JP2013012046A - Multi-touch panel device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a multi-touch panel device capable of reducing a processing load on a system and an application (software).SOLUTION: A multi-touch panel device includes: a touch panel whose input surface for receiving touch input is divided into plural areas; and a detector 110 for individually detecting the touch input in each of the plural areas. The detector 110 limits the detection of the touch input in accordance with individual setting K1 for each of the plural areas. Thus, the multi-touch panel device can limit positional information to be output to a system and an application (software) using the device by area. This suppresses unnecessary input of positional information to the system and the application (software) using the device, thereby reducing a processing load.

Description

  The present invention relates to a multi-touch panel device.

  Touch panel devices are widely used as input devices for small electronic devices such as portable communication devices and portable game devices, and their fields of use are expanding. Along with this, multiple touch inputs can be performed simultaneously to enable advanced operations such as pinch-in / pinch-out to enlarge, reduce, and rotate the displayed image, and swipe to turn the displayed book page. An acceptable multi-touch panel device has been developed.

  Since this multi-touch panel device allows a plurality of contact inputs in the entire panel, many unnecessary contact inputs due to an erroneous operation or the like are detected unlike a device that allows only one contact input at the same time. For this reason, it is conceivable that a system or application (software) that uses the apparatus becomes overloaded due to processing of a plurality of input position information.

  In relation to this problem, Patent Document 1 discloses that, in a multi-touch panel, an area where contact input is detected is scanned at a high frequency, while other areas are scanned at a low frequency to reduce excessive current consumption. Technology is disclosed.

Special table 2011-507123 gazette

  However, according to this technology, although the load of the detection process of the touch panel device itself can be reduced, the load of the position information process in the system or application (software) cannot be reduced.

  An object of the present invention is to provide a multi-touch panel device that can reduce the processing load in a system or application (software).

  In order to solve the above-described problem, the multi-touch panel device according to the present invention detects the touch input individually for each of the touch panel in which the input surface that receives the touch input is divided into a plurality of areas and the plurality of areas. A detecting unit.

  The detection unit limits detection of the contact input according to individual settings for each of the plurality of regions.

  The multi-touch panel device according to the present invention includes a touch panel in which an input surface that receives contact input is divided into a plurality of regions, and a detection unit that individually detects contact inputs for each of the plurality of regions. Can be input.

  Since the detection unit limits detection of contact input according to individual settings for each of the plurality of regions, the position information output to a system or application (software) that uses the device may be limited for each region. it can. Therefore, the system or application (software) that uses the apparatus can omit unnecessary position information processing and reduce the load of position information processing.

  On the other hand, since the touch panel device can omit unnecessary detection, not only power consumption can be reduced, but also the overall detection processing time can be shortened.

  In addition, the multi-touch panel device according to the present invention includes a touch panel in which an input surface that receives contact input is divided into a plurality of regions, instead of the above-described configuration or in addition to the above-described configuration, and each of the plurality of regions , A detection unit that individually detects the position of the contact input, and a position information output unit that outputs position information indicating the position of the contact input.

  The position information output unit restricts the output of the position information according to individual settings for each of the plurality of regions.

  The multi-touch panel device according to the present invention includes a touch panel in which an input surface that receives contact input is divided into a plurality of regions, and a detection unit that individually detects the position of the contact input for each of the plurality of regions. Multiple contact inputs are possible at the same time.

  Since the position information output unit restricts the output of position information in accordance with individual settings for each of a plurality of areas, the load of processing position information in a system or application (software) that uses the apparatus can be reduced. .

  Here, the content of the above setting may be simply information indicating whether the touch input is valid or invalid, or the valid or invalid touch input according to the identification number assigned to each touch input. It is good also as information which shows.

  Further, the contents of the setting can be freely rewritten according to the request of the system or application (software) if it is changed by a signal input from an external device.

  Furthermore, the multi-touch panel device according to the present invention preferably includes a non-volatile setting recording unit that records setting contents in order to save the trouble of resetting the device when the power is turned on.

  As described above, according to the present invention, it is possible to provide a multi-touch panel device that can reduce the processing load in a system or application (software).

