JP2012212240A - Touch panel system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a touch panel system capable of allowing a user to make a desired input more smoothly.SOLUTION: A first detection area 11 is set on the surface of a detection surface 6p corresponding to an image each of a plurality of operation marks 20 displayed on a display surface 5p, and a second detection area 12 is set in a three-dimensional area from the detection surface 6p to a predetermined detection distance L. An image corresponding to a selection candidate mark 21 in which it is detected that a detection object is present in the second detection area 12 is enlarged and displayed, and the first detection area is set as a first detection area 13 enlarged according to the image of an enlarged selection candidate mark. The second detection area 12 as an enlarged second detection area 14 is coincident with the first detection area 13 enlarged on the detection surface 6p and is set such that the shape of a cross section in parallel with the detection surface 6p decreases as a distance from the detection surface 6p increases.

Description

  The present invention relates to a touch panel system that includes a display surface that displays a plurality of operation marks as images, and a sensor that detects at least the approach of a detection target to a detection surface that is set to cover the display surface.

  In various devices such as a digital camera, a portable device, and a vehicle navigation device, a touch panel that serves as an operation unit that serves as a display screen and receives a user's instruction input is widely used. In such a touch panel, operation buttons and operation switches as operation marks are displayed as images on the display screen. Then, an input to the operation button or the operation switch is performed by bringing a user's finger or the like close to or touching the operation mark. Many operation marks may be displayed on the display screen. Especially when character keys for character input are displayed, the space between the character keys is narrowed, and the characters different from the desired characters are displayed. A key may be entered.

  In view of the above problems, Japanese Patent Application Laid-Open No. 7-229751 (Patent Document 1) discloses an information input display device that enlarges and displays only an operation mark selected by a user's selection operation (No. 1). 5-7, 48 paragraphs, FIG. 10 etc.). Japanese Patent Application Laid-Open No. 2006-103358 (Patent Document 2) includes an infrared sensor having a detection area that covers the touch panel, and displays an enlarged display of an operation mark expected to be directed by a user's finger or the like. A vehicle information display device is disclosed (paragraphs 42-47, 71-73, FIGS. 5, 6, 12-17, etc.). Further, in Japanese Patent Application Laid-Open No. 2005-275576 (Patent Document 3), when a user touches the vicinity of an operation mark, the operation mark located near the touched position is more than the other operation marks. An enlarged touch panel is disclosed (32nd, 38th, 41st to 43rd paragraphs, FIGS. 6-8).

  Since only the selected operation mark is enlarged in the apparatus of Patent Document 1, even if the operation mark is hidden by a user's finger or the like during operation, it is easily confirmed whether the operation mark is selected. be able to. Even when a different operation mark is selected, the operation mark is enlarged and displayed, so that the user can easily find an erroneous input. However, since it is an enlarged display after selection by the user, the operability itself at the time of selection is not improved. Since the apparatus of Patent Document 2 requires an additional sensor called an infrared sensor, there is a possibility that the scale of the apparatus increases and the manufacturing cost increases. In the device of Patent Document 3, it is necessary to perform a touch operation outside the frame of the operation mark in order to enlarge the operation mark, and when a character interval, that is, a region outside the frame is narrow, using a keyboard for character input, This touch operation itself is not easy. In addition, once an operation mark has been enlarged, the enlargement is canceled and does not return to its original size unless there is an input to any of the operation marks or after a predetermined non-input time has elapsed. . Accordingly, if the desired operation mark is not enlarged and displayed, it may take time to input.

JP-A-229751 JP 2006-103358 A JP 2005-275576 A

  In view of the above background, it is desired to provide a touch panel system that allows a user to perform desired input more smoothly.

In view of the above problems, the characteristic configuration of the touch panel system according to the present invention is as follows.
A touch panel system comprising: a display surface that displays a plurality of operation marks as images; and a sensor that detects at least the approach of a detection target to a detection surface set to cover the display surface,
A display control unit for displaying the operation mark as an image on the display surface;
Based on the detection result of the sensor, when one of the detection objects reaches the detection surface, the one of the plurality of operation marks according to the position of the detection object on the surface of the detection surface. A first detector for detecting that one is selected;
A second detection unit that detects the presence of the detection object within a predetermined detection distance from the detection surface based on a detection result of the sensor;
The first detection area which is a detection area of the first detection unit is set on the surface of the detection surface corresponding to each image of the plurality of operation marks displayed on the display surface,
The second detection area, which is a detection area of the second detection unit, corresponds to each image of the plurality of operation marks displayed on the display surface, from the detection surface to the predetermined detection distance. Set to a 3D area,
When it is detected that the detection target exists in the second detection area corresponding to any of the plurality of operation marks, the display control unit detects the detection target. An image of the selection candidate mark that is the operation mark corresponding to the second detection area is enlarged and displayed as compared with the image of the other operation mark,
The first detection unit sets the first detection area corresponding to the selection candidate mark according to the enlarged image of the selection candidate mark,
The second detection unit matches the second detection area corresponding to the selection candidate mark with the first detection area set according to the image of the selection candidate mark on the surface of the detection surface. And setting so that the cross-sectional shape parallel to the detection surface is reduced as the distance from the detection surface increases.

