JP4435011B2 - Input coordinate processing program and input coordinate processing apparatus - Google Patents

Description

  The present invention relates to an input coordinate processing program and an input coordinate processing apparatus. More specifically, the present invention relates to display of display means using input coordinates output from a pointing device such as a touch panel that outputs coordinate information of a predetermined coordinate system. The present invention relates to an input coordinate processing program and an input coordinate processing apparatus that execute processing.

  2. Description of the Related Art Conventionally, a technique for executing display processing of display means based on coordinates input by operating a touch panel or a mouse is known. For example, a web browser for browsing web pages on the Internet has been proposed that enables an operation called “mouse gesture” (see, for example, Non-Patent Document 1).

  In the browser described in Non-Patent Document 1, when the mouse is moved to the left in the state where the mouse is right-clicked in the background area of the web page and the right click is released, the web page is advanced to the next page. On the other hand, when the mouse is right-clicked in the background area of the web page and moved to the right, when the right-click is released, the previous page is restored. Also, after moving the mouse down with the right mouse click in the background area of the web page and releasing the right click, a new window is opened. Furthermore, when the mouse is moved down with the mouse right-clicked in the background area of the web page and then moved up and the right-click is released, the window is duplicated.

  Also, after right-clicking the mouse on a link on a web page, moving the mouse up in the right-clicked state, and releasing the right-click, the link destination is opened in a new window. Also, after right-clicking the mouse on a link on a web page, moving the mouse down with the right-click, moving up and releasing the right-click opens the link destination in the background. These are different processes when the left mouse button is clicked on a link on a web page, compared to opening the link destination in the original window. As described above, in the mouse gesture disclosed in Non-Patent Document 1, display processing by the display unit is executed based on the direction in which the locus of the input coordinates by the mouse is accumulated or a combination of the directions. Yes.

In addition, a technique is proposed in which the locus of input coordinates on the touch panel is a pen locus, the window is moved to the pen movement destination when the pen locus does not turn, and the window is stored in a predetermined portion when the pen locus is turned. (For example, refer to Patent Document 1).
“Opera FAQ> Mouse-related”, [online], [March 15, 2005 search], Internet <URL: http: // dai. pekori. to / opera / faq / mice> Japanese Patent No. 3095145

  However, in the browser described in Non-Patent Document 1, the operation using the mouse gesture is often not intuitive for the user. For example, there is an intuitive relationship between the above-described operation of moving the mouse down with the mouse right-clicked in the background area of the web page and the display process of “opening a new window”. Hard to find. Similarly, between the above-described operation of “moving the mouse down after moving the mouse right-clicked in the background area of the web page” and the display process of “duplicating the window” It is difficult to find the relationship intuitively. Therefore, the user must memorize | store the relationship between these operation and a display process as a mere convention. The fact that the user has to remember such conventions is a barrier to using the useful mouse gesture function.

  Also in the technique of the above-mentioned Patent Document 1, the relationship between the touch operation in which the pen locus based on the locus of the input coordinates on the touch panel is turned back and the display processing of storing the window is simply associated as a convention for the user. However, it is difficult to intuitively find the relationship between this operation and the display process. However, even if the relationship between the user's operation and the display process associated therewith is high, it is meaningless if the display process itself is useless. Therefore, it is also desirable that the display process itself that is highly relevant to the user's operation is useful.

  SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide an input coordinate processing program and an input coordinate processing apparatus capable of executing display processing having high utility by an intuitive operation by a coordinate input operation.

  In order to achieve the above object, the present invention employs the following configuration. Reference numerals in parentheses, step numbers (steps are abbreviated as S and only step numbers are described), and the like indicate correspondence with the embodiments described later in order to help understanding of the present invention. The scope of the present invention is not limited at all.

  The first invention is a first display section (12 or 11) constituting a display device based on input coordinates (coordinate data corresponding to a contact position) output from a pointing device (15) according to a user operation. And an input coordinate processing program that is executed by a computer (21) that executes display processing for displaying one screen at a time on the second display unit (11 or 12). The input coordinate processing program includes an input coordinate storage step (S43, S63, S68, S73, S84, S87, S92, S104, S107, S114, S120, S134, S139, S144), a reference coordinate storage step (S44), and a processing step. (S69, S88, S115, S135) and display control steps (S69, S88, S115, S135) are executed by the computer. The input coordinate storage step detects the coordinate information (DC1) based on the display coordinate system (screen coordinate system) of the image displayed on the display device according to the input coordinates output from the pointing device, and stores the memory (24). To remember. In the reference coordinate storage step, the first coordinate information among the series of coordinate information stored in the input coordinate storage step is set as the reference coordinate (DC2) and stored in the memory. The processing step acquires a display image (a response image corresponding to a tab or a link or an image displayed on the first LCD 11 or the second LCD 12) based on at least one coordinate information in the series of coordinate information. . The display control step indicates a reference direction (upward or downward) in which the operation direction indicated by the series of coordinate information in the display coordinate system with respect to the reference coordinate is from the position of the first display unit to the position of the second display unit (Yes in S65, Yes in S83, Yes in S111, Yes in S131), the display image acquired in the processing step is displayed on the second display unit (FIGS. 5, 7, and 10). The display image acquired in the processing step includes a response image corresponding to the tab and the link, at least a part of the image displayed on the first display unit, and the like. The pointing device is an input device that specifies an input position and coordinates on the screen, and is realized by, for example, a touch panel, a mouse, a track pad, a track ball, or the like. A coordinate system used in each input device is a touch panel coordinate system or a screen coordinate system. The first display unit and the second display unit may be physically separated display units, or may be formed by physically dividing one display screen. Furthermore, the arrangement relationship between the first display unit and the second display unit may be two upper and lower screens or two left and right screens.

  In a second aspect based on the first aspect, the computer downloads a file based on the input coordinates via the communication unit (33) communicating with the network and browses it on a display device. It is something to execute. The processing step executed by the computer obtains a response image corresponding to the response area when the reference coordinates are located in the response area (tab, link) of the web browser (Yes in S46, Yes in S47). The display control step executed by the computer displays the response image on the second display unit when the operation direction indicates the reference direction (FIGS. 5 and 7).

  In a third aspect based on the second aspect, the processing step executed by the computer is at least partly displayed on the first display unit when the reference coordinates are located in the background area of the web browser (Yes in S48). Image (the image displayed on the second LCD 12 or the first LCD 11) is acquired. The display control step executed by the computer displays at least a part of the image displayed on the first display unit on the second display unit when the operation direction indicates the reference direction (FIG. 10).

  In a fourth aspect based on the second aspect, the reference direction is an upward direction or a downward direction in which the second display unit is provided with respect to the first display unit of the display device. The processing step executed by the computer acquires images acquired in the past in the processing step when the reference coordinates are located in the background area of the web browser and the operation direction indicates the left direction or the right direction. In the display control step executed by the computer, when the operation direction indicates the left direction or the right direction (Yes in S136, Yes in S141), an image acquired in the past is displayed on the first display unit (S140, S145). .

  In a fifth aspect based on the first aspect described above, when the processing step executed by the computer encloses a predetermined area displayed on the first display unit (DC3) as a series of coordinate information trajectories (DC3), An enlarged image obtained by enlarging the image in the predetermined area is acquired (S108). The display control step executed by the computer displays the enlarged image on the second display unit (FIG. 9).

  In a sixth aspect based on the first aspect, the reference direction is an upward direction or a downward direction in which the second display unit is provided with respect to the first display unit of the display device. The processing step executed by the computer acquires a page image different from the page displayed on the first display unit when the operation direction indicates the left direction or the right direction. The display control step executed by the computer displays another page image on the first display unit when the operation direction indicates the left direction or the right direction.

  In a seventh aspect based on the first aspect, the coordinate information based on the display coordinate system corresponding to the input coordinates output from the pointing device is displayed on the image displayed on the first display section and on the second display section. It can be set to only one of the images to be displayed.

  8th invention performs the display process which displays one screen at a time on the 1st display part which comprises a display apparatus, and a 2nd display part based on the input coordinate output from a pointing device according to a user's operation. An input coordinate processing program executed on a computer. The input coordinate processing program causes the computer to execute an input coordinate storage step, a reference coordinate storage step, a processing step (S74, S93, S121), and a display control step (S74, S93, S121). In the input coordinate storage step, coordinate information based on the display coordinate system of the image displayed on the display device is detected and stored in the memory in accordance with the input coordinates output from the pointing device. In the reference coordinate storage step, the first coordinate information among the series of coordinate information stored in the input coordinate storage step is set as reference coordinates and stored in the memory. The processing step acquires a display image based on at least one piece of coordinate information among the series of coordinate information. The display control step indicates a reciprocating direction (vertical direction) in which the operation direction indicated by the series of coordinate information in the display coordinate system is reciprocated in the direction in which the first display unit and the second display unit are arranged with reference to the reference coordinate. (Yes in S70, Yes in S89, Yes in S116 and S117) At least a part of the image displayed on the second display unit is displayed on the first display unit, and the display image acquired in the processing step Is displayed on the second display section (FIGS. 6, 8, and 12). Note that the display image acquired in the processing step includes a response image and at least a part of the image displayed on the first display unit.

  9th invention performs the display process which displays one screen at a time on the 1st display part which comprises a display apparatus, and a 2nd display part based on the input coordinate output from a pointing device according to a user's operation An input coordinate processing program executed on a computer. The input coordinate processing program causes the computer to execute an input coordinate storage step, a reference coordinate storage step, a processing step, and a display control step. In the input coordinate storage step, coordinate information based on the display coordinate system of the image displayed on the display device is detected and stored in the memory in accordance with the input coordinates output from the pointing device. In the reference coordinate storage step, the first coordinate information among the series of coordinate information stored in the input coordinate storage step is set as reference coordinates and stored in the memory. The processing step acquires a display image based on at least one piece of coordinate information among the series of coordinate information. The display control step is acquired in the processing step when the operation direction indicated by the series of coordinate information in the display coordinate system with respect to the reference coordinate indicates a reference direction from the position of the first display unit to the position of the second display unit. The displayed image is displayed on the second display unit. In the display control step, when the operation direction indicates a reciprocating direction that reciprocates in the direction in which the first display unit and the second display unit are arranged, at least a part of the image displayed on the second display unit Is displayed on the first display unit, and the display image acquired in the processing step is displayed on the second display unit.