It is a block diagram of the electronic device provided with the multi-touch panel apparatus. It is a top view of the lower board | substrate of a touch panel. It is a top view of the upper board | substrate of a touch panel. It is a functional block diagram of a panel control part. It is a functional block diagram of a detection part. It is a top view of the input surface showing the setting example 1 for every area | region. It is the top view of the input surface showing the example 2 of a setting for every area | region. 10 is a plan view of a part of the input surface showing an example of contact input in setting example 2. FIG. FIG. 10 is a plan view of a part of the input surface showing another example of contact input in setting example 2. It is the top view of the input surface showing the example 3 of a setting for every area | region. 10 is a plan view of a part of an input surface showing an example of contact input in setting example 3. FIG. FIG. 10 is a plan view of a part of the input surface showing another example of contact input in setting example 3. FIG. 10 is a plan view of a part of the input surface showing another example of contact input in setting example 3. FIG. 10 is a plan view of a part of the input surface showing another example of contact input in setting example 3. FIG. 10 is a plan view of a part of the input surface showing another example of contact input in setting example 3. FIG. 10 is a plan view of a part of the input surface showing another example of contact input in setting example 3. It is a flowchart showing operation | movement of a panel control part.

  FIG. 1 is a configuration diagram of an electronic device including a multi-touch panel device. The electronic device is, for example, a portable communication device or a portable game device, and includes a multi-touch panel device 1 that receives a plurality of contact inputs at the same time, and a system control unit 2 that controls the overall operation.

  The system control unit 2 can be configured by, for example, an arithmetic processing circuit. In this case, a CPU (Central Processing Unit) 20 that performs arithmetic processing, a ROM (Read Only Memory) 21 that stores a program for operating the CPU 20, and the like. And a RAM (Random Access Memory) 22 used for a working area of the memory space of the CPU 20. However, the system control unit 2 is not limited to the one that functions by software in this way, and may be configured by hardware such as an application specific integrated circuit.

  The system control unit 2 is, for example, an operating system (OS: Operating System) for managing and controlling electronic devices, or a system that operates a specific application such as a game. The system control unit 2 outputs setting information related to contact input to the multi-touch panel device 1 and processes position information of the contact input output from the multi-touch panel device 1. For example, the system control unit 2 determines whether or not the position of the contact input matches an operation location such as a button displayed on the display, and performs a predetermined operation.

The multi-touch panel device 1 is communicably connected to the CPU 20 via, for example, a USB (Universal Serial Bus) interface. However, the connection form between the multi-touch panel device 1 and the CPU 20 is not limited to this, and may be an interface such as RS-232C (Recommended Standard 232C) or I ² C (Inter-Integrated Circuit). Furthermore, the multi-touch panel device 1 may be connected to the bus 23 of the CPU 20 together with the RAM 22 and the ROM 21.

  The multi-touch panel device 1 includes a touch panel 10 having an input surface that receives contact input from a user, and a panel control unit 11 for driving the touch panel 10. The touch panel 10 is arranged such that the input surface is superimposed on a display unit such as a liquid crystal display, thereby allowing the user to sensuously operate buttons or the like virtually displayed on the display unit.

  The touch panel 10 includes an upper substrate 10b and a lower substrate 10a that are provided to be opposed to each other with a spacer or the like therebetween. The upper substrate 10b and the lower substrate 10a have substantially the same size and a rectangular input surface.

The lower substrate 10a is obtained by forming a transparent conductive film on one surface of a glass substrate. The transparent conductive film is made of ITO (Indium Tin Oxide), a material obtained by adding Al or Ga to ZnO (zinc oxide), or a material obtained by adding Sb or the like to SnO ₂ (tin oxide). .

  As shown in FIG. 2, the transparent conductive film of the lower substrate 10 a has an input surface that receives contact input divided into a plurality of regions (1) to (32) 101. The plurality of regions 101 are formed so as to be insulated from each other, and are individually electrically connected to the panel control unit 11 via, for example, a wiring of a flexible substrate extended to the lower substrate 10a.

  Therefore, the touch panel device 10 can detect the contact input individually for each of the plurality of regions 101, thereby simultaneously detecting the plurality of contact inputs. In the present embodiment, an example of 32 regions 101 obtained by dividing into four in the vertical direction and dividing into eight in the horizontal direction is given, but the form of division is not limited. Moreover, in this embodiment, although each area | region 101 is arrange | positioned at matrix form, the arrangement | positioning form is not limited.

