JP6614539B1 - Program and information processing apparatus - Google Patents

Abstract

[PROBLEMS] To reduce the possibility of incorrect input even when a touch position on a touch panel may be displaced. A program related to a predetermined game includes a processor, a touch position information acquisition unit 113 that acquires touch position information indicating a touch position on a touch panel, and a touch position in a first operation direction related to the predetermined game. When it exists in the first input area for inputting an instruction and the first condition is satisfied, the position based on the touch position is specified as the first feature position, and the touch position is determined to be the second value related to the predetermined game. A feature position specifying unit 114 that specifies a position based on the touch position as the second feature position when the second input region exists in the second input area for inputting an operation direction instruction and satisfies the second condition; Based on the feature position and the second feature position, the input area determining unit 115 functions to determine the positions of the first input area and the second input area. [Selection] Figure 5

Description

  The present invention relates to a program and an information processing apparatus.

  Devices that accept input of instructions from users using a touch panel have become widespread (see, for example, Patent Document 1).

JP 2014-044455 A

  By the way, a predetermined input area for inputting a desired instruction may be provided at a predetermined position of the touch panel. In such a case, the user can input a desired instruction by touching a predetermined input area of the touch panel.

  However, for example, when the user tries to touch a predetermined input area without looking at the touch panel, or when the user tries to touch the predetermined input area multiple times, the touch position of the user is The position may be shifted to a position different from the predetermined input area. When the user's touch position deviates from a predetermined input area, there is a problem that the user cannot input a desired instruction.

  The present invention has been made in view of the above-described circumstances, and is a technique that can reduce the possibility of erroneous input even when the touch position on the touch panel may be displaced. Providing is one of the resolution issues.

  In order to solve the above problems, a program according to one embodiment of the present invention includes a processor, an acquisition unit that acquires touch position information indicating a touch position on a touch panel, and a touch period during which the touch on the touch panel continues. The touch position indicated by the touch position information acquired by the acquisition unit exists in a first input area for inputting a first operation direction instruction related to the game, and the first condition related to the touch position is When satisfied, the position based on the touch position is specified as the first position, and the touch position indicated by the touch position information acquired by the acquisition unit in the touch period is the second operation direction related to the game. When the second condition that is present in the second input area for inputting an instruction and satisfies the second condition related to the touch position, the position based on the touch position is set to the second A specifying unit that specifies the position; and a determination unit that determines positions of the first input region and the second input region based on the first position and the second position specified by the specifying unit. To function.

It is explanatory drawing which shows an example of the external appearance of the terminal device 10 which concerns on embodiment of this invention. 2 is an explanatory diagram illustrating an example of an appearance of a terminal device 10. FIG. 2 is an explanatory diagram illustrating an example of an appearance of a terminal device 10. FIG. 2 is an explanatory diagram illustrating an example of an appearance of a terminal device 10. FIG. 2 is a block diagram illustrating an example of a configuration of a terminal device 10. FIG. 2 is a block diagram illustrating an example of a hardware configuration of a terminal device 10. FIG. It is explanatory drawing which shows the example of a touch position change. It is explanatory drawing which shows the example of a touch position change. It is explanatory drawing which shows the example of a touch position change. It is explanatory drawing which shows the example of a touch position change. 4 is a flowchart illustrating an example of the operation of the terminal device 10. 10 is an explanatory diagram illustrating an example of a touch position change according to Modification Example 1. FIG. 10 is an explanatory diagram illustrating an example of a touch position change according to Modification Example 1. FIG. 12 is an explanatory diagram illustrating an example of a touch position change according to Modification 2. FIG. 12 is an explanatory diagram illustrating a touch position change example according to Modification 3. FIG. 10 is an explanatory diagram illustrating an example of a touch position change according to Modification Example 5. FIG. 14 is an explanatory diagram illustrating an example of an input region R [m] according to Modification 6. FIG. 11 is an explanatory diagram illustrating an example of an operation region V according to Modification Example 7. FIG. 10 is an explanatory diagram illustrating an example of an operation region V according to Modification Example 8. FIG. 10 is an explanatory diagram illustrating an example of an operation region V according to Modification 9. FIG. It is a block diagram which shows an example of a structure of information processing system SYS which concerns on the modification 13. FIG.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. In each figure, the size and scale of each part are appropriately changed from the actual ones. Further, since the embodiments described below are preferable specific examples of the present invention, various technically preferable limitations are given. However, the scope of the present invention is particularly limited in the following description. Unless otherwise stated, the present invention is not limited to these forms.

[A. Embodiment]
Embodiments of the present invention will be described below.

[1. Overview of terminal device]
Hereinafter, an example of an outline of the terminal device 10 according to the present embodiment will be described with reference to FIGS. 1 to 4.

  1 to 4 are explanatory diagrams for explaining an example of the appearance of the terminal device 10. The terminal device 10 is a portable information processing device such as a smartphone, a tablet terminal, or a portable game device. However, the terminal device 10 may be a stationary information processing device such as a business game device or a desktop personal computer.

As illustrated in FIGS. 1 to 4, the terminal device 10 includes a touch panel 1002. The touch panel 1002 functions as the display unit 12 that can display various images (see FIG. 5). Further, the touch panel 1002 functions as the input unit 13 that receives an instruction input from the user U of the terminal device 10 (see FIG. 5). Specifically, when the touch panel 1002 is in contact with the touch panel 1002, the touch panel 1002 detects the touch position P that is the contact position of the object on the touch panel 1002, and the touch position information indicating the detected touch position P. Are output periodically.
In the following, it is assumed as an example that the object that contacts the touch panel 1002 is the finger FG of the user U.

  In this embodiment, for convenience of explanation, as shown in FIGS. 1 to 4, a touch panel coordinate system ΣD that is a coordinate system fixed to the touch panel 1002 is introduced. Specifically, the touch panel coordinate system ΣD is, for example, a two-axis orthogonal coordinate system having an origin OD fixed at a predetermined position of the touch panel 1002 and having an XD axis and a YD axis orthogonal to each other.

  In the present embodiment, the terminal apparatus 10 displays an image related to a predetermined game on the touch panel 1002 by executing a program (an example of a “program”) related to a predetermined game. Specifically, when the terminal device 10 executes a predetermined game, for example, as illustrated in FIG. 1, the terminal device 10 displays a virtual space SP related to the predetermined game on the touch panel 1002 and the virtual game. A character CR relating to a predetermined game existing in the space SP is displayed.

In the present embodiment, as illustrated in FIG. 2, when the terminal device 10 changes from a state in which the finger FG of the user U is not in contact with the touch panel 1002 to a state in contact, the finger on the touch panel 1002 The touch position P of FG is set as the reference position OV, and the operation region V is set for the position based on the reference position OV. The operation area V is a so-called virtual pad, and is an area for receiving an input related to the operation of the character CR by the user U.
In the present embodiment, as shown in FIG. 2, it is assumed as an example that the operation region V is a region inside a circle BdR having a radius r centered on the reference position OV. Moreover, in this embodiment, the case where the operation area | region V is displayed on the touchscreen 1002 in the aspect which can be visually recognized by the user U is assumed as an example. However, the operation area V may be a virtual area provided on the touch panel 1002 so as not to be visually recognized by the user U.
Hereinafter, the change from the state in which the finger FG of the user U is not in contact with the touch panel 1002 to the state in contact is referred to as “touch-in”.

  In the present embodiment, the terminal device 10 maintains the state in which the operation region V is set on the touch panel 1002 during the touch period TV, which is a period during which the user U's finger FG maintains contact with the touch panel 1002. When the terminal device 10 changes from a state in which the user U's finger FG is in contact with the touch panel 1002 to a state in which the user U's finger FG is not in contact, the terminal device 10 extinguishes the operation region V set in the touch panel 1002.

  As shown in FIG. 2, in this embodiment, the case where the operation area V includes four input areas R [1] to R [4] is assumed as an example. Further, in the present embodiment, it is assumed as an example that the input area R [m] is an area for inputting an instruction in the direction in which the face of the character CR faces in the touch panel coordinate system ΣD (m is 1 ≦ 1). Natural number satisfying m ≦ 4). However, the input area R [m] may be an area for inputting an instruction in the direction in which the face of the character CR faces in the virtual space SP. In the present embodiment, the direction in which the face of the character CR faces is an example of the “operation direction related to the game”.

  In the following, for convenience of explanation, an operation area coordinate system ΣV, which is a coordinate system having the reference position OV as the origin, is introduced. Specifically, the operation region coordinate system ΣV is, for example, a two-axis orthogonal coordinate system having an XV axis and a YV axis orthogonal to each other with the reference position OV as the origin. In this embodiment, the case where the XV axis and the XD axis are parallel and the YV axis and the YD axis are parallel is assumed as an example. However, the XV axis may have a different direction from the XD axis, and the YV axis may have a different direction from the YD axis. The portion of the XV axis on the + XV side from the reference position OV is an example of the “first reference line”, and the portion of the XV axis on the −XV side of the reference position OV is an example of the “second reference line”. It is.

In the present embodiment, as an example, as illustrated in FIG. 2, the terminal device 10 sets the input region R [1] as a region located in the + XV direction (an example of “first direction”) from the reference position OV. The input area R [2] is set as an area located in the −XV direction (an example of “second direction”) from the reference position OV, and the input area R [3] is set to be greater than the reference position OV. It is set as a region located in the + YV direction (an example of the “third direction”), and the input region R [4] is positioned in the −YV direction (another example of the “third direction”) relative to the reference position OV. Set as the area to perform.
More specifically, in the present embodiment, the terminal apparatus 10 uses the input region R [1] as a starting point at the reference position OV, and the angle θ (an example of “first angle”) with the + XV direction set to the −YV side. A line segment Bd [1] [4] extending in a direction inclined by an angle and a line segment Bd [1] [3] extending in a direction inclined by an angle θ from the reference position OV to the + YV side on the + YV side. ] And a circle-shaped region between the circles BdR. In addition, the terminal device 10 extends the input region R [2] in a direction inclined from the reference position OV by the angle θ (an example of “second angle”) with respect to the −XV direction to the −YV side. A line segment Bd [2] [4], a line segment Bd [2] [3] extending from the reference position OV as a starting point and inclined to the + YV side by an angle θ, a circle BdR, Set as a fan-shaped area between. Further, the terminal device 10 sets the input area R [3] as a sector area between the line segment Bd [1] [3], the line segment Bd [2] [3], and the circle BdR. Further, the terminal device 10 sets the input area R [4] as a sector area between the line segment Bd [1] [4], the line segment Bd [2] [4], and the circle BdR.
In the present embodiment, as an example, it is assumed that the angle θ is 45 degrees. However, the angle θ may be an angle larger than 0 degree and smaller than 90 degrees. In the present embodiment, the first angle and the second angle are equal angles, but the first angle and the second angle may be different angles.

After the touch-in, for example, the user U tilts the finger FG while keeping the finger FG in contact with the touch panel 1002, so that any of the input areas R [1] to R [4] in the operation area V can be selected. You can touch that area. When the touch position P of the finger FG is present in the input area R [m], the terminal device 10 corresponds to the input area R [m] with the face of the character CR in the direction in the touch panel coordinate system ΣD. An instruction to turn in the direction is received.
Specifically, in the present embodiment, as illustrated in FIG. 3, when the touch position P exists in the input area R [1] (an example of “first input area”), the terminal device 10 has a touch panel coordinate system. An instruction that the direction of the face of the character CR in ΣD is the + XD direction (an example of “first operation direction”) is received. In the present embodiment, as illustrated in FIG. 4, when the touch position P is present in the input area R [2] (an example of “second input area”), the terminal device 10 displays a character in the touch panel coordinate system ΣD. An instruction indicating that the direction in which the face of CR is facing is the −XD direction (an example of “second operation direction”) is received. In the present embodiment, when the touch position P exists in the input area R [3] (an example of “third input area”), the terminal device 10 determines the direction in which the face of the character CR faces in the touch panel coordinate system ΣD. , + YD direction (an example of “third operation direction”) is received. In the present embodiment, the terminal device 10 faces the face of the character CR in the touch panel coordinate system ΣD when the touch position P exists in the input area R [4] (another example of the “third input area”). An instruction to change the direction to the −YD direction (another example of the “third operation direction”) is received.
Hereinafter, a period in which the state where the touch position P exists in the input area R [m] continues is referred to as an input area touch period TR [m].

  Although the details will be described later, the terminal device 10 according to the present embodiment, based on the touch position P existing in the input area R [1], the feature position P-R [1] ("first position" One example) is specified, and the feature position P-R [2] (an example of “second position”) is specified based on the touch position P existing in the input region R [2]. Then, the terminal device 10 can correct the position of the operation area V in the touch panel coordinate system ΣD based on the feature position PR [1] and the feature position PR [2]. That is, the terminal device 10 corrects the reference position OV in the touch panel coordinate system ΣD based on the feature position PR [1] and the feature position PR [2], thereby performing an operation viewed from the touch panel coordinate system ΣD. Correct the position of the area coordinate system ΣV.

