JP7286856B2 - Information processing system, program and information processing method - Google Patents

Description

The present invention relates to an information processing system, a program, and an information processing method.

2. Description of the Related Art Conventionally, information processing systems are known that provide applications via information processing devices (user terminals) such as computers and smartphones. For example, in recent years, games that can be executed on user terminals such as smartphones and game terminals that can access servers via a network have been provided (see, for example, Patent Document 1).

In a game that can be executed on a user terminal, a virtual operation unit called a virtual stick is displayed on the game screen. There is something that the player (movable object) is controlled by.

Japanese Patent No. 5117466

In a game in which a virtual operation unit as described above is displayed on the game screen, the player is operated by a swipe motion in which the user touches the game screen. Action cannot be realized. therefore,
The player's actions are sometimes restricted to two-dimensional actions, leaving room for improvement in operability.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an information processing system, a program, and an information processing method that can improve convenience when operating a movable object in an application. It is.

To achieve the above object, the present invention provides an information processing system that provides an application that can be executed on an information processing terminal,
a detection unit that detects a three-dimensional motion of a user's finger;
a motion control unit that controls the three-dimensional motion of a movable object within the application based on the three-dimensional motion of the user's finger detected by the detection unit;
It is characterized by having

According to this, the movable object in the application is three-dimensionally controlled according to the three-dimensional motion of the user's finger detected by the detection unit. Therefore, since the user can intuitively operate the application, the convenience for the user when operating the application such as a game is improved.

According to the present invention, user convenience is improved when operating a movable object within an application.

1 is a block diagram illustrating the outline of the configuration of an information processing system according to an embodiment of the present invention; FIG. Similarly, it is a block diagram for explaining the outline of the configuration of the server of the information processing system according to the present embodiment. Similarly, it is a block diagram for explaining the outline of the configuration of the storage of the server of the information processing system according to the present embodiment. Similarly, it is a block diagram for explaining the outline of the configuration of game information processed by the information processing system according to the present embodiment. Similarly, it is a flowchart explaining the outline of the processing of the operation control unit of the information processing program of the information processing system according to the present embodiment. Similarly, it is a figure which shows an example of the game screen of the information processing system which concerns on this Embodiment. Similarly, it is a figure which shows an example of the game screen of the information processing system which concerns on this Embodiment. Similarly, it is a figure which shows an example of the game screen of the information processing system which concerns on this Embodiment. Similarly, it is a figure which shows an example of the game screen of the information processing system which concerns on this Embodiment. Similarly, it is a block diagram for explaining the outline of the configuration of the user terminal of the information processing system according to the present embodiment. Similarly, it is a flowchart explaining the outline of the processing of the information processing system according to the present embodiment.

Next, an information processing system according to an embodiment of the present invention will be described with reference to FIGS. 1 to 11. FIG.

FIG. 1 is a block diagram illustrating the outline of the configuration of an information processing system according to an embodiment of the present invention. As illustrated, for example, the information processing system 10 includes a server 20 and one or more user terminals 30 (information processing terminals), which are connected to a network 100 such as the Internet.
are accessiblely connected to each other via By providing the functions of the server 20 in the user terminal 30 , the information processing system 10 may be configured only by the user terminal 30 . Further, the information processing system 10 of this example is a system that provides applications in the game field, but is not limited to this, and can also be applied to systems that provide applications in various fields other than games. Fields other than games include, for example, an application for viewing the inside of real estate. It is possible to move a character three-dimensionally within a building within the application, control the three-dimensional movement of a virtual camera, and control the field of view (visual field) of the display image displayed on the screen in three dimensions. can.

In the present embodiment, the server 20 is deployed in the operator 1 (system administrator) who provides the application (game in this example) in the information processing system 10, and the user terminal 30 executes the application provided by the operator 1. It is held by the user 2 who uses it.

