JP2011090404A - Coordinate input device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a coordinate input device for obtaining a square coordinate output by using an existing interface, and using the contact of inexpensive conductive rubber. <P>SOLUTION: The coordinate input device is configured such that a Y directional first counter electrode 121, a Y directional second counter electrode 122, an X directional first counter electrode 123, and an X directional second counter electrode 124 are respectively formed of an elastic body which electrically conducts the first electrode and the second electrode of the corresponding contacts of Y directional first contacts 11 and 12, Y directional second contacts 13 and 14, X directional first contacts 15 and 16 and X directional second contacts 17 and 18 when it is brought into contact with the first substrate 10, and whose area brought into contact with the first substrate 10 is variable, and dummy resistances are connected in parallel with each contact, and the second electrodes of each contact are connected to each other. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a coordinate input device used for a portable terminal or the like.

  Conventionally, as a coordinate input device in a portable terminal such as a telephone or various game machines, a so-called multi-directional key is provided in which a plurality of contacts are provided in the east, west, north, and south directions, and an input vector is detected by turning the contacts on and off. 1) is known. This method is easy to detect, but has a problem that the detection accuracy of the vector direction depends on the number of contacts, and the size is difficult to detect.

  Coordinate input devices (Patent Document 2 and Patent Document 3) that detect an input vector in an analog manner by combining a movable contact made of pressure-sensitive conductive rubber with a fixed contact instead of the on-off contact are known. In these methods, an expensive pressure-sensitive conductive rubber must be used, and after determining the conduction resistance of each contact, an input vector must be calculated from the coordinate data of the contact on the substrate.

  Also, a detection method (Patent Document 4) for measuring the resistance ratio of two pressure-sensitive resistance elements has been proposed. However, a dedicated detection circuit must also be prepared, and other on-states such as a keypad can be used. In addition to an off-type input device, a pressure-sensitive resistance element must be formed by screen printing, which takes time and effort to manage this load-resistance characteristic.

  In any of the methods, the coordinates obtained are in the same circular shape as the contact arrangement unless any correction is made. In particular, when there is only one contact point in the east, west, north, and south directions, the east, west, north, and south are the vertices. Since it is a rhombus, some correction was required to match the rectangular display screen.

  On the other hand, a touch panel that detects a position touched on a display screen by an LCD, a CRT, or the like is provided. As a touch panel, a resistive film type is often used, and interface devices for this resistive film type are in circulation.

JP 2005-115725 A Japanese Unexamined Patent Publication No. 6-309095 JP 2003-83819 A Japanese Patent No. 3275116

  The present invention can use an existing interface, uses an inexpensive conductive rubber contact, and easily outputs a rectangular coordinate similar to a display screen used for a portable device or the like depending on the configuration of the contact. An object is to provide a coordinate input device that can be obtained.

  In order to solve the above-described problem, according to one aspect of the present invention, an XY orthogonal coordinate system is set on a main surface, and a first Y-direction contact and a second Y-direction contact are disposed opposite to each other in the Y direction across the origin. A first contact in the X direction and a second contact in the X direction disposed opposite to each other in the X direction across the origin, and the first contact in the Y direction, the second contact in the Y direction, and the second contact in the X direction. Each contact of the one contact and the X-direction second contact has a first electrode and a second electrode, respectively, and the Y-direction first contact, the Y-direction second contact, the X-direction first contact, and the X-direction. A dummy resistor is connected in parallel to each contact of the direction second contact, and each second of the Y direction first contact, the Y direction second contact, the X direction first contact, and the X direction second contact. The electrodes are connected to each other on the first substrate connected to each other and the main surface facing the first substrate. And a Y-direction first counter electrode and a Y-direction second counter electrode arranged to face the Y-direction second contact, respectively, and a X-direction first contact and the X-direction second contact, respectively. An X-direction first counter electrode and an X-direction second counter electrode, the second substrate being displaceable relative to the first substrate, the Y-direction first counter electrode, and the Y-direction second counter When the electrode, the X-direction first counter electrode, and the X-direction second counter electrode are in contact with the first substrate, they are electrically connected to the first electrode and the second electrode, respectively, and are in contact with the first substrate. It consists of an elastic body with variable area.

  According to another aspect of the present invention, an X-Y orthogonal coordinate system is set on the main surface, and a Y-direction first contact and a Y-direction second contact disposed opposite to each other in the Y direction across the origin, and X across the origin An X-direction first contact and an X-direction second contact disposed to face each other, the Y-direction first contact, the Y-direction second contact, the X-direction first contact, and the X-direction second Each contact of the contact has a first electrode and a second electrode, respectively, and each of the first contact in the Y direction, the second contact in the Y direction, the first contact in the X direction, and the second contact in the X direction. , Dummy resistors are connected in parallel to form a Y-direction first contact unit, a Y-direction second contact unit, an X-direction first contact unit, and an X-direction second contact unit, and the Y-direction first contact unit and Y-direction contact unit is configured by connecting the Y-direction second contact units in series. The X-direction first contact unit and the X-direction second contact unit are connected in series to form an X-direction contact unit, and one end of the Y-direction contact unit is connected to a power source via the first switch means, The other end of the Y-direction contact unit is grounded via the second switch means, one end of the X-direction contact unit is connected to the power source via the third switch means, and the other end of the X-direction contact unit is the fourth. A first substrate grounded through a switch means, and a Y-direction first counter electrode disposed on a main surface facing the first substrate so as to oppose the Y-direction first contact and the Y-direction second contact, respectively. And the Y-direction second counter electrode, and the X-direction first counter electrode and the X-direction second counter electrode disposed to face the X-direction first contact and the X-direction second contact, respectively. Displaceable with respect to the substrate A second substrate, and the Y-direction first counter electrode, the Y-direction second counter electrode, the X-direction first counter electrode, and the X-direction second counter electrode are in contact with the first substrate, respectively. The first and second switch means are turned on, and the third and fourth switch means are made of an elastic body that electrically connects the first electrode and the second electrode and can change the area in contact with the first substrate. In the state where the switch is turned off, the potential of the common contact is measured via the X direction contact unit, the first and second switch means are turned off, and the third and fourth switch means are turned on. The potential of the common contact is measured via the Y direction contact unit.