[2. Configuration of terminal device]
Hereinafter, an example of the configuration of the terminal device 10 will be described with reference to FIGS. 5 and 6.

  FIG. 5 is a functional block diagram illustrating an example of the configuration of the terminal device 10.

  As illustrated in FIG. 5, the terminal device 10 includes a control unit 11 that controls each unit of the terminal device 10, a display unit 12 that displays an image, and an input unit 13 that receives an instruction input by a user of the terminal device 10. And a storage unit 14 that stores various information, and a vibration generation unit 15 that vibrates the terminal device 10 including the touch panel 1002.

  The storage unit 14 includes a program relating to a predetermined game, touch position history information indicating a history of the touch position P indicated by the touch position information periodically output from the touch panel 1002 over the touch period TV, and a characteristic position P−. Various pieces of information including feature position information indicating R [m] and input area information indicating the position of the input area R [m] in the touch panel coordinate system ΣD are stored.

  The control unit 11 includes a game control unit 111, a display control unit 112, a touch position information acquisition unit 113, a feature position specifying unit 114, an input area determination unit 115, and a vibration control unit 116.

The game control unit 111 controls the progress of a predetermined game. Specifically, the game control unit 111 corresponds to the input area R [m] the direction in which the face of the character CR faces in the touch panel coordinate system ΣD when the touch position P exists in the input area R [m]. Set the direction.
The display control unit 112 controls the display unit 12 so that the display unit 12 displays the virtual space SP, the character CR, and the operation area V.
The touch position information acquisition unit 113 (an example of “acquisition unit”) acquires touch position information periodically output from the input unit 13.
The feature position specifying unit 114 (an example of the “specifying unit”) specifies the feature position P-R [m] based on the touch position P existing in the input region R [m] in the input region touch period TR [m]. To do.
The input region determination unit 115 (an example of a “determination unit”) determines the position of the operation region V on the touch panel 1002 based on the feature position PR [1] and the feature position PR [2].
The vibration control unit 116 causes the vibration generating unit 15 to vibrate the terminal device 10 when the touch position P changes from a state that does not exist in the input region R [m] to a state that exists in the input region R [m]. Next, the vibration generator 15 is controlled. However, when the touch position P is changed from a state in which the touch position P exists in the input region R [m] to a state in which the touch position P does not exist in the input region R [m], the vibration generating unit 15 causes the terminal device 10 to move. The vibration generating unit 15 may be controlled to vibrate, or the vibration generating unit 15 may be controlled so that the vibration generating unit 15 vibrates the terminal device 10 when a touch-in occurs.

  FIG. 6 is a hardware configuration diagram illustrating an example of a hardware configuration of the terminal device 10.

  As illustrated in FIG. 6, the terminal device 10 includes a processor 1000 that controls each unit of the terminal device 10 (an example of an “information processing device”), a memory 1001 that stores various types of information, a touch panel 1002, and a vibration generation device 1003. And comprising.

The memory 1001 includes, for example, a volatile memory such as a RAM (Random Access Memory) that functions as a work area of the processor 1000, and an EEPROM (Electrically Erasable Programmable Read-Only Memory) that stores various information such as a program related to a predetermined game. And functions as the storage unit 14.
The processor 1000 is, for example, a CPU (Central Processing Unit), and functions as the control unit 11 by executing a program related to a predetermined game stored in the memory 1001 and operating according to the program.
The touch panel 1002 functions as the display unit 12 and the input unit 13 as described above.
The vibration generator 1003 is, for example, a vibration motor that generates vibration, and functions as the vibration generator 15.

  The processor 1000 includes hardware such as a GPU (Graphics Processing Unit), a DSP (Digital Signal Processor), or an FPGA (Field Programmable Gate Array) in addition to or instead of the CPU. It may be done. In this case, part or all of the control unit 11 realized by the processor 1000 may be realized by hardware such as a DSP.

[3. Relationship between touch position and operation area]
Hereinafter, an example of the relationship between the touch position P of the finger FG and the operation region V on the touch panel 1002 will be described with reference to FIGS.

  7 to 10 show an example of a change in the relationship between the touch position P of the finger FG on the touch panel 1002 and the operation area V set on the touch panel 1002 in the period from time t1 to time t10 (hereinafter, “ It is an explanatory view for explaining “example of touch position change”). Hereinafter, the touch position P at time t is referred to as touch position P [t], the operation area V at time t is referred to as operation area V [t], and the operation area coordinate system ΣV at time t is referred to as the operation area coordinate system. It is referred to as ΣV [t], and the reference position OV at time t is referred to as a reference position OV [t].

As shown in FIG. 7, in the touch position change example, it is assumed that the finger FG touches the touch position P [t1] at time t1. That is, in the touch position change example, the touch period TV starts from time t1. In this case, the input area determination unit 115 sets an operation area coordinate system ΣV [t1] with the touch position P [t1] as the reference position OV [t1], and inputs the position to the position corresponding to the reference position OV [t1]. An operation area V [t1] including areas R [1] to R [4] is set.
When the operation area V is set, the input area determination unit 115 causes the storage unit 14 to store the position of the input area R [m] included in the operation area V as input area information.

  As shown in FIG. 7, in the touch position change example, the finger FG moves the input region R [1] from the touch position P [t1] to the touch position P [t2] from time t1 to time t2. Assume that the robot moves while touching. Further, in the touch position change example, it is assumed that the touch position P [t2] at the time t2 exists in the input region R [1]. That is, in the touch position change example, the touch position P enters the input area R [1] at a time between time t1 and time t2. In other words, in the touch position change example, the input area touch period TR [1] (an example of “first touch period”) is started from the time between time t1 and time t2.

In the present embodiment, the feature position specifying unit 114 determines that the touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 at one time in the input area touch period TR [1] is the input area touch period TR. Positioned closest to + XV among one or a plurality of touch positions P indicated by one or a plurality of touch position information acquired by the touch position information acquisition unit 113 in a period from the time when [1] is started to one time When the condition to perform (an example of “first condition”) is satisfied, the touch position P corresponding to the one time is specified as the feature position P-R [1]. In other words, in the present embodiment, the feature position specifying unit 114 determines that the touch position P is the position farthest from the reference position OV in the + XV direction in the input area touch period TR [1]. Is satisfied, the touch position P is specified as the feature position P-R [1].
In the touch position change example, it is assumed that the touch position P [t2] is the position farthest from the reference position OV in the + XV direction among the touch positions P in the period from the time t1 to the time t2. For this reason, in the touch position change example, the feature position specifying unit 114 specifies the touch position P [t2] as the feature position PR [1] at time t2.

  Note that, as described above, the input region determination unit 115 determines the operation region coordinate system ΣV, the reference position OV, and the operation region V based on the feature position PR [1] and the feature position PR [2]. Correct the position. However, as shown in FIG. 7, in the touch position change example, the characteristic position PR [1] is specified at the time t2, but the characteristic position PR [2] is not specified. Therefore, in the touch position change example, the input region determination unit 115 determines the reference position OV [t2] and the operation region coordinate system so that the operation region V [t2] and the operation region V [t1] are at the same position. Set ΣV [t2].

As shown in FIG. 7, in the touch position change example, the finger FG moves the input region R [1] from the touch position P [t2] to the touch position P [t3] from time t2 to time t3. Assume that the robot moves while touching. In the touch position change example, it is assumed that the touch position P [t3] at the time t3 is present on the −XV side of the touch position P [t2] in the input region R [1]. That is, in the touch position change example, the touch position P [t2] is on the + XV side with respect to the touch position P [t3]. Therefore, in the touch position change example, the feature position specifying unit 114 maintains the state where the touch position P [t2] is specified as the feature position PR [1] even at the time t3.
In the touch position change example, the characteristic position P-R [2] is not specified even at the time t3. For this reason, in the touch position change example, the input area determination unit 115 sets the reference position OV [t3] and the operation area coordinate system so that the operation area V [t3] and the operation area V [t2] are at the same position. Set ΣV [t3].

As shown in FIG. 8, in the touch position change example, the finger FG moves the input region R [1] from the touch position P [t3] to the touch position P [t4] from time t3 to time t4. Assume that the robot moves while touching. In the touch position change example, the touch position P [t4] at time t4 is located on the + XV side of the input area R [1] with respect to the touch position P [t2] and the touch position P [t3]. Suppose. Therefore, in the touch position change example, the feature position specifying unit 114 specifies the touch position P [t4] as the feature position PR [1] at time t4. In other words, in the touch position change example, the feature position specifying unit 114 updates the feature position PR [1] from the touch position P [t2] to the touch position P [t4] at time t4.
In the touch position change example, the characteristic position P-R [2] is not specified even at time t4. Therefore, in the touch position change example, the input area determination unit 115 determines the reference position OV [t4] and the operation area coordinate system so that the operation area V [t4] and the operation area V [t3] are at the same position. Set ΣV [t4].

  As shown in FIG. 8, in the touch position change example, from time t4 to time t5, the finger FG moves the input region R [1] and the input region R [4] from the touch position P [t4] to the touch position P [ It is assumed that the user moves to t5 while touching the touch panel 1002. In the touch position change example, it is assumed that the touch position P enters the input area R [2] at time t5. That is, in the touch position change example, the input area touch period TR [1] ends at a time between time t4 and time t5, and the input area touch period TR [2] (“second touch period” from time t5). Is started).

In the present embodiment, the feature position specifying unit 114 determines that the touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 at one time in the input area touch period TR [2] is the input area touch period TR. Among one or a plurality of touch positions P indicated by one or a plurality of touch position information acquired by the touch position information acquisition unit 113 in a period from the time when [2] is started to one time, the most on the −XV side. When the condition of being located (an example of “second condition”) is satisfied, the touch position P corresponding to the one time is specified as the feature position P-R [2]. In other words, in the present embodiment, the feature position specifying unit 114 says that the touch position P is the position farthest from the reference position OV in the −XV direction in the input area touch period TR [2]. When the condition is satisfied, the touch position P is specified as the feature position P-R [2]. Hereinafter, the first condition and the second condition may be collectively referred to as a feature position specifying condition.
In the touch position change example, it is assumed that the input area touch period TR [2] starts at time t5. That is, in the touch position change example, in the touch position P in the period from the start of the input area touch period TR [2] to the time t5, the touch position P [t5] is in the −XV direction from the reference position OV. It is the most distant position. For this reason, in the touch position change example, the feature position specifying unit 114 specifies the touch position P [t5] as the feature position PR [2] at time t5.

Incidentally, after the touch position P moves from the input area R [m] to the outside of the input area R [m], the touch position P may enter the input area R [m] again. That is, after the end of one input area touch period TR [m] in which the touch position P exists in the input area R [m], another input area touch period in which the touch position P exists in the input area R [m] again. TR [m] may be started. In this case, the feature position specifying unit 114 performs one input area touch period TR in a period from the end of one input area touch period TR [m] to the start of another input area touch period TR [m]. The specified result of the characteristic position P-R [m] at the end of [m] is maintained. In this case, when another input area touch period TR [m] is started, the feature position specifying unit 114 at the end of one input area touch period TR [m] And a new feature position P-R [m] is specified in another input area touch period TR [m].
More specifically, when the feature position specifying unit 114 specifies the feature position PR [m] in one input area touch period TR [m], the feature position specifying unit 114 sets the specified feature position PR [R] [m]. The position information is stored in the storage unit 14. Then, when the feature position specifying unit 114 specifies the feature position P-R [m] in the other input area touch period TR [m], the feature position specifying unit 114 obtains the feature position information based on the specified feature position PR [R]. Update.

  In the touch position change example, the feature position specifying unit 114 specifies the touch position P [t4] at the time t4 as the feature position PR [1] at the end of the input area touch period TR [1]. Assume a case. Therefore, in the touch position change example, as shown in FIG. 8, the feature position specifying unit 114 displays the touch position P [t4] as a feature even at time t5 after the input area touch period TR [1] ends. The state specified as the position P-R [1] is maintained.

