JP2021037269A - Information processing system, information processing program, information processing method, and information processing device - Google Patents

Abstract

To provide an information processing system capable of reducing a data amount to be used to control a vibrator.SOLUTION: An information processing system is provided with a vibrator 117. The information processing system shows a model of time change related to a frequency of vibration, and stores a frequency model function with a frequency variable showing a frequency of a certain period in the model and a period variable related to the period as variables. The information processing system determines a value of the frequency variable and a value of the period variable. The information processing system generates vibration information showing a vibration pattern regulated by a time change in a frequency obtained by applying the determined value of the frequency variable and the determined value of the period variable to the frequency model function. The information processing system controls the vibration of the vibrator on the basis of the vibration information.SELECTED DRAWING: Figure 11

Description

The present invention relates to an information processing system, an information processing program, an information processing method, and an information processing device that control the vibration of an oscillator.

Conventionally, the vibration of the vibrator included in the apparatus has been controlled (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2016-202486

When the vibrator is vibrated with various vibration patterns, the device provided with the vibrator must store a large number of vibration patterns, which may increase the amount of data used for controlling the vibrator.

Therefore, an object of the present invention is to provide an information processing system, an information processing program, an information processing method, and an information processing apparatus capable of reducing the amount of data used for controlling an oscillator.

In order to solve the above problems, the present invention has adopted the following configurations (1) to (13).

(1)
An example of the present invention is an information processing system including an oscillator. The information processing system includes a function storage unit, a variable determination unit, a generation unit, and a vibration control unit. The function storage unit shows a model of time change with respect to the frequency of vibration, and stores a frequency model function having a frequency variable indicating the frequency of a certain period in the model and a period variable related to the period as variables. The variable determination unit determines the value of the frequency variable and the value of the period variable. The generation unit generates vibration information indicating a vibration pattern defined by a time change of the frequency obtained by applying the determined value of the frequency variable and the value of the determined period variable to the frequency model function. The vibration control unit controls the vibration of the vibrator based on the vibration information.

According to the configuration of (1) above, the amount of data used for controlling the oscillator can be reduced by storing the frequency model function and generating vibration information based on the frequency model function.

(2)
The function storage unit may store a plurality of types of frequency model functions indicating models of time changes of frequencies different from each other. The variable determination unit may further determine the function specification information that specifies one of the plurality of types of frequency model functions. The generator is defined by the time variation of the frequency obtained by applying the determined frequency variable value and the determined period variable value to the frequency model function specified by the determined function specification information. Vibration information indicating the vibration pattern may be generated.

According to the configuration of (2) above, by using a plurality of frequency model functions, it is possible to vibrate the oscillator with various vibration patterns while suppressing the amount of data used for controlling the oscillator.

(3)
The period variable may include a start variable that indicates the time from the start of the model of time change indicated by the frequency model function to the start of vibration.

According to the configuration of (3) above, it is possible to adjust the time point at which vibration starts in the vibration pattern. When the configuration of the above (3) is combined with the configuration of (7) described later, the interval at the start time of vibration in a plurality of vibration patterns can be easily adjusted.

(4)
The frequency model function may be a function in which the time length of the vibration pattern is determined by applying the value of the period variable to the frequency model function.

According to the configuration of (4) above, it is possible to generate a vibration pattern having a long time regardless of the capacity of the storage device.

(5)
The function storage unit shows a model of time change with respect to the amplitude of vibration, and may further store an amplitude model function having an amplitude variable indicating the amplitude of vibration as a variable. The variable determination unit may further determine the value of the amplitude variable. The generator uses the determined frequency variable value and the determined period variable value as the frequency model function to obtain the frequency change over time and the determined amplitude variable value as the amplitude model function. Vibration information indicating a vibration pattern defined by the time variation of the amplitude obtained by application may be generated.

According to the configuration of (5) above, a vibration pattern having a different amplitude in addition to the frequency can be defined by a function, and the vibrator can be vibrated with a wider variety of vibration patterns.

(6)
The amplitude variable may include an end amplitude variable that indicates the end point amplitude in the model of time variation with respect to the amplitude of vibration.

According to the configuration of (6) above, the vibration pattern can be defined so that the vibration is continuous in the two continuous vibration patterns, and the variation of the vibration pattern that can be generated can be increased.

(7)
The variable determination unit may determine a plurality of pairs of the value of the frequency variable and the value of the period variable.
The generator is obtained by integrating a plurality of vibration patterns based on a determined set of a plurality of sets of frequency variable values and a set of period variable values, in which a plurality of vibration patterns in which vibrations occur do not overlap with each other. Vibration information indicating one vibration pattern may be generated.

According to the configuration of (7) above, the calculation process for integrating the vibration patterns can be easily performed.

(8)
The oscillator may be capable of vibrating with a waveform obtained by synthesizing each vibration waveform corresponding to each of the first predetermined number of vibration information of two or more. The variable determination unit may determine a second predetermined number larger than the first predetermined number for the set of the value of the frequency variable and the value of the period variable. The generation unit integrates two or more vibration patterns out of the second predetermined number of vibration patterns based on the determined set into one vibration pattern, thereby collectively indicating the first predetermined number of vibration patterns. A predetermined number of vibration information may be generated.

According to the configuration of (8) above, the number of vibration patterns (that is, the first predetermined number) that the oscillator can handle is not limited to the number of vibration patterns defined according to the set of variables determined by the variable determination unit. Vibration information can be generated.