  In yet another aspect of the present invention, an XY orthogonal coordinate system is set on the main surface, and a Y-direction first contact and a Y-direction second contact that are arranged opposite to each other in the Y direction with the origin interposed therebetween, An X-direction first contact and an X-direction second contact disposed opposite to each other in the X direction, the Y-direction first contact, the Y-direction second contact, the X-direction first contact, and the X-direction first contact Each of the two contacts has a first electrode and a second electrode, and each contact of the Y-direction first contact, the Y-direction second contact, the X-direction first contact, and the X-direction second contact. In addition, a dummy resistor is connected in parallel to form a Y-direction first contact unit, a Y-direction second contact unit, an X-direction first contact unit, and an X-direction second contact unit, and the Y-direction first contact unit And the Y direction second contact unit is connected in series, and the Y direction contact unit A first substrate configured to connect the X-direction first contact unit and the X-direction second contact unit in series to form an X-direction contact unit; and a main surface facing the first substrate on the Y-direction. A Y-direction first counter electrode and a Y-direction second counter electrode disposed to face the first contact and the Y-direction second contact, respectively, and the X-direction first contact and the X-direction second contact, respectively. An X-direction first counter electrode and an X-direction second counter electrode, the second substrate being displaceable with respect to the first substrate, the Y-direction first counter electrode, and the Y-direction When the second counter electrode, the X-direction first counter electrode, and the X-direction second counter electrode are in contact with the first substrate, they electrically conduct the first electrode and the second electrode, respectively, and the first substrate Made of an elastic body that can vary the area in contact with, While a current flows from the other direction the contact unit or the X-direction contact unit, measuring the potential difference between the end of the potential difference between the X-direction contact unit of the ends of the Y-direction contact unit.

  According to the present invention, an existing interface can be used, an inexpensive conductive rubber contact is used, and, depending on the configuration of the contact, rectangular coordinate output similar to that of a display screen used for a portable device or the like can be easily performed. Can get to.

It is a figure which shows an example of the contact arrangement of the coordinate input device of this Embodiment. It is a figure which shows the Y direction 1st contact. It is a figure which shows arrangement | positioning of the counter electrode provided in the 2nd board | substrate facing a 1st board | substrate. It is a figure which shows the 2nd other aspect of the counter electrode provided in the 2nd board | substrate facing a 1st board | substrate. It is a figure which shows the resistance characteristic with respect to the press load of conductive rubber. It is a figure which shows the relationship between a contact and a counter electrode. It is sectional drawing of the coordinate input device of this Embodiment. It is sectional drawing of the coordinate input device of another aspect. It is a figure which shows the detection circuit diagram of the coordinate input device of this Embodiment. It is a figure which shows the detection circuit diagram of the coordinate input device of 2nd Embodiment. It is a figure which shows arrangement | positioning of the contact arrange | positioned on the 1st board | substrate. It is a figure which shows the figure obtained when it traces so that a circle may be drawn, pressing a pressing member strongly. It is a figure which shows the figure obtained when it traces so that a circle may be drawn, pushing a pressing member weakly. It is a figure which shows arrangement | positioning of 3rd Embodiment. It is a figure which shows schematically the circuit structure of 3rd Embodiment. It is a figure which shows the figure obtained by 3rd Embodiment.

  Next, embodiments of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals. However, it should be noted that the drawings are schematic and the ratios of the constituent members are different from the actual ones. Therefore, specific dimensions should be determined in consideration of the following description. Moreover, it is a matter of course that portions having different dimensional relationships and ratios are included between the drawings.

  Further, the following embodiments exemplify apparatuses and methods for embodying the technical idea of the present invention, and the embodiments of the present invention include the material, shape, structure, The layout is not specified as follows. Various modifications can be made to the embodiment of the present invention within the scope of the claims.

[First Embodiment]
FIG. 1 is a diagram illustrating an example of contact arrangement of the coordinate input device according to the first embodiment.

  In the coordinate input device, an XY orthogonal coordinate system is set in the main surface of the flat insulating first substrate 10, and the Y-direction first contact groups 11 and 12 that face each other across the origin O in the Y direction and the Y direction. Second contact groups 13 and 14 are formed. Further, X-direction first contact groups 15 and 16 and X-direction second contact groups 17 and 18 that face each other across the origin O in the X direction are formed.

