JP2011210083A - Display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display device with ease of operation.SOLUTION: The display device includes a control unit, which calculates respective arrangement points for displaying a plurality of input icons displayed on a display unit around a contact coordinate, which calculates distances from the plurality of input icons to the respective arrangement points, and which displays the input icons at arrangement points of a combination such that the distance from the input icons to the arrangement points is minimized. According to this structure, the travel distance of a table operator's visual line for searching an icon and the operation of the finger, hand or the like thereof for performing input operation can be reduced.

Description

  The present invention particularly relates to a display device including a touch panel.

  In recent years, instead of using an input means such as a keyboard for operating the display device, a display device having a touch panel for directly inputting data, operation instructions, and the like on the display screen has been used. In particular, in a display device having a touch panel used in a vehicle-mounted navigation device, an input operation displayed on the screen such as a route information display button or a peripheral facility search button is touched with a fingertip or the like, and an input operation is performed on the screen. By performing the process, a process of displaying route information, display of surrounding facilities, and the like is executed in accordance with each input instruction.

  An input icon is an operation screen of a personal computer or the like that represents the contents and object of processing with a small picture or figure. The user moves the mouse, moves the mouse cursor on the screen to the input icon, and operates by pressing a button.

  In the input operation on the touch panel 3, in Patent Document 1, a pop-up menu is displayed by touching an input icon displayed on the screen of the display device, and selection from an arbitrary menu object to another menu object in the pop-up menu is performed. Is disclosed. By this method, the operation of the selected input icon can be simplified.

JP 2005-196810 A

  However, the display device described in Patent Literature 1 requires time and effort to search for input icons arranged on the screen.

  In particular, when an operator driving a car operates the navigation display device, he / she looks for the input icon displayed for a limited time, such as when he / she wants to check detailed information on the map during the signal waiting time. The driver has to move his / her finger or hand to the input icon, which is a heavy burden on the driver.

  In view of the above problems, an object of the present invention is to provide a display device that can reduce the amount of movement of a line of sight when an operator searches for an input icon on a touch panel and can reduce the amount of movement of a finger or a hand. To do.

  In order to solve the above-described problem, the display device for an in-vehicle device according to the present invention calculates each arrangement point where a plurality of input icons displayed on the display unit are arranged around the contact coordinates, and each of the plurality of input icons displays each of the arrangement points. A control unit is provided that calculates the distance to the arrangement point and displays the input icon at a combination arrangement point that minimizes the distance from the input icon to the arrangement point.

According to the present invention, the operator of the display device can reduce the amount of movement of the line of sight for searching for an input icon and the operation of a finger, a hand, or the like that performs the input operation, so that the operability of the display device is improved.

1 is a block diagram of a display device according to an embodiment of the present invention. The flowchart which shows the display process of the display apparatus in one Embodiment of this invention. The figure explaining the contact coordinate on the display part of one Embodiment of this invention The figure explaining the input icon area | region and non-input icon on the display part of one Embodiment of this invention The figure explaining the distance of the contact coordinate of FIG. 3 and an input icon The figure explaining the position which moves the input icon of the same FIG. The figure explaining the method of specifying the input icon arrange | positioned in the position demonstrated in FIG. The figure explaining the locus | trajectory which moves the input icon specified in FIG. 7 to the circumference | surroundings of a contact coordinate The figure explaining the method of specifying the some layer displayed on the display part of one Embodiment of this invention The figure explaining the contact coordinates on the specified layer in FIG. The figure explaining that the input icon arrange | positioned on the display part of one Embodiment of this invention is arrange | positioned by a different magnitude | size. The figure explaining the method to change the input icon on the display part of one Embodiment of this invention to an appropriate size. The figure which shows the input icon arrange | positioned around the contact coordinate of one Embodiment of this invention The figure which shows the example for moving the input icon arrange | positioned around the contact coordinate of one Embodiment of this invention to the position where an operator is easy to operate The figure which shows a mode that the input icon arrange | positioned around the contact coordinate of one Embodiment of this invention rotates the periphery of a contact coordinate.

  Hereinafter, the display apparatus 1 used for the navigation apparatus in one Embodiment of this invention is demonstrated using drawing.

  FIG. 1 is a block diagram of a display device 1 according to an embodiment of the present invention.