In the present embodiment, as described above, the input region determination unit 115 corrects the position of the operation region V based on the feature position PR [1] and the feature position PR [2].
Specifically, in the present embodiment, the input area determination unit 115 first determines the correction position Md based on the feature position PR [1] and the feature position PR [2]. Next, the input area determination unit 115 determines an operation area movement vector Vmd starting from the reference position OV and ending with the correction position Md. Then, the input area determination unit 115 moves the reference position OV, the operation area coordinate system ΣV, and the operation area V by a movement amount corresponding to the operation area movement vector Vmd. Thereby, the input area determination unit 115 can correct the positions of the reference position OV, the operation area coordinate system ΣV, and the operation area V in the touch panel coordinate system ΣD so that the correction position Md and the reference position OV coincide. it can. When the position of the operation area V is corrected, the input area determination unit 115 updates the input area information stored in the storage unit 14 with the position of the input area R [m] included in the operation area V. . Hereinafter, the operation region movement vector Vmd determined at the time t is referred to as an operation region movement vector Vmd [t].
In the present embodiment, the input area determination unit 115 exemplifies a case where the reference position OV is corrected by moving the reference position OV by a movement amount corresponding to the operation area movement vector Vmd. Is not limited to such an embodiment. The input area determination unit 115 may simply set the correction position Md determined based on the feature position PR [1] and the feature position PR [2] as the reference position OV. In other words, for example, when the correction position Md is determined at one time, the input region determination unit 115 determines one based on the determined correction position Md without considering the reference position OV at the one time. The reference position OV at another time after the time may be determined.

In the present embodiment, for example, the input region determination unit 115 determines the position of the midpoint between the point existing at the feature position PR [1] and the point existing at the feature position PR [2] as the correction position. Determined as Md.
However, the input area determination unit 115 may determine, for example, a position between the feature position PR [1] and the feature position PR [2] as the correction position Md, or the feature position PR [ A position having the same distance from 1] and the characteristic position PR [2] may be determined as the correction position Md. In short, the input region determination unit 115 may determine the position defined by the feature position PR [1] and the feature position PR [2] as the correction position Md.
For example, the input region determining unit 115 determines the position in the reference region where the distance from the line segment connecting the feature position PR [1] and the feature position PR [2] is equal to or less than a predetermined reference distance as the correction position Md. It may be determined as
Further, for example, the input region determination unit 115 refers to the feature position PR [R] that is identified earlier among the feature position PR [1] and the feature position PR [2] as the preceding feature position. When the feature position PR [R] specified later among the feature position PR [1] and the feature position PR [2] is referred to as a succeeding feature position, the following feature than the preceding feature position. A position close to the position may be determined as the correction position Md. According to this example, the correction position Md is provided in the vicinity of the latest touch position P by the finger FG, so that the correction position Md is set closer to the preceding feature position than the subsequent feature position. Thus, it is possible to reduce the amount of movement of the finger FG when the touch position P is changed from the input area R corresponding to the subsequent feature position to the input area R corresponding to the preceding feature position. That is, according to this example, the touch position P is set to the input area R [1] and the input area R [2] as compared with the case where the correction position Md is set closer to the preceding feature position than the subsequent feature position. The operability in the operation of moving the finger FG so as to reciprocate between can be kept better.
For example, the input area determination unit 115 may determine a position closer to the subsequent feature position than the preceding feature position in the reference area as the correction position Md. According to this example, it is possible to maintain good operability in the operation of moving the finger FG so that the touch position P reciprocates between the input region R [1] and the input region R [2].
Further, for example, the input area determination unit 115 is a position within the reference area that is closer to the succeeding feature position than the preceding feature position and whose distance from the succeeding feature position is greater than or equal to a predetermined reference interval. May be determined as the correction position Md. If the interval between the correction position Md and the subsequent feature position is less than a predetermined reference interval, the latest touch position P existing in the input area R corresponding to the subsequent feature position and the input corresponding to the preceding feature position. An interval with the region R is also less than a predetermined reference interval. When the interval between the correction position Md and the subsequent feature position is less than a predetermined reference interval, the user U tries to touch the input region R corresponding to the subsequent feature position with the finger FG. Therefore, there is a high possibility that an erroneous operation of erroneously touching the finger FG on the input region R corresponding to the preceding feature position will occur. On the other hand, according to this example, since the correction position Md is provided at a position separated from the subsequent feature position by a predetermined reference interval or more, the latest touch existing in the input region R corresponding to the subsequent feature position is provided. The interval between the position P and the input region R corresponding to the preceding feature position can be separated by a predetermined reference interval or more. For this reason, according to this example, compared with the case where the interval between the correction position Md and the succeeding feature position is less than the predetermined reference interval, the input region R different from the input region R intended by the user U is erroneously set. Thus, it is possible to reduce the possibility of an erroneous operation of touching the finger FG.
Further, for example, the input region determination unit 115 determines, as the correction position Md, a position that is closer to the subsequent feature position than the preceding feature position and that is separated by a predetermined reference interval or more from the subsequent feature position. May be. According to this example, compared with the case where the interval between the correction position Md and the succeeding feature position is less than the predetermined reference interval, the finger FG is erroneously applied to the input region R different from the input region R intended by the user U. It is possible to reduce the possibility of an erroneous operation of touching.
Further, for example, the input region determination unit 115 includes the feature position PR [1] and the feature position PR [2] among the positions within the reference region and closer to the subsequent feature position than the preceding feature position. The correction position Md may be determined such that the ratio of the distance between the correction position Md and the succeeding feature position to the distance between is equal to or greater than a predetermined value α (α is “0 <α <1”). Satisfying natural numbers). According to this example, the ratio of the distance between the correction position Md and the succeeding feature position to the distance between the feature position PR [1] and the feature position PR [2] is less than the predetermined value α. In comparison, it is possible to reduce the possibility of an erroneous operation in which the finger FG is erroneously touched in an input area R different from the input area R intended by the user U.
Further, for example, the input area determination unit 115 corrects the distance between the feature position PR [1] and the feature position PR [2] among positions closer to the succeeding feature position than the preceding feature position. The correction position Md may be determined so that the ratio of the distance between the position Md and the subsequent feature position is equal to or greater than a predetermined value α. According to this example, the ratio of the distance between the correction position Md and the succeeding feature position to the distance between the feature position PR [1] and the feature position PR [2] is less than the predetermined value α. In comparison, it is possible to reduce the possibility of an erroneous operation in which the finger FG is erroneously touched in an input area R different from the input area R intended by the user U.
Hereinafter, the correction position Md determined by the input region determination unit 115 at time t is referred to as a correction position Md [t].

In the touch position change example, as illustrated in FIG. 8, the input region determination unit 115 sets the midpoint of the feature position PR [1] and the feature position PR [2] at the correction position Md [ t5]. The input area determination unit 115 determines an operation area movement vector Vmd [t5] starting from the reference position OV [t5] and ending with the correction position Md [t5].
Then, the input region determination unit 115 determines the end point position of the operation region movement vector Vmd [t5] when the starting point of the operation region movement vector Vmd [t5] is set to the reference position OV [t5] at time t6. The operation area coordinate system ΣV [t6] is set so that the reference position OV [t6] is determined and the reference position OV [t6] is the origin. Further, the input area determination unit 115 sets the operation area V [t6] at a position corresponding to the operation area coordinate system ΣV [t6] at time t6. In the variation, the time t6 is a time later than the time t5, but the time t6 may be the same time as the time t5.

  As shown in FIG. 9, in the touch position change example, the finger FG moves the input region R [2] from the touch position P [t5] to the touch position P [t7] from time t6 to time t7. Assume that the robot moves while touching. In the touch position change example, it is assumed that the touch position P [t7] at the time t7 is present on the −XV side of the touch position P [t5] in the input region R [2]. For this reason, in the touch position change example, the feature position specifying unit 114 specifies the touch position P [t7] as the feature position PR [2] at time t7. In other words, in the touch position change example, the feature position specifying unit 114 updates the feature position PR [2] from the touch position P [t5] to the touch position P [t7] at time t7.

In the touch position change example, as illustrated in FIG. 9, the input region determination unit 115 sets the midpoint of the feature position PR [1] and the feature position PR [2] at the correction position Md [ t7]. Further, the input area determination unit 115 determines an operation area movement vector Vmd [t7] starting from the reference position OV [t7] and ending with the correction position Md [t7].
Then, at time t8, the input area determination unit 115 corresponds the reference position OV [t7], the operation area coordinate system ΣV [t7], and the operation area V [t7] to the operation area movement vector Vmd [t7]. The reference position OV [t8], the operation area coordinate system ΣV [t8], and the operation area V [t8] are set by moving the movement amount. In other words, the input area determination unit 115 sets the reference position OV [t8], the operation area coordinate system ΣV [t8], and the reference position OV [t8] so that the reference position OV [t8] is equal to the correction position Md [t7]. The operation area V [t8] is set. In the touch position change example, the time t8 is a time later than the time t7, but the time t8 may be the same time as the time t7.

As shown in FIG. 10, in the touch position change example, from time t8 to time t9, the finger FG moves the input area R [2] and the input area R [4] from the touch position P [t7] to the touch position P [ Assume that the user moves to t9 while touching the touch panel 1002. In the touch position change example, it is assumed that the touch position P enters the input area R [1] again at time t9. That is, in the touch position change example, the input area touch period TR [2] ends at a time between time t8 and time t9, and the input area touch period TR [1] starts again at time t9. .
In the following, for convenience of explanation, the input area touch period TR [1] that starts at a time between time t1 and time t2 is referred to as the previous input area touch period TR [1] and starts at time t9. The input area touch period TR [1] may be referred to as a subsequent input area touch period TR [1].

As described above, in the present embodiment, when the subsequent input area touch period TR [1] is started, the feature position specifying unit 114 at the end of the previous input area touch period TR [1] The identification result of R [1] is discarded, and the feature position P-R [1] is newly identified in the subsequent input area touch period TR [1].
Therefore, in the touch position change example, the feature position specifying unit 114 specifies the touch position P [t9] as the feature position PR [1] at time t9 as shown in FIG. In other words, in the touch position change example, the feature position specifying unit 114 updates the feature position PR [1] from the touch position P [t4] to the touch position P [t9] at time t9.

In the touch position change example, as illustrated in FIG. 10, the input region determination unit 115 determines the midpoint of the feature position PR [1] and the feature position PR [2] at the correction position Md [ t9]. The input area determination unit 115 determines an operation area movement vector Vmd [t9] starting from the reference position OV [t9] and ending with the correction position Md [t9].
Then, at time t10, the input area determination unit 115 corresponds the reference position OV [t9], the operation area coordinate system ΣV [t9], and the operation area V [t9] to the operation area movement vector Vmd [t9]. The reference position OV [t10], the operation area coordinate system ΣV [t10], and the operation area V [t10] are set by moving the movement amount. In other words, the input area determination unit 115 sets the reference position OV [t10], the operation area coordinate system ΣV [t10], and the reference position OV [t10] so that the reference position OV [t10] is equal to the correction position Md [t9]. The operation area V [t10] is set. In the touch position change example, the time t10 is a time later than the time t9, but the time t10 may be the same time as the time t9.

[4. Operation of terminal device]
Hereinafter, an example of the operation of the terminal device 10 will be described with reference to FIG.

  FIG. 11 is a flowchart illustrating an example of the operation of the terminal device 10 when the terminal device 10 executes a predetermined game. In the present embodiment, for example, when the user U of the terminal device 10 inputs a predetermined start operation for starting a predetermined game from the touch panel 1002, the terminal device 10 starts the predetermined game. And

As shown in FIG. 11, when a predetermined game is started, the touch position information acquisition unit 113 determines whether or not the touch panel 1002 outputs touch position information (S100).
And the touch position information acquisition part 113 advances a process to step S128, when the result of determination in step S100 is negative.
On the other hand, the touch position information acquisition part 113 acquires the touch position information output from the touch panel 1002, when the result of determination in step S100 is affirmative (S102). The touch position information acquisition unit 113 updates the touch position history information stored in the storage unit 14 based on the touch position information acquired in step S102. Specifically, the touch position information acquisition unit 113 associates the touch position information acquired in step S102 with the time when the touch position information is acquired, and then includes the touch position information in the touch position history information. The touch position history information may include information indicating whether or not the touch position P at each time is present in the input area R [m].

Next, the feature position specifying unit 114 determines whether or not the time when the touch position information acquisition unit 113 acquires the touch position information in step S102 is after the touch-in to the touch panel 1002 by the user U's finger FG. Is determined (S104). Specifically, the feature position specifying unit 114 refers to, for example, touch position history information in step S104, so that the touch position information acquired by the touch position information acquiring unit 113 in step S102 is the touch period TV. It is determined whether or not the touch position information is acquired after the second of the one or more touch position information acquired by the touch position information acquisition unit 113 after the start.
Then, when the result of the determination in step S104 is negative, the feature position specifying unit 114 proceeds with the process to step S124.
On the other hand, if the determination result in step S104 is affirmative, the feature position specifying unit 114 acquires the input area information stored in the storage unit 14, and specifies the position of each input area R [m] (S106). .