  On the other hand, the upper substrate 10b is formed by forming a transparent resistive film on one surface of the film. This resistance film can be formed of the same material as the transparent conductive film. The film is made of polyethylene terephthalate, polycarbonate, or a transparent resin material.

  As shown in FIG. 3, the upper substrate 10b is provided with two sets of electrodes 301, 302, 311 and 312 along a pair of opposing sides. The two sets of electrodes 301, 302, 311, 312 are electrically connected to the panel control unit 11 via, for example, wiring of a flexible substrate extended to the upper substrate 10 b. In the present embodiment, the touch panel 10 is exemplified by a resistive film type, but is not limited to this, and another type such as a capacitance type may be adopted.

  FIG. 4 shows a functional configuration of the panel control unit 11. Panel control unit 11 includes a detection unit 110, an identification number giving unit 111, a position information output unit 112, a setting recording unit 113, and a signal processing unit 114. The panel control unit 11 may be configured only by hardware or may function by software.

  The detection unit 110 detects a contact input and detects a position of the contact input. The identification number assigning unit 111 assigns an identification number called a contact number or the like to each detected contact input. The position information output unit 112 outputs an identification number and position information indicating the detected position to the CPU 20 for each contact input. The setting recording unit 113 records setting information K1 and K2 for limiting detection by the detection unit 110 and output of position information by the position information output unit 12, respectively. The signal processing unit 114 processes a signal input from the CPU 20 and changes the setting information K1 and K2. Hereinafter, the configuration of the multi-touch panel device 1 will be described in detail.

  FIG. 5 shows a functional configuration of the detection unit 110. The detection unit 110 is connected to the electrodes 301, 302, 311 and 312 of the upper substrate 10b and the conductive film regions (1) to (32) 101 of the lower substrate 10a.

  The detection unit 110 includes voltage sources V1 and V2, switches 45 to 47, a current detection unit 42, a switch control unit 43, a region selection unit 44, a filter 48, an analog-digital conversion unit 41, and coordinate calculation. Part 40. The voltage source V1 applies a constant voltage between the electrodes 301 and 302 arranged in the X-axis direction shown in the figure via the switch 46. The voltage source V2 applies a constant voltage between the electrodes 311 and 312 arranged in the Y-axis direction shown in the figure via the switch 47. One electrode 301 in the X-axis direction is supplied with the power supply voltage Vcc via the switch 45.

  The switches 45 to 47 are on / off controlled by control signals S 1 to S 3 from the switch control unit 43. The power supply voltage Vcc and the voltage values of the voltage sources V1 and V2 may be the same or different from each other.

  Each region 101 of the conductive film of the lower substrate 10 a is connected to the region selector 44 and the filter 48. The region selection unit 44 sequentially selects a plurality of regions (1) to (32) 101. The order of selection is not limited. Then, the current detection unit 42 detects the current in the region 101 selected by the region selection unit 44 in accordance with the setting information K1 in the setting recording unit 113 and outputs a detection signal S4 to the switch control unit 43.

  The analog-digital conversion unit 41 is connected to each region 101 through the filter 48 and is also connected to the coordinate calculation unit 40. Here, the analog-digital conversion unit 41 converts the analog value of the voltage into a digital value, and the coordinate calculation unit 40 determines the X, X of the contact input from the voltage value of each region 101 based on the potential gradient of the upper substrate 10b. Y coordinate is calculated.

  The operation of the detection unit 110 will be described. The switch control unit 43 outputs a control signal S1 to turn on the switch 45 and apply the voltage Vcc to the electrode 301. At this time, if there is a contact input F, as shown in the figure, the P point of the upper substrate 10b and the Q point of the lower substrate 10a are in contact with each other for pressing, and the region (n) 101 where the Q point exists is present. Current flows. When the region selection unit 44 selects the region (n) 101, the current detection unit 42 detects the current in the region (n) 101 and outputs a detection signal S4 to the switch control unit 43. On the other hand, when no current is detected, the region selection unit 44 selects another region 101.

  The switch control unit 43 alternately turns on and off the switches 46 and 47 by outputting the control signals S2 and S3 when the detection signal S4 is input. That is, when the contact input F is detected, the switch control unit 43 turns on the switch 46 and turns off the switch 47, and then turns off the switch 46 and turns on the switch 47.