  According to this characteristic configuration, when the second detection unit detects that a detection target object such as a user's fingertip or a stylus pen exists in the second detection area, the operation mark corresponding to the second detection area is displayed. The image is enlarged, and the first detection area corresponding to the operation mark is also enlarged. That is, when the detection target is in the vicinity of the first detection unit, the image of the operation mark and the first detection area corresponding to the image are enlarged, so that the user can afford to enlarge the operation mark. The object to be detected can be brought close to or in contact with the image. As a result, even if the image of the operation mark is small and the possibility of causing an erroneous operation on the adjacent operation mark is high, it is possible to operate the desired operation mark with high accuracy and efficiency. Become. Furthermore, among the second detection areas formed in the three-dimensional area, the second detection area corresponding to the enlarged first detection area is reduced in shape parallel to the detection surface as the distance from the detection surface increases. For example, it is formed in a cone shape whose top is sheared. Therefore, the further away from the detection surface, the easier it is to move the detection target to the second detection area of another operation mark adjacent to the selection candidate mark. That is, even when the selection candidate mark that is not the desired operation mark is displayed in an enlarged manner, the detection target is easily moved to the second detection area of the adjacent operation mark at a position away from the detection surface. be able to. And the operation mark corresponding to the 2nd detection area | region of a moving destination can be rapidly made into a new selection candidate mark. As a result, the image of the new selection candidate mark is enlarged, and the first detection area and the second detection area are enlarged accordingly. Thus, according to this characteristic configuration, a touch panel system that allows a user to perform desired input more smoothly is realized.

  By the way, the first detection area is set under the same condition according to the image of each operation mark displayed on the display surface without being enlarged in a state where the selection candidate mark is not selected. Similarly, in a state where the selection candidate mark has not been selected, it is preferable that the second detection area is also set under the same conditions for the image of each operation mark (and the first detection area). In addition, when there is a selection candidate mark, it is preferable that the second detection region is set under the same conditions in terms of a candidate for the next selection candidate mark for an operation mark other than the selection candidate mark. . That is, it is preferable that the second detection area corresponding to the operation mark that is not the selection candidate mark is set under the same conditions corresponding to the first detection area. As one form, the second detection unit of the touch panel system according to the present invention is configured such that the second detection region corresponding to the operation mark that is not the selection candidate mark is moved from the detection surface to the detection distance. It is preferable that the first detection area is set to a three-dimensional area formed by a translated locus.

  As described above, the operation mark becomes a selection candidate mark according to the presence or absence of the detection target in the second detection area, and the first detection area and the second detection area corresponding to the selection candidate mark are selection candidates. Enlarged compared to before the mark. However, when the detection object goes out of the second detection area corresponding to the selected candidate mark, the selection candidate mark returns to the general operation mark, and the enlarged first detection area. And the 2nd detection field also returns to the size before expansion. If the positions of the first detection area and the second detection area fluctuate before and after the enlargement, the setting of the detection area when the selection candidate mark is switched is not stable. In addition, such enlargement is particularly required because there are many input candidates such as character keys, so that the size of each operation mark on the screen is reduced, and an adjacent operation mark is selected. This is a case where there is a high possibility that In this case, since the possibility that the selection candidate mark is frequently switched increases, it is preferable that the switching is smooth. When the position of the detection area is held before and after enlargement, the detection area of the operation mark adjacent to the selection candidate mark that is the operation mark to be enlarged overlaps the detection area of the selection candidate mark. May occur. In this case, priority is given to the detection area of the selection candidate mark that is to be enlarged, and the detection area of the operation mark adjacent to it is reduced by the area that overlaps the detection area. It is preferable that the effect obtained can be enjoyed to the maximum.

  In view of such a point of view, the touch panel system according to the present invention is preferably configured as a first detection unit and a second detection unit as described below. That is, the first detection unit positions the first detection area of the operation mark adjacent to the selection candidate mark before and after the expansion of the first detection area corresponding to the expansion of the selection candidate mark. Is preferably set while excluding an area overlapping with the first detection area corresponding to the enlarged selection candidate mark. The second detection unit positions the second detection area of the operation mark adjacent to the selection candidate mark before and after the expansion of the second detection area corresponding to the expansion of the selection candidate mark. Is preferably set while excluding an area overlapping with the second detection area corresponding to the enlarged selection candidate mark.

  Here, if the first detection area corresponding to the selection candidate mark is set to match the outline of the image of the selection candidate mark on the display surface, the user refers to the image on the display surface. Smooth operation is possible. On the other hand, the second detection area corresponding to the selection candidate mark coincides with the first detection area set according to the image of the selection candidate mark on the surface of the detection surface, and becomes parallel to the detection surface as the distance from the detection surface increases. The cross-sectional shape is set to be reduced. At this time, if the second detection region is set as a three-dimensional region in which the centroids of all cross sections parallel to the detection surface are positioned on one vertical line with respect to the detection surface, the position of the invisible second detection region It is easy for the user to grasp and operability is also good. In addition, when the cross section of the second detection area parallel to the detection surface is reduced while maintaining the similar shape of the first detection area, the user can easily grasp the shape of the invisible second detection area, and the operation is good. Can provide sex. Thus, as one aspect, in the touch panel system according to the present invention, the first detection area corresponding to the selection candidate mark matches the outer shape of the image of the selection candidate mark on the display surface. As the second detection area corresponding to the selected candidate mark moves away from the detection surface, the cross section parallel to the detection surface is reduced while maintaining the similar shape of the first detection area. In addition, it is preferable that the centroids of all cross sections parallel to the detection surface are set so as to be positioned on one vertical line with respect to the detection surface.

