JP2008102789A - Controller, image processing system, information processor, information processing program, and storage medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a controller capable of moving an object in a virtual space with a sensation close to a real world. <P>SOLUTION: The controller 20 is provided with: a right gripping part 21; a left gripping part 22; a connection part 23; a linear sensor; and a CPU. The right gripping part 21 is gripped by the right hand of a player, and the left gripping part 22 is gripped by the left hand of the player. The connection part 23 connects the right gripping part 21 to the left gripping part 22 so that the relative positions of both of them can be changed. A linear sensor detects the change quantity of the relative positions of the right gripping part 21 and the left gripping part 22. An operation signal for instructing the movement of an operation target object in a virtual space formed by the device body according to the change quantity to be detected by the linear sensor is generated and transmitted to the device body under the control of the CPU. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an information processing apparatus such as a video game machine, a controller that communicates with the information processing apparatus, an image processing system, an information processing program, and a storage medium.

  As a controller for communicating with a video game machine, a controller having a plurality of operation buttons is known. A player using this controller can operate an object in an image displayed on the display screen by the video game machine by pressing an operation button.

  Further, in JP-A-8-17984, two gripping portions that can be gripped in the left and right hands are connected to bendable, the amount and direction of bending of both gripping portions are detected, and the detected amount of bending and A remote controller is disclosed in which an operation amount and an operation direction are determined depending on the direction. A player using this controller can operate an object in the image with a feeling different from that when using the operation buttons by bending the two gripping portions.

Japanese Patent Application Laid-Open No. 8-17984

  Here, in the case where an object representing a hand is moved in a virtual space displayed as an image, for example, if the player can move the object by operating the controller as if moving his / her hand, a sense close to the real world It becomes possible to operate the controller.

  However, in the above conventional controller, since the movement of the object is operated by pressing the operation button or bending the two gripping portions, it is difficult to operate the controller with a sense close to the real world.

  The present invention has been made in view of the above-described problems, and an object thereof is to provide a controller capable of moving an object in a virtual space with a sense close to the real world.

  The present invention is a controller that communicates with an information processing apparatus, and includes a first gripping unit, a second gripping unit, a coupling unit, a detection unit, a signal generation unit, and a transmission unit.

  In one embodiment of the present invention, the information processing apparatus forms a virtual space including a predetermined object. The first gripping part is gripped by one hand of the user. The second grip portion is gripped by the other hand of the user. A connection means connects the 1st holding part and the 2nd holding part so that both relative positions can be changed. The detection means detects the amount of change in the relative position between the first grip portion and the second grip portion. The signal generation unit generates a signal based on the change amount detected by the detection unit. The transmission unit transmits the signal generated by the signal generation unit to the information processing apparatus.

  The connecting means connects the first gripping part and the second gripping part so as to be movable along the main axis. The detecting means detects the amount of change in the distance along the main axis between the first grip portion and the second grip portion. The signal generation means generates a first operation signal when the detection means detects the distance change amount. The first operation signal instructs the movement of the predetermined object according to the detected change amount of the distance.

  According to the present invention, when moving an object in a virtual space, the controller can be operated with a sense close to the movement of a hand moving an object in the real world.

[Schematic configuration of entertainment system of this embodiment]
An entertainment system as an embodiment of the present invention is schematically shown in FIG.

  The entertainment system includes an entertainment device (hereinafter referred to as a device main body) 10 that is an example of an information processing device (video game machine), a controller 20 that is an operation terminal operated by a player (user), and a device main body 10. And a monitor device (for example, a television receiver) 100 to which video and audio signals are supplied. The monitor device 100 includes an image display unit (display screen) 101 that displays an image based on a video signal supplied from the device body 10.

  Information is transmitted and received between the apparatus main body 10 and the controller 20 by communication. The communication method between the two may be either wired communication via the cable 13 or wireless communication. The controller 20 of the present embodiment can perform both wired and wireless communication. When the controller 20 is connected to the apparatus body 10 by wired connection, wired communication is performed, and when the wired connection is released, wireless communication is performed. Communication is performed.

  In the example of FIG. 1, the apparatus main body 10 has a plurality of controller ports 11 (in this embodiment, four locations 11A, 11B, 11C, and 11D). When the controller 20 and the apparatus main body 10 are connected to each other by the cable 13, the plug connector 12 provided at one end of the cable 13 is connected to any one of the controller ports 11 of the apparatus main body 10 (in this example, 11A). The plug connector 14 provided at the other end is inserted and electrically connected to the connection port 15 of the controller 20. In addition, by using other controller ports 11 (11B, 11C, and 11D in this example), the apparatus main body 10 can be simultaneously connected to the plurality of controllers 20 by wire. The wired connection method between the apparatus main body 10 and the controller 20 only needs to be bi-directionally communicable. In this embodiment, a connection in the USB (Universal Serial Bus) format (hereinafter referred to as USB connection) is adopted. Yes.

  Further, the controller 20 is provided with a wireless communication unit (antenna) 17 that performs wireless transmission and reception of information with the wireless communication unit (antenna) 16 of the apparatus body 10. As a communication method between the two wireless communication units 16 and 17, a general-purpose short-distance high-speed wireless communication method such as Bluetooth (registered trademark) communication or a dedicated short-distance can be used as long as two-way wireless communication is possible. Any communication system such as a wireless communication system can be applied. In this embodiment, a Bluetooth wireless communication system (hereinafter referred to as BT communication) is adopted.

  Based on the video signal from the apparatus main body 10, the game player displays an image of the image display unit 101 in a state where an image including the three-dimensional virtual space and a predetermined object in the virtual space is displayed on the image display unit 101. When a predetermined operation is performed on the controller 20 in order to move the object while viewing the image, a signal is transmitted from the controller 20 to the apparatus main body 10. When the apparatus main body 10 receives a predetermined signal from the controller 20, the apparatus main body 10 generates a video signal corresponding to the signal from the controller 20 and outputs it to the monitor device 100, and the image display unit 101 responds to the operation of the player. A predetermined object that moves in the virtual space (hereinafter, referred to as an operation target object 120) is displayed.

  In this embodiment, the virtual space formed by the apparatus main body 10 is a three-dimensional space defined by an X axis (horizontal direction), a Y axis (vertical direction), and a Z axis (depth direction) that are orthogonal to each other. Further, the operation target object 120 in the virtual space moves along each of the X-axis direction, the Y-axis direction, and the Z-axis direction in accordance with a signal from the controller 20 (in the following description, translation X and translation Y respectively. And a rotation Z (referred to as rotation X, rotation Y, and rotation Z in the following description), respectively, about the axes parallel to the X, Y, and Z axes.

  A signal transmitted from one controller 20 to the apparatus main body 10 includes at least six kinds of different information (operation signals) such as translation X, translation Y, translation Z, rotation X, rotation Y, and rotation Z. On the side, at least six receiving ports (port numbers 1 to 6) are set for one controller 20. In the present embodiment, as shown in FIG. 11, the translation Z information is port number 1, the translation Y information is port number 2, the rotation Y information is port number 3, and the rotation Z information is port number 4. However, information about translation X is assigned to port number 5, and information about rotation X is assigned to port number 6, respectively.

[Appearance of device body]
In the apparatus main body 10, in addition to the controller port 11 (11A to 11D) and the wireless communication unit 16, a memory card slot and a disk in which a memory card containing a semiconductor memory element or the like is detachable are not shown. Open / close button to open or close tray, disc tray, power on / standby, reset / on / standby / reset button, audio / video output terminal (AV multi-output terminal), PC card slot, optical digital output A terminal, an IEEE (Institute of Electrical and Electronics Engineers) 1394 connection terminal, a power switch, an AC power input terminal, and the like are provided.

  The apparatus body 10 executes a video game based on an application program for a video game recorded on a disk medium such as a so-called DVD-ROM or CD-ROM, or is recorded on a DVD video or a CD, for example. Video data and audio data can be reproduced (decoded).

  The application program, video, and audio data are not limited to disk media, but may be those read from a semiconductor memory or tape medium, or supplied via a wired or wireless wide-area or intra-area communication line.

[Internal circuit configuration of the device body]
FIG. 2 shows a main internal configuration of the apparatus main body 10.

  As shown in FIG. 2, the apparatus main body 10 includes a main bus 61 and a sub bus 62, and these buses 61 and 62 are connected to or disconnected from each other via a bus interface 63.

  The main bus 61 includes a main CPU 64, a main memory 65 including a RAM, a main DMAC (Direct Memory Access Controller) 66, and an image processing device (GPU (Graphic Processing Unit)) 68 including a frame memory 67. Connected. The GPU 68 is connected with a CRTC (CRT controller) 69 which is a control means for generating a video output signal. By the video output signal, an image is displayed on a predetermined display device (in this embodiment, the image display unit 101 of the monitor device 100) connected to the device body 10 by a cable or the like.

  The main CPU 64 reads a startup program from the ROM 70 on the sub-bus 62 via the bus interface 63 when the apparatus main body 10 is started up, and executes the startup program to operate the operating system. Further, the media drive 71 is controlled, and application programs and data are read from the media 72 loaded in the media drive 71 and stored in the main memory 65. Furthermore, geometry processing is performed on various data read from the medium 72, for example, three-dimensional object data (coordinate values of vertexes (representative points) of polygons) composed of a plurality of basic figures (polygons). A display list containing polygon definition information as a content is generated by geometry processing. Further, the compressed data is decompressed by the MPEG (Moving Picture Experts Group) method or the JPEG (Joint Photographic Experts Group) method. That is, the main CPU 64 has an information decoding function for decoding information by software.

  The polygon definition information includes drawing area setting information and polygon information. The drawing area setting information includes offset coordinates in the frame buffer address of the drawing area and coordinates of a drawing clipping area for canceling drawing when there are polygon coordinates outside the drawing area. The polygon information is composed of polygon attribute information and vertex information. The polygon attribute information is information for designating a shading mode, an α blending mode, a texture mapping mode, and the like. The vertex information is the coordinates in the vertex drawing area, the vertex texture. This is information such as in-region coordinates and vertex colors.

