JP6022928B2 - Touch panel device - Google Patents

Description

  The present invention scans by irradiating light in a direction perpendicular to the X axis and a direction perpendicular to the Y axis along the contacted surface whose position on the surface is specified in the XY coordinate system. And a scanning unit that detects the position of one or more light-shielding objects on the contacted surface in an XY coordinate system based on the result of the scanning.

  In recent years, by detecting the coordinates related to the information written on the display screen and overwriting the image displayed on the display screen, the information written on the image is displayed in an overlapping manner, or Electronic whiteboards that can capture written information in a computer in real time have become widespread.

  For example, Patent Document 1 is a so-called optical scanning type touch panel that scans light and detects a light shielding object by shielding the light, and scans in a grid pattern throughout the display screen to detect that there is a light shielding object. In this case, the moving speed of the light shielding object is calculated, and if it is determined that the light shielding object is moving at high speed, the scanning range is limited to a narrower range, and a plurality of light beams emitted from one light emitting element are received. When the scanning speed in the oblique direction detected by the element is determined and the moving speed of the light shielding object is determined to be equal to or lower than the predetermined speed, the scanning to the target point is performed by reducing the number of light receiving elements in the scanning in the diagonal direction. A touch panel (coordinate position detection device) capable of specifying coordinates with high accuracy while improving followability is disclosed.

JP 2007-65776 A

  In the touch panel of Patent Document 1 described above, the scan direction and order are determined in advance. First, an overall rough scan is performed, and after the approximate position of the object is determined, the detailed scan is performed to obtain detailed coordinates. carry out. In the detailed scan, the response performance is improved after narrowing the scan range, and it corresponds to the high-speed movement of the position of the object (object point). At the same time, the accuracy of the detected coordinate position is improved by performing processing such as oblique scanning. The scan order of the detailed scan is basically the same as the overall schematic scan, and the scan is advanced in one direction.

  However, since the range is set narrow in the detailed scan, depending on the speed of the target, the target may move out of the specified range. In particular, in a touch panel capable of multi-touch, when two or more touches are detected, and when these objects move at high speed, the detailed scan is performed first for the object to be subjected to the second detailed scan. In addition to the scan time for the object to be performed, the time to start scanning the object (second target point) for which the second detailed scan is performed and to capture the second object As a result of the movement of the target object (second target point) for the added time, an event that exceeds the set range and is determined to be the disappearance of the target object may occur.

  On the other hand, when the scan range is simply expanded, the scan time is increased by the extent that the range is expanded, and the object moves between the end of the scan and the start of the next scan. There is a problem that the distance also increases.

  Furthermore, if the scan range is expanded to extend the scan time, the detection speed is slowed and the usability is affected. Also, if the object is moving in the same direction as the scan direction, the corresponding object will escape from the scan, so it will take time to capture, or the object will be out of range before capturing The problem of moving will occur.

The present invention has been made in view of such circumstances, and its object is to drive a light emitting element and a light receiving element corresponding to each other so that the position on the surface is specified in the XY coordinate system. Detects the position of one or more shaders on the contact surfaces, determine a predetermined region on the XY coordinate system including the position of the test out the shaders in each shader, X axis corresponding to the area Even if the light-shielding object moves at high speed by alternately driving the light-emitting element and the light-receiving element corresponding to each other from both ends to the center of each range and the Y-axis range, It is providing the touch panel apparatus which can detect without losing.

The touch panel device according to the present invention emits light in a direction orthogonal to the X axis and a direction orthogonal to the Y axis along the contacted surface whose position on the surface is specified in the XY coordinate system. a plurality of light emitting elements for irradiating a plurality of light receiving elements arranged to face the respective light emitting elements, the light-emitting element and the light receiving element is driven and a scanning unit which performs scanning, the plurality of light emitting elements and When a light shielding object is detected in one detection process in which the plurality of light receiving elements are sequentially driven to detect the light shielding object, the position of one or more light shielding objects on the contacted surface is detected in another detection process. In the touch panel device, an area determination unit that determines a predetermined area on the XY coordinate system including the detected position for each light shielding object in the other detection process is provided, and the scanning unit corresponds to the area For each X-axis range and Y-axis range, From both ends toward the center of, alternately, characterized in that are configured to drive a mutual corresponding light emitting element and a light receiving element.

In the present invention, the position of one or a plurality of light shielding objects on the contacted surface is detected by the one detection process , and the area determination unit is configured to detect the position of each light shielding object detected by the one detection process . A region is determined, and light emitting elements and light receiving elements corresponding to each other are alternately driven from both ends of each range toward the center with respect to the range of the X axis and the range of the Y axis corresponding to the region.

In the touch panel device according to the present invention, during the other detection processing , the scanning unit alternately turns one end side from the center to one end and the other end side from the center to the other end in each range. Further, the light emitting element and the light receiving element corresponding to each other are driven .

