JP2010002946A - Display terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display terminal, capable of rapidly and surely detecting a contact to a touch panel while preventing false detection of the contact by suppressing the influence of noise. <P>SOLUTION: The display terminal includes: two touch panels (touch panel 1 and touch panel 2); and controllers (controller 26 and controller 27) for detecting a contact of an object to the touch panels respectively. A CPU 21 determines a scanning position in a display area of a display 5 from signals output from a horizontal synchronous signal generation circuit 41 and a vertical synchronous signal generation circuit 42 of a display I/F 25 controlling display from the display device 5. Contact detection information from the touch panel which is arranged in the scanning position is invalidated. According to this, the influence of electromagnetic noise generated in the scanning position on the contact detection of the touch panel can be eliminated. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a display terminal. More specifically, the present invention relates to a display terminal that has a plurality of touch panels and performs control for switching between valid / invalid detection of contact with the touch panel based on a scanning position.

  Conventionally, LCDs (Liquid Crystal Display), organic EL (Electroluminescence) displays, and the like have been generally used as display devices. In these display devices, a desired image is formed in the display region by applying a voltage to a display element provided in the display region to change its physical characteristics. Furthermore, a display device provided with a touch panel in a display area as a user interface is widely adopted for portable display terminals and the like.

When a voltage is applied to the display element to form an image, electromagnetic noise accompanying voltage displacement is generated in the voltage application portion. Then, the touch panel may malfunction due to the electromagnetic noise, and contact detection may be erroneous. Therefore, various countermeasures against noise are generally applied to such a display device. For example, there has been proposed an information processing apparatus capable of suppressing the influence of noise by controlling the generation timing of noise and the detection timing of contact with the touch panel to be inconsistent (Patent Document 1). reference).
JP 2006-79405 A

  However, in the above-described apparatus, the touch detection process for the touch panel is not performed at all before and after the timing of occurrence of noise. For this reason, there is a problem that it may take time for the device to detect contact with the touch panel after the user touches the touch panel, or the device may not be able to detect contact. It was.

  The present invention has been made to solve the above-mentioned problems, and it is possible to prevent erroneous detection of contact with the touch panel by suppressing the influence of noise, and to detect contact quickly and reliably. It is an object to provide a display terminal that can be used.

  In order to solve the above-described problem, a display terminal according to a first aspect of the present invention includes a display unit and an image formed by changing physical characteristics of display elements provided in a display area of the display unit. Scanning means for scanning the display area, a plurality of touch panels arranged in the display area of the display section, detection means for detecting contact with the touch panel, and the plurality of touch panels arranged in the display area of the display section A touch panel specifying means for specifying a scanning position touch panel which is a touch panel arranged at a scanning position by the scanning means, and a switching means for switching between valid / invalid detection of contact with the touch panel by the detecting means. , Invalidate the detection of the touch to the scanning position touch panel specified by the touch panel specifying means, Ku and a switching means to enable the detection of the contact to at least one of the touch panel.

  According to a second aspect of the present invention, in addition to the configuration of the first aspect, the display terminal includes the touch panel when scanning is performed in the main scanning direction and the sub-scanning direction by the scanning unit. Has a shape obtained by dividing the display area of the display unit in a direction parallel to the main scanning direction, and is arranged side by side in a direction parallel to the sub-scanning direction.

  According to a third aspect of the present invention, there is provided a display terminal according to the first or second aspect, wherein the scanning position is moved in accordance with the scanning performed by the scanning means. When the touch panel is switched from one touch panel to another, the touch panel includes an elapsed time measuring unit that measures an elapsed time from the switching timing, and the switching unit has a predetermined time measured by the elapsed time measuring unit. In the period up to, the detection of contact with the one touch panel is invalidated, and when the elapsed time reaches a predetermined time, the detection of contact with the one touch panel is validated.

  According to a fourth aspect of the present invention, in addition to the configuration of the first aspect of the present invention, the display unit is a non-volatile display that requires scanning only when the display content is updated. Update that scans to form an image by changing the physical characteristics of the display elements of the non-volatile display unit provided in the portion where contact is detected when contact is detected by the touch panel Scanning means is provided, and the switching means switches between valid / invalid detection of contact with the touch panel by the detecting means when scanning is performed by the update scanning means.

  In the display terminal according to the first aspect of the present invention, the detection of contact by the touch panel arranged in the scanned portion of the display area of the display device is invalidated. As a result, the electromagnetic noise generated at the scanning position affects the touch detection process for the touch panel, and even if erroneous touch detection occurs on the touch panel, the false detection is invalidated. It is possible to prevent the operation of the terminal from being affected. In addition, since the detection of the contact with the touch panel arrange | positioned in the part which is not scanned among the display areas of a display apparatus is effective, a display terminal can detect the contact to the touch panel by a user continuously. It becomes possible.

  In the display terminal of the invention according to claim 2, since the moving speed of the scanning portion is lower in the sub-scanning direction than in the main scanning direction, the touch panel is arranged side by side in the sub-scanning direction, so that the touch panel is moved to the touch panel. The period for switching between valid / invalid detection of contact can be set longer. As a result, in addition to the effect of the first aspect of the invention, the processing load of the switching means can be reduced.

  In the display terminal according to the third aspect of the present invention, when the scanning position moves from a specific touch panel (one touch panel) to an adjacent touch panel (other touch panel), after the elapse of a certain time from the movement timing, Switch the detection of touch to the touch panel from disabled to enabled. Since the scanning position moves to a place away from one touch panel after a certain period of time, in addition to the effect of the invention according to claim 1 or 2, electromagnetic noise generated at the scanning position is effective for contact detection. It is possible to suppress the influence on the one touch panel.

  In the display terminal of the invention according to claim 4, the display unit is a non-volatile display unit having a characteristic of retaining display contents even when power supply is cut off, and a stylus or the like is provided on the touch panel disposed in the display unit. Assume that the display terminal has a function of forming an image on the contact portion by touching with. If the non-volatile display section scans only when the display content is rewritten, the physical characteristics of the display element can be changed and the display content can be rewritten. The detection is invalidated, and the control for validating the detection of contact with at least one of the touch panels excluding the scanning position touch panel is performed. As a result, in addition to the effects of the invention according to any one of claims 1 to 3, electromagnetic noise generated at the scanning position affects the touch detection process for the touch panel, and erroneous touch detection occurs on the touch panel. Even in such a case, since the erroneous detection is invalidated, it is possible to prevent the operation of the display terminal from being affected.