  The GPU 68 holds a drawing context, reads the corresponding drawing context based on the identification information of the image context included in the display list notified from the main CPU 64, performs a rendering process using the drawing context, and stores it in the frame memory 67. Draw a polygon. Since the frame memory 67 can also be used as a texture memory, the pixel image on the frame memory 67 can be pasted on a polygon to be drawn as a texture.

  When the USB communication module 78 or the BT communication module 79 receives a signal from the controller 20, the main CPU 64 generates a display list based on the received signal and outputs the display list to the GPU 68.

  The main DMAC 66 performs DMA transfer control for each circuit connected to the main bus 61 and performs DMA transfer control for each circuit connected to the sub-bus 62 according to the state of the bus interface 63. .

  The sub bus 62 reads out the sound data stored in the sound memory 76, the sub CPU 73 composed of a microprocessor, the sub memory 74 composed of RAM, the sub DMAC 75, the ROM 70 in which programs such as the operating system are stored. An audio processing device (SPU (Sound Processing Unit)) 77 that outputs as audio output, a USB communication module 78 that transmits and receives wired information to and from the controller 20 via a USB connection cable, and a controller 20 that via BT communication. A BT communication module 79 that transmits and receives information wirelessly, a media drive 71 for mounting a predetermined medium 72, and a keyboard 80 are connected. The medium 72 is a recording medium such as a CD-ROM or DVD-ROM in which an image processing program is recorded. The apparatus main body 10 executes a required entertainment process by reading and executing the image processing program. The USB communication module 78 includes the controller port 11 (shown in FIG. 1), and the BT communication module 79 includes the wireless communication unit 16 (shown in FIG. 1).

  The sub CPU 73 performs various operations in accordance with programs stored in the ROM 70. The sub DMAC 75 controls DMA transfer and the like for each circuit connected to the sub bus 62 only when the bus interface 63 separates the main bus 61 and the sub bus 62.

[Controller structure]
The structure of the controller 20 will be described with reference to FIGS. 3 is an external perspective view of the controller 20, FIG. 4 is a front view of the controller 20 viewed from the direction of arrow IV in FIG. 3, FIG. 5 is a plan view of the controller 20 viewed from the direction of arrow V in FIG. FIG. 7 is a perspective view schematically showing the internal structure of the controller 20, and FIG. 8 shows the arrangement of the coil springs 52 to 55 in the controller 20. It is a schematic diagram.

  As shown in FIGS. 3 to 6, the controller 20 includes a right grip 21 that is gripped by the player's right hand, a left grip 22 that is gripped by the player's left hand, a right grip 21, and a left grip 22. Are connected to each other, and a central case body 24 is provided. The connection port 15 for USB connection with the apparatus main body 10 and the wireless communication unit 17 for BT communication with the apparatus main body 10 are provided in the central case body 24. 3 to 6, the illustration is omitted.

  The right grip 21 includes a hollow right case body 25 having a long cylindrical shape that can be easily gripped by the right hand, and a base body 27 (see FIG. 7) that is provided inside the right case body 25 and is fixed to the right case body 25. Show). Similarly, the left gripping portion 22 also has a hollow left case body 26 having a long cylindrical shape that can be easily gripped by the left hand, and a base body 28 that is provided inside the left case body 26 and is fixed to the left case body 26 ( As shown in FIG.

  In the following description, in the left-right direction, the up-down direction, and the front-rear direction, the controller with the right grip portion 21 (right case body 25) and the left grip portion 22 (left case body 26) standing in a substantially vertical direction. Left and right direction (direction parallel to the x axis in the figure), vertical direction (direction parallel to the y1 axis and y2 axis in the figure), and front-back direction (parallel to the z1 axis and z2 axis in the figure) for the player holding the 20 with both hands Mean direction). In this embodiment, the x axis is the main axis, the y1 axis is the first rotation axis, the z1 axis is the second rotation axis, the y2 axis is the third rotation axis, and the z2 axis is the fourth rotation. Each corresponds to an axis.

  The right grip 21 is pressed by the first operation button 31 pressed by the player's right thumb, the second operation button 32 pressed by the right index finger, and the middle finger, ring finger, or little finger of the right hand. The third operation button 33 is provided. The first operation button 31 is disposed on the upper surface on the one surface side of the right case body 25 where the right case body 25 is easily operated by the thumb of the right hand while the player holds the right case body 25. The first operation button 31 is disposed on the upper surface on the one surface side of the right case body 25, and the second and third operation buttons 32 and 33 are the upper surface on the other surface side of the right case body 25 and the center of the surface. And are arranged respectively. That is, the first operation button 31 is located at a place where it can be easily operated by the thumb of the right hand holding the right case body 25, and the second operation button 32 is operated by the index finger of the right hand holding the right case body 25. The third operation button 33 is located at a place where it can be easily operated by the middle finger, ring finger, or little finger of the right hand holding the right case body 25. These first to third operation buttons 31, 32, 33 are assigned different functions depending on the game application, such as setting and execution of the function of the game character. Instead of the third operation button 33, an operation button for the middle finger and an operation button for the ring finger and the little finger may be provided. Further, instead of or in addition to the right grip 21, an operation button operated by each finger of the left hand may be provided on the left grip 22 as well as the right grip 21.

  As shown in FIG. 7, the connecting portion 23 includes a right connecting mechanism (first connecting mechanism) 34 supported by the base body 27 inside the right case body 25 (shown in FIG. 3), and a left case body 26 ( The left coupling mechanism (second coupling mechanism) 35 supported by the base body 28 in the interior of the interior shown in FIG. 3, and the central coupling mechanism (main coupling mechanism) 36 that couples the right coupling mechanism 34 and the left coupling mechanism 35. With.

  The right connecting mechanism 34 includes an upper rotating shaft 37, a lower rotating shaft 38, a central rotating shaft 39, a front rotating shaft 40, a rear rotating shaft 41, an upper and lower connecting body 42, and a front and rear connecting body 43.

  The upper rotary shaft 37, the lower rotary shaft 38, and the central rotary shaft 39 are arranged vertically on the same axis as the y1 axis that extends in the longitudinal direction of the right case body 25 (shown in FIG. 3) and passes through the approximate center of the right case body 25. Are arranged side by side. An upper end portion of the upper rotation shaft 37 and a lower end portion of the lower rotation shaft 38 are rotatably supported by the base body 27. The lower end portion of the upper rotating shaft 37 is fixed to the upper portion of the upper and lower connecting body 42, and the upper end portion of the lower rotating shaft 38 is fixed to the lower portion of the upper and lower connecting body 42. The upper end and the lower end of the central rotating shaft 39 are rotatably supported by the upper part and the lower part of the front-rear connecting body 43, respectively. The front rotary shaft 40 and the rear rotary shaft 41 extend in the front-rear direction of the right case body 25 (shown in FIG. 3), pass through the approximate center of the right case body 25, and are coaxial with the z1 axis orthogonal to the y1 axis. It is arranged side by side. The front end portion of the front rotating shaft 40 and the rear end portion of the rear rotating shaft 41 are rotatably supported by the base body 27. The rear end portion of the front rotating shaft 40 is fixed to the front portion of the front / rear connecting body 43, and the front end portion of the rear rotating shaft 41 is fixed to the rear portion of the front / rear connecting body 43. The right end of the first connecting shaft 44 extending in the left direction intersecting with the y1 axis and the z1 axis is fixed substantially at the center in the vertical direction of the central rotating shaft 39. The left end portion of the first connecting shaft 44 is the right case body 25. Protruding from. A first connecting shaft 44 is inserted into the upper and lower connecting body 42 and has an elongated hole shape in the vertical direction allowing rotation of the first connecting shaft 44 around the z1 axis (the front rotating shaft 40 and the rear rotating shaft 41). A shaft insertion portion 45 is provided. The first connecting shaft 44 is inserted into the front / rear connecting body 43 and has an elongated hole shape in the front / rear direction allowing rotation of the first connecting shaft 44 around the y1 axis (upper rotating shaft 37 and lower rotating shaft 38). A shaft insertion portion 46 is provided.

  Since the right coupling mechanism 34 has the above-described structure, when the base body 27 (right gripping portion 21) is rotated around the y1 axis with the first coupling shaft 44 fixed, the base body 27 has the upper rotation shaft 37 and the lower It rotates with respect to the rotating shaft 38. The shaft insertion portion 46 of the front / rear connecting body 43 allows rotation of the front / rear connecting body 43 (the front rotating shaft 40 and the rear rotating shaft 41) around the y1 axis accompanying this rotation. Similarly, when the base body 27 (right gripping portion 21) is rotated around the z1 axis with the first connecting shaft 44 fixed, the base body 27 rotates with respect to the front rotation shaft 40 and the rear rotation shaft 41. . The shaft insertion part 45 of the upper and lower coupling body 42 allows the rotation of the upper and lower coupling body 42 (upper rotation shaft 37 and lower rotation shaft 38) around the z1 axis accompanying this rotation.

  In addition, since the right coupling mechanism 34 has the above-described structure, the y1 axis and the z1 axis are always maintained in an orthogonal state. On the other hand, the state of the first connecting shaft 44 and the y1 axis is changed by rotating the base body 27 around the z1 axis with respect to the first connecting shaft 44. Similarly, the state of the first connecting shaft 44 and the z1 axis is changed by rotating the base body 27 around the y1 axis with respect to the first connecting shaft 44. As will be described later, in the right case body 25, a coil spring 54 (which biases the base body 27 so that the first connecting shaft 44 is positioned coaxially with the x axis orthogonal to both the y1 axis and the z1 axis). As shown in FIG.