The games provided by the operator 1 in the information processing system 10 include, for example, fighting games, shooting games, puzzle games, action games, baseball games, soccer games, other sports games, quiz games, pinball games, card games, and rhythm games. , RP
G (role-playing game), location information game, board game, adventure game, casino game, simulation game, strategy game, racing game, or a combination of any of these may be used.

Next, a specific configuration of each part of the information processing system 10 of this embodiment will be described.
In the following description, the description of "game" can be replaced with "application".

The server 20 is a desktop or notebook computer (
information processing device).

FIG. 2 is a block diagram for explaining the outline of the configuration of the server 20. As shown in FIG. As illustrated, the server 20 includes a processor 21, a memory 22, a storage 23, a transmitter/receiver 24, and an input/output unit 2.
5 which are electrically connected to each other via a bus 26 .

The processor 21 is an arithmetic device that controls the operation of the server 20, controls transmission and reception of data between elements, and performs processes necessary for executing application programs.

This processor 21 is, for example, a CPU (Central Process
It is a switching unit), and executes each process by executing an application program stored in a storage 23 described later and developed in a memory 22 .

The memory 22 is a DRAM (Dynamic Random Access Memory
y) and other volatile storage devices, and flash memory and HDD (Ha
rd Disc Drive) or other non-volatile storage device.

This memory 22 is used as a work area for the processor 21, and is used as a BIOS (Basic Input/Output System) executed when the server 20 is started.
and various setting information and the like are stored.

The storage 23 stores programs and information used for various processes. The configuration of this storage 23 will be described later. In this example, the storage unit of the server 20 is
It is composed of a memory 22 and a storage 23, but is not limited to this.

The transmitter/receiver 24 connects the server 20 to the network 100 . This transmitting/receiving unit 24 is
Bluetooth (registered trademark) and BLE (Bluetooth Low Energy
) may be provided with a short-range communication interface.

The input/output unit 25 is an interface to which an input/output device such as a keyboard, mouse, or display is connected.

The bus 26 transmits, for example, address signals, data signals, and various control signals among the connected processor 21 , memory 22 , storage 23 , transmission/reception unit 24 and input/output unit 25 .

FIG. 3 is a block diagram for explaining the outline of the configuration of the storage 23. As shown in FIG. As illustrated, the storage 23 includes a database 40 and an information processing program 41 in this embodiment.

The database 40 is implemented as a storage area provided by the storage 23, and stores game information D1 as an example of application information in this embodiment.

FIG. 4 is a block diagram for explaining the outline of the configuration of the game information D1. As illustrated, the game information D1 includes game data d1a, event data d1b, player data d1c, and reward data d1d.

In this embodiment, the game data d1a includes characters and items that appear in the game,
It is composed of data related to game settings according to the type of game, such as a background image.

In the present embodiment, the characters that make up the game data d1a are the players who act in the game by the operation of the user 2 via the user terminal 30, the characters that become companions of the player, or the characters that fight against the player. etc. are included.

In the present embodiment, the event data d1b is composed of an arbitrary event in which a trial (for example, a battle with an enemy character, etc.) is set by the user 2 as a player. In-game rewards such as items used in , recovery of the player's energy, etc., which will be described later, may be given.

In the present embodiment, the player data d1c includes a player name, data relating to a character owned by the user 2 as a player, data relating to settings of the player's actions for the user 2,
It is composed of data related to items owned by the player of user 2, data related to play stages, and the like.

The data about owned characters includes, for example, the current values of various parameters such as level, attack power, defense power, and physical strength associated with the character's ID.

Data relating to the player's motion settings include, for example, arbitrary preset criteria that relate the three-dimensional motion vectors of the user's 2 fingers to the player's motion vectors.