(9)
The frequency model function may further use a repeating variable as a variable. The variable determination unit may further determine the value of the iterative variable. The generator determines the vibration pattern defined by the time change of the frequency obtained by applying the determined frequency variable value and the determined period variable value to the frequency model function. Vibration information indicating a repetitive vibration pattern obtained by repeating the number of times indicated by may be generated.

According to the configuration of (9) above, it is possible to generate a vibration pattern in which a certain mode of vibration is repeated with a smaller amount of data.

(10)
The information processing system may include a first device including an oscillator and a second device that communicates with the first device. The second device may include a function storage unit, a variable determination unit, a generation unit, and a transmission unit that transmits vibration information to the first device. The first device may include a receiving unit that receives vibration information from the second device, and a vibration control unit that controls the vibration of the vibrator based on the vibration information received by the receiving unit.

According to the configuration of (10) above, the amount of data used for controlling the oscillator in the second device can be reduced.

(11)
The information processing system may include a first device including an oscillator and a second device that wirelessly communicates with the first device. The second device may include a variable determination unit and a transmission unit that transmits the determined value of the frequency variable and the value of the period variable to the first device. The first device may include a receiving unit, a generating unit, and a vibration control unit. The receiving unit receives the value of the frequency variable and the value of the period variable from the second device. The generator generates vibration information based on the values of the frequency variable and the period variable received by the receiver.

According to the configuration of (11) above, since the information indicating the variable is transmitted from the second device to the first device, at least one of the communication amount and the communication frequency between the devices can be reduced.

(12)
The first device and the second device may be capable of operating in a plurality of modes including the first mode and the second mode. In the first mode, the transmitter of the second apparatus transmits the value of the frequency variable and the value of the period variable determined by the variable determination unit to the first apparatus, and the first apparatus transmits the value of the frequency variable received by the receiver. The vibration of the vibrator is controlled based on the vibration information generated by the generator based on the value of and the value of the period variable. In the second mode, the second device transmits vibration information indicating a predetermined vibration pattern to the first device, and the first device controls the vibration of the vibrator based on the vibration information transmitted from the second device. To do.

According to the configuration of (12) above, by using the function, the amount of data used for controlling the oscillator can be reduced, and the oscillator can be vibrated by a vibration pattern that cannot be generated from the function. Can be done.

(13)
The first device may further include a reply unit. The reply unit makes a reply to the second device in response to the fact that the value of the frequency variable and the value of the period variable are received from the second device. If there is no reply from the first device to the transmission of the value of the frequency variable and the value of the period variable within a predetermined time from the transmission, the transmitter retransmits the value of the frequency variable and the value of the period variable to the first device. You may send it.

According to the configuration (13) above, it is possible to improve the possibility that the vibrator can be vibrated when wireless communication is performed between the first device and the second device.

Another example of the present invention is information that causes the computer of the information processing apparatus to execute processing in some of the parts (for example, the variable determination part and the generation part) of the information processing system in the above (1) to (13). It may be a processing program. Further, another example of the present invention may be an information processing method executed in the information processing system according to the above (1) to (13). Further, another example of the present invention is an information processing device including the function storage unit, the generation unit, and the vibration control unit in the above (1) to (13), which is different from the information processing device. It may be an information processing device including a receiving unit that receives the value of the frequency variable and the value of the period variable from the device. Further, another example of the present invention may be another information processing device that transmits the value of the frequency variable and the value of the period variable to the information processing device.

According to the present invention, the amount of data used for controlling the oscillator can be reduced.

The figure which shows an example of each device included in a game system The figure which shows an example of the state which the left controller 3 and the right controller 4 are attached to the main body device 2. The figure which shows an example of the state which the left controller 3 and the right controller 4 are removed from the main body device 2, respectively. Six views showing an example of the main unit 2 Six views showing an example of the right controller 4 Block diagram showing an example of the internal configuration of the main unit 2 A block diagram showing an example of the internal configuration of the main unit 2 and the left controller 3 and the right controller 4. The figure which shows an example of the ring type expansion apparatus 5. Block diagram showing an example of the internal configuration of the ring type expansion device 5 The figure which shows an example of a state in which a user uses a ring type expansion device 5. A block diagram showing the functional configurations of the ring-type expansion device 5 and the right controller 4 related to the vibration control of the vibrator 117. The figure which shows an example of the 1st vibration model used in this embodiment. The figure which shows an example of the 2nd vibration model used in this embodiment. Diagram showing an example of correspondence information The figure which shows an example of the integrated vibration pattern which integrated a plurality of vibration patterns The figure which shows an example of the generation method of vibration information The figure which shows an example which vibrates an oscillator based on the vibration information which shows two vibration patterns. A flowchart showing an example of vibration control processing executed by the ring type expansion device 5. A block diagram showing the functional configurations of the main unit 2 and the right controller 4 related to the vibration control of the vibrator 117. Flowchart showing an example of vibration control processing in a modified example Diagram showing another example of the vibration model Diagram showing another example of the vibration model

[1. Game system configuration]
Hereinafter, a game system according to an example of this embodiment will be described. FIG. 1 is a diagram showing an example of each device included in the game system. As shown in FIG. 1, the game system 1 includes a main body device 2, a left controller 3, a right controller 4, and a ring-type expansion device 5.

