 47 c of the two elastic members 46 and 47 may be in contact with the outer periphery of the slide member 35. Thereby, the load when the slide member 35 is slid in the direction of the fixed end can be made larger than the load when the slide member 35 is slid in the direction of the intermediate portion. Further, the fixed ends 46a and 47a may be fixed at the same location or at different locations. The same applies to the fixed ends 46b and 47b.

  Further, as shown in FIG. 11, the intermediate portions 46 c to 48 c of the three elastic members 46 to 48 may be in contact with the outer periphery of the slide member 35. Thereby, the load when the slide member 35 is slid in the direction of the fixed end can be made larger than the load when the slide member 35 is slid in the direction of the intermediate portion. Similarly to FIG. 10, the fixed ends on one side of the adjacent elastic members may be fixed at the same location or at different locations.

  Further, as shown in FIG. 12, the outer peripheral shape of the slide member 35 (36, 37) with which the intermediate portions 46c to 49c of the four elastic members 46 to 49 are in contact is not limited to a circle, but an ellipse or a quadrangle. Or a polygon such as an octagon. Moreover, if the contact part of the slide member which contacts an elastic member is circular as shown in the figure, friction between the elastic member and the slide member can be suppressed.

1, 2 Operation input device 10 Lower case 10a Arrangement surface 10b Slide surface 11a, 11b, 12a, 12b, 13a, 13b, 14a, 14b Mounting portion 20 Upper case 20a Through hole 30, 35, 36, 37 Slide member (slide key) )
30a Protrusion part 41-44 Elastic member (coil spring)
41a, 41b Fixed end 41c, 42c, 43c, 44c Intermediate part (coil part)
46 to 49 Elastic member 50 Contact portion 60 Lower case 70 Upper case 71 Y direction displacement portion 72 X direction displacement portion 73 Stopper 76a, 77a, 78b, 79b Mounting portion 80 Lower cover 90 Detection portion 91 to 94 Conductor pattern 91a to 94a Electrode 91b, 93b Resistive film 95, 96 Contact terminal 100 Upper cover

Claims (8)

An operation input device that receives an operation input,
A slide member that slides according to the operation input;
Comprising at least three or more elastic members fixed at both ends;
In an initial state in which the operation input is not received, the operation input device is characterized in that the intermediate portions of the elastic members are in contact with the outer periphery of the slide member at different contacts.   2. The operation input device according to claim 1, wherein the intermediate portion is in contact with the outer periphery in a biased state capable of holding the slide member in a position in the initial state in the initial state.   The operation input device according to claim 2, wherein the intermediate portion biases inward toward the outer periphery in the initial state.   The operation input device according to any one of claims 1 to 3, wherein an outer peripheral portion in contact with the intermediate portion of the slide member has an arc shape.   The operation input device according to any one of claims 1 to 4, wherein the elastic member is a coil spring. The outer circumference is a circumference,
The operation input device according to any one of claims 1 to 5, wherein the elastic members are arranged at equal intervals in a circumferential direction of the outer periphery.   The operation input device according to claim 6, wherein the number of the elastic members is four. An operation input device that receives an operation input,
A slide member that slides according to the operation input;
Comprising at least two or more elastic members fixed at both ends;
In an initial state in which the operation input is not received, the intermediate portions of the elastic members are in contact with the outer periphery of the slide member in a biased state in which the slide member can be held at the position in the initial state by different contact points. An operation input device characterized by comprising:

Images