Next, the feature position specifying unit 114 determines whether or not the touch position P indicated by the touch position information acquired by the touch position information acquiring unit 113 in step S102 exists in the input region R [m] (S108). ). When the determination result in step S108 is affirmative, the time when the touch position information acquisition unit 113 acquires the touch position information in step S102 is included in the input area touch period TR [m]. The feature position specifying unit 114 may update the touch position history information based on the determination result of step S108.
If the result of determination in step S108 is negative, the feature position specifying unit 114 proceeds with the process to step S126.

On the other hand, when the result of the determination in step S108 is affirmative, the vibration control unit 116 acquires the touch position information acquired by the touch position information acquisition unit 113 in step S102 during the input area touch period TR [m]. It is determined whether the touch position information is the first acquired among the one or more touch position information acquired by the unit 113 (S110).
And the vibration control part 116 advances a process to step S114, when the result of determination in step S110 is negative.
On the other hand, if the result of the determination in step S110 is affirmative, the vibration control unit 116 controls the vibration generating unit 15 so that the vibration generating unit 15 vibrates the terminal device 10 (S112).

Next, the feature position specifying unit 114 determines whether or not the touch position P indicated by the touch position information acquired by the touch position information acquiring unit 113 in step S102 satisfies the feature position specifying condition (S114). Specifically, the feature position specifying unit 114 determines that the touch position P indicated by the touch position information acquired by the touch position information acquiring unit 113 in step S102 exists in the input region R [1] in step S114. Determines whether the touch position P satisfies the first condition. In addition, in step S114, when the touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 in step S102 is present in the input region R [2], the feature position specifying unit 114 It is determined whether or not the touch position P satisfies the second condition. In step S114, the feature position specifying unit 114 sets the touch position P indicated by the touch position information acquired by the touch position information acquiring unit 113 in step S102 to the input area R [3] or the input area R [4]. If it exists, it is determined that the feature position specifying condition is not satisfied.
And the characteristic position specific | specification part 114 advances a process to step S126, when the result of determination in step S114 is negative.

  On the other hand, if the result of determination in step S114 is affirmative, the feature position specifying unit 114 determines the touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 in step S102 as the feature position PR [m ] (S116). Specifically, when the touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 in step S102 satisfies the first condition, the feature position specifying unit 114 determines the touch position P as the touch position P. It is specified as a feature position P-R [1]. In addition, the feature position specifying unit 114 determines that the touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 in step S102 satisfies the second condition. Specify as -R [2]. The feature position specifying unit 114 updates the feature position information stored in the storage unit 14 based on the specification result in step S116.

Next, the input area determination unit 115 determines whether or not both the feature position PR [1] and the feature position PR [2] exist (S118).
Then, if the determination result in step S118 is negative, the input area determination unit 115 advances the process to step S126.
On the other hand, if the determination result in step S118 is affirmative, the input region determination unit 115 determines the reference position OV based on the feature position PR [1] and the feature position PR [2] (S120). .

  Next, the input area determination unit 115 determines the positions of the input areas R [1] to R [4] in the touch panel coordinate system ΣD based on the reference position OV determined in step S120 (S122). The input area determining unit 115 updates the input area information stored in the storage unit 14 with the position of the input area R [m] determined in step S122.

  On the other hand, if the result of determination in step S104 is negative, the input area determination unit 115 sets the reference position OV to the touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 in step S102, The operation area V including the input areas R [1] to R [4] is set at a position based on the reference position OV (S124).

  Further, when the result of determination in step S108, S114, or S118 is negative, the input area determination unit 115 maintains the position of the input area R [m] without changing (S126).

Thereafter, the game control unit 111 determines the direction in which the face of the character CR faces in the touch panel coordinate system ΣD (S128).
Specifically, in step S128, the game control unit 111 is a case where the finger FG is in contact with the touch panel 1002 (S100: Y), and the touch position P is present in the input area R [m] ( S108: Y), the direction in which the face of the character CR faces in the touch panel coordinate system ΣD is set to a direction corresponding to the input area R [m]. Further, in step S128, the game control unit 111 determines that the finger FG is in contact with the touch panel 1002 (S100: Y), and the touch position P does not exist in the input area R [m] (S108: N). ), The direction in which the face of the character CR faces in the touch panel coordinate system ΣD is set to a predetermined direction, for example, the front direction as shown in FIG. In addition, when the finger FG is not in contact with the touch panel 1002 in step S128 (S100: N), the game control unit 111 sets a direction in which the face of the character CR in the touch panel coordinate system ΣD faces, for example, a predetermined direction, for example, The front direction is set as shown in FIG.

  Next, in the display control unit 112, the display unit 12 generates display information for displaying the virtual space SP, the character CR, and the operation area V, and the display unit 12 displays an image based on the display information. Thus, the display unit 12 is controlled (S130).

  Thereafter, the game control unit 111 determines whether or not the user U has input a predetermined end operation for ending the predetermined game from the touch panel 1002 (S132). And the game control part 111 advances a process to step S100, when the determination result in step S132 is affirmative, and complete | finishes a predetermined game, when the determination result in step S132 is negative.

[5. Conclusion of the embodiment]
As described above, in the present embodiment, the input region determination unit 115 inputs the input regions R [1] to R [4] based on the feature position PR [1] and the feature position PR [2]. ] Is determined. Therefore, in the present embodiment, even when the touch position P in the operation region V gradually shifts, the input region determination unit 115 corrects the operation region V in accordance with the shift of the touch position P. Is possible. Therefore, according to the present embodiment, for example, it is possible to reduce the possibility of erroneous input due to the shift of the touch position P, as compared with the case where the position of the operation region V is fixed on the touch panel 1002. Become.

In general, the relative position relationship between two feature positions PR [R] of the feature position PR [1] and the feature position PR [2], and the feature position PR [1] ] And the feature position PR [2], the distance between the two feature positions PR [m] is the shape and size of the finger FG in contact with the touch panel 1002, and the user U touches the touch panel 1002 with the finger FG. There is a high possibility that the pressure is determined according to the touch mode for each user U, such as the pressure at the time of contact with the user and the method of moving the finger FG.
On the other hand, in the present embodiment, the input region determination unit 115 performs input based on the two feature positions PR [R], that is, the feature position PR [1] and the feature position PR [2]. The position of the operation area V including the area R [1] and the input area R [2] is determined. For this reason, according to the present embodiment, for example, a touch mode for each user U is considered in comparison with a mode in which the position of the input region R [m] is determined based on one feature position P-R [m]. The operation area V including the input area R [1] and the input area R [2] can be set at the position. Thereby, according to this embodiment, compared with the aspect which determines the position of input area R [m] based on one feature position PR [R], for example, input area R for an arbitrary user U The operability in the operation of bringing the finger FG into contact with [m] can be kept better.

By the way, in a specific type of game, there is a case where the frequency of inputting an instruction in one direction related to the game is higher than the frequency of inputting an instruction in another direction related to the game. For example, in a predetermined game, there is a case where the frequency of inputting an instruction in the XD axis direction including the + XD direction and the −XD direction is higher than the frequency of inputting an instruction in the YD axis direction including the + YD direction and the −YD direction. . Then, according to the aspect in which the position of the input region R [m] is determined based on the touch position P related to the input of the less frequent instruction, the input region R [m] is time-dependent on the position of the finger FG of the user U. There is a possibility that the position may be set to a position that does not correspond to the shift.
On the other hand, in this embodiment, the input area determination unit 115 is based on the touch position P existing in the input area R [1] and the input area R [2] corresponding to the input of the instruction in the XD axis direction. The positions of the input area R [3] and the input area R [4] are determined. For this reason, according to the present embodiment, the frequency of input of instructions in the XD axis direction including the + XD direction and the −XD direction is higher than the frequency of input of instructions in the YD axis direction including the + YD direction and the −YD direction. For example, based on the touch position P existing in the input area R [3] and the input area R [4] corresponding to the input of the instruction in the YD axis direction, the input area R [3] and the input area R [4 ], It is possible to increase the possibility that the operation region V is set at a position that accurately corresponds to the shift of the touch position P.

[B. Modified example]
Each of the above forms can be variously modified. Specific modifications are exemplified below. Two or more aspects arbitrarily selected from the following examples can be appropriately combined within a range that does not contradict each other. In addition, about the element in which an effect | action and a function are equivalent to embodiment in the modification illustrated below, the code | symbol referred by the above description is diverted and each detailed description is abbreviate | omitted suitably.

[Modification 1]
In the embodiment described above, the feature position specifying unit 114 applies the feature position PR [1] based on the touch position P existing in the input area R [1] and the touch position P existing in the input area R [2]. Based on the feature position PR [1] and the feature position PR [2], the input region determination unit 115 specifies the + XV direction and the -XV direction. The position of the operation region V in the XV-axis direction including and the position of the operation region V in the YV-axis direction including the + YV direction and the -YV direction are defined, but the present invention is not limited to such a mode. .
For example, the feature position specifying unit 114 adds the feature position PR based on the touch position P existing in the input region R [3] in addition to the feature position PR [1] and the feature position PR [2]. [3] may be specified, and the feature position P-R [4] may be specified based on the touch position P existing in the input area R [4].
Specifically, the feature position specifying unit 114 performs the touch acquired by the touch position information acquisition unit 113 at one time in the input area touch period TR [3] in which the touch position P exists in the input area R [3]. The touch position P indicated by the position information is 1 or 1 indicated by one or more touch position information acquired by the touch position information acquisition unit 113 in a period from the time when the input area touch period TR [3] is started to one time. When a condition (an example of “third condition”) that is located closest to + YV among a plurality of touch positions P is satisfied, the touch position P corresponding to the one time is represented by the feature position PR [ 3] may be specified.
Further, the feature position specifying unit 114 includes the touch position information acquired by the touch position information acquiring unit 113 at one time in the input area touch period TR [4] in which the touch position P exists in the input area R [4]. The touch position P indicated is one or more touches indicated by one or more touch position information acquired by the touch position information acquisition unit 113 in a period from the time when the input area touch period TR [4] is started to one time. When the condition that the position P is located on the most -YV side among the positions P (an example of “fourth condition”) is satisfied, the touch position P corresponding to the one time is selected as the feature position PR [4]. May be specified.
In this case, the input region determination unit 115 determines the position of the operation region V in the XV axis direction based on the feature position PR [1] and the feature position PR [2], and the feature position P Based on -R [3] and feature position PR [4], the position of the operation region V in the YV-axis direction may be determined.
In the following, the first condition, the second condition, the third condition, and the fourth condition may be collectively referred to as a feature position specifying condition.

  12 and 13 are explanatory diagrams for describing an example of a touch position change according to this modification. In the touch position change example according to this modification, the period from time t1 to time t4 is the same as the touch position change example according to the embodiment shown in FIGS.

In the touch position change example according to this modification, as shown in FIG. 12, from time t4 to time t5, the finger FG moves the input area R [1] and the input area R [4] to the touch position P [t4]. Is assumed to move to the touch position P [t5] while touching the touch panel 1002 and enter the input area R [2] at time t5. In the touch position change example according to this modification, the feature position specifying unit 114 specifies the touch position P [t5] as the feature position PR [2] at time t5. Also, in the touch position change example according to this modification, it is assumed that the feature position specifying unit 114 specifies the touch position P [t4] as the feature position PR [1] at time t5. In the touch position change example according to this modification, the input region determination unit 115 sets the midpoint of the feature position PR [1] and the feature position PR [2] at the correction position Md [ t5]. Further, the input region determining unit 115 obtains a vector obtained by extracting only the XV component from the vectors starting from the reference position OV [t5] and ending at the correction position Md [t5], as the operation region movement vector Vmd [t5]. Determine as
Then, at time t6, the input area determination unit 115 corresponds the reference position OV [t5], the operation area coordinate system ΣV [t5], and the operation area V [t5] to the operation area movement vector Vmd [t5]. The reference position OV [t6], the operation area coordinate system ΣV [t6], and the operation area V [t6] are set by moving the movement amount. In the touch position change example according to this modification, the time t6 is a time later than the time t5, but the time t6 may be the same time as the time t5.

In the touch position change example according to this modification, as shown in FIG. 13, the finger FG moves the input region R [2] from the touch position P [t5] to the touch position P [t7] from time t6 to time t7. Suppose that the user moves while touching the touch panel 1002 and enters the input area R [3] at time t7. In the touch position change example according to this modification, the feature position specifying unit 114 specifies the touch position P [t7] as the feature position PR [3] at time t7.
Thereafter, from time t7 to time t8, the finger FG moves the input area R [3], the input area R [2], and the input area R [4] from the touch position P [t7] to the touch position P [t8]. Suppose that the user moves while touching the touch panel 1002. In the touch position change example according to this modification, the feature position specifying unit 114 specifies the touch position P [t8] as the feature position PR [4] at time t8. In the touch position change example according to this modification, the input region determination unit 115 sets the midpoint of the feature position PR [3] and the feature position PR [4] at the correction position Md [ t8]. Then, the input area determination unit 115 obtains a vector obtained by extracting only the YV component from the vectors starting from the reference position OV [t8] and ending at the correction position Md [t8], as the operation area movement vector Vmd [t8]. Determine as
Then, at time t9, the input area determination unit 115 corresponds the reference position OV [t8], the operation area coordinate system ΣV [t8], and the operation area V [t8] to the operation area movement vector Vmd [t8]. The reference position OV [t9], the operation area coordinate system ΣV [t9], and the operation area V [t9] are set by moving the movement amount. In the touch position change example according to this modification, the time t9 is a time later than the time t8, but the time t9 may be the same time as the time t8.