In this embodiment, for example, if the finger of user 2 moves in the x direction, the player also moves in the x direction, and if the finger of user 2 moves in the y direction, the player also moves in the y direction. be The data regarding the setting of the player's motion may include, for example, information indicating the relationship between the direction of the motion vector of the finger and the direction of the motion vector of the movable object (player). In addition to the case where the direction of the motion vector of the finger and the direction of the motion vector of the movable object are matched, the case where the angle is corrected by predetermined arithmetic processing (for example, when the finger of user 2 moves in the x direction, If the player moves in the y-direction, and the user's finger moves in the y-direction, the player moves in the z-direction, etc.). The data regarding the setting of the player's motion may include, for example, information indicating the relationship between the magnitude of the motion vector of the finger and the magnitude of the motion vector of the movable object (player). For example, if the finger of user 2 moves 10 mm from the reference position, the movable object also moves 1 mm within the application.
It includes information on correspondence such as movement by 0 mm or movement by a distance multiplied by a predetermined magnification. Also, the three-dimensional motion of the finger of the user 2, the zoom-in motion of the screen in the application,
and a zoom-out operation may be associated.

Data related to owned items includes, for example, values such as the number of owned items associated with item IDs.

The data about the play stage is data about the stage that the user 2 has played so far as a player among the set stages, and includes, for example, the number of times played and the data when the stage is cleared. .

The reward data d1d is data relating to in-game rewards given to the player.

In the present embodiment, this in-game reward includes, for example, the execution of an arbitrary event executed in the game, an increase in the drop rate indicating the probability that the player obtains an arbitrary item, and the exchange of items in the game. In-game points that are consumed when recovering the player's energy, etc., or function execution commands, etc. be

The information processing program 41 shown in FIG. 3 includes a game processing section 41a, an operation control section 41b, and an interface generation section 41c in this embodiment.

In the present embodiment, the game processing unit 41a is a module that executes basic game processing such as game progress and character control. Executes processing, reward giving processing, or the like.

In the character training process, in the present embodiment, a character selected by the user 2 as a player increases the experience value and energy of the character based on any preset action such as being made to run or swim by the user 2. This is a process of improving the value and executing the training of the character.

In this embodiment, the event processing is processing for executing an event according to the action of the character selected by the user 2 as a player, and the function restriction processing includes restriction of functions executed in the game and cancellation of the restriction. , and the reward giving process is a process of giving an in-game reward to the player used by the user 2 .

The game processing unit 41a also executes various other basic processes of the game.

The motion control unit 41b shown in FIG. 3 is a module that controls the motion of the player in the game in this embodiment.

FIG. 5 is a flowchart for explaining the outline of the processing of the operation control section 41b. First, when the game is started after the game is started, a three-dimensional camera (depth camera) as a detection unit of the user terminal 30 detects the position of the finger of the user 2 as shown in the figure. In step S1, the motion control unit 41b sets the detected finger position of the user 2 as a reference position for controlling the motion of the player.

In the present embodiment, for example, when the user 2 holds his/her finger over an arbitrary part on the front side of the user terminal 30, the three-dimensional camera detects the position of the finger of the user 2 at that position, and detects the detected position. is set as the reference position. The timing of setting the reference position may be a preset timing such as initial setting when using the application for the first time, or may be set by the user such as when the user 2 selects the reference position setting icon displayed on the screen. The timing may be based on the operation of 2.

After setting the reference position, when the game is started, in step S2, the user terminal 3
Based on the detection signal generated according to the three-dimensional motion of the finger of the user 2 detected by the 3D camera 0 and transmitted from the user terminal 30, the mode of motion of the finger of the user 2 is determined. The three-dimensional motion of the finger of the user 2 detected by the three-dimensional camera means the three-dimensional position of the finger relative to the reference position, or the moving direction, moving distance, moving speed, acceleration, etc. of the finger.

In the present embodiment, for example, the user 2 moves his or her finger three-dimensionally in the vertical and horizontal directions of the user terminal 30, or the user 2 moves his or her finger three-dimensionally in the depth direction of the user terminal 30. The mode of the finger motion of the user 2, such as whether or not, is discriminated.

Once the mode of action of the user 2 is determined, the virtual three-dimensional action of the player in the game is controlled in step S3.