  The left coupling mechanism 35 has substantially the same configuration as that of the right coupling mechanism 34 except that the corresponding components are arranged symmetrically with the right coupling mechanism 34. Is omitted. The configurations corresponding to the first connecting shaft 44, the y1 axis, and the z1 axis are referred to as the second connecting shaft 47, the y2 axis, and the z2 axis, respectively, and are distinguished from the right connecting mechanism 34.

  The central coupling mechanism 36 includes the first coupling shaft 44, the second coupling shaft 47, and the central base body 48.

  The central base body 48 is disposed inside the central case body 24 (shown in FIG. 3) and supports the central case body 24. The central base body 48 includes a base portion 49 extending in the left-right direction, a right support portion 50 extending from the right end portion of the base portion 49, and a left support portion 51 extending from the left end portion of the base portion 49. In the present embodiment, the left support portion 51 is configured by two opposing plates. The right support portion 50 rotatably supports the left end portion of the first connecting shaft 44. The left support portion 51 supports the right end side of the second connecting shaft 47 so as to be slidable in the left-right direction. The first connecting shaft 44 and the second connecting shaft 47 are positioned on the same axis (x axis) while being supported by the right support portion 50 and the left support portion 51.

  As shown in FIG. 8, a plurality of first coil springs 52 (biasing members) for biasing the rotational position of the first connecting shaft 44 with respect to the right support portion 50 to a predetermined initial position are provided inside the central case body 24. Means) and a plurality of second coil springs 53 (urging means) for urging the sliding position of the second connecting shaft 47 with respect to the left support portion 51 to a predetermined position. One end of the first coil spring 52 is fixed to the central base body 48, and the other end is fixed to the first connecting shaft 44. One end of the second coil spring 53 is fixed to the central base body 48, and the other end is fixed to the second connecting shaft 47. In an initial state in which no external rotational force is applied to the first connecting shaft 44 due to the biasing force from the first coil spring 52, the first connecting shaft 44 is set to a predetermined initial position with respect to the right support portion 50. Set to Further, in an initial state in which no external sliding force is applied to the second connecting shaft 47 due to the biasing force from the second coil spring 53, the second connecting shaft 47 is predetermined with respect to the right support portion 50. Set to the initial position.

  Inside the right case body 25 and the left case body 26, the rotational positions of the upper rotating shaft 37 and the lower rotating shaft 38 with respect to the base bodies 27 and 28, and the front rotating shaft 40 and the rear rotating shaft 41 with respect to the base bodies 27 and 28. A plurality of third and fourth coil springs 54 and 55 (urging means) for urging the rotational position to a predetermined initial position are provided. One end of the third coil spring 54 is fixed to the base body 27, and the other end is fixed to the first connecting shaft 44. One end of the fourth coil spring 55 is fixed to the base body 28, and the other end is fixed to the second connecting shaft 47.

  In the initial state in which no external force is applied to the right gripping part 21 and the left gripping part 22 due to the biasing force from these coil springs 52, 53, 54, 55, the right gripping part 21 and the left gripping part 22 are set to the initial positions. Is done. In such an initial position, the x axis, the y1 axis, and the z1 axis are orthogonal to each other, the x axis, the y2 axis, and the z2 axis are orthogonal to each other, the y1 axis and the y2 axis are parallel, and the z1 axis and the z2 axis are Become parallel.

  As shown in FIG. 4, the central coupling mechanism 36 is provided with two guide shafts 56 that are arranged in parallel with the second coupling shaft 47 and guide the sliding movement of the second coupling shaft 47.

  As shown in FIG. 7, a linear sensor 91 (distance change amount detecting means) that is fixed to the central base body 48 and detects the position of the second connecting shaft 47 is provided inside the central case body 24 (shown in FIG. 3). And a first rotation angle sensor 92 (fifth angle change amount detection means) for detecting the rotation angle of the first connecting shaft 44 is provided. Further, in the right case body 25, a second rotation angle sensor 93 (first angle change amount detecting means) for detecting the rotation angle of the lower rotation shaft 38 (upper rotation shaft 37) and the front rotation shaft 40 are provided. A third rotation angle sensor 94 (second angle change amount detection means) for detecting the rotation angle of the (rear rotation shaft 41) is provided. Similarly, in the left case body 26, a fourth rotation angle sensor 95 (third angle change amount detecting means) for detecting the rotation angle of the lower rotation shaft 38 (upper rotation shaft 37), and a front rotation shaft A fifth rotation angle sensor 96 (fourth angle change amount detection means) for detecting the rotation angle of 40 (rear rotation shaft 41) is provided. The linear sensor 91 is configured by a linear potentiometer or the like, and each rotation angle sensor 92 to 96 is configured by a potentiometer or an encoder.

  The fluctuation amount of the detection value from the linear sensor 91 corresponds to the change amount of the distance along the x axis between the right grip portion 21 and the left grip portion 22. The amount of change in the detection value from the first rotation angle sensor 92 corresponds to the amount of change in the angle about the x axis between the right grip 21 and the left grip 22. The amount of change in the detection value from the second rotation angle sensor 93 corresponds to the amount of change in the angle about the y1 axis between the right grip 21 and the central coupling mechanism 36. The amount of change in the detected value from the third rotation angle sensor 94 corresponds to the amount of change in the angle about the z1 axis between the right grip 21 and the central coupling mechanism 36. The amount of change in the detected value from the fourth rotation angle sensor 95 corresponds to the amount of change in the angle about the y2 axis between the left grip 22 and the central coupling mechanism 36. The amount of change in the detection value from the fifth rotation angle sensor 96 corresponds to the amount of change in the angle about the z2 axis between the left grip 22 and the central coupling mechanism 36. In this embodiment, since the detection value from each of the sensors 91 to 96 when the controller 20 is set to the initial position is set to zero, the detection including the positive and negative signs from each of the sensors 91 to 96 is performed. The value becomes each variation amount from the initial position as it is.

  Further, the central coupling mechanism 36 is provided with a load applier 97 that applies a sliding resistance (load) to the second coupling shaft 47 and varies the external force required for the sliding movement of the second coupling shaft 47. Such a load applier 97 may be provided as appropriate for the first connecting shaft 44, the upper rotating shaft 37, the lower rotating shaft 38, the front rotating shaft 40, or the rear rotating shaft 41.

  Further, as shown in FIG. 3, the central case body 24 is provided with a power button 57, a HOME button 58, an LED (display unit) 59, and a mode switch 60. Each time the power button 57 is pressed, the power ON / OFF state of the controller 20 is switched. The HOME button 58 is assigned for input when starting communication with the apparatus main body 10 and for input for starting the apparatus main body 10 to display the menu screen on the image display unit 101. The mode changeover switch 60 is assigned for switching between a mode in which the controller 20 functions as a right-handed person (hereinafter referred to as a right mode) and a mode in which the controller 20 functions as a left-handed person (hereinafter referred to as a left mode). Yes. Setting the knob 60a of the mode switch 60 to the right side sets the controller 20 to the right mode, and setting the knob 60a to the left side sets the controller 20 to the left mode. Note that the power button 57, the HOME button 58, and the mode switch 60 may not be provided separately, and the above functions may be assigned to the first to third operation buttons 31 to 33.

[Electrical configuration of controller]
Next, FIG. 9 shows a main electrical configuration of the controller 20.

  As shown in FIG. 9, the controller 20 includes a CPU 81, a ROM 82, a RAM 84, a battery 83, an operation input unit 85, an LED 59, an operation sensor 86, an acceleration sensor 87, a load applicator 97, and a USB. A communication module 88 and a BT communication module 89 are included, and these are connected via a bus 90. The operation input unit 85 is a general term for the first to third operation buttons 31 to 33, the power button 57, the HOME button 58, and the mode switch 60. The operation sensor 86 is a general term for the linear sensor 91 and the first to fifth rotation angle sensors 92 to 96.

  The CPU 81 executes predetermined processes such as an activation process, an operation signal generation process, an instruction signal generation process, a signal output process, a load control process, and a display control process.

  In the activation process, when the controller 20 is activated, the activation program is read from the ROM 82 and the activation program is executed. In the operation signal generation process, an operation signal corresponding to the detection value from the operation sensor 86 is generated. In the instruction signal generation process, an instruction signal set in advance according to an operation input from the player to the operation input unit 85 is generated. In the signal output process, the signal generated by the operation signal generation process or the instruction signal generation process is transmitted from the USB communication module 88 or the BT communication module 89 to the apparatus body 10. In the load control process, the load applied by the load applier 97 to the second connecting shaft 47 is controlled according to the load information received from the apparatus main body 10 by the USB communication module 88 or the BT communication module 89. Details of the operation signal generation process and the load control process will be described later.

  In the display control process, the LED 59 is controlled to a predetermined light emission state. This display control process includes a mode display control process. In the mode display control process, the light emission state (for example, light emission color) of the LED 59 is changed depending on whether the controller 20 is set to the right mode or the left mode. The player can recognize the mode in which the controller 20 is set by looking at the light emission state of the LED 59 and can switch the mode by operating the mode switch 60 as necessary.

  The USB communication module 88 transmits / receives information to / from the apparatus main body 10 via a USB connection cable, and the BT communication module 89 transmits / receives information to / from the apparatus main body 10 via BT communication. I do. The USB communication module 88 includes the connection port 15 (shown in FIG. 1), and the BT communication module 89 includes the wireless communication unit 17 (shown in FIG. 1).

  The USB cable 13 (shown in FIG. 1) for connecting the controller 20 and the apparatus main body 10 includes a power supply line. In the USB connection state, the apparatus main body 10 supplies power to the controller 20 via the power supply line. And the battery 83 is charged.

  The acceleration sensor 87 is disposed on the x-axis of the controller 20 and detects gravitational acceleration. The CPU 81 uses the detection value of the acceleration sensor 87 to calculate the tilt angle of the y axis with respect to the vertical direction around the x axis (the tilt angle around the x axis of the controller 20).

