JP4020246B2 - Touchpad device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a pointing device used as a man-machine interface of devices such as a personal computer, a PDA, a mobile phone, a game device, and a car navigation device, and more particularly to a touch pad that performs coordinate operations on the screen of these devices.
[0002]
[Prior art]
Pointing devices such as a trackball, a touch pad, and a pointing stick are used as devices for performing coordinate operations on screens displayed on the display devices of various devices as described above. Among the so-called pointing devices, in recent years, many of the familiar notebook-type personal computers are equipped with capacitive and pressure-sensitive touchpads that are particularly excellent in terms of space saving and operability. In the future, it is expected to be installed in PDAs, mobile phones, car navigation devices, etc., which are strongly requested to save space.
[0003]
By the way, with such a touchpad, if the operation surface of the touchpad is stroked with a finger, an operation index such as a pointer or cursor on the screen can be moved to perform coordinate operations. While it has been highly evaluated as an excellent man-machine interface, some have pointed out problems such as complicated operation and easy fatigue.
[0004]
More specifically, this problem often occurs when the pointer cannot be moved to a target designated position only by performing a coordinate operation of stroking the touch pad once with a finger, for example. That is, in such a case, it is necessary to repeatedly perform the coordinate operation for stroking the pointer so that the pointer reaches the target designated position, and the direction of movement of the pointer is always set to a constant direction for each stroking coordinate operation. It is difficult to correct the direction each time. As a result, the coordinate operation becomes complicated, and the operator feels tired. Furthermore, the problem of this complication is not only when operating an operation index such as a pointer with a touchpad, but also when scrolling a web page of a frame size that cannot be displayed on the screen of the display device on the screen vertically and horizontally. This is also the case when performing coordinate operations on the screen, and there is a high demand for improvement.
[0005]
[Problems to be solved by the invention]
The present invention has been made against the background of such prior art. An object of the present invention is to provide a touch pad device that can easily perform an accurate coordinate operation.
[0006]
In order to achieve this object, the present invention sets an operation origin in a coordinate operation unit for a touch pad device that performs coordinate operations on a screen according to operation point coordinates detected by a coordinate operation unit forming an XY coordinate system. A direction angle centered on the operation origin is set to the operation point coordinates that can be detected by the coordinate operation unit, and when one operation point coordinate is detected, the direction angle set to the one operation point coordinate The touch pad device is characterized in that the coordinate operation of the screen is performed until the continuous detection of the one operation point coordinate is released.
[0007]
An operation origin is set in the coordinate operation unit, and a direction angle centered on the operation origin is set in an operation point coordinate that can be detected by the coordinate operation unit, and when one operation point coordinate is detected, The coordinate operation on the screen is performed along the direction angle set to one operation point coordinate until the continuous detection of the one operation point coordinate is canceled. It is possible to easily and accurately perform screen coordinate operations such as operation indicators such as a pointer and a cursor, screen scrolling, and the like along the direction angle. That is, the operator performs an operation for detecting the operation point coordinates, that is, by a stationary coordinate operation such as continuously touching a specific part of the coordinate operation unit with a finger or continuously applying an operation pressing force with a finger to the specific part. , So you can perform accurate and easy coordinate operations.
[0008]
The touch pad device sets the speed to the operation point coordinates in which the direction angle is set, and when one operation point coordinate is detected, the one operation is performed according to the speed set to the one operation point coordinate. The screen coordinate operation can be performed until the continuous detection of the point coordinates is canceled.
[0009]
When the speed is set to the operation point coordinates for which the direction angle is set and one operation point coordinate is detected, the speed of the one operation point coordinate is continuously changed according to the speed set to the one operation point coordinate. Since the coordinate operation on the screen is performed until the detection is canceled, not only the accurate and easy coordinate operation as described above can be performed, but also the movement speed of the operation index such as the pointer or the cursor even if the direction angle is the same. It is possible to variably operate the scroll speed such as screen scrolling and the like, and the operation efficiency can be improved.
[0010]
The touch pad device may be configured to include an operation point coordinate selection unit that detects one of the operation point coordinates when a plurality of operation point coordinates are detected.
[0011]
Even if a plurality of operation point coordinates are detected by the operator's power, or by different finger thicknesses for each operator, one of the operation point coordinates is selected by the operation point coordinate selection means. The accuracy can be further improved. Such operation point coordinate selection means can be realized by a microcomputer or the like that coordinates the coordinate operation processing by executing a predetermined computer program.
[0012]
The touch pad device can be configured to include switch means that can perform an input operation on a selected element displayed on the screen.
[0013]
Since the switch means for performing an input on the selection element displayed on the screen is provided, an input operation on the selection element can also be performed.
[0014]
The touch pad device can be configured as a switch means that can be operated by applying an operation pressing force to the coordinate operation unit at a position below the coordinate operation unit.
[0015]
Since the switch means capable of input operation by applying an operation pressing force to the coordinate operation section is provided below the coordinate operation section, the input operation by the switch means can be performed without releasing the finger from the coordinate operation in the coordinate operation section. It becomes possible, and higher operability of the device can be realized by the cooperative operation of the coordinate operation and the input operation.
[0016]
In the touch pad device, the coordinate operation unit can be formed as a dome-shaped coordinate operation unit.