Block diagram schematically showing an example of the configuration of the touch panel system Explanatory diagram showing the principle of detection by capacitance Explanatory diagram showing the relationship between operation marks and coordinate detection Waveform diagram showing an example of capacitance around the electrode The figure which shows an example of a detection field by a sectional view A perspective view showing an example of the second detection region A perspective view showing an example of an eccentric second detection region Flow chart showing an example of a detection procedure by the touch panel system The figure which shows an example of the display and detection area which are expanded by planar view and sectional view The perspective view which shows an example of the display and detection area which are expanded The figure which shows the other example of the display and detection area which are expanded by planar view and sectional view The figure which shows the structural example of a surface type touch panel typically The figure which shows the structural example of a projection type touch panel typically

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Various types of touch panels as pointing devices, such as a resistive film type and a capacitance type, have been proposed. Here, a capacitance type will be described as an example. As shown in FIGS. 12 and 13, two types of capacitive touch panels are known. One method is a surface capacitive type shown in FIG. 12, and the other method is a projected capacitive type shown in FIG.

  As shown in FIG. 12, the surface type includes, for example, a cover layer 81 provided on the surface, a conductive film 82 provided on a substrate layer such as a glass substrate 84, and electrodes 83 provided on the four corners. Is done. By applying a voltage to the electrode 83 via the drive circuit 85, a uniform electric field is formed on the entire touch panel 70. When the detection object 90 such as a user's fingertip touches or comes close to the screen (cover layer 81), the detection object 90 and the touch panel 70 and the detection object 90 are formed from the electrodes 83 at the four corners. A current flows through the capacitor 89. The position on the touch panel 70 (cover layer 81) is specified by calculating the ratio of the current flowing from the electrodes 83 at the four corners. In the case of the projection type, as shown in FIG. 13, an electrode layer 6a in which an electrode pattern is formed is provided on a substrate 6b such as a printed board or a transparent film. And the change of the electrostatic capacitance between the electrodes which a detection target object 90, such as a user's fingertip, approached to the protection panel 7a of the insulator material arrange | positioned on the electrode layer 6a is detected. The electrode closest to the detection target 90 is specified by the capacitance of each electrode of the electrode layer 6a, and therefore the position of the electrode is specified as the position (coordinates) on the touch panel 7.

  As described above, in any method, the position on the touch panel where the detection target approaches or contacts can be specified as a coordinate value on the touch panel. In the present embodiment, the touch panel system of the present invention will be described below using a projection touch panel as an example. FIG. 1 is a block diagram schematically showing one configuration example of a touch panel system 10 of the present invention. As illustrated in FIG. 1, the touch panel system 10 includes a display unit 5 such as a liquid crystal display device, a touch panel 7, and a circuit unit 9. The circuit unit 9 determines a capacitance detection unit 91 having an analog circuit as a core, a driver circuit 92 that drives a liquid crystal of the display unit 5, calculation of coordinates at which a detection target is detected, and contents to be displayed on the display unit 5. For example, a control operation unit 93 that performs an operation for this purpose. The capacitance detection unit 91 also functions as the sensor 6 in the touch panel 7 together with the electrode layer 6a formed of a transparent electrode such as ITO (indium tin oxide) and the transparent substrate 6b such as glass. In addition, the control arithmetic unit 93 is preferably configured using a logical arithmetic circuit such as a microcomputer or a DSP (digital signal processor).

  As shown in FIG. 1, the control calculation unit 93 includes the functional units of the display control unit 3, the first detection unit 1, and the second detection unit 2. The display control unit 3 is a functional unit that displays the operation mark 20 as an image on the display surface 5 p of the display unit 5. The display control unit 3 is preferably configured with an image processing circuit or the like as a core. Here, the operation mark 20 refers to the function when the touch panel 70 is operated by the detection target object and the operation input is transmitted from the touch panel system 10 to another control device or the like to realize a specific function. Is a mark represented on the display surface 5p so that can be easily perceived. For example, an operation button or operation switch drawn by an illustration or the like, a character key for character input, or the like. The operation mark 20 is also a mark for partitioning an operation area which is an area on the touch panel 70 for causing the above-described specific function when the touch panel 70 is operated by a detection target. This section may clearly define the operation area by a frame line indicating the outer edge of the mark or the operation area without displaying a clear frame line, etc. Also good. For example, the virtual boundary may be partitioned so that the user can perceive by arranging and displaying a plurality of marks. In particular, a character key or the like can be divided into operation areas even if there is no frame line clearly indicating the outer edge by arranging a plurality of characters and displaying them on the display surface 5p.