  In the first embodiment, the Y-direction first contact, the Y-direction second contact, the X-direction first contact, and the X-direction second contact are each configured as a contact group including two contacts. However, this invention is not limited to this, The case where each contact has one contact or 3 or more contacts may be included.

  The Y-direction first contact groups 11 and 12 are composed of a Y-direction first contact 11 and a Y-direction second contact 12 facing each other across the Y-axis, and the Y-direction second contact groups 13 and 14 sandwich the Y-axis. The Y-direction third contact 13 and the Y-direction fourth contact 14 are opposed to each other. The X-direction first contact groups 15 and 16 are composed of an X-direction first contact 15 and an X-direction second contact 16 facing each other with the X-axis interposed therebetween, and the X-direction second contact groups 17 and 18 sandwich the X-axis. The X-direction third contact 17 and the X-direction fourth contact 18 are opposed to each other.

  FIG. 2 is a diagram illustrating the Y-direction first contact 11.

  The Y-direction first contact 11 is formed in a comb-like shape, and includes a first electrode 11a and a second electrode 11b arranged so as to be fitted to each other. The other contacts 12 to 18 are also configured in the same shape. Such a comb-shaped electrode has good pressure-sensitive characteristics by accurately detecting the area of the counter electrode described later.

  Note that the contacts 11 to 18 of the present embodiment are not limited to the comb-teeth shape, and may be configured as other shapes such as electrodes extending in parallel.

  Returning to FIG. 1, the Y direction first contact 11 and the Y direction second contact 12 of the Y direction first contact group 11, 12 and the Y direction third contact 13 and the Y direction second contact of the Y direction second contact group 13, 14. The four contacts 14 form a quadrangular shape 1 such as a rectangle. These Y direction first contact groups 11 and 12 and Y direction second contact groups 13 and 14 constitute a Y direction press detecting means.

  Similarly, the X direction first contact 15 and the X direction second contact 16 of the X direction first contact group 15, 16, and the X direction third contact 17 and the X direction fourth contact of the X direction second contact group 17, 18. 18 also constitutes a square shape 2 such as a rectangle. These X direction first contact groups 15 and 16 and the X direction second contact groups 17 and 18 constitute an X direction press detecting means.

  The Y-direction first to fourth contacts 11 to 14 and the X-direction first to fourth contacts 15 to 18 are located on the circumference 3 equidistant from the origin O. The Y direction first to fourth contacts 11 to 14 and the X direction first to fourth contacts 15 to 18 are not limited to the circumference 3 but may be located on the elliptical circumference.

  FIG. 3 is a diagram showing the arrangement of the counter electrodes provided on the second substrate facing the first substrate.

  The second substrate 20 is disposed at a predetermined distance so as to be displaceable facing the first substrate 10. On the flat insulating main surface of the second substrate 20, a first facing opposite to the Y-direction first contact 11 and the Y-direction second contact 12 of the Y-direction first contact group 11, 12 of the first substrate 10. A Y-direction first counter electrode 121 having an electrode 21 and a second counter electrode 22 is provided, and a third counter facing the Y-direction third contact 13 and the Y-direction fourth contact 14 of the Y-direction second contact group 13, 14. A Y-direction second counter electrode 122 having an electrode 23 and a fourth counter electrode 24 is provided. Further, an X-direction first counter electrode 123 having a fifth counter electrode 25 and a sixth counter electrode 26 facing the X-direction first contact 15 and the X-direction second contact 16 of the X-direction first contact group 15, 16 is provided. The X-direction second counter electrode 124 having the seventh counter electrode 27 and the eighth counter electrode 28 facing the X-direction third contact 17 and the X-direction fourth contact 18 of the X-direction second contact group 17, 18 is provided. It has been.

  The first to eighth counter electrodes 21 to 28 constituting these counter electrodes 121 to 124 are molded into a substantially spherical shape by so-called conductive rubber in which carbon-based, silver-based, or other conductive particles are blended with, for example, silicon rubber. Has been. As the conductive rubber, in addition to what is called a pressure-sensitive conductive grade, an inexpensive conductive rubber used for a general on-off switch can be used.

  FIG. 4 is a diagram illustrating another aspect of the arrangement of the counter electrodes provided on the second substrate facing the first substrate.

  The present embodiment is not limited to the configuration shown in FIG. 3, and the Y-direction first counter electrode 121, the Y-direction second counter electrode 122, the X-direction first counter electrode 123, and the X-direction second counter electrode 124 are included. It can also be configured as a single electrode.

  In this embodiment, on the main surface of the second substrate 20, a Y-direction first counter electrode 121 facing the Y-direction first contact groups 11, 12 of the first substrate 10 is provided, and the Y-direction second contact group 13. , 14 is provided in the Y direction second counter electrode 122. Further, an X-direction first counter electrode 123 facing the X-direction first contact groups 15 and 16 is provided, and an X-direction second counter electrode 124 facing the X-direction second contact groups 17 and 18 is provided.

  FIG. 5 is a diagram showing resistance characteristics against the pressing load of the conductive rubber.

Curve a in the figure shows the characteristics of the pressure-sensitive conductive grade conductive rubber. Such conductive rubber, resistance decreases as the pressing load increases, asymptotically approaches a constant stable resistance R _ON. Curve b in the figure shows the characteristics of the conductive rubber used for the on-off switch. Such conductive rubber, a stable resistance R _ON of abruptly resistance when the pressing load increases are reduced.