[0017]
Since the coordinate operation unit is a dome-shaped coordinate operation unit, the vertex can be easily tactilely sensed compared to the case where it has a planar shape like the conventional touchpad described above. Random multi-directional operation can be performed intuitively and accurately. In addition, in the curved inclined portion other than the apex serving as the operation origin, it is possible to feel tactilely from the finger operating the position information such as the inclination direction and the inclination. Therefore, further accurate operability can be realized. And in order to obtain such an accurate operability, it is not necessary to use a device structure with a large apparatus thickness such as a trackball having the same operation method. Can be satisfied. Such advantages are particularly advantageous as a pointing device mounted on a portable device such as a notebook type personal computer, a mobile phone, a PDA, or the like, which is particularly required to reduce the size of the entire device.
[0018]
The touch pad device having the coordinate operation unit as a dome-shaped coordinate operation unit is most preferable when the entire surface of the coordinate operation unit is a dome-shaped coordinate operation unit, but the coordinate operation unit is partially used as a dome-shaped coordinate operation unit. It may be configured.
[0019]
In addition, the dome-shaped coordinate operation unit is preferably bulged upward with respect to the flat general surface of the operation substrate and the base substrate, in other words, it is preferably convex toward the operator. You may comprise as what was dented below with respect to the surface.
[0020]
The touch pad device includes a coordinate operation unit, a flexible operation substrate on which a predetermined electrode pattern is formed, and a base substrate, with the electrode patterns facing each other in an insulated state. A contact portion that conducts when a pressing operation is applied to the substrate can be configured with a membrane sheet that outputs as operation point coordinates.
[0021]
Since the coordinate operation unit is formed of a membrane sheet, the coordinate operation unit can be configured to be very thin, and is particularly advantageous for the device that is strongly demanded to reduce the size of the device.
[0022]
The touch pad device may be configured such that a resin spacer whose upper surface portion corresponds to the surface shape of the back surface is provided between the back surface of the base substrate and the switch means.
[0023]
Since a resin spacer whose upper surface portion corresponds to the surface shape of the back surface is provided between the back surface of the base substrate and the switch means, the shape retention of the base substrate that receives the operation pressing force can be improved. The operation pressing force can also be reliably transmitted through the resin spacer. In addition, the resin spacer itself is displaced in the pressing direction at the time of an input operation that applies a larger operation pressing force than at the time of coordinate operation. Therefore, the operator feels that the resin spacer is displaced as a tactile feeling of input operation. And the operability can be further improved.
[0024]
The touch pad device including the resin spacer can be configured as a resin spacer and a base substrate that are integrated with each other by bonding.
[0025]
Since the resin spacer and the base substrate are integrated by bonding, the shape retention of the base substrate is further improved. In addition, since there is no play between the resin spacer that transmits the operation pressing force to the switch means and the base substrate, the operation pressing force applied to the base substrate can be directly transmitted to the resin spacer, and the input operation can be performed. Operability can be improved. Furthermore, since the touchpad device of the present invention can be assembled using the base substrate integrated with the resin spacer as one module, the assembly workability can be improved.
[0026]
In the touch pad device including the resin spacer, the resin spacer is inserted into the annular outer peripheral portion having a guide hole in a portion corresponding to the central portion of the coordinate operation unit, and the guide hole is movable up and down to the switch means. It can be formed as a divided body having a central operating portion that transmits the operating pressing force, and a switch means is provided below the central operating portion.
[0027]
A division having an annular outer peripheral portion having a guide hole in a portion corresponding to the central portion of the coordinate operation portion, and a central operation portion that is inserted in the guide hole so as to be vertically movable and transmits an operation pressing force to the switch means. Since it is formed as a body and the switch means is provided below the central operating part, the operation pressing force can be reliably transmitted to the switch means by the central operating part.
[0028]
In the touch pad device in which the resin spacer is a divided body composed of an annular outer peripheral portion and a central operating portion, it can be configured as another switch means provided below the annular outer peripheral portion.
[0029]
Since another switch means is provided below the annular outer peripheral portion, further multi-functionality of the input operation can be realized by the switch means corresponding to the central operating portion and the switch means corresponding to the annular outer peripheral portion. In this case, a plurality of other switch means may be provided along the annular outer periphery.
[0030]
In the touch pad device in which the resin spacer is formed as a divided body including an annular outer peripheral portion and a central operating portion, the annular outer peripheral portion can be further formed as a divided body including a plurality of parts along the circumferential direction.
[0031]
Since the annular outer peripheral portion is formed as a divided body composed of a plurality of parts along the circumferential direction, for example, a switch means is provided below each divided body, and when an operation pressing force is applied to one divided body, they are adjacent to each other. It is possible to reliably prevent erroneous input of other switch means.
[0032]
In the touch pad device in which the coordinate operation area is configured as a dome-shaped coordinate operation unit, it is preferable that the resin spacer is formed in a shape corresponding to the cavity on the back surface of the dome-shaped coordinate operation unit on the base substrate.
[0033]
Since the resin spacer has a shape corresponding to the cavity on the back surface of the dome-shaped coordinate operation unit in the base substrate, the shape retention of the base substrate is improved and the operation pressing force applied to the dome-shaped coordinate operation unit is limited. Therefore, the operation pressing force can be reliably transmitted to the switch means, and the operability of the input operation can be improved.
[0034]
The touchpad device is preferably a switch member that generates a click feeling when the switch means is pressed.
