WO2022045132A1 - Operation position detecting device - Google Patents

Abstract

An operation position detecting device is an operation position detecting device including an operating panel, the operating panel including a first operating region in which an input operation is detectable, a first protruding portion provided protruding from a surface of the operating panel in the first operating region, and a second protruding portion provided protruding from a surface of the first protruding portion.

Description

Operation position detector

The present invention relates to an operation position detection device.

For example, Patent Document 1 below discloses a console system provided with a touch pad having a three-dimensional three-dimensional shape in which a hemispherical portion and a flat portion are combined. Since there is a clear difference in shape between the hemisphere and the flat surface of this touchpad, the operator who operates this touchpad can tactilely determine whether he is touching the hemisphere or the flat surface. It can be determined.

Japanese Unexamined Patent Publication No. 2018-169758

However, the touch pad of Patent Document 1 does not have an element that makes it possible to tactilely discriminate between the reference position and the direction of operation within the range in which the hemisphere portion is provided. Therefore, the operator who operates the touch pad of Patent Document 1 may operate a portion of the hemisphere that should not be operated. Further, the operator who operates the touch pad of Patent Document 1 may perform an operation in a direction in which the touch pad should not be operated.

The operation position detection device according to one embodiment is an operation position detection device including an operation panel, and the operation panel protrudes from the surface of the operation panel in a first operation area in which an input operation can be detected and a first operation area. It has a first protrusion provided above the surface and a second protrusion provided so as to project from the surface of the first protrusion.

According to one embodiment, by making it easy to recognize the position where the operation panel should be operated, it is possible to suppress the input operation from being performed at the position where the operation panel should not be operated. Further, according to one embodiment, by making it easy to recognize the direction to be operated, it is possible to suppress the operation in the direction in which the operation should not be performed.

Plan view of the steering wheel according to the embodiment Top view of the operation position detection device according to one embodiment Partially enlarged cross-sectional view showing the shape of the first protrusion of the operation position detection device according to the embodiment in an enlarged manner. A plan view of the operation position detection device with the operation panel according to the embodiment removed. A plan view showing the positional relationship between each protrusion and each detection electrode in the operation position detection device according to the embodiment. A plan view for explaining a scroll operation method of the operation position detection device according to one embodiment. Partially enlarged cross-sectional view for explaining the scroll operation method of the operation position detection device according to one embodiment. An exploded perspective view of the operation position detection device according to the embodiment. Schematic diagram for explaining the display contents performed by the external device controlled by the control unit when the input operation is performed on the first protrusion according to the embodiment. A schematic diagram for explaining a state in which a fourth selection element is selected in a display content performed by an external device controlled by a control unit according to an embodiment. In the display content performed by the external device controlled by the control unit according to the embodiment, the display position of the fourth selection element to the seventh selection element is changed when an input operation is performed on the second operation area. Schematic diagram to explain how it is done A schematic diagram for explaining a state in which a fifth selection element is selected in a display content performed by an external device controlled by a control unit according to an embodiment. It is a top view for demonstrating the swipe operation method of the operation position detection apparatus which concerns on one Embodiment. It is a side view for demonstrating the swipe operation method of the operation position detection apparatus which concerns on one Embodiment.

Hereinafter, one embodiment will be described with reference to the drawings.

FIG. 1 is a plan view of the steering wheel 10 according to the embodiment. The steering wheel 10 shown in FIG. 1 is a steering device mounted in front of the driver's seat in a vehicle such as an automobile and operated by the driver of the vehicle. As shown in FIG. 1, the steering wheel 10 includes an annular wheel portion 12, a hub portion 14 provided at the center of the wheel portion 12 and connected to a column (not shown) extending from the vehicle, and a wheel. It has a pair of left and right spoke portions 16 that connect the portions 12 and the hub portion 14. An operation position detection device 100 is provided on each of the pair of left and right spoke portions 16. The operation position detection device 100 is an input device provided on the spoke portion 16 so that the driver can perform an input operation using the thumb while holding the steering wheel 10.