Also, the image displayed on the user terminal 30 may be the third-person viewpoint of the player as shown in FIGS. 6, 7, and 8, or may be the first-person viewpoint. The first person view is FPS (First Person Sh
ooter) and other 3D action shooting fields. Also, in this system,
The server 20 or the user terminal 30 may include a viewpoint switching unit that switches between the third-person viewpoint and the first-person viewpoint. Such viewpoint switching may be automatically switched on the server 20 or user terminal 30 side according to the progress of the game or scene, or may be switched according to a request from the user via the user terminal 30. can be In the case of the first-person viewpoint, the field of view of the display image displayed on the user terminal 30 changes according to the action of a movable object (character, virtual camera, etc.) within the application. Specifically, a virtual view from the character's viewpoint is displayed according to the direction in which the character is facing (line-of-sight direction). In the case of the third-person viewpoint, as shown in FIGS. 6, 7, and 8, an image of a character taken from a position separated by a predetermined distance is displayed on the screen. Note that the field of view of the image displayed on the user terminal may be directly controlled based on the three-dimensional movement of the finger. In other words, it is also possible to control the imaging range (field of view) of the virtual camera in the application (including zooming in and zooming out) based on the three-dimensional motion of the finger. In this case, the operation of a virtual camera that virtually captures the background image and movable objects within the application is controlled based on the three-dimensional motion of the finger, and the imaging range of the virtual camera is displayed on the user terminal. image.

In the present embodiment, a three-dimensional movement vector of the finger of the user 2 and a movement vector of the character C selected as the player by the user 2 are generated based on the data regarding the setting of the movement of the player included in the player data d1c. Associate (or match) to control actions.

FIG. 6 is a diagram for explaining the outline of the processing of the action control unit 41b when the view of the game screen is set so that the character C selected as the player by the user 2 is viewed from the front.

As shown in the figure, when it is determined that the motion of the finger of the user 2 is an upward movement on the screen indicated by the arrow V1 or a downward movement on the screen indicated by the arrow V2, the game screen IF is displayed.
A character C displayed in 1 is controlled to move upward as indicated by an arrow U or downward as indicated by an arrow D depending on how the user's finger moves.

Note that, in the present embodiment, the upward motion U is, for example, a jump motion when the character C is walking, a rising motion when the character C is flying, and a downward motion. The motion to D is, for example, a crouching motion when the character C is walking, and a descending motion when the character C is flying.

On the other hand, if it is determined that the motion of the finger of the user 2 is moving leftward on the screen indicated by the arrow V3 or moving rightward on the screen indicated by the arrow V4, the character displayed on the game screen IF1 C controls the motion such that it moves rightward as indicated by arrow R or leftward as indicated by arrow L according to the mode of motion of the finger of user 2 .

Furthermore, the user 2's finger movement is shown by an arrow V5 in the forward direction in the depth direction with respect to the game screen IF1 (for example, by moving the finger closer to the camera), or in the backward direction in the depth direction with respect to the game screen IF1 by the arrow V6. If it is determined that the action is to move (for example, to move the finger away from the camera), the character C displayed on the game screen IF1 moves in the forward direction indicated by the arrow F or Movement is controlled, such as movement in the backward direction indicated by arrow B.

FIG. 7 is a diagram for explaining the outline of the processing of the action control unit 41b when the view of the game screen IF1 is set to see the character C from the side.

As shown in the figure, when it is determined that the motion of user 2's finger is the motion of moving the finger in the upward direction V1 on the screen or the motion of moving the finger in the downward direction V2 on the screen, the character C displayed on the game screen IF1 The movement is controlled such that the finger moves upward U or downward D depending on the mode of movement of the finger.

Note that, in the present embodiment, the upward motion U is, for example, a jump motion when the character C is walking, a rising motion when the character C is flying, and a downward motion. The motion to D is, for example, a crouching motion when the character C is walking, and a descending motion when the character C is flying.

On the other hand, if the motion of the finger of the user 2 is moved in the screen left direction V3 or in the screen right direction V
4, the character C displayed on the game screen IF1 moves in the forward direction F or the backward direction B according to the mode of motion of the finger of the user 2, and controls the motion. do.