  Hereinafter, a display terminal embodying the present invention will be described with reference to the drawings. These drawings are used for explaining the technical features that can be adopted by the present invention, and the configuration of the apparatus described, the flowcharts of various processes, etc., unless otherwise specified. It is not intended to be limited to that, but merely an illustrative example.

  First, an overview of the display terminal 10 will be described with reference to FIG. FIG. 1 is a schematic diagram illustrating a physical configuration of the display terminal 10. 1 is defined as a horizontal direction and a vertical direction as a vertical direction.

  As shown in FIG. 1, the display terminal 10 includes a display device 5 having a substantially rectangular display area, a touch panel 3 (touch panel 1 and touch panel 2) provided so as to cover the display area of the display device 5, and a display. Input devices 13 and 14 for performing an input operation on the terminal 10 are provided.

  In the display device 5, a known display element that changes physical characteristics by changing an electrical state is arranged in the display area. Examples of the display element include a liquid crystal element and an organic EL (Electroluminescence) element. These display elements are sequentially scanned with the horizontal direction as the main scanning direction and the vertical direction as the sub-scanning direction, and the electrical characteristics are changed in order, thereby changing the physical characteristics of the display elements. This makes it possible to form a desired image in the display area. For example, when a liquid crystal element is employed as the display element, an image is formed by changing the polarization state of the liquid crystal element by applying a voltage. Further, when an organic EL element is adopted as a display element, a voltage is applied to inject holes and electrons into the organic EL element, and these are recombined to emit light to form an image. ing.

  Each of the touch panel 1 and the touch panel 2 constituting the touch panel 3 has a shape obtained by dividing the display area of the display device 5 into two equal parts in the horizontal direction. A touch panel 1 is disposed on the upper side, and a touch panel 2 is disposed on the lower side. The touch panel 1 and the touch panel 2 are panels that can detect a contact position when an object contacts the surface. The display terminal 10 determines the input content from the user based on information on the image displayed on the display device 5 and the contact position detected by the touch panel 1 and the touch panel 2.

  In addition, it does not specifically limit as a drive system of a touch panel, A conventionally well-known drive system can be used. For example, a resistance film method and a surface acoustic wave method can be used.

  Further, the input device 13 and the input device 14 are configured by switches that can detect the operation content by the user, and are provided for performing an input operation on the display terminal 10. Examples of the switch include a contact switch and a tactile switch. Then, when the user operates the input device 13 and the input device 14, it is possible to perform an operation for switching (page updating) an image displayed in the display area of the display device 5 and a setting operation for the display terminal 10. It has become.

  Next, an outline of scanning executed to form an image on the display area of the display device 5 will be described with reference to FIG. FIG. 2 is a schematic diagram showing an outline of scanning.

  In the display area of the display device 5, although not shown, a plurality of signal lines are formed in a matrix in the horizontal direction and the vertical direction. A pixel electrode for applying a voltage to the display element is provided in a portion surrounded by the matrix signal lines. When a voltage is applied to both the horizontal and vertical signal lines adjacent to the pixel electrode, the voltage can be applied between the pixel electrode and the counter electrode. . It is assumed that “n” signal lines are provided in the horizontal direction and “m” signal lines are provided in the vertical direction.

  In the display terminal 10, as shown in FIG. 2, the voltage of the signal line in the vertical direction is turned on and off in order from the left end to the right in the state where the voltage of the signal line in the specific horizontal direction is turned on ("horizontal This is referred to as “direction scanning”. When the vertical signal line to be controlled reaches the right end, the horizontal signal line whose voltage is turned on is moved down by one step (referred to as “vertical scanning”, arrow 31 in the figure), and repeatedly in the vertical direction. The voltage of the signal line is ON-OFF controlled in order from the left end to the right. When the voltage application control is completed up to the lowermost pixel electrode, the process returns to the uppermost left, and the above-described processing is repeatedly executed. The display terminal 10 forms a desired image in the display area of the display device 5 by performing scanning by executing the above processing and sequentially changing the electrical state of the display element.

  Next, the electrical configuration of the display terminal 10 will be described with reference to FIG. FIG. 3 is a schematic diagram showing an electrical configuration of the display terminal 10.

  As shown in FIG. 3, the display terminal 10 has a CPU 21 that controls the whole, a program executed by the CPU 21, a hard disk 23 that stores display data to be displayed on the display device 5 of the display terminal 10, and the CPU 21 stores the program. A memory 22, which is a volatile storage element for storing temporary data generated during execution, is provided. The CPU 21, the hard disk 23, and the memory 22 are electrically connected via a bus so that the CPU 21 can access the storage areas of the hard disk 23 and the memory 22.

  The display terminal 10 is provided with a memory card 24. The memory card 24 stores display data to be displayed on the display device 5 of the display terminal 10. The CPU 21 and the memory card 24 are electrically connected via a bus so that the CPU 21 can access the storage area of the memory card 24.

  The display terminal 10 is provided with an input device 13 and an input device 14. As described above, the input device 13 and the input device 14 are configured by switches that can detect the operation content by the user. The CPU 21, the input device 13, and the input device 14 are connected via the I / O port 15 and the bus so that the CPU 21 can detect the content of operations performed on the input device 13 and the input device 14. Electrically connected.

  The display terminal 10 is provided with a display device 5 and a display device interface (abbreviated as “display device I / F”) 25. As described above, the display device 5 includes a display element in which a physical characteristic is changed by changing an electrical state in the display area, and a desired image can be displayed in the display area. ing. Further, the display device I / F 25 is provided to control scanning of the display element based on an instruction from the CPU 21 to form a desired image in the display area of the display device 5. The CPU 21 and the display device I / F 25 are electrically connected via a bus so that an instruction from the CPU 21 can be received. Further, the display device I / F 25 and the display device 5 are electrically connected so that the display device 5 can be controlled by the display device I / F 25. Details of the scanning control by the display device I / F 25 will be described later.