  The rubber hardness is preferably 35 to 80 degrees as defined in JIS K6253 type A, and is set in the range of 40 degrees or more from the operational feeling, 75 degrees or less from the durability, and 45 to 70 degrees from the total balance. It is more preferable.

  FIG. 6 is a diagram illustrating the relationship between the contact and the counter electrode.

  The second substrate 20 is supported at a predetermined distance so as to be displaceable with respect to the first substrate 10. In the second substrate 20, the first counter electrode 21 of the Y-direction first counter electrode 121 is the first electrode 11 a of the Y-direction first contact 11 constituting the first contact groups 11, 12 formed on the first substrate 10. And it is formed to face the second electrode 11b.

  When the second substrate 20 is pressed, the first counter electrode 21 is pressed against the first contact 11 in the Y direction according to the pressing load, and conducts between the first electrode 11a and the second electrode 11b. The area where the first counter electrode 21 made of conductive rubber contacts the Y-direction first contact 11 increases according to the pressing force due to the elastic force of the rubber.

Therefore, the first electrode 11a and the second electrode 11b are electrically connected when the pressing force reaches a predetermined value, and thereafter, when the resistance value decreases according to the pressing force or when the stable resistance _RON reaches a predetermined value. Stay at that value.

  In addition, although the relationship with the 1st counter electrode 21 was shown about the Y direction 1st contact 11 among the Y direction 1st contact groups 11 and 12 here, the Y direction 2nd contact of the Y direction 1st contact groups 11 and 12 was shown. 12, the Y-direction second contact groups 13 and 14, the X-direction first contact groups 15 and 16, and the X-direction second contact groups 17 and 18 also have the same relationship as the corresponding counter electrodes 22 to 28.

  FIG. 7 is a cross-sectional view of the coordinate input device according to the present embodiment.

  This figure corresponds to a cross section obtained by cutting the first substrate 10 shown in FIG. 1 along a straight line II and the second substrate 20 shown in FIG. 3 along a straight line II-II.

  FIG. 7A is a cross-sectional view of the coordinate input device in a state where no pressing operation is performed. The second substrate 20 is supported at a predetermined distance from the first substrate 10 by a dome-shaped elastic support member 31 so that the second substrate 20 can be displaced with respect to the first substrate 10.

  The first substrate 10 includes a first electrode 11a and a second electrode 11b of the Y-direction first contact 11 of the Y-direction first contact groups 11 and 12, and a Y-direction fourth contact 14 of the Y-direction second contact groups 13 and 14. The first electrode 14a and the second electrode 14b are formed. On the second substrate 20, a counter electrode 21 is formed facing the first contact 11 in the Y direction, and a fourth counter electrode 22 is formed facing the fourth contact 14 in the Y direction.

  In the elastic support member 31, a pressing member 32 that can be operated with a finger or the like to apply a pressing force to the second substrate 20 is provided on the opposite surface on which the second substrate 20 is disposed.

  In such a state where the electrode is not pressed, the counter electrode is held away from the opposing first and second electrodes, or is in contact with the first and second electrodes with at least a slight pressing force. The first and second electrodes are insulated or have a sufficiently high resistance value.

  FIG. 7B is a cross-sectional view of the coordinate input device in a state where a pressing operation is performed.

  When a pressing force is applied to the pressing member 32 by the finger 100 or the like, the elastic support member 31 is elastically deformed and buckles as necessary to generate a click feeling.

Here, the first electrode 11a and the second electrode 11b of the Y-direction first contact 11 of the Y-direction first contact groups 11 and 12 are in contact with the first counter electrode 21, and between the first electrode 11a and the second electrode 12a. The resistance rapidly decreases as the pressing force increases, and eventually becomes a constant stable resistance _RON .

  7 illustrates the Y-direction first contact 11 of the Y-direction first contact groups 11 and 12 and the Y-direction fourth contact 14 of the Y-direction second contact groups 13 and 14, but this is not the case. The same applies to the contact groups.

  FIG. 8 is a cross-sectional view of a coordinate input device according to another aspect.

  In another aspect, a first central contact 19 (third contact) and a central counter electrode 29 are formed in the central portions of the first substrate 10 and the second substrate 20, respectively. The first central contact 19 includes a first electrode 19a and a second electrode 19b. The contact and the counter electrodes 19 and 29 provided in the central part can be provided for detecting the start of coordinate input operation.

  Note that the contact and the counter electrode for detecting such an input operation are not limited to the central portion of the first substrate 10 and the second substrate 20, but can be provided on the outer peripheral portion.

  FIG. 9 is a diagram illustrating a detection circuit diagram of the coordinate input device according to the present embodiment.

  This detection circuit includes a Y-direction coordinate detection unit 40 and an X-direction coordinate detection unit 50.

  In the Y-direction coordinate detection unit 40, the Y-direction first contact 41 (11) and the Y-direction second contact 42 (12) of the Y-direction first contact group 11, 12 and the first dummy resistor 45 are connected in parallel. A Y-direction first contact unit 201 is configured.