FIG. 8 is an exploded perspective view of the operation position detection device according to the embodiment. As shown in FIGS. 1 and 8, the operation position detection device 100 includes an operation panel 110 provided on the driver side and an electrostatic detection board (FPC120) provided on the back surface side of the operation panel 110 when viewed from the driver. ), And a circuit board 130 having an integrated circuit (control unit 132) for processing the detection signal. Further, the operation position detection device 100 has a case 102 that supports the operation panel 110 and the circuit board 130. The operation position detection device 100 has an electrostatic detection mechanism, and when the driver touches the surface 110A of the operation panel 110 or makes a gesture, the content of the input operation is electrostatically charged. It has a function to detect and generate a detection signal. Further, the operation position detection device 100 is a device that can generate an operation signal according to the content of the input operation and output it to an operation target device (for example, an audio device or the like). The operation panel 110 has a shape that is a combination of a planar shape and a protruding shape. In the present application, the gesture refers to an operation in which the operator moves a hand or a finger close to the operation panel 110 along the surface shape formed by the operation panel 110, and during the operation. , At least once, refers to the action of the hand touching the operation panel 110. Gesture is an example of input operation.

In the present embodiment, for convenience, the direction corresponding to the height direction of the vehicle is set to the vertical direction (Z-axis direction) with the traveling direction of the vehicle on which the steering wheel 10 is mounted as a reference, and the traveling direction of the vehicle is set to the front-rear direction. The direction (Y-axis direction). Further, the vertical direction and the direction orthogonal to the front-back direction are defined as the left-right direction (X-axis direction).

FIG. 2 is a plan view of the operation position detection device 100 according to the embodiment. FIG. 3 is a partially enlarged cross-sectional view showing an enlarged shape of the first protrusion 112 of the operation position detection device 100 according to the embodiment. FIG. 4 is a plan view of the operation position detection device 100 in a state where the operation panel 110 according to the embodiment is removed. The pair of left and right operation position detection devices 100 included in the steering wheel 10 have the same configuration except that they are symmetrical. Hereinafter, the configuration of the operation position detection device 100 will be described using the operation position detection device 100 on the left side as a representative.

As shown in FIG. 2, in a plan view from the rear (Y-axis negative direction), the vertical operation direction (an example of the "first operation direction") and the left-right operation direction of the operation panel 110 included in the operation position detection device 100. (An example of the "second operation direction") is tilted counterclockwise by a predetermined angle with respect to the vertical direction (Z-axis direction) and the left-right direction (X-axis direction) of the steering wheel 10. In the following description, the vertical operation direction of the operation panel 110 is the Z'axis direction, the upper operation direction is the Z'(+) direction, and the lower operation direction is the Z'(−) direction. Further, the left-right operation direction of the operation panel 110 is the X'axis direction, the right operation direction is the X'(+) direction, and the left operation direction is the X'(−) direction. The vertical operation direction is parallel to the tangential direction of the arc drawn by the fingertip of the thumb when the driver touches the operation panel 110 with the thumb while holding the steering wheel 10 and rotates the thumb around the thumb ball. It is provided in.

As shown in FIGS. 2 to 4, the operation position detection device 100 includes a case 102, an operation panel 110, an FPC 120, a circuit board 130, and a light guide sheet 140.

The case 102 is a member that functions as a base of the operation position detection device 100. The case 102 is a member that houses the FPC 120, the circuit board 130, and the light guide sheet 140. The case 102 supports the operation panel 110, the FPC 120, the circuit board 130, and the light guide sheet 140. For example, the case 102 is formed as a molded body obtained by molding a synthetic resin material by using a mold technique.

The operation panel 110 is a flat plate-shaped member that covers the front surface of the case 102. For example, the surface 110A of the operation panel 110 formed as a molded body made of a synthetic resin material is an operation surface on which an input operation is performed by an operator. The surface 110A is provided with a first operation region 111. The first protrusion 112 is provided so as to project in the first operation region 111.

In the present embodiment, the first protrusion 112 has a substantially semi-elliptical sphere shape obtained by cutting out a part of an ellipsoidal sphere. That is, the surface 112A of the first protrusion 112 has a quadric surface shape. Further, in the present embodiment, the first operation region 111 and the first protrusion 112 have an elliptical shape in which the vertical operation direction (Z'axis direction, an example of the "first direction") is the longitudinal direction in a plan view. Have. That is, the vertical operation direction is a direction that overlaps with the long axis of the elliptical shape formed by the first operation region 111 and the first protrusion 112 in a plan view.