  Further, the display terminal 10 is provided with a counter 40. The counter 40 determines the scanning position in the display area of the display device 5 (the position of the pixel electrode for which voltage control is performed by scanning) from the output signal (details will be described later) from the display device I / F 25. It is provided to notify the CPU 21. The display device I / F 25 and the counter 40 are electrically connected so that the output signal from the display device I / F 25 can be detected by the counter 40. The counter 40 and the CPU 21 are electrically connected via a bus so that the CPU 21 can detect an output signal from the counter 40.

  The display terminal 10 includes a touch panel 1 and a touch panel 2, and a touch panel controller 26 and a touch panel controller 27 (hereinafter abbreviated as “controller”) for controlling them. The controller 26 and the controller 27 are provided to detect a contact position when an object touches the surfaces of the touch panel 1 and the touch panel 2 and notify the CPU 21 of information on the detected position (referred to as “detected position information”). ing. And CPU21, the controller 26, and the controller 27 are electrically connected so that detection position information can be notified to CPU21.

  The display terminal 10 is provided with an external communication interface (abbreviated as “external communication I / F”) 28. The external communication I / F 28 is a communication module provided so that the display terminal 10 can communicate with an external device. The external communication I / F 28 can use various devices according to the communication method with the external device. For example, when the display terminal 10 communicates with an external device via a USB cable, a USB controller is used as the external communication I / F 28. When the display terminal performs wireless communication, the external communication I / F 28 is used. An RF module is used.

  Next, a scanning position determination method and a touch panel valid / invalid switching method will be described with reference to FIGS. 4 is a schematic diagram showing an electrical connection state among the CPU 21, the display device I / F 25, the counter 40, the touch panel 1 and the touch panel 2, and FIG. 5 shows a case where the valid / invalid of the touch panel 1 and the touch panel 2 is switched. It is a timing chart.

  The signal pattern of the horizontal synchronization signal in FIG. 5 indicates the pattern of the signal output from the horizontal synchronization signal generation circuit 41 (see FIG. 4, see below), and the signal pattern of the vertical synchronization signal is the vertical synchronization signal generation. The pattern of the signal output from the circuit 42 (refer FIG. 4 and mentioned later) is shown. The signal pattern of the touch panel 1 input valid period indicates a period during which the CPU 21 validates / invalidates the detected position information from the controller 26 connected to the touch panel 1, and the signal pattern of the touch panel 2 input valid period is The period during which the CPU 21 validates / invalidates the detected position information from the controller 27 connected to the touch panel 2 is shown.

  First, an outline of a method for detecting a scanning position on the touch panel 1 and the touch panel 2 will be described. In the display terminal 10, the counter 40 counts the number of output signals (vertical synchronization signal, horizontal synchronization signal, details will be described later) from the display device I / F 25, and the scanning position is determined from this count value. Specifically, the counter 40 counts the number of output signals (vertical synchronization signal, horizontal synchronization signal) from the display device I / F 25 and outputs a signal to notify the CPU 21 of the accumulated value. On the other hand, the CPU 21 determines the scanning position based on the signal received from the counter 40.

  Here, electromagnetic noise accompanying voltage displacement is generated at the scanning position, and the electromagnetic noise may cause the touch detection operation by the touch panel to malfunction. Therefore, the CPU 21 invalidates the detected position information from the controller (controller 26 or controller 27) connected to the touch panel disposed at the scanning position. This eliminates the influence of erroneous touch panel detection caused by electromagnetic noise.

  As shown in FIG. 4, the display device I / F 25 is electrically connected to the CPU 21, and can receive display data that is data to be displayed in the display area of the display device 5 from the CPU 21. . The display device I / F 25 includes a horizontal synchronization signal generation circuit 41 and a vertical synchronization signal generation circuit 42.

  Among these generation circuits, the horizontal synchronization signal generation circuit 41 generates a pulse signal (referred to as “horizontal synchronization signal”) output from the display device I / F 25 at the start of horizontal scanning. The vertical synchronization signal generation circuit 42 generates a pulse signal (referred to as “vertical synchronization signal”) output from the display device I / F 25 at the start of vertical scanning.

  Here, in the display area of the display device 5, n signal lines are arranged in the horizontal direction as described above. The horizontal synchronization signal is output from the horizontal synchronization signal generation circuit 41 at the timing when the horizontal scanning to the rightmost end is completed and the scanning position moves to the leftmost end of the signal line one stage below. Accordingly, as shown in FIG. 5, a total of n horizontal synchronization signals are output from the horizontal synchronization signal generation circuit 41 while scanning is performed from the top row to the bottom row of the display device 5. In addition, the vertical synchronization signal is output from the vertical synchronization signal generation circuit 42 at the timing when the horizontal scanning of the bottom row is completed and scanning is newly started from the top row.

  As shown in FIG. 4, the horizontal synchronization signal generation circuit 41 and the vertical synchronization signal generation circuit 42 of the display device I / F 25 are in a state of being electrically connected to the display device 5. In this state, the display device 5 receives the horizontal synchronization signal and the vertical synchronization signal described above, thereby adjusting the timing of the horizontal direction scanning and the vertical direction scanning and executing the scanning. Thereby, an image of display data is formed in the display area of the display device 5.

  As shown in FIG. 4, the horizontal synchronizing signal generating circuit 41 and the vertical synchronizing signal generating circuit 42 of the display device I / F 25 are electrically connected to the counter 40. The horizontal synchronization signal and the vertical synchronization signal output from the display device I / F 25 can be detected. The counter 40 is electrically connected to the CPU 21. Then, it is possible for the CPU 21 to detect information on the signal output from the counter 40.

  The counter 40 accumulates the number of received horizontal synchronizing signals, and notifies the CPU 21 when the accumulated value (referred to as “horizontal synchronizing signal accumulated value”) is updated. In addition, when the vertical synchronization signal is received, the CPU 21 is notified (this notification is “vertical synchronization detection signal”). Further, at the timing of receiving the vertical synchronizing signal, the accumulated horizontal synchronizing signal accumulated value is cleared and reset with “1”. Therefore, the CPU 21 that detects these signals from the counter 40 can recognize the scanning position.

  Further, as shown in FIG. 4, the CPU 21 is electrically connected to a controller 26 that is connected to the touch panel 1 and a controller 27 that is connected to the touch panel 2. Then, by receiving the detected position information from the controller 26 and the controller 27, when an object comes into contact with the touch panel 3 (touch panel 1 and touch panel 2), the detected position can be recognized.