Furthermore, if the user 2's finger motion mode is determined to be a motion of moving forward in the depth direction V5 with respect to the game screen IF1 or a motion of moving backward in the depth direction V6 with respect to the game screen IF1, the character displayed on the game screen IF1 C controls movement such as moving leftward L or rightward R depending on the mode of finger movement of user 2 .

FIG. 8 is a diagram for explaining the outline of the processing of the action control unit 41b when the view of the game screen IF1 is set to see the character C from above.

As shown in the figure, when it is determined that the motion of user 2's finger is the motion of moving the finger in the upward direction V1 on the screen or the motion of moving the finger in the downward direction V2 on the screen, the character C displayed on the game screen IF1 The movement is controlled such that it moves in the backward direction B or the forward direction F depending on the mode of motion of the finger.

On the other hand, if the motion of the finger of the user 2 is moved in the screen left direction V3 or in the screen right direction V
4, the character C displayed on the game screen IF1 is controlled to move in the right direction R or left direction L according to the motion of the finger of the user 2. do.

Furthermore, if the user 2's finger motion mode is determined to be a motion of moving forward in the depth direction V5 with respect to the game screen IF1 or a motion of moving backward in the depth direction V6 with respect to the game screen IF1, the character displayed on the game screen IF1 C controls the motion such that it moves upward U or downward D depending on how the finger of the user 2 moves.

Note that, in the present embodiment, the upward motion U is, for example, a jump motion when the character C is walking, a rising motion when the character C is flying, and a downward motion. The motion to D is, for example, a crouching motion when the character C is walking, and a descending motion when the character C is flying.

The interface generation unit 41c shown in FIG. 3 is a module that generates a state display interface that indicates the three-dimensional motion state of the user's 2 finger.

FIG. 9 is a diagram illustrating an overview of the status display interface. As shown, the state display interface IF2 comprises a transparent (or translucent) virtual sphere S arranged in a virtual three-dimensional area consisting of x-, y-, and z-axes.

In the present embodiment, the direction of the three-dimensional action of the finger of the user 2, that is, the direction of the virtual three-dimensional action of the character selected as the player, the action line M from the center point O of the virtual sphere S is extended, and the motion area A is displayed on the spherical surface of the phantom sphere S where the motion line M and the phantom sphere S intersect.

This state display interface IF2 is displayed at an arbitrary portion on the game screen, such as the lower left corner of the game screen. The position of the status display interface IF2 may be changeable. In that case, for example, a button image or the like requesting a position change of the state display interface IF2 is displayed on the game screen, and the user 2 selects the position change request button, and taps an arbitrary position on the screen. By specifying the status display interface IF
2 can be changed.

As a result, the user 2 can simultaneously see the three-dimensional movement of his/her finger and the virtual three-dimensional movement of the character following it, thereby improving the convenience of operating the game.

A game is executed in the user terminal 30 according to the present embodiment based on the processing by the information processing program 41 including the game processing unit 41a, the operation control unit 41b, and the interface generation unit 41c.

In this embodiment, the user terminal 30 shown in FIG. 1 is implemented by a smart phone, which is a portable information terminal, but is implemented by, for example, a terminal dedicated to games, a tablet computer, a desktop computer, or a notebook computer. can be anything.

FIG. 10 is a block diagram for explaining the outline of the configuration of the user terminal 30. As shown in FIG. As shown,
The user terminal 30 includes a control unit 31, a display 32, and a three-dimensional camera 33 as a detection unit.
is provided as the main configuration. The detection unit is not limited to the three-dimensional camera 33, and may be various sensor devices capable of detecting three-dimensional movements of the finger. Alternatively, the server 20 or the user terminal 30 may be provided with an analysis unit that analyzes an image of a monocular camera provided in the user terminal 30 to estimate a three-dimensional motion, and may function as a detection unit.