[0035]
Since the switch means is a switch member that generates a click feeling by pressing, the operator can be surely sensed that the input operation has been performed by the occurrence of the click feeling, and the operability can be improved.
[0036]
As such a switch member, a disc spring-like contact member or a tact switch can be used. For an electrical device that preferably does not have a click feeling in the input operation, for example, a membrane switch can be used as a switch means.
[0037]
The touch pad device may be configured to include invalid control means for invalidating the coordinate operation when a large number of operation point coordinates are detected at a position vertically above the switch means by a pressing operation.
[0038]
In this way, the coordinate operation is invalidated by the invalid control means, so that when the switch means is pressed, the input operation is reliably performed while the operation index such as a pointer or a cursor positioned at a predetermined position is stopped. Yes. Such invalid control means can be realized by a microcomputer or the like that coordinates the coordinate operation process by executing a predetermined computer program.
[0039]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. In addition, the description which overlaps in each embodiment is abbreviate | omitted unless it mentions especially.
[0040]
First Embodiment [FIGS. 1 to 7]
[0041]
The touch pad device 1 of the present embodiment is configured to include a switch member 3 as a switch means below the coordinate operation unit 2.
[0042]
The coordinate operation unit 2 has a basic structure in which a flexible operation substrate 4 and a base substrate 5 are laminated. The operation board 4 is formed with a dome-shaped coordinate operation portion 4a that bulges upward. In this embodiment, this portion is used as a coordinate operation region R. The base substrate 5 is formed with a dome-shaped coordinate operation unit 5a having a substantially similar shape with a slightly smaller radius of curvature than that of the dome-shaped coordinate operation unit 4a. . These dome-shaped coordinate operation units 4a and 5a are separated from each other by a gap d1 and are electrically insulated from each other. The gap d1 is preferably in the range of 0.05 mm to 1 mm in terms of operability and input sensitivity, and more preferably in the range of 0.1 mm to 0.5 mm.
[0043]
The operation substrate 4 and the base substrate 5 can be formed using a thin, light and flexible material such as a resin film. Specifically, polyethylene terephthalate resin, polyethylene naphthalate resin, polycarbonate resin, polyamide resin, polypropylene resin, polystyrene resin, polyurethane resin, polyvinyl resin, fluororesin, polyacetate resin, polyimide resin, acrylic resin, thermoplastic elastomer, etc. The resin film which formed the resin material like this thinly can be utilized. The operation substrate 4 and the base substrate 5 are joined to each other at the outer portions of the dome-shaped coordinate operation units 4a and 5a by heat fusion, ultrasonic fusion, welding, adhesion with an adhesive, adhesion with a double-sided tape, or the like. Therefore, it is an integral structure.
[0044]
Resin spacers 5 c are provided in the hollow portions 5 b formed on the back surface of the dome-shaped coordinate operation portion 5 a of the base substrate 5. The resin spacer 5c is joined to the base substrate 5 to be an integrated object. Therefore, the upper surface of the resin spacer 5c and the back surface of the dome-shaped coordinate operation unit 5a are in close contact with each other, and there is no play between them.
[0045]
The resin spacer 5c needs to hold the shape of the base substrate 5 and the shape of the operation substrate 4 integrally formed with the base substrate 5 and be able to reliably press the switch member 3. Therefore, as a specific example of the material, a thermoplastic resin, a thermosetting resin, a synthetic rubber, or a thermoplastic elastomer can be used. In addition, about synthetic rubber and a thermoplastic elastomer, in order to transmit operation pressing force to the switch member 3 reliably, a thing with comparatively high hardness is preferable. And as a joining method with the base substrate 5, in addition to integral molding in the mold such as two-color molding and insert molding of the resin spacer 5c and the base substrate 5, thermal fusion, ultrasonic fusion, welding, adhesive, etc. They are joined to each other by adhesion using a double-sided tape, adhesive using a double-sided tape, and the like, so that an integrated structure is obtained. Of these, in-mold integrated molding that does not require a joining step is particularly preferred.
[0046]
The operation substrate 4 and the base substrate 5 are formed with a lattice-like matrix pattern coordinate detection unit. That is, as shown in FIG. 3A, a vertical stripe electrode pattern 4c is formed on the back surface 4b of the operation substrate 4, and a horizontal stripe electrode pattern 5e is formed on the surface 5d of the base substrate 5. Yes. When the operation substrate 4 and the base substrate 5 are joined as described above, the coordinate detection region R of the matrix pattern is formed in the coordinate operation region R in an insulated state via the gap d1 as shown in FIG. Is done. For each operation point coordinate that can be detected by such a matrix pattern, that is, each intersection coordinate of the electrode patterns 4c and 5e, a direction angle centered on the operation origin Pc and a predetermined speed are set. Therefore, when a coordinate operation such as a pointer is performed with the touch pad device 1, the coordinate operation (movement) of the pointer is performed according to the direction angle and speed (movement speed) set to the detected operation point coordinates. become.
[0047]
It should be noted that outside the coordinate operation region R, the electrode patterns 4c and 5e are not electrically connected to each other. When bonding is performed using an adhesive, the adhesive is used. When using a double-sided tape, a double-sided tape is used. In the case of joining, the coordinate operation region R is insulated by the insulating coating. The electrode patterns 4c and 5e can be formed by etching metal foil or applying conductive ink. In FIG. 3, the conductive lines constituting the electrode patterns 4c and 5e are illustrated as being connected to each other. However, in order to perform coordinate operations, it is necessary to be able to specify the coordinates of the pressed location. Therefore, in practice, the individual conductive wires are connected in an insulated state to a control system (not shown) via a terminal portion (not shown).