  Here, in this circuit diagram, the Y direction first contact 11 and the Y direction second contact 12 of the Y direction first contact groups 11 and 12 are shown by equivalent circuits 41 and 42 in which a switch and a variable resistor are connected in series, In order to clarify the correspondence, reference numerals 41 (11) and 42 (12) are used. The same applies to the following.

  In addition, the Y-direction third contact 43 (13) and the Y-direction fourth contact 44 (14) of the Y-direction second contact group 13, 14 are connected in parallel with the second dummy resistor 46, and the Y-direction second contact unit 202 is connected. Is configured.

  The Y-direction first contact unit 201 and the Y-direction second contact unit 202 are connected in series to form a Y-direction contact unit 205, and the connection point is a Y-direction common potential line 49. The Y-direction contact unit 205 constitutes the Y-direction coordinate detection unit 40 at the same time. One end 62 of the Y-direction contact unit 205 is connected to the power supply level via the second switch 48, and the other end 61 is connected to the ground level via the first switch 47.

  Here, the Y-direction first contact groups 11 and 12 and the Y-direction second contact group 13 are measured by measuring the potential of the Y-direction common potential line 49 with the first switch 47 and the second switch 48 turned on. , 14 can be detected. Alternatively, when any one of the contact groups is in the off state, the resistance ratio between the corresponding dummy resistors 45 and 46 and the contact group in the on state can be detected.

  In the X-direction coordinate detection unit 50, the X-direction first contact 51 (15) and the X-direction second contact 52 (16) of the X-direction first contact groups 15 and 16 and the third dummy resistor 55 are connected in parallel. The X direction first contact unit 203 is configured.

  The X direction third contact 53 (17) and the X direction fourth contact 54 (18) of the X direction second contact groups 17 and 18 are connected in parallel with the fourth dummy resistor 56, and the X direction second contact unit 204 is connected. Is configured.

  The first to fourth dummy resistors 45, 46, 55, and 56 may be provided on the first substrate 10 by means of soldering, resistance paste printing, or the like, or provided outside the first substrate. Also good.

  The X-direction first contact unit 203 and the X-direction second contact unit 204 are connected in series to form an X-direction contact unit 206, and the connection point is an X-direction common potential line 59. The X-direction contact unit 206 constitutes the X-direction coordinate detection unit 50 at the same time. One end 64 of the X-direction contact unit 206 is connected to the power supply level via the fourth switch 58, the other end is connected to the ground level via the third switch 57, and the other is connected to the X-direction common potential line 59. Yes.

  Here, the X-direction first contact groups 15 and 16 and the X-direction second contact group 17 are measured by measuring the potential of the X-direction common potential line 59 with the third switch 57 and the fourth switch 58 turned on. , 18 can be detected. Alternatively, when any one of the contact groups is in the off state, the resistance ratio between the corresponding dummy resistors 55 and 56 and the contact group in the on state can be detected.

The dummy resistor 45,46,55,56 is 1 to 30 times the value of the ballast resistor _{R ON.} This smaller and power consumption is increased, it becomes difficult to capture the transient change in resistance of up to stabilize the resistance R _ON from a large and an insulating state. Furthermore, in order to obtain a practical output range, it is more preferably 2 to 6 times. Usually, inexpensive on - the conductive rubber for off for _{R ON} is approximately 0.3～1Keiomega, set around the 1～3.3Keiomega.

  The Y-direction common potential line 49 of the Y-direction coordinate detection unit 40 and the X-direction common potential line 59 of the X-direction coordinate detection unit 50 are connected via a fifth switch 39. As described above, when the Y direction coordinate detection unit 40 and the X direction coordinate detection unit 50 detect the XY coordinates independently, the fifth switch 39 is turned off.

  By the fifth switch 39, the second contacts 11b and 12b of the Y-direction first contact groups 11 and 12, the second contacts 13b and 14b of the Y-direction second contact groups 13 and 14, and the X-direction first contact groups 15 and 16 are used. The second contacts 15b and 16b and the second contacts 17b and 18b of the X-direction second contact groups 17 and 18 are connected to each other via a Y-direction common potential line 49 and an X-direction common potential line 59.

  In the coordinate input device according to the present embodiment, the fifth switch 39 is turned on to connect the Y-direction common potential line 49 of the Y-direction coordinate detection unit 40 and the X-direction common potential line 59 of the X-direction coordinate detection unit 50. The existing resistive touch panel interface can be diverted.

  That is, the Y-direction coordinate detection unit 40 is, for example, a Y-side resistance film, the X-direction coordinate detection unit 50 is an X-side resistance film, and the first switch 47 and the second switch 48 connected to the Y-direction coordinate detection unit 40, the X direction By alternately turning on and off the combination of the third switch 57 and the fourth switch 58 to which the coordinate detection unit 50 is connected and switching the Y direction coordinate detection unit 40 and the X direction coordinate detection unit 50, a so-called constant voltage driving system is used. As with the resistive touch panel, input coordinates can be easily obtained.

  Specifically, by turning on the first switch 47 and the second switch 48 and turning off the third switch 57 and the fourth switch 58, the Y-direction coordinate detection unit 40 is turned on and the X-direction coordinate detection unit 50 is turned off. Thus, the Y-direction common potential line 49 and the X-direction common potential line 59 have potentials related to the coordinates in the Y direction. On the other hand, by turning off the first switch 47 and the second switch 48 and turning on the third switch 57 and the fourth switch 58, the Y-direction coordinate detection unit 40 is turned off and the X-direction coordinate detection unit 50 is turned on. In the Y-direction common potential line 49 and the X-direction common potential line 59, potentials relating to coordinates in the X direction are obtained. The potentials of the Y-direction common potential line 49 and the X-direction common potential line 59 can be input to the interface of the resistive touch panel.