In the present invention, when the other detection process is performed, the scanning unit alternately alternates between one end side and the other end side of each range in each of the X-axis range and the Y-axis range. The light emitting element and the light receiving element corresponding to each other are driven .

In the touch panel device according to the present invention, during the other detection process , the scanning unit alternately drives the light emitting element and the light receiving element corresponding to each other with respect to the X axis range and the Y axis range. It is configured.

In the present invention, when performing the other detection processing , the scanning unit alternately drives the light emitting element and the light receiving element corresponding to each other with respect to the range of the X axis and the range of the Y axis.

  According to the present invention, even a light-shielding object that moves at high speed can be detected without losing its position when the light-shielding object moves out of the region.

It is the conceptual diagram which displayed notionally the electronic whiteboard which concerns on embodiment of this invention. It is a functional block diagram which shows the principal part structure of the electronic whiteboard which concerns on embodiment of this invention. It is a functional block diagram which shows the principal part structure of the control part in the touchscreen part of the electronic whiteboard which concerns on embodiment of this invention. It is a functional block diagram explaining the process of the light scanning in the electronic whiteboard which concerns on embodiment of this invention. It is explanatory drawing explaining the whole general | schematic scan in the electronic whiteboard which concerns on embodiment of this invention. It is explanatory drawing explaining the local detailed scan in the electronic whiteboard which concerns on embodiment of this invention. In the related art, when the light shielding object is moving at a high speed, it is out of the determined detailed scan narrow area, and the light shielding object disappears. It is explanatory drawing explaining the method of the local detailed scan in the electronic whiteboard which concerns on embodiment of this invention. It is explanatory drawing explaining the local detailed scan actually performed in the electronic whiteboard which concerns on embodiment of this invention. It is a flowchart explaining the local detailed scan of the detailed scan narrow zone Z performed in the electronic whiteboard which concerns on embodiment of this invention. It is explanatory drawing explaining the location where a light receiving element is influenced by crosstalk light. It is explanatory drawing explaining the location where a light receiving element is not influenced by crosstalk light.

  Hereinafter, the case where the touch panel device according to the present invention is applied to a so-called electronic whiteboard will be described in detail with reference to the drawings.

  FIG. 1 is a conceptual diagram conceptually showing an electronic whiteboard 100 according to an embodiment of the present invention, and FIG. 2 is a functional block diagram showing a main configuration of the electronic whiteboard 100 according to the embodiment of the present invention. It is.

  The electronic whiteboard 100 according to the embodiment of the present invention includes a display unit 100A and a touch panel unit 100B, and the touch panel unit 100B includes a light emitting element that emits infrared light and a light receiving element that receives infrared light, and blocks light. This is a so-called infrared shielding touch panel that detects the position of an object. In the electronic whiteboard 100, for example, the display unit 100A is connected to a personal computer (hereinafter referred to as a PC) via HDMI, and the touch panel unit 100B is connected via USB. In the present embodiment, the display unit 100A and the touch panel unit 100B are configured to be independent for each function of video display and coordinate instruction, but for the purpose of synchronizing the video display and coordinate instruction, etc. Configuration and control may be integrated. Further, the I / F for video display and coordinate instruction is not limited to HDMI and USB, and other methods may be used.

  The display unit 100A includes, for example, an LCD or an EL (Electroluminescence) panel, and displays video output from the PC and characters, line drawings, and the like received from the user via the touch panel unit 100B and the PC. In addition, a touch panel unit 100B is provided so as to surround the display screen 101 (contacted surface) of the display unit 100A.

  The touch panel unit 100 </ b> B includes a control unit 1, a ROM 2, a RAM 3, an I / F unit 5, and a scanning unit 9, and transmits / receives coordinate data to / from the PC via the I / F unit 5.

  The control unit 1 of the touch panel unit 100B displays characters, line drawings, etc. on the display unit 100A by accepting writing / drawing of characters, line drawings, etc. via the PC based on the coordinates related to the scanning result by the scanning unit 9. .

  A control program is stored in the ROM 2 in advance, and the RAM 3 temporarily stores data and can be read out regardless of the storage order, storage position, or the like. The RAM 3 stores, for example, a program read from the ROM 2 and various data generated by executing the program.

  The control unit 1 loads the control program stored in advance in the ROM 2 onto the RAM 3 and executes it, thereby controlling the various hardware described above via the bus and causing the touch panel unit 100B to function.

  FIG. 3 is a functional block diagram showing a main configuration of the control unit 1 in the touch panel unit 100B of the electronic whiteboard 100 according to the embodiment of the present invention. The control unit 1 includes a CPU 11, a coordinate calculation unit 12, a light shield management unit 13, a first detection unit 14, and a second detection unit 15.