In this embodiment, the control unit 31 controls each unit of the user terminal 30 such as the display 32 and the three-dimensional camera 33, and is composed of, for example, a processor, memory, storage, transmission/reception unit, and the like.

In this embodiment, the control unit 31 stores a game application or a browser capable of browsing a website, and based on the processing in the information processing program 41 of the server 20, the user terminal is controlled via the game application or the browser. At 30 the game is run.

In the present embodiment, the display 32 displays a screen interface of the game executed by the user terminal 30, including the game screen IF1 shown in FIGS.

The display 32 is a so-called touch panel that accepts information input by touching the display surface, and is implemented by various technologies such as a resistive film system and a capacitance system. In this example, the display 32 and the three-dimensional camera 33 constitute an input unit that receives an input operation from the user in the user terminal, but the present invention is not limited to this. The input unit may have a keyboard and a mouse, may have a microphone capable of input operation by voice, or may have an eye tracking device for acquiring line-of-sight information.
The display 32 also constitutes a display unit that outputs application images.

In the present embodiment, the three-dimensional camera 33 is an in-camera mounted on the front surface of the smartphone that is the user terminal 30, and is configured with various sensors such as a proximity sensor that detects the distance to an object, User action information D2 is detected.

The user action information D2 is information that is input regarding the player's operation or action, and is image information based on any action of the user 2 .

In the present embodiment, this user action information D2 is, for example, a three-dimensional motion of the user 2 moving his/her finger up, down, left, or right with respect to the user terminal 30, or a three-dimensional motion of the user 2 moving his or her finger to the depth of the user terminal 30. It is an operation to move in a direction (back and forth direction).

When the user action information D2 is detected by the three-dimensional camera 33 of the user terminal 30, the three-dimensional camera 33 generates a detection signal according to the mode of action of the user 2. FIG.

Next, an outline of processing of the information processing system 10 according to the present embodiment will be described.

FIG. 11 is a flowchart for explaining the outline of the processing of the information processing system 10 according to this embodiment. As shown, first, in step S10, user 2 starts the game.

After starting the game, at the start of the game, when the user 2 holds his/her finger over the three-dimensional camera 33 of the user terminal 30 and the three-dimensional camera 33 detects the position of the finger of the user 2, step S11 is performed.
, the position of the finger of the user 2 detected by the three-dimensional camera 33 is set as a reference position when controlling the action of the player. More specifically, detecting the position of the tip of any one finger,
It is preferable to set it as a reference position. Note that detection is not limited to fingertips, and specific joints or arbitrary parts of fingers may be detected.

After setting the reference position, the user 2 starts the game in step S12.

When the game is started, in step S13, the virtual three-dimensional motion of the character selected as the player by the user 2 is controlled based on the three-dimensional motion of the finger of the user 2. FIG.

In the present embodiment, for example, in response to a three-dimensional motion of the user 2 moving the finger in the vertical and horizontal directions of the game screen or a motion of the user 2 moving the finger in the three-dimensional direction of the game screen,
The character performs a virtual three-dimensional motion in the game at a vector corresponding (or coinciding with) the three-dimensional motion vector of the finger of the user 2 . The direction, distance, speed, and acceleration of the three-dimensional motion of the finger of the user 2 may not completely match the direction, distance, speed, and acceleration of the three-dimensional motion of the character in the game. , for example, performing a correction process based on a predetermined formula set in advance.

Thus, in this system, the three-dimensional motion of the movable object in the application is controlled based on the three-dimensional motion of the user's finger detected by the detection unit. This improves convenience for the user 2 when operating the application. Specifically, in this example, the character selected as the player by the user 2 is controlled to follow the three-dimensional motion of the user's finger detected by the user terminal 30, so that the user 2 can intuitively Since the game can be operated, the convenience for the user 2 when operating the game is improved.

The present invention is not limited to the above-described embodiments, and various modifications are possible without departing from the scope of the invention.