[Description of operation signal generation processing]
FIG. 10 is a schematic diagram showing the relationship between the right grip 21, the left grip 22, and the operation sensor 86 (each sensor 91, 92, 93, 94, 95, 96), and FIG. 11 shows the right mode and the left mode. It is a figure which shows the role (function) of each sensor 91, 92, 93, 94, 95, 96 at the time.

  This operation signal generation process includes a process (mode setting process) in which the controller 20 is selectively switched between the right mode and the left mode in accordance with an input from the player. In the following description, the signal generation process in the right mode will be described first, and the left mode will be described later. The controller 20 may be provided with a mode other than the right mode and the left mode. In the mode setting process in this case, one mode among a plurality of modes including the right mode and the left mode is alternatively set according to the input from the player.

(Basic explanation of signal generation processing in right mode)
As shown in FIG. 10, the linear sensor 91 detects a relative position along the x axis between the right grip portion 21 and the left grip portion 22. The first rotation angle sensor 92 detects an angle about the x axis between the right grip 21 and the left grip 22. The second rotation angle sensor 93 detects an angle about the y1 axis between the right grip 21 and the central coupling mechanism 36. The third rotation angle sensor 94 detects an angle around the z1 axis between the right grip 21 and the central coupling mechanism 36. The fourth rotation angle sensor 95 detects an angle around the y2 axis between the left grip 22 and the central coupling mechanism 36. The fifth rotation angle sensor 96 detects an angle around the z2 axis between the left grip 22 and the central coupling mechanism 36. In the present embodiment, since the detection values from the sensors 91 to 96 in the state where the controller 20 is set to the initial position are set to zero, the detection values from the sensors 91 to 96 are directly used as the initial positions. It becomes each fluctuation amount from.

  As shown in the upper column of FIGS. 10 and 11, in the right mode, the fourth rotation angle sensor 95 that detects the rotation amount around the y2 axis is assigned to the translation Z, and the CPU 81 uses the fourth rotation angle sensor. An operation signal corresponding to the detected value of 95 is generated, and the generated operation signal is output to port number 1 of the apparatus main body 10 (shown in FIG. 1). When the detection value from the fourth rotation angle sensor 95 fluctuates in the positive direction, the apparatus main body 10 operates on the operation target displayed on the image display unit 101 (shown in FIG. 1) of the monitor device 100 (shown in FIG. 1). When the object 120 (shown in FIG. 1) is moved and displayed in the positive direction along the Z axis, and is moved in the negative direction, the object 120 is moved and displayed along the Z axis in the negative direction.

  The fifth rotation angle sensor 96 that detects the amount of rotation around the z2 axis is assigned to translation Y, and the CPU 81 generates an operation signal corresponding to the detection value of the fifth rotation angle sensor 96, and the generated operation signal Is output to the port number 2 of the apparatus main body 10. When the detection value from the fifth rotation angle sensor 96 fluctuates in the positive direction, the apparatus main body 10 moves the operation target object 120 displayed on the image display unit 101 of the monitor apparatus 100 in the positive direction along the Y axis. If it is moved and displayed, and moved in the negative direction, it is moved and displayed along the Y axis in the negative direction.

  The second rotation angle sensor 93 that detects the rotation amount around the y1 axis is assigned to the rotation Y, and the CPU 81 generates an operation signal corresponding to the detection value of the second rotation angle sensor 93, and the generated operation signal Is output to port number 3 of the apparatus body 10. When the detection value from the second rotation angle sensor 93 fluctuates in the positive direction, the apparatus body 10 rotates and displays the operation target object 120 displayed on the image display unit 101 of the monitor apparatus 100 in the positive direction around the Y axis. On the other hand, if it fluctuates in the negative direction, the image is rotated and displayed in the negative direction around the Y axis.

  The third rotation angle sensor 94 that detects the rotation amount around the z1 axis is assigned to the rotation Z, and the CPU 81 generates an operation signal corresponding to the detection value of the third rotation angle sensor 94, and the generated operation signal Is output to port number 4 of the apparatus main body 10. When the detection value from the third rotation angle sensor 94 fluctuates in the positive direction, the apparatus main body 10 displays the operation target object 120 displayed on the image display unit 101 of the monitor device 100 in the positive direction around the Z axis. On the other hand, when it fluctuates in the negative direction, the display is rotated in the negative direction around the Z axis.

  The linear sensor 91 that detects the amount of movement along the x-axis is assigned to the translation X, and the CPU 81 generates an operation signal corresponding to the detection value of the linear sensor 91, and the generated operation signal is used as the port number of the apparatus main body 10. 5 is output. When the detection value from the linear sensor 91 fluctuates in the positive direction, the apparatus body 10 moves and displays the operation target object 120 displayed on the image display unit 101 of the monitor apparatus 100 in the positive direction along the X axis. On the other hand, if it fluctuates in the negative direction, it moves and displays in the negative direction along the X axis.

  The first rotation angle sensor 92 that detects the rotation amount around the x-axis is assigned to the rotation X, and the CPU 81 generates an operation signal corresponding to the detection value of the first rotation angle sensor 91, and the generated operation signal Is output to the port number 6 of the apparatus main body 10. When the detection value from the first rotation angle sensor 92 fluctuates in the positive direction, the apparatus body 10 rotates and displays the operation target object 120 displayed on the image display unit 101 of the monitor device 100 in the positive direction around the X axis. On the other hand, when it fluctuates in the negative direction, it is rotated and displayed in the negative direction around the X axis.

  The positive direction of the detection values of the linear sensor 91 and the rotation sensors 92 to 96 is set in advance so that the operation target object 120 moves or rotates in accordance with the moving direction of the player's right hand in the right mode.

(Relationship between controller operation in right mode and movement of operation target object)
Next, the relationship between the operation of the controller 20 by the player and the movement of the operation target object 120 will be described with reference to FIGS. In FIG. 13 to FIG. 24, the signs of A, B, and C are added after the right grip 21 and the operation target object 120, respectively, so that the position of the right grip 21 and the display position of the operation target object 120 are associated. Expresses the relationship. Further, in the present embodiment, a game program in which the detection values of the sensors 91 to 96 are associated with the coordinate positions and rotation angles of the respective axes (X axis, Y axis, Z axis) in the virtual space is stored in the apparatus body 10. Exemplifies the movement of the operation target object 120 when executing the above. Note that the movement of the operation target object 120 varies depending on the program executed by the apparatus main body 10. For example, the sign of the detection value of each sensor 91 to 96 is associated with the movement direction along each axis in the virtual space and the rotation direction around each axis, and the absolute value of the detection value is the movement speed or rotation speed. When the apparatus main body 10 executes the program associated with “”, the operation target object 120 exhibits a movement different from that of the present embodiment.

  As shown in FIG. 12, the player who operates the controller 20 grips the right grip 21 with the right hand 130R and grips the left grip 22 with the left hand 130L. At the start of the operation, the right grip 21 and the left grip 22 are raised so that the x axis, the z1 axis, and the z2 axis are set substantially horizontal and the y1 axis and the y2 axis are set substantially vertical, respectively. The player holds the controller 20. By being gripped by the player in this way, the controller 20 enters the basic operation state.

  When the right-handed player moves the operation target object 120, the controller 20 is set to the right mode, and the right hand 130R is moved to move the right grip 21 while the left hand 130L is fixed so that the left grip 22 does not move. Move or rotate.

  When the operation target object 120 is translated in the X direction in the virtual space, as shown in FIGS. 13 and 14, the player holds the left grip 22 (left hand 130L) fixed and moves the right arm as a whole in the horizontal direction. The right grip 21 is moved with respect to the left grip 22 along the x-axis. This amount of movement is detected by a linear sensor 91 (shown in FIG. 10), and an operation signal corresponding to the amount of movement (detected value) is output to port number 5 of the apparatus main body 10 (shown in FIG. 1). The operation target object 120 displayed in 101 moves in parallel along the Z axis.

  For example, as shown in FIG. 13, the right grip 21 </ b> A adjacent to the left grip 22 moves to the right (in the direction of the arrow in FIG. 13) along the x axis, and is at an intermediate position (indicated by reference numeral 21 </ b> B in FIG. 13). , The operation target object 120A located on the left side of the virtual space is moved to the center position (reference numeral 120B in FIG. 14) in the virtual space, as shown in FIG. Through the X axis to the right position (indicated by reference numeral 120C in FIG. 14). That is, the operation target object 120 is moved and displayed in the same direction as the right hand 130R as the player's right hand 130R moves in the left-right direction.

  When the operation target object 120 is translated in the Y direction in the virtual space, as shown in FIGS. 15 and 16, the player holds the left grip 22 (left hand 130 </ b> L) fixed and moves the right arm up and down as a whole. The right grip 21 and the central coupling mechanism 36 are rotated about the z2 axis. This rotation amount is detected by a fifth rotation sensor 96 (shown in FIG. 10), and an operation signal corresponding to the rotation amount (detection value) is output to port number 2 of the apparatus main body 10 (shown in FIG. 1). The operation target object 120 displayed on the image display unit 101 moves in parallel along the Y axis.

  For example, as shown in FIG. 15, the right grip 21A positioned below the left grip 22 rotates and moves upward (in the direction of the arrow in FIG. 15) about the z2 axis, and reaches an intermediate position (in FIG. 15). When moving to an upper position (indicated by reference numeral 21C in FIG. 15) through the upper position (indicated by reference numeral 21B), the operation target object 120A positioned below the virtual space has a central position in the virtual space (indicated by reference numeral 120B in FIG. 16) To the upper position (indicated by reference numeral 120C in FIG. 16) through the Y axis. Accordingly, the operation target object 120 is moved and displayed in the same direction as the right hand 130R as the player's right hand 130R moves in the vertical direction.