  The coordinate calculation unit 12 calculates the coordinates on the display screen 101 of the display unit 100A of a light shielding object such as a pen-type input device or a finger. Specifically, the coordinates of such a light blocking object are calculated based on an intensity signal described later, which is transmitted when the light blocking on the display screen 101 of the display unit 100A is detected by the touch panel unit 100B.

  The light shielding object management unit 13 manages the position (coordinates) of the light shielding object detected by the scanning of the scanning unit 9. For example, when the light shielding object moves, the light shielding object management unit 13 stores and updates a coordinate history representing the movement of the light shielding object.

  The first detection unit 14 detects the positions of one or more light shielding objects from the entire area on the display screen 101 of the display unit 100A. Specifically, the scanning unit 9 of the touch panel 100B performs light scanning (hereinafter, referred to as an overall schematic scan) over the entire area on the display screen 101 of the display unit 100A, and the overall schematic scan acquired from the touch panel 100B. Based on the intensity signal according to the result, the first detection unit 14 detects the coordinates of the light shielding object on the display screen 101 of the display unit 100A.

  The second detection unit 15 detects the position of the light shielding object detected by the first detection unit 14 from a partial area on the display screen 101 of the display unit 100A. For example, when the first detection unit 14 detects the position of one or a plurality of light shielding objects based on the result of the overall outline scan, the CPU 11 narrows a predetermined range including the light shielding objects by a method described later. The area is determined for each shade object. The scanning unit 9 of the touch panel 100B performs light scanning (hereinafter referred to as local detailed scanning) for each determined narrow area. At this time, the second detection unit 15 detects the coordinates on the XY coordinate system for each light shielding object detected by the first detection unit 14 based on the intensity signal related to the result of the local detailed scan acquired from the touch panel 100B. To do.

  The CPU 11 controls the light emitting element and the light receiving element of the scanning unit 9 and determines a narrow area (hereinafter referred to as a detailed scan narrow area) on the XY coordinate system for the local detailed scan. That is, the CPU 11 determines a predetermined scanning region (detailed scanning narrow region) centered on the coordinates based on the coordinates of the light shielding object detected by the first detection unit 14. More specifically, a detailed scan narrow area specified from a predetermined range on the X axis centered on the X coordinate of the light shielding object and a predetermined range on the Y axis centered on the Y coordinate of the light shielding object is determined.

  The touch panel unit 100B is an infrared shielding touch panel as described above. That is, when a light blocking is detected when a pen-type input device (not shown) or the tip of a finger or the like approaches or comes close to the display screen 101 of the display unit 100A, the light-shielding object (pen-type input) is detected. The position of the device or finger). That is, as a result of scanning, a signal (intensity signal) obtained from the light receiving element is sent to the control unit 1, and based on this, the coordinate calculation unit 12 calculates the coordinates of such a light shielding object. In this way, the touch panel unit 100B accepts input of position designation on the display unit 100A, characters, line drawings, and the like from the user.

  The touch panel unit 100B includes a scanning unit 9 that scans infrared light (hereinafter referred to as infrared light) along the display screen 101 of the display unit 100A. The scanning unit 9 irradiates infrared light. A light emitting unit 91 having a plurality of light emitting elements, a light receiving unit 92 having a plurality of light receiving elements for receiving infrared light from the corresponding light emitting elements, and a light emitting signal and a light receiving signal from the control unit 1 (CPU 11). Address decoder 93 assigned to unit 91 and light receiving unit 92, and A / D converter 94 for converting an analog signal from light receiving unit 92 used for detection of a light shielding object into a digital signal.

  FIG. 4 is a functional block diagram illustrating light scanning processing in the electronic whiteboard 100 according to the embodiment of the present invention.

  The light emitting unit 91 has a multiplexer (not shown), and each of the light emitting elements is connected to the multiplexer. The light receiving unit 92 also includes a multiplexer (not shown), and each of the light receiving elements is connected to the multiplexer. Further, each light emitting element of the light emitting unit 91 is configured to correspond (oppose) to any one light receiving element of the light receiving unit 92.

  The CPU 11 of the control unit 1 outputs a light emission signal for causing the plurality of light emitting elements to emit light to the address decoder 93A, and outputs a light reception signal for causing the plurality of light receiving elements to receive light to the address decoder 93B. The address decoder 93A outputs, to the light emitting unit 91, a signal for specifying any one of the light emitting elements related to light emission in response to the signal from the CPU 11, and the address decoder 93B responds to the signal from the CPU 11. Then, a signal for specifying the light receiving element corresponding to the specified light emitting element among the light receiving elements is output to the light receiving unit 92.

  The light emitting element thus identified emits infrared light, and the corresponding light receiving element receives infrared light. At this time, an intensity signal indicating the intensity of the infrared light received by the light receiving element as a voltage value is output to the A / D converter 94. The A / D converter 94 converts the intensity signal into an 8-bit digital signal, for example, and outputs the converted intensity signal to the control unit 1. The control unit 1 sequentially repeats the process of acquiring the intensity signal from each light receiving element in order to acquire the intensity signal from all the light receiving elements.