  As described above, in the present modification, the input area determination unit 115 performs the input area R [1] and the input area R based on the touch position P existing in the input area R [1] and the input area R [2]. The position of [2] is determined, and the positions of the input area R [3] and the input area R [4] are determined based on the touch position P existing in the input area R [3] and the input area R [4]. . For this reason, according to the present embodiment, for example, compared to the case where the position of the input region R [m] is fixed on the touch panel 1002, the possibility of erroneous input associated with the shift of the touch position P is reduced. Is possible.

[Modification 2]
In the embodiment described above, the inclination of the operation area coordinate system ΣV with respect to the touch panel coordinate system ΣD does not change, but the present invention is not limited to such an aspect.
For example, the input area determination unit 115 may change the inclination of the operation area coordinate system ΣV with respect to the touch panel coordinate system ΣD based on a plurality of feature positions P-R [m]. More specifically, when the feature position specifying unit 114 specifies the feature position PR [1] and the feature position PR [2], the input region determination unit 115 determines the feature position PR from the reference position OV. Even if the operation region coordinate system ΣV is set by determining the direction toward [1] as the + XV direction and determining the direction from the reference position OV toward the feature position PR [2] as the −XV direction. Good.

  FIG. 14 is an explanatory diagram for explaining an example of a touch position change according to the present modification. In the touch position change example according to this modification, the period from time t1 to time t4 is the same as the touch position change example according to the embodiment shown in FIGS.

In the touch position change example according to this modification, as shown in FIG. 14, the finger FG moves the input area R [1] and the input area R [4] from the time t4 to the time t5, and touches the position P [t4]. Is assumed to move from the touch position P [t5] while touching the touch panel 1002 and enter the input area R [2] at time t5. In the touch position change example according to this modification, the feature position specifying unit 114 specifies the touch position P [t5] as the feature position PR [2] at time t5. Also, in the touch position change example according to this modification, it is assumed that the feature position specifying unit 114 specifies the touch position P [t4] as the feature position PR [1] at time t5. In the touch position change example according to this modification, the input region determination unit 115 sets the midpoint of the feature position PR [1] and the feature position PR [2] at the correction position Md [ t5]. Further, the input area determining unit 115 determines a vector starting from the reference position OV [t5] and ending at the correction position Md [t5] as the operation area movement vector Vmd [t5].
Then, at time t6, the input area determination unit 115 corresponds the reference position OV [t5], the operation area coordinate system ΣV [t5], and the operation area V [t5] to the operation area movement vector Vmd [t5]. The reference position OV [t6], the operation area coordinate system ΣV [t6], and the operation area V [t6] are set by moving the movement amount. More specifically, the input area determination unit 115 moves the reference position OV from time t5 to time t6 so that the reference position OV [t6] matches the correction position Md [t5].
Thereafter, at time t7, the input area determination unit 115 determines the direction from the correction position Md [t5] to the characteristic position PR [R] [1] as the + XV direction, and the input area R [3] from the correction position Md [t5]. ], The direction orthogonal to the direction from the correction position Md [t5] to the feature position PR [1] is defined as the + YV direction, thereby setting the operation region coordinate system ΣV [t7]. . Then, the input area determination unit 115 sets the input areas R [1] to R [4] at positions based on the operation area coordinate system ΣV [t7] at time t7. Specifically, the input area determination unit 115 sets the input area R [1] in the + XV direction from the reference position OV [t7] at time t7, and inputs in the −XV direction from the reference position OV [t7]. Set the area R [2], set the input area R [3] in the + YV direction from the reference position OV [t7], and set the input area R [4] in the -YV direction from the reference position OV [t7]. To do.
In the touch position change example according to this modification, time t6 and time t7 are times later than time t5, but time t6 and time t7 may be the same time as time t5.

  As described above, in the present modification, the input region determination unit 115 performs the XV axis and YV axis of the operation region coordinate system ΣV based on the feature position PR [1] and the feature position PR [2]. Determine the slope of. For this reason, according to the present embodiment, for example, compared with an aspect in which the inclination of the operation area coordinate system ΣV is fixed on the touch panel 1002, the possibility of erroneous input due to the shift of the touch position P can be reduced. It becomes possible.

[Modification 3]
Although the touch position P existing in the input area R [m] is specified as the feature position PR [m] in the above-described embodiment and the first modification and the second modification, the present invention is limited to such a mode. It is not something.
For example, the feature position specifying unit 114 includes the input area R [m] and is based on the touch position P existing in the extended area RX [m], which is an area wider than the input area R [m]. -R [m] may be specified.

  Specifically, the feature position specifying unit 114 includes the touch position information acquisition unit at one time in the extended area touch period TX [m] in which the state where the touch position P exists in the extended area RX [m] continues. One or a plurality of touch positions acquired by the touch position information acquisition unit 113 in a period from the time when the extended region touch period TX [m] is started to one time is indicated by the touch position P indicated by the touch position information acquired by the 113. One of the touch positions P indicated by the information satisfies the condition that it exists at a position farthest from the reference position OV in the direction indicating the extended region RX [m] from the reference position OV. The touch position P corresponding to the time is identified as the characteristic position P-R [m].

More specifically, as shown in FIG. 15, the feature position specifying unit 114 is an extended area where the touch position P continues to exist in the extended area RX [1] (an example of “first area”). In the touch period TX [1], the touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 at one time is from the time when the extended area touch period TX [1] is started to one time. The condition of being positioned closest to + XV among one or a plurality of touch positions P indicated by one or a plurality of touch position information acquired by the touch position information acquisition unit 113 during another period (another example of “first condition”) ), The touch position P corresponding to the one time is specified as the characteristic position P-R [1].
In addition, the feature position specifying unit 114 selects one of the extended area touch periods TX [2] in which the touch position P continues in the extended area RX [2] (an example of “second area”). The touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 at the time is acquired by the touch position information acquisition unit 113 in the period from the time when the extended area touch period TX [2] is started to one time. In the case where the condition (other example of “second condition”) that is located closest to −XV among the one or more touch positions P indicated by the one or more touch position information is satisfied, the one The touch position P corresponding to the time is specified as the characteristic position P-R [2].

  As described above, in the present modification, the feature position specifying unit 114 determines the feature position P-R [m] based on the touch position P existing in the extended area RX [m] including the input area R [m]. The position of the input region R [m] is determined based on the characteristic position P-R [m]. For this reason, according to this modification, for example, compared with the case where the position of the input region R [m] is fixed on the touch panel 1002, the possibility of erroneous input due to the shift of the touch position P is reduced. Is possible.

[Modification 4]
In the embodiment described above and Modifications 1 to 3, the feature position specifying unit 114 indicates that the touch position P indicates the input area R [m] from the reference position OV in the input area touch period TR [m]. In the direction, when the characteristic position specifying condition that the position is farthest from the reference position OV is satisfied, the touch position P is specified as the characteristic position P-R [m]. It is not limited to.
For example, the feature position specifying unit 114 determines that the touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 at one time in the input area touch period TR [m] is the input area touch period TR [m]. From a reference position Pref [m] determined based on one or a plurality of touch positions P indicated by one or a plurality of touch position information acquired by the touch position information acquisition unit 113 in a period from the time when the touch is started to one time. If the condition that the input area R [m] is away from the reference position OV in the direction indicating the input region R [m] is satisfied, the touch position P corresponding to the one time is selected as the feature position PR. It may be specified as [m].

Specifically, the feature position specifying unit 114 determines that the touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 at one time in the input area touch period TR [1] is the input area touch period TR. The reference position Pref [determined based on one or more touch positions P indicated by one or more touch position information acquired by the touch position information acquiring unit 113 in a period from the time when [1] is started to one time. 1] (an example of “first reference position”), when the condition of being in the + XV direction (another example of “first condition”) is satisfied, the touch position P corresponding to the one time is The characteristic position P-R [1] may be specified.
Further, the feature position specifying unit 114 indicates that the touch position P indicated by the touch position information acquired by the touch position information acquisition unit 113 at one time in the input area touch period TR [2] is the input area touch period TR [2] Reference position Pref [2] (based on one or a plurality of touch positions P indicated by one or a plurality of touch position information acquired by the touch position information acquisition unit 113 in a period from the time when the touch is started to one time. When the condition of being in the −XV direction (another example of the “second condition”) is satisfied rather than the “example of the second reference position”, the touch position P corresponding to the one time is characterized. The position P-R [2] may be specified.

  The reference position Pref [m] is, for example, one or a plurality of touch position information acquired by the touch position information acquisition unit 113 in a period from the time when the input area touch period TR [m] is started to one time. May be an average position of one or a plurality of touch positions P, or may be an input region R [m] from a reference position OV among some touch positions P of the one or more touch positions P. May be a touch position P that is farthest from the reference position OV.

[Modification 5]
In the embodiment and the first to fourth modifications described above, the feature position specifying unit 114 performs the touch when the touch position P satisfies the feature position specifying condition in the input area touch period TR [m]. Although the position P is specified as the characteristic position P-R [m], the present invention is not limited to such an embodiment.
The feature position specifying unit 114 touches part or all of one or more touch positions P indicated by one or more touch position information acquired by the touch position information acquiring unit 113 in the input area touch period TR [m]. The feature position P-R [m] may be specified based on the position P.

  Specifically, the feature position specifying unit 114 selects one of the one or more touch positions P indicated by the one or more touch position information acquired by the touch position information acquisition unit 113 in the input area touch period TR [m]. You may identify the average position of the touch position P of a part or all as the characteristic position PR [R]. For example, in the example illustrated in FIG. 16, the feature position specifying unit 114 includes three pieces of touch position information acquired by the touch position information acquisition unit 113 in the input area touch period TR [1] as touch positions P [t2] and P [ When t3] and P [t4] are indicated, the average position of the three touch positions P [t2], P [t3], and P [t4] is specified as the feature position P-R [1]. May be.

  Further, for example, the feature position specifying unit 114 lastly among the one or more touch positions P indicated by the one or more touch position information acquired by the touch position information acquisition unit 113 in the input region touch period TR [m]. The touch position P indicated by the acquired touch position information may be specified as the characteristic position P-R [m]. Specifically, in the example illustrated in FIG. 16, the feature position specifying unit 114 determines that the three touch position information acquired by the touch position information acquisition unit 113 in the input area touch period TR [1] is the touch position P [t2]. , P [t3] and P [t4], the touch position P [t4] corresponding to the last acquired touch position information may be specified as the feature position P-R [1].

  Further, for example, the feature position specifying unit 114 is substantially omitted for a predetermined time or more out of the plurality of touch positions P indicated by the plurality of touch position information acquired by the touch position information acquiring unit 113 in the input area touch period TR [m]. When two or more touch positions P existing at the same position exist, the two or more touch positions P may be specified as the characteristic position P-R [m]. Here, “one touch position P and another touch position P are present at substantially the same position” means that, for example, one touch position P and another touch position P are present at the same position. The distance between one touch position P and another touch position P may be a predetermined distance or less.

[Modification 6]
In the above-described embodiment and Modifications 1 to 5, the case where the input area R [m] is a fan-shaped area is illustrated, but the present invention is not limited to such a mode. For example, as shown in FIG. 17, the input region R [m] may be an elliptical region or a polygonal region.

[Modification 7]
In the above-described embodiment and Modifications 1 to 6, the operation area V is composed of the input areas R [1] to R [4] that are areas for inputting an instruction in the direction in which the character CR faces. However, the present invention is not limited to such an embodiment. The operation area V may include a neutral area RN that is an area that does not accept an input of a direction in which the character CR faces. In this case, the neutral region RN may be provided as a region including the center of the input regions R [1] to R [4], that is, the reference position OV, as shown in FIG. Good.

[Modification 8]
In the above-described embodiment and Modifications 1 to 7, the input area R [m] is an area for inputting a single direction instruction relating to a predetermined game. It is not limited to. The input area R [m] includes, for example, K sub-areas R [m] [1] to R [m] [K] for inputting instructions in K directions, as shown in FIG. (K is a natural number of 2 or more).