  In a tenth aspect of the invention, display processing for displaying one screen at a time on the first display unit and the second display unit constituting the display device is executed based on input coordinates output from the pointing device in accordance with a user operation. It is an input coordinate processing device. The input coordinate processing device includes storage means (24), input coordinate storage processing means, reference coordinate storage processing means, processing means, and display control means. The input coordinate storage processing unit detects coordinate information based on the display coordinate system of the image displayed on the display device according to the input coordinates output from the pointing device, and stores the detected coordinate information in the storage unit. The reference coordinate storage processing means sets the first coordinate information among the series of coordinate information stored by the input coordinate storage processing means as reference coordinates and stores the reference coordinate information in the storage means. The processing means acquires a display image based on at least one coordinate information in the series of coordinate information. The display control means is obtained by the processing means when the operation direction indicated by the series of coordinate information in the display coordinate system with respect to the reference coordinates indicates a reference direction from the position of the first display section to the position of the second display section. The displayed image is displayed on the second display unit.

  In an eleventh aspect of the invention, display processing for displaying one screen at a time on the first display unit and the second display unit constituting the display device is executed based on input coordinates output from the pointing device in accordance with a user operation. It is an input coordinate processing device. The input coordinate processing apparatus includes storage means, input coordinate storage processing means, reference coordinate storage processing means, processing means, and display control means. The input coordinate storage processing unit detects coordinate information based on the display coordinate system of the image displayed on the display device according to the input coordinates output from the pointing device, and stores the detected coordinate information in the storage unit. The reference coordinate storage processing means sets the first coordinate information among the series of coordinate information stored by the input coordinate storage processing means as reference coordinates and stores the reference coordinate information in the storage means. The processing means acquires a display image based on at least one coordinate information in the series of coordinate information. The display control means, when the operation direction indicated by the series of coordinate information in the display coordinate system with respect to the reference coordinate indicates the reciprocating direction reciprocating the direction in which the first display unit and the second display unit are arranged, At least a part of the image displayed on the second display unit is displayed on the first display unit, and the display image acquired by the processing means is displayed on the second display unit.

  In a twelfth aspect of the present invention, display processing for displaying one screen at a time on the first display unit and the second display unit constituting the display device is executed based on input coordinates output from the pointing device in accordance with a user operation. This is an input coordinate processing device. The input coordinate processing apparatus includes storage means, input coordinate storage processing means, reference coordinate storage processing means, processing means, and display control means. The input coordinate storage processing unit detects coordinate information based on the display coordinate system of the image displayed on the display device according to the input coordinates output from the pointing device, and stores the detected coordinate information in the storage unit. The reference coordinate storage processing means sets the first coordinate information among the series of coordinate information stored by the input coordinate storage processing means as reference coordinates and stores the reference coordinate information in the storage means. The processing means acquires a display image based on at least one coordinate information in the series of coordinate information. The display control means is obtained by the processing means when the operation direction indicated by the series of coordinate information in the display coordinate system with respect to the reference coordinates indicates a reference direction from the position of the first display section to the position of the second display section. The displayed image is displayed on the second display unit, and the operation direction is displayed on the second display unit when the reciprocating direction reciprocates in the direction in which the first display unit and the second display unit are arranged. At least a part of the image that has been displayed is displayed on the first display unit, and the display image acquired by the processing means is displayed on the second display unit.

  According to the first aspect, a highly useful display process can be executed by an intuitive operation in response to an operation by the user using the pointing device. For example, when the user operates using a pointing device in the direction from the first display unit to the second display unit, the image acquired in the processing step (the response image corresponding to the tab or link or the first display unit is displayed). (At least a part of the image) is displayed on the second display unit in the operation direction (direction from the first display unit to the second display unit). As described above, the operation direction input by the user to the pointing device and the display processing corresponding thereto are intuitive. Moreover, leaving the original display information on the first display unit and displaying the information corresponding to the process on the second display unit can be useful in various situations.

  According to the second aspect, in the display process of the web browser, a response image obtained by selecting a tab or a link destination can be displayed on the second display unit in the operation direction destination.

  According to the third aspect, in the display process of the web browser, the image displayed on the first display unit can be displayed on the second display unit located in the operation direction.

  According to the fourth aspect of the present invention, in the display processing of the web browser, by operating the pointing device in the left or right direction different from the reference direction, the so-called “return” or “forward” generally indicated in the left-right direction. Corresponding display processing can be performed.

  According to the fifth aspect, the user can enlarge and display a desired image on the second display unit by performing an operation that surrounds a part of the image displayed on the first display unit. .

  According to the sixth aspect of the invention, by operating the pointing device in the left or right direction different from the reference direction, it corresponds to “previous page” or “next page” generally indicated in the left-right direction in an electronic book or the like. Display processing can be performed.

  According to the seventh aspect of the invention, it is possible to perform display processing on another display unit where operation input is impossible by operating on one display unit where operation input is possible.

  According to the eighth aspect, a highly useful display process can be executed by an intuitive operation in response to an operation by the user using the pointing device. For example, when the user performs an operation such as reciprocating in the direction in which the first display unit and the second display unit are arranged using a pointing device, at least a part of the image displayed on the second display unit is operated. Image displayed on the first display unit in one direction (the direction from the second display unit to the first display unit) and acquired in the processing step (displayed on the response image corresponding to the tab or link or on the first display unit) At least a part of the image) is displayed on the second display unit in the other direction of operation (the direction from the first display unit to the second display unit). Therefore, the information displayed on the display unit in the reciprocating operation direction of the user (the direction in which the first display unit and the second display unit are located) is switched. As described above, the direction of the operation input by the user to the pointing device and the display processing corresponding to the direction are intuitive. Moreover, leaving the original display information on the first display unit and displaying the information corresponding to the process on the second display unit can be useful in various situations.

  According to the ninth aspect, the same effect as obtained in the first and eighth aspects can be obtained.

  Further, according to the input coordinate processing apparatus of the present invention, the same effect as the above-described input coordinate processing program can be obtained.

  An input coordinate processing apparatus that executes an input coordinate processing program according to an embodiment of the present invention will be described with reference to the drawings. The input coordinate processing program of the present invention can be applied by being executed by an arbitrary computer system that can be displayed on the display device. This will be described using an input coordinate processing program. FIG. 1 is an external view of a game apparatus 1 that executes the input coordinate processing program of the present invention. Here, a portable game device is shown as an example of the game device 1.

  In FIG. 1, the game apparatus 1 includes a first LCD (Liquid Crystal Display) 11 and a second LCD 12. The housing 13 includes an upper housing 13a and a lower housing 13b. The first LCD 11 is housed in the upper housing 13a, and the second LCD 12 is housed in the lower housing 13b. The resolutions of the first LCD 11 and the second LCD 12 are both 256 dots × 192 dots. In this embodiment, an LCD is used as the display device. However, any other display device such as a display device using EL (Electro Luminescence) can be used. Further, the first LCD 11 and the second LCD 12 can be used with arbitrary resolutions.

  The upper housing 13a is formed with sound release holes 18a and 18b for releasing sound from a pair of speakers (30a and 30b in FIG. 2) to be described later.

  In the lower housing 13b, as an input device, a cross switch 14a, a start switch 14b, a select switch 14c, an A button 14d, a B button 14e, an X button 14f, a Y button 14g, a power switch 14h, an L button 14L, and an R button 14R is provided. As a further input device, a touch panel 15 is mounted on the screen of the second LCD 12. The lower housing 13b is also provided with an insertion port for storing the memory card 17 and the stick 16.

  As the touch panel 15, an arbitrary type such as a resistive film type, an optical type (infrared type), and a capacitive coupling type can be used. The touch panel 15 is an example of a pointing device having a function of outputting coordinate data corresponding to the contact position when the surface is touched with the stick 16. In the following description, it is assumed that the player operates the touch panel 15 with the stick 16, but it is of course possible to operate the touch panel 15 with a pen (stylus pen) or a finger instead of the stick 16. In the present embodiment, the touch panel 15 having a resolution (detection accuracy) of 256 dots × 192 dots is used as in the resolution of the second LCD 12. However, the resolution of the touch panel 15 and the resolution of the second LCD 12 are not necessarily the same.

  The memory card 17 is a recording medium that records an input coordinate processing program and the like, and is detachably attached to an insertion port provided in the lower housing 13b.

  Next, the internal configuration of the game apparatus 1 will be described with reference to FIG. FIG. 2 is a block diagram showing the internal configuration of the game apparatus 1.

  In FIG. 2, a CPU core 21 is mounted on the electronic circuit board 20 accommodated in the housing 13. A connector 23 is connected to the CPU core 21 via a bus 22, an input / output interface circuit (referred to as I / F circuit in the drawing) 25, a first GPU (Graphics Processing Unit) 26, a second GPU 27, a RAM 24, The LCD controller 31 and the wireless communication unit 33 are connected. The memory card 17 is detachably connected to the connector 23. The memory card 17 includes a ROM 17a that stores an input coordinate processing program and a RAM 17b that stores backup data in a rewritable manner. The input coordinate processing program stored in the ROM 17a of the memory card 17 is loaded into the RAM 24, and the input coordinate processing program loaded into the RAM 24 is executed by the CPU core 21. In addition to the input coordinate processing program, the RAM 24 appropriately stores data for generating temporary data obtained by the CPU core 21 executing the program. The I / F circuit 25 is connected to the touch panel 15, the right speaker 30a, the left speaker 30b, and the operation switch unit 14 including the cross switch 14a and the A button 14d shown in FIG. The right speaker 30a and the left speaker 30b are disposed inside the sound release holes 18a and 18b, respectively.