The main body device 2 is an example of an information processing device, and functions as a game machine main body in the present embodiment. The left controller 3 and the right controller 4 can be attached to and detached from the main body device 2, respectively (see FIGS. 1 and 3). That is, the user can attach the left controller 3 and the right controller 4 to the main body device 2 and use them as an integrated device (see FIG. 2). The user can also use the main unit 2 and the left controller 3 and the right controller 4 as separate bodies (see FIG. 3). In the following, the main body device 2 and the controllers 3 and 4 may be collectively referred to as a “game device”.

The ring type expansion device 5 is an example of the expansion device used for the right controller 4. The ring-type expansion device 5 is used with the right controller 4 mounted on the ring-type expansion device 5. As described above, in the present embodiment, the user can also use the right controller 4 in a state of being attached to the ring type expansion device 5 (see FIG. 10). The ring-type expansion device 5 is not limited to the right controller 4, and the left controller 3 may be attached to itself.

[1-1. Game device configuration]
FIG. 2 is a diagram showing an example of a state in which the left controller 3 and the right controller 4 are attached to the main body device 2. As shown in FIG. 2, the left controller 3 and the right controller 4 are mounted on the main body device 2 and integrated with each other. The main body device 2 is a device that executes various processes (for example, game processes) in the game system 1. The main body device 2 includes a display 12. The left controller 3 and the right controller 4 are devices including an operation unit for inputting by the user.

FIG. 3 is a diagram showing an example of a state in which the left controller 3 and the right controller 4 are removed from the main body device 2. As shown in FIGS. 2 and 3, the left controller 3 and the right controller 4 are detachable from the main body device 2. In the following, the term "controller" may be used as a general term for the left controller 3 and the right controller 4.

FIG. 4 is a six-view view showing an example of the main body device 2. As shown in FIG. 4, the main body device 2 includes a substantially plate-shaped housing 11. In the present embodiment, the main surface of the housing 11 (in other words, the front surface, that is, the surface on which the display 12 is provided) has a substantially rectangular shape.

As shown in FIG. 4, the main body device 2 includes a display 12 provided on the main surface of the housing 11. The display 12 displays an image generated by the main body device 2. In the present embodiment, the display 12 is a liquid crystal display (LCD). However, the display 12 may be any kind of display device. The main unit 2 can also output an image to an external monitor.

The main body device 2 includes a speaker inside the housing 11. As shown in FIG. 4, speaker holes 11a and 11b are formed on the main surface of the housing 11. Then, the output sound of the speaker is output from these speaker holes 11a and 11b, respectively.

Further, the main body device 2 includes a left terminal 17 which is a terminal for the main body device 2 to perform wired communication with the left controller 3, and a right terminal 21 for the main body device 2 to perform wired communication with the right controller 4.

As shown in FIG. 4, the main body device 2 includes a slot 23. The slot 23 is provided on the upper side surface of the housing 11. The slot 23 has a shape in which a predetermined type of storage medium can be mounted. The predetermined type of storage medium is, for example, a storage medium (for example, a dedicated memory card) dedicated to the game system 1 and an information processing device of the same type. A predetermined type of storage medium stores, for example, data used in the main unit 2 (for example, save data of an application) and / or a program executed in the main unit 2 (for example, an application program). Used to do. Further, the main body device 2 includes a power button 28.

FIG. 5 is a six-view view showing an example of the right controller 4. As shown in FIG. 5, the right controller 4 includes a housing 51. In the present embodiment, the housing 51 has a vertically long shape, that is, a shape that is long in the vertical direction (that is, the y-axis direction shown in FIG. 5). The right controller 4 can also be gripped in a vertically elongated direction when it is removed from the main body device 2. The housing 51 has a shape and size that can be gripped with one hand, particularly with the right hand, when gripped in a vertically elongated direction. Further, the right controller 4 can be gripped in a horizontally long direction. When the right controller 4 is gripped in a horizontally long direction, it may be gripped with both hands.

The right controller 4 includes an analog stick 52 as a direction input unit. As shown in FIG. 5, the analog stick 52 is provided on the main surface of the housing 51. By tilting the analog stick 52, the user can input a direction according to the tilting direction (and input a size corresponding to the tilted angle). Further, the right controller 4 may be provided with a cross key, a slide stick capable of slide input, or the like instead of the analog stick. Further, in the present embodiment, it is possible to input by pressing the analog stick 52.

Further, the right controller 4 includes various operation buttons. The right controller 4 includes four operation buttons 53 to 56 (specifically, A button 53, B button 54, X button 55, and Y button 56) on the main surface of the housing 51. Further, the right controller 4 includes a + (plus) button 57 and a home button 58. Further, the right controller 4 includes a first R button 60 and a ZR button 61 on the upper right side of the side surface of the housing 51. Further, the right controller 4 includes a second L button 65 and a second R button 66 on the side surface of the housing 51 on the side to be mounted when mounted on the main body device 2. These operation buttons are used to give instructions according to various programs (for example, OS programs and application programs) executed by the main unit 2.

Further, the right controller 4 includes a terminal 64 for the right controller 4 to perform wired communication with the main body device 2.