  The CPU 11 of the control unit 1 calculates the amount of light received by the light receiving element based on the intensity signal acquired from each light receiving element. When the calculated amount of received light exceeds a predetermined threshold, the CPU 11 determines that the optical path of the infrared light received by the light receiving element is not blocked. When the calculated amount of received light is equal to or less than a predetermined threshold, it is determined that the optical path of infrared light received by the light receiving element is blocked.

  Based on the determination result of the CPU 11, the coordinate calculation unit 12, the first detection unit 14, and the second detection unit 15 calculate the position of the light shielding object. That is, the coordinate calculation unit 12, the first detection unit 14, and the second detection unit 15 specify a light receiving element in which the optical path of infrared light is blocked, and based on the position of the specified light receiving element, the display unit 100A A process of calculating the coordinates of the light shielding object on the display screen 101 is performed.

  As described above, the touch panel 100 </ b> B sends to the control unit 1 an intensity signal related to the result of the overall rough scan and the local detailed scan by the scanning unit 9. At the time of the overall rough scan, light is emitted and received by all the light emitting elements and the light receiving elements, and at the time of the local detailed scan, the light emitting elements and the light received in each detailed scan narrow area determined by the CPU 11. Light is emitted and received only by the element.

  Hereinafter, the local detailed scan and the overall schematic scan will be described in detail. FIG. 5 is an explanatory diagram illustrating an overall schematic scan in the electronic whiteboard 100 according to the embodiment of the present invention, and FIG. 6 illustrates a local detailed scan in the electronic whiteboard 100 according to the embodiment of the present invention. It is explanatory drawing to do.

  The display screen 101 of the display unit 100A has a rectangular shape, and a plurality of light emitting elements 911, 911,... Are arranged in parallel along the edge of the display unit 100A on the right and lower sides of the display screen 101 in the drawing. Yes. The light emitting element 911 is, for example, a light emitting diode (LED) that emits infrared light. In the drawing, the optical path of the infrared light emitted from each light emitting element 911 is indicated by a solid arrow.

  The plurality of light emitting elements 911, 911,... On the right side are provided so that the optical paths of the infrared light emitted from the respective light emitting elements 911 are parallel to each other along the display screen 101. , 911,... Are similarly provided.

  That is, the right light-emitting elements 911, 911,... In the left-right direction (X-axis direction) and the plurality of lower light-emitting elements 911, 911,. They are provided so as to be orthogonal to each other.

  Further, on the display screen 101 of the display unit 100A, light receiving elements 921, 921,... Are provided at positions facing the light emitting elements 911, 911,.

  That is, on the left side and the upper side of the display screen 101 of the display unit 100A, a plurality of light receiving elements 921, 921,. The light receiving element 921 is a light receiving diode that receives infrared light. The infrared light from the light emitting elements 911, 911,... Is received by the light receiving elements 921, 921,.

  As in the case of the light emitting elements, the upper light receiving elements 921, 921, ... and the left light receiving elements 921, 921, ... are provided so that the optical paths of the infrared light to be received are orthogonal to each other.

  The scanning unit 9 sequentially causes the light emitting elements 911 to emit light one by one from the one end to the other end in the X-axis direction and from one end to the other end in the Y-axis direction on the display screen 101 of the display unit 100A. The position, size, and the like of the light shielding object on the display screen 101 of 100A are detected as described above.

  In the case of the overall schematic scan, as shown in FIG. 5, the scanning unit 9 performs a process of scanning the entire display screen 101 of the display unit 100A to detect a light shielding object. That is, the light emitting elements 911 are sequentially caused to emit light one by one from one end to the other end in the X-axis direction, and a light shielding object on the display screen 101 of the display unit 100A is detected.

  In the case of the local detailed scan, as shown in FIG. 6, only the detailed scan narrow area Z determined by the CPU 11 is scanned. Specifically, for example, when one or a plurality of light shielding objects are detected by the overall rough scan, the CPU 11 determines a detailed scan narrow area corresponding to each light shielding object. The detailed scan narrow area determines, for example, a predetermined range on the X axis centered on the X coordinate of the center of each light shield, and a predetermined range on the Y axis centered on the Y coordinate of the center of the light shield. These are regions determined by these, and are determined to have a sufficient width in preparation for the movement of the light shield.

  On the other hand, in the prior art, the local detailed scan for the detailed scan narrow area Z is performed in one direction in the same scan order as the general outline scan. Therefore, when such a light shielding object is moving at high speed, the light shielding object may come off from the determined detailed scan narrow area Z before the position is detected by scanning.