  As shown in FIG. 1, the display device includes a display unit 2 that displays a map, an input icon, and the like, and a touch panel 3 that is arranged in an upper layer of the display unit 2 and corresponds to a detection unit that detects contact of an object. . Further, the display unit 2 is connected to the touch panel 3 and the display unit 2 and instructs the display unit 2 to move the input icon to the point where the object touches based on the display information of the display unit 2 and the contact information of the object detected by the touch panel. The control unit 4 is provided. And it is connected with the control part 4, and the memory | storage part 5 is provided with the positional information regarding the touch panel 3 and the display part 2, the function information of an input icon, etc.

  The display unit 2 uses a liquid crystal panel, an organic EL (Electro-Luminescence), a plasma display, or the like. The input icons displayed on the display unit 2 are arranged at the corners of the screen so as not to obstruct the map or video displayed on the screen, or are evenly arranged on the entire screen so that the input icons are easy to see. To do.

  The touch panel 3 uses a pressure detection method, a resistance film method, a capacitance method, an electromagnetic induction method, or the like. The operator touches the screen of the display unit 2 with a finger, a pen, or the like, thereby pressing the specific place where the finger or the like is touching the touch panel 3 arranged on the upper layer of the display unit 2, electric resistance, electric capacity. The energy of elastic waves changes. By detecting the amount of change, the contact coordinates (Xn, Yn) on the screen touched by a finger or the like are specified.

  The storage unit 5 reads and writes data to and from a nonvolatile storage medium such as an HDD. The storage unit 5 includes, in addition to function information such as input icon position information data indicating whether or not an input icon exists at an XY coordinate position on the screen of the display unit 2 and a program executed when each input icon is selected. The control unit 4 stores map data for route guidance and the like. The input icon position information data includes center coordinate information of all displayed input icons. The input icon includes a map enlargement / display button for displaying information related to the map displayed on the display unit 2, a route information display button, a peripheral facility search button, a music information playback button that can be played back by the navigation device, and a stop button. Fast forward button, rewind button, etc.

  The control unit 4 includes a CPU and a RAM, and is connected to the display unit 2, the touch panel 3, and the storage unit 5. When detecting that the operator's finger or the like has touched the touch panel 3, the control unit 4 outputs a command to the display unit 2 so as to move the position of the input icon arranged on the display unit 2 close to the finger. .

  Hereinafter, the process which the control part 4 of the display apparatus 1 which is one Embodiment of this invention performs is demonstrated using figures.

  FIG. 2 is a flowchart illustrating the display process of the display device 1 according to the embodiment of the present invention.

  First, as shown in step S100, the touch panel 3 arranged on the upper layer of the display unit 2 is touched with a finger or the like. At this time, as shown in FIG. 3, the touch panel 3 detects the contact coordinates (Xn, Yn) on the display unit 2 that overlap the contact point of the touch panel 3 touched by the finger.

  Then, as shown in step S110, the control unit 4 determines whether or not an input icon exists on the display unit 2.

  If “YES” in step S110, that is, if an input icon is present on the display unit 2 as shown in FIG. 3, the display unit 2 overlaps with the contact point touched by the operator with a finger or the like, as shown in step S120. It is determined whether the upper contact coordinates (Xn, Yn) are an icon region. The input icon represents the contents and object of processing on the operation screen with a small picture or figure, and therefore has an area corresponding to the area corresponding to the small picture or figure on the screen. This area is called an icon area.

If “YES” in step S120, that is, if the contact coordinates (Xn, Yn) are not input icons as shown in FIG. Judge whether it has moved for 2 seconds. That is, the intention of the operator who performs the next process is not to move the finger for 2 seconds. The time setting of 2 seconds can be changed.
If “YES” in the step S130, that is, if it is determined that the contact coordinates are not moved, the control unit 4 determines the center coordinates (An, Bn, Cn, Dn) of the input icon as shown in a step S140. Is read from the storage unit. As shown in FIG. 5, the center coordinates when the input icons on the screen are A to D are (XA, YA) to (XD, YD).
And as shown to step S150, the control part 4 calculates the distance of a contact coordinate from the center coordinate of an input icon by a trigonometric function, and makes distance between this contact point and the center point of an input icon LA-LD, respectively. .