  A first VRAM (Video RAM) 28 is connected to the first GPU 26, and a second VRAM 29 is connected to the second GPU 27. In response to an instruction from the CPU core 21, the first GPU 26 generates a first display image based on data for generating a display image stored in the RAM 24 and draws the first display image in the first VRAM 28. Similarly, the second GPU 27 generates a second display image in accordance with an instruction from the CPU core 21 and draws it in the second VRAM 29. The first VRAM 28 and the second VRAM 29 are connected to the LCD controller 31.

  The LCD controller 31 includes a register 32. The register 32 stores a value of 0 or 1 according to an instruction from the CPU core 21. When the value of the register 32 is 0, the LCD controller 31 outputs the first display image drawn in the first VRAM 28 to the first LCD 11 and the second display image drawn in the second VRAM 29 as the second display image. Output to the LCD 12. When the value of the register 32 is 1, the first display image drawn in the first VRAM 28 is output to the second LCD 12, and the second display image drawn in the second VRAM 29 is output to the first LCD 11. To do.

  The wireless communication unit 33 has a function of exchanging data used for game processing and other data with the wireless communication unit 33 of other game devices. As an example, the wireless LAN standard of IEEE802.11. Provides wireless communication functions that comply with Then, the wireless communication unit 33 outputs the received data to the CPU core 21. Further, the wireless communication unit 33 transmits data instructed by the CPU core 21 to another game device. Note that the game device 1 is connected via the wireless communication unit 33 by mounting a protocol such as TCP / IP (Transmission Control Protocol / Internet Protocol) or a predetermined browser in the wireless communication unit 33 or the storage unit in the game device 1. Connection with a network such as the Internet. The game apparatus 1 can download data such as documents and images published on the network and browse them on the first LCD 11 and the second LCD 12.

  The input coordinate processing program of the present invention may be supplied not only to the computer system through an external storage medium such as the memory card 17 but also to the computer system through a wired or wireless communication line. The input coordinate processing program may be recorded in advance in a nonvolatile storage device inside the computer system. The information storage medium for storing the input coordinate processing program is not limited to the nonvolatile semiconductor memory, but may be a CD-ROM, a DVD, or an optical disk storage medium similar to them.

  Next, with reference to FIG. 3 to FIG. 12, before describing specific processing operations by the input coordinate processing program executed in the game apparatus 1, the processing operations are performed on the first LCD 11 and the second LCD 12. A display form example to be displayed will be described. In order to make the description concrete, the first LCD 11 and the second LCD 12 are used to connect to a network such as the Internet via the wireless communication unit 33 and to display data such as documents and images disclosed on the network. An example will be described. FIG. 3 is a diagram showing an example of an initial screen display displayed on the first LCD 11 and the second LCD 12. FIG. 4 is a diagram illustrating a screen display example displayed on the first LCD 11 and the second LCD 12 when the touch panel 15 on the link destination displayed on the second LCD 12 is tapped. FIG. 5 is a diagram showing a screen display example displayed on the first LCD 11 and the second LCD 12 when the touch panel 15 is slid upward from the link destination displayed on the second LCD 12. FIG. 6 is displayed on the first LCD 11 and the second LCD 12 when the touch panel 15 is slid upward from the link destination displayed on the second LCD 12 and then reciprocated downward. It is a figure which shows the example of a screen display. FIG. 7 is a diagram illustrating a screen display example displayed on the first LCD 11 and the second LCD 12 when the touch panel 15 is slid downward from the tab displayed on the second LCD 12. FIG. 8 shows screens displayed on the first LCD 11 and the second LCD 12 when the touch panel 15 is slid downward from the tab displayed on the second LCD 12 and then reciprocated upward. It is a figure which shows the example of a display. FIG. 9 is a diagram illustrating a screen display example displayed on the first LCD 11 and the second LCD 12 when the touch panel 15 is slid so as to surround a part of the information displayed on the second LCD 12. . FIG. 10 is a diagram illustrating a screen display example displayed on the first LCD 11 and the second LCD 12 when the touch panel 15 is slid upward from the background image displayed on the second LCD 12. FIG. 11 is a diagram for explaining each region set when the touch panel 15 on the background image displayed on the second LCD 12 is touch-operated. FIG. 12 is displayed on the first LCD 11 and the second LCD 12 when the touch panel 15 is slid upward from the background image displayed on the second LCD 12 and then reciprocated downward. It is a figure which shows the example of a screen display.

  In FIG. 3, when browsing information such as documents and images published on the network via the wireless communication unit 33 on the game apparatus 1, the current browsing is selected only on the second LCD 12 as an example of the initial stage. Information is displayed. For example, homepage information selected by the user is displayed on the second LCD 12. In the example shown in FIG. 3, a text link and an image link indicating a link destination and a tab for changing browsing to other information in the homepage information are displayed as response areas in the homepage information. An icon set for browsing the network in the game apparatus 1 is displayed side by side at the left end of the display screen of the second LCD 12. As one of these icons, an enclosure mode icon is set.

  In FIG. 4, when the user touches the touch panel 15 on the link destination displayed on the second LCD 12 (on the image link in FIG. 4) using the stick 16, a circle centered on the touched point. M1 is displayed (state shown in the left diagram of FIG. 4). Then, when the user releases the stick 16 from the touch panel 15, the home page information (response image) of the link destination touched is displayed on the second LCD 12 (state shown in the right diagram of FIG. 4). Although the home page information displayed on the second LCD 12 is changed to the linked home page information, the display mode of the first LCD 11 does not change. Hereinafter, as described above, an operation of touching and releasing the touch panel 15 for a moment is referred to as a tap operation.

  In FIG. 5, the user touches the touch panel 15 on the link destination displayed on the second LCD 12 (on the text link in FIG. 5), and slides the stick 16 upward without releasing from the touch panel 15. When the operation is performed, an upward arrow M2 is displayed in the vicinity of the point where the touch operation is currently performed (state in the left diagram of FIG. 5). Hereinafter, an operation in which the touch panel 15 is touched and slid without leaving the touch panel 15 is referred to as a slide operation. Specifically, the screen coordinate corresponding to the touch input coordinate where the user first touched the touch panel 15 is set as the start point coordinate (x1, y1), and the determination line y = y1 + c1 is set in the same screen coordinate system. Here, c1 is a predetermined constant. Then, when a sliding operation is performed on the touch panel 15 upward to an area above the determination line (touch input coordinates (xt, yt) in FIG. 5), an upward arrow M2 is displayed.

  After the slide operation, when the user releases the stick 16 from the touch panel 15 in an area above the determination line, the link destination corresponding to the first touched link destination (that is, the link destination corresponding to the start point coordinates (x1, y1)). ) Home page information is displayed on the first LCD 11. The second LCD 12 continues to display the homepage information as it is without changing the display (the state shown in the right figure of FIG. 5). That is, the information (response image) designated by the first touch operation is mounted in the user's slide operation direction (upward direction from the second LCD 12 toward the first LCD 11) while leaving the display information on the second LCD 12. Displayed on the display unit (first LCD 11).

  In FIG. 6, the user touches the link destination displayed on the second LCD 12 (on the text link in FIG. 6) and slides the touch panel 15 upward without releasing the touch panel 15. When a slide operation reciprocating in the direction is performed, an up and down arrow M3 is displayed in the vicinity of the point where the touch operation is currently performed (state in the left diagram of FIG. 6). Specifically, the start point coordinates (x1, y1) and the determination line y = y1 + c1 are set as in FIG. Then, after sliding on the touch panel 15 up to the area above the determination line, when sliding to the area below the determination line in the opposite direction (touch input coordinates (xt, yt in FIG. 6) )), An up and down arrow M3 is displayed.

  When the user releases the stick 16 from the touch panel 15 in an area below the determination line after the above-and-down sliding operation, the link destination (that is, the start point coordinates (x1, y1) that is touched first) corresponds. Homepage information (response image) of (link destination) is displayed on the second LCD 12. Then, the first LCD 11 displays the home page information that has been displayed on the second LCD 12 until then (the state shown in the right diagram of FIG. 6). That is, the original display information on the second LCD 12 is displayed on the first LCD 11, the information specified by the first touch operation is displayed on the second LCD 12, and the user's slide operation direction (first LCD 11 and The information displayed on the upper and lower display units (the first LCD 11 and the second LCD 12) is displayed so as to be switched in accordance with the vertical direction in which the second LCD 12 is reciprocated.

  In FIG. 7, when the user touches the touch panel 15 on the tab displayed on the second LCD 12 (on the tab “xxx” in FIG. 7), the tab (that is, the tab corresponding to the start point coordinates (x1, y1)). Other information (response image) in the homepage information being browsed corresponding to “xxx”) is immediately displayed on the first LCD 11. When an operation of sliding the stick 16 downward without releasing from the touch panel 15 is performed, a downward arrow M4 is displayed in the vicinity of the currently touched point (state in the left diagram of FIG. 7). Specifically, the screen line corresponding to the touch input coordinates with which the user first touched the touch panel 15 is set as the start point coordinates (x1, y1), and the determination line y = y1-c2 is set in the same screen coordinate system. Here, c2 is a predetermined constant. Then, when a sliding operation is performed on the touch panel 15 downward to an area below the determination line (touch input coordinates (xt, yt) in FIG. 7), a downward arrow M4 is displayed.