  Here, the CPU 21 detects the position detected from the controller connected to the touch panel (either the touch panel 1 or the touch panel 2) disposed at the scanning position among the touch panels 3 disposed in the display area of the display device 5. Control to invalidate information. As a result, even when electromagnetic wave noise is generated at the scanning position due to scanning, and this electromagnetic wave noise affects the touch detection of the touch panel (and the controller) and is erroneously detected, the display terminal 10 as a whole is erroneous. The situation where the detection is recognized is avoided.

  Specifically, as shown in FIG. 5, when the horizontal synchronization signal cumulative value received by the CPU 21 from the counter 40 is in the range of “1 to (n / 2)”, the scanning position is the display device 5. In the upper half of the display area, that is, in the area where the touch panel 1 is arranged. Therefore, the CPU 21 invalidates the detected position information from the controller 26 (attached to the touch panel 1) and receives the controller 27 (attached to the touch panel 2) while receiving the cumulative value of the horizontal synchronization signal of such values from the counter 40. The detected position information from is valid (T1 to T2).

  On the other hand, when the horizontal synchronization signal accumulated value received by the CPU 21 from the counter 40 is within the range of “(n / 2 + 1) to n”, the scanning position is within the lower half of the display area of the display device 5. That is, it exists in the area | region where the touch panel 2 is arrange | positioned. Therefore, the CPU 21 validates the detected position information from the controller 26 (attached to the touch panel 1) and receives the controller 27 (attached to the touch panel 2) while receiving the horizontal synchronization signal cumulative value of such values from the counter 40. The detected position information from is invalidated (T2 to T3).

  As described above, the CPU 21 detects the contact with the touch panel arranged at the scanning position in the display area of the display device 5 by switching the valid / invalid of the detected position information received from the controller 26 and the controller 27. It is possible to switch between valid / invalid. Thereby, even if it is a case where a false detection generate | occur | produces by the electromagnetic noise which generate | occur | produces at a scanning position, the state which recognizes a false detection as the display terminal 10 whole is avoided.

  Next, contact position detection processing executed by the CPU 21 of the display device 5 will be described with reference to FIGS. 6 and 7. FIG. 6 is a flowchart of the touch panel detection switching process, and FIG. 7 is a flowchart of the touch panel detection process. The touch panel detection switching process is a process that is always activated by the CPU 21 with the display terminal 10 powered on. The touch panel detection process is a process activated by the CPU 21 when reception of detected position information is started from either the controller 26 or the controller 27.

  The touch panel detection switching process will be described with reference to FIG. As shown in FIG. 6, in the touch panel detection switching process, the CPU 21 determines whether or not a vertical synchronization detection signal is received from the counter 40, and waits until a vertical synchronization detection signal is received (S11: NO). Then, based on the fact that the vertical synchronization signal generating circuit 42 of the display device I / F 25 has output the vertical synchronization signal, a vertical synchronization detection signal is output from the counter 40 to the CPU 21, and the CPU 21 receives it (S11). : YES), the CPU 21 determines that it is the timing at which the horizontal scanning of the bottom row is completed and the horizontal scanning is newly started from the top row. In this case, since the scanning position exists in the area where the touch panel 1 is arranged in the display area of the display device 5, the CPU 21 sets the panel 1 flag to invalidate the detection of the touch on the touch panel 1. “0” is stored in (S13). Next, “1” is stored in the panel 2 flag in order to validate detection of contact with the touch panel 2 (S15). These flags (panel 1 flag and panel 2 flag) are used to determine whether the detected position information from the controller 26 and the controller 27 is valid or invalid in the touch panel detection process in FIG. 7 described later. (Details will be described later).

  Next, the CPU 21 determines the accumulated horizontal synchronization signal received from the counter 40 in this state. If the horizontal synchronization signal cumulative value is not less than “1” and not more than “n / 2” (S17: NO), the process waits until the horizontal synchronization signal cumulative value becomes “n / 2 + 1”. In this state, since the scanning position is in the upper half of the display area of the display device 5, that is, in the area where the touch panel 1 is disposed, detection of contact with the touch panel 1 is invalid (panel 1 flag: 0). ), Detection of contact with the touch panel 2 is valid (panel 2 flag: 1). As a result, even when electromagnetic noise is radiated to the touch panel (touch panel 1) arranged at the scanning position and erroneous detection of contact occurs, the CPU 21 invalidates the erroneous detection information from the touch panel. be able to.

  When the scanning is continuously executed and the horizontal synchronizing signal cumulative value is added by the counter 40 and the horizontal synchronizing signal cumulative value becomes “(n / 2) +1” (S17: YES), the CPU 21. Determines that the scanning position has moved into the area where the touch panel 2 is arranged in the display area of the display device 5. And CPU21 memorize | stores "1" in the panel 1 flag in order to validate the detection of the contact to the touch panel 1 (S19). Next, “0” is stored in the panel 2 flag in order to invalidate the detection of the touch on the touch panel 2 (S21).

  Next, the CPU 21 determines whether or not the cumulative value of the horizontal synchronization signal received from the counter 40 is a value not less than “(n / 2) +1” and not more than “n”, and waits until it is out of the range of this value (S23). : YES). In this state, since the scanning position is in the lower half of the display area of the display device 5, that is, in the area where the touch panel 2 is disposed, detection of contact with the touch panel 1 is effective (panel 1 flag: 1 ), Detection of contact with the touch panel 2 is invalid (panel 2 flag: 0). Thereby, even when electromagnetic noise is radiated to the touch panel (touch panel 2) arranged at the scanning position and erroneous detection of contact occurs, the CPU 21 invalidates the erroneous detection information from the touch panel. be able to.

  When the scanning is continuously executed and the scanning of the lowermost column of the display area of the display device 5 is finished, a vertical synchronization signal is output from the vertical synchronization signal generation circuit of the display device I / F 25 after a predetermined time has elapsed. The When this is detected by the counter 40, the horizontal synchronization signal cumulative value is cleared and reset to "1" and notified to the CPU 21 together with the vertical synchronization detection signal.

  In the state where the horizontal synchronization signal accumulation is continuously monitored, the CPU 21 finishes scanning the bottom row of the display area of the display device 5 and starts horizontal scanning received from the counter 40 when the top row scanning is started. The accumulated signal value is “1” (S23: NO). Here, the CPU 21 stores “1” in the panel 2 flag in order to validate detection of contact with the touch panel 2 (S25), and returns to S11. In S11, since the CPU 21 receives the vertical synchronization detection signal from the counter 40 together with the horizontal synchronization signal accumulated value (S11: YES), the CPU 21 proceeds to S13 and repeats the above processing.