As shown in FIG. 5, the right controller 4 includes a notification LED 67. The notification LED 67 is a notification unit for notifying the user of predetermined information. The notification LED 67 is provided on the slider 62, and specifically, is provided on the mounting surface of the slider 62 (that is, the surface facing the x-axis positive direction side shown in FIG. 5). In the present embodiment, the right controller 4 includes four LEDs as notification LEDs 67. The predetermined information is, for example, information regarding a number assigned to the right controller 4 by the main body device 2 and the remaining battery level of the right controller 4.

Like the right controller 4, the left controller 3 includes an analog stick and a plurality of operation buttons. Further, the left controller 3 is provided with a terminal for performing wired communication with the main body device 2 like the right controller 4.

FIG. 6 is a block diagram showing an example of the internal configuration of the main body device 2. In addition to the configuration shown in FIG. 4, the main unit 2 includes the components 81 to 91, 97, and 98 shown in FIG. Some of these components 81-91, 97, and 98 may be mounted as electronic components on an electronic circuit board and housed in a housing 11.

The main body device 2 includes a processor 81. The processor 81 is an information processing unit that executes various types of information processing executed in the main unit 2, and may be composed of only a CPU (Central Processing Unit), a CPU function, and a GPU (Graphics Processing Unit). ) It may be composed of a SoC (System-on-a-chip) including a plurality of functions such as a function. The processor 81 executes an information processing program (for example, a game program) stored in a storage unit (specifically, an internal storage medium such as a flash memory 84 or an external storage medium installed in slot 23). By doing so, various types of information processing are executed.

The main unit 2 includes a flash memory 84 and a DRAM (Dynamic Random Access Memory) 85 as an example of an internal storage medium built therein. The flash memory 84 and the DRAM 85 are connected to the processor 81. The flash memory 84 is a memory mainly used for storing various data (which may be a program) stored in the main unit 2. The DRAM 85 is a memory used for temporarily storing various types of data used in information processing.

The main unit 2 includes a slot interface (hereinafter, abbreviated as “I / F”) 91. Slots I / F91 are connected to the processor 81. The slot I / F 91 is connected to the slot 23, and reads and writes data to a predetermined type of storage medium (for example, a dedicated memory card) mounted in the slot 23 according to the instruction of the processor 81.

The processor 81 executes the above-mentioned information processing by appropriately reading and writing data between the flash memory 84 and the DRAM 85 and each of the above-mentioned storage media.

The main body device 2 includes a controller communication unit 83. The controller communication unit 83 is connected to the processor 81. The controller communication unit 83 wirelessly communicates with the left controller 3 and / or the right controller 4. The communication method between the main unit 2 and the left controller 3 and the right controller 4 is arbitrary, but in the present embodiment, the controller communication unit 83 has Bluetooth (between the left controller 3 and the right controller 4). Communicate in accordance with the standard of (registered trademark).

Further, the display 12 is connected to the processor 81. The processor 81 displays the image generated (for example, by executing the above-mentioned information processing) and / or the image acquired from the outside on the display 12.

FIG. 7 is a block diagram showing an example of the internal configuration of the main body device 2, the left controller 3, and the right controller 4. The details of the internal configuration of the main body device 2 are shown in FIG. 6 and are omitted in FIG. 7.

The right controller 4 includes a communication control unit 111 that communicates with the main body device 2. As shown in FIG. 7, the communication control unit 111 is connected to each component including the terminal 64. In the present embodiment, the communication control unit 111 can communicate with the main body device 2 by both wired communication via the terminal 64 and wireless communication not via the terminal 64. The communication control unit 111 controls the communication method performed by the right controller 4 with respect to the main unit device 2. That is, when the right controller 4 is mounted on the main body device 2, the communication control unit 111 communicates with the main body device 2 via the terminal 64. When the right controller 4 is removed from the main body device 2, the communication control unit 111 performs wireless communication with the main body device 2 (specifically, the controller communication unit 83). Wireless communication between the controller communication unit 83 and the communication control unit 111 is performed according to, for example, a Bluetooth (registered trademark) standard.

Further, the right controller 4 includes a memory 112 such as a flash memory. The communication control unit 111 is composed of, for example, a microcomputer (also referred to as a microprocessor), and executes various processes by executing firmware stored in the memory 112.

The right controller 4 includes each button 113 (specifically, buttons 53-58, 60, 61, 65, and 66). Further, the right controller 4 includes an analog stick (described as “stick” in FIG. 7) 52. Each button 113 and the analog stick 52 repeatedly output information about the operation performed to itself to the communication control unit 111 at an appropriate timing.

The communication control unit 111 acquires information related to input (specifically, information related to operation) from each input unit (specifically, each button 113 and analog stick 52). The communication control unit 111 transmits operation data including the acquired information (or information obtained by performing predetermined processing on the acquired information) to the main unit 2. The operation data is repeatedly transmitted once at a predetermined time. The interval at which the information regarding the input is transmitted to the main body device 2 may or may not be the same for each input unit.

By transmitting the operation data to the main body device 2, the main body device 2 can obtain the input made to the right controller 4. That is, the main body device 2 can determine the operation of each button 113 and the analog stick 52 based on the operation data.

The right controller 4 includes an oscillator 117 for notifying the user by vibration. In the present embodiment, the oscillator 117 is controlled by a command from the main body device 2. That is, when the communication control unit 111 receives the above command from the main body device 2, the communication control unit 111 drives the vibrator 117 in accordance with the command. Here, the right controller 4 includes a codec unit 116. When the communication control unit 111 receives the command, the communication control unit 111 outputs a control signal corresponding to the command to the codec unit 116. The codec unit 116 generates a drive signal for driving the oscillator 117 from the control signal from the communication control unit 111 and gives it to the oscillator 117. As a result, the oscillator 117 operates.