  The coordinate information of the operation mark 20 corresponding to the displayed image is transmitted to the first detection unit 1 and the second detection unit 2 described later. Based on the detection result of the sensor 6, the first detection unit 1 detects the position of the detection object on the detection surface 6 p (planar surface) when one detection object such as a user's fingertip reaches a detection surface 6 p described later. It is a functional unit that detects that one of the plurality of operation marks 20 is selected according to the coordinates). The second detection unit 2 is a functional unit that detects the presence of a detection target object within a predetermined detection distance L from the detection surface 6 p based on the detection result of the sensor 6. As will be described later, the second detection unit 2 can also detect the position (spatial coordinates) of a detection object existing within a predetermined detection distance L from the detection surface 6p.

  Here, with reference to FIG. 2, based on the sensor 6, the basic principle in which the 1st detection part 1 and the 2nd detection part 2 detect a detection target object is demonstrated easily. The left side of FIG. 2 shows a change in capacitance that occurs between one of the plurality of electrodes formed on the electrode layer 6a and the detection target. As shown in FIG. 2, the capacitance increases as the distance between the object to be detected and the touch panel 7, more precisely, the electrode layer 6a decreases. When this capacitance reaches the first threshold Th1, the first detection unit 1 detects that the detection target has reached the touch panel 7. That is, as shown in FIG. 2, the detection surface 6p is set at a position where the capacitance reaches the first threshold Th1, and when the detection object reaches the detection surface 6p, It is detected that the touch panel 7 has been reached. As apparent from FIG. 2, the detection surface 6p does not have to be set to coincide with the surface of the protective panel 7a of the touch panel 7, and may be set apart from the protective panel 7a. Naturally, the detection surface 6a may be set to coincide with the surface of the protective panel 7a.

  A virtual detection start surface 6q is set at a position away from the detection surface 6p by a predetermined detection distance L in a direction opposite to the touch panel 7. As shown in FIG. 2, the detection start surface 6q is set at a position where the capacitance between the detection target and the electrode layer 6a reaches a second threshold Th2 that is smaller than the first threshold Th1. ing. Based on the detection result of the sensor 6, the second detection unit 2 detects that a detection target exists within a predetermined detection distance L from the detection surface 6 p.

  FIG. 3 shows a plurality of operation marks 20 viewed from a direction perpendicular to the touch panel 7. Here, a character key is shown as an example of the operation mark 20. Reference numeral 6e in the figure simulates an electrode formed on the electrode layer 6a. In addition, among the electrodes 6e, the electrode 6t shown in black is, as shown in FIG. 4, the capacitance at the center of the electrode 6t, that is, the distribution peak of the capacitance around the electrode 6t has the first peak. The electrode 6e exceeding the threshold value Th1 is shown. In addition, among the electrodes 6e, the shaded electrode 6s has a capacitance at the center of the electrode 6s, that is, the peak of the distribution of the capacitance around the electrode 6s, as shown in FIG. The electrode 6e is smaller and does not exceed the first threshold value Th1. In the example illustrated in FIG. 3, the first detection unit 1 has the largest capacitance, and the electrode 6t whose value exceeds the first threshold Th1 is the electrode 6e corresponding to the position of the detection target. judge. Then, it is determined that the operation mark 20 (here, the letter key “G”) displayed at the coordinates of the electrode 6t is selected by the detection target.

  Thus, the touch panel system 10 includes at least a display surface 5p that displays a plurality of operation marks 20 as images, and a sensor that at least detects the approach of the detection object to the detection surface 6p set to cover the display surface 5p. 6. Specifically, the operation mark 20 is displayed as an image on the display surface 5 p by the display control unit 3. Further, the approach of the detection object detected by the sensor 6 is determined by the first detection unit 1 as described above, and corresponds to the position on the detection surface 6p when the detection object reaches the detection surface 6p. It is detected that the operation mark 20 to be selected is selected. In this embodiment, in addition to the 1st detection part 1, the 2nd detection part 2 is also provided and the touchscreen system 10 is comprised. As described above, the second detection unit 2 is configured to have a function of detecting the presence of the detection object within the predetermined detection distance L from the detection surface 6p. That is, the touch panel system 10 according to the present embodiment includes two detection units having different detection areas.

  Here, the first detection region 11 that is the detection region of the first detection unit 1 and the second detection region 12 that is the detection region of the second detection unit 2 will be described with reference to FIGS. As shown in FIG. 5, the first detection area 11 is set on the surface of the detection surface 6p corresponding to each image of the plurality of operation marks 20 displayed on the display surface 5p. As shown in FIGS. 5 and 6, the second detection area 12 corresponds to each image of the plurality of operation marks 20 displayed on the display surface 5 p and is opposite to the display surface 5 p from the detection surface 6 p. It is set in a three-dimensional region up to a predetermined detection distance L set in the direction (up to the detection start surface 6q). In this embodiment, the 1st detection part 1 sets the 1st detection area | region 11 on the surface of the detection surface 6p. Further, the second detection unit 2 sets the second detection region 12 in a three-dimensional region from the detection surface 6p to the detection start surface 6q.