  When diverting an existing resistive touch panel interface, in the measurement in the Y direction, the first switch 47 and the second switch 48 are turned on, the third switch 57 and the fourth switch 58 are turned off, and the Y direction coordinate detection unit 40 is turned on. The potential difference of the Y-side resistance film is measured at one end 61 or the other end 62 of the Y-side. In the measurement in the X direction, the first switch 47 and the second switch 48 are turned off, the third switch 57 and the fourth switch 58 are turned on. Measure the potential difference. For example, such measurement can be performed by supplying the output of one end 61 of the Y direction coordinate detection unit 40 and one end 63 of the X direction coordinate detection unit 50 to the A / D converter 67.

  The fifth switch 39 can be omitted if it is not necessary to detect the start of the input operation on the coordinate input device side. The fifth switch 39 can also be constituted by the first central contact 19 and the central counter electrode 29 shown in FIG.

[Second Embodiment]
FIG. 10 is a diagram illustrating a detection circuit diagram of the coordinate input device according to the second embodiment.

  In the second embodiment, the fifth switch 39 connecting the Y direction coordinate detection unit 40 and the X direction coordinate detection unit 50 is turned on, and one end 61 of the Y direction coordinate detection unit 40 is fixed via the first detection resistor 72. The current source 71 is connected, and the other end 62 is directly connected to the constant current source 71. Further, one end 63 of the X-direction coordinate detection unit 50 is connected to the ground level via the second detection resistor 73, and the other end 64 is directly connected to the ground level.

  Then, the potential difference between the one end 62 and the other end 61 of the Y-direction coordinate detection unit 40 is detected as the Y output by detecting the potential difference between both ends of the first detection resistor 72 by the first differential amplifier 74. Further, the potential difference between the one end 64 and the other end 63 of the X direction coordinate detection unit 50 is detected as the X difference by detecting the potential difference between both ends of the second detection resistor 73 by the second differential amplifier 75.

  In other words, a current is passed through the fifth switch 39 from the Y-direction contact unit 205 corresponding to the Y-direction coordinate detection unit 40 to the X-direction contact unit 206 corresponding to the X-direction coordinate detection unit 50. Then, the potential difference between the end portions 61 and 62 of the Y-direction contact unit 205 is detected as a Y output, and the potential difference between the end portions 63 and 64 of the X-direction contact unit 206 is detected as an X output.

  The direction in which the current flows is not limited to the Y-direction contact unit 205 to the X-direction contact unit 206, and conversely may be the X-direction contact unit 206 to the Y-direction contact unit 205.

  According to another embodiment, there is no need to switch the Y-direction coordinate detection unit 40 and the X-direction coordinate detection unit 50. Therefore, since there is little noise associated with switching and the operating frequency is low, when the current / voltage characteristics of the contact are non-linear, such as inexpensive conductive rubber used for general on-off switches as conductive rubber However, stable input coordinates can be obtained.

  Such other embodiments have the same configuration as that obtained by diverting an existing interface for a resistive touch panel. The interface in this case corresponds to, for example, a constant current power source, first and second detection resistors 72 and 73, and first and second differential amplifiers 74 and 75.

  Next, the operation of the coordinate input device according to the present embodiment will be described.

  When the input operation is not performed, the Y-direction first contact groups 11 and 12, the Y-direction second contact groups 13 and 14, the X-direction first contact groups 15 and 16 and the X-direction second contact on the first substrate 10. Groups 17 and 18 are all off.

When the pressing member 32 shown in FIG. 7 is pressed to apply a pressing force to the portion corresponding to the Y-direction first contact groups 11 and 12 in the negative region of the Y axis in FIG. 1, the second substrate 20 is displaced. The Y-direction first counter electrode 121 shown in FIG. 3 contacts the Y-direction first contact groups 11 and 12. As a result, the first electrode and the second electrode of the Y-direction first contact groups 11 and 12 are electrically connected to each other, and the area where the Y-direction first counter electrode 121 contacts the Y-direction first contact groups 11 and 12 according to the pressing force. As the voltage increases, the resistance decreases and eventually becomes a constant stable resistance _RON .

  In this state, when the pressing position is moved in the clockwise direction with respect to the origin O, the resistance of the Y-direction second contact 12 of the Y-direction first contact groups 11 and 12 rises, and eventually becomes an off state, and the Y-direction second contact group. The fourth contact 14 in the Y direction 13 and 14 contacts the second counter electrode 122 in the Y direction and the resistance decreases. When the pressing position is further moved in the clockwise direction, the Y-direction first contact 11 of the Y-direction first contact groups 11 and 12 is eventually turned off, and the Y-direction third contact 13 of the Y-direction second contact groups 13 and 14 is turned off. The Y-direction third contact 13 and the Y-direction fourth contact 14 of the Y-direction second contact group 13, 14 are simultaneously turned on in contact with the direction second counter electrode 122.