[Modification 9]
In the above-described embodiment and Modifications 1 to 8, the case where the operation region V includes four input regions R [1] to R [4] has been described as an example. It is not limited to the embodiment. The operation area V only needs to include M input areas R [1] to R [M] (M is a natural number of 2 or more). The operation area V may include, for example, 12 input areas R [1] to R [12] as shown in FIG.
In the present modification, the number M of input areas may be an even number. In this case, the input region R [1] and the input region R [2] may be provided at symmetrical positions with respect to the reference position OV, as illustrated in FIG.

[Modification 10]
In the above-described embodiment and Modifications 1 to 9, the first direction indicating the input region R [1] from the reference position OV is opposite to the second direction indicating the input region R [2] from the reference position OV. However, the present invention is not limited to such an embodiment. The first direction and the second direction may be different directions or the same direction.

[Modification 11]
In the above-described embodiment and Modifications 1 to 10, the input area R [m] is an area for inputting an instruction in the direction in which the character CR faces, but the present invention is limited to such an aspect. It is not a thing. The input area R [m] may be an area for inputting an instruction relating to a predetermined game. For example, the input area R [1] is an area for inputting an attack instruction (an example of “first instruction”) by the character CR in a predetermined game, and the input area R [2] is a predetermined area. In the game, it may be an area for inputting a defense instruction (an example of “second instruction”) by the character CR. Further, for example, the input area R [m] may be an area for inputting an instruction of the moving direction of the character CR in the touch panel coordinate system ΣD or the virtual space SP. Specifically, for example, the input area R [1] is an area for inputting an instruction to move the character CR in one direction in the touch panel coordinate system ΣD or the virtual space SP. R [2] may be an area for inputting an instruction to move the character CR in another direction in the touch panel coordinate system ΣD or the virtual space SP.

[Modification 12]
In the above-described embodiment and modification examples 1 to 11, the program related to the predetermined game is described as an example of the program. However, the present invention is not limited to such an aspect. The program may be a program related to an arbitrary application. In this case, the first instruction may be an instruction related to an arbitrary application, and the second instruction may be an instruction related to an arbitrary application and an instruction different from the first instruction.

[Modification 13]
In the embodiment and the modifications 1 to 12 described above, the predetermined game is executed in the terminal device 10, but the present invention is not limited to such an aspect. The predetermined game may be executed in components other than the terminal device 10.

FIG. 21 is an explanatory diagram showing an overview of the information processing system SYS according to the present modification. The information processing system SYS includes a server device 30A and a terminal device 10A. The server device 30A can execute a predetermined game and can communicate with the terminal device 10A via the network NW.
Specifically, the server device 30A includes a control unit 11 that controls each unit of the server device 30A, a storage unit 31 that stores various information such as a program related to a predetermined game, and an external device such as the terminal device 10A. And a communication unit 32 for performing communication between them. In addition to the display unit 12, the input unit 13, and the vibration generation unit 15, the terminal device 10A includes a communication unit 16 for executing communication with an external device such as the server device 30A. The display unit 12 and the input unit 13 are mounted as the touch panel 1002 described above.
Server device 30A generates display information based on information input from input unit 13 of terminal device 10A. Further, the display unit 12 included in the terminal device 10A displays an image related to a predetermined game based on display information generated in the server device 30A.

[C. Addendum]
From the above description, the present invention is grasped as follows, for example. In order to facilitate understanding of each aspect, reference numerals in the drawings are appended in parentheses for convenience in the following, but the present invention is not limited to the illustrated aspects.

[Appendix 1]
The program according to an aspect of the present invention includes a processor that acquires a touch position information indicating a touch position on a touch panel, and a touch acquired by the acquisition unit in a touch period in which the touch on the touch panel is continued. When the touch position indicated by the position information is present in the first input area for inputting an instruction of the first operation direction related to the game and satisfies the first condition related to the touch position, the touch position is based on the touch position. A position is specified as a first position, and a second input for inputting an instruction of a second operation direction related to the game by the touch position indicated by the touch position information acquired by the acquisition unit in the touch period. A specifying unit that specifies a position based on the touch position as a second position when the second condition relating to the touch position is present in the region; Based on the first position and the second position specified by the specifying unit, and functioning as a determining unit that determines the positions of the first input region and the second input region. To do.

  In this aspect, the determination unit includes a first position that is a position based on the touch position in the first input area, and a second position that is a position based on the touch position in the second input area (hereinafter referred to as the first position and the first position). The second input position and the second input area (hereinafter, the first input area and the second input area may be referred to as “input area”). The position is sometimes collectively referred to as Accordingly, in this aspect, the determination unit can correct the position of the input area according to the shift of the touch position even when the touch position in the input area is gradually shifted. For this reason, according to this aspect, compared with the case where the position of the input area is fixed, for example, it is possible to reduce the possibility of erroneous input due to the shift of the touch position on the touch panel.

  By the way, a mode of determining the positions of the first input region and the second input region based on one feature position (hereinafter, this mode is referred to as “proportional”) is also conceivable. Specifically, in the comparative example, as an example, a first representative position that is a representative position of the first input area, such as the center position or the center of gravity of the first input area, is set at a position corresponding to one feature position. In addition, a second representative position that is a representative position of the second input area, such as the center position or the center of gravity of the second input area, is determined at a position corresponding to the first representative position (hereinafter referred to as the first representative position). The representative position and the second representative position may be collectively referred to as “representative position”). For example, in the comparative example, one feature position is determined as the first representative position, and a position having a predetermined positional relationship with the first representative position is determined as the second representative position. That is, in the proportionality, the relative positional relationship between each feature position and the representative position of each input area or the interval between each feature position and the representative position of each input area cannot be adjusted. In other words, the proportionality is a constraint that the relative positional relationship between each feature position and the representative position of each input region is maintained in a predetermined positional relationship, or each feature position and the representative position of each input region. The position of the first input area and the second input area is only determined under the restriction that the distance between the first input area and the second input area is maintained at a predetermined distance.

  On the other hand, for example, when the user touches the touch panel with a finger, the size and shape of the user's finger are different for each user. Further, for example, when the user touches the touch panel with a finger, the pressure when the user touches the touch panel with the finger, the inclination of the finger with respect to the touch panel, the way of moving the finger, and the like are different for each user. Thus, when the user touches the touch panel with a finger, the touch mode is different for each user. Therefore, when the user touches the touch panel with a finger, the relative positional relationship between each feature position and the representative position of each input area, and the interval between each feature position and the representative position of each input area are also set for each user. Will be different. Therefore, in order to keep good operability in an operation for inputting an instruction for the first operation direction and an operation for inputting an instruction for the second operation direction for an arbitrary user. It is preferable to adjust the relative positional relationship between each feature position and the representative position of each input area, and the interval between each feature position and the representative position of each input area according to the touch mode for each user. .

  However, in contrast, as described above, it is difficult to adjust the relative positional relationship between each feature position and the representative position of each input area, or the interval between each feature position and the representative position of each input area. It is. For this reason, in contrast, operability in an operation for inputting an instruction for the first operation direction and an operation for inputting an instruction for the second operation direction is given to an arbitrary user. It is difficult to keep good.

  On the other hand, according to this aspect, the determination unit determines the positions of the first input area and the second input area using the two characteristic positions of the first position and the second position. In general, the relative positional relationship between the first position and the second position and the interval between the first position and the second position are determined according to the touch mode for each user. Probability is high. For this reason, according to this aspect, operability in an operation for inputting an instruction in the first operation direction and an operation for inputting an instruction in the second operation direction for an arbitrary user. Can be kept better than the proportionality.

  In the above aspect, the “first operation direction related to the game” is an example of “the operation direction related to the game”. The “operation direction related to the game” may be, for example, a direction in the virtual space related to the game or a direction on the screen related to the game. The “direction in the virtual space related to the game” is, for example, the direction of change of one or both of the position and orientation of the game element in the virtual space related to the game. Here, the “game element” may be, for example, a virtual object that exists in the virtual space related to the game, or a virtual camera that captures an image of the virtual space related to the game. Among these, the “virtual object existing in the virtual space related to the game” may be a concept including, for example, a character related to the game and an object related to the game. The “direction on the screen related to the game” may be, for example, the direction of change of one or both of the position and orientation on the screen of the image showing the virtual object displayed on the screen related to the game. The moving direction on the menu screen of an image showing a game element that is not related to the progress of the game, such as a pointer displayed on the menu screen, may be used.

  In the above aspect, the “second operation direction related to the game” is another example of the “operation direction related to the game”. Here, the “second operation direction” is a direction different from the first operation direction. The “second operation direction” may be a direction opposite to the first operation direction, for example.

  In the above aspect, the “first input area” may be, for example, an area provided in an aspect that can be visually recognized on the touch panel for inputting a first operation direction instruction relating to the game. It may be a virtual area provided in a manner that is not visually recognized on the touch panel in order to input an instruction for the first operation direction related to the game. The “second input area” is, for example, an area that is different from the first input area, and is provided in a manner that can be visually recognized on the touch panel in order to input a second operation direction instruction related to the game. Or a virtual area that is different from the first input area and is provided in a manner that is not visually recognized on the touch panel in order to input a second operation direction instruction relating to the game. May be.

  In the above aspect, the “first condition” may be, for example, a condition for the presence range of the touch position indicated by the touch position information, or a condition for the history of the touch position indicated by the touch position information. Alternatively, it may be a condition about the moving speed of the touch position indicated by the touch position information. Here, the “condition regarding the history of the touch position indicated by the touch position information” means, for example, that the touch position indicated by the touch position information is within the period in which the touch position indicated by the touch position information exists in the first input area. The condition may be that the position is farthest from the reference position in a predetermined direction. Specifically, the “condition about the touch position history indicated by the touch position information” is, for example, when the first input area is positioned in the first direction relative to the second input area. The condition that the touch position indicated by the touch position information is the farthest position from the second input area in the first direction during the period in which the touch position to be indicated exists in the first input area may be used. In addition, the “condition regarding the presence range of the touch position indicated by the touch position information” means, for example, that the touch position indicated by the touch position information is within the period in which the touch position indicated by the touch position information exists in the first input area. The first input area may be in a condition that it exists in a predetermined range for a predetermined time or more. Specifically, the “condition regarding the presence range of the touch position indicated by the touch position information” means, for example, that the touch position indicated by the touch position information is substantially the same position over a predetermined time in the first input area. It may be the condition. Here, a certain position and another position are “substantially the same position”, for example, a certain position and another position may be the same position, or a certain position and another position are predetermined. It is possible to have a positional relationship that is less than or equal to the distance. The “second condition” may be, for example, a condition regarding the presence range of the touch position indicated by the touch position information, a condition regarding a history of touch positions indicated by the touch position information, or a touch. The condition regarding the moving speed of the touch position indicated by the position information may be used. Specifically, the “second condition” refers to, for example, when the second input area is positioned in the second direction relative to the first input area, the touch position indicated by the touch position information is the second input area. It may be a condition that the touch position indicated by the touch position information is a position farthest from the first input area in the second direction during the existing period. The “second condition” may be a condition that, for example, the touch position indicated by the touch position information is substantially the same position for a predetermined time or more in the second input area.

  In the above aspect, the “position based on the touch position” may be, for example, a position specified by using the touch position, or may be a position determined based on the touch position. Specifically, the “position based on the touch position” may be, for example, the same position as the touch position, an average position of the touch positions in a predetermined period, or the touch position and the predetermined position. It may be a position below the distance.

[Appendix 2]
A program according to another aspect of the present invention is the program according to attachment 1, wherein, in the touch period, the specifying unit indicates that the touch position indicated by the touch position information acquired by the acquisition unit is the first input. A position based on the touch position is specified as a first position when the first condition exists in the first area including the area and the first condition is satisfied, and the touch position information acquired by the acquisition unit in the touch period When the touch position to be shown exists in the second area including the second input area and the second condition is satisfied, the position based on the touch position is specified as the second position.

In this aspect, the determination unit determines the positions of the first input area and the second input area using the two characteristic positions of the first position and the second position. Accordingly, in this aspect, the determination unit can correct the position of the input area according to the shift of the touch position even when the touch position in the input area is gradually shifted.
Further, according to this aspect, since the determination unit determines the positions of the first input area and the second input area using the two feature positions, an instruction for the first operation direction is given to an arbitrary user. It is possible to keep the operability in the operation for performing the input and the operation for performing the input of the instruction in the second operation direction better than the comparison.
Further, according to this aspect, the position based on the touch position in the first area including the first input area is specified as the first position, and the position based on the touch position in the second area including the second input area is determined as follows: Specify as the second position. That is, according to this aspect, even when the touch position is outside the input area, the position of the input area can be corrected using the characteristic position based on the touch position. Therefore, according to this aspect, for example, as compared with the case where the position of the input area is corrected only when the touch position exists in the input area, the setting of the input area corresponding to various touch modes can be flexibly performed. Is possible.