In the above embodiment, the view (display image) of the game screen is such that the character C selected by the user 2 as the player is viewed from the front from the third-person viewpoint, the character C is viewed from the side, and the character C is viewed from above. Although the setting for viewing the character C from above has been described, various settings such as a setting for viewing the character C from below or from behind may be used. Also, the view of the game screen may be a first-person viewpoint that shows the scenery seen from the character C's eyes.

In the above embodiment, after setting the reference position, when the finger of the user 2 is at the reference position, the action line M does not extend from the center point O of the virtual sphere S (the action area A is not displayed), and the center point It may be possible to display that the operation line M is positioned at O (for example, the display of the center point O becomes larger, brighter, or darker, etc.). Also, at that time, the character may be in a stopped state. Further, when the user 2 stops the finger at a position away from the reference position, the character continues to move in the direction of the position of the finger with respect to the reference position according to the position of the finger of the user 2 with respect to the reference position. good too. In this case, the state display interface IF2 continues to display the motion line M extending from the center point O of the virtual sphere S and the spherical motion area A according to the direction of the virtual three-dimensional motion of the character. may

In the above embodiment, the three-dimensional camera 33 mounted on the user terminal 30 detects the three-dimensional motion of the finger of the user 2 . may detect the three-dimensional motion of

Furthermore, the number of fingers of the user 2 detected by the user terminal 30 may be one, two, or any other number. It can be a finger. When two or more fingers are detected, the operation of opening and closing the two or more fingers,
A motion in which two or more fingers move in the same direction may be detected, and a movable object in the application may perform a motion associated with each motion. In that case,
A three-dimensional motion of the user's finger and a movable object in the application are associated and pre-stored in the storage unit. A user may also be able to associate three-dimensional movements of the user's fingers with movements of movable objects within the application. i.e.
Based on the user's instruction via the user terminal 30, the control unit of the server 20 associates an arbitrary three-dimensional motion of the user's finger with a specific motion of the movable object in the application, and stores it in the storage unit. You may make it For example, the server 20 causes the user terminal 30 to display a plurality of motions of a movable object in an application stored in advance in the storage unit,
Receiving an instruction to select a specific action from among them via the user terminal 30,
A three-dimensional motion of the user's finger to be associated with the motion is received based on an input operation via the user terminal 30 . As a result, it is possible to store any finger in association with a specific motion of the movable object and use it for three-dimensional manipulation of the movable object. In addition, three-dimensional movements of the user's fingers (e.g., gestures), predetermined operations within the application (e.g., menu display, operation of shortcuts, volume adjustment, etc., zoom adjustment (screen enlargement,
reduction) ON/OFF switching of various functions, etc.) may be stored in the storage unit in association with each other. The combination of the user's finger motion and the operation within the application may be set by the user, or may be set in advance by the system administrator. Also, the motion of the user's finger or hand detected by the user terminal may be tracked and used as a game controller. In this case as well, motions of the user's fingers and hands are stored in association with predetermined motions in the game. In a racing game, it is possible to move the steering wheel in the game by following the motion of the finger or hand. The game is not particularly limited, and may be, for example, a so-called video game or a VR game.

In addition, in this system, the detection unit may detect whether the finger is the finger of the right hand or the finger of the left hand. In that case, different actions can be set for the fingers of the right hand and the fingers of the left hand, increasing the variation in the manipulation of the movable object. In addition, it is possible to operate the movable object using one or more fingers on either the left or right hand or fingers on both hands.