  When the operation target object 120 is translated in the Z direction in the virtual space, as shown in FIGS. 17 and 18, the player holds the left grip 22 (left hand 130L) fixed and moves the right arm as a whole in the front-rear direction. The right grip 21 and the central coupling mechanism 36 are rotated about the y2 axis. This rotation amount is detected by a fourth rotation sensor 95 (shown in FIG. 10), and an operation signal corresponding to the rotation amount (detection value) is output to port number 1 of the apparatus body 10 (shown in FIG. 1). The operation target object 120 displayed on the image display unit 101 moves in parallel along the Z axis.

  For example, as shown in FIG. 17, the right grip 21 </ b> A located behind (to the front of the player) relative to the left grip 22 rotates and moves forward (in the direction of the arrow in FIG. 17) about the y2 axis. When the intermediate object (indicated by reference numeral 21B in FIG. 17) moves to the farther front position away from the player (indicated by reference numeral 21C in FIG. 17), the operation target object 120A located on the near side of the virtual space is In the virtual space, it moves in parallel along the Z-axis through the center position (indicated by reference numeral 120B in FIG. 18) to the back side position (indicated by reference numeral 120C in FIG. 18). Accordingly, the operation target object 120 is moved and displayed in the same direction as the right hand 130R as the player moves the right hand 130R in the front-rear direction.

  When rotating the operation target object 120 around the X axis in the virtual space, as shown in FIGS. 19 and 20, the player rotates the right wrist while fixing the left grip 22 (left hand 130L), The grip 21 is rotated around the x axis. This rotation amount is detected by the first rotation sensor 92 (shown in FIG. 10), and an operation signal corresponding to the rotation amount (detection value) is output to the port number 6 of the apparatus body 10 (shown in FIG. 1). The operation target object 120 displayed on the image display unit 101 rotates around the X axis.

  For example, as shown in FIG. 19, the right grip 21A whose upper end is inclined rearward (near the player) rotates and moves in the positive direction (arrow direction in FIG. 19) about the x-axis. When the upper end of the position moves (indicated by reference numeral 21B in FIG. 19) to a position (indicated by reference numeral 21C in FIG. 19) whose upper end tilts forward (backward away from the player), the operation target object 120A in the virtual space is In the same direction as the rotation of the right gripping part 21 around the x axis, it rotates around the X axis through the position indicated by the reference numeral 120B in FIG. Therefore, the operation target object 120 is rotated and displayed in the same direction as the movement of the right hand 130R in accordance with the rotation of the player's right hand 130R (the rotation of the right grip portion 21 around the x axis).

  When rotating the operation target object 120 around the Y axis in the virtual space, as shown in FIGS. 21 and 22, the player rotates the right wrist while fixing the left grip 22 (left hand 130L), The grip 21 is rotated around the y1 axis. This rotation amount is detected by the second rotation sensor 93 (shown in FIG. 10), and an operation signal corresponding to the rotation amount (detection value) is output to the port number 3 of the apparatus main body 10 (shown in FIG. 1). The operation target object 120 displayed on the image display unit 101 rotates around the Y axis.

  For example, as shown in FIG. 21, the right gripping portion 21A, whose left end is inclined backward (toward the player), rotates and moves in the positive direction (arrow direction in FIG. 21) about the y1 axis. When the left end moves through a position (indicated by reference numeral 21B in FIG. 21) to a position (indicated by reference numeral 21C in FIG. 21) where the left end is tilted forward (backward away from the player), the operation target object 120A in the virtual space is 22 rotates around the Y axis in the same direction as the rotation of the right grip 21 around the y1 axis up to the position indicated by the reference numeral 120C through the position indicated by the reference numeral 120B. Therefore, the operation target object 120 is rotated and displayed in the same direction as the movement of the right hand 130R in accordance with the rotation of the right hand 130R of the player (the rotation of the right gripper 21 around the y1 axis).

  When the operation target object 120 is rotated around the Z axis in the virtual space, as shown in FIGS. 23 and 24, the player rotates the right wrist while fixing the left grip 22 (left hand 130L), The grip 21 is rotated around the z1 axis. This rotation amount is detected by a third rotation sensor 94 (shown in FIG. 10), and an operation signal corresponding to the rotation amount (detection value) is output to the port number 4 of the apparatus body 10 (shown in FIG. 1). The operation target object 120 displayed on the image display unit 101 rotates around the Z axis.

  For example, as shown in FIG. 23, the right grip 21A whose upper end is inclined to the right side for the player rotates in the positive direction (in the direction of the arrow in FIG. 23) about the z1 axis, and reaches an intermediate position (FIG. 23). When the player moves to a position where the upper end of the player tilts to the left side (indicated by reference numeral 21C in FIG. 23) via the middle reference numeral 21B), the operation target object 120A in the virtual space passes through the position indicated by reference numeral 120B in FIG. It rotates about the Z axis in the same direction as the rotation of the right grip 21 around the z1 axis up to the position indicated by reference numeral 120C. Accordingly, the operation target object 120 is rotated and displayed in the same direction as the movement of the right hand 130R as the player's right hand 130R rotates (the rotation of the right gripper 21 around the z1 axis).

(Basic explanation of signal generation processing in left mode)
Next, an operation signal generation process executed by the CPU 81 in the left mode will be described.

  When the left-handed player moves and displays the operation target object 120, the left hand 130L is moved by moving the left hand 130L in a state where the controller 20 is set to the left mode and the right hand 130R is fixed so that the right grip 21 does not move. Is moved or rotated. Here, the CPU 81 exchanges the roles of the left and right hands in the right mode, and outputs the operation signal in the left mode so that the operation target object 120 moves by moving the left hand 130L in the same manner as the right hand 130R in the right mode. Generate.

  Specifically, as shown in the lower column of FIG. 11, the second rotation angle sensor 93 that detects the rotation amount around the y1 axis is assigned to the translation Z, and the CPU 81 determines the second rotation angle sensor 93. An operation signal corresponding to the detected value is generated, and the generated operation signal is output to port number 1 of the apparatus body 10.

  The third rotation angle sensor 94 that detects the rotation amount around the z1 axis is assigned to translation Y, and the CPU 81 generates an operation signal corresponding to the detection value of the third rotation angle sensor 94, and the generated operation signal Is output to the port number 2 of the apparatus main body 10.

  The fourth rotation angle sensor 95 that detects the rotation amount around the y2 axis is assigned to the rotation Y, and the CPU 81 generates an operation signal corresponding to the detection value of the fourth rotation angle sensor 95, and the generated operation signal Is output to port number 3 of the apparatus main body 10 (shown in FIG. 1).

  The fifth rotation angle sensor 96 that detects the rotation amount around the z2 axis is assigned to the rotation Z, and the CPU 81 generates an operation signal according to the detection value of the fifth rotation angle sensor 96, and the generated operation signal Is output to port number 4 of the apparatus main body 10.

  Note that the linear sensor 91 that detects the amount of movement along the x-axis and the first rotation angle sensor 92 that detects the amount of rotation around the x-axis are respectively in translation X and rotation X as in the right mode. Assigned.

  The positive direction of the detection values of the linear sensor 91 and the rotation sensors 92 to 96 is set in advance so that the operation target object 120 moves or rotates in accordance with the moving direction of the right hand of the player in the right mode. Therefore, only by changing the sensors 91 to 96 to which the functions are assigned between the left mode and the right mode as described above, the operation target object 120 is moved in the direction opposite to the moving direction of the left hand of the player in the left mode. It may move or rotate.

  For example, if the fourth rotation angle sensor 95 is simply assigned to the rotation Y in the left mode, the operation target object 120 is obtained when the player rotates the left hand 130L and rotates the left grip 22 around the y2 axis. The direction of rotation around the Y axis is opposite to the direction of rotation of the player's left hand 130L, giving the player a sense of discomfort. In order to eliminate such a sense of incongruity, in the left mode, the CPU 81 of the present embodiment reverses the detected value from the fourth rotation angle sensor 95 (the detected value + θ is −θ and the detected value −θ is changed). Process as + θ) to generate an operation signal.

  For the same reason, in the left mode, the CPU 81 processes the detected values from the fifth rotation angle sensor 96, the first rotation sensor 92, and the linear sensor 91 by reversing the positive and negative values to generate an operation signal. To do.

  As described above, in the controller 20 of the present embodiment, the operation target object 120 moves or rotates in accordance with the moving direction of the dominant hand of the player. Therefore, when moving the operation target object 120 in the virtual space, the real-world object is moved. The controller 20 can be operated with a feeling close to the movement of the hand.

  Further, a right mode for a right-handed player and a left mode for a left-handed player can be selected and set. In the right mode, the operation target object 120 moves or rotates in accordance with the moving direction of the right hand 130R. In the left mode, the operation target object 120 moves or rotates in accordance with the moving direction of the left hand 130L, so that the right-handed player and the left-handed player can operate the controller 20 with the same feeling.

  Furthermore, since the operation signal output from the controller 20 is generated according to the right mode and the left mode, the apparatus main body 10 only needs to execute a common process regardless of the right mode and the left mode.

(Explanation of controller tilt correction)
The player can arbitrarily set the posture of the controller 20, and in addition to the standing state shown in FIG. 25 (a), for example, as shown in FIG. 25 (b), the controller 20 is tilted around the x axis. May be operated. In the standing state, the x axis, the z1 axis, and the z2 axis are set substantially horizontal, and the y1 axis and the y2 axis are set substantially vertical. In the tilted state, the x-axis is set substantially horizontal, but the z1 axis and the z2 axis are tilted from the horizontal direction, and the y1 axis and the y2 axis are tilted from the vertical direction. The feeling of operation of the controller 20 for the player is different between the standing state and the inclined state. For example, in the right mode, the amount of movement of the right grip 21 in the vertical direction when the right grip 21 is rotated about the z2 axis is greater in the standing state than in the tilted state.