[0048]
In this embodiment, the switch member 3 is made of a metal disc spring contact member such as an inverted saddle-shaped stainless steel plate. The switch member 3 is surface-mounted on a substrate 6a built in a housing 6 of a device on which the touch pad device 1 is mounted. Therefore, when an input operation pressing force is applied to the switch member 3, the switch member 3 is deformed with a click feeling and comes into contact with a contact portion 6b formed in a circuit of the substrate 6a below the switch member 3. In this way, an input operation by the switch member 3 can be performed separately from the coordinate operation by the coordinate operation unit 2.
[0049]
The input load of the switch member 3 formed of the metal disc spring setting member is about 3N, which is larger than the conduction load of the electrode patterns 4c and 5e in the coordinate operation unit 2 which is about 0.2N. Therefore, erroneous input of the switch member 3 can be prevented by the coordinate operation pressing force applied to the coordinate operation unit 2.
[0050]
The switch member 3 of the present embodiment is made up of a metal disc spring contact member. However, the switch member 3 is a disc spring contact member made of a reverse-shaped hard resin film provided with a conductive contact on the surface facing the contact portion 6b. You may comprise with a switch. A click feeling can be obtained also by these. Further, when it is not necessary to have a click feeling, a membrane switch or the like may be used as the switch member 3.
[0051]
Next, the functional block diagram of this embodiment is shown in FIG.
[0052]
The coordinate operation unit 2 of the touch pad device 1 is connected to an operation point coordinate selection unit 7, an invalid control unit 8, a speed setting unit 9, and an operation mode switching unit 10. These means 7 to 10 can be realized by the microcomputer 11, for example.
[0053]
As shown in FIG. 5A, there are a plurality of electrode patterns 4c and 5e in the coordinate operation region R of the lattice matrix pattern, depending on the magnitude of the operating pressing force, the thickness of the finger to which the operating pressing force is applied, and the like. When the contact is made (when the black circle in the figure is the contact point), that is, when multiple points are contacted, it is unclear which operation point coordinate is used to perform the coordinate operation. The operation point coordinate selection means 7 of this embodiment specifies one operation point coordinate when such a large number of operation point coordinates are detected. Specifically, for example, the number of contacted conductive lines is counted for each of the electrode pattern 4c and the electrode pattern 5e, and by specifying the center line, P1 in FIG. 5A is selected as the operation point coordinates.
[0054]
The invalidation control means 8 of the present embodiment invalidates the coordinate operation when it is estimated that an input operation by the switch member 3 is performed. Otherwise, for example, if the coordinate operation is effective when an attempt is made to select the selected element displayed on the screen with the pointer by the coordinate operation and the user wants to select the selected element by the input operation, the operation push by the input operation is effective. The pointing position of the pointer may be shifted due to the pressure, which is likely to cause an erroneous operation. In order to prevent such inconvenience, as shown in FIG. 5 (b), when the electrode patterns 4c and 5e are in multipoint contact with each other at a position vertically above the switch member 3 (in the illustrated example, five contact points indicated by black circles are formed). If it is determined that the input operation by the switch member 3 is performed, the invalidation control means 8 executes control for invalidating the coordinate operation.
[0055]
As described above, the intersection coordinates of the electrode patterns 4c and 5e, that is, the operation point coordinates, are set with respect to the moving speed of the pointer, the cursor, etc. and the scrolling speed of the screen with the operation origin Pc as the center. The speed setting means 9 is for changing the speed set for each operation point coordinate. For example, as shown in FIG. 5C, the region R1, the region R2, and the region R3 are set according to the distance from the operation origin Pc, and when the operation point coordinates included in the region R1 are detected, the speed is low. The cursor is moved. Similarly, the operation point coordinates included in the region R2 are medium speed, the operation point coordinates included in the region R3 are high speed, and the cursor is moved. The speed setting means 9 can change the speed set in the operation point coordinates by changing the diameters of the regions R1, R2, and R3. In FIG. 5C, the region is set concentrically from the operation origin Pc. However, the region may not be concentric, and only the low speed region and the high speed region may be used. Also, the speed can be set for each operation point coordinate so that the speed gradually increases as the distance from the operation origin Pc increases. The speed setting means 9 of the present embodiment sets the speed of each operation point coordinate.
[0056]
The operation mode conversion means 10 of this embodiment converts the coordinate operation by the coordinate operation unit 2 into other input operations for executing various functions prepared in a device on which the touch pad device 1 is mounted. Specifically, in the coordinate operation region R, it is detected that the electrode patterns 4c and 5e of the operation substrate 4 and the base substrate 5 are continuously connected for a predetermined time, and the coordinate operation is switched to the input operation. An example of the operation by the switched input operation is, for example, switching to an operation for enlarging or reducing the display magnification of the WEB page displayed in the display area of the WEB browser.