The oscillator 117 is, more specifically, a linear vibration motor. Unlike a normal motor that rotates, the linear vibration motor is driven in a predetermined direction according to the input voltage, so that the linear vibration motor can be vibrated with an amplitude and a frequency corresponding to the waveform of the input voltage. In the present embodiment, the vibration control signal transmitted from the main body device 2 to the right controller 4 may be a digital signal representing a frequency and an amplitude for each unit time. In another embodiment, information indicating the waveform itself may be transmitted from the main unit 2, but the amount of communication data can be reduced by transmitting only the amplitude and frequency. Further, in order to further reduce the amount of data, instead of the numerical values of the amplitude and frequency at that time, only the difference from the previous value may be transmitted. In this case, the codec unit 116 converts the digital signal indicating the amplitude and frequency values acquired from the communication control unit 111 into an analog voltage waveform, and inputs the voltage according to the waveform to input the oscillator 117 to the oscillator 117. Drive. Therefore, the main body device 2 can control the amplitude and frequency at which the vibrator 117 is vibrated at that time by changing the amplitude and frequency to be transmitted for each unit time. The amplitude and frequency transmitted from the main unit 2 to the right controller 4 are not limited to one, and two or more may be transmitted. In that case, the codec unit 116 can generate a waveform of the voltage that controls the vibrator 117 by synthesizing the waveforms indicated by the plurality of received amplitudes and frequencies.

The right controller 4 includes a power supply unit 118. In this embodiment, the power supply unit 118 includes a battery and a power control circuit. Although not shown, the power control circuit is connected to the battery and is also connected to each part of the right controller 4 (specifically, each part that receives power from the battery).

Although not shown, the left controller 3 has the same configuration as that of the right controller 4 shown in FIG. 7.

[1-2. Ring-type expansion device configuration]
FIG. 8 is a diagram showing an example of a ring type expansion device. Note that FIG. 8 shows a ring-type expansion device 5 in a state where the right controller 4 is mounted. In the present embodiment, the ring type expansion device 5 is an expansion device to which the right controller 4 can be mounted. Although the details will be described later, in the present embodiment, the user performs a novel operation of applying a force to the ring-type expansion device 5 to deform it. The user can operate the ring-type expansion device 5 by performing a fitness operation using the ring-type expansion device 5 as if exercising, for example.

As shown in FIG. 8, the ring type expansion device 5 includes an annular portion 201 and a main body portion 202. The annular portion 201 has an annular shape. In the present embodiment, the annular portion 201 is formed in an annular shape by the elastic member and the pedestal portion described later. In the present embodiment, the annular portion 201 is an annular portion. In another embodiment, the shape of the annular portion 201 is arbitrary, and may be, for example, an elliptical annular shape.

The main body portion 202 is provided on the annular portion 201. The main body portion 202 has a rail portion (not shown). The rail portion is an example of a mounting portion on which the right controller 4 can be mounted. In this embodiment, the rail portion slidably engages with the slider 62 (see FIG. 5) of the right controller 4. By inserting the slider 62 in a predetermined linear direction (that is, in the sliding direction) with respect to the rail member, the rail member and the slider 62 can slide in the linear direction with respect to the rail member. Engage. The rail portion is similar to the rail portion of the main body device 2 in that it can be slidably engaged with the slider of the controller. Therefore, the rail portion may have the same configuration as the rail portion of the main body device 2.

In this embodiment, the right controller 4 has a locking portion 63 (see FIG. 5). The locking portion 63 is provided so as to project laterally (that is, in the z-axis positive direction shown in FIG. 5) from the slider 62. The locking portion 63 is movable toward the inside of the slider 62 and is urged in a direction (for example, by a spring) so as to project laterally. Further, the rail portion is provided with a notch. In a state where the slider 62 is inserted all the way into the rail portion, the locking portion 63 is locked in the notch. The right controller 4 is attached to the main body 202 by locking the locking portion 63 in the notch while the slider 62 is engaged with the rail portion.

The right controller 4 includes a release button 69 that can be pressed (see FIG. 5). The locking portion 63 moves toward the inside of the slider 62 in response to the release button 69 being pressed, and is in a state of not projecting (or hardly projecting) with respect to the slider 62. Therefore, when the release button 69 is pressed while the right controller 4 is attached to the main body 202 of the ring-type expansion device 5, the locking portion 63 is not locked (or almost locked) in the notch. Will disappear). From the above, in the state where the right controller 4 is attached to the main body 202 of the ring type expansion device 5, the user can easily remove the right controller 4 from the ring type expansion device 5 by pressing the release button 69. ..

As shown in FIG. 8, the ring type expansion device 5 has grip covers 203 and 204. The grip covers 203 and 204 are parts for the user to grip. In the present embodiment, by providing the grip covers 203 and 204, the user can easily grip the ring type expansion device 5. In the present embodiment, the left grip cover 203 is provided at a portion near the left end of the annular portion 201, and the right grip cover 204 is provided at a portion near the right end of the annular portion 201.