  In addition, although operation | movement about the Y direction 1st contact groups 11 and 12 and the Y direction 2nd contact groups 13 and 14 was demonstrated here, X direction 2nd contact groups 15 and 16 and X direction 2nd contact groups 17 and 18 were demonstrated. The operation of is the same.

The plot of the output voltage of the coordinate input device in the XY plane, the resistance of each contact 11 to 18 presses the annular pressing member 32 with a large force such that R _ON, circle around the origin O in FIG. 1 When an operation such as tracing was performed, a substantially rectangular figure was drawn. On the other hand, the resistance of each contact 11 to 18 when performing an operation of tracing the pressing member 32 in the same manner with a small force that does not lead to the R _ON, the voltage is substantially circular figure is drawn.

As shown in FIG. 11, comb-shaped contacts 11 to 18 having a diameter of 3 mm are arranged in a regular octagon on a circumference of 10 mm in the first substrate 10. On the second substrate 20 facing the first substrate 10, a counter electrode having a curvature of 2.4 mm was formed of conductive silicon rubber 87C40P (manufactured by Shin-Etsu Polymer: rubber hardness 45 degrees). The annular pressing member 32 (see FIG. 7) was made of acrylic having a thickness of 0.9 mm. Ballast resistance _{R ON} of the contacts 11 to 18 was 600Ω when load 500 gf.

  The detection circuit shown in FIG. 9 is used, 3.3 kΩ is used as the first to fourth dummy resistors 45, 46, 55, 56, the fifth switch 39 is turned on, and the Y-direction coordinate detection unit 40 is common in the Y direction. The potential line 49 and the X-direction common potential line 59 of the X-direction coordinate detection unit 50 are connected.

  The circuit configuration shown in FIG. 10 was applied, the first detection resistor 72 and the second detection resistor 73 were each set to 20Ω, and the 1 mA constant current source 71 was used. A potential difference between both ends of the first detection resistor 72 and the second detection resistor 73 is detected by a first differential amplifier 74 and a second differential amplifier 75 having an internal resistance of 1 kΩ and a differential gain of 200 times, and Y output and X output, respectively. It was.

  While pressing the surface of the annular pressing member 32 with a thumb strongly, a circle was drawn, and the output of the interface was displayed on the XY plane. As a result, a substantially rectangular figure as shown in FIG. 12 was observed.

  On the other hand, while gently pressing the surface of the annular pressing member 32 with a little finger, a circle was drawn and the output of the interface was displayed on the XY plane. As a result, a substantially circumferential figure as shown in FIG. 13 was observed.

[Third Embodiment]
Next, the comb-shaped contacts were arranged in a regular square in the east, west, south, and north directions, and the other components were input in the same manner as the coordinate input device.

  FIG. 14 is a diagram illustrating an arrangement according to the third embodiment.

  In the first substrate 10, the Y-direction first contact 210 and the Y-direction second contact 212 are arranged so as to face each other with the origin in the Y direction with respect to the XY rectangular coordinate system set on the main surface, and the origin in the X direction. The X direction first contact 211 and the X direction second contact 213 are formed so as to face each other.

  FIG. 15 is a diagram schematically showing a circuit configuration of the third embodiment.

  The other end connected to the ground level through the switch of the Y-direction contact unit 221 including the Y-direction first contact 210 and the Y-direction second contact 212, and the X-direction first contact 211 and the X-direction second contact 213 are included. A potential difference from one end connected to the power supply level via the X-direction contact unit 222 is detected via the multiplexer 220. Here, each switch for connecting the Y-direction contact unit 221 and the X-direction contact unit 222 to the power supply line and the ground level and the multiplexer 220 correspond to an interface of a resistive touch panel. Actually, switching was performed using a three-state gate (74HC125) of a C-MOS IC as a switch.

  While pressing the surface of the annular pressing member 32 with a thumb strongly, a circle was drawn, and the output of the interface was displayed on the XY plane. As a result, a rhombus-shaped figure different in the direction of each side from the XY direction as shown in FIG. 16 was drawn. Further, it was observed that the waveform was disturbed when switching the contacts in the XY directions, but coordinate data could be obtained.

[Other embodiments]
As described above, the present invention has been described according to the embodiment. However, it should be understood that the descriptions and drawings constituting a part of this disclosure are illustrative and do not limit the present invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art.

  As described above, the present invention includes various embodiments not described herein.

  The present invention can be used for coordinate input in various electronic devices such as portable terminals.

DESCRIPTION OF SYMBOLS 10 1st board | substrate 11,12 Y direction 1st contact group 13,14 Y direction 2nd contact group 15.16 X direction 1st contact group 17,18 X direction 2nd contact group 20 2nd board | substrates 21-28 1st-1st Eighth counter electrode 121 Y direction first counter electrode 122 Y direction second counter electrode 123 X direction first counter electrode 124 X direction second counter electrode

Claims (8)