  The controller 20 of the present embodiment is provided with an acceleration sensor (gravity sensor) 87 for detecting the inclination (inclination angle θ) of the controller 20 around the x axis, and the player moves the controller 20 from the standing state around the x axis. In the case of tilting operation, the CPU 81 calculates the tilt angle θ using the detection value from the acceleration sensor 87, executes tilt correction processing based on the calculated tilt angle θ, and calculates the difference from the operational feeling in the standing state. It is small.

  Here, the basic concept of inclination correction will be described using the movement amount detection sensor shown in FIGS. 26 and 27 as a model.

  In this model, the controller 20 is provided with the acceleration sensor 87 (shown in FIG. 26A) and the movement amount detection sensor 102 (shown in FIG. 27A). The inclination angle θ around the x axis of the controller 20 (shown in FIG. 26B) is calculated using the detection value from the acceleration sensor 86. The movement amount detection sensor 102 is disposed in the right grip 21 and the controller 20 is not inclined about the x axis (as shown in FIG. 26A, the right grip 21 and the left grip (not shown)). In the standing state), the front-rear direction detecting unit M (shown in FIG. 27A) that detects the amount of movement of the right grip 21 in the front-rear direction z with respect to the left gripper, A direction detection unit N (shown in FIG. 27A).

  When the controller 20 moves the right grip 21 with respect to the left grip with the tilt angle θ around the x-axis, the detection value m of the front-rear direction detector M as shown in FIG. And the detection value n of the vertical direction detection unit N are inclined by the inclination angle θ from the horizontal direction and the vertical direction, respectively, and these detection values m and n are the movement amounts of the right grip 21 in the horizontal direction and the vertical direction. It does not match.

  Therefore, the detection values from the front-rear direction detection unit M and the vertical direction detection unit N are corrected according to the following equations (1) and (2).

Detection value of the front-rear direction detection unit M after correction = mcos θ + n sin θ (1)
Detection value of the vertical direction detection unit N after correction = −msinθ + ncosθ (2)
In the above equations (1) and (2), m is a detection value of the front-rear direction detection unit M, n is a detection value of the vertical direction detection unit N, and θ is an inclination angle θ around the x axis of the controller 20. Further, the above expressions (1) and (2) are expressions when the arrow direction in FIGS. 26 and 27 is positive.

  The CPU 81 of the present embodiment executes a tilt correction process based on the basic concept of the tilt correction. Specifically, the detection value of the second rotation sensor 93 and the third detection value φ3 are determined based on the actual detection value φ2 of the second rotation sensor 93, the actual detection value φ3 of the third rotation sensor 94, and the inclination angle θ. The detection value of the rotation sensor 94 is corrected. The corrected detection value of the second rotation sensor 93 is calculated by substituting φ2 into n and φ3 into n in the above equation (1), and the corrected detection value of the third rotation sensor 94 is It is calculated by substituting φ2 for n and φ3 for n in the above equation (2). Similarly, the detection value of the fourth rotation sensor 95 and the fifth rotation sensor are determined by the actual detection value φ4 of the fourth rotation sensor 95, the actual detection value φ5 of the fifth rotation sensor 96, and the inclination angle θ. 96 detection values are corrected. The corrected detection value of the fourth rotation sensor 95 is calculated by substituting φ4 for n and φ5 for n in the equation (1), and the corrected detection value of the fifth rotation sensor 96 is It is calculated by substituting φ4 for n and φ5 for n in the above equation (2). The CPU 81 generates an operation signal based on the corrected detection value. In the present embodiment, the same inclination correction processing is executed in the right mode and the left mode.

  In this embodiment, the acceleration sensor 86 for detecting the inclination of the controller 20 around the x-axis is provided. However, instead of or in addition to this, the inclination of the controller 20 around the z1 axis and the z2 axis is detected. The CPU 81 may execute an inclination correction process based on the inclination angle detected by the acceleration sensor. Further, the inclination angle of the controller 20 may be detected by means other than the acceleration sensor.

  In the present embodiment, the tilt correction process is performed on the controller 20 side, but may be performed on the apparatus main body 10 side. In this case, the controller 20 transmits the detection value of the acceleration sensor 87 to the apparatus main body 10 as well as transmitting it to the apparatus main body 10 without correcting the actual detection value of each rotation sensor. In the apparatus main body 10, the main CPU 64 and the sub CPU 73 of the apparatus main body 10 execute the tilt correction process using these detection values received from the controller 20.

(Explanation of combination correction of detection value of operation sensor)
In the right mode, when the operation target object 120 (shown in FIG. 1) is translated in the Z direction in the virtual space, the player moves from the initial state shown in FIG. 28A to the left grip 22 (left hand 130L). As shown in FIG. 28 (b), the right grip 21 is rotated about the y2 axis. By such an operation, the operation target object 120 translates in the Z direction in the virtual space according to the detection value of the fourth rotation angle sensor 95.

  However, since the right gripping portion 21 is also rotatable around the y1 axis, it is difficult for the player to rotate the left gripping portion 21 around the y2 axis without rotating around the y1 axis, and it is natural that it is not unreasonable. When the operation is performed, the right grip 21 moves linearly forward (upward in the figure) as shown in FIG. In this case, since the right grip 22 rotates around the y1 axis, the operation target object 120 moves around the Y axis in the virtual space according to the detection value of the second rotation angle sensor 93 against the intention of the player. It will rotate.

  In the present embodiment, in order to eliminate the above inconvenience, the CPU 81 determines that the second value when the absolute value of the detection value θ1 (shown in FIG. 29) of the fourth rotation angle sensor 95 is equal to or larger than a predetermined value. A value obtained by dividing the detection value θ1 of the fourth rotation angle sensor 95 from the actual detection value of the rotation angle sensor 93 is calculated as the detection value of the second rotation angle sensor 93, and based on the calculated detection value after correction. To generate an operation signal. Thereby, it is suppressed that the operation target object 120 moves against a player's intention.

  Further, since the condition is that the absolute value of the detection value θ1 of the fourth rotation angle sensor 95 is not less than a predetermined value, the player wants to positively rotate the right grip 21 around the y2 axis. The correction process is executed only in such a case. That is, when the player wants to actively rotate the right grip 21 around the y1 axis, even if the right grip 21 rotates around the y2 axis against the player's intention, the fourth rotation angle sensor 95 If the absolute value of the detected value θ1 is less than the predetermined value, the correction process is not executed, and the operation target object 120 rotates around the Y axis in the virtual space by the amount intended by the player.

  Similarly, the CPU 81 performs the correction process on the detection value of the third rotation angle sensor 94 using the detection value of the fifth rotation angle sensor 96.

  In the present embodiment, the correction process is performed on the controller 20 side, but this may be performed on the apparatus main body 10 side. In this case, the controller 20 transmits the actual detection value of each rotation sensor to the apparatus main body 10 without correcting it. In the apparatus main body 10, the main CPU 64 and the sub CPU 73 of the apparatus main body 10 execute the tilt correction process using these detection values received from the controller 20.

[Explanation of load control processing]
The CPU 81 controls the load applied by the load applicator 97 to the second connecting shaft 47 according to the load information received from the apparatus main body 10 by the USB communication module 88 or the BT communication module 89. For example, when the virtual space includes the operation target object 120 (shown in FIG. 1) and a contact target object (not shown) having a soft surface, the apparatus main body 10 loads information according to the softness of the surface of the contact target object. Is transmitted to the controller 20. When the operation target object 120 moves along the X axis direction by the operation from the player and contacts the contact target object, the CPU 18 causes the load applier 97 to move the second connection shaft 47 in accordance with the received load information. Control the load to be applied. Thereby, the player can experience the softness of the surface of the contact target object.

  The description of each of the above embodiments is an example of the present invention. For this reason, the present invention is not limited to the above-described embodiments, and various modifications can be made even outside the above-described embodiments as long as they do not depart from the technical idea according to the present invention. Of course.

It is a schematic diagram which shows the outline | summary of the entertainment system as one Embodiment of this invention. It is a block diagram which shows the main internal structures of an apparatus main body. It is an external appearance perspective view of a controller. It is the front view which looked at the controller from the arrow IV direction of FIG. It is the top view which looked at the controller from the arrow V direction of FIG. It is the rear view which looked at the right holding part of the controller from the arrow VI direction of FIG. It is a perspective view which shows typically the internal structure of a controller. It is a schematic diagram which shows arrangement | positioning of the coil spring in a controller. It is a block diagram which shows the main electrical structures of a controller. It is a schematic diagram which shows the relationship between a right holding part, a left holding part, and an operation sensor. It is a figure which shows the function of each operation sensor at the time of right mode and left mode. It is a schematic diagram which shows the state at the time of the operation start of a controller. It is a schematic diagram which shows the state which moved the right holding part to the x-axis direction. It is a schematic diagram which shows the motion of the operation target object corresponding to the movement to the x-axis direction of a right holding part. It is a mimetic diagram showing the state where the right grasping part was rotated around the z2 axis. It is a schematic diagram which shows the motion of the operation target object corresponding to rotation around the z2 axis of the right grip. It is a mimetic diagram showing the state where the right grasping part was rotated around the y2 axis. It is a schematic diagram which shows a motion of the operation target object corresponding to rotation around the y2 axis of the right grip. It is a schematic diagram which shows the state which rotated the right grip part around the x-axis. It is a schematic diagram which shows a motion of the operation target object corresponding to the rotation of the right grip part around the x axis. It is a schematic diagram which shows the state which rotated the right holding | gripping part around the y1 axis | shaft. It is a schematic diagram which shows the motion of the operation target object corresponding to rotation around the y1 axis of the right grip. It is a schematic diagram which shows the state which rotated the right grip part around the z1 axis | shaft. It is a schematic diagram which shows the motion of the operation target object corresponding to rotation around the z1 axis of the right grip. It is a perspective view which shows typically the state where the player grasped the controller, (a) shows the state where the controller stood up, and (b) shows the state where the controller was inclined. It is a schematic diagram which shows the controller of the model for demonstrating inclination correction | amendment, (a) shows the state which raised the controller, (b) shows the state which inclined the controller. It is a schematic diagram which shows the movement amount detection sensor of the model for demonstrating inclination correction | amendment, (a) shows the state which raised the controller, (b) shows the state which inclined the controller. It is a schematic diagram which shows the operation state of a controller, (a) shows an initial state, (b) shows the state which rotated the right grip part about the y2 axis without producing the rotation about the y1 axis, (c ) Shows a state in which the right gripping part is rotated around the y2 axis with rotation around the y1 axis. It is a schematic diagram which shows the rotation angle sensor of FIG.28 (c).

