JP2013242767A - Input apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an input apparatus having a plurality of regions for detecting contact, enabling operation over the plurality of regions, and allowing an operator to check the boundary of each region with the feeling of fingertips.SOLUTION: An input apparatus 1 includes a plurality of detection regions A-E for detecting contact with respect to detection surfaces and outputting operation signals, and non-detection regions X-Xthat are provided between the plurality of detection regions A-E and at different angles from the detection surfaces of adjacent detection regions A-E among the plurality of detection regions A-E, and do not detect the contact.

Description

  The present invention relates to an input device.

  As a conventional technique, there is an input device in which a touch pad is divided into a plurality of areas and each area has a different function (see, for example, Patent Document 1).

  This input device scrolls a display area, which is a pointing area used for designating coordinates on a display screen of a display device connected to the input device, as a divided touchpad area. And a vertical scroll area used for scrolling the display image up and down with respect to the display screen. Further, ribs are provided on the boundary lines of the above-described areas.

  According to the input device described above, since the rib has a raised shape with respect to the touch pad, the operator can recognize the boundary of each region by the touch of the fingertip.

JP 2000-20194 A

  However, the input device shown in Patent Document 1 is not supposed to be operated across a plurality of areas, and when an operation is performed across a plurality of areas, the operator's fingertips are caught on the ribs, and it cannot be said that the operation feeling is good. .

  Therefore, an object of the present invention is to provide an input device that has a plurality of areas for detecting contact, can be operated across a plurality of areas, and allows the operator to check the boundaries of each area by the touch of a fingertip. Is to provide.

One aspect of the present invention includes a plurality of detection regions that detect contact with a detection surface and output an operation signal;
Provided is an input device having a non-detection region that is provided at an angle different from a detection surface of an adjacent detection region among the plurality of detection regions and does not detect contact between the plurality of detection regions.

One of the plurality of detection areas of the input device is provided in parallel to the installation surface of the input device,
The non-detection area is provided so as to rise from one of the plurality of detection areas with respect to the installation surface,
The detection region adjacent to the non-detection region other than one of the plurality of detection regions may be provided on the opposite side of the plurality of detection regions so as to be lowered with respect to the installation surface.

Further, one of the plurality of detection regions of the input device is arranged in the center,
The non-detection region is arranged around one of the plurality of detection regions,
The detection area other than one of the plurality of detection areas may be arranged outside the non-detection area.

  The detection area and the non-detection area of the input device may be connected to each other continuously.

  Further, one of the plurality of detection regions of the input device may be subjected to a surface treatment different from the detection region other than the one of the plurality of detection regions.

  Further, one of the plurality of detection regions of the input device moves to the installation surface side, and the detection region other than the one of the plurality of detection regions moves to the side opposite to the installation surface, and is one of the plurality of detection regions. The distance from a detection area other than one of the plurality of detection areas may be variable.

  According to the present invention, it is possible to perform an operation across a plurality of areas, and the operator can confirm the boundary of each area by the touch of a fingertip. Further, it is possible to prevent the operator from erroneously touching a detection region other than the detection region to be operated.

1A to 1C are a plan view, an α-α cross-sectional view, and a β-β cross-sectional view showing an example of the configuration of the input device according to the embodiment, respectively. FIG. 2 is a block diagram illustrating an example of a configuration of an information processing apparatus using the input device according to the present embodiment. FIGS. 3A to 3C are diagrams for explaining the operation content in the input device. 4A and 4B are diagrams for explaining an example of an operation performed on an image displayed on the display screen of the display unit of the information processing apparatus. 5A to 5C are β-β cross-sectional views showing modifications of the configuration of the input device.

(Configuration of input device)
1A to 1C are a plan view, an α-α cross-sectional view, and a β-β cross-sectional view showing an example of the configuration of the input device according to the embodiment, respectively.

This input device 1 is provided between detection areas A to E for detecting contact of an operator's finger and outputting an operation signal, and non-detection that is provided between the detection areas A to D and detection area E and does not detect contact. and a region _X a to X _D.

As an example, the detection region E is provided in parallel to the installation surface S of the input device 1. In addition, the non-detection areas X _{A to} X _D form a slope so as to surround the detection area E, and the detection areas A to _D surround the non-detection areas X _{A to} X _D in the outer circumferential direction. A slope is formed so as to go down. The boundary between the regions is preferably continuous and smooth, but may be discontinuous as long as the operator's fingertips are not caught.

The size of the input device 1 is, for example, 40 mm × 40 mm in plan view, the size of the detection region E is 26 mm × 26 mm, and the angle of the detection regions A to D and the non-detection regions X _{A to} X _D with respect to the detection region E is 45. °. The size can be changed as appropriate according to the intended use.