FIG. 9 is a block diagram showing an electrical connection relationship of the components included in the ring type expansion device 5. As shown in FIG. 9, the ring type expansion device 5 includes a strain detection unit 211. The strain detection unit 211 is an example of a detection unit that detects that the annular portion 201 is deformed. In the present embodiment, the strain detection unit 211 includes a strain gauge. The strain detection unit 211 outputs a signal indicating the strain of the pedestal portion according to the deformation of the elastic member described later (in other words, a signal indicating the magnitude of the deformation of the elastic member and the direction of the deformation).

Here, in the present embodiment, the annular portion 201 has an elastic portion that can be elastically deformed and a pedestal portion. The pedestal portion holds both ends of the elastic member so that a ring is formed by the pedestal portion and the elastic member. Since the pedestal portion is provided inside the main body portion 202, it is not shown in FIG. The pedestal portion is made of a material having higher rigidity than the elastic member. For example, the elastic member is made of resin (specifically, FRP (Fiber Reinforced Plastics)), and the pedestal portion is made of metal. The strain gauge is provided on the pedestal portion and detects the strain of the pedestal portion. When the annular portion 201 is deformed from the steady state, the pedestal portion is distorted due to the deformation, so that the strain of the pedestal portion is detected by the strain gauge. Based on the detected strain, the direction in which the annular portion 201 is deformed (that is, the direction in which the two grip covers 203 and 204 approach or separate from each other) and the amount of deformation can be calculated.

In another embodiment, the strain detecting unit 211 may include an arbitrary sensor capable of detecting that the annular portion 201 is deformed from the steady state instead of the strain gauge. For example, the detection unit 211 may include a pressure-sensitive sensor that detects the pressure applied when the annular portion 201 is deformed, or may include a bending sensor that detects the amount of bending of the annular portion 201.

The ring type expansion device 5 includes a signal conversion unit 212. In the present embodiment, the signal conversion unit 212 includes an amplifier and an AD converter. The signal conversion unit 212 is electrically connected to the distortion detection unit 211, amplifies the output signal of the distortion detection unit 211 by an amplifier, and performs AD conversion by an AD converter. The signal conversion unit 212 outputs a digital signal indicating the distortion value detected by the distortion detection unit 211. In another embodiment, the signal conversion unit 212 does not include the AD converter, and the control unit 213 described later may include the AD converter.

The ring type expansion device 5 includes a control unit 213. The control unit 213 is a processing circuit including a processor and a memory, and is, for example, an MCU (Micro Controller Unit). The control unit 213 is electrically connected to the signal conversion unit 212, and the output signal of the signal conversion unit 212 is input to the control unit 213. Further, the ring type expansion device 5 includes terminals 214. The terminal 214 is electrically connected to the control unit 213. When the right controller 4 is mounted on the ring-type expansion device 5, the control unit 213 provides information indicating the distortion value indicated by the output signal of the signal conversion unit 212 (in other words, ring operation data described later) to the terminal 214. Is transmitted to the right controller 4 via.

The ring type expansion device 5 includes a power conversion unit 215. The power conversion unit 215 is electrically connected to each of the above units 211 to 214. The power conversion unit 215 supplies electric power supplied from the outside (that is, the right controller 4) to each of the above units 211 to 214 via the terminal 214. The power conversion unit 215 may adjust the voltage or the like of the supplied electric power and supply it to each of the above units 211 to 214.

The "data related to the detection result of the distortion detection unit" transmitted by the ring type expansion device 5 to another device is the detection result (in the present embodiment, the output signal of the distortion detection unit 211 indicating the distortion of the pedestal unit). ) Itself, or data obtained by performing some processing (for example, data format conversion and / or calculation processing on the distortion value) on the detection result. May be good. For example, the control unit 213 may perform a process of calculating the deformation amount of the elastic member based on the strain value which is the detection result. At this time, the “data regarding the detection result of the strain detection unit” is the deformation amount. It may be the data which shows.

In another embodiment, the ring type expansion device 5 may include a battery and operate by the electric power of the battery. Further, the battery included in the ring type expansion device 5 may be a rechargeable battery that can be charged by the electric power supplied from the right controller 4.

FIG. 10 is a diagram showing an example of how the user uses the ring type expansion device 5. As shown in FIG. 10, the user can play a game by using the ring type expansion device 5 in addition to the game device (that is, the main body device 2 and the respective controllers 3 and 4).

For example, as shown in FIG. 10, the user holds the ring-type expansion device 5 equipped with the right controller 4 with both hands. At this time, the user can play the game by operating the ring-type expansion device 5 (for example, an operation of deforming the ring-type expansion device 5 and an operation of moving the ring-type expansion device 5).

Note that FIG. 10 illustrates a state in which the user grips the grip covers 203 and 204 and pushes the ring-type expansion device 5 to deform the grip covers 203 and 204. By this movement, the user can perform a fitness movement for training both arms as a game operation. The user can operate the game by various operations on the ring type expansion device 5. For example, the user can perform an operation of deforming the ring type expansion device 5 while holding one grip cover with both hands and touching the other grip cover to the abdomen. With this movement, the user can perform a fitness movement for training the arms and abdominal muscles as a game operation. In addition, the user can also perform an operation of deforming the ring-type expansion device 5 in a state where the grip covers 203 and 204 are applied to the inner thighs of both feet and the ring-type expansion device 5 is sandwiched between the legs. By this movement, the user can perform a fitness movement for training the muscles of the foot as a game operation. As described above, according to the present embodiment, the user can perform many kinds of fitness movements by using the ring-shaped expansion device 5 which is an annular shape.