Explanation of symbols

  10: device main body, 15: connection port, 17: wireless communication unit, 20: controller, 21: right gripping part, 22: left gripping part, 23: coupling part, 24: central case body, 25: right case body, 26 : Left case body, 27: base body, 34: right coupling mechanism, 35: left coupling mechanism, 36: central coupling mechanism, 48: central base body, 52: first coil spring, 53: second coil spring, 54: Third coil spring, 55: fourth coil spring, 81: CPU, 86: operation sensor, 87: acceleration sensor, 91: linear sensor, 92: first rotation angle sensor, 93: second rotation angle sensor, 94 : Third rotation angle sensor, 95: fourth rotation angle sensor, 96: fifth rotation angle sensor, 97: load applicator, 100: monitor device, 101 image display unit, 120: object to be operated, 130R: play Of the left hand, 130L: the right hand of the player

Claims (23)

A controller that communicates with an information processing apparatus that forms a virtual space including a predetermined object,
A first gripping part gripped by one hand of the user;
A second gripping part gripped by the other hand of the user;
A connecting means for connecting the first gripping part and the second gripping part so that the relative positions of both can be changed;
Detecting means for detecting a change amount of a relative position between the first gripping portion and the second gripping portion;
Signal generating means for generating a signal based on the amount of change detected by the detecting means;
Transmission means for transmitting the signal generated by the signal generation means to the information processing apparatus,
The connecting means connects the first gripping portion and the second gripping portion so as to be movable along a main axis,
The detecting means detects a change amount of a distance along the main axis between the first gripping portion and the second gripping portion;
The signal generation means generates a first operation signal that indicates the movement of the predetermined object according to the detected distance change amount when the detection means detects the distance change amount. A featured controller. The controller of claim 1,
The controller, wherein the movement of the predetermined object indicated by the first operation signal is a horizontal movement in the virtual space. The controller according to claim 1 or 2, wherein
The coupling means couples the first gripping portion and the second gripping portion so as to be rotatable around a rotation axis set in a direction different from the main shaft,
The detecting means detects a change amount of an angle around the rotation axis between the first gripping portion and the second gripping portion;
A second operation for instructing the movement of the predetermined object according to the detected amount of change of the angle when the detection unit detects the amount of change of the angle about the rotation axis; A controller characterized by generating a signal. The controller according to claim 3, wherein
The movement of the predetermined object instructed by the second operation signal is a vertical movement, a depth movement, a rotation about a vertical axis, and a depth axis in the virtual space. A controller characterized by being one of rotations. A controller according to any one of claims 1 to 4,
The connecting means connects the first gripping part and the second gripping part so as to be rotatable about the main axis,
The detecting means detects a change amount of an angle around the main axis between the first gripping portion and the second gripping portion;
A third operation signal for instructing the movement of the predetermined object according to the detected change amount of the angle when the detection unit detects the change amount of the angle about the main axis; A controller characterized by generating. The controller according to claim 5, wherein
The controller, wherein the movement of the predetermined object instructed by the third operation signal is rotation about a horizontal axis in the virtual space. A controller that communicates with an information processing device,
A first gripping part gripped by one hand of the user;
A second gripping part gripped by the other hand of the user;
A connecting means for connecting the first gripping part and the second gripping part so that the relative positions of both can be changed;
Detecting means for detecting a change amount of a relative position between the first gripping portion and the second gripping portion;
Signal generating means for generating a signal based on the amount of change detected by the detecting means;
Transmitting means for transmitting the signal generated by the signal generating means to the information processing apparatus;
An inclination angle detecting means,
The connecting means connects the first gripping part and the second gripping part so as to be movable along the main axis, and is rotatable about a rotation axis set in a direction different from the main axis. Concatenate,
The detection means detects a change amount of a distance along the main axis between the first grip portion and the second grip portion and a change amount of an angle around the rotation axis,
The rotating shaft extends in a vertical direction in a basic operation state in which the first grip portion and the second grip portion are gripped by the user,
The inclination angle detection means detects an inclination angle of the rotating shaft with respect to a vertical direction,
The signal generation means corrects the change amount of the angle around the rotation axis detected by the detection means using the inclination angle detected by the inclination angle detection means, and corresponds to the corrected change amount. A controller characterized by generating a signal. The controller according to claim 7, wherein
The controller according to claim 1, wherein the tilt angle detection means detects a tilt angle of the rotating shaft around the main shaft. A controller according to claim 7 or claim 8, wherein
The connecting means connects the first gripping part and the second gripping part so as to be rotatable around another rotation axis set in a direction different from the main axis and the rotation axis,
The detecting means detects a change amount of an angle around the other rotation axis between the first gripping portion and the second gripping portion;
The signal generation means corrects the change amount of the angle of the other rotation shaft detected by the detection means using the inclination angle detected by the inclination angle detection means, and a signal corresponding to the corrected change amount. A controller characterized by generating. A controller that communicates with an information processing device,
A first gripping part gripped by one hand of the user;
A second gripping part gripped by the other hand of the user;
A connecting means for connecting the first gripping part and the second gripping part so that the relative positions of both can be changed;
Detecting means for detecting a change amount of a relative position between the first gripping portion and the second gripping portion;
Signal generating means for generating a signal based on the amount of change detected by the detecting means;
Transmission means for transmitting the signal generated by the signal generation means to the information processing apparatus,
The coupling means includes a main coupling mechanism, a first coupling mechanism that couples the first gripping part and the main coupling mechanism, and a second coupling that couples the second gripping part and the main coupling mechanism. A coupling mechanism;
The main connection mechanism connects the first connection mechanism and the second connection mechanism so as to be movable along a main axis,
The first coupling mechanism couples the first grip portion and the main coupling mechanism so as to be rotatable around a rotation axis set in a direction different from the main axis,
The second coupling mechanism couples the second grip portion and the main coupling mechanism so as to be rotatable around another rotation axis set in a direction different from the main axis,
The rotation axis and the other rotation axis are set substantially parallel,
The detection means includes a change amount of an angle about the rotation axis between the first gripping portion and the main coupling mechanism, and the other between the second gripping portion and the main coupling mechanism. The amount of change in the angle around the rotation axis of
The signal generation unit corrects the change amount of the angle centered on the rotation axis detected by the detection unit using the change amount of the angle centered on the other rotation axis, and sets the corrected change amount. A controller characterized by generating a corresponding signal. The controller of claim 10, comprising:
The controller, wherein the signal generation means performs the correction when an amount of change in angle about the rotation axis detected by the detection means is a predetermined value or more. A controller that communicates with an information processing apparatus that forms a virtual space including a predetermined object,
A first gripping part gripped by one hand of the user;
A second gripping part gripped by the other hand of the user;
A connecting means for connecting the first gripping part and the second gripping part so that the relative positions of both can be changed;
Detecting means for detecting a change amount of a relative position between the first gripping portion and the second gripping portion;
Signal generating means for generating a signal based on the amount of change detected by the detecting means;
Transmission means for transmitting the signal generated by the signal generation means to the information processing apparatus,
The coupling means includes a main coupling mechanism, a first coupling mechanism that couples the first gripping part and the main coupling mechanism, and a second coupling that couples the second gripping part and the main coupling mechanism. A coupling mechanism;
The main coupling mechanism is configured to couple the first coupling mechanism and the second coupling mechanism so as to be movable along the main axis and to be rotatable about the main axis.
The main shaft extends in the left-right direction with respect to the user in a basic operation state in which the first grip portion and the second grip portion are gripped by the user,
The first coupling mechanism couples the first gripping part and the main coupling mechanism so as to be rotatable around a first rotation axis set in a direction different from the main axis, and the main axis and A second rotation axis set in a direction different from the first rotation axis, and connected to be rotatable about the second rotation axis;
The second coupling mechanism couples the second gripping portion and the main coupling mechanism so as to be rotatable around a third rotation axis set in a direction different from the main axis, and the main axis and A fourth rotation axis set in a direction different from the third rotation axis, and rotatably connected around the fourth rotation axis;
The first rotating shaft and the third rotating shaft extend in the vertical direction in the basic operation state,
The second rotating shaft and the fourth rotating shaft extend in the front-rear direction with respect to the user in the basic operation state,
The detection means includes
A distance change amount detection means for detecting a change amount of a distance along the main axis between the first grip portion and the second grip portion;
First angle change amount detection means for detecting an amount of change in angle about the first rotation axis between the first gripping portion and the main coupling mechanism;
A second angle change amount detecting means for detecting a change amount of an angle about the second rotation axis between the first grip portion and the main coupling mechanism;
Third angle change amount detection means for detecting an amount of change of an angle around the third rotation axis between the second grip portion and the main coupling mechanism;
A fourth angle change amount detecting means for detecting a change amount of an angle around the fourth rotation axis between the second grip portion and the main coupling mechanism;
A fifth angle change amount detection means for detecting a change amount of an angle about the main axis between the first grip portion and the second grip portion;
The signal generating means includes
When the distance change amount detecting means detects the distance change amount, an operation signal for instructing a horizontal movement of the predetermined object in the virtual space according to the detected distance change amount is generated.
When the first angle change amount detecting means detects the angle change amount, the rotation of the predetermined object around the vertical axis in the virtual space is determined according to the detected angle change amount. Generate an operation signal to indicate,
When the second angle change amount detection unit detects the angle change amount, the rotation of the predetermined object about the axis in the depth direction in the virtual space is determined according to the detected angle change amount. Generate an operation signal to indicate,
When the third angle change amount detection means detects an angle change amount, an operation signal is generated to instruct the movement of the predetermined object in the virtual space in the depth direction according to the detected angle change amount. And
When the fourth angle change amount detection means detects an angle change amount, an operation signal is generated to instruct the vertical movement of the predetermined object in the virtual space according to the detected angle change amount. And