The second protrusion 113 is provided on the surface 112A of the first protrusion 112 so as to project. In the present embodiment, the second protrusion 113 is provided in a linear shape overlapping the elliptical minor axis formed by the surface 112A in a plan view. The second protrusion 113 is an elongated rib shape that passes through the center of the elliptical shape and extends along the surface 112A in the left-right operation direction (X'axis direction, an example of the “second direction”). , It is provided with a height dimension that allows the operator to recognize that it has a rib shape when touched. Further, the second protrusion 113 is provided with a height dimension that does not interfere with the input operation by the operator. As shown in FIG. 3, the corner portion of the rib shape is chamfered, and the cross-sectional shape of the second protrusion 113 has a hemispherical shape. That is, the surface 113A of the second protrusion 113 has a curved surface.

Further, as shown in FIG. 2, the operation panel 110 has second operation areas 114A and 114B provided on the surface 110A outside the first operation area 111 in the left-right operation direction (X'axis direction). .. Further, the operation panel 110 has third protrusions 115A and 115B provided so as to project from the surface 110A in the second operation areas 114A and 114B. The third protrusions 115A and 115B are provided with a height dimension that allows the operator to recognize that they are protrusions when touched. Further, the third protrusions 115A and 115B are provided with a height dimension that does not interfere with the input operation by the operator. In the present embodiment, the operation panel 110 has a second operation area 114A in each of the left operation direction side (X'(−) side) and the right operation direction side (X'(+) side) of the first operation area 111. , 114B and third protrusions 115A, 115B. The second operation areas 114A and 114B and the third protrusions 115A and 115B are provided on the extension line of the second protrusion 113 in a plan view. The third protrusions 115A and 115B project from the surface 110A toward the rear (Y-axis negative direction). The third protrusion 115A has an isosceles triangle shape in a plan view from the rear (Y-axis negative direction), and the apex shared by the two isosceles triangles is on the left operation direction side (X'(X'( -) Is provided on the side). Further, the third protrusion 115B has an isosceles triangle shape in a plan view from the rear, and the apex shared by the two isosceles triangles is the right operation direction side (X'(+) side). It is provided in.

Further, as shown in FIG. 2, the operation panel 110 has third operation areas 116A and 116B provided on the surface 110A outside the first operation area 111 in the vertical operation direction (Z'axis direction). Further, the operation panel 110 has fourth protrusions 117A and 117B provided so as to project from the surface 110A in the third operation areas 116A and 116B. The fourth protrusions 117A and 117B are provided with a height dimension that allows the operator to recognize that they are protruding portions when touched. Further, the fourth protrusions 117A and 117B are provided with a height dimension that does not interfere with the gesture by the operator. In the present embodiment, the operation panel 110 has a third operation area 116A in each of the upper operation direction side (Z'(+) side) and the lower operation direction side (Z'(−) side) of the first operation area 111. , 116B and fourth protrusions 117A, 117B. The third operation areas 116A and 116B and the fourth protrusions 117A and 117B are provided on an extension of the elliptical long axis formed by the surface 112A in a plan view. The fourth protrusions 117A and 117B have a monolithic shape and project from the surface 110A toward the rear (Y-axis negative direction). The fourth protrusion 117A has an isosceles triangle shape in a plan view from the rear (Y-axis negative direction), and the apex shared by the two isosceles triangles is the upper operation direction side (Z'(Z'(Z'( It is provided on the +) side). Further, the fourth protrusion 117B has an isosceles triangle shape in a plan view from the rear, and the apex shared by the two isosceles triangles is the lower operation direction side (Z'(-) side). It is provided in.

The FPC 120 is a film-like substrate arranged on the back side (Y-axis positive side) of the operation panel 110. As will be described later with reference to FIG. 4, a plurality of detection electrodes are arranged on the surface 120A of the FPC 120. For example, each of the plurality of detection electrodes is formed by using a thin film material having conductivity (for example, copper foil). The capacitance of each of the plurality of detection electrodes is changed by capacitively coupling with a finger in the vicinity of the detection electrode. As a result, the control unit 132 of the circuit board 130 electrically connected to each of the plurality of detection electrodes can detect the input operation to the operation panel 110.

The circuit board 130 has a flat plate shape and has an electronic circuit formed on its surface. The circuit board 130 is arranged in the Y-axis positive direction of the FPC 120. As the circuit board 130, for example, a PWB (Printed Wiring Board) or the like is used. The circuit board 130 includes a control unit 132. The control unit 132 is connected to each of the plurality of detection electrodes via the FPC 120. The control unit 132 can detect an input operation to the operation panel 110 based on the detection signal (that is, the capacitance value) of each of the plurality of detection electrodes. As the control unit 132, for example, an IC, a microcomputer, or the like is used.