  When the switch 46 is on and the switch 47 is off, a voltage is applied between the electrodes 301 and 302 in the X-axis direction. At this time, the divided voltage value Vx by the sheet resistances 30a and 30b between the point P and the electrodes 301 and 302 is input to the filter 48 through the point Q. The divided voltage value Vx is subjected to noise removal by the filter 48 and input to the analog-digital converter 41. The coordinate calculation unit 40 detects the X coordinates of the positions P and Q of the contact input F in the X-axis direction connecting the electrodes 301 and 302 based on the partial pressure value Vx converted into a digital value.

  On the other hand, when the switch 46 is off and the switch 47 is on, a voltage is applied between the electrodes 311 and 312 in the Y-axis direction. At this time, similarly to the above-described content, the divided voltage value Vy by the sheet resistances 31a and 31b between the point P and the electrodes 311 and 312 is input to the filter 48 via the point Q. The divided voltage value Vy is subjected to noise removal by the filter 48 and input to the analog-digital converter 41. The coordinate calculation unit 40 detects the Y coordinates of the positions P and Q of the contact input F in the Y-axis direction connecting the electrodes 311 and 312 based on the partial pressure value Vy converted into a digital value. The order of detecting the X coordinate and the Y coordinate is not limited.

  The contact input position (Px, Py) obtained in this manner is output to the identification number assigning unit 111 shown in FIG. The identification number assigning unit 111 assigns an identification number to the contact input. At this time, the assigned identification number is selected based on the detected position (Px, Py) of the contact input.

  For example, the identification number giving unit 111 may give the smallest number among the unassigned numbers to the new contact input according to the time series. However, the order of numbers assigned in time series may be either ascending order or descending order.

  On the other hand, the identification number assigning unit 111 assigns the same identification number to the existing contact input. Whether the contact input is existing or new is determined by holding the position (Px, Py) of the contact input to which an identification number has been assigned, of which the position is close to the detected position (Px, Py) of the contact input. It is performed based on the presence or absence of something within the range.

  Thus, by assigning identification numbers in the order detected by the detection unit 110, management of the identification numbers in the system control unit 2 is facilitated. For easier management, it is preferable that the identification number assigned to a specific contact input does not change even if there is no other contact input.

  The position information output unit 112 illustrated in FIG. 4 outputs position information indicating the position (Px, Py) of the contact input to the CPU 20. For example, the position information output unit 112 includes a recording unit such as a memory, and can output the position information by writing the position information in the recording unit.

  The setting recording unit 113 is a non-volatile recording unit such as a flash memory, and records the setting information K1 of the detection unit 110 and the setting information K2 of the position information output unit 112 shown in FIG. Further, the signal processing unit 114 changes the setting information K1, K2 based on the signal input from the CPU 20. According to this, the contents of the setting information K1 and K2 can be freely rewritten according to the request of the system control unit 2, and the trouble of resetting when the apparatus is turned on can be saved.

  The setting information K1 is information indicating whether the touch input is valid or invalid for each region 101. The detection unit 110 limits the detection of contact input according to the setting information K1. For example, the current detection unit 42 may detect the current of the region 101 only when the contact input of the region 101 selected by the region selection unit 44 is set to be valid.

  FIG. 6 shows an example in which the contact input of the area (A) 101a represented by hatching is set to be invalid, and the contact input of the area (B) 101b represented by white paint is set to be valid. Yes. In such a setting, for example, the display unit overlapping the multi-touch panel device 1 may display a question text in the area (A) 101a and display an area for inputting the answer in the area (B) 101b. Conceivable.

  In this case, when the region selection unit 44 selects the region (A) 101a, the current detection unit 42 does not detect the current in the region (A) 101a. Therefore, the multi-touch panel device 1 does not detect a contact input in the area (A) 101a.

  Since the other region (B) 101b is set to be effective for contact input, when the region selection unit 44 selects the region (B) 101b, the current in the region (B) 101b is detected. Therefore, the multi-touch panel device 1 detects a contact input in the region (B) 101b.