  Next, touch panel detection processing will be described with reference to FIG. When either of the controller 26 and the controller 27 detects the start of contact with the touch panel 3 (touch panel 1 and touch panel 2), the detected position information is transmitted to the CPU 21. Receiving this detected position information, the CPU 21 refers to the information stored in the panel 2 flag and determines whether or not the detection of the touch on the touch panel 2 is valid (S1). If “0” is stored in the panel 2 flag (S1: NO), the detection of contact with the touch panel 2 is invalid, and the process waits as it is.

  In this state, scanning by the display device I / F 25 proceeds, the scanning position moves, and “1” is stored in the panel 2 flag (see S15, S25, FIG. 6) (S1: YES), then the CPU 21 In this state, the detected position information received from the controller 27 (connected to the touch panel 2) is validated (S3), and it is determined that the object is in contact with the surface of the touch panel 2 based on the detected position information.

  Next, the CPU 21 refers to the information stored in the panel 1 flag, and determines whether or not detection of contact with the touch panel 1 is valid (S5). If “1” is stored in the panel 1 flag (S5: NO), the detection of contact with the touch panel 1 is invalid, and the process waits as it is.

  In this state, scanning by the display device I / F 25 proceeds, the scanning position moves, and “1” is stored in the panel 1 flag (see S21, FIG. 6) (S5: YES). In this state, the detected position information received from the controller 26 is validated (S7), and it is determined that an object is in contact with the surface of the touch panel 1 based on the detected position information.

  As described above, the CPU 21 determines the scanning position from the horizontal synchronizing signal and the vertical synchronizing signal used for scanning the display area of the display device 5, and detects the touch on the touch panel arranged at the scanning position. Invalid. Thereby, even when electromagnetic noise generated at the scanning position affects the touch panel and erroneous detection occurs, the CPU 21 invalidates the detected position information. It becomes possible to prevent false detection.

  Note that the display device I / F 25 that controls the display device 5 in order to display an image on the display area of the display device 5 of FIG. 3 by scanning corresponds to the “scanning unit” of the present invention, and the touch panel 3 (touch panel 1 The controller 26 and the controller 27 that transmit the detected position information to the CPU 21 when an object comes into contact with the touch panel 2) correspond to the “detecting means” of the present invention. Further, in S11, S17, and S23 of FIG. 6, the CPU 21 that performs the process of determining the scanning position based on the horizontal synchronization signal accumulated value received from the counter 40 corresponds to the “panel specifying means” of the present invention. 7, the CPU 21 that performs processing for switching the validity / invalidity of the detected position information from the controller 26 and the controller 27 based on the panel 1 flag and the panel 2 flag corresponds to the “switching means” of the present invention.

  In addition, this invention is not limited to the said embodiment, A various change is possible.

  In the above-described embodiment, the two touch panels 3 (touch panel 1 and touch panel 2) are arranged in the display area of the display device 5, but the present invention is not limited to this configuration. Therefore, a configuration in which three or more touch panels are arranged in the display area of the display device 5 may be adopted. In the case of a configuration in which three or more touch panels are arranged, detection of contact with the touch panel arranged at the scanning position may be invalidated, and detection of contact with other touch panels may be valid. It does not matter as invalid.

  In the above-described embodiment, the CPU 21 determines the scanning position based on the horizontal synchronization signal and the vertical synchronization signal output from the display device I / F 25, and performs control to switch between valid / invalid detection of contact with the touch panel 3. However, the present invention is not limited to this scanning position determination method. Therefore, for example, the scanning position may be determined by managing the elapsed time from the scanning start time and comparing it with the horizontal synchronization frequency and the vertical synchronization frequency.

  In the above-described embodiment, the counter 40 accumulates the horizontal synchronization signals output from the display device I / F 25 and notifies the CPU 21 of the results, but the present invention is not limited to this configuration. Therefore, the CPU 21 may directly receive the horizontal synchronization signal and accumulate the number of times.

In the above-described embodiment, the shape of the touch panel has a shape obtained by dividing the display area of the display device 5 in the horizontal direction. However, the shape of the touch panel is not limited to this shape, and touch panels having other shapes. May be arranged in the display area. However, the speed at which the scanning position is switched is slower in the vertical scanning than in the horizontal scanning. Therefore, the touch panel is shaped and arranged as described above, so that the touch detection touch detection is enabled / disabled. And the frequency can be minimized. As a result, the processing load on the CPU 21 can be reduced.
<Modification 1>

  An outline of a touch panel valid / invalid switching method in Modification 1 will be described. In the first modification, scanning proceeds on the touch panel 3 under the control of the display device I / F 25, and the scanning position is a region where the touch panel 1 is disposed from a region where the touch panel 1 is disposed in the display region of the display device 5. In a predetermined period before and after the movement timing (referred to as “movement timing”), control for invalidating detection of contact with both the touch panel 1 and the touch panel 2 is performed. Before and after the movement timing, the scanning position and the touch panel for which contact detection is enabled are in proximity to each other. In such a case, by disabling detection of contact with both touch panels, the scanning position Electromagnetic noise that is generated causes erroneous detection of the touch panel, and prevents the display terminal 10 as a whole from being recognized as erroneous detection.

  With reference to FIG.8 and FIG.9, the modification 1 of the display terminal 10 which actualized this invention is demonstrated. FIG. 8 is a timing chart when the validity / invalidity of the touch panel 3 (touch panel 1 and touch panel 2) in Modification 1 is switched, and FIG. 9 is a flowchart of the touch panel detection switching process. The physical configuration (FIG. 1), the electrical configuration (FIG. 2), the electrical connection state (FIG. 3), and the flowchart (FIG. 7) of the touch panel detection process of the display terminal 10 are described above. In the following, the description is omitted or simplified.