  FIG. 7 is an explanatory diagram for explaining that when the light shield K is moving at high speed, the light shield is lost from the determined detailed scan narrow area Z. For convenience of explanation, the local detailed scan is performed by sequentially emitting the light emitting elements 911, 911,... 911 arranged along the X-axis direction one by one (in the order of (1) to (7) in the figure). The case where it performs is demonstrated to an example. That is, the local detailed scan is performed from the right side to the left side.

  In general, writing is performed at a speed range of about 1 [mm / msec] to 3 [mm / msec]. For example, if it takes about 20 msec for one local detailed scan, it will be performed during one local detailed scan. The shade K is expected to move up to about 60 mm.

  Further, since the light shield K continues to move even when the next local detail scan is started, if the moving direction of the light shield K and the execution direction of the local detailed scan are the same, the light shield Since the light shield K moves by an amount corresponding to the time until K is captured, it may come out of the determined detailed scan narrow area Z, and there may be a problem that it is determined that the light shield K has disappeared.

  Further, as a countermeasure against this, when the scan range is simply expanded, the time required for the local detailed scan increases accordingly, so the amount of movement of the light shield K also increases, deviating from the detailed scan narrow area Z, Alternatively, there is an adverse effect that the reaction speed when the pen-type input device is touched becomes slow. Also, when the scan range is set by predicting the movement position from the speed of the light shield K, if the position is greatly different from the prediction, the detailed scan narrow area Z is similarly deviated.

  For example, when the local detailed scan is sequentially performed on a plurality of light shields, the scan interval for each light shield is naturally longer, and thus the above-described problem becomes apparent.

  The electronic whiteboard 100 of the present invention is configured to cope with such a problem. FIG. 8 is an explanatory diagram for explaining a method of local detailed scanning in the electronic whiteboard 100 according to the embodiment of the present invention. For convenience of explanation, a local detailed scan on the X axis, that is, a case where the local detailed scan is performed by causing the light emitting elements 911, 911,... 911 arranged along the X axis direction to emit light will be described as an example. In the figure, (1) to (8) indicate the light emission order of the light emitting elements 911, 911,.

  In the electronic whiteboard 100 according to the embodiment of the present invention, the local detailed scan so as to be sandwiched from both ends of the range in the X-axis direction (hereinafter referred to as the corresponding X-axis range) corresponding to the determined detailed scan narrow area Z. I do. In other words, light is emitted from one end (for example, the left end in the figure) and the other end (for example, the right end in the figure) of the detailed scan narrow area Z toward the center of the detailed scan narrow area Z (corresponding X axis range). A local detailed scan is performed by sequentially emitting light from the elements 911, 911,. More specifically, local detailed scanning is alternately performed on one end side from the center of the corresponding X-axis range to the one end and on the other end side from the center of the corresponding X-axis range to the other end. That is, the local detailed scan is performed by causing the light emitting elements 911, 911,... 911 to emit light in the order of (1) to (8) in FIG.

  The detailed scan narrow area Z is determined by the CPU 11 within a range in which the local detailed scan is completed within a time range in which the up / down of the position of the light shield K can be completely grasped, and the range in which the light shield K moves during the local detailed scan. It is determined by the width that can be covered.

  By performing the local detailed scan in this manner, even if the light shielding object K moves at a high speed, the possibility that the light shielding object K disappears from the determined detailed scan narrow area Z is reduced. it can. That is, in the electronic whiteboard 100 of the present invention, the light emitting elements 911, 911,... Alternately with respect to one end side and the other end side of the fine scan narrow area Z toward the center of the fine scan narrow area Z. Since the local detailed scan is performed by emitting light 911, the position (contact point) of the light shielding object K can be detected regardless of the moving direction even if the light shielding object K has a high moving speed.

  In addition, when the position of the light shielding object K in the detailed scan narrow area Z is detected by the local detailed scan, the detailed scan narrow area Z is newly determined based on the center coordinates of the detected position, and the local scan again. A detailed scan is performed. This is repeated every time the position of the shade K is detected by the local detailed scan.

  On the other hand, if the position of the light shield K cannot be detected within the determined detailed scan narrow area Z, the whole outline scan is returned to and the light shield K (or from the entire area on the display screen 101 of the display unit 100A). The position of the new light shielding object) is detected.

  In the electronic whiteboard 100 of the present invention, light emitting elements 911, 911,... 911 alternately from both ends of the fine scan narrow area Z (left and right in FIG. 8) toward the center of the fine scan narrow area Z. Since the local detailed scan is performed by emitting light, the local detailed scan ends at the center of the detailed scan narrow area Z. Therefore, for example, when the light shield is present in the center of the detailed scan narrow area Z, it can be recognized as if there are two light shields by performing light shield on both the left and right sides of the light shield. In such a case, when light is shielded even in the center of the detailed scan narrow area Z, it can be determined that the object is one point connected in the center.