  The detection areas A to E of the input device 1 are, for example, touch pads that detect positions on the touched detection surface when the detection surface is touched with a part of the operator's body (for example, a finger). For example, the operator can operate the information processing apparatus 4 by operating the detection surface. As the detection areas A to E of the input device 1, for example, a well-known resistive film type, infrared type, SAW (Surface Acoustic Wave) type, capacitive type touch pad or the like can be used.

  The detection regions A to E of the input device 1 according to the present embodiment detect, for example, a change in current that is inversely proportional to the distance between the electrode provided below the detection surface and the finger when the finger approaches the detection surface. It is a capacitive touch pad that outputs as

The surface including the detection areas A to E and the non-detection areas X _{A to} X _D of the input device 1 is formed in a plate shape using, for example, PET (Polyethylene terephthalate) or glass. For the detection regions A to E, a matrix-like electrode is formed on the back surface of the detection surface, and for example, ITO (Indium Tin Oxide) is used.

  In addition, the input device 1 reads the capacitance from the electrodes on the back surface of the detection areas A to E according to the clock signal generated inside, and coordinates based on the read capacitance value (capacitance value). A value is generated and output to the control unit 2 as an operation signal.

  FIG. 2 is a block diagram illustrating an example of a configuration of an information processing apparatus using the input device according to the present embodiment.

  The information processing device 4 includes an input device 1 that outputs an operation signal based on an input operation (contact) by an operator, and a character that converts the operation signal input from the input device 1 into a control signal or displays on the display unit 3 And a control unit 2 including a CPU (Central Processing Unit) and a GPU (Graphic Processing Unit) that output information such as images and images to the display unit 3, and a display unit 3 such as a liquid crystal display that displays characters and images . In addition, the control part 2 may be incorporated in the input device 1 or the display part 3, and may be comprised independently.

  The control unit 2 functions as an operation signal receiving unit 20, an operation signal converting unit 21, a control signal output unit 22, a display control unit 23, and the like.

  The operation signal receiving unit 20 receives an operation signal output from the input device 1.

  The operation signal converting means 21 converts the operation signal received by the operation signal receiving means 20 into a control signal based on a table or the like (not shown) for converting the operation signal and the control signal prepared in advance.

  The control signal output means 22 outputs the control signal converted by the operation signal conversion means 21 to an external device (not shown) connected to the display control means 23 or the information processing device 4 according to the type of the control signal.

  The display control unit 23 outputs information for displaying an image on the display unit 3. Further, information for displaying an image on the display unit 3 is changed based on the control signal output by the control signal output means 22.

  The display unit 3 is a known liquid crystal display such as a TFT (Thin Film Transistor) type. The display unit 3 is connected to the control unit 2 and displays an image on the display screen based on information for displaying an image output from the control unit 2.

(Operation)
Hereinafter, the operation of the information processing apparatus 4 will be described by dividing it into (1) basic operation, (2) input device operation example, and (3) image display operation example, with reference to FIGS.

(1) Basic Operation First, when power is supplied to the information processing apparatus 4 from a power source (not shown), the display control unit 23 of the control unit 2 displays an initial screen on the display unit 3.

  Next, the operator performs some operation by touching the input device 1 while viewing the initial screen of the display unit 3.

  The input device 1 detects the position touched by the operator in the detection areas A to E on the detection surface. The position is detected by reading the capacitance from the electrode in accordance with an internally generated clock signal, and the detected position is a coordinate value based on the read capacitance value (capacitance value). Is generated and output as an operation signal. The operation signal output from the input device 1 is input to the control unit 2.

  The operation signal receiving means 20 of the control unit 2 receives the input operation signal. Next, the operation signal converting unit 21 converts the operation signal received by the operation signal receiving unit 20 into a control signal based on a table for converting the operation signal and the control signal prepared in advance.

  Next, the control signal output means 22 of the control unit 2 is connected to the display control means 23 or the information processing apparatus 4 according to the type of the control signal from the control signal converted by the operation signal accepting means 20 or an external device (not shown). Output to. The control signal output means 22 also outputs a control signal when the display of the display control means 23 is changed.

  When the control signal is input from the control signal output unit 22, the display control unit 23 changes information for displaying an image on the display unit 3 based on the control signal. A specific example of the change will be described in detail in “(3) Image display operation example”.

  When the control signal output unit 22 outputs a control signal to an external device or the like, the external device operates based on the control signal.

  Below, operation with respect to the input device 1 is demonstrated concretely.

(2) Input Device Operation Example FIGS. 3A to 3C are diagrams for explaining the operation content in the input device 1.