  Note that the signal pattern of the horizontal synchronization signal in FIG. 8 indicates the pattern of the signal output from the horizontal synchronization signal generation circuit 41 (see FIG. 4, see below), and the signal pattern of the vertical synchronization signal is the vertical synchronization signal generation. The pattern of the signal output from the circuit 42 (refer FIG. 4 and mentioned later) is shown. Further, the signal pattern of the touch panel 1 input valid period indicates a period in which the detected position information from the controller 26 in a state where the CPU 21 is connected to the touch panel 1 is valid. The signal pattern of the touch panel 2 input valid period is the CPU 21. Indicates a period in which the detected position information from the controller 27 in a state of being connected to the touch panel 2 is valid.

  With reference to FIG. 8, the timing chart in the case where the valid / invalid of the touch panel 3 (touch panel 1 and touch panel 2) is switched will be described. As shown in FIG. 8, scanning proceeds on the touch panel 3 under the control of the display device I / F 25, and a horizontal synchronization signal is output from the horizontal synchronization signal generation circuit 41 (see FIG. 4), and horizontal scanning is sequentially performed. (T11-T12). When the scanning position is in the upper half of the display area of the display device 5, that is, in the area where the touch panel 1 is disposed, detection of contact with the touch panel 1 is invalidated and the touch panel 2 is touched. Only the detection of contact is enabled.

  Here, when the horizontal synchronization signal cumulative value calculated by the counter 40 becomes “(n / 2) −3” (T12), the scanning position approaches the touch panel 2 in a state where the detection of contact is valid. Therefore, it is determined that the influence of electromagnetic noise generated at the scanning position on the touch panel 2 is increased. Then, detection of contact with the touch panel 2 is invalidated. In this state, detection of contact with both the touch panel 1 and the touch panel 2 is invalid (T12 to T13).

  In this state, scanning proceeds, and the scanning position moves from the area where the touch panel 1 is arranged in the display area of the display device 5 to the area where the touch panel 2 is arranged (the horizontal synchronization signal cumulative value is “n / 2”). To “(n / 2) +1”). However, since the distance between the scanning position and the touch panel 1 is short immediately after the movement, detection of contact with the touch panel 1 is not effective.

  When scanning further proceeds and the horizontal synchronization signal cumulative value calculated by the counter 40 becomes “(n / 2) +3”, the distance between the scanning position and the touch panel 1 is sufficiently long and is generated at the scanning position. It is determined that the influence of the electromagnetic noise on the touch panel 1 is reduced. And the detection of the contact to the touch panel 1 is made effective (T13-T14). As described above, it is possible to reduce the influence of the electromagnetic noise generated from the scanning position on the touch panel 3 by switching the validity / invalidity of the detection of the touch to the touch panel.

  Next, a flowchart of the touch panel detection switching process will be described with reference to FIG. As shown in FIG. 9, in the touch panel detection switching process, the CPU 21 determines whether or not a vertical synchronization detection signal is received from the counter 40, and waits until a vertical synchronization detection signal is received (S31: NO). When the vertical synchronization signal generation circuit 42 of the display device I / F 25 outputs the vertical synchronization signal, a vertical synchronization detection signal is output from the counter 40 to the CPU 21, and the CPU 21 receives this ( S31: YES), the CPU 21 determines that it is the timing when the horizontal scanning of the lowermost row is completed and the horizontal scanning is newly started from the uppermost row. In this case, since the scanning position is in the area where the touch panel 1 is arranged in the display area of the display device 5, the CPU 21 sets the panel 1 flag to invalidate the detection of the touch on the touch panel 1. “0” is stored (S33). Next, “1” is stored in the panel 2 flag in order to validate detection of contact with the touch panel 2 (S35).

  Next, the CPU 21 determines the accumulated horizontal synchronization signal received from the counter 40 in this state. When the horizontal synchronization signal cumulative value is not less than “1” and not more than “(n / 2) -4” (S37: NO), the horizontal synchronization signal cumulative value is “(n / 2) -3”. Wait until. In this state, since the scanning position is in the upper half of the display area of the display device 5, that is, in the area where the touch panel 1 is disposed, detection of contact with the touch panel 1 is invalid (panel 1 flag: 0). ), Detection of contact with the touch panel 2 is valid (panel 2 flag: 1).

  When the scanning is continuously executed and the horizontal synchronization signal accumulated value is added by the counter 40 and the horizontal synchronization signal accumulated value becomes “(n / 2) −3” (S37: YES), The CPU 21 determines that the scanning position has approached the touch panel 2 on which contact detection is enabled. Then, “0” is stored in the panel 2 flag in order to invalidate the detection of the touch on the touch panel 2 (S39). In this state, detection of contact with both the touch panel 1 and the touch panel 2 is invalid (panel 1 flag: 0, panel 2 flag: 0).

  Next, the CPU 21 determines the accumulated horizontal synchronization signal received from the counter 40 in this state. And it waits until predetermined time passes and a horizontal synchronizing signal cumulative value will be "(n / 2) +3" (S41: NO). During this time, the scanning position moves from the area where the touch panel 1 is arranged in the display area of the display device 5 to the area where the touch panel 2 is arranged (the horizontal synchronization signal cumulative value is changed from “n / 2” to “( n / 2) +1 ”).

  Further, the CPU 21 waits until a predetermined time elapses from the movement timing as the scanning progresses, and the scanning position is sufficiently distant from the arrangement position of the touch panel 1 (S41: NO). When the horizontal synchronization signal cumulative value becomes “(n / 2) +3” (S41: YES), the distance between the scanning position and the touch panel 1 becomes sufficiently long after a predetermined time has elapsed, and the electromagnetic waves generated at the scanning position. It is determined that the influence of noise on the touch panel 1 is reduced. Then, “1” is stored in the panel 1 flag in order to validate the detection of contact with the touch panel 1 (S43).

  Next, the CPU 21 determines whether or not the cumulative value of the horizontal synchronization signal received from the counter 40 is a value not less than “(n / 2) +3” and less than “n”, and waits until it is out of the range of this value (S45). : YES). In this state, since the scanning position is in the lower half of the display area of the display device 5, that is, in the area where the touch panel 2 is disposed, detection of contact with the touch panel 1 is effective (panel 1 flag: 1 ), Detection of contact with the touch panel 2 is invalid (panel 2 flag: 0).

  When the scanning is continuously executed and the scanning of the lowermost column of the display area of the display device 5 is finished, a vertical synchronization signal is output from the vertical synchronization signal generation circuit of the display device I / F 25 after a predetermined time has elapsed. The When this is detected by the counter 40, the horizontal synchronization signal cumulative value is cleared and reset to "1" and notified to the CPU 21 together with the vertical synchronization detection signal.