[2. Overview of vibration control processing]
Next, a process of controlling the vibration of the vibrator 117 of the right controller 4 will be described. In the present embodiment, the oscillator 117 is controlled not only by a command from the main body device 2 as described above, but also by a command (vibration information described later) from the ring type expansion device 5. Hereinafter, a process in which the ring type expansion device 5 controls the vibration of the vibrator 117 will be described with reference to FIGS. 11 to 16.

FIG. 11 is a block diagram showing a functional configuration of the ring type expansion device 5 and the right controller 4 relating to the vibration control of the vibrator 117. In the present embodiment, the main body device 2 is not related to the process in which the ring type expansion device 5 vibrates the vibrator 117. Here, in the present embodiment, the right controller 4 and the ring-type expansion device 5 to which the right controller 4 is mounted can operate in an independent operation mode in which processing is executed independently of the main body device 2. In the independent operation mode, the right controller 4 operates without communicating with the main body device 2. In the present embodiment, the process of vibrating the vibrator 117 by the ring-type expansion device 5 is executed in the independent operation mode. However, in another embodiment, the process of vibrating the vibrator 117 by the ring type expansion device 5 may be executed in a mode different from the independent operation mode, and the right controller 4 and the main body device 2 communicate with each other. It may be executed in mode.

As shown in FIG. 11, the ring-type expansion device 5 includes a function storage unit 301, a variable determination unit 302, and a generation unit 303. In the present embodiment, the function storage unit 301 is realized by the memory of the control unit 213. The variable determination unit 302 and the generation unit 303 are realized by the control unit 213. Further, as shown in FIG. 11, the right controller 4 includes a vibration control unit 304 in addition to the above-mentioned oscillator 117. In the present embodiment, the vibration control unit 304 is realized by the communication control unit 111 and the codec unit 116.

The function storage unit 301 stores a function indicating a model of the vibration pattern of the vibrator 117 (hereinafter, referred to as a “vibration model”). Here, the vibration pattern is a convenient concept that refers to a specific transition of an amplitude value and / or a frequency value in a certain period (see FIGS. 15 and 17). Further, in the vibration model, the above vibration pattern is defined by setting specific values of amplitude and frequency for the vibration model. The vibration model shows a generalization of vibration patterns that differ in specific values of duration, amplitude, and / or frequency, but have a common tendency of amplitude and / or frequency transition (see FIGS. 12 and 13). ..

FIG. 12 is a diagram showing an example of the first vibration model used in the present embodiment. The first vibration model shown in FIG. 12 does not generate vibration during the period from the start time until the time t1 elapses, and the period from the time t1 elapses until the time t2 elapses has an amplitude a1. Moreover, a model of a vibration pattern that vibrates at a frequency f1 is shown. In the first vibration model, the amplitude a1, the time t1, the time t2, and the frequency f1 are variables. The first vibration model shows the tendency of the amplitude and frequency of vibration to change as described above, and by setting specific values for the above four variables, a specific vibration pattern is determined. It will be.

The first vibration model includes a variable indicating frequency and a variable indicating amplitude. Therefore, the first vibration model can be represented by the function F (t) of the time change of the frequency and the function A (t) of the time change of the amplitude as shown in the following equations (1) and (2). it can.
F (t) = 0 (0 ≦ t <t1), F (t) = f1 (t1 ≦ t <t2) ... (1)
A (t) = 0 (0 ≦ t <t1), A (t) = a1 (t1 ≦ t <t2) ... (2)
In the present embodiment, the frequency of vibration in a state where vibration is not generated (that is, the amplitude is 0) is represented by "0". In the present embodiment, as in F (t) above, a function indicating a vibration model and a function of changing the frequency with time is called a frequency model function. The frequency model function is a variable indicating the frequency of a certain period in the vibration model (hereinafter referred to as a frequency variable; here, variable f1) and a variable related to the period (hereinafter referred to as a period variable; here, variables t1 and t2). It is a function that uses and as a variable. The frequency variable is a variable that determines the variable that is the output of the function (that is, the above F (t)), and is not the variable that is the output of the function itself. Further, the variable related to the period is a variable that can specify the period, and means, for example, a variable indicating the start time point, the end time point, or the length of the period. In the present embodiment, the variables t1 and t2, which are period variables, are variables indicating the length of time, but the period variables are variables indicating a certain time point (that is, the elapsed time from the start time point) in the vibration model. There may be.

Further, in the present embodiment, as in A (t) above, a function indicating a vibration model and a function of time-varying amplitude is referred to as an amplitude model function. The amplitude model function is a function in which a variable indicating the amplitude at a certain time point in the vibration model (hereinafter, referred to as an amplitude variable; here, variable a1) and the above-mentioned period variable are variables. In the present embodiment, the amplitude model function uses an amplitude variable and a period variable (here, variables t1 and t2) relating to the period corresponding to the amplitude indicated by the amplitude variable as variables. However, in other embodiments, the amplitude model function may not have a period variable as a variable. For example, the amplitude model function may be a function in which only the amplitude variable indicating the amplitude in the entire period of the vibration pattern is used as a variable.