As shown in FIG. 3A, an operation such as a coordinate instruction is input by moving the operator's index finger 5 or the like on the detection area E of the input device 1 and moving it. At this time, when the finger is moved to the end of the detection region E, the index finger 5 comes into contact with the concave portion d _A , the non-detection region X _A or the concave portion d _C , and the non-detection region X _C. It can be recognized that the index finger 5 is located at the same time. The index finger 5 does not malfunction because it does not contact the detection areas A and C (B, D). In addition, you may operate the input device 1 not only with the index finger 5 but with other fingers, and you may operate using input tools, such as a stylus pen.

Also, as shown in FIG. 3B, the operator's index finger 5 or the like is moved in contact with the detection area E of the input device 1 to get over the concave part d _A , the non-detection area X _A , and the convex part u _A. By touching the detection area A, an operation different from the coordinate instruction or the like (see “(3) Image display operation example” described later) is input. Note that the index finger 5 can move smoothly while contacting the detection area E, the recess d _A , the non-detection area X _A , the projection u _A , and the detection area A, unlike the case of overcoming the ribs and the like.

Further, as shown in FIG. 3C, an operation such as a coordinate instruction is input by moving the operator's index finger 5 or the like on the detection area B (A, C, D) of the input device 1 and moving it. The At this time, if the finger is moved to the end of the detection area B (the boundary with A or C), the index finger 5 comes into contact with the convex portion s _A or s _B , and the operator has the index finger 5 at the end of the detection area B. Positioning can be recognized by tactile sense. Further, when the finger is moved to the edge of the detection area B (the boundary between the X _B), index finger 5 comes into contact with the protrusion u _B, the operator by tactile that the index finger 5 at the edge of the detection area B located Can be recognized. Further, since the index finger 5 does not touch the detection area E, it does not malfunction.

(3) Example of Image Display Operation FIGS. 4A and 4B are diagrams for explaining an example of an operation performed on an image displayed on the display screen of the display unit 3 of the information processing device 4. .

  The case where the icon display screen 30 and the map display screen 31 are displayed on the display screen of the display unit 3 by the display control means 23 as shown in FIG. A plurality of types of icons 30a to 30d are displayed on the icon display screen 30, and a map and an enlargement / reduction bar 31a for operating the enlargement / reduction of the map are displayed on the map display screen 31.

  The map display screen 31 is a screen that displays a map used in a navigation system or the like, and the icons 30 a to 30 d of the icon display screen 30 are arranged on the map display screen 31.

  When the operator performs an operation in the detection area E of the input device 1, the map is scrolled on the map display screen 31. When an operation is performed in the detection area D of the input device 1, the enlargement / reduction bar 31a of the map display screen 31 is operated, and the enlargement ratio of the displayed map is changed.

  Further, when the operator performs an operation in the detection area B of the input device 1, the icons 30a to 30d selected on the icon display screen 30 are changed.

At this time, the operator performs an operation in the detection area B of the input device 1 moves over the non-detection region X _B from the detection area B in a state where the icon 30a is selected in the detection region E in the icon display screen 30 operated As shown in FIG. 4A, the icon 30a is moved (dropped) to the map display screen 31. The arrangement position on the map display screen 31 can be moved by operating the detection area E of the input device 1.

  Note that, for example, from when the input device 1 is operated to when the icon 30a is instructed, the input device 1 outputs an operation signal according to the operation, and is received by the operation signal receiving unit 20 to be operated signal converting unit. 21 is converted into a control signal, and the control signal output means 22 outputs it to the display control means 23, and the display control means 23 performs display processing. However, in order to simplify the explanation below, the same processing is performed. Description of this process is omitted.

  Moreover, as shown in FIG.4 (b), the case where the map display screen 31 and the menu display screen 32 are displayed is demonstrated. On the menu display screen 32, menu icons 32a to 32f for changing to a screen corresponding to each function are displayed.

  When the operator performs an operation in the detection area E of the input device 1, the operation is reflected on either the map display screen 31 or the menu display screen 32. When the operation on the map display screen 31 is valid, the map is scrolled, and when the operation on the menu display screen 32 is valid, one of the menu icons 32a to 32f is selected.

For example, when the operation of the map display screen 31 is valid, the operator operation to move is made from the detection area B of the input device 1 in the detection region E overcame non-detection region X _B, the map display screen The operation at 31 becomes invalid, and the operation at the menu display screen 32 becomes valid.

Also, if the operation on the menu screen 32 is valid, the operator operation to move is made from the detection region D of the input device 1 in the detection region E overcame non-detection region X _D, menu display screen The operation in 32 becomes invalid, and the operation in the map display screen 31 becomes valid.