[0057]
Control operations by the operation point coordinate selection means 7, invalidation control means 8, speed setting means 9, and operation mode conversion means 10 as described above are performed by an operation point coordinate selection program and invalidation from a memory (not shown) built in the microcomputer 11. The control program, speed setting program, and operation mode conversion control program are read out and executed by a central processing unit (not shown). The operation of control target elements such as pointers, cursors, etc., and screen scrolls based on the control result is displayed on a display device 12 such as a display connected to the microcomputer 11.
[0058]
Next, an operation example of this embodiment will be described.
[0059]
The touch pad device 1 of the present embodiment is used as a touch pad device of a notebook type personal computer, PDA or mobile phone, and as shown in FIG. 6, a pointer 13 displayed on a liquid crystal display constituting a display device 12 is displayed. A series of operations for selecting the icon 14 that is moved and the direction angle is located at an angle of 45 ° to the right will be described as an example.
[0060]
The current designated coordinates of the pointer 13 coincide with the operation origin Pc shown in FIG. Therefore, in order to move the pointer 13 as described above, first, any one on the operation line L (FIG. 5 (c)) whose direction angle θ is 45 ° to the right with respect to the operation origin Pc of the coordinate operation unit 2. Apply operating pressure to the point. Then, the flexible operation substrate 4 is deformed in a concave shape, the electrode pattern 4c comes into contact with the electrode patterns 4c and 5e of the base substrate 5, and the operation point coordinates are detected by a control system (not shown). As a result, the pointer 13 moves in the direction in which the direction angle θ is obliquely 45 ° to the right. At this time, when the operation point coordinate detected by applying the operation pressing force is the operation point coordinate P2 belonging to the region R1 shown in FIG. 5C, the pointer 13 moves to the right at a relatively slow speed. Move in the direction of 45 ° diagonally. Similarly, the operation point coordinate P3 belonging to the region R2 can be moved in the direction at medium speed, and the operation point coordinate P4 belonging to the region R3 can be moved in the direction at high speed.
[0061]
The operation point coordinate selection means 7 performs the detection of the operation point coordinates as described above. The operating point coordinate selection means 7 detects the intersection coordinates of the electrode patterns 4c and 5e that are turned on when the operating pressing force is applied as operating point coordinates. Here, when a large number of operation point coordinates are detected as described above, one of the operation point coordinates is selected. Therefore, the operating point coordinates are almost constant even if there is a difference in the force of the operating pressing force that varies depending on the operator or the difference in the thickness of the operator's finger. It can be carried out.
[0062]
Then, the operation pressing force applied when the indication position of the pointer 13 is on the icon 14 may be canceled. As a result, the pointer 13 stops on the icon 14. Therefore, as an operator, the pointer 13 can be easily and accurately moved only by applying an operation pressing force.
[0063]
In order to move the pointer 13 as described above more efficiently, first, an operation pressing force is applied so that the operation point coordinate P4 belonging to the region R3 is detected, and the pointer 13 is moved to a position near the icon 14 at high speed. Move. Then, when the pointer 13 comes to a position before the icon 14, the portion to which the operation pressing force is applied is returned to the operation origin Pc side so that the operation point coordinate P2 is detected. Then, since the pointer 13 changes to low speed movement, it can be accurately stopped on the icon 14.
[0064]
Thus, when the pointer 13 is first moved at high speed, for example, the pointer 13 may pass the icon 14 as it is. In such a case, the finger that is applying the operation pressing force is once released, and the operation pressing force is applied so that the operation point coordinate P5 that is 45 ° obliquely to the lower left of the operation origin Pc is detected. In this way, the pointer 13 that has gone too far can be returned to the icon 14.
[0065]
When the pointer 13 indicates the icon 14, an input operation for selecting it is performed next. In this operation, an operation pressing force that is larger than the operation pressing force applied to perform the coordinate operation may be applied as it is. For this reason, the operator can shift to the input operation as it is without releasing the operation finger, so that it is not necessary to perform other key operations, and the operability is very good.
[0066]
Then, when the above-described larger operation pressing force is applied, the operation point coordinates are in any position in the coordinate operation region R through the base substrate 5 and the resin spacer 5c in close contact with the back surface of the base substrate 5. The operation pressing force is reliably transmitted to the switch member 3. Along with this, the switch member 3 which is a metal disc spring contact member is deformed with a click feeling of “click”. As a result, the switch member 3 and the contact portion 6c of the substrate 6a are brought into conductive contact, and an input operation for selecting the icon 14 is performed. Therefore, the operator can feel the click feeling of the switch member 3 called “click” and perform a reliable selection operation.
[0067]
This time, an input operation for confirming the selection of the icon 14 is performed. For this operation, like the double click operation performed with the mouse device, the operation pressing force is once released and then a large operation pressing force is applied again. Thus, an input operation for confirming the selection for the icon 14 is performed.
[0068]
It is also possible to perform a drag operation and a drop operation of the icon 14 without performing this confirmation operation. When the drag operation is performed, the coordinate operation may be performed again as described above when the selection operation is performed on the icon 14. When the icon 14 is moved to a predetermined position, the icon 14 can be dropped if the switch member 3 is input as described above.
[0069]
Next, a screen scroll operation will be described as another operation example. Here, as shown in FIG. 7, a case where the frame size of the WEB page W2 is larger than the display area W1 of the browser displayed on the liquid crystal display constituting the display device 12 will be described as an example.