Hereinafter, as shown in step S <b> 160, the control unit 4 determines three input icons to be arranged around the contact coordinates in the order closer to the contact coordinates. As shown in FIG. 5, an input icon is displayed on the screen.
Since there are four input icons A to D and the number of input icons set arbitrarily is three, three are selected from the distance LA to LD between the contact point and the input icon in order of increasing distance. The At this time, the selected input icons are LB, LD, and LA in ascending order of the distance, and the input icon C is excluded from the selection target.
Next, as shown in step S170, arrangement points (P, Q, R) at which the input icons are arranged around the contact coordinates are calculated. In this calculation method, first, as shown in FIG. 6, a circle with a radius having a predetermined distance from the contact point is assumed. This radius has an optimum value depending on the screen size and device, and can be set each time.

  Then, after assuming an arc having a predetermined radius from the contact point n, as shown in FIG. 6, the coordinate values of three points divided into three on the arc having a predetermined radius are calculated. The calculated three arrangement points are P, Q, and R, respectively, and the coordinates are (Xp, Yp) to (Xr, Yr).

  Next, as shown in step S180, the control unit 4 calculates the distances from the center points of the three input icons to the three arrangement points. As shown in FIG. 7, the length of the line segment between the center point of the input icons A, B, and D and P, Q, and R is calculated using a trigonometric function in the same manner as described above.

  And as shown to step S190, the control part 4 selects the arrangement | positioning point used as the combination with the smallest distance from the center point of an input icon to an arrangement | positioning point. The input icons are in an exclusive relationship that is not duplicated at the points P, Q, and R. As shown in FIG. 7, if icon A moves to point P, the amount of movement is LA-P, icon B moves to point Q or point R, and icon D moves to the other arrangement point from icon B. become. For the input icon movement, select the combination with the lowest total movement amount of these three input icons (in this embodiment, (LA-P) + (LB-Q) + (LD-R)). To do.

  Then, as shown in step S200, the input icons are arranged at arrangement points around the contact coordinates. As shown in FIG. 8, after the moving route of the input icon is selected, the input icon moves using the selected line segment as the locus of the center point of the input icon. At that time, since the input icons are arranged at the same timing at the points P, Q, and R, the moving speed of each input icon is different.

  When the input icon is arranged around the contact coordinates in step S200, the function indicated by the input icon to be executed is selected by touching the input icon with a finger among the input icons arranged around the contact coordinates in step S210. .

  Then, as shown in step 220, the display unit 2 displays on the screen that the input icon touched with the finger has been selected.

  Thereafter, as shown in step S230, the input icon is returned to the arrangement before being arranged around the contact coordinates.

  And as shown to step S240, the process which the selected input icon performs is performed. For example, when three input icons of an enlarged map display button, a reduced map display button, and a route information display button are arranged and the operator selects the enlarged map display button, the map displayed on the display unit 5 is displayed. The control unit 5 instructs the display unit 2 to perform enlarged display. By this instruction, the displayed map screen is enlarged.

  Returning to step S110, if there is no input icon on the screen, that is, if “NO” in the step S110, the process is ended.

  Returning to step S120, if “NO” in step S120, that is, if the area on the screen touched by the operator is an input icon area, it is recognized that the input icon has been selected, as shown in S240. Then, the processing of the input icon is executed.

  Returning to step S130, if “NO” in step S130, that is, if the contact coordinates touched with a finger are moving on the screen, the processing of the input command is performed as shown in step S240. This is because when the navigation is displaying a map or the like and a scrolling operation is performed on the screen, the control unit 4 does not give an instruction to place the input icon around the contact coordinates, and performs a normal scrolling process. Let it be done.

  In step S200, after the input icons are arranged around the contact coordinates, when there is no input icon to be processed and a certain time has passed without touching the input icons, the input icons are arranged around the contact coordinates. The input icon returns to the initial arrangement before being arranged around the contact coordinates.

  Hereinafter, a method of specifying the contact coordinates when there are a plurality of layers on the screen will be described with reference to FIG.

  FIG. 9 is a diagram illustrating an example of a screen for explaining a method of specifying a plurality of layers displayed on the display unit.