  After the slide operation, when the user releases the stick 16 from the touch panel 15 in an area below the determination line, the information displayed on the first LCD 11 corresponding to the touched tab is displayed on the second LCD 12. The state is displayed (the state shown in the right diagram of FIG. 7). Although the home page information displayed on the second LCD 12 is changed to other information corresponding to the tab, the first LCD 11 continues to display other information corresponding to the tab. That is, information (response image) designated by the first touch operation is displayed on the display unit (second LCD 12) mounted in the user's slide operation direction (downward direction from the first LCD 11 toward the second LCD 12). Is displayed. In the right diagram of FIG. 7, both the first LCD 11 and the second LCD 12 display information (response image) designated by the first touch operation, but the first LCD 11 The original information displayed before the touch operation may be redisplayed.

  In FIG. 8, when the user performs a touch operation on a tab displayed on the second LCD 12 (on the tab “xxx” in FIG. 8), the tab “xxx” corresponding to the tab (that is, the start point coordinates (x1, y1)). The other information (response image) in the homepage information being browsed corresponding to) is immediately displayed on the first LCD 11. When a slide operation is performed to reciprocate upward after sliding the touch panel 15 downward without being separated from the top of the touch panel 15, a vertical arrow M5 is displayed in the vicinity of the currently touched point (see FIG. 8 (state in the left figure). Specifically, the start point coordinates (x1, y1) and the determination line y = y1-c2 are set as in FIG. Then, after sliding on the touch panel 15 to the area below the determination line, when sliding to the area above the determination line in the opposite direction (touch input coordinates (xt, yt in FIG. 8) )), An up and down arrow M5 is displayed.

  When the user releases the stick 16 from the touch panel 15 in an area above the determination line after the slide operation that reciprocates up and down, information corresponding to the touched tab is displayed on the second LCD 12. Become. Then, the first LCD 11 displays the original homepage information that has been displayed on the second LCD 12 until then (the state in the right diagram of FIG. 8). That is, the original display information on the second LCD 12 is displayed on the first LCD 11, the information specified by the first touch operation is displayed on the second LCD 12, and the user's slide operation direction (second LCD 12 and The information displayed on the upper and lower display units (the first LCD 11 and the second LCD 12) is displayed so as to be switched according to the vertical direction in which the first LCD 11 is reciprocated.

  In FIG. 9, when the user taps the enclosure mode icon Ia, the game apparatus 1 moves to the enclosure mode and operates. When the user performs a touch operation on the touch panel 15 using the stick 16 so as to surround some information (character information described in the background image in FIG. 9) displayed on the second LCD 12 in the enclosing mode, A trajectory M6 is displayed in accordance with the touched trajectory (the state shown in the left diagram of FIG. 9). Specifically, the screen coordinates corresponding to the touch input coordinates with which the user first touched the touch panel 15 are set as the start point coordinates (x1, y1), and the start point centered on the start point coordinates (x1, y1) in the same screen coordinate system. Set the neighborhood area. Then, when a slide operation is performed to the vicinity of the start point so as to surround the touch panel 15 (touch input coordinates (xt, yt) in FIG. 9), a locus M6 is displayed. Then, when the user releases the stick 16 from the touch panel 15 in the area near the start point, the information surrounded by the locus M6 is enlarged (enlarged image) and displayed on the first LCD 11. The second LCD 12 continuously displays the homepage information as it is without changing the display (the state shown in the right diagram of FIG. 9). That is, the information (enlarged image) surrounded by the touch operation is displayed on the other display unit (first LCD 11) while the display information on the second LCD 12 is left.

  In FIG. 10, when the user touches the touch panel 15 on the background image displayed on the second LCD 12 and slides upward without releasing from the touch panel 15, the guide image M <b> 7 is located near the start point coordinates. In addition, an upward arrow M8 is displayed in the vicinity of the currently touched point (the state shown in the left diagram of FIG. 10).

  Specifically, as shown in FIG. 11, the screen coordinates corresponding to the touch input coordinates with which the user first touched the touch panel 15 is used as a reference with the start point coordinates (x1, y1) as a plurality of regions in the same screen coordinate system. Set. A predetermined area AM is set around the start point coordinates (x1, y1). In the screen coordinate system (x, y), the predetermined area AM is an area where x1−k1 ≦ x ≦ x1 + k1 and y1−k2 <y <y1 + k2. Here, k1 and k2 are predetermined constants, respectively. Then, a guide image M7 is displayed at the boundary of the predetermined area AM.

  An upper area AT is set above the predetermined area AM. In the screen coordinate system (x, y), the upper area AT is an area where x1−k1 ≦ x ≦ x1 + k1 and y ≧ y1 + k2. A lower area AB is set below the predetermined area AM. In the screen coordinate system (x, y), the lower area AB is an area where x1−k1 ≦ x ≦ x1 + k1 and y ≦ y1−k2. A left area AL is set on the left side of the predetermined area AM. In the screen coordinate system (x, y), the left area AL is an area where x <x1-k1. A right area AR is set on the right side of the predetermined area AM. In the screen coordinate system (x, y), the right area AR is an area where x> x1 + k1. Then, as shown in FIG. 10, when a slide operation is performed upward on the touch panel 15 to the upper area AT above the predetermined area AM (that is, the area surrounded by the guide image M7) (touch input coordinates (FIG. 10)). xt, yt)), and an upward arrow M8 is displayed.

  When the user releases the stick 16 from the touch panel 15 in the upper area AT after the slide operation, the home page information being browsed on the second LCD 12 (that is, the home page information designated by the start point coordinates (x1, y1)). ) Is displayed on the first LCD 11. The second LCD 12 continues to display the homepage information as it is without changing the display (the state shown in the right diagram of FIG. 10). That is, the information (displayed on the second LCD 12) is displayed on the starting side in the user's slide operation direction (upward from the second LCD 12 toward the first LCD 11) while leaving the display information on the second LCD 12. Is displayed on the display unit (first LCD 11) mounted in the slide operation direction.

  In FIG. 12, the user touches the touch panel 15 on the background image displayed on the second LCD 12 and slides upward to the upper area AT without releasing from the touch panel 15, and then into the predetermined area AM. When a slide operation that reciprocates up and down (touch input coordinates (xt, yt) in FIG. 12) is performed, a guide image M7 is displayed in the vicinity of the start point coordinates, and an up and down arrow M9 is displayed in the vicinity of the currently touched point. (The state shown in the left diagram of FIG. 12). Each area set at this time is the same as the area described in FIG.

  When the user releases the stick 16 from the touch panel 15 within the predetermined area AM after the above-described slide operation that reciprocates up and down, the home page information (that is, the start point coordinates (x1, y1) specified on the second LCD 12 is designated). Homepage information) is displayed on the first LCD 11. Then, the home page information being browsed on the first LCD 11 is displayed on the second LCD 12 (the state shown in the right figure of FIG. 12). That is, the display information on the second LCD 12 is displayed on the first LCD 11, the display information on the first LCD 11 is displayed on the second LCD 12, and the user's slide operation direction (the first LCD 11 and the second LCD 12 is displayed). The information displayed on the upper and lower display units (the first LCD 11 and the second LCD 12) is displayed so as to be switched in accordance with the vertical direction in which the direction is arranged.

  Next, specific processing operations performed by the input coordinate processing program executed by the game apparatus 1 will be described with reference to FIGS. FIG. 13 is a flowchart showing an operation in which the game apparatus 1 performs input coordinate processing by executing the input coordinate processing program. FIG. 14 is a subroutine showing the detailed operation of the link designation process in step 50 in FIG. FIG. 15 is a subroutine showing the detailed operation of the tab designation process in step 51 in FIG. 16 to 18 are subroutines showing the detailed operation of the background designation process in step 52 in FIG. FIG. 19 is a diagram showing an example of various data stored in the RAM 24 by the processing operation based on FIG. The program for executing these processes is included in the input coordinate processing program stored in the ROM 17a, and is read from the ROM 17a to the RAM 24 when the game apparatus 1 is turned on. It is executed by the CPU core 21. In order to make the description more specific, the first LCD 11 and the second LCD 12 are connected to a network such as the Internet via the wireless communication unit 33 and data such as documents and images disclosed on the network are displayed. The operation will be described using an example of browsing in the above.

  First, when a power source (not shown) of the game apparatus 1 is turned on, a boot program (not shown) is executed by the CPU core 21, whereby an input coordinate processing program stored in the memory card 17 is stored in the RAM 24. Loaded. When the loaded input coordinate processing program is executed by the CPU core 21, the steps shown in FIG. 13 (abbreviated as “S” in FIGS. 13 to 18) are executed.

  In FIG. 13, the CPU core 21 displays information such as documents and images published on the designated web page on at least the second LCD 12 in accordance with a user operation (step 41; see FIG. 3). Then, the CPU core 21 sets the touch input flag DFt stored in the RAM 24 to OFF (step 42), and advances the processing to the next step. In step 42, the CPU core 21 sets all the first to twelfth mode flags DF1 to DF12 stored in the RAM 24 to off.

  Here, as shown in FIG. 19, the coordinate data input from the touch panel 15 is converted into coordinates on the image displayed on the second LCD 12 corresponding to the touch position where the touch panel 15 is touched, and the RAM 24. Are stored as touch input coordinates DC1. In addition, the RAM 24 appropriately stores start point coordinates DC2, trajectory coordinates DC3, and the like as position data DC for generating an image. In addition to the touch input flag DFt, the RAM 24 includes first to twelfth mode flags DF1 to DF12 as flag data DF for determining a process to be performed next (hereinafter referred to as the next process). Remembered. Further, an index image DI1, a trajectory image DI2, a guide image DI3, and the like are appropriately stored as image data DI for generating an image indicating the recognized operation gesture.