  However, when detecting the position of the light shielding object by actual local detailed scanning, the light emitting elements 911, 911,... 911 arranged along two directions, for example, the X-axis direction and the Y-axis direction, are used. A local detailed scan is performed by irradiating infrared light in a direction orthogonal to the X axis and in a direction orthogonal to the Y axis. Hereinafter, a local detailed scan in the X-axis direction is referred to as an X-axis local detailed scan, and a local detailed scan in the Y-axis direction is referred to as a Y-axis local detailed scan.

  FIG. 9 is an explanatory diagram for explaining the local detailed scan actually performed in the electronic whiteboard 100 according to the embodiment of the present invention. In the figure, I to VIII indicate the light emission order of the light emitting elements 911, 911,.

  When detecting the position (coordinates) of the light shielding object K by an actual local detailed scan, it is necessary to perform both the X-axis local detailed scan in the X-axis direction and the Y-axis local detailed scan in the Y-axis direction. . Therefore, in the electronic whiteboard 100 of the present invention, in each of the X-axis local detailed scan and the Y-axis local detailed scan, ranges in the X-axis direction and the Y-axis direction corresponding to the detailed scan narrow area Z (hereinafter, corresponding to each) The local detail scan is alternately performed so as to be sandwiched from both ends of the X-axis range and the corresponding Y-axis range). In other words, from one end (for example, the left end in the drawing) and the other end (for example, the right end in the drawing) to the center of the corresponding X-axis range, and one end (for example, the upper end in the drawing) in the corresponding Y-axis range. And the local detailed scan is performed by sequentially emitting the light emitting elements 911, 911,... 911 from the other end (for example, the lower end in the drawing) toward the center of the corresponding Y-axis range. At this time, the X-axis local detailed scan and the Y-axis local detailed scan are alternately performed.

  That is, in the electronic whiteboard 100 of the present invention, as shown in FIG. 9, the light emitting elements 911, 911,... 911 are caused to emit light in the order of I, III, II, IV, V, VII, VI, and VIII. Thus, the actual local detailed scan (X-axis local detailed scan and Y-axis local detailed scan) is performed.

  In this way, by causing the light emitting elements 911, 911,... 911 to emit light from the outside of the detailed scan narrow area Z that is a rectangle toward the center, Regardless of the moving direction, the position (contact point) of the light shield K can be detected.

  Note that the order is not limited to the above as long as the light emitting elements 911, 911,... 911 emit light from the outside of the detailed scan narrow area Z toward the center. Either the X-axis local detailed scan or the Y-axis local detailed scan may be started for the first time. Hereinafter, other examples of the order in which the light emitting elements 911, 911,.

<Example 1> I, IV, II, III, V, VIII, VI, VII
<Example 2> II, IV, I, III, VI, VIII, V, VII
<Example 3> II, III, I, IV, VI, VII, V, VIII
<Example 4> III, I, IV, II, VII, V, VIII, VI
<Example 5> III, II, IV, I, VII, VI, VIII, V
<Example 6> IV, I, III, II, VIII, V, VII, VI
<Example 7> IV, II, III, I, VIII, VI, VII, V
<Example 8> I, II, III, IV, V, VI, VII, VIII
<Example 9> II, I, III, IV, VI, V, VII, VIII
<Example 10> I, II, IV, III, V, VI, VIII, VII
<Example 11> II, I, IV, III, VI, V, VIII, VII

  FIG. 10 is a flowchart for explaining the local detailed scan of the detailed scan narrow area Z performed in the electronic whiteboard 100 according to the embodiment of the present invention. For convenience of explanation, it is assumed that the user draws on the display screen 101 of the display unit 100A using a pen-type input device (not shown). For example, when the tip of the pen-type input device comes into contact with the display screen 101, the light is blocked. Is detected.

  First, the scanning unit 9 of the touch panel 100B performs an overall schematic scan on the entire area on the display screen 101 of the display unit 100A (step S101), and detects a light shielding object (coordinates) on the display screen 101.

  At this time, the first detection unit 14 determines whether or not there is a light shielding object on the display screen 101 based on the intensity signal related to the result of the overall outline scan acquired from the scanning unit 9 (step S102).

  When the 1st detection part 14 determines with there being no light-shielding object on the display screen 101 (step S102: NO), a process returns to step S101. On the other hand, when the first detection unit 14 determines that there is a light shielding object on the display screen 101 (step S102: YES), for example, when there are one or more light shielding objects, the CPU 11 determines that each of the light shielding objects is as described above. A detailed scan narrow area including the position of the light shielding object is determined for each light shielding object (step S103).

  At this time, the scanning unit 9 of the touch panel 100B performs a local detailed scan for each determined detailed scan narrow area (step S104). As described above, the local detailed scan by the scanning unit 9 is performed from one end and the other end in the corresponding X-axis range of the detailed scan narrow area toward the center, and from one end and the other end in the corresponding Y-axis range to the center. ... 911 sequentially emit light, and the X-axis local detailed scan and the Y-axis local detailed scan are alternately performed. At this time, the second detection unit 15 detects the coordinates for each light shielding object based on the intensity signal related to the result of the local detailed scan acquired from the scanning unit 9.