FIG. 13 is a diagram showing an example of a second vibration model used in the present embodiment. The second vibration model shown in FIG. 13 shows a model of a vibration pattern in which the amplitude and frequency change as shown in (a) to (c) below.
(A) No vibration is generated during the period from the start time to the lapse of time t4.
(B) During the period from the time when the time t4 elapses to the time when the time t5 elapses, vibration is performed with a constant amplitude a2 and a frequency f2.
(C) In the period from the time when the time t5 elapses to the time when the time t6 elapses, the amplitude decreases from a2 to 0 (specifically, it decreases in a decrease mode in which the amount of decrease per unit time is constant). And, the vibration is performed at the frequency f2.
The time t4, t5 and t6, the frequency f2 and the amplitude a1 are variables, respectively. Similar to the first vibration model, the second vibration model shows the tendency of the amplitude and frequency of vibration to change, and the specific vibration pattern is determined by setting specific values in the above variables. Will be done. Similar to the first vibration model, the second vibration model described above is also indicated by a frequency model function and an amplitude model function. According to the second vibration model, for example, by setting the variable t6 to 0, the amplitude becomes constant as in the first vibration model (for example, the pattern BD shown in FIG. 17). It is also possible to specify, and by setting the variable t5 to 0, it is also possible to specify a vibration pattern in which the amplitude decreases (for example, pattern A shown in FIG. 17).

In the present embodiment, the function storage unit 301 stores a frequency model function and an amplitude model function as functions indicating the vibration model. Specifically, in the present embodiment, the first and second vibration models are used, and the function storage unit 301 includes a frequency model function and an amplitude model function indicating the first vibration model, and a second vibration model function. The frequency model function and the amplitude model function indicating the vibration model of the above are stored.

As described above, in the present embodiment, the game system 1 stores a model of a vibration pattern (that is, a vibration model) that vibrates the vibrator 117. Here, assuming that data showing the vibration waveform itself that vibrates the vibrator 117 is stored, when the vibrator 117 is vibrated by a plurality of types of vibration patterns, the game system 1 has data for each vibration pattern. Must be memorized, and the amount of data increases as the types of vibration patterns increase. On the other hand, in the present embodiment, the game system 1 stores a vibration model and generates a vibration waveform using the vibration model (details will be described later). According to this, the amount of data in the game system 1 can be reduced as compared with the case where the vibration waveform data is stored.

In another embodiment, the vibration model may be one of either a frequency model function or an amplitude model function. For example, in other embodiments, a vibration model in which the amplitude a1 in the first vibration model is a fixed value may be used. This vibration model does not include amplitude variables and can only be shown by the frequency model function. Therefore, for such a vibration model, the function storage unit 301 need only store the frequency model function. Further, the function storage unit 301 may store only the amplitude model function for the vibration model that does not include the frequency variable.

Further, the number of vibration models (specifically, frequency model function and amplitude model function) stored in the game system 1 is arbitrary, and the function storage unit 301 may store only one vibration model. Three or more vibration models may be stored.

In the present embodiment, the frequency model function and the amplitude model function are functions in which the time length of the vibration pattern is determined by applying the period variable to the frequency model function. For example, for the first vibration model, the time length of the vibration pattern is determined to be (t1 + t2) by determining the period variables t1 and t2. Further, for the second vibration model, the time length of the vibration pattern is determined to be (t4 + t5 + t6) by determining the period variables t4 to t6. Here, according to the method of storing the data showing the vibration waveform itself that vibrates the vibrator 117, the amount of data increases as the time of the vibration waveform becomes longer. Therefore, depending on the capacity of the storage device, the vibration takes a long time. It may not be possible to memorize the waveform. On the other hand, in the present embodiment, the amount of data of the vibration model (that is, the frequency model function and the amplitude model function) does not substantially change even if the vibration pattern time becomes long, so that the game system 1 stores the data. It is possible to generate a vibration pattern with a long time regardless of the capacity of the device.

In another embodiment, the vibration model represented by the frequency model function and the amplitude model function may have a fixed time length of the vibration pattern (that is, it does not change depending on the period variable). For example, in the vibration model shown in FIG. 12, the time length (t1 + t2) of the vibration pattern may be fixed to a predetermined value. At this time, the period variables t1 and t2 can be set under the condition that (t1 + t2) is constant.

The variable determination unit 302 shown in FIG. 11 determines the value of the variable in the vibration model. In the present embodiment, the variable determination unit 302 determines the value of the variable according to the satisfied condition according to the condition that the predetermined vibration condition is satisfied. The vibration condition is a condition for causing the vibrator 117 to vibrate. Here, in the present embodiment, the ring-type expansion device 5 detects a pushing operation or a pulling operation on the ring-type expansion device 5 and counts the number of operations. The pushing operation is an operation of deforming the annular portion 201 in the direction in which the two grip covers 203 and 204 of the ring type expansion device 5 approach each other. Further, the pulling operation is an operation of deforming the annular portion 201 in the direction in which the two grip covers 203 and 204 are separated from each other. The first vibration condition is that the number of operations is a predetermined number of divisions (for example, 100, 200, 300, 400 times). The second vibration condition is that the number of operations is the upper limit (for example, 500 times). In the present embodiment, the variable determination unit 302 determines the value according to the satisfied condition according to the condition that the first vibration condition or the second vibration condition is satisfied. As a result, the vibrator 117 vibrates in a vibration pattern corresponding