[0070]
In this case, in order to scroll the WEB page W2 in the upward direction, the downward direction, the right direction, and the left direction, a coordinate operation similar to the movement operation of the pointer 13 is performed. That is, since the center of the display area W1 of the browser is coincident with the operation origin Pc shown in FIG. 5C, the coordinate operation unit is detected so that the operation point coordinates at which the direction angle and the speed desired to be scrolled are obtained are detected. An operation pressing force may be applied to 2. As a result, the WEB page W2 can be scrolled in all directions and displayed visually easily and accurately.
[0071]
In general, on the WEB page and the like, the main operations are the movement of the pointer 13 and the scrolling of the WEB page W2 as described above. For example, when the display content of the WEB page W2 is a map or the like. It is very convenient to be able to enlarge and reduce the display magnification, and it is also very convenient for the visually impaired and the like that the display magnification can be changed for display by various software instead of the map. In such a case, for example, after moving the pointer 13 to a place where the display magnification is to be enlarged by the above-described coordinate operation, the microcomputer 11 performs an input operation using the above-described switch member 3 so as to enlarge the display magnification. You can also control the display with. When the display magnification is reduced, the operation mode conversion means 10 switches the coordinate operation unit 2 from the coordinate operation to the input operation. Specifically, for example, when the microcomputer 11 detects the time in which the electrode patterns 4c and 5e of the coordinate operation unit 2 are in contact with each other and the operation pressing force is continuously applied exceeding a certain threshold, Performs display magnification reduction control.
[0072]
Second Embodiment [FIGS. 8 to 10]
[0073]
The touch pad device 21 of this embodiment also includes a coordinate operation unit 22 and a switch member 23 as in the first embodiment.
[0074]
However, the operation substrate 24 and the base substrate 25 of the coordinate operation unit 22 of this embodiment are formed with peripheral wall portions 24b and 25b rising from the general surfaces 24a and 25a, respectively. The height of the peripheral wall portions 24b and 25b is set to a height corresponding to the thickness of the casing 26 of the device on which the touch pad device 21 is mounted. Domed coordinate operation units 24c and 25c are formed on the peripheral wall portions 24b and 25b, and a coordinate operation region R is provided.
[0075]
Resin spacers (27, 28) having a top surface shape corresponding to the surface shape of the back surface are provided in close contact with the back surface of the dome-shaped coordinate operation unit 25c of the base substrate 25. The resin spacers (27, 28) of this embodiment are composed of an annular outer peripheral portion 27 and a central actuating portion 28, and the annular outer peripheral portion 27 is formed as a divided body composed of a plurality of parts along the circumferential direction. Yes. Specifically, the upper piece 27a, the lower piece 27b, the right piece 27c, and the left piece 27d. A cylindrical guide hole 27e penetrating in the vertical direction is formed at the center of the annular outer peripheral portion 27, and a central operating portion 28 is inserted therethrough so as to be movable up and down.
[0076]
A switch member 23 is provided under each of the pieces 27a to 27d of the annular outer peripheral portion 27 and the central operating portion 28, and each switch member 23 is a contact portion 26b of a substrate 26a built in the housing of the device. The input operation can be performed by conductive contact with. Therefore, in the touch pad device 21 of this embodiment, since a maximum of five different input operations can be performed, further multi-functionalization can be achieved.
[0077]
Here, the electrode patterns 24d and 25d formed on the operation substrate 24 and the base substrate 25 of this embodiment will be described. As shown in FIG. 10, the operation substrate 24 in the coordinate operation region R starts from the center of the coordinate operation region R. Radially formed electrode patterns 24d are formed, and the base substrate 25 is formed with electrode patterns 25d formed in multiple concentric circles from the center. A direction angle is set for the radial electrode pattern 24d. In the illustrated example, a total of eight radial electrode patterns 24d are formed, and of course eight directions can be detected. However, a pressing operation force is simultaneously applied to the adjacent electrode patterns 24d, and a contact point is formed for each. Once formed, by taking the center between the two points, a maximum of 16 directions can be detected. In addition, the speed is set in the multiple concentric electrode pattern 25d. Specifically, for example, the moving speed of a pointer or the like can be set to gradually increase from the central electrode pattern 25d toward the outer electrode pattern 25d. In the touch pad device 21 of the present embodiment, coordinate operations are performed using these electrode patterns 24 and 25.
[0078]
When the electrode patterns 24d and 25d come into multipoint contact during this coordinate operation, one of the operation point coordinates may be selected as in the first embodiment. The operating point coordinate selecting means 7 sets the operating point as follows.
[0079]
For example, as shown in FIG. 10, it is assumed that two electrode patterns 24d and three electrode patterns 25d are in contact with each other and are in multipoint contact at six locations, and six operation point coordinates are detected. In this case, in the example of the first embodiment, the center-of-gravity coordinate is selected as the operation point coordinate, so the operation point selected is P6. However, if the operation point coordinates P6 are selected in this way, the operator's feeling of operation may not coincide with the unexpected. That is, since the coordinate operation region R is formed as a dome shape as a whole, the dome shape coordinate operation portions 24c and 25c are inclined downward from the apex thereof. The downward inclined surface acts to cause an illusion to the operator. That is, the operator's operational feeling may be intended to press the operating point coordinates that are actually higher in the drawing and rightward than the operating point coordinates P6. This is considered to be an illusion caused by the downwardly inclined surface. In the present embodiment, such disagreement in operational feeling is eliminated as follows.