  Next, the CPU 11 determines whether or not a light shielding object has been detected based on the detection result by the second detection unit 15 (step S105). If the CPU 11 determines that no light shielding object has been detected in such a local detailed scan (step S105: NO), the process returns to step S101.

  On the other hand, if the CPU 11 determines that a light shielding object has been detected in such a local detailed scan (step S105: YES), the CPU 11 determines whether or not the local detailed scan for the detailed scan narrow region has ended (step S106). . That is, in the electronic whiteboard 100 according to the embodiment of the present invention, the determined detailed scan narrow area is scanned to the end even if a light shielding object is detected during the local detailed scan.

  If the CPU 11 determines that the local detailed scan for the detailed scan narrow area has not been completed (step S106: NO), the process returns to step S104.

  On the other hand, when the CPU 11 determines that the local detailed scan for the detailed scan narrow area has been completed (step S106: YES), the CPU 11 determines continuity for the light shielding object detected in the local detailed scan (step S106: YES). Step S107).

  Hereinafter, the determination of continuity by the CPU 11 will be described in detail. For convenience of explanation, the case of X-axis local detailed scanning will be described as an example with reference to FIG.

  8 in FIG. 8 from one end (for example, the left end in the figure) and the other end (for example, the right end in the figure) of the detailed scan narrow area Z toward the center of the detailed scan narrow area Z (corresponding X axis range). When the light emitting elements 911, 911,... 911 are caused to emit light in the order of 1) to (8), light shielding is performed on both the left and right sides of the light shielding object K. It is recognized as if the light shield K exists. Therefore, in the electronic whiteboard 100 according to the embodiment of the present invention, scanning is continued to the center of the detailed scan narrow area Z even if light shielding by the light shield K is performed during the local detailed scanning. Based on the result of the local detailed scan, if the light shielding is continued even in the center of the detailed scan narrow area Z, the CPU 11 determines that the two light shielding objects K are the same, and the detailed scan narrow area Z When the light is not shielded in the center, the CPU 11 determines that there are two light shields K.

  Next, the second detection unit 15 detects the coordinates of the light shielding object based on the result of the local detailed scan and the determination result in step S107 (step S108). The coordinates of the detected light shielding object are stored by the light shielding object management unit 13. Thereafter, for example, a drawing process is performed based on the detected coordinates.

  For example, a tact switch (not shown) is attached to the pen-type input device, and the CPU 11 monitors a signal from the tact switch to determine whether an end instruction has been received from the user ( Step S109).

  If the CPU 11 determines that an end instruction has not been received from the user (step S109: NO), the process returns to step S103 to determine a new detailed scan narrow area of the light-shielding object after movement. On the other hand, if the CPU 11 determines that an end instruction has been received from the user (step S109: YES), the process ends.

  The present invention is not limited to the above description. 911 (hereinafter referred to as the X-axis side light-emitting element) arranged along the X-axis direction and the light-emitting elements 911, 911, arranged along the Y-axis direction. ... 911 (hereinafter referred to as the Y-axis side light emitting element) can emit light together, and so-called simultaneous scanning is also applicable. Hereinafter, for convenience of explanation, a light receiving element that receives light from the X axis side light emitting element is referred to as an X axis side light receiving element, and a light receiving element that receives light from the Y axis side light emitting element is referred to as a Y axis side light receiving element.

  Even in the case of the simultaneous scanning, the light of the X-axis side light emitting element is usually detected by the opposed X-axis side light receiving element arranged in parallel. However, in the local detailed scan, for example, the X-axis side light emitting element ( When the position of the Y-axis side light-emitting element and the Y-axis side light-receiving element (X-axis side light-receiving element) is close, the light from the X-axis side light-emitting element (Y-axis side light-emitting element) approaches (X-axis side light receiving element) may be detected, and this unexpected light is called crosstalk light.

  FIG. 11 is an explanatory diagram for explaining a portion where the light receiving element is affected by the crosstalk light, and FIG. 12 is an explanatory diagram for explaining a portion where the light receiving element is not affected by the crosstalk light.

  When the X-axis side light-emitting element and the Y-axis side light-emitting element emit light at the same time, the cross-talk light input to the light-receiving element other than the assumed opposite light-emitting element is shown in FIG. As shown in FIG. For this reason, it is desirable to perform scanning separately in the X direction and the Y direction. However, in the present invention, even if the X-axis side light-emitting element and the Y-axis side light-emitting element emit light at the same time on the display screen 101, as shown in FIG. It is possible to simultaneously emit light at two or more locations by differentiating the wavelengths of the X-axis side light-emitting element and the Y-axis side light-emitting element.