  5 and 6 show an example in which the second detection region 12 is set in a three-dimensional region formed by a locus obtained by translating the first detection region 11 from the detection surface 6p to the detection distance L. 5 and 6 show an example in which the second detection region 12 is set so that the centroids of all cross sections parallel to the detection surface 6p are located on one vertical line with respect to the detection surface 6p. However, the present invention is not limited to this. For example, as shown in FIG. 7, the second detection region 12 is set such that a line (curved line is acceptable) connecting the center of gravity of each cross section is deviated from a vertical line with respect to the detection surface 6p. May be. For example, when the detection object is approaching from a substantially determined direction, the convenience may be improved by decentering the second detection region 12 in that direction. As an example, a touch panel may be mounted on a display device installed in the center of a console between a driver seat and a passenger seat of a vehicle. In this case, in order to facilitate the operation of the touch panel from the driver's seat, it is preferable to set the second detection region 12 eccentrically in the driver's seat direction.

  Hereinafter, the procedure for detecting the detection target object by the touch panel system 10 will be described with reference to the flowchart of FIG. When the touch panel system 10 does not detect the detection object in any of the first detection area 11 and the second detection area 12, the first detection area 11 and the second detection area 11 shown in FIGS. The detection area 12 is set and is on standby. The touch panel system 10 (second detection unit 2) first determines whether there is a detection target in the second detection area 12 (# 01). That is, it is determined whether or not there is a detection object in any of the set second detection areas 12 for the plurality of operation marks 20. In any case, when the detection target is not detected, the process waits as it is and repeats step # 01.

  When the presence of the detection target is detected in step # 01, that is, when the second detection unit 2 detects that the detection target exists in the second detection region 12, the second detection unit 2 detects the detection target. The spatial coordinates (three-dimensional coordinates) in which are present are calculated and acquired (# 02). As described above with reference to FIG. 3, the plane coordinates can be coordinates defined by the electrode 6e where the largest capacitance is detected. Further, the coordinates in the direction orthogonal to the display surface 5p and the detection surface 6p can be determined by the value of the capacitance of the electrode 6e used for defining the plane coordinates. That is, the coordinate in the direction orthogonal to the detection surface 6p and the capacitance have a correlation, and the distance between the detection target and the detection surface 6p and the capacitance are theoretically inversely proportional. Therefore, the second detection unit 2 can calculate the distance between the detection target and the detection surface 6p based on the capacitance value, and can calculate three-dimensional coordinates.

  The second detection unit 2 determines the operation mark 20 corresponding to the second detection region 12 including the spatial coordinates obtained in step # 02 (# 03). In other words, the second detection unit 2 determines the operation mark 20 corresponding to the second detection region 12 to which the spatial coordinates obtained in step # 02 belong as a selection candidate mark. Then, the second detection unit 2 transmits information on the selection candidate mark to the display control unit 3. As a result, the display control unit 3 displays the selected candidate mark in an enlarged manner as compared with the other operation marks 20 (# 04). Here, FIG. 9 to FIG. 11 are also used to explain in detail the enlarged display of the selection candidate mark and the change of the detection area associated with the enlarged display.

  For example, when a detection target exists in the second detection area 12 of the operation mark 20 indicating the alphabet “G” in FIG. 5, the operation mark 20 includes the selection candidate mark 21 as shown in FIG. 9. Become. Then, the image of the selection candidate mark 21 is enlarged by the display control unit 3 as compared with the other operation marks 20 (# 04). As described above, the first detection region 11 is set on the surface of the detection surface 6p corresponding to each image of the operation mark 20 displayed on the display surface 5p. Therefore, corresponding to the enlarged image of the selection candidate mark 21, the first detection area 11 is also an enlarged first detection area 13 that is enlarged as compared with the other first detection areas 11 (# 05).

  In addition, as described above, the second detection area 12 corresponds to each image of the operation mark 20 from the detection surface 6p to a predetermined detection distance L set in a direction opposite to the display surface 5p side. Are set in the three-dimensional region. Accordingly, the second detection area 12 also becomes an enlarged second detection area 14 that is enlarged compared to the other second detection areas 12 corresponding to the enlarged image of the selection candidate mark 21 (# 05). However, at this time, the enlarged second detection region 14 is set such that the cross-sectional shape parallel to the detection surface 6p is reduced as the distance from the detection surface 6p increases (see FIGS. 9 and 10). That is, the second detection unit 2 sets the second detection area 12 (enlarged second detection area 14) corresponding to the selection candidate mark 21 according to the image of the selection candidate mark 21 on the detection surface 6p. It is set so that the shape of the cross section that coincides with the first detection area 11 (enlarged first detection area 13) and is parallel to the detection surface 6p is reduced as the distance from the detection surface 6p increases.