[0080]
Specifically, the coordinate operation area R is divided into four parts such as an upper right area, an upper left area, a lower right area, and a lower left area, and a large number of operation point coordinates are detected in the upper right area (as illustrated in FIG. 10). In this case, the operation point coordinates at a position on the upper side and on the right side of the center of gravity coordinate P6 are selected. That is, in the example of FIG. 10, P7 is selected as the operation point coordinates by the operation point coordinate selection means 7. Similarly, in the upper left area, the operation point coordinates at the upper left side and the left side of the center of gravity in the figure are selected. In the lower right region, the operation point coordinates that are lower in the drawing than the barycentric coordinates and in the right side are selected. In the lower left region, the operation point coordinates that are lower in the drawing than the barycentric coordinates and in the left position are selected. As described above, the operation point coordinate selection unit 7 according to the present embodiment is configured such that, when a large number of operation point coordinates are detected, the coordinate operation region R that is an inclined surface is at the lower position in the inclination direction at the pressed position and the operation direction. By correcting the deviation for the selection of the operating point coordinates such that the operating point coordinates are selected outside the position, the sensory discrepancy between the operator's operational feeling and the actually selected operating point coordinates P7 is resolved. Therefore, the operability of coordinate operation is greatly improved.
[0081]
Other Embodiments [FIGS. 11-14]
[0082]
  In addition to the touch pad devices 1 and 21 of the first embodiment and the second embodiment described above, for example, FIG.11~ Figure14A touch pad device having a cross-sectional shape as shown in FIG. Note that these touch pad devices have a circular shape in plan view.
[0083]
  First, figure11In the touch pad device 31 showing only the coordinate operation unit, the coordinate operation region R has a flat surface shape. Also in this regard, the same actions and effects as in the above-described embodiment can be exhibited.
[0084]
  Figure12In the touch pad device 41 shown only in the coordinate operation unit, the coordinate operation region R has a concave curved shape. It is the shape which turned the dome shape coordinate operation parts 24c and 25c of 2nd Embodiment upside down. Also in this regard, the same actions and effects as in the above-described embodiment can be exhibited.
[0085]
  Figure13In the touch pad device 51 showing only the coordinate operation unit, the base substrate 53 is provided with a support protrusion 54 that holds the gap d2 in the non-formation portion of the electrode pattern in the coordinate operation region R of the operation substrate 52 and the base substrate 53. Is. A support protrusion 56 corresponding to the support protrusion 54 is also formed on the resin spacer 55. The support protrusions 54 and 56 can maintain the gap d2 even when the operation pressing force is repeatedly applied over a long period of time. In addition, although the figure showed the example which formed the one support protrusion 54,56, you may make it maintain the clearance gap d2 by forming multiple and supporting the operation board | substrate 52 by many points. And also about this, the effect | action and effect similar to above-mentioned embodiment can be exhibited.
[0086]
  Figure14The touch pad device 61 is a modification of the second embodiment, and is provided with a central operating portion 64 so as to penetrate through the operation substrate 62 and the base substrate 63. A locking flange 64a projecting outward in a ring shape is formed at the lower end of the central operating portion 64, and is prevented from coming off by a locking step portion 65a formed in a hollow shape on the endless annular outer peripheral portion 65. . Reference numeral 66 denotes a waterproof / dustproof sheet material which is bonded to the base substrate 63. An annular support portion 67 is formed between the operation substrate 62 and the base substrate 63, thereby supporting the operation substrate 62 from the back side. By setting it as such a touch pad apparatus 61, since the upper surface of the center action | operation part 64 is exposed outside, it becomes easier to perform input operation. In addition, the same operations and effects as those of the above-described embodiment can be exhibited.
[0087]
  Above figure11~ Figure14The coordinate operation area may be a polygonal shape or an elliptical shape in plan view. In particular, since the display screens of display devices of various devices are usually rectangular, the operability can be further improved if the display screen is formed in a corresponding shape.
[0088]
【The invention's effect】
An operation origin is set in the coordinate operation unit, and a direction angle centered on the operation origin is set in an operation point coordinate that can be detected by the coordinate operation unit, and when one operation point coordinate is detected, According to the present invention in which the coordinate operation of the screen is performed along the direction angle set to one operation point coordinate until the continuous detection of the one operation point coordinate is canceled, the operation point coordinate is detected. As long as it continues, screen coordinate operations such as operation indicators such as pointers and cursors and screen scrolling can be performed easily and accurately along a specific direction angle.
[0089]
When the speed is set to the operation point coordinates for which the direction angle is set and one operation point coordinate is detected, the speed of the one operation point coordinate is continuously changed according to the speed set to the one operation point coordinate. According to the present invention in which the coordinate operation of the screen is performed until the detection is canceled, an accurate and easy coordinate operation can be performed, and even if the direction angle is the same, the movement speed of the operation index such as the pointer or the cursor It is possible to variably operate the scroll speed such as screen scrolling and the like, and the operation efficiency is improved.
[0090]
According to the present invention, even if a plurality of operation point coordinates are detected by the operator's force, the finger thickness that is different for each operator, etc., one of the operation point coordinates is selected by the operation point coordinate selecting means. As a result, the accuracy of the operation can be further improved.