The light guide sheet 140 is a sheet-like member having light guide properties provided between the operation panel 110 and the circuit board 130. The operation panel 110 has a light-transmitting marker unit (not shown), and the light guide sheet 140 receives light emitted from an LED (Light Emitting Diode) 134 provided on the circuit board 130. Leads to the illuminated marker section.

(Configuration of FPC120)
As shown in FIG. 4, the first detection electrodes 122A to 122G, the second detection electrodes 124A and 124B, and the third detection electrodes 126A and 126B are arranged on the surface 120A of the FPC 120.

The first detection electrodes 122A to 122G are arranged side by side in the vertical operation direction (Z'axis direction) at the center of the left-right operation direction (X'axis direction, an example of the "second direction") along the surface 120A. There is. Each of the first detection electrodes 122A to 122G has a rectangular shape whose long side is parallel to the left-right operation direction.

The second detection electrode 124A is arranged on the left operation direction side (X'(−) side) with respect to the first detection electrodes 122A to 122G. The second detection electrode 124A is arranged at a position overlapping the third protrusion 115A. The second detection electrode 124A detects an input operation with respect to the third protrusion 115A. The second detection electrode 124A has a triangular shape indicating the left operation direction according to the shape of the third protrusion 115A.

The second detection electrode 124B is arranged on the right operation direction side (X'(+) side) of the first detection electrodes 122A to 122G. The second detection electrode 124B is arranged at a position overlapping the third protrusion 115B. The second detection electrode 124B detects an input operation with respect to the third protrusion 115B. The second detection electrode 124B has a triangular shape indicating the right operation direction according to the shape of the third protrusion 115B.

The third detection electrode 126A is arranged on the upper operation direction side (Z'(+) side) with respect to the first detection electrodes 122A to 122G. The third detection electrode 126A is arranged at a position overlapping the fourth protrusion 117A. The third detection electrode 126A detects an input operation with respect to the fourth protrusion 117A. The third detection electrode 126A has a triangular shape indicating the upper operation direction according to the shape of the fourth protrusion 117A.

The third detection electrode 126B is arranged on the lower operation direction side (Z'(−) side) with respect to the first detection electrodes 122A to 122G. The third detection electrode 126B is arranged at a position overlapping the fourth protrusion 117B. The third detection electrode 126B detects an input operation with respect to the fourth protrusion 117B. The third detection electrode 126B has a triangular shape indicating a downward operation direction according to the shape of the fourth protrusion 117B.

Further, on the surface 120A of the FPC 120, peripheral electrodes 128A to 128D are further arranged on the outside of both the left and right sides of the first detection electrodes 122A to 122G. The peripheral electrodes 128A and 128B are arranged side by side in the vertical operation direction (Z'axis direction) on the left operation direction side (X'(−) side) of the first detection electrodes 122A to 122G. The peripheral electrodes 128C and 128D are arranged side by side in the vertical operation direction (Z'axis direction) on the right operation direction side (X'(+) side) of the first detection electrodes 122A to 122G. The peripheral electrodes 128A to 128D are used for correcting the detection of the scroll operation.

(Positional relationship between each protrusion and each detection electrode)
FIG. 5 is a plan view showing the positional relationship between each protrusion and each detection electrode in the operation position detection device 100 according to the embodiment. In FIG. 5, the first protrusion 112, the second protrusion 113, the third protrusions 115A and 115B, and the fourth protrusions 117A and 117B are superimposed on the surface 120A of the FPC 120.

As shown in FIG. 5, of the first detection electrodes 122A to 122G, the first detection electrodes 122B to 122F are arranged at positions overlapping with the first protrusion 112. As a result, the capacitance of the first detection electrodes 122B to 122F changes according to the input operation with respect to the first protrusion 112, and the input operation can be detected.

Further, as shown in FIG. 5, the second detection electrode 124A is arranged at a position overlapping with the third protrusion 115A. As a result, the capacitance of the second detection electrode 124A of the second detection electrode 124A changes according to the input operation with respect to the third protrusion 115A, and the input operation can be detected.

Further, as shown in FIG. 5, the second detection electrode 124B is arranged at a position overlapping with the third protrusion 115B. As a result, the capacitance of the second detection electrode 124B changes according to the input operation with respect to the third protrusion 115B, and the input operation can be detected.