(Effect of embodiment)
According to the above-described embodiment, for example, since the recess d _A or the recess d _C is provided at the end of the detection area E, the operator can recognize the boundary of each area by touching the fingertip.

  Further, without providing ribs or the like between the regions, the regions are connected continuously or at a level difference that does not catch the finger, so the index finger 5 can move smoothly while contacting each region, Operation across the area is possible.

Further, a non-detection area is provided between the detection area E and the detection areas A to D, and when the index finger 5 is positioned at the end of the detection area E, the non-detection areas X _{A to} X _D are contacted, and the detection area A Since it is configured so as not to contact ~ D, malfunction can be suppressed.

  The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from or adjusting the technical idea of the present invention. For example, the configuration of the input device 1 may be modified as shown below.

  5A to 5C are β-β cross-sectional views showing modifications of the configuration of the input device 1.

As shown to Fig.5 (a), you may comprise the cross section of the detection areas D and B (A, C) with a curved surface. Further, the non-detection regions X _{A to} X _D may be configured with curved surfaces. By configuring each surface with a curved surface, the operation across the regions is performed more smoothly.

Further, as shown in FIG. 5 (b), constituted by a polygon as a cross section of the non-detection region _{X D1, X D2} and _{X B1, X B2 (X A1} , X A2 and _{X C1, X C2)} May be. By making the polygonal shape, the boundary of the detection area E can be confirmed by the touch of the fingertip, and when performing an operation across a plurality of areas, the operation across each area is performed as compared to the case where it is not a polygonal shape. It can be moved more smoothly.

In the embodiment, the detection regions A to E have a configuration in which a matrix-like electrode is formed on the back surface of the detection surface, and the non-detection regions X _{A to} X _D are not formed on the back surface of the detection surface. As shown in FIG. 5C, electrodes are formed on the entire back surface of the detection surface, and insulating covers X _D3 , X so as not to detect contact in the areas corresponding to the non-detection areas X _{A to} X _{D B3} (X _A3 , X _C3 ) may be provided.

  Note that these modifications may be combined as appropriate.

  Further, a mechanical switch may be provided under the detection areas A to E or under the input device 1 so that different push operations can be performed on the detection areas A to E, respectively.

  In the embodiment, the detection areas A to E are described as detecting positions on the detection surface touched by the operator. However, when the operator moves a fingertip or the like while touching the detection surface, the movement amount Or the moving speed may be detected.

  Further, the surface treatment applied to the detection regions A to D may be different from the surface treatment applied to the detection region E. For example, the user may feel the surface treatment of the detection areas A to D smoothly, and the user may feel the roughness of the surface treatment of the detection area E. Or vice versa.

  Further, by making the detection area E variable in a direction approaching the installation surface S of the input device 1 and making the detection areas A to D variable in a direction away from the installation surface S, the detection area E and the detection areas A to D are changed. The step distance may be variable.

DESCRIPTION OF SYMBOLS 1 Input device 2 Control part 3 Display part 4 Information processing apparatus 5 Index finger 20 Operation signal reception means 21 Operation signal conversion means 22 Control signal output means 23 Display control means 30 Icon display screen 30a-30d Icon 31 Map display screen 31a Enlargement / reduction bar 32 menu screen A-E detection area _X A -X _D non-detection region

Claims (6)

A plurality of detection areas for detecting contact with the detection surface and outputting an operation signal;
An input device comprising: a non-detection area that is provided at an angle different from a detection surface of an adjacent detection area among the plurality of detection areas and that does not detect contact between the plurality of detection areas. One of the plurality of detection areas is provided in parallel to the installation surface of the input device,
The non-detection area is provided so as to rise from one of the plurality of detection areas to the installation surface,
The detection area adjacent to the non-detection area other than the one of the plurality of detection areas is provided on the opposite side to the one of the plurality of detection areas so as to be lowered with respect to the installation surface. The input device described in 1. One of the plurality of detection regions is arranged in the center,
The non-detection region is arranged around one of the plurality of detection regions,
The input device according to claim 2, wherein a detection area other than one of the plurality of detection areas is arranged outside the non-detection area.   The input device according to claim 1, wherein the detection area and the non-detection area are continuously connected to each other.   The input device according to claim 1, wherein one of the plurality of detection regions is subjected to a surface treatment different from that of the detection region other than the one of the plurality of detection regions.   One of the plurality of detection areas moves to the installation surface side, and a detection area other than the one of the plurality of detection areas moves to the opposite side of the installation surface, and one of the plurality of detection areas, The input device according to claim 1, wherein a distance from a detection region other than one of the plurality of detection regions is variable.

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