  As described above, when the enlarged second detection region 14 is formed in a truncated cone shape (a truncated cone shape such as a truncated cone or a truncated pyramid) whose top is sheared, the detection target is detected at a position away from the detection surface 6p. It becomes easy to move the object to the second detection area 12 of the operation mark 20 adjacent to the selection candidate mark 21. That is, even when an undesired operation mark 20 is selected as the selection candidate mark 21, the detection object is easily moved to the second detection region 12 of the adjacent operation mark 20 at a position away from the detection surface 6p. Can be moved. As a result, the operation mark 20 corresponding to the second detection area 12 at the movement destination can be quickly set as a new selection candidate mark 21. Here, as one aspect, as shown in FIG. 11, at a position away from the detection surface 6p by a predetermined detection distance L, that is, the second detection region 12 (enlarged second detection region 14) of the selection candidate mark 21. In the detection start surface 6q), the enlarged second detection region 14 is preferably reduced so that the cross-sectional shape (for example, width M) parallel to the detection surface 6p is the same as the shape before enlargement. As the distance from the detection surface 6p increases, the second detection area 12 becomes closer to a state where the second detection area 12 is not enlarged. Therefore, the operability when the selection candidate mark 21 is reselected is good.

  As shown in FIG. 9 and the like, as the image of the selection candidate mark 21 is enlarged and displayed, at least a part of the image of the operation mark 20 adjacent to the selection candidate mark 21 and the enlarged selection are displayed. The image of the candidate mark 21 may overlap. Therefore, when the image of the selection candidate mark 21 is enlarged at a magnification that does not overlap the image of the selection candidate mark 21 that has been enlarged to all of the operation marks 20 adjacent to the selection candidate mark 21. Is preferred. Preferably, in order to ensure the visibility of the adjacent operation mark 20, the image of the selection candidate mark 21 is superimposed while leaving about 1/2 to 2/3 of the adjacent operation mark 20. It is good that the enlargement ratio is high.

  Further, when the enlarged image of the selection candidate mark 21 overlaps at least a part of the image of the adjacent operation mark 20, the area of the first detection region 11 of the operation mark 20 becomes narrow accordingly. At this time, it is preferable that the position of the first detection region 11 is held. That is, as one aspect, the first detection unit 1 uses the first detection area 11 of the operation mark 20 adjacent to the selection candidate mark 21 as the first detection area 11 corresponding to the enlargement of the selection candidate mark 21. It is preferable to set the position while maintaining the position before and after the enlargement, and exclude the area overlapping the first detection area 11 (enlarged first detection area 13) corresponding to the enlarged selection candidate mark 21. In other words, the first detection unit 1 sets the first detection area 11 of the operation mark 20 adjacent to the selection candidate mark 21 before and after the expansion of the first detection area 11 corresponding to the expansion of the selection candidate mark 21. Therefore, it is preferable to set the area excluding the area overlapping with the enlarged first detection area 13 and to set the outline position of the remaining area. If the selection candidate mark 21 is not appropriate for the user and the object to be detected is brought into contact with the adjacent operation mark 20 as it is, the operability is good if the previous position is held. Further, the calculation by the control calculation unit 93 such as the calculation of the coordinates of the corresponding operation mark 20 can be easily performed except for the overlapping area, and the calculation load can be reduced.

  Similarly, when the first detection area 11 becomes narrower, the second detection area 12 of the operation mark 20 that is adjacent to the selection candidate mark 21 and overlaps the enlarged image also becomes smaller. At this time, similarly to the first detection region 11, the second detection region 12 is preferably in a state where the position is held. That is, the second detection unit 2 positions the second detection area 12 of the operation mark 20 adjacent to the selection candidate mark 21 before and after the expansion of the second detection area 12 corresponding to the expansion of the selection candidate mark 21. Is set while excluding the area that overlaps the second detection area 12 (enlarged second detection area 14) corresponding to the enlarged selection candidate mark 21. In other words, the second detection unit 2 changes the second detection area 12 of the operation mark 20 adjacent to the selection candidate mark 21 before and after the expansion of the second detection area 12 corresponding to the expansion of the selection candidate mark 21. Thus, it is preferable to set the area excluding the area overlapping with the enlarged second detection area 14 and to set the outline position of the remaining area. That is, at least the position of the second detection area 12 is maintained before and after the enlargement, so that the selection candidate mark 21 is not appropriate for the user, and the user can make another operation mark 20 the selection candidate mark 21. The operability when moving a detection object such as a fingertip of the finger is good. Further, the calculation by the control calculation unit 93 such as the calculation of the coordinates of the corresponding operation mark 20 can be easily performed except for the overlapping area, and the calculation load can be reduced.

  Furthermore, as described above, the enlarged second detection region 14 is set in a truncated cone shape. Accordingly, at the position away from the detection surface 6p, the enlarged second detection area 14 and the second detection area 12 corresponding to the operation mark 20 adjacent to the selection candidate mark 21 may not overlap (for example, (See FIG. 11). In this case, the cross-sectional area of the second detection area 12 corresponding to the operation mark 20 adjacent to the selection candidate mark 21 and parallel to the detection surface 6p is the second detection area 12 (enlarged) corresponding to the selection candidate mark 21. It is possible to maintain the same cross-sectional area as before the second detection area 14) is enlarged. Therefore, when the selection candidate mark 21 is not appropriate for the user and the detection target object such as the user's fingertip is moved in order to make another operation mark 20 the selection candidate mark 21, the detection target object is detected. There is no need to move it greatly in the direction along the surface 6p, and the operability is good.