Further, as shown in FIG. 5, the third detection electrode 126A is arranged at a position overlapping with the fourth protrusion 117A. As a result, the capacitance of the third detection electrode 126A changes according to the input operation with respect to the fourth protrusion 117A, and the input operation can be detected.

Further, as shown in FIG. 5, the third detection electrode 126B is arranged at a position overlapping with the fourth protrusion 117B. As a result, the capacitance of the third detection electrode 126B changes according to the input operation with respect to the fourth protrusion 117B, and the input operation can be detected.

(Scroll operation method of operation position detection device 100)
6 and 7 are a plan view and a partially enlarged cross-sectional view for explaining a scroll operation method of the operation position detection device 100 according to the embodiment. In FIG. 6, the first protrusion 112, the second protrusion 113, the third protrusions 115A and 115B, and the fourth protrusions 117A and 117B are overlapped with respect to the surface 120A of the FPC 120.

The second protrusion 113 has a jetty shape that protrudes rearward (Y-axis negative direction) from the surface 112A and is provided in the left-right operation direction. Further, the second protrusion 113 is arranged at the center position in the front-rear direction of the surface 112A of the first protrusion 112. The surface 113A of the second protrusion 113 has a curved surface shape having a larger curvature than the surface 112A. Further, the first protrusion 112 has an elliptical shape, and is arranged at a position where the driver can perform an input operation using his / her thumb while holding the steering wheel 10. Therefore, when the operator touches the first protrusion 112 and recognizes its shape, the operator slides the finger 20 in the vertical operation direction (Z'axis direction) even if there is no other suggestive information. (That is, scroll operation) can be performed.

Further, the operator touches the first protrusion 112 and the second protrusion 113 at the same time with the finger 20 when performing the scroll operation. At that time, the operator can clearly recognize the common features and the highly related features of the first protrusion 112 and the second protrusion 113. Specifically, since the elliptical short axis direction formed by the first protrusion 112 and the direction provided with the second protrusion 113 are common, the operator can easily recognize the left and right operation directions. I can. Further, since the elliptical long axis direction formed by the first protrusion 112 and the direction provided with the second protrusion 113 are orthogonal to each other, the operator can easily recognize the vertical operation direction. Further, since the second protrusion 113 is arranged at the center position in the front-rear direction of the surface 112A of the first protrusion 112, the operator can set the center position of the elliptical shape formed by the first protrusion 112 in the long axis direction. Easy to recognize. As a result, the operator can easily determine the reference position when the scroll operation is performed on the surface 112A and the direction in which the scroll operation should be performed based on the information obtained from the tactile sense.

Here, in the example shown in FIGS. 6 and 7, the upper operation direction side (Z'(+) side) of the second protrusion 113 is defined as a point on the intersection line between the second protrusion 113 and the first protrusion 112. A contact point P1 is defined in which the cross-sectional shape is obtuse or right-angled when the peripheral portion is cut in the ZY plane. Further, a contact point P2 formed as a point on a ridgeline connecting the vertices of the second protrusion 113 is defined. Further, it is formed on the lower operation direction side (Z'(-) side) of the second protrusion 113 as a point on the intersection line between the second protrusion 113 and the first protrusion 112, and the peripheral portion is cut by the ZY plane. A contact point P3 whose cross-sectional shape is obtuse or right-angled is defined.

As shown in FIGS. 6 and 7, the operator slides the finger 20 in the downward operation direction (Z'(−) direction) from the contact point P1 to the contact point P3 via the contact point P2. Therefore, it is possible to perform a scroll operation in the downward operation direction for the application to be operated.

On the contrary, the operator slides the finger 20 from the contact point P3 to the contact point P1 via the contact point P2 in the upward operation direction (Z'(+) direction) to move the operation target application. On the other hand, it is possible to perform a scroll operation in the upward operation direction.

At this time, since the first protrusion 112 has an elliptical shape, the operator can tactilely determine the vertical operation direction (Z'axis direction) in which the finger 20 should be slid.

Further, since the second protrusion 113 extends in the left-right operation direction (X'axis direction), the operator slides the finger 20 in a direction orthogonal to the extending direction of the second protrusion 113. It can be tactilely determined as the vertical operation direction (Z'axis direction).

Therefore, according to the operation position detection device 100 according to the embodiment, by making it easy to recognize the position to be operated on the operation panel, it is possible to suppress the input operation from being performed at the position where the operation panel should not be operated. Further, according to the operation position detection device 100 according to the embodiment, by making it easy to recognize the direction to be operated, it is possible to suppress the operation in the direction in which the operation should not be performed.