  In the above aspect, the “first region” may be, for example, the same region as the first input region or a region wider than the first input region including the first input region. . The “second area” is, for example, an area that does not include the first area, and may be the same area as the second input area, or an area that does not include the first area, and the second input area. The area may be wider than the second input area including the area.

[Appendix 3]
A program according to another aspect of the present invention is the program according to attachment 1, wherein, in the touch period, the specifying unit indicates that the touch position indicated by the touch position information acquired by the acquisition unit is the first input. When changing from a state existing at a position different from the area to a state existing at the first input area, the position based on the touch position after the change is specified as the first position, and the touch period When the touch position indicated by the touch position information acquired by the acquisition unit is changed from a state existing in a position different from the second input area to a state existing in the second input area, A position based on the touch position is specified as the second position.

  In this aspect, for example, at the first time, the specifying unit specifies the position based on the touch position existing in one input area as the feature position, and at the second time after the first time, the touch is performed. When the position is outside the one input area, and the touch position is again in the one input area at the third time after the second time, the specifying unit performs the third time. A position based on the touch position at is specified as a feature position. For this reason, in this aspect, the specifying unit can set a new feature position at the third time without being bound to the feature position specified at the first time. That is, in this aspect, even when the touch position changes, the determination unit flexibly determines the input position according to the change of the touch position without being bound to the feature position specified at the past time. It becomes possible.

[Appendix 4]
A program according to another aspect of the present invention is the program according to attachment 1 or 3, wherein the specifying unit has a touch position indicated by touch position information acquired by the acquisition unit in the touch period. In the first touch period existing in one input area, when the touch position is farthest from the reference position in the first direction, the position based on the touch position is specified as the first position, Among the touch periods, in the second touch period in which the touch position indicated by the touch position information acquired by the acquisition unit exists in the second input area, the touch position is separated from the reference position in the second direction. A position based on the touch position is specified as the second position when it is farthest away.

  Generally, among the touch positions existing in the first input area, the touch position furthest away from the reference position in the first direction, and among touch positions existing in the second input area, the second direction from the reference position. The relative positional relationship and interval with the most distant touch position vary depending on the touch mode for each user. In this aspect, the specifying unit specifies the position based on the touch position as the first position when the touch position exists in the first input area and is farthest from the reference position in the first direction. When the touch position exists in the second input area and is farthest from the reference position in the second direction, the position based on the touch position is specified as the second position. For this reason, according to this aspect, operability in an operation for inputting an instruction in the first operation direction and an operation for inputting an instruction in the second operation direction for an arbitrary user. Can be kept better than the proportionality.

  In the above aspect, the “reference position” may be, for example, a position between the first input area and the second input area, or is substantially equidistant from the first input area and the second input area. The position may be an arbitrary position on the touch panel.

  In the above aspect, the “first direction” may be, for example, a direction indicating an arbitrary position included in the first input area from the reference position, or included in the first input area from the reference position. A direction different from a direction indicating an arbitrary position may be used. The “second direction” is a direction different from the first direction. The “second direction” may be, for example, a direction opposite to the first direction or a direction intersecting the first direction. Specifically, the “second direction” may be, for example, a direction indicating an arbitrary position included in the second input area from the reference position, or an arbitrary included in the second input area from the reference position. The direction may be different from the direction indicating the position.

[Appendix 5]
A program according to another aspect of the present invention is the program according to attachment 1 or 3, wherein the specifying unit has a touch position indicated by touch position information acquired by the acquisition unit in the touch period. In the first touch period existing in one input area, when the touch position is located in a first direction with respect to a first reference position determined based on a history of touch positions in the first touch period, A position based on the touch position is specified as the first position, and the touch position indicated by the touch position information acquired by the acquisition unit in the touch period is a second touch period in the second input region. The touch position is based on the touch position when the touch position is located in the second direction with respect to the second reference position determined based on the touch position history in the second touch period. Position is specified as the second position, it is characterized.

  In general, when the touch position is positioned in the first direction relative to the first reference position in the first touch period, the touch position in the second touch period is the first touch position. In the case where the position is located in the second direction with respect to the two reference positions, the relative positional relationship with the touch position and the interval vary according to the touch mode for each user. In this aspect, the specifying unit sets, as the first position, a position based on the touch position when the touch position is positioned in the first direction relative to the first reference position in the first touch period. In the second touch period, the position based on the touch position when the touch position is positioned in the second direction relative to the second reference position is specified as the second position. For this reason, according to this aspect, operability in an operation for inputting an instruction in the first operation direction and an operation for inputting an instruction in the second operation direction for an arbitrary user. Can be kept better than the proportionality.

  In the above aspect, the “first reference position” means, for example, that the touch position indicated by the touch position information is located closest to the first direction in the period before the current time in the first touch period. The position based on the touch position indicated by the touch position information at the time to be performed may be used. In addition, the “first reference position” may be, for example, an average position of touch positions indicated by touch position information in a period before the current time in the first touch period. The “second reference position” is, for example, the touch position at the time when the touch position indicated by the touch position information is located closest to the second direction in the second touch period that is past the current time. It may be a position based on the touch position indicated by the information. In addition, the “second reference position” may be, for example, an average position of touch positions indicated by touch position information in a period before the current time in the second touch period.

[Appendix 6]
A program according to another aspect of the present invention is the program according to attachment 4, wherein the determination unit determines a position between the first position and the second position as the reference position, The position of the first input area is determined such that the first input area is positioned in a first direction relative to the reference position, and the second input area is positioned in a second direction relative to the reference position. The position of the second input area is determined so as to be positioned.

  Generally, among the touch positions existing in the first input area, the touch position furthest away from the reference position in the first direction, and among touch positions existing in the second input area, the second direction from the reference position. The relative positional relationship and interval with the most distant touch position vary depending on the touch mode for each user. In this aspect, the specifying unit is configured such that when the touch position is present in the first input area located in the first direction relative to the reference position and is farthest from the reference position in the first direction, The position based on the touch position is specified as the first position, and the touch position exists in the second input area located in the second direction relative to the reference position and is farthest from the reference position in the second direction. In this case, the position based on the touch position is specified as the second position. For this reason, according to this aspect, operability in an operation for inputting an instruction in the first operation direction and an operation for inputting an instruction in the second operation direction for an arbitrary user. Can be kept better than the proportionality.

[Appendix 7]
A program according to another aspect of the present invention is the program according to appendix 4 or 6, wherein the determination unit changes from a state where the touch panel is not touched to a state where the touch panel is touched. A position based on the touch position indicated by the touch position information acquired by the acquisition unit after the change is determined as the reference position.

  In this aspect, the determining unit determines, as a reference position, a position based on the touch position after the touch is changed to the touched state when the touch is changed from the touchless state to the touched state. That is, in this aspect, the determination unit determines the positions of the first input area and the second input area based on the first position and the second position specified by the touch position when the touch on the touch panel occurs. To do. Therefore, according to this aspect, for example, in a case where a touch on the touch panel occurs compared to a case where the reference position and the positions of the first input area and the second input area are determined in advance, the desired input area It is possible to reduce the possibility of touching an input area different from the above by mistake. In other words, according to this aspect, for example, it is possible to reduce the possibility of erroneous input as compared with a case where the reference position and the positions of the first input area and the second input area are determined in advance. It becomes possible.

[Appendix 8]
A program according to another aspect of the present invention is the program according to appendix 1 or 3, wherein, in the touch period, the specifying unit indicates that the touch position indicated by the touch position information acquired by the acquisition unit is the first position. In one input area, when the positions are substantially the same for a predetermined time or longer, the position based on the touch position is specified as the first position, and the touch position information acquired by the acquisition unit in the touch period is specified. When the touch position to be shown is substantially the same position over the predetermined time in the second input area, the position based on the touch position is specified as the second position.

  In this aspect, the specifying unit specifies a position based on the touch position as a feature position when the touch position is substantially the same position over a predetermined time in the input area. In general, when the touch position is maintained at substantially the same position in the input area, the user who made the touch is likely to have an intention to touch the input area, and the touch may not be an erroneous input. High nature. For this reason, according to this aspect, it can prevent that a 1st input area and a 2nd input area are set in the position contrary to a user's intention.

[Appendix 9]
A program according to another aspect of the present invention is the program according to appendices 1 to 8, wherein the determination unit is configured so that the first input area is positioned in a first direction with respect to a reference position. The position of the first input area is determined, and the position of the second input area is set such that the second input area is positioned in a second direction opposite to the first direction from the reference position. It is characterized by determining.

In general, in the touch period, the touch position is, for example, between a first input area positioned in a first direction relative to a reference position and a second input area positioned in a second direction relative to the reference position. When reciprocating, there is a high possibility that the touch position is shifted in the first direction or the second direction from the desired position. In particular, when the first input area is provided on the opposite side of the second input area when viewed from the reference position, the first input area is provided at a position that is not opposite to the second input area when viewed from the reference position. Compared with the case where it is, the possibility that the distance between the arbitrary positions in the 1st input area and the arbitrary positions in the 2nd input area will become large becomes high. That is, when the first input area is provided on the opposite side of the second input area when viewed from the reference position, the first input area is provided at a position that is not opposite to the second input area when viewed from the reference position. Compared with the case where it is, the possibility that the amount of displacement of the touch position with respect to a desired position in the first input area or the second input area will increase is increased.
On the other hand, the determination unit according to this aspect performs the first input based on the first position based on the touch position in the first input area and the second position based on the touch position in the second input area. The positions of the area and the second input area are corrected. That is, when the touch position shifts with respect to a desired position, the determination unit according to this aspect performs the first input region and the second input based on the first position and the second position determined according to the shift. The position of the input area can be corrected. In this aspect, as described above, since the first input area is provided on the opposite side of the second input area when viewed from the reference position, the first input area is the second input area when viewed from the reference position. Compared to the case where the first position and the second position are provided at positions that are not on the opposite side, there is a higher possibility that the first position and the second position will reflect the shift of the touch position with respect to the desired position more sensitively. . Therefore, in this aspect, even if the touch position is shifted in the first direction or the second direction, the determination unit determines the position of the first input area and the second input area according to the shift of the touch position. Can be corrected. For this reason, according to this aspect, for example, compared with the case where the positions of the first input area and the second input area are fixed, the possibility of erroneous input due to the shift of the touch position on the touch panel is reduced. It becomes possible.

[Appendix 10]
A program according to another aspect of the present invention is the program according to appendix 9, wherein the determination unit has an angle formed with a first reference line extending in the first direction from the reference position. At least a part of a region having an angle of 1 or less is determined as the first input region, and an angle formed by a second reference line extending in the second direction from the reference position is equal to or less than the second angle At least a part of the area is determined as the second input area.

  In this aspect, as an example, the determination unit determines the first input area as a fan-shaped area extending from the reference position in the first direction, and sets the second input area from the reference position in the second direction. Determined as a fan-shaped area that expands. Therefore, according to this aspect, for example, when the user touches the touch panel with a finger, the user touches the first input region by tilting the finger in the first direction while touching the finger at the reference position. It is possible to touch the second input area by tilting the finger in the second direction while touching the reference position. That is, according to this aspect, for example, when the user touches the touch panel with a finger, the user touches the two input areas of the first input area and the second input area without separating the finger from the touch panel. It becomes possible. For this reason, according to this aspect, for example, compared with the case where the finger needs to be separated from the touch panel between the touch on the first input area and the touch on the second input area, the user can It is possible to easily switch between the operation for inputting the operation direction instruction and the operation for inputting the second operation direction instruction.

  In the above aspect, the “first angle” may be an angle of 90 degrees or less. The “first angle” may be 45 degrees, for example. The “second angle” may be an angle of 90 degrees or less. The “second angle” may be 45 degrees, for example.

[Appendix 11]
A program according to another aspect of the present invention is the program according to appendices 1 to 10, wherein the determination unit is configured so that the first input area is positioned in a first direction with respect to a reference position. The position of the first input area is determined, the position of the second input area is determined such that the second input area is positioned in the second direction relative to the reference position, and the specifying unit specifies Based on the first position and the second position, a position of a third input area for inputting an instruction for a third operation direction related to the game is determined, and the third input area is the reference position. The second direction is opposite to the first direction, and the third direction intersects the first direction and the second direction. It is a direction to do.

  According to this aspect, the determination unit determines the positions of the first input area, the second input area, and the third input area based on the first position and the second position. Therefore, according to this aspect, for example, when the touch position exists in the third input area, the touch position is specified as the third position, and the first position, the second position, and the third position Compared with the aspect in which the positions of the first input area, the second input area, and the third input area are determined based on the position, the frequency of touching the third input area is less than the first input area and the second input area. Even when the frequency of touching the input area is lower, the position of the third input area can be accurately determined.

  In the above aspect, the “third direction” may be, for example, a direction orthogonal to the first direction and the second direction.