  By realizing simultaneous light emission and scanning at two or more locations, the scanning speed can be greatly improved, and as a result, merits such as improved followability and improved reaction speed can be obtained. Also, when two or more simultaneous scans are possible, as described above, the local detailed scan is narrowed from the outside of the determined detailed scan narrow area toward the center, thereby effectively moving the moving light shielding object. Detection is possible.

  In addition, the coordinate management unit 12, the light shielding unit management unit 13, the first detection unit 14, and the second detection unit 15 described above may be configured by hardware logic, or by the CPU 11 executing a predetermined program. It may be constructed in software.

  For example, the local detailed scanning method may be recorded on a computer-readable recording medium that records a program to be executed by a computer. As a result, it is possible to provide a portable recording medium on which the program code (execution format program, intermediate code program, source program) for performing the processing is recorded.

  In the present embodiment, since the processing is performed by the microcomputer, the ROM 2 shown in FIG. 2 may be the recording medium of the present invention. In addition, a program reading device may be provided as an external storage device (not shown), and the program medium may be read by being inserted into the program reading device.

  In any case, the stored program may be configured to be accessed and executed by the microprocessor, or in any case, the program code is read and the read program code is stored in the microcomputer. It may be downloaded to a program storage area (not shown) and the program may be executed. It is assumed that this download program is stored in the main device in advance.

  Here, the program medium is a recording medium configured to be separable from the main body, such as a magnetic tape, a tape system such as a cassette tape, a magnetic disk such as a flexible disk or a hard disk, or a CD-ROM / MO / MD / DVD. Semiconductors such as optical discs, IC cards (including memory cards) / optical cards, etc., mask ROM, EPROM (Erasable Programmable Read Only Memory), EEPROM (Electrically Erasable Programmable Read Only Memory), flash ROM, etc. It may be a medium that carries a fixed program code including a memory.

  Further, the present invention is not limited to the above description, and only one of the X-axis local detailed scan and the Y-axis local detailed scan may be performed.

In the present invention, the contacted surface 101 whose position on the surface is specified in the XY coordinate system, and light is irradiated along the contacted surface 101 in a direction orthogonal to the X axis and a direction orthogonal to the Y axis. And a scanning unit 9 that performs scanning, and is detected by a touch panel device 100 that detects the position of one or more light shielding objects K on the contacted surface 101 in an XY coordinate system based on the scanning result. An area determination unit 11 that determines a predetermined area Z on the XY coordinate system including a position for each light shielding object is provided, and the scanning unit 9 performs an X-axis range and a Y-axis range corresponding to the area Z. The rescan is performed from both ends of each range toward the center.
According to the present invention, even a light-shielding object that moves at high speed can be detected without losing its position when the light-shielding object moves out of the region.
In the present invention, at the time of the rescanning, the scanning unit 9 is configured to alternately scan one end side from the center to one end and the other end side from the center to the other end. It is characterized by being.
According to the present invention, even if it is not a complicated configuration in which scanning is simultaneously performed on one end side and the other end side, a light-blocking object that moves at high speed can be detected without losing its position by moving out of the region.
In the present invention, at the time of the re-scanning, the scanning unit 9 is configured to alternately scan the X-axis range and the Y-axis range.
According to the present invention, even if it is not a complicated configuration in which scanning is simultaneously performed on the X-axis side and the Y-axis side, a light-blocking object that moves at high speed can be detected without losing its position by moving out of the region. .

9 Scanning section 11 CPU (area determining means)
15 2nd detection part 100 Touch panel apparatus 100A Display part 100B Touch panel 101 Display screen (contacted surface)
K shader Z detailed scan narrow area

Claims (3)

A contacted surface whose position on the surface is specified in an XY coordinate system, and a plurality of light emitting elements that irradiate light in a direction orthogonal to the X axis and a direction orthogonal to the Y axis along the contacted surface ; A plurality of light receiving elements arranged to face each light emitting element; and a scanning unit that scans by driving the light emitting elements and the light receiving elements, and sequentially drives the plurality of light emitting elements and the plurality of light receiving elements. In the touch panel device that detects the position of one or more light-shielding objects on the contacted surface in another detection process when the light-shielding object is detected in one detection process of detecting the light-shielding object,
In the other detection processing, comprising a region determining means for determining a predetermined region on the XY coordinate system including the detected position for each light shielding object,
The scanning unit is configured to alternately drive light emitting elements and light receiving elements corresponding to the X axis range and the Y axis range corresponding to the region from both ends of the range toward the center. There is a touch panel device. In the other detection process , the scanning unit alternately and alternately corresponds to one end side from the center to one end and the other end side from the center to the other end in each range , and The touch panel device according to claim 1, wherein the touch panel device is configured to drive the light receiving element . In the other detection processing , the scanning unit is configured to alternately drive light emitting elements and light receiving elements corresponding to the X axis range and the Y axis range. The touch panel device according to claim 1 or 2.

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