  The setting information K2 is information indicating whether the contact input is valid or invalid for each region 110 according to the identification number assigned to each contact input. The position information output unit 112 restricts the output of position information according to the setting information K2. For example, the position information output unit 112 records the position information corresponding to the combination of the valid area 101 and the identification number in the recording unit, while the invalid area 101 and the identification number. It is preferable not to record the position information corresponding to the combination in the recording means.

  FIG. 7 shows an example in which, in addition to the example shown in FIG. 6, the contact input whose identification number is “2” or more is set to be invalid for the area (C) 101c represented by the shaded pattern. Yes. That is, the example of FIG. 7 is set so as not to allow multi-touch in the region (C) 101c. In such setting, for example, the display unit displays an explanatory text in the area (A) 101a, displays an image that can be rotated in the area (B) 101b, and further displays the image in the area (C) 101c. It is conceivable that a selectable area is displayed as the center of the rotation operation.

  In this case, as illustrated in FIG. 8, in the state where the contact input 60 with the identification number “1” is detected in the region (B) 101b (see “1” in the figure), the same region (B) 101b. Since the identification number “2” is assigned to the new contact input 61 (see “(2)” in the figure), the output is not limited by the position information output unit 112. For this reason, the system control unit 2 detects the contact input 61 (see “OK” in the figure).

  In the state where the contact input 60 with the identification number “1” is detected in the area (B) 101b (see “1” in the figure), the new contact input 62 to the area (C) 101c is the identification number. Since “2” is given (see “(2)” in the figure), the position information output unit 112 restricts the output. For this reason, the system control unit 2 does not detect the contact input 62 (see “NG” in the figure). Note that the new contact input 63 to the same area 101b as the contact input 60 with the identification number “1” is allowed only one contact input in each area 101. Therefore, the system controller 2 does not depend on the above setting. It is not detected (see “NG” in the figure).

  Next, as illustrated in FIG. 9, in a state where the contact input 60 with the identification number “1” is detected in the region (C) 101c (see “1” in the drawing), the region (B) 101b is entered. Since the identification number “2” is assigned to the new contact input 61 (see “(2)” in the figure), the output is not limited. For this reason, the system control unit 2 detects the contact input 61 (see “OK” in the figure).

  Further, in a state where the contact input 60 with the identification number “1” is detected in the region (C) 101c (see “1” in the figure), a new contact input to the other region 101 of the same region (C) 101c. 62 is assigned an identification number “2” (see “(2)” in the figure), and thus the output is restricted by the position information output unit 112. For this reason, the system control unit 2 does not detect the contact input 62 (see “NG” in the figure). Note that the new contact input 63 to the same area 101c as the contact input 60 with the identification number “1” is allowed only one contact input in each area 101. Therefore, the system controller 2 does not depend on the above setting. It is not detected (see “NG” in the figure).

  Next, in addition to the example shown in FIG. 7, FIG. 10 shows an example in which the contact input with the identification number “1” is set to be invalid for the region (D) 101d represented by the dot pattern. ing. In such setting, for example, the display unit displays an explanatory text in the area (A) 101a, displays an operable image in the area (B) 101b, the area (C) 101c, and the area (D) 101d. The button for image operation is displayed on the screen, and the button in the area (D) 101b cannot be operated unless the button in the area (C) 101c is pressed.

  In this case, as illustrated in FIG. 11, in the state where there is no contact input, the new contact input 60 to the region (D) 101d is assigned the identification number “1” (“(1 The position information output unit 112 restricts the output. For this reason, the contact input 60 is not detected by the system control unit 2 (see “NG” in the figure).

  Further, as illustrated in FIG. 12, in a state where the contact input 60 with the identification number “1” is detected in the region (B) 101b (see “1” in the figure), the region (D) 101d is input to the region (D) 101d. Since the identification number “2” is assigned to the new contact input 61 (see “(2)” in the figure), the output is not limited by the position information output unit 112. For this reason, the system control unit 2 detects the contact input 61 (see “OK” in the figure).

  FIG. 13 shows an example in which the contact input 60 with the identification number “1” is moved from the region (B) 101b to the region (D) 101d in the state where there is no contact input (“( 1) "). In this example, the output of the contact input 60 is not limited by the position information output unit 112 in the area (B) 101b, but is limited in the area (D) 101d. Therefore, the system control unit 2 detects the contact input 60 only when it is in the region (B) 101b (see “OK” and “NG” in the figure).