  In the state where the horizontal synchronization signal accumulation is continuously monitored, the CPU 21 finishes scanning the bottom row of the display area of the display device 5 and starts horizontal scanning received from the counter 40 when the top row scanning is started. The accumulated signal value becomes “1” (S45: NO). Here, the CPU 21 stores “1” in the panel 2 flag in order to validate detection of contact with the touch panel 2 (S47), and returns to S31. In S31, since the CPU 21 receives the vertical synchronization signal from the counter 40 together with the horizontal synchronization signal (S31: YES), the CPU 21 proceeds to S33 and repeats the above processing.

  As described above, the distance relationship between the scanning position and the touch panel is determined, and if it is determined that the distance between the two is close, it is determined that the influence of the electromagnetic noise generated at the scanning position on the touch panel is large. To do. And even if it is a case where a scanning position is not the arrangement position of a touch panel, the detection of the touch to a touch panel is invalidated. Thereby, even if electromagnetic noise that may affect the vicinity of the scanning position affects the touch panel and erroneous detection occurs, the CPU 21 invalidates the detected position information, and thus the display terminal 10 as a whole. It is possible to prevent erroneous detection of contact with the touch panel 3.

  In S45 of FIG. 9, the CPU 21 that performs processing for monitoring the elapsed time from when the scanning position is located in the region where the touch panel 2 is located is based on the horizontal synchronization signal cumulative value. Corresponds to “elapsed time measuring means”.

  In addition, this invention is not limited to the said modification 1, A various change is possible.

In the above modification, when the horizontal synchronization signal accumulated value of the counter 40 is “(n / 2) −3” to “(n / 2) +3”, the predetermined time has not elapsed from the movement timing. The detection of the touch on the touch panel 1 and the touch panel 2 is invalidated. However, the threshold value of the horizontal synchronization signal cumulative value in the case of invalidating the detection of the touch is not limited to the above, and is another value. It doesn't matter.
<Modification 2>

  A modification 2 of the display terminal embodying the present invention will be described. In the display terminal 10 according to the second modification, the display element provided in the display area of the display device 5 requires a change in electrical state only at the time of rewriting, and maintains the physical characteristics at the time of rewriting after rewriting. An element having the following is used. Accordingly, the display terminal 10 functions as so-called electronic paper that does not consume power even during display.

  Furthermore, in the display terminal 10 according to the second modification, when the user inputs a display area using a stylus or the like, the input information is detected and an image is formed at a contact portion between the stylus and the touch panel 3 ( Hereinafter referred to as “handwriting input function”). The display terminal 10 realizes this function by controlling scanning so that a desired image is formed at the contact position detected by the touch panel 1 and the touch panel 2.

  The flowchart of the touch panel detection process in the modification 2 is demonstrated with reference to FIG.10 and FIG.11. FIG. 10 is a flowchart of the handwriting input process in the second modification, and FIG. 11 is a touch panel detection switching process in the second modification. The physical configuration (FIG. 1), the electrical configuration (FIG. 2), the electrical connection state (FIG. 3), and the flowchart (FIG. 7) of the touch panel detection process of the display terminal 10 are described above. In the following, the description is omitted or simplified. Further, the touch panel detection switching process shown in FIG. 11 has a different configuration only in the processing part following S25 in the touch panel detection switching process shown in FIG. Accordingly, in the following description, overlapping parts are simplified.

  As shown in FIG. 10, the CPU 21 of the display terminal 10 in Modification 2 first monitors whether or not the handwriting input function is enabled by the user via the input device 13, the input device 14, the stylus, and the like ( S51). Here, in a state where the handwriting input function is disabled (S51: NO), it is not necessary to form an image on the contact portion of the touch panel with a stylus or the like. Therefore, only when information being displayed in the display area of the display device 5 is updated (S63: YES), the touch panel detection switching process (S65, see FIG. 11, described later) is executed. In the touch panel detection switching process, the touch / non-contact of the touch panel 3 is switched according to the scanning position of the display area. Then, after updating the display contents, the process returns to S51. On the other hand, if it is not necessary to update the information being displayed in the display area of the display device 5 (S63: NO), it is not necessary to perform scanning, and the process proceeds to S51 without performing any special processing.

  On the other hand, when it is detected that the handwriting input function is enabled (S51: YES), the CPU 21 monitors the detected position information from the controller 26 or the controller 27 (S53). Here, when the touch panel 1 or the touch panel 2 is not touched by the stylus or the like and the detected position information is not received from either the controller 26 or the controller 27 (S53: NO), scanning for updating the display content is executed. Therefore, “1” is stored in both the panel 1 flag and the panel 2 flag in order to validate detection of contact with the touch panel 3 (touch panel 1 and touch panel 2) (S61). Then, the process proceeds to S59.

  On the other hand, when the CPU 21 receives the detected position information from the controller 26 or 27 and determines that the user has touched the touch panel 3 (touch panel 1 or touch panel 2) with a stylus or the like (S53: YES), an image is displayed at the contact position. In order to form it, it is necessary to scan the display area of the display device 5. Therefore, the CPU 21 specifies a place where an image is formed based on the received detected position information, and transmits display data in a state where the image is formed to the display device I / F 25. Then, the display device I / F 25 starts scanning for displaying the transmitted display data in the display area of the display device 5 (S55).

  Next, the CPU 21 executes touch panel detection switching processing in this state, and switches between enabling / disabling the touch on the touch panel according to the scanning position of the display area (S57).

  The touch panel detection switching process will be described with reference to FIG. As shown in FIG. 11, in the touch panel detection switching process, the CPU 21 determines whether a vertical synchronization detection signal is received from the counter 40, and waits until a vertical synchronization detection signal is received (S71: NO).

  Here, when the information being displayed in the display area of the display device 5 is updated, a vertical synchronization signal is output from the vertical synchronization signal generation circuit 42 of the display device I / F 25 and is received from the counter 40 that has received the vertical synchronization signal. A vertical synchronization detection signal is output to the CPU 21.

  When the CPU 21 receives this vertical synchronization detection signal (S71: YES), the CPU 21 determines that it is time to finish the horizontal scanning of the bottom row and start the horizontal scanning from the top row. In this case, since the scanning position exists in the area where the touch panel 1 is arranged in the display area of the display device 5, the CPU 21 sets the panel 1 flag to invalidate the detection of the touch on the touch panel 1. “0” is stored in (S73). Next, “1” is stored in the panel 2 flag in order to validate detection of contact with the touch panel 2 (S75).