The present invention has the following configurations.
(Item 1)
In an information processing system that provides an application that can be executed on an information processing terminal,
a detection unit that detects a three-dimensional motion of a user's finger;
a motion control unit that controls the three-dimensional motion of a movable object within the application based on the three-dimensional motion of the user's finger detected by the detection unit;
An information processing system comprising:
(Item 2)
The information processing system according to item 1, wherein the detection unit includes a three-dimensional camera.
(Item 3)
Item 1 or 2, wherein the motion control unit sets the position of the user's finger detected by the detection unit at a predetermined timing as a reference position when controlling the motion of the movable object. Information processing system as described.
(Item 4)
an interface generation unit that generates a state display interface indicating a three-dimensional position of the user's finger relative to the reference position;
The information processing system according to item 3, characterized by comprising:
(Item 5)
The operation control unit is
5. The information processing system according to any one of items 1 to 4, wherein a three-dimensional motion vector of the user's finger is associated with a motion vector of the movable object in the application.
(Item 6)
The operation control unit is
6. Any one of items 1 to 5, wherein the motion direction of the user's finger is associated with the motion direction of the movable object in the application in accordance with setting of the direction of the movable object displayed on the application screen. or the information processing system according to item 1.
(Item 7)
The operation control unit is
7. The information processing system according to any one of items 1 to 6, wherein the field of view of the display image within the application is controlled based on the three-dimensional movement of the movable object.
(Item 8)
In an information processing system that provides an application that can be executed on an information processing terminal,
a detection process for detecting a three-dimensional motion of a user's finger with a detection unit;
a motion control process for controlling the three-dimensional motion of a movable object within the application based on the three-dimensional motion of the user's finger;
A program characterized by causing a computer to execute
(Item 9)
In an information processing system that provides an application that can be executed on an information processing terminal,
a detection step of detecting a three-dimensional motion of a user's finger with a detection unit;
a motion control step of controlling the three-dimensional motion of a movable object within the application based on the three-dimensional motion of the user's finger;
An information processing method comprising:

1 business operator 2 user 10 information processing system 20 server 30 user terminal 33 detection sensor 40 database 41 information processing program (program)
41b operation control unit 41c interface generation unit D2 user operation information IF2 status display interface

Claims (7)

In an information processing system that provides an application that can be executed on an information processing terminal,
a detection unit that detects a three-dimensional motion of a user's hand;
a motion control unit that controls the three-dimensional motion of a movable object within the application based on the three-dimensional motion of a user's hand detected by the detection unit;
with
The motion control unit associates a specific three-dimensional motion of the user's hand with a specific motion of the movable object in the application and stores the information in the storage unit based on the user's instruction. system. The motion control unit controls, when the detection unit detects a predetermined three-dimensional motion of the user's hand, to perform the specific motion associated with the predetermined three-dimensional motion of the user's hand to the movable object. 2. The information processing system according to claim 1, wherein the execution of is controlled by. The detection unit is capable of detecting a three-dimensional motion of one or more fingers of the user,
The motion control unit controls, when the detection unit detects a predetermined three-dimensional motion of the user's finger, to perform the specific motion associated with the predetermined three-dimensional motion of the user's finger on the movable object. 2. The information processing system according to claim 1, wherein the execution of is controlled by. The detection unit is capable of detecting whether the user's hand is a right hand or a left hand,
4. The information processing system according to any one of claims 1 to 3, wherein the motion control unit controls the three-dimensional motion of the movable object based on whether the user's hand is right handed or left handed. The detection unit is capable of detecting motions of both hands of the user,
5. The information processing system according to claim 1, wherein the motion control unit controls the three-dimensional motion of the movable object based on motions of both hands of the user. In an information processing system that provides an application that can be executed on an information processing terminal,
A detection process for detecting a three-dimensional motion of a user's hand with a detection unit;
a motion control process for controlling the three-dimensional motion of a movable object within the application based on the three-dimensional motion of the user's hand;
a process of associating a specific three-dimensional motion of a user's hand with a specific motion of a movable object in an application and storing the same in a storage unit, based on the user's instruction;
A program characterized by causing a computer to execute In an information processing system that provides an application that can be executed on an information processing terminal,
a detection step of detecting a three-dimensional motion of a user's hand with a detection unit;
a motion control step of controlling the three-dimensional motion of a movable object within the application based on the three-dimensional motion of the user's hand;
a step of associating a specific three-dimensional motion of a user's hand with a specific motion of a movable object in an application and storing the associated motion in a storage unit, based on the user's instruction;
An information processing method comprising:

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