  Further, the first detection area 11 (enlarged first detection area 13) corresponding to the selection candidate mark 21 is preferably set so as to match the outer shape of the image of the selection candidate mark 21 on the display surface 5p. It is. The user can perform a smooth operation with reference to the image on the display surface 5p. On the other hand, in the second detection region 12 (enlarged second detection region 14) corresponding to the selection candidate mark 21, the centroids of all cross sections parallel to the detection surface 6p are located on one vertical line with respect to the detection surface 6p. When set as a three-dimensional region, the user can easily grasp the position of the invisible enlarged second detection region 14 and the operability is improved. Further, when the cross section of the enlarged second detection region 14 parallel to the detection surface 6p is reduced while maintaining the similar shape of the enlarged first detection region 13, the shape of the invisible enlarged second detection region 14 is also changed by the user. It is easy to grasp and can provide good operability.

  In step # 05 of FIG. 8, when the first detection area 11 and the second detection area 12 are changed to the enlarged first detection area 13 and the enlarged second detection area 14, respectively, the first detection area 11 ( It is determined whether or not the detection target has reached the enlarged first detection region 13) (# 06). If the detection target has not reached the enlarged first detection area 13, the process returns to step # 01, and steps # 01 to # 06 are repeated. During this time, when the detection object is present in the second detection area 12 (enlarged second detection area 14) of the same operation mark 20, the same operation mark 20 (selection direction mark 21) is enlarged and displayed. Accordingly, the enlarged first detection area 13 and the enlarged second detection area 14 are set accordingly. On the other hand, during this time, when the detection object moves to the second detection area 12 of another operation mark 20, a new selection candidate mark 21 is determined accordingly and corresponds to the new selection candidate mark 21. An enlarged first detection area 13 and an enlarged second detection area 14 are set.

  In step # 06, when it is determined that the detection target has reached the first detection region 11, as described above with reference to FIG. 3, the coordinates defined by the electrode 6e where the largest capacitance is detected. Are acquired as plane coordinates (# 07). Since the operation mark 20 can be specified by this coordinate, information indicating which operation mark 20 has been selected is determined by the detection target. This information is transmitted from the touch panel system 10 to another control device or the like, and control according to the contents of the operation mark 20 is performed. When the first detection unit 1 detects the operation mark 20, the selection candidate mark 21 is canceled and becomes a normal operation mark 20 (# 08). The display control unit 3 cancels the enlargement of the image of the operation mark 20 that was the selection candidate mark 21, and displays the operation mark 20 in a normal size (# 14). The first detection unit 1 and the second detection unit 2 correspond to the enlarged first detection region 13 and the enlarged second detection region 14 corresponding to the image of the operation mark 20 for which the enlarged display has been canceled, respectively. The detection area 11 and the second detection area 12 are changed (# 15).

  As described above, the touch panel system 20 according to the present invention in which the two detection areas, the first detection area 11 and the second detection area 12, are set, allows the user to perform desired input more smoothly. Become.

[Other Embodiments]
Hereinafter, other embodiments of the present invention will be described. Note that the configuration of each embodiment described below is not limited to being applied independently, and can be applied in combination with the configuration of other embodiments as long as no contradiction arises.

(1) In the above embodiment, as illustrated in FIGS. 5 to 7, the second detection unit 2 has the second detection area 12 corresponding to the operation mark 20 that is not the selection candidate mark 21. An example is shown in which a three-dimensional region is formed that is formed by a locus obtained by translating the first detection region 11 from the detection surface 6p to the detection distance L. However, the present invention is not limited to this. For example, as shown in FIG. 7, the second detection region 12 is set such that a line (curved line is acceptable) connecting the center of gravity of each cross section is deviated from a vertical line with respect to the detection surface 6p. In such a case, the second detection region 12 may be formed by a locus in which the first detection region 11 is moved so as to be orthogonal to the reference line extending in such an eccentric direction.

(2) In the above embodiment, the position of the first detection area 11 of the operation mark 20 adjacent to the selection candidate mark 21 is maintained before and after the expansion of the first detection area 11 corresponding to the selection candidate mark 21. The second detection area 12 of the operation mark 20 adjacent to the selection candidate mark 21 is set while maintaining the position before and after the expansion of the second detection area 12 corresponding to the selection candidate mark 21. An example is shown. However, without being limited to this configuration, the first detection area 11 and the second detection area 12 may be set by offsetting the position to the side not adjacent to the selection candidate mark 21. When a gap is provided between the operation marks 20, the amount by which the detection area of the operation mark 20 adjacent to the selection candidate mark 21 is reduced can be reduced. In this case, the first detection area 11 and the second detection area 12 corresponding to the operation mark 20 adjacent to the selection candidate mark 21 do not overlap with the enlarged first detection area 13 and the enlarged second detection area 14, respectively. May be offset, or may have an overlapping region even after being offset.