  Returning to FIG. 13, the CPU core 21 determines whether or not there is a touch input from the touch panel 15 according to a user operation (step 43). If there is a touch input, the process proceeds to the next step 44. On the other hand, if there is no touch input, it is determined whether or not browsing of the currently displayed information is to be terminated (step 53). Next, when continuing browsing, the CPU core 21 returns to step 43 to repeat the process, and when ending browsing, ends the process according to the flowchart.

  In step 44, the CPU core 21 uses the coordinates on the image displayed on the second LCD 12 corresponding to the contact position where the touch panel 15 is currently touched (that is, the current touch input coordinates DC1) as the start point coordinates DC2 in the RAM 24. To remember. Next, the CPU core 21 sets the touch input flag DFt stored in the RAM 24 to ON (step 45), and advances the processing to the next step.

  Next, the CPU core 21 determines whether the image corresponding to the position indicated by the start point coordinate DC2 is a link (step 46), a tab (step 47), and a background image (step 48). to decide. When the image corresponding to the position indicated by the start point coordinate DC2 is a link such as an image link or a text link (Yes in Step 46), the CPU core 21 performs a link designation process (Step 50) and performs the above Step 42. Return to and repeat the process. If the image corresponding to the position indicated by the start point coordinate DC2 is a tab (Yes in step 47), the CPU core 21 performs tab designation processing (step 51), returns to step 42, and repeats the processing. When the image corresponding to the position indicated by the start point coordinate DC2 is a background image (Yes in step 48), the CPU core 21 performs background designation processing (step 52), returns to step 42, and repeats the processing. . Furthermore, when the image corresponding to the position indicated by the start point coordinate DC2 is neither a link, a tab, nor a background image (steps 46 to 48 are all No), the CPU core 21 responds to the position indicated by the start point coordinate DC2. The process is repeated (step 49), and the process returns to step 42 to repeat the process. Hereinafter, detailed operations of the link designation process, the tab designation process, and the background designation process will be described.

  In FIG. 14, in the link designation process in step 50, first, the CPU core 21 sets the first mode flag DF1 stored in the RAM 24 to ON (step 61). Then, the CPU core 21 displays the circle M1 centered on the current touch input coordinate DC1 on the information displayed on the second LCD 12 using the index image DI1 (step 62; see FIG. 4), and the user It is determined whether or not has been touched off (step 63). The CPU core 21 proceeds to the next step 64 when the user touches off, and proceeds to step 65 when the touch operation is continued.

  In step 64, the CPU core 21 executes the first mode based on the first mode flag DF1 that is currently turned on, and ends the processing by the subroutine. Here, the first mode is a process for performing the display described with reference to the right side of FIG. 4. The display mode of the first LCD 11 is not changed, and the home page information of the link destination that has been tapped is changed to the second mode. This is a process of displaying on the LCD 12.

  In step 65, the CPU core 21 determines whether or not the current touch input coordinate DC1 is in an image area above the determination line including the determination line (hereinafter referred to as an area equal to or higher than the determination line). Then, the CPU core 21 proceeds to the next step 66 when the touch input coordinate DC1 is in an area equal to or higher than the determination line, and returns to step 62 and repeats the process when it is in an area below the determination line. Here, the CPU core 21 sets the determination line used in step 65 based on the starting point coordinates DC2 (x1, y1) as y = y1 + c1 (c1: constant). Then, if the current touch input coordinate DC1 (xt, yt) is yt ≧ y1 + c1, the CPU core 21 determines that the current touch input coordinate DC1 is in an area greater than the determination line.

  In step 66, the CPU core 21 sets the second mode flag DF2 stored in the RAM 24 to ON, and sets the first mode flag DF1 and the third mode flag DF3 to OFF. Then, the CPU core 21 displays an upward arrow M2 on the information displayed on the second LCD 12 in the vicinity of the current touch input coordinate DC1 using the index image DI1 (step 67; see FIG. 5), and the user It is determined whether or not has been touched off (step 68). Then, the CPU core 21 proceeds to the next step 69 when the user touches off, and proceeds to step 70 when the touch operation is continued.

  In step 69, the CPU core 21 executes the second mode based on the second mode flag DF2 that is currently set to ON, and ends the processing by the subroutine. Here, the second mode is a process of performing the display described with reference to the right diagram of FIG. It is processing to do.

  In step 70, the CPU core 21 determines whether or not the current touch input coordinate DC1 is in an area below the determination line used in step 65. If the touch input coordinate DC1 is in the area below the determination line, the CPU core 21 proceeds to the next step 71. On the other hand, when the CPU core 21 is in an area equal to or greater than the determination line, if the second mode flag DF2 is set to ON, the CPU core 21 returns to step 67 and repeats the process, and the second mode flag DF2 is set to OFF. Then, the process returns to step 66 and the process is repeated (step 75).

  In step 71, the CPU core 21 sets the third mode flag DF3 stored in the RAM 24 to ON and sets the second mode flag DF2 to OFF. Then, the CPU core 21 displays an up and down arrow M3 on the information displayed on the second LCD 12 in the vicinity of the current touch input coordinate DC1 using the index image DI1 (step 72; see FIG. 6). It is determined whether or not the user has touched off (step 73). Then, the CPU core 21 proceeds to the next step 74 when the user touches off, and returns to step 70 to repeat the process when the touch operation is continued.

  In step 74, the CPU core 21 executes the third mode based on the third mode flag DF3 that is currently set to ON, and ends the processing by the subroutine. Here, the third mode is a process for performing the display described with reference to the right diagram of FIG. It is a process displayed on LCD12.

  Here, after the third mode flag DF3 is set to ON in the above step 71, if the slide operation is performed to the area above the determination line (that is, No in the above step 70), the above step 66 is executed. Therefore, the third mode flag DF3 is set to off and the second mode flag DF2 is set to on again. That is, the downward slide operation gesture using the touch panel 15 from the area above the determination line to the area below the determination line is canceled, and the upward slide operation from the start point coordinate DC2 to the area above the determination line. Only is recognized as a valid operation gesture.

  In FIG. 15, in the tab designation process in step 51, first, the CPU core 21 sets the fourth mode flag DF4 stored in the RAM 24 to ON (step 81). Next, the CPU core 21 executes the fourth mode based on the fourth mode flag DF4 that is currently turned on (step 82), and advances the processing to the next step. Here, the fourth mode is a process in which other information in the homepage information being browsed corresponding to the touch-operated tab (that is, the tab corresponding to the start point coordinate DC2) is immediately displayed on the first LCD 11. (For example, see the left diagram in FIG. 7 and the left diagram in FIG. 8).

  Next, the CPU core 21 determines whether or not the current touch input coordinate DC1 is in an image area below the determination line including the determination line (hereinafter referred to as an area below the determination line) (step 83). ). Then, the CPU core 21 advances the process to the next step 85 when the touch input coordinate DC1 is in the area below the determination line. On the other hand, when the touch input coordinate DC1 is in an area above the determination line, the CPU core 21 determines whether or not the user has touched off (step 84). Then, when the touch operation is continued, the CPU core 21 returns to step 83 and repeats the process. When the user touches off, the CPU core 21 ends the subroutine. Here, the CPU core 21 sets y = y1−c2 as a determination line used in step 83 based on the start point coordinate DC2 (x1, y1) (c2: constant). Then, if the current touch input coordinate DC1 (xt, yt) is yt ≦ y1-c2, the CPU core 21 determines that the current touch input coordinate DC1 is in the area below the determination line.

  In step 85, the CPU core 21 sets the fifth mode flag DF5 stored in the RAM 24 to ON, and sets the fourth mode flag DF4 and the sixth mode flag DF6 to OFF. Then, the CPU core 21 displays a downward arrow M4 on the information displayed on the second LCD 12 in the vicinity of the current touch input coordinate DC1 using the index image DI1 (step 86; see FIG. 7), and the user It is determined whether or not has been touched off (step 87). Then, the CPU core 21 proceeds to the next step 88 when the user touches off, and proceeds to step 89 when the touch operation is continued.

  In step 88, the CPU core 21 executes the fifth mode based on the fifth mode flag DF5 that is currently turned on, and ends the processing by the subroutine. Here, the fifth mode is a process for performing the display described with reference to the right diagram of FIG. 7. Other information displayed on the first LCD 11 corresponding to the touch-operated tab is displayed as the second mode. This is a process of displaying on the LCD 12. In the fifth mode, the first LCD 11 and the second LCD 12 both display information corresponding to the tab, but the original information displayed before the touch operation is displayed on the first LCD 11. May be redisplayed.

  In step 89, the CPU core 21 determines whether or not the current touch input coordinate DC1 is in an area above the determination line used in step 83. Then, when the touch input coordinate DC1 is in an area above the determination line, the CPU core 21 proceeds to the next step 90. On the other hand, if the CPU core 21 is in the area below the determination line, if the fifth mode flag DF5 is set to ON, the CPU core 21 returns to step 86 and repeats the process, and the fifth mode flag DF5 is set to OFF. If so, the process returns to step 85 to repeat the process (step 94).

  In step 90, the CPU core 21 sets the sixth mode flag DF6 stored in the RAM 24 to ON and sets the fifth mode flag DF5 to OFF. Then, the CPU core 21 displays an up and down arrow M5 on the information displayed on the second LCD 12 in the vicinity of the current touch input coordinate DC1 using the index image DI1 (step 91; see FIG. 8). It is determined whether or not the user has touched off (step 92). Then, the CPU core 21 proceeds to the next step 93 when the user touches off, and returns to step 89 and repeats the process when the touch operation is continued.

  In step 93, the CPU core 21 executes the sixth mode based on the sixth mode flag DF6 that is currently turned on, and ends the processing by the subroutine. Here, the sixth mode is a process of performing the display described with reference to the right diagram of FIG. Correspondingly, this is a process of displaying other information displayed on the first LCD 11 on the second LCD 12.