When the fifth angle change amount detection unit detects the angle change amount, the rotation of the predetermined object about the horizontal axis in the virtual space is determined according to the detected angle change amount. A controller characterized by generating an operation signal to be instructed. A controller according to any one of claims 1 to 12,
A first mode suitable for an operation mode in which the position of the second gripping portion is held and the first gripping portion is moved, and the second gripping portion is held by holding the position of the first gripping portion. A mode setting means for selecting and setting one mode according to an input from the user from a plurality of modes including a second mode suitable for the operation mode to be moved;
The controller, wherein the signal generation unit generates the signal according to a process corresponding to a mode set by the mode setting unit among a plurality of processes set in advance corresponding to each of the plurality of modes. A first gripping part gripped by one hand of the user;
A second gripping part gripped by the other hand of the user;
A connecting means for connecting the first gripping part and the second gripping part so that the relative positions of both can be changed;
Detecting means for detecting a change amount of a relative position between the first gripping portion and the second gripping portion;
Signal generating means for generating a signal based on the amount of change detected by the detecting means;
A transmission unit for transmitting the signal generated by the signal generation unit;
Receiving means for receiving a signal from the transmitting means;
An information processing apparatus comprising: an image processing unit that forms a virtual space including a predetermined object;
An image processing system comprising:
The connecting means connects the first gripping portion and the second gripping portion so as to be movable along a main axis,
The detecting means detects a change amount of a distance along the main axis between the first gripping portion and the second gripping portion;
The signal generation means generates a first operation signal according to the change amount of the distance detected by the detection means,
The image processing means moves the predetermined object in the virtual space in the horizontal direction based on the received first operation signal when the receiving means receives the first operation signal from the transmitting means. An image processing system characterized by generating an image. The image processing system according to claim 14,
The coupling means couples the first gripping portion and the second gripping portion so as to be rotatable around a rotation axis set in a direction different from the main shaft,
The detecting means detects a change amount of an angle around the rotation axis between the first gripping portion and the second gripping portion;
The signal generating means generates a second operation signal according to an angle change amount centered on the rotation axis detected by the detecting means,
When the receiving unit receives the second operation signal from the transmitting unit, the image processing unit moves the predetermined object in the virtual space in the vertical direction based on the received second operation signal. An image to be generated, an image to be moved in the depth direction, an image to be rotated about an axis in the vertical direction, and an image to be rotated about an axis in the depth direction are generated. . The image processing system according to claim 14 or 15,
The connecting means connects the first gripping part and the second gripping part so as to be rotatable about the main axis,
The detecting means detects a change amount of an angle around the main axis between the first gripping portion and the second gripping portion;
The signal generating means generates a third operation signal in accordance with the amount of change in angle about the main axis detected by the detecting means,
When the receiving unit receives the third operation signal from the transmitting unit, the image processing unit moves the predetermined object on the horizontal axis in the virtual space based on the received third operation signal. An image processing system for generating an image to be rotated as a center. A first gripping part gripped by one hand of the user, a second gripping part gripped by the other hand of the user, the first gripping part and the second gripping part, Based on a change amount detected by the detection means, a detection means for detecting a change amount of the relative position between the first gripping portion and the second gripping portion, and a change amount detected by the detection means. A signal generating unit configured to generate a signal; and a transmitting unit configured to transmit the signal generated by the signal generating unit. The coupling unit includes the first gripping unit and the second gripping unit as main axes. The detection means detects a change amount of the distance along the main axis between the first gripping part and the second gripping part, and the signal generation means A controller that generates a first operation signal in accordance with a change amount of the distance detected by the detection unit; In a information processing apparatus capable of communicating,
Receiving means for receiving a signal from the transmitting means;
Image processing means for forming a virtual space including a predetermined object,
The image processing means moves the predetermined object in the virtual space in the horizontal direction based on the received first operation signal when the receiving means receives the first operation signal from the transmitting means. An information processing apparatus characterized by generating an image. A first gripping part gripped by one hand of the user, a second gripping part gripped by the other hand of the user, the first gripping part and the second gripping part, Based on a change amount detected by the detection means, a detection means for detecting a change amount of the relative position between the first gripping portion and the second gripping portion, and a change amount detected by the detection means. A signal generating unit configured to generate a signal; and a transmitting unit configured to transmit the signal generated by the signal generating unit. The coupling unit includes the first gripping unit and the second gripping unit as main axes. The detection means detects a change amount of the distance along the main axis between the first gripping part and the second gripping part, and the signal generation means A controller that generates a first operation signal in accordance with a change amount of the distance detected by the detection unit; In an information processing program executed by a computer of an information processing apparatus capable of communicating,
The image processing means forming a virtual space including a predetermined object;
Receiving a signal from the transmitting means;
When the receiving means receives the first operation signal, the image processing means generates an image for moving the predetermined object in the horizontal direction in the virtual space based on the received first operation signal. When,
An information processing program for causing a computer to execute a plurality of steps including: The connecting means of the controller connects the first gripping part and the second gripping part so as to be rotatable around a rotation axis set in a direction different from the main axis, and the detection means An amount of change in angle about the rotation axis between the first gripping part and the second gripping part is detected, and the signal generation means is centered on the rotation axis detected by the detection means. The information processing program according to claim 18, wherein the information processing program generates the second operation signal according to the amount of change in the angle.
The plurality of steps include:
When the receiving means receives the second operation signal, an image for moving the predetermined object in the vertical direction in the virtual space based on the received second operation signal, an image for moving in the depth direction, An information processing program comprising: the image processing unit generating any one of an image rotated about an axis in a vertical direction and an image rotated about an axis in a depth direction. The connecting means of the controller connects the first gripping part and the second gripping part so as to be rotatable about the main axis, and the detecting means is configured to connect the first gripping part and the second gripping part. A change amount of an angle centered on the main axis with respect to the gripping portion is detected, and the signal generating means outputs a third operation signal in accordance with the change amount of the angle centered on the main axis detected by the detection means. An information processing program according to claim 18 or 19, wherein
The plurality of steps include:
When the receiving means receives the third operation signal, an image for rotating the predetermined object around the horizontal axis in the virtual space based on the received third operation signal is the image processing means. The information processing program characterized by including the step which produces | generates. A first gripping part gripped by one hand of the user, a second gripping part gripped by the other hand of the user, the first gripping part and the second gripping part, Based on a change amount detected by the detection means, a detection means for detecting a change amount of the relative position between the first gripping portion and the second gripping portion, and a change amount detected by the detection means. A signal generation unit configured to generate a signal; a transmission unit configured to transmit a signal generated by the signal generation unit; and an inclination angle detection unit. The connection unit includes the first grip portion and the second grip unit. The gripping unit is coupled to be movable along the main axis, and is coupled to be rotatable about a rotation axis set in a direction different from the main axis, and the detection means is connected to the first gripping unit and the first gripping unit. The amount of change in the distance along the main axis between the second grip part and the rotation axis The amount of change of the center angle is detected, and the rotation axis extends in the vertical direction in a basic operation state where the first grip portion and the second grip portion are gripped by the user, and the tilt angle detection means Detects the tilt angle of the rotating shaft with respect to the vertical direction, and the transmitting means is a computer of an information processing apparatus capable of communicating with a controller that transmits a signal based on the tilt angle detected by the tilt angle detecting means. An information processing program to be executed by
Receiving a signal from the transmitting means;
When the receiving means receives the signal based on the angle change amount and the signal based on the tilt angle, the information processing means corrects the angle change amount using the tilt angle; and
The information processing means executes a predetermined process using the corrected change amount;
An information processing program for causing the computer to execute a plurality of steps including: A first gripping part gripped by one hand of the user, a second gripping part gripped by the other hand of the user, the first gripping part and the second gripping part, Based on a change amount detected by the detection means, a detection means for detecting a change amount of the relative position between the first gripping portion and the second gripping portion, and a change amount detected by the detection means. Signal generating means for generating a signal, and transmitting means for transmitting the signal generated by the signal generating means, wherein the connecting means includes a main connecting mechanism, the first gripping portion, and the main connecting mechanism. A first coupling mechanism that couples the second gripping portion and the main coupling mechanism, and the main coupling mechanism includes the first coupling mechanism and the first coupling mechanism. A second connection mechanism is movably connected along the main axis, and the first connection mechanism is connected to the first connection mechanism. A holding portion and the main coupling mechanism are coupled to be rotatable about a rotation axis set in a direction different from the main shaft, and the second coupling mechanism includes the second gripping portion and the main coupling mechanism. Are connected so as to be rotatable around another rotating shaft set in a direction different from the main shaft, the rotating shaft and the other rotating shaft are set substantially parallel to each other, and the detecting means A first angle change amount centered on the rotation axis between one gripping part and the main coupling mechanism, and the other rotation axis between the second gripping part and the main coupling mechanism. An information processing program to be executed by a computer of an information processing apparatus capable of communicating with a controller that detects the second angle change amount,
Receiving a signal from the transmitting means;
When the receiving means receives the signal based on the first angle change amount and the signal based on the second angle change amount, the information processing means uses the second angle change amount to change the first angle. Correcting the amount of change;
The information processing means executes a predetermined process using the corrected change amount;
An information processing program for causing the computer to execute a plurality of steps including:   A computer-readable storage medium in which the information processing program according to any one of claims 18 to 22 is stored.

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