  As shown in FIG. 9, when there are a plurality of layers on the screen, the coordinates for each layer are set in addition to the coordinates (X, Y) of the entire screen. For example, the effective area of layer 3 in the entire screen (X, Y) is the shaded area in FIG. If the effective area (shaded area) of layer 3 is selected with a finger or a cursor, only layer 3 becomes an effective layer, and coordinates having the origin at the lower left corner of the layer 3 window are generated.

  Here, as shown in FIG. 10, when the effective area of the layer 3 is selected, the layer 3 is shifted to the foreground, and the coordinates of the layer 3 are generated. The coordinates of the contact point n at that time are (X3n, Y3n).

  Hereinafter, a process of changing the size of the input icon when the input icon is moved from the initial arrangement to the periphery of the contact coordinates will be described with reference to FIG.

  FIG. 11 is a diagram for explaining that the input icons arranged on the display unit are arranged in different sizes.

  As shown in FIG. 11, even when the sizes of the input icons are different, the input icon to be moved and the coordinates of the movement destination are determined by the above method, and the input icon is moved to the coordinates of the movement destination. As shown in FIG. 12, the shapes of the input icons exist in various colors and shapes, but all effective areas for selecting the input icons have a rectangular shape. In addition, characters attached to the input icon are always displayed in horizontal characters. Then, the input icon is enlarged or reduced so that the input icons are arranged at the coordinates of the movement destination so that the vertical lengths Yi of the input icons to be arranged are aligned while the aspect ratio of the input icons is fixed. .

As shown in FIG. 13, the number of input icons arranged around the contact coordinates can be set to 3-8.
Also, as shown in FIG. 14, when the input icon is arranged around the contact coordinates by touching the finger on the screen, the input icon is placed in a place where the operator can easily operate by sliding on the screen without releasing the finger. Can be moved.

  Further, as shown in FIG. 15, when an input icon is arranged around the contact coordinates by touching the finger on the screen, the input icon arranged around the finger is displayed after a certain period of time without releasing the finger. Can be set to rotate around.

  The present invention is not limited to the display device 1 using the touch panel 3, and an arbitrary place on the screen is clicked using a cursor instead of a finger, and input icons are arranged around the clicked contact coordinates. You may do it.

  With this configuration, the operator can simply operate the command by touching the display using the touch panel 3 without looking at the screen, and the input icon is arranged at the touched place.

  Therefore, when the driver performs an operation while driving, the amount of movement of the line of sight and the operation of a finger, a hand, etc. that perform the input operation can be reduced, so that the burden on the navigation operation of the driver is reduced.

  Furthermore, the input icon placed around the contact coordinates can be displayed by rotating around the contact coordinates, so even if one of the placed input icons is placed at a position where it is difficult to see with a finger etc. The operability is improved because the icon moves to a place where it can be easily seen.

  Since the number, arrangement, and size of the input icons arranged around the contact coordinates can be set, the input icons can be arranged easily for the operator to operate.

  In addition, when the display unit 2 is a multi-layer display, input icons can be displayed around the contact coordinates for each layer, so that an input icon other than the layer to be operated can be arranged to confuse the operator. Can be prevented.

  As described above, the display device 1 according to the present invention is particularly useful as a display device having a touch panel function such as a navigation device.

DESCRIPTION OF SYMBOLS 1 Display apparatus 2 Display part 3 Touch panel 4 Control part 5 Memory | storage part

Claims (4)

A display for displaying a plurality of input icons;
A touch panel provided on the display unit for detecting the contact position of the object;
A control unit that obtains contact coordinates on the display unit from the contact position of the touch panel, displays a plurality of input icons displayed on the display unit in the order close to the contact coordinates, and selects an input icon; With
The control unit calculates each arrangement point for arranging the plurality of input icons displayed on the display unit around the contact coordinates, calculates a distance from the plurality of input icons to each arrangement point, and calculates the distance from the input icon. A display device that displays an input icon at a combination arrangement point having the smallest distance to the arrangement point. The display device according to claim 1, wherein the control unit displays an input icon arranged around the contact coordinates by rotating around the contact coordinates. The display device according to claim 1, wherein the control unit can set the number, arrangement, and size of input icons arranged around the contact coordinates. The display device according to claim 1, wherein when the display unit is a multi-layer display, the control unit displays an input icon for each layer around the contact coordinates.