An XY Cartesian coordinate system is set on the main surface, and the Y-direction first contact and the Y-direction second contact arranged opposite to each other in the Y direction across the origin, and arranged in the X direction across the origin. X-direction first contact and X-direction second contact, each of the Y-direction first contact, the Y-direction second contact, the X-direction first contact and the X-direction second contact, A first electrode and a second electrode, each of the first contact in the Y direction, the second contact in the Y direction, the first contact in the X direction, and the second contact in the X direction has a dummy resistor in parallel; A first substrate connected to each other, wherein the second electrodes of the Y-direction first contact, the Y-direction second contact, the X-direction first contact, and the X-direction second contact are connected to each other;
A Y-direction first counter electrode and a Y-direction second counter electrode disposed on the main surface facing the first substrate so as to face the Y-direction first contact and the Y-direction second contact, respectively, and the X-direction A second substrate having an X-direction first counter electrode and an X-direction second counter electrode disposed to face the first contact and the X-direction second contact, respectively, and being displaceable with respect to the first substrate. Have
When the Y-direction first counter electrode, the Y-direction second counter electrode, the X-direction first counter electrode, and the X-direction second counter electrode are in contact with the first substrate, the first electrode and the second electrode respectively A coordinate input device comprising an elastic body that is electrically conductive and has a variable area in contact with the first substrate. An XY Cartesian coordinate system is set on the main surface, and a Y-direction first contact and a Y-direction second contact arranged opposite to each other in the Y direction across the origin, and arranged opposite to the X direction across the origin. X-direction first contact and X-direction second contact, each of the Y-direction first contact, the Y-direction second contact, the X-direction first contact and the X-direction second contact, A dummy resistor is connected in parallel to each contact of the first contact in the Y direction, the second contact in the Y direction, the first contact in the X direction, and the second contact in the X direction. A Y-direction first contact unit, a Y-direction second contact unit, an X-direction first contact unit, and an X-direction second contact unit, and the Y-direction first contact unit and the Y-direction second contact unit Connected in series to form a Y-direction contact unit, and the X-direction first contact An X direction contact unit is configured by connecting a unit and the X direction second contact unit in series, and one end of the Y direction contact unit is connected to a power source via a first switch means. One end of the X-direction contact unit is connected to a power source via third switch means, and the other end of the X-direction contact unit is grounded via fourth switch means. A first substrate;
A Y-direction first counter electrode and a Y-direction second counter electrode disposed on the main surface facing the first substrate so as to face the Y-direction first contact and the Y-direction second contact, respectively, and the X-direction A second substrate having an X-direction first counter electrode and an X-direction second counter electrode disposed to face the first contact and the X-direction second contact, respectively, and being displaceable with respect to the first substrate. Have
When the Y-direction first counter electrode, the Y-direction second counter electrode, the X-direction first counter electrode, and the X-direction second counter electrode are in contact with the first substrate, the first electrode and the second electrode respectively It is made of an elastic body that is electrically conductive and can vary the area that contacts the first substrate,
With the first and second switch means turned on and the third and fourth switch means turned off, the potential of the common contact is measured via the X-direction contact unit, and the first and second switch means The coordinate input device is characterized in that the potential of the common contact is measured via the Y-direction contact unit in a state in which the third and fourth switch means are turned on. An XY Cartesian coordinate system is set on the main surface, and a Y-direction first contact and a Y-direction second contact arranged opposite to each other in the Y direction across the origin, and arranged opposite to the X direction across the origin. X-direction first contact and X-direction second contact, each of the Y-direction first contact, the Y-direction second contact, the X-direction first contact and the X-direction second contact, A dummy resistor is connected in parallel to each contact of the first contact in the Y direction, the second contact in the Y direction, the first contact in the X direction, and the second contact in the X direction. A Y-direction first contact unit, a Y-direction second contact unit, an X-direction first contact unit, and an X-direction second contact unit, and the Y-direction first contact unit and the Y-direction second contact unit Connected in series to form a Y-direction contact unit, and the X-direction first contact A first substrate to constitute a X-direction contact unit of unit and the X-direction second contact unit are connected in series,
A Y-direction first counter electrode and a Y-direction second counter electrode disposed on the main surface facing the first substrate so as to face the Y-direction first contact and the Y-direction second contact, respectively, and the X-direction A second substrate having an X-direction first counter electrode and an X-direction second counter electrode disposed to face the first contact and the X-direction second contact, respectively, and being displaceable with respect to the first substrate. Have
When the first counter electrode in the Y direction, the second counter electrode in the Y direction, the first counter electrode in the X direction, and the second counter electrode in the X direction contact the first substrate, the first electrode and the second electrode respectively. It is made of an elastic body that is electrically conductive and can vary the area that contacts the first substrate,
Coordinates that flow current from one of the Y-direction contact unit or the X-direction contact unit to the other and measure the potential difference at the end of the Y-direction contact unit and the potential difference at the end of the X-direction contact unit. Input device.   The Y-direction first contact, the Y-direction second contact, the X-direction first contact, and the X-direction second contact each have one or a plurality of contacts. The coordinate input device described in 1.   5. The Y-direction first counter electrode, the Y-direction second counter electrode, the X-direction first counter electrode, and the X-direction second counter electrode are made of conductive rubber. The coordinate input device described in 1.   The coordinate input device according to claim 1, further comprising an elastic support member that displaceably supports the second substrate with respect to the first substrate.   The coordinate input device according to claim 1, wherein the first electrode and the second electrode have a comb shape.   The Y-direction first counter electrode and the Y-direction second counter electrode each have two counter electrodes facing each other across the Y axis, and the X-direction first counter electrode and the X-direction second counter electrode are The coordinate input device according to claim 1, further comprising two counter electrodes facing each other across the X axis.