Further, when the operator slides the finger 20 along the surface 112A and the surface 113A in the vertical operation direction (Z'axis direction), the operator makes a predetermined distance (that is, the contact point P1) based on the information obtained from the tactile sense. The slide operation (distance from to the contact point P3) can be performed. That is, a certain amount of slide operation can be easily performed without looking at the operation panel 110.

By performing such a slide operation, the operator can perform a vertical scroll operation on the application to be operated.

The control unit 132 is connected to electrodes (122A to 122G, 124A, 124B, 126A, 126B, 128A to 128D) provided on the FPC 120. Further, the control unit 132 is connected to an external device (not shown) such as a display of the operation position detection device 100. The control unit 132 receives the detection signal (that is, the capacitance value) detected from each of the electrodes (122A to 122G, 124A, 124B, 126A, 126B, 128A to 128D), and indicates based on the detection signal. 20 position information is determined. Further, the control unit 132 transmits the position signal of the detection position to the external device.

FIG. 9 is a schematic diagram for explaining the display content performed by the external device controlled by the control unit 132 when the input operation is performed on the first protrusion according to the embodiment. When a predetermined amount of vertical scrolling operation is performed, the control unit 132 transmits the position signal related to the input content to an external device, and for example, distances the display position of the selection element M2 shown in FIG. The L transition is made to the selected position S1. Further, when the scroll operation is performed twice as much as the above-mentioned predetermined amount of scroll operation, the control unit 132 selects, for example, by shifting the display position of the selection element M3 shown in FIG. 9 by twice the distance L. Set to position S1.

Further, by adjusting the control unit 132 in advance and associating the amount of the input operation with the transition distance of the selection element, it becomes easy to accurately operate the external device. Specifically, for example, by associating the distance L with the amount of change in the position signal (that is, the amount of input operation) when the finger 20 moves from the contact point P1 to the contact point P3, the external device can be used. It becomes easy to operate accurately.

An example of the action and effect when the control unit 132 is adjusted in advance will be described below. The operator can quantitatively perform the slide operation from the contact point P1 to the contact point P3 based on the information obtained from the tactile sense. The control unit 132 generates a position signal based on the input operation, and the position signal changes by a predetermined amount. The external device moves the display position of the selection element M2 by the distance L to the selection position S1 based on the position signal. When this series of operations is performed, the operator does not need to look at the operation panel 110. That is, since the operator can easily perform an accurate amount of input operation by touch typing, the operator can operate the external device accurately and without excess or deficiency.

(Shortcut operation method of operation position detection device 100)
In addition, the operator refers to the first protrusion 112 and the second protrusion 113 in the upper operation direction (Z'(+) direction) which is the long axis direction from the first protrusion 112 to the first protrusion 112. The finger 20 can be moved. Then, the position of the fourth protrusion 117A protruding from the moving destination is grasped tactilely, and an input operation (upper shortcut operation) for the third operation area 116A provided corresponding to the fourth protrusion 117A is performed. )It can be performed. At this time, the control unit 132 detects that an input operation to the fourth protrusion 117A has been performed based on the capacitance value of the third detection electrode 126A provided on the back side of the fourth protrusion 117A. Can be done.

Further, the operator refers to the first protrusion 112 and the second protrusion 113 in the downward operation direction (Z'(−) direction) which is the long axis direction from the first protrusion 112 to the first protrusion 112. The finger 20 can be moved. Then, the position of the fourth protrusion 117B protruding from the moving destination is grasped tactilely, and an input operation (lower shortcut operation) for the third operation area 116B provided corresponding to the fourth protrusion 117B is performed. )It can be performed. At this time, the control unit 132 detects that the input operation to the fourth protrusion 117B has been performed based on the capacitance value of the third detection electrode 126B provided on the back side of the fourth protrusion 117B. Can be done.

The input operation can be shortened by adjusting the control unit 132 in advance and associating the transition distance of the selection element with the input operation for the third operation area. Specifically, for example, by associating a distance that is an integral multiple of the distance L with the upper shortcut operation, a slide operation from the contact point P1 to the contact point P3 can be performed quickly and accurately simply by performing the upper shortcut operation. It is possible to perform the same input operation as repeating the above several times. Since the operator can tactilely grasp the position of the fourth protrusion (117A, 117B), the operator can easily perform a shortcut operation by touch typing.