  On the other hand, FIG. 14 shows an example in which the contact input 60 with the identification number “1” is moved from the region (D) 101d to the region (B) 101b, contrary to the example of FIG. (Refer to “(1)”). In this example, the output of the contact input 60 is restricted by the position information output unit 112 in the region (D) 101d, but the output is not restricted in the region (B) 101b. Therefore, the system control unit 2 detects the contact input 60 only when it is in the region (B) 101b (see “OK” and “NG” in the figure).

  In the example of FIGS. 13 and 14, the identification number “1” is continuously given to the moving contact input 60, as described above, because the identification number giving unit 111 has the position of the contact input 60 ( This is because the same identification number is assigned by determining the continuity of (Px, Py). Since the detection unit 110 scans the entire area 101 at a speed faster than the movement speed of the contact input 60, the moving contact input 60 is mistakenly detected in two or more areas 101 at a time. Will not be detected.

  FIG. 15 shows that the contact input 60 with the identification number “1” is detected in the region (B) 101b (see “1” in the figure), and the region (B) 101b changes to the region (D) 101d. An example is shown in which the contact input 60 with the identification number “2” is moved (see “(2)” in the figure). In this example, the output of the contact input 60 is not limited in both the region (B) 101b and the region (C) 101c. Therefore, the system control unit 2 detects the contact input 61 in both the areas 101b and 101c (see “OK” in the figure).

  On the other hand, in FIG. 16, contrary to the example of FIG. 15, in the state where the contact input 60 with the identification number “1” is detected in the region (B) 101 b (see “1” in the figure), the region (D ) An example in which the contact input 60 with the identification number “2” is moved from 101d toward the region (B) 101b (see “(2)” in the figure). In this example, the output of the contact input 60 is not limited in both the region (B) 101b and the region (C) 101c. Therefore, the system control unit 2 detects the contact input 61 in both the areas 101b and 101c (see “OK” in the figure).

  The setting information K2 illustrated in FIG. 7 and FIG. 10 is shown as an invalid contact input condition, but on the contrary, it may indicate an effective contact input condition. . That is, the setting of the area (C) may be that the contact input with the identification number “1” is valid, and the area (D) may be valid even if the contact input with the identification number “2” or more is valid. Good.

  Next, the operation of the panel control unit 11 described so far will be described with reference to the flow shown in FIG. First, the switch control unit 43 applies the power supply voltage Vcc to the electrode 301 by turning on the switch 45, and the region selection unit 44 selects one region 101 (step St1). Then, the current detection unit 42 reads the setting information K1 of the setting recording unit 113, and determines whether the contact input in the selected area 101 is valid or invalid (step St2).

  When the contact input in the region 101 is invalid, the current detection unit 42 does not perform current detection (NO in step St2). At this time, if the selection of all the regions 101 has not been completed (NO in step St5), the region selection unit 44 selects another region 101 (step St12) and performs the same steps St1 and S2. On the other hand, when the contact input in the area 101 is valid, the current detection unit 42 detects the contact input by current detection (YES in step St2). When detecting the contact input, the current detection unit 42 outputs a detection signal S4 to the switch control unit 43.

  When receiving the detection signal S4 (YES in Step St3), the switch control unit 43 outputs the control signals S2 and S3 to the switches 46 and 47, respectively. Then, the coordinates (Px, Py) of the contact input are detected (step St4). On the other hand, if there is no detection signal S4 (NO in step St3), the region selection unit 44 selects another region 101 (step NO in step St5) if selection of all the regions 101 has not been completed (step ST5). St12), similar steps St2 and S3 are performed.

  Next, when Steps St <b> 2 to S <b> 4 described above are completed for all the regions 101 (YES in Step St <b> 5), the identification number assigning unit 111 performs a new contact for each detected contact input based on the coordinates (Px, Py). It is determined whether or not it is an input (step St6). Then, when the contact input is new (YES in step St6), the identification number assigning unit 111 newly assigns an identification number to this contact input (step St7).

  Next, the position information output unit 112 selects the identification number (step St8), reads the setting K2 of the setting recording unit 113, and whether the contact input of the selected identification number is valid or invalid in the corresponding area 101. Is determined (step St9).