  Here, after the sixth mode flag DF6 is set to ON in Step 90, when the slide operation is performed to the area below the determination line (that is, No in Step 89), Step 85 is executed. Accordingly, the sixth mode flag DF6 is set off and the fifth mode flag DF5 is set on again. That is, the upward slide operation gesture using the touch panel 15 from the area below the determination line to the area above the determination line is canceled, and the downward slide operation from the start point DC2 to the area below the determination line. Only is recognized as a valid operation gesture.

  In FIG. 16, in the background designating process in step 52, first, the CPU core 21 determines whether or not the enclosing mode is currently set (step 101). If the CPU core 21 is not in the enclosing mode, the process proceeds to the next step 111 (FIG. 17). On the other hand, the CPU core 21 proceeds to the next step 102 in the case of the enclosure mode. Here, as described with reference to FIG. 9, the enclosure mode is an operation mode that is shifted when the user taps the enclosure mode icon Ia.

  In step 102, the CPU core 21 determines whether or not the current touch input coordinate DC1 is in the start point vicinity region. Next, the CPU core 21 determines whether or not to form an enclosing curve when the locus coordinates DC3 are connected in time series order (step 103). When the touch input coordinate DC1 is in the vicinity of the start point and the locus coordinate DC3 group forms an enclosing curve (both Step 102 and Step 103 are Yes; see the left diagram in FIG. 9), the CPU core 21 The process proceeds to the next step 105. On the other hand, when the touch input coordinate DC1 is not in the vicinity of the start point or the locus coordinate DC3 group does not form an enclosing curve (No in Step 102 and Step 103), the CPU core 21 is touched off by the user. Whether or not (step 104). Then, when the user touches off, the CPU core 21 ends the processing by the subroutine. On the other hand, when the touch operation is continued, the CPU core 21 adds and stores the current touch input coordinate DC1 as the locus coordinate DC3 in the RAM 24 (step 109), and returns to step 101 to continue the process.

  In step 105, the CPU core 21 sets the seventh mode flag DF7 stored in the RAM 24 to ON. Then, the CPU core 21 displays the trajectory M6 on the information displayed on the second LCD 12 along the current trajectory coordinate DC3 using the trajectory image DI2 (step 106; see FIG. 9), and the user It is determined whether or not touch-off has been performed (step 107). The CPU core 21 proceeds to the next step 108 when the user touches off, and returns to step 102 to continue the process when the touch operation is continued.

  In step 108, the CPU core 21 executes the seventh mode based on the seventh mode flag DF7 that is currently turned on, and ends the processing by the subroutine. The CPU core 21 clears all the trajectory coordinates DC3 stored in the RAM 24 after executing the seventh mode. Here, the seventh mode is a process for performing the display described with reference to the right diagram of FIG. 9. The display mode of the second LCD 12 is not changed, and the information surrounded by the locus M6 is enlarged and changed. 1 is a process of displaying on one LCD 11.

  In FIG. 17, when the background designation process in step 52 is not the enclosed mode (No in step 101), the CPU core 21 executes step 111. In step 111, the CPU core 21 determines whether or not the current touch input coordinate DC1 is in the upper area AT (see FIG. 11). Then, when the touch input coordinate DC1 is in the upper area AT, the CPU core 21 advances the process to the next step 112. On the other hand, if the touch input coordinate DC1 is not in the upper area AT, the CPU core 21 proceeds to the next step 116. Here, the CPU core 21 sets the upper area AT used in step 111 with x1−k1 ≦ x ≦ x1 + k1 and y ≧ y1 + k2 based on the starting point coordinate DC2 (x1, y1) (k1, k2: constant). . Then, the CPU core 21 determines that the current touch input coordinate DC1 is in the upper area AT if the current touch input coordinate DC1 (xt, yt) is x1−k1 ≦ xt ≦ x1 + k1 and yt ≧ y1 + k2. To do.

  In step 112, the CPU core 21 sets the eighth mode flag DF8 stored in the RAM 24 to ON, and sets the ninth to twelfth mode flags DF9 to DF12 to OFF. Then, the CPU core 21 displays the guide image M7 in the vicinity of the current touch input coordinate DC1 and the guide image M7 in the vicinity of the start point coordinate DC2 on the information displayed on the second LCD 12 using the index image DI1. (Step 113; see FIG. 10), it is determined whether or not the user has touched off (Step 114). Then, the CPU core 21 proceeds to the next step 115 when the user touches off, and proceeds to step 116 when the touch operation is continued.

  In step 115, the CPU core 21 executes the eighth mode on the basis of the eighth mode flag DF8 that is currently turned on, and ends the processing by the subroutine. Here, the eighth mode is a process for performing the display described with reference to the right diagram of FIG. 10, and the information displayed on the second LCD 12 is changed to the first information while the display information on the second LCD 12 is left. This process is also displayed on the LCD 11.

  In step 116, the CPU core 21 determines whether or not the current touch input coordinate DC1 is in the predetermined area AM (see FIG. 11). If the touch input coordinate DC1 is not in the predetermined area AM, the CPU core 21 proceeds to the next step 131 (FIG. 18). On the other hand, when the touch input coordinate DC1 is in the predetermined area AM, the CPU core 21 proceeds to the next step 118 if the eighth mode flag DF8 is set to ON, and sets the eighth mode flag DF8 to OFF. If so, the process proceeds to the next step 131 (step 117). Here, the CPU core 21 sets the predetermined area AM used in step 116 based on the start point coordinate DC2 (x1, y1) as x1−k1 ≦ x ≦ x1 + k1 and y1−k2 <y <y1 + k2 (k1, k2: constant). If the current touch input coordinate DC1 (xt, yt) is x1−k1 ≦ xt ≦ x1 + k1 and y1−k2 <yt <y1 + k2, the CPU core 21 determines that the current touch input coordinate DC1 is the predetermined area AM. It is determined that

  In step 118, the CPU core 21 sets the ninth mode flag DF9 stored in the RAM 24 to ON and sets the eighth mode flag DF8 to OFF. Then, the CPU core 21 displays the guide image M7 on the information displayed on the second LCD 12 in the vicinity of the current touch input coordinate DC1 and the up and down arrow M9 and the start point coordinate DC2 using the index image DI1. (Step 119; see FIG. 12), it is determined whether or not the user has touched off (Step 120). Then, the CPU core 21 proceeds to the next step 121 when the user touches off, and proceeds to step 131 (FIG. 18) when the touch operation is continued.

  In step 121, the CPU core 21 executes the ninth mode based on the ninth mode flag DF9 that is currently turned on, and ends the processing by the subroutine. Here, the ninth mode is a process for performing the display described with reference to the right diagram of FIG. 12, and the information displayed on the first LCD 11 and the information displayed on the second LCD 12 are switched. This is a process of displaying on the first LCD 11 and the second LCD 12.

  In step 131 of FIG. 18, the CPU core 21 determines whether or not the current touch input coordinate DC1 is in the lower area AB (see FIG. 11). If the touch input coordinate DC1 is not in the lower area AB, the CPU core 21 proceeds to the next step 136. On the other hand, when the touch input coordinate DC1 is in the lower area AB, the CPU core 21 advances the process to the next step 132. Here, the CPU core 21 sets the lower region AB used in step 131 with reference to the starting point coordinate DC2 (x1, y1) by x1−k1 ≦ x ≦ x1 + k1 and y ≦ y1−k2 (k1, k2: constant). Then, the CPU core 21 determines that the current touch input coordinate DC1 is in the lower area AB if the current touch input coordinate DC1 (xt, yt) is x1−k1 ≦ xt ≦ x1 + k1 and yt ≦ y1−k2. Judge.

  In step 132, the CPU core 21 turns on the tenth mode flag DF10 stored in the RAM 24, and turns off the eighth, ninth, eleventh, and twelfth mode flags DF8, DF9, DF11, and DF12. Set to. Then, the CPU core 21 uses the index image DI1 to display a guide arrow M10 (not shown) near the current touch input coordinate DC1 and a guide image M7 (see FIG. 10) around the start point coordinate DC2 on the second LCD 12. (Step 133), and it is determined whether or not the user has touched off (step 134). Then, the CPU core 21 proceeds to the next step 135 when the user touches off, and proceeds to step 136 when the touch operation is continued.

  In step 135, the CPU core 21 executes the tenth mode based on the tenth mode flag DF10 that is currently set to ON, and ends the processing by the subroutine. Here, the tenth mode is a process of displaying the information displayed on the first LCD 11 on the second LCD 12 while leaving the display information on the first LCD 11. That is, in the tenth mode, the information (first display) displayed on the starting side in the user's slide operation direction (downward from the first LCD 11 toward the second LCD 12) while retaining the display information on the first LCD 11. Information displayed on the LCD 11) is displayed on the display unit (second LCD 12) mounted in the slide operation direction.

  In step 136, the CPU core 21 determines whether or not the current touch input coordinate DC1 is in the left area AL (see FIG. 11). Then, when the touch input coordinate DC1 is not in the left area AL, the CPU core 21 advances the process to the next step 141. On the other hand, if the touch input coordinate DC1 is in the left area AL, the CPU core 21 proceeds to the next step 137. Here, the CPU core 21 sets the left side area AL used in step 136 based on the start point coordinate DC2 (x1, y1) by x <x1-k1 (k1: constant). Then, if the current touch input coordinate DC1 (xt, yt) is xt <x1-k1, the CPU core 21 determines that the current touch input coordinate DC1 is in the left area AL.

  In step 137, the CPU core 21 sets the eleventh mode flag DF11 stored in the RAM 24 to ON, and sets the eighth to tenth mode flags DF8 to DF10 and the twelfth mode flag DF12 to OFF. Then, the CPU core 21 uses the index image DI1 to display the guide image M7 (see FIG. 10) around the start point coordinate DC2 and the left arrow M11 (not shown) near the current touch input coordinate DC1 and the second LCD 12. (Step 138), and it is determined whether or not the user has touched off (step 139). Then, the CPU core 21 proceeds to the next step 140 when the user touches off, and proceeds to step 141 when the touch operation is continued.