[Appendix 12]
A program according to another aspect of the present invention is the program according to appendices 1 to 11, wherein the determining unit specifies the first position and the second position when the specifying unit specifies the first position and the second position. A direction indicating the first position from a reference position is determined as a first direction, a direction indicating the second position from the reference position is determined as a second direction, and the first direction and the The positions of the first input area and the second input area are determined based on a second direction.

  In this aspect, the determination unit includes the first input region and the second input based on the first direction determined according to the first position and the second direction determined according to the second position. Determine the location of the region. Therefore, in this aspect, even when the touch position in the input area gradually shifts, the determination unit corrects the inclination of the input area in the coordinate system fixed to the touch panel according to the shift of the touch position. Is possible. For this reason, according to this aspect, for example, compared with the case where the inclination of the input area in the coordinate system fixed to the touch panel is fixed, the possibility of erroneous input due to the shift of the touch position on the touch panel is reduced. It becomes possible to do.

[Appendix 13]
A program according to another aspect of the present invention is the program according to attachments 1 to 12, wherein the processor is changed from a state where the touch panel is not touched to a state where the touch panel is touched, The acquisition unit acquires the touch position indicated by the touch position information acquired by the acquisition unit when the touch position is changed from a state different from the first input region to a state existing in the first input region. In the case where at least one of the case where the touch position indicated by the touch position information is changed from the state existing at the position different from the second input area to the state existing in the second input area, the touch panel is used. It is further characterized by functioning as a vibration control unit that vibrates.

  According to this aspect, for example, when the user touches the touch panel with a finger, the user intuitively grasps at least one of the change in the presence / absence of the touch and the change in the touch position as a touch panel vibration by a tactile sense. It becomes possible to do.

[Appendix 14]
An information processing apparatus according to an aspect of the present invention includes an acquisition unit that acquires touch position information indicating a touch position on a touch panel, and a touch position acquired by the acquisition unit in a touch period in which the touch on the touch panel continues. The position based on the touch position when the touch position indicated by the information exists in the first input area for inputting an instruction of the first operation direction related to the game and satisfies the first condition related to the touch position. As the first position, and the touch position indicated by the touch position information acquired by the acquisition unit in the touch period is a second input area for inputting an instruction of the second operation direction related to the game A specifying unit that specifies a position based on the touch position as a second position when the second condition related to the touch position is satisfied, and the specifying unit Based on the identified first position and said second position, and a determination unit for determining the position of said first input region and the second input region, characterized in that.

In this aspect, the determination unit determines the position of the input region based on the feature position. Accordingly, in this aspect, the determination unit can correct the position of the input area according to the shift of the touch position even when the touch position in the input area is gradually shifted. For this reason, according to this aspect, compared with the case where the position of the input area is fixed, for example, it is possible to reduce the possibility of erroneous input due to the shift of the touch position on the touch panel.
Further, according to this aspect, the determination unit determines the positions of the first input area and the second input area using the two feature positions. Therefore, according to this aspect, operability in an operation for inputting an instruction for the first operation direction and an operation for inputting an instruction for the second operation direction for an arbitrary user. Can be kept better than the proportionality.

[Appendix 15]
In the program according to another aspect of the present invention, the processor acquires the processor in the acquisition unit that acquires the touch position information indicating the touch position on the touch panel, and the touch period during which the touch on the touch panel continues. When the touch position indicated by the touch position information exists in the first input area for inputting the first instruction and the first condition related to the touch position is satisfied, the position based on the touch position is set to the first position. The touch position indicated by the touch position information acquired by the acquisition unit in the touch period is present in a second input area for inputting a second instruction, and is associated with the touch position. When two conditions are satisfied, a specifying unit that specifies a position based on the touch position as a second position, the first position specified by the specifying unit, and the first position Based on the position, and the first input region and a determining section for determining a position of the second input region, thereby to function, characterized in that.

In this aspect, the determination unit determines the position of the input region based on the feature position. Accordingly, in this aspect, the determination unit can correct the position of the input area according to the shift of the touch position even when the touch position in the input area is gradually shifted. For this reason, according to this aspect, compared with the case where the position of the input area is fixed, for example, it is possible to reduce the possibility of erroneous input due to the shift of the touch position on the touch panel.
Further, according to this aspect, the determination unit determines the positions of the first input area and the second input area using the two feature positions. For this reason, according to this aspect, the operability in the operation for inputting the first instruction and the operation for inputting the second instruction for any user is compared with the proportionality. Can be kept good.

  In the above aspect, the “first instruction” may be, for example, an instruction related to a game provided using a touch panel, or an instruction related to an arbitrary service provided using a touch panel. Good. The “second instruction” is, for example, an instruction different from the first instruction, may be an instruction regarding a game provided using the touch panel, or is an instruction different from the first instruction. An instruction related to an arbitrary service provided using the touch panel may be used.

[Appendix 16]
In the program according to another aspect of the present invention, the processor acquires the processor in the acquisition unit that acquires the touch position information indicating the touch position on the touch panel, and the touch period during which the touch on the touch panel continues. When the touch position indicated by the touch position information exists in the first input area for inputting an instruction of the first operation direction related to the game, the position based on the touch position can be specified as the first position. Yes, in the touch period, when the touch position indicated by the touch position information acquired by the acquisition unit exists in a second input area for inputting an instruction of a second operation direction related to the game, the touch The position based on the position can be specified as a second position, based on the first position and the second position specified by the specification section, A determination unit for determining the position of the first input region and the second input region, thereby to function, characterized in that.

In this aspect, the determination unit determines the position of the input region based on the feature position. Accordingly, in this aspect, the determination unit can correct the position of the input area according to the shift of the touch position even when the touch position in the input area is gradually shifted. For this reason, according to this aspect, compared with the case where the position of the input area is fixed, for example, it is possible to reduce the possibility of erroneous input due to the shift of the touch position on the touch panel.
Further, according to this aspect, the determination unit determines the positions of the first input area and the second input area using the two feature positions. Therefore, according to this aspect, operability in an operation for inputting an instruction for the first operation direction and an operation for inputting an instruction for the second operation direction for an arbitrary user. Can be kept better than the proportionality.

DESCRIPTION OF SYMBOLS 10 ... Terminal device, 11 ... Control part, 12 ... Display part, 13 ... Input part, 14 ... Memory | storage part, 15 ... Vibration generating part, 111 ... Game control part, 112 ... Display control part, 113 ... Touch position information acquisition part , 114... Feature position specifying unit, 115... Input area determining unit, 116... Vibration control unit, 1000.

Claims (14)

Processor,
An acquisition unit for acquiring touch position information indicating a touch position on the touch panel;
In the touch period in which the touch on the touch panel continues,
The touch position indicated by the touch position information acquired by the acquisition unit is
Exists in the first input area for inputting an instruction of the first operation direction related to the game,
When the first condition related to the touch position is satisfied,
Specifying a position based on the touch position as a first position;
In the touch period,
The touch position indicated by the touch position information acquired by the acquisition unit is
Exists in a second input area for inputting a second operation direction instruction relating to the game,
When the second condition related to the touch position is satisfied,
A specifying unit that specifies a position based on the touch position as a second position;
Based on the first position and the second position specified by the specifying unit,
A determination unit for determining positions of the first input area and the second input area;
Make it work,
A program characterized by that. The specific part is:
In the touch period,
The touch position indicated by the touch position information acquired by the acquisition unit is
Present in a first region including the first input region;
When the first condition is satisfied,
Specifying a position based on the touch position as a first position;
In the touch period,
The touch position indicated by the touch position information acquired by the acquisition unit is
Present in a second region including the second input region;
When the second condition is satisfied,
Specifying a position based on the touch position as a second position;
The program according to claim 1, wherein: The specific part is:
In the touch period,
The touch position indicated by the touch position information acquired by the acquisition unit is
From a state existing at a position different from the first input area,
When changed to a state existing in the first input area,
A position based on the touch position after the change is specified as the first position,
In the touch period,
The touch position indicated by the touch position information acquired by the acquisition unit is
From a state existing at a position different from the second input area,
When changing to a state existing in the second input area,
A position based on the touch position after the change is specified as the second position.
The program according to claim 1, wherein: The specific part is:
Of the touch period,
In the first touch period in which the touch position indicated by the touch position information acquired by the acquisition unit exists in the first input area,
When the touch position is farthest from the reference position in the first direction,
Specifying a position based on the touch position as the first position;
Of the touch period,
In the second touch period in which the touch position indicated by the touch position information acquired by the acquisition unit exists in the second input area,
When the touch position is farthest from the reference position in the second direction,
Specifying a position based on the touch position as the second position;
The program according to claim 1 or 3, characterized by the above. The specific part is:
Of the touch period,
In the first touch period in which the touch position indicated by the touch position information acquired by the acquisition unit exists in the first input area,
The touch position is
When positioned in the first direction from the first reference position determined based on the history of the touch position in the first touch period,
Specifying a position based on the touch position as the first position;
Of the touch period,
In the second touch period in which the touch position indicated by the touch position information acquired by the acquisition unit exists in the second input area,
The touch position is
When located in the second direction with respect to the second reference position determined based on the history of the touch position in the second touch period,
Specifying a position based on the touch position as the second position;
The program according to claim 1 or 3, characterized by the above. The determination unit
Determining a position between the first position and the second position as the reference position;
The first input area is positioned in a first direction with respect to the reference position,
Determining the position of the first input area;
The second input area is positioned in a second direction with respect to the reference position,
Determining the position of the second input area;
The program according to claim 4, wherein: The determination unit
From the state where there is no touch on the touch panel,
When the touch panel changes to a touch state,
The position based on the touch position indicated by the touch position information acquired by the acquisition unit after the change,
Determining the reference position;
The program according to claim 4 or 6, characterized by the above. The specific part is:
In the touch period,
The touch position indicated by the touch position information acquired by the acquisition unit is
In the first input area, when the position is substantially the same over a predetermined time,
Specifying a position based on the touch position as the first position;
In the touch period,
The touch position indicated by the touch position information acquired by the acquisition unit is
In the second input area, when it is substantially the same position over the predetermined time,
Specifying a position based on the touch position as the second position;
The program according to claim 1 or 3, characterized by the above. The determination unit
The first input area is positioned in the first direction from the reference position,
Determining the position of the first input area;
The second input area is positioned in a second direction opposite to the first direction from the reference position.
Determining the position of the second input area;
The program according to claim 1, wherein the program is any one of the above. The determination unit
At least a part of a region whose angle formed with the first reference line extending in the first direction from the reference position is equal to or less than the first angle,
Determining the first input area;
An angle formed by a second reference line extending in the second direction from the reference position is at least part of a region having a second angle or less.
Determining the second input area;
The program according to claim 9, wherein: The determination unit
The first input area is positioned in the first direction from the reference position,
Determining the position of the first input area;
The second input area is positioned in a second direction with respect to the reference position,
Determining the position of the second input area;
Based on the first position and the second position specified by the specifying unit,
Determining a position of a third input area for inputting an instruction of a third operation direction according to the game;
The third input area is
Located in a third direction from the reference position,
The second direction is
A direction opposite to the first direction;
The third direction is
A direction intersecting the first direction and the second direction,
The program according to any one of claims 1 to 10, wherein the program is characterized by the above. The determination unit
When the specifying unit specifies the first position and the second position,
A direction indicating the first position from a reference position is determined as a first direction;
A direction indicating the second position from the reference position is determined as a second direction;
Based on the first direction and the second direction,
Determining positions of the first input area and the second input area;
The program according to claim 1, wherein the program is any one of the above. The processor;
From the state where there is no touch on the touch panel,
When the touch panel changes to a touch state,
The touch position indicated by the touch position information acquired by the acquisition unit is
From a state existing at a position different from the first input area,
A change to a state existing in the first input area;
The touch position indicated by the touch position information acquired by the acquisition unit is
From a state existing at a position different from the second input area,
When it changes to a state existing in the second input area;
In at least one of
A vibration control unit for vibrating the touch panel;
As a further function,
The program according to any one of claims 1 to 12, characterized in that: An acquisition unit for acquiring touch position information indicating a touch position on the touch panel;
In the touch period in which the touch on the touch panel continues,
The touch position indicated by the touch position information acquired by the acquisition unit is
Exists in the first input area for inputting an instruction of the first operation direction related to the game,
When the first condition related to the touch position is satisfied,
Specifying a position based on the touch position as a first position;
In the touch period,
The touch position indicated by the touch position information acquired by the acquisition unit is
Exists in a second input area for inputting a second operation direction instruction relating to the game,
When the second condition related to the touch position is satisfied,
A specifying unit that specifies a position based on the touch position as a second position;
Based on the first position and the second position specified by the specifying unit,
A determination unit for determining positions of the first input area and the second input area;
Comprising
An information processing apparatus.

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