(Input mode switching operation method of operation position detection device 100)
Further, the operator uses the first protrusion 112 and the second protrusion 113 as a reference, and the finger 20 is in the left operation direction (X'(−) direction) on the extension line from the first protrusion 112 to the second protrusion 113. Can be moved. Then, the position of the third protrusion 115A protruding from the moving destination is grasped tactilely, and an input operation (left input mode) for the second operation area 114A provided corresponding to the third protrusion 115A is performed. Switching operation) can be performed. At this time, the control unit 132 detects that the input operation to the third protrusion 115A has been performed based on the capacitance value of the second detection electrode 124A provided on the back side of the third protrusion 115A. Can be done.

Further, the operator uses the first protrusion 112 and the second protrusion 113 as a reference, and the finger 20 is in the right operation direction (X'(+) direction) on the extension line from the first protrusion 112 to the second protrusion 113. Can be moved. Then, the position of the third protrusion 115B protruding from the moving destination is grasped tactilely, and the input operation (right input mode) for the second operation area 114B provided corresponding to the third protrusion 115B is performed. Switching operation) can be performed. At this time, the control unit 132 detects that the input operation to the third protrusion 115B has been performed based on the capacitance value of the second detection electrode 124B provided on the back side of the third protrusion 115B. Can be done.

FIG. 10 is a schematic diagram for explaining a state in which the fourth selection element M4 is selected in the display content performed by the external device controlled by the control unit 132 according to the embodiment. FIG. 11 shows from the fourth selection element M4 when an input operation is performed on the second operation area (114A, 114B) in the display content performed by the external device controlled by the control unit 132 according to the embodiment. It is a schematic diagram for demonstrating how the display position of the 7th selection element M7 is changed. FIG. 12 is a schematic diagram for explaining a state in which the fifth selection element M5 is selected in the display content performed by the external device controlled by the control unit 132 according to the embodiment.

The operation position detection device 100 is often set as an input device for operating a plurality of operation targets, and is set so that an input mode for operating each operation target can be switched. In such a case, the external device controlled by the control unit 132 may be provided with a display function for indicating the state of the input mode to the operator. As an example of the display function, there is a drum rotation selection type interface configured to include selection elements (M4 to M7) associated with each operation target as shown in FIGS. 10 to 12. In such a drum rotation selection type interface, the current input mode state is indicated by the type of selection element displayed at the selection position S2. The control unit 132 according to one embodiment is adjusted so that the display position of the selection element (M4 to M7) moves and the drum rotation selection type interface rotates each time the input mode switching operation is performed. Specifically, for example, as shown in FIG. 10, when the left input mode switching operation is performed while the selection element M4 is displayed at the selection position S2, the drum rotation selection type interface rotates counterclockwise. After passing through the state of FIG. 11, the drum is rotated by 90 ° to reach the state shown in FIG. At this time, the input mode is switched from the input mode corresponding to the selection element M4 to the input mode corresponding to the selection element M5. Since the operator can tactilely grasp the position of the third protrusion (115A, 115B), the operator can easily switch the input mode by touch typing.

Further, when the operator touches the first protrusion 112 and recognizes its shape, the operator slides the finger 20 in the left-right operation direction (X'axis direction) even if there is no other suggestive information. (That is, a swipe operation) can be performed. When the control unit 132 detects that the swipe operation has been performed by the operator, the control unit 132 rotates the drum rotation selection type interface in the manner shown in FIGS. 10 to 12 according to the content of the input, and inputs the input. It has a function to switch modes.

FIG. 13 is a plan view for explaining a swipe operation method of the operation position detection device 100 according to the embodiment. FIG. 14 is a side view for explaining a swipe operation method of the operation position detection device 100 according to the embodiment.

For example, when the operator transitions the finger 20 from the contact point P2 shown in FIGS. 13 and 14 to the contact point P5, the operation is detected as a swipe input operation to the right. Further, for example, when the operator transitions the finger 20 from the contact point P4 to the contact point P5, the operation is detected as a swipe input operation to the right. Further, for example, when the operator transitions the finger 20 from the contact point P4 to the contact point P2, the operation is detected as a swipe input operation to the right.

For example, when the operator transitions the finger 20 from the contact point P2 to the contact point P4, the operation is detected as a swipe input operation to the left. Further, for example, when the operator transitions the finger 20 from the contact point P5 to the contact point P4, the operation is detected as a swipe input operation to the left. Further, for example, when the operator transitions the finger 20 from the contact point P5 to the contact point P2, the operation is detected as a swipe input operation to the left.