  Next, the CPU 21 determines the accumulated horizontal synchronization signal received from the counter 40 in this state. If the horizontal synchronization signal cumulative value is not less than “1” and not more than “n / 2” (S77: NO), the process waits until the horizontal synchronization signal cumulative value becomes “n / 2 + 1”.

  When the scanning is continuously executed and the horizontal synchronization signal cumulative value is added by the counter 40 and the horizontal synchronization signal cumulative value becomes “(n / 2) +1” (S 77: YES), the CPU 21. Determines that the scanning position has moved into the area of the display area of the display device 5 where the touch panel 2 is disposed. And CPU21 memorize | stores "1" in the panel 1 flag in order to validate the detection of the contact to the touch panel 1 (S79). Next, “0” is stored in the panel 2 flag in order to invalidate the detection of contact with the touch panel 2 (S81).

  Next, the CPU 21 determines whether or not the cumulative value of the horizontal synchronizing signal received from the counter 40 is a value not less than “(n / 2) +1” and not more than “n”, and waits until it is out of the range of this value (S83). : YES).

  When the scanning is continuously executed and the scanning of the lowermost column of the display area of the display device 5 is finished, a vertical synchronization signal is output from the vertical synchronization signal generation circuit of the display device I / F 25 after a predetermined time has elapsed. The When this is detected by the counter 40, the horizontal synchronization signal cumulative value is cleared and reset to "1" and notified to the CPU 21 together with the vertical synchronization detection signal.

  Here, the CPU 21 receives from the counter 40 when the scanning of the bottom row of the display area of the display device 5 is finished and the scanning of the top row is started in a state where the horizontal synchronization signal accumulation is continuously monitored. The horizontal synchronization signal cumulative value is “1” (S83: NO). Here, the CPU 21 stores “1” in the panel 2 flag to validate the detection of the touch on the touch panel 2 (S85), ends the touch panel detection switching process, and returns to the touch panel detection process (see FIG. 10). .

  After the touch panel detection switching process is completed and the display content is updated with the display data transmitted to the display device I / F 25, the CPU 21 proceeds to S59 as shown in FIG. In S59, the CPU 21 monitors whether or not the handwriting input function is invalidated by the user via the input device 13, the input device 14, and the touch panel (S59). If the handwriting input function is not invalidated (S59: NO), the process returns to S53 and the above-described processing is repeated. On the other hand, when the handwriting input function is invalidated (S59: YES), the process returns to S51 and the above-described processing is repeated.

  As described above, in the second modification, the display terminal 10 has a handwriting input function. In the handwriting input function, when contact is detected on the touch panel 3, it is necessary to form an image on the contact portion. Therefore, even when the display device 5 does not require scanning except for rewriting, It is necessary to update the display contents by executing scanning. In such a case, electromagnetic noise that may occur at the scanning position may affect the contact detection by the touch panel 3 and may cause erroneous detection. However, as described above, by executing the control to invalidate the detection position information from the touch panel arranged at the scanning position, it is possible to suppress the influence of erroneous detection due to electromagnetic noise and accurately recognize the contact position. It becomes possible.

  The display device 5 in the second modification corresponds to the “nonvolatile display unit” of the present invention, and the display device I / F 25 that controls the display device 5 in the second modification corresponds to the “update scanning unit”.

3 is a schematic diagram showing a physical configuration of the display terminal 10. FIG. It is a schematic diagram which shows the outline | summary of the scanning performed in order to form an image. 3 is a schematic diagram showing an electrical configuration of the display terminal 10. FIG. 3 is a schematic diagram showing an electrical connection state of the display terminal 10. FIG. It is a timing chart in case validity / invalidity of a touch panel switches. It is a flowchart of a touch panel detection switching process. It is a flowchart of a touch panel detection process. 10 is a timing chart when the touch panel is enabled / disabled in Modification 1; 10 is a flowchart of touch panel detection switching processing in Modification 1; 10 is a flowchart of a handwriting input process in Modification 2. It is a flowchart of the touchscreen detection switching process in the modification 2.

Explanation of symbols

1, 2, 3 Touch panel 5 Display device 10 Display terminal 21 CPU
25 Display I / F
26, 27 controller

Claims (4)

A display unit;
Scanning means for scanning the display area in order to form an image by changing the physical characteristics of the display elements provided in the display area of the display unit;
A plurality of touch panels arranged side by side in the display area of the display unit;
Detecting means for detecting contact with the touch panel;
Touch panel specifying means for specifying a scanning position touch panel that is a touch panel arranged at a scanning position by the scanning means among the plurality of touch panels arranged in the display area of the display unit;
Switching means for switching between valid / invalid detection of contact with the touch panel by the detection means, invalidating detection of contact with the scan position touch panel specified by the touch panel specifying means, excluding the scan position touch panel A display terminal comprising switching means for enabling detection of contact with at least one of the touch panels. When scanning is performed in the main scanning direction and the sub-scanning direction by the scanning unit,
The touch panel
The display terminal according to claim 1, wherein the display terminal has a shape obtained by dividing a display area of the display unit in a direction parallel to the main scanning direction, and is arranged side by side in a direction parallel to the sub-scanning direction. . An elapsed time measuring means for measuring an elapsed time from the switching timing when the scanning position touch panel is switched from one touch panel to another as the scanning position is moved by the scanning performed by the scanning means; Prepared,
The switching means is
The period until the elapsed time measured by the elapsed time measuring means reaches a predetermined time invalidates the detection of contact with the one touch panel, and when the elapsed time reaches the predetermined time, the one touch panel The display terminal according to claim 1, wherein detection of contact with the display is made effective. The display unit is a non-volatile display unit that requires scanning only when updating the display content,
In the case where contact is detected by the touch panel, an update scanning unit that performs scanning to form an image by changing the physical characteristics of the display element of the nonvolatile display unit provided in the portion where the contact is detected is provided. ,
The switching means is
4. The display terminal according to claim 1, wherein when the scanning is performed by the update scanning unit, the detection of the touch detection by the detection unit on the touch panel is switched between valid / invalid. 5. .

Images