(3) In the above embodiment, the first detection area 11 (enlarged first detection area 13) corresponding to the selection candidate mark 21 matches the outer shape of the image of the selection candidate mark 21 on the display surface 5p. An example of setting is shown. However, the enlarged first detection region 13 does not necessarily need to be set in accordance with the outer shape of the image on the display surface 5p. Psychologically, since the user operates aiming at the center of the selection candidate mark 21, the enlarged first detection region 13 may be set in a range smaller than the enlarged image. Enlarging the image makes it easier to aim at the center of the image. Therefore, even in this case, the operability is improved. For example, as illustrated in FIG. 9 and FIG. 11, when a gap is provided between the selection candidate mark 21 and the mark 20 adjacent to the selected candidate mark 21, the first detection region is expanded up to the range of the gap. It may be set as 13. In this case, the first detection area 11 of the operation mark 20 adjacent to the selection candidate mark 21 is not narrower than the appearance (display on the display surface 5p). Therefore, the operability in the case of operating the adjacent operation mark 20 regardless of the enlarged display is ensured.

(4) In the above embodiment, as the second detection region 12 (enlarged second detection region 14) corresponding to the selection candidate mark 21 is separated from the detection surface 6p, the cross section parallel to the detection surface 6p is enlarged first. An example in which the detection area 13 is reduced while maintaining the similar shape is shown. However, the present invention is not limited to this, and does not prevent reduction in any shape. Moreover, in the said embodiment, the expansion 2nd detection area 14 showed the example set so that the gravity center of all the cross sections parallel to the detection surface 6p may be located on one perpendicular line with respect to the detection surface 6p. However, it does not prevent the enlarged second detection region 14 from being set eccentrically, for example, as in the second detection region 12 illustrated in FIG. In addition, when the enlarged second detection region 14 is set eccentrically, the enlarged first detection region 13 is moved as it moves away from the detection surface 6p while moving the enlarged first detection region 13 so as to be orthogonal to the reference line extending in the eccentric direction. The enlarged second detection region 14 may be formed by a trajectory that is reduced.

  The present invention is applied to a touch panel system that includes a display surface that displays a plurality of operation marks as images, and a sensor that detects at least the approach of a detection target to a detection surface that is set to cover the display surface. be able to. Further, the touch panel system of the present invention can be applied to a monitor device provided in a vehicle, a portable device such as a cash dispenser, a ticket vending machine, and a smartphone.

1: 1st detection part 2: 2nd detection part 3: Display control part 5p: Display surface 6: Sensor 6p: Detection surface 10: Touch panel system 11: 1st detection area 12: 2nd detection area 13: Enlarged 1st detection Area 14: Enlarged second detection area 20: Operation mark 21: Selection candidate mark 90: Detection object L: Detection distance

Claims (4)

A touch panel system comprising: a display surface that displays a plurality of operation marks as images; and a sensor that detects at least the approach of a detection target to a detection surface set to cover the display surface,
A display control unit for displaying the operation mark as an image on the display surface;
Based on the detection result of the sensor, when one of the detection objects reaches the detection surface, the one of the plurality of operation marks according to the position of the detection object on the surface of the detection surface. A first detector for detecting that one is selected;
A second detection unit that detects the presence of the detection object within a predetermined detection distance from the detection surface based on a detection result of the sensor;
The first detection area which is a detection area of the first detection unit is set on the surface of the detection surface corresponding to each image of the plurality of operation marks displayed on the display surface,
The second detection area, which is a detection area of the second detection unit, corresponds to 3 images from the detection surface to the predetermined detection distance corresponding to the images of the plurality of operation marks displayed on the display surface. Set to dimension area,
When it is detected that the detection target exists in the second detection area corresponding to any of the plurality of operation marks, the display control unit detects the detection target. An image of the selection candidate mark that is the operation mark corresponding to the second detection area is enlarged and displayed as compared with the image of the other operation mark,
The first detection unit sets the first detection area corresponding to the selection candidate mark according to the enlarged image of the selection candidate mark,
The second detection unit matches the second detection area corresponding to the selection candidate mark with the first detection area set according to the image of the selection candidate mark on the surface of the detection surface. The touch panel system is set so that the shape of the cross section parallel to the detection surface is reduced as the distance from the detection surface increases.   The second detection unit moves the second detection area corresponding to the operation mark that is not the selection candidate mark by a locus obtained by translating the first detection area from the detection surface to the detection distance. The touch panel system according to claim 1, wherein the touch panel system is set to a three-dimensional region to be formed. The first detection unit maintains the position of the first detection area of the operation mark adjacent to the selection candidate mark before and after the expansion of the first detection area corresponding to the expansion of the selection candidate mark. And setting except for an area overlapping with the first detection area corresponding to the enlarged selection candidate mark,
The second detection unit maintains the position of the second detection area of the operation mark adjacent to the selection candidate mark before and after the expansion of the second detection area corresponding to the expansion of the selection candidate mark. The touch panel system according to claim 1, wherein the touch panel system is set except for an area overlapping with the second detection area corresponding to the enlarged selection candidate mark. The first detection area corresponding to the selection candidate mark is set to match the outer shape on the display surface of the image of the selection candidate mark,
The second detection region corresponding to the selection candidate mark is reduced while the cross section parallel to the detection surface is kept similar to the first detection region as the distance from the detection surface is reduced, and the detection surface The touch panel system according to any one of claims 1 to 3, wherein the center of gravity of all cross sections parallel to each other is set on one vertical line with respect to the detection surface.

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