Although one embodiment of the present invention has been described in detail above, the present invention is not limited to these embodiments, and various modifications or modifications are made within the scope of the gist of the present invention described in the claims. It can be changed.

The second protrusion 113 is not limited to the shape described in the embodiment. For example, the second protrusion 113 may have a rib shape extending in the vertical operation direction (Z'axis direction) along the surface 112A of the first protrusion 112. Further, for example, the second protrusion 113 extends along the surface 112A of the first protrusion 112 in each of the left-right operation direction (X'axis direction) and the up-down operation direction (Z'axis direction). It may have a cross-shaped rib shape in a plan view. Further, for example, the second protrusion 113 may have a dot shape provided at the center of the surface 112A of the first protrusion 112. Further, for example, the second protrusions 113 are continuously arranged side by side in the left-right operation direction (X'axis direction) or the up-down operation direction (Z'axis direction) along the surface 112A of the first protrusion 112. It may have a plurality of dots. Further, for example, the second protrusion 113 has a shape in which a concave shape and a convex shape are combined (for example, a shape in which a plurality of grooves are intermittently formed in a direction in which the rib shape extends with respect to the rib shape. ) May be present. In other words, for example, the second protrusion 113 may be an aggregate of a plurality of rib pieces arranged continuously in one direction with a gap between them.

This international application claims priority based on Japanese Patent Application No. 2020-141887 filed on August 25, 2020, and the entire contents of this application shall be incorporated into this international application.

10 Steering wheel 12 Wheel part 14 Hub part 16 Spoke part 100 Operation position detection device 102 Case 110 Operation panel 110A Surface 111 1st operation area 112 1st protrusion 112A Surface 113 2nd protrusion 113A Surface 114A, 114B 2nd operation area 115A, 115B 3rd protrusion 116A, 116B 3rd operation area 117A, 117B 4th protrusion 120 FPC
120A Surface 122A-122G 1st detection electrode 124A, 124B 2nd detection electrode 126A, 126B 3rd detection electrode 128A-128D Peripheral electrode 130 Circuit board 132 Control unit 134 LED
140 light guide sheet

Claims (11)

1. An operation position detection device equipped with an operation panel.
   The operation panel is
   The first operation area where input operations can be detected, and
   A first protrusion provided so as to project from the surface of the operation panel in the first operation region,
   An operation position detection device characterized by having a second protrusion provided so as to project from the surface of the first protrusion.
2. The operation position detection device according to claim 1, wherein the surface of the first protrusion has a curved surface.
3. The operating position detecting device according to claim 1 or 2, wherein the second protrusion is continuously formed on the surface of the first protrusion in a plan view.
4. The claim is characterized in that the second protrusion is continuously formed along a second operation direction orthogonal to the first operation direction arranged along a predetermined direction of the first protrusion. The operation position detecting device according to 1 or 2.
5. The operation position detecting device according to claim 4, wherein the first protrusion has an elliptical shape having the first operation direction as a longitudinal direction in a plan view.
6. The operation panel is
   On the surface of the operation panel, a second operation area where an input operation can be detected, which is provided outside the first operation area in the second operation direction,
   The operation position detecting device according to claim 4 or 5, wherein the second operation region has a third protrusion provided so as to project from the surface of the operation panel.
7. The operation panel is
   On the surface of the operation panel, a third operation area where an input operation can be detected, which is provided outside the first operation area in the first operation direction,
   The operation position detecting device according to any one of claims 4 to 6, wherein the third operation region has a fourth protrusion provided so as to project from the surface of the operation panel.
8. The fourth aspect of claim 4, wherein a plurality of first detection electrodes are arranged side by side in the first operation direction at a position overlapping with the first protrusion and detect a scroll operation with respect to the first protrusion. Operation position detector.
9. The operation position detecting device according to claim 6, further comprising a second detection electrode arranged at a position overlapping the third protrusion and detecting an input operation with respect to the third protrusion.
10. The operation position detecting device according to claim 7, further comprising a third detection electrode arranged at a position overlapping the fourth protrusion and detecting an input operation with respect to the fourth protrusion.
11. The operating position detecting device according to claim 8, further comprising a plurality of peripheral electrodes arranged side by side in the first operating direction on the outside of the plurality of first detecting electrodes in the second operating direction.

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