  If the contact input is invalid (NO in step St9), the position information output unit 112 selects another identification number if selection of all identification numbers is not completed (NO in step St11). (Step St13), the same steps St8 and S9 are performed. On the other hand, when the contact input is valid (YES in step St9), the position information output unit 112 outputs the position information to the system control unit 2 (step St10).

  When the same steps St8 to S10 are completed for all the identification numbers (YES in step St11), the panel control unit 11 performs the processing from step St1 again when continuing the processing (NO in step St12). On the other hand, for example, when the power of the electronic device is turned off or when the stop of the application is notified from the system control unit 2, the panel control unit 11 ends the process (YES in step St12). In this flow, there is no limitation on the selection order of the area 101 and the selection order of the identification numbers.

  As described so far, the detection unit 110 limits the position information output to the system control unit 2 for each region 101 in order to limit the detection of contact input according to the individual setting K1 for each of the plurality of regions 101. Can be limited. Therefore, the system control unit 2 omits unnecessary position information processing and reduces the load of position information processing.

  On the other hand, since the touch panel device 1 can omit unnecessary detection, not only power consumption can be reduced, but also the overall detection processing time can be shortened.

  Further, since the position information output unit 112 restricts the output of the position information according to the individual setting K2 for each of the plurality of areas, the load of the position information processing in the system control unit 2 can be reduced.

  In the embodiment described above, two types of setting information K1 and K2 are used together, but the present invention is not limited to this, and only one of them may be used. In this case, for example, the output control unit 112 may refer to only the setting information K1 and simply limit the output of the position information for each region 101 regardless of the identification number.

  In the above-described embodiment, the setting information K1 and K2 are recorded in the setting recording unit 113. However, the present invention is not limited to this. For example, the system controller 2 is provided with a non-volatile recording means accessible by the CPU 20, and the CPU 20 directly outputs the setting information K 1 and K 2 to the detection unit 110 and / or the position information output unit 112. You may do it.

  Further, instead of the setting recording unit 113 or together with the setting recording unit 113, switching means such as a dip switch for changing the setting information K1, K2 may be provided.

  Although the contents of the present invention have been specifically described above with reference to the preferred embodiments, it is obvious that those skilled in the art can take various modifications based on the basic technical idea and teachings of the present invention. It is.

DESCRIPTION OF SYMBOLS 1 Multi touch panel apparatus 10 Touch panel 101 Area | region 110 Detection part 111 Identification number provision part 112 Position information output part 113 Setting recording part K1, K2 Setting information

Claims (9)

A touch panel in which an input surface that receives contact input is divided into a plurality of regions;
For each of the plurality of regions, including a detection unit that individually detects the contact input,
The multi-touch panel device, wherein the detection unit limits detection of the contact input according to individual settings for each of the plurality of regions. A touch panel in which an input surface that receives contact input is divided into a plurality of regions;
For each of the plurality of regions, a detection unit that individually detects the position of the contact input;
A position information output unit that outputs position information indicating the position of the contact input,
The position information output unit restricts the output of the position information in accordance with individual settings for each of the plurality of regions.   The multi-touch panel device according to claim 1, wherein the content of the setting is information indicating whether the contact input is valid or invalid.   The multi-touch panel device according to claim 2, wherein the content of the setting is information indicating whether the contact input is valid or invalid according to an identification number assigned to each of the contact inputs. .   The multi-touch panel device according to claim 1, wherein the content of the setting is changed by a signal input from an external device.   The multi-touch panel device according to claim 1, further comprising a non-volatile setting recording unit that records contents of the setting. A touch panel in which an input surface that receives contact input is divided into a plurality of regions;
For each of the plurality of regions, the detection unit that individually detects the contact input and the position of the contact input;
A position information output unit that outputs position information indicating the position of the contact input,
The detection unit limits the detection of the contact input according to an individual first setting for each of the plurality of regions,
The position information output unit restricts output of the position information in accordance with an individual second setting for each of the plurality of regions. The content of the first setting is information indicating that the contact input is valid or invalid,
The content of the second setting is information indicating whether the contact input is valid or invalid according to an identification number assigned to each of the contact inputs. Multi touch panel device.   The multi-touch panel device according to claim 4, wherein the identification number is given to the contact input in the order detected by the detection unit.

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