  In step 140, the CPU core 21 executes the eleventh mode based on the eleventh mode flag DF11 that is currently turned on, and ends the processing by the subroutine. Here, the eleventh mode refers to past information displayed on the second LCD 12 or the present second LCD 12 while leaving the display information on the first LCD 11 in accordance with the user's leftward sliding operation. This is a process for displaying information corresponding to the previous page of information displayed on the second LCD 12. For example, in the eleventh mode, a so-called “return” operation of a browser or an operation of displaying a previous page in an electronic book or the like can be performed on the information displayed on the second LCD 12. When the electronic book is displayed on the second LCD 12, the left direction is generally an instruction to display the previous page in the horizontally written electronic book, but the document configuration of the electronic book to be displayed (for example, vertical writing, comics, Depending on the (foreign language document), the instruction to display the next page may be set to the left slide operation.

  In step 141, the CPU core 21 determines whether or not the current touch input coordinate DC1 is in the right area AR (see FIG. 11). If the touch input coordinate DC1 is not in the right area AR, the CPU core 21 returns to step 111 (FIG. 17) and continues the process. On the other hand, if the touch input coordinate DC1 is in the right area AR, the CPU core 21 proceeds to the next step 142. Here, the CPU core 21 sets the right area AR used in step 141 with x> x1 + k1 based on the start point coordinate DC2 (x1, y1) (k1: constant). Then, if the current touch input coordinate DC1 (xt, yt) is xt> x1 + k1, the CPU core 21 determines that the current touch input coordinate DC1 is in the right area AR.

  In step 142, the CPU core 21 sets the twelfth mode flag DF12 stored in the RAM 24 to ON, and sets the eighth to eleventh mode flags DF8 to DF11 to OFF. Then, the CPU core 21 uses the index image DI1 to display a right arrow M12 (not shown) in the vicinity of the current touch input coordinate DC1 and a guide image M7 (see FIG. 10) around the start point coordinate DC2 on the second LCD 12. (Step 143), and determines whether or not the user has touched off (step 144). Then, the CPU core 21 proceeds to the next step 145 when the user touches off, and proceeds to step 111 when the touch operation is continued.

  In step 145, the CPU core 21 executes the twelfth mode based on the twelfth mode flag DF12 that is currently set to ON, and ends the processing by the subroutine. Here, the twelfth mode refers to past information or current information displayed on the second LCD 12 as the next processing while leaving display information on the first LCD 11 in accordance with a user's rightward slide operation. In this process, information corresponding to the next page of information displayed on the second LCD 12 is displayed on the second LCD 12. For example, in the twelfth mode, a so-called “forward” operation of the browser or an operation of displaying the next page in an electronic book or the like can be performed on the information displayed on the second LCD 12. When an electronic book is displayed on the second LCD 12, the right direction is generally an instruction to display the next page in a horizontally written electronic book, but the previous page is displayed according to the document configuration of the electronic book to be displayed. You may set the instruction to slide to the right.

  Here, in the background designating process other than the enclosing mode, after any of the eighth to twelfth mode flags DF8 to DF12 is set to ON, when the slide operation is performed from the currently touched area to another area, the ON is performed. The mode flag that was set to is set to OFF, and the other mode flags are set to ON. For example, when the eighth mode flag DF8 is set to ON in step 112 and a slide operation is performed to the left area AL (that is, Yes in step 136), the eighth mode flag DF8 is set to OFF and the eleventh mode is set. The flag DF11 is set on. In this case, the upward slide operation gesture using the touch panel 15 from the start point coordinate DC2 to the upper area AT is canceled, and only the left slide operation from the start point coordinate DC2 to the left area AL is recognized as an effective operation gesture. Is done. That is, it is possible to easily cancel a slide operation gesture for performing a predetermined operation, and only a slide operation from the start point DC2 to the corresponding region is recognized as an effective operation gesture by simply sliding to another region. can do.

  In the above description, the gesture in the four directions using the touch panel 15 is configured to be recognized. However, it may be possible to recognize the operation gesture in five or more directions. By further subdividing each other area centering on the predetermined area AM, gestures in five directions or more using the touch panel 15 can be recognized. In this case, the guide image M7 is displayed as a rectangular pattern as a boundary of the predetermined area AM (see FIG. 10), and is a target image for the user to recognize an effective operation gesture using the touch panel 15. It may be displayed in the shape of the shape. For example, when it is possible to recognize not only four-way gestures using the touch panel 15 as described above but also multi-directional operation gestures, polygonal symbols corresponding to the number of direction segments may be displayed.

  As described above, in the game apparatus 1, a highly useful process can be executed by an intuitive operation in response to a user's slide operation using the touch panel 15. For example, when the user performs an upward slide operation using the touch panel 15, an image (response image, enlarged image, second image) acquired by processing according to the start point coordinate DC <b> 2 while leaving the display information on the second LCD 12. Image displayed on the LCD 12) is displayed on the first LCD 11 in the slide operation direction (upward direction from the second LCD 12 toward the first LCD 11). Further, when the user performs a downward sliding operation using the touch panel 15, an image acquired by processing according to the start point coordinate DC2 is in the sliding operation direction (downward direction from the first LCD 11 toward the second LCD 12). It is displayed on a certain second LCD 12. Further, when the user performs a sliding operation that reciprocates in the vertical direction using the touch panel 15, the image displayed on the second LCD 12 is displayed on the first LCD 11, and is acquired by processing according to the start point coordinate DC2. Since an image (response image, image displayed on the first LCD 11) is displayed on the first LCD 11, a slide operation direction (vertical direction reciprocating in the direction in which the first LCD 11 and the second LCD 12 are located) The information displayed on the upper and lower display sections (first LCD 11 and second LCD 12) is displayed so as to be switched. As described above, the direction of the slide operation input by the user to the touch panel 15 and the display processing corresponding thereto are intuitive. In addition, displaying the information corresponding to the process on the other display unit while leaving the original display information can be useful in various situations.

  In the above description, each input coordinate process has been described using a specific operation procedure for specific description. However, these are only examples, and the present invention is limited to these operation procedures. It goes without saying that there is nothing. For example, the number of slide operations that can be recognized as operation gestures on the touch panel 15 may be further increased.

  Further, in the above description, in order to make the description more specific, description has been made using an example in which data such as documents and images published on the network is browsed on the first LCD 11 and the second LCD 12, but other information is also available. Alternatively, the image may be displayed on the first LCD 11 and the second LCD 12. For example, a digital book that is converted into digital data and recorded on an electronic medium, such as a dictionary, may be displayed on the first LCD 11 and the second LCD 12 as viewed on the game apparatus 1.

  In the above-described embodiment, as an example of the liquid crystal display unit for two screens, a case where the first LCD 11 and the second LCD 12 that are physically separated from each other are arranged one above the other (in the case of two upper and lower screens) will be described. did. However, the configuration of the display screen for two screens may be other configurations. For example, the first LCD 11 and the second LCD 12 may be arranged on the left and right on one main surface of the lower housing 13b. In addition, a vertically long LCD having the same horizontal width as the second LCD 12 and having a vertical length twice as long (that is, a single LCD having a vertical display size of two screens) is placed below. It may be arranged on one main surface of the side housing 13b so that the first and second display images are displayed vertically (that is, displayed adjacently without the upper and lower boundary portions). In addition, a horizontally long LCD having the same vertical width as the second LCD 12 and having a width twice as long as the second LCD 12 is disposed on one main surface of the lower housing 13b, and the first and second in the horizontal direction. These display images may be displayed on the left and right (that is, displayed adjacently without the left and right boundary portions). That is, the first and second display images may be displayed by physically dividing one screen into two. Regardless of the form of the game image, the present invention can be similarly realized by disposing the touch panel 15 on the screen on which the second display image is displayed. When the first and second display images are displayed by physically dividing one screen into two, the touch panel 15 may be disposed on the entire screen.

  In the embodiment described above, the touch panel 15 is integrally provided on the game apparatus 1. However, it goes without saying that the present invention can be realized even if the game apparatus and the touch panel are configured separately. Further, the touch panel 15 may be provided on the upper surface of the first LCD 11.

  Moreover, in the said Example, although the touch panel was used as an input means of the game device 1, other pointing devices may be used. Here, the pointing device is an input device that specifies an input position and coordinates on the screen. For example, a mouse, a trackpad, a trackball, or the like is used as an input means, and is calculated from an output value output from the input means The present invention can be similarly realized by using the information of the screen coordinate system.

  In the above embodiment, the touch panel 15 is integrally provided in the game apparatus 1, but an information processing apparatus (input coordinate processing apparatus) such as a general personal computer using the touch panel as one of the input means may be used. .

  The input coordinate processing program and the input coordinate processing apparatus according to the present invention can execute highly useful display processing by an intuitive operation according to an operation using a pointing device by a user, and are disclosed on the network. It is useful as an information processing apparatus such as a game apparatus that browses information such as documents and images that are displayed or displays display information such as an electronic book on a display apparatus, a program that is executed by the information processing apparatus, and the like.