[0091]
According to the present invention including the switch means for performing an input on the selection element displayed on the screen, an input operation on the selection element can also be performed. Further, according to the present invention, the switch means capable of performing an input operation by applying an operation pressing force to the coordinate operation unit is provided below the coordinate operation unit. The input operation by means can be performed, and higher operability of the device can be realized by the cooperative operation of the coordinate operation and the input operation.
[0092]
According to the present invention in which the coordinate operation unit is a dome-shaped coordinate operation unit, the apex can be easily and tactilely sensed as compared to the case where the coordinate operation unit has a planar shape like the conventional touchpad described above. Random multidirectional operation with the vertex as the operation origin can be performed intuitively and more accurately. And in order to obtain such an accurate operability, it is not necessary to use a device structure with a large apparatus thickness such as a trackball having the same operation method. Can be satisfied.
[0093]
According to the present invention in which the coordinate operation unit is configured by a membrane sheet, the coordinate operation unit can be configured to be very thin, which is particularly advantageous for a device that is strongly demanded to reduce the size of the device.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view taken along the line DA-DA in FIG. 2 showing a touch pad device according to a first embodiment.
FIG. 2 is a plan view of the touch pad device of FIG. 1;
FIGS. 3A and 3B are explanatory diagrams showing an operation board and a base board. FIG. 3A is a schematic development view, and FIG. 3B is a wiring pattern of a coordinate operation area when the operation board and the base board are combined. Pattern diagram.
4 is a functional block diagram of the touch pad device of FIG. 1. FIG.
FIG. 5 is an explanatory diagram of a control operation of the touch pad device of FIG. 1;
6 is an explanatory diagram of a pointer coordinate operation performed by the touchpad device of FIG. 1; FIG.
FIG. 7 is a diagram showing a size relationship between a display area of a WEB browser and a frame area of a WEB page.
8 is a cross-sectional view taken along the line DB-DB in FIG. 8 showing the touch pad device according to the second embodiment.
9 is a plan view of the touch pad device of FIG. 2. FIG.
10 is an explanatory diagram showing an electrode pattern in a coordinate operation area of the touchpad device of FIG. 7;
FIG. 11 is a cross-sectional view of a touchpad device according to a third embodiment.
FIG. 12 is a cross-sectional view of a touchpad device according to a fourth embodiment.
FIG. 13 is a cross-sectional view of a touchpad device according to a fifth embodiment.
FIG. 14 is a cross-sectional view of a touch pad device according to a sixth embodiment.
[Explanation of symbols]
1 Touchpad device
2 Coordinate operation section
3 Switch member (switch means)
4 Operation board
4a Dome-shaped coordinate operation unit
5 Base substrate
5a Dome-shaped coordinate operation unit
7 Operating point coordinate selection means
21 Touchpad device (second embodiment)
22 Coordinate operation section
23 Switch member (switch means)
24 Operation board
24c Dome coordinate operation unit
25c Dome-shaped coordinate operation unit
31 Touchpad Device (Third Embodiment)
41 Touchpad Device (Fourth Embodiment)
51 Touchpad Device (Fifth Embodiment)
52 Operation board
53 Base substrate
61 Touchpad Device (Sixth Embodiment)
62 Operation board
63 Base substrate
Pc Operation origin
P1 to P7 Operating point coordinates

Claims (7)

In a touchpad device that performs coordinate operations on a screen according to operation point coordinates detected by a coordinate operation unit that forms an XY coordinate system,
In the coordinate operation unit, an operation origin is set, and a direction angle centered on the operation origin is set in an operation point coordinate that can be detected by the coordinate operation unit. When one operation point coordinate is detected, The coordinate operation on the screen is performed along the direction angle set to one operation point coordinate until the continuous detection of the one operation point coordinate is canceled ,
Switch means capable of input operation by applying an operation pressing force to the coordinate operation unit is provided below the coordinate operation unit,
A touch pad device , comprising: an invalid control means for invalidating a coordinate operation when a large number of operation point coordinates are detected by a press operation at a position vertically above the switch means by the press operation .   When the speed is set to the operation point coordinates for which the direction angle is set and one operation point coordinate is detected, the speed of the one operation point coordinate is continuously changed according to the speed set to the one operation point coordinate. The touch pad device according to claim 1, wherein the coordinate operation of the screen is performed until the detection is canceled.   The touch pad device according to claim 1, further comprising an operation point coordinate selecting unit that selects one of the operation point coordinates when a plurality of operation point coordinates are detected. The touchpad device according to any one of claims 1 to 3, wherein the coordinate operation unit is formed as a dome-shaped coordinate operation unit. The coordinate operation unit is provided with a flexible operation substrate and a base substrate each having a predetermined electrode pattern, and the electrode patterns are arranged facing each other in an insulated state, and a pressing operation is applied to the operation substrate. The touchpad device according to any one of claims 1 to 4, wherein the touchpad device includes a membrane sheet that outputs a contact portion that is electrically connected to the operation point coordinates. A resin spacer is provided between the coordinate operation unit and the switch means,
The resin spacer is formed as a divided body having an annular outer peripheral portion having a guide hole in a portion corresponding to the central portion of the coordinate operation portion, and a central operating portion inserted through the guide hole so as to be movable up and down. 6. The touch pad device according to claim 1, wherein the switch means is provided below the central operating portion. The touch pad device according to claim 6, further comprising another switch means capable of performing an input operation by applying an operation pressing force to the coordinate operation portion below the annular outer peripheral portion.

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