External view of game apparatus 1 for executing input coordinate processing program of the present invention The block diagram which shows the internal structure of the game device 1 of FIG. The figure which shows the example of a screen display of the initial stage displayed on 1st LCD11 and 2nd LCD12 The figure which shows the example of a screen display displayed on the 1st LCD11 and the 2nd LCD12 when tapping the touch panel 15 on the link destination displayed on the 2nd LCD12. The figure which shows the example of a screen display displayed on the 1st LCD11 and the 2nd LCD12 when the touch panel 15 is slid upward from the link destination displayed on the 2nd LCD12. Screen display examples displayed on the first LCD 11 and the second LCD 12 when the touch panel 15 is slid upward from the link destination displayed on the second LCD 12 and then reciprocated downward. Illustration The figure which shows the example of a screen display displayed on the 1st LCD11 and the 2nd LCD12 when the touch panel 15 is slid downward from the tab displayed on the 2nd LCD12. An example of a screen display displayed on the first LCD 11 and the second LCD 12 when the slide operation is performed to reciprocate upward after sliding the touch panel 15 downward from the tab displayed on the second LCD 12 is shown. Figure The figure which shows the example of a screen display displayed on the 1st LCD11 and the 2nd LCD12 when the touch panel 15 is slid so that the one part information displayed on the 2nd LCD12 may be enclosed. The figure which shows the example of a screen display displayed on the 1st LCD11 and the 2nd LCD12 when the touch panel 15 is slid upward from the background image displayed on the 2nd LCD12. The figure for demonstrating each area | region set when the touch panel 15 on the background image displayed on the 2nd LCD 12 is touch-operated. Screen display examples displayed on the first LCD 11 and the second LCD 12 when the touch panel 15 is slid upward from the background image displayed on the second LCD 12 and then reciprocated downward. Illustration Flowchart showing an operation in which the game apparatus 1 performs an input coordinate process by executing an input coordinate process program executed by the game apparatus 1 Subroutine showing detailed operation of the link designation process in step 50 in FIG. Subroutine showing detailed operations for the tab designation process in step 51 in FIG. Subroutine showing the detailed operation of the background designating process in step 52 in FIG. Subroutine showing the detailed operation of the background designating process in step 52 in FIG. Subroutine showing the detailed operation of the background designating process in step 52 in FIG. The figure which shows an example of the various data memorize | stored in RAM24 by the processing operation based on FIG.

Explanation of symbols

1 game device 11 first LCD
12 Second LCD
13 Housing 13a Upper housing 13b Lower housing 14 Operation switch 14a Cross switch 14b Start switch 14c Select switch 14d A button 14e B button 14f X button 14g Y button 14h Power switch 14L L button 14R R button 15 Touch panel 16 Stick 17 Memory card 17a ROM
17b RAM
18a, 18b Sound release hole 20 Electronic circuit board 21 CPU core 22 Bus 23 Connector 24 RAM
25 I / F circuit 26 1st GPU
27 Second GPU
28 First VRAM
29 Second VRAM
30a Right speaker 30b Left speaker 31 LCD controller 32 Register 33 Wireless communication unit

Claims (11)

Input executed by a computer that executes display processing for displaying one screen at a time on the first display unit and the second display unit constituting the display device based on input coordinates output from the pointing device in accordance with a user operation A coordinate processing program,
In the computer,
An input coordinate storage step of detecting coordinate information based on a display coordinate system of an image displayed on the first display unit and storing it in a memory in accordance with input coordinates output from the pointing device;
Of the series of coordinate information stored in the input coordinate storage step, the first coordinate information is set as a reference coordinate and stored in a memory as a reference coordinate storage step.
A processing step of acquiring a display image based on at least one coordinate information of the series of coordinate information ;
It is determined whether the operation direction indicated by the series of coordinate information in the display coordinate system with respect to the reference coordinate indicates a reference direction from the position of the first display unit to the position of the second display unit. A determination step, and
When the determination result at the determination step is affirmative, the display image acquired at the processing step is displayed on the second display unit, and when the determination result at the determination step is negative, the display is acquired at the processing step. An input coordinate processing program for executing a display control step of displaying the displayed image on the first display unit . In the determination step, when at least the latest coordinates in the coordinate group indicated by the series of coordinate information are present in an area closer to the reference direction than the determination line set on the reference direction side of the reference coordinates, the series The input coordinate processing program according to claim 1, wherein the operation direction indicated by the coordinate information is determined to indicate the reference direction. Further causing the computer to execute a release determination step for determining whether or not the input coordinate is output from the pointing device or whether the state has been released,
In the display control step, when the determination result in the release determination step is affirmative and the determination result in the determination step is affirmative, the display image acquired in the processing step is displayed on the second display unit. The display image acquired in the processing step is displayed on the first display unit when the determination result in the release determination step is affirmative and the determination result in the determination step is negative. Or the input coordinate processing program of 2. The computer executes a display process of a web browser that downloads a file via a communication unit that communicates with a network and browses on the display device based on the input coordinates,
In the previous Kisho management step, when the reference coordinate is located in the answer area of the web browser, the response image corresponding to the response region is acquired,
Prior Symbol Table示制control step, the case where the determination result of determination by the step is affirmative, with the response image Ru is displayed on the second display unit, when the determination result of determination by the step is negative, The input coordinate processing program according to claim 1, wherein the response image is displayed on the first display unit . In the previous Kisho management step, the reference coordinates when located in the background region of the web browser, at least a portion of the image displayed on said first display unit is acquired,
Prior Symbol Table示制control step, when the determination result by the determination step is positive, with displays at least a part of the image displayed on said first display portion on said second display unit, according to the decision step 5. The input coordinate processing program according to claim 4 , wherein when the determination result is negative, at least a part of the image displayed on the first display unit is displayed on the first display unit . The reference direction is an upward direction or a downward direction in which the second display unit is provided with respect to the first display unit of the display device,
In the determination step, it is further determined whether or not the reference coordinates are located in a background area of a web browser and the operation direction indicates a left direction or a right direction,
In the previous Kisho management step, when the reference coordinate by said determining step is positioned in the background area of the web browser, and, where the operation direction is determined to be the left or right, the past in the process steps image acquired is acquired,
Prior Symbol Table示制control step, when the operation direction by the determination step is determined to be left or right, appears in the display image obtained in the past on the first display unit, to claim 4 The input coordinate processing program described. In the determination step, it is further determined whether or not the locus of the series of coordinate information surrounds a predetermined area displayed on the first display unit,
In the previous Kisho management step, if the trajectory of the set of coordinate information by said determination step determines the pre Kisho constant regions that enclose an enlarged image obtained by enlarging the image of the predetermined area is acquired,
Prior Symbol Table示制control step, if the trajectory of the set of coordinate information by said determination step determines that surrounds the predetermined area, causes displaying the enlarged image on the second display unit, according to claim 1 The input coordinate processing program described in 1. Input executed by a computer that executes display processing for displaying one screen at a time on the first display unit and the second display unit constituting the display device based on input coordinates output from the pointing device in accordance with a user operation A coordinate processing program,
In the computer,
An input coordinate storage step of detecting coordinate information based on a display coordinate system of an image displayed on the first display unit and storing it in a memory in accordance with input coordinates output from the pointing device;
Of the series of coordinate information stored in the input coordinate storage step, the first coordinate information is set as a reference coordinate and stored in a memory as a reference coordinate storage step.
A reference direction in which an operation direction indicated by the series of coordinate information in the display coordinate system with respect to the reference coordinate is an upper direction or a lower direction in which the second display unit is provided with respect to the first display unit is defined. A first determination step for determining whether or not
A first display control step of displaying a page image displayed on the first display unit on the second display unit when the determination result in the first determination step is affirmative;
A second determination step of determining whether or not the operation direction indicates a left direction or a right direction; and
When the determination result by the second determination step is affirmative, a second display control step of displaying a page image different from the page image displayed on the first display unit on the first display unit is executed. Input coordinate processing program. In the second display control step, when the second determination step determines that the operation direction is the left direction, a page image before the page image displayed on the first display unit is displayed in the first display. When the second determination step determines that the operation direction is the right direction, the page image next to the page image displayed on the first display unit is displayed on the first display unit. The input coordinate processing program according to claim 8. An input coordinate processing apparatus that executes display processing for displaying one screen at a time on a first display unit and a second display unit constituting a display device based on input coordinates output from a pointing device in accordance with a user operation. And
Storage means;
Input coordinate storage processing means for detecting coordinate information based on a display coordinate system of an image displayed on the first display unit according to input coordinates output from the pointing device, and storing the detected coordinate information in the storage means;
Of the series of coordinate information stored by the input coordinate storage processing means, reference coordinate storage processing means for setting the first coordinate information as reference coordinates and storing it in the storage means;
Processing means for acquiring a display image based on at least one coordinate information of the series of coordinate information;
It is determined whether the operation direction indicated by the series of coordinate information in the display coordinate system with respect to the reference coordinate indicates a reference direction from the position of the first display unit to the position of the second display unit. A determination means;
When the determination result by the determination means is affirmative, the display image acquired by the processing means is displayed on the second display unit, and when the determination result by the determination means is negative, the display is acquired by the processing means. An input coordinate processing apparatus comprising display control means for displaying the displayed image on the first display unit . An input coordinate processing apparatus that executes display processing for displaying one screen at a time on a first display unit and a second display unit constituting a display device based on input coordinates output from a pointing device in accordance with a user operation. And
Storage means;
Input coordinate storage processing means for detecting coordinate information based on a display coordinate system of an image displayed on the first display unit according to input coordinates output from the pointing device, and storing the detected coordinate information in the storage means;
Among the series of coordinate information stored by the input coordinate storage processing means, reference coordinate storage processing means for setting the first coordinate information as reference coordinates and storing it in the storage means;
A reference direction in which an operation direction indicated by the series of coordinate information in the display coordinate system with respect to the reference coordinate is an upper direction or a lower direction in which the second display unit is provided with respect to the first display unit is defined. First determining means for determining whether or not
A first display control means for displaying a page image displayed on the first display section on the second display section when the determination result by the first determination section is affirmative;
Second determination means for determining whether or not the operation direction indicates a left direction or a right direction;
A second display control unit that displays a page image different from the page image displayed on the first display unit on the first display unit when the determination result by the second determination unit is affirmative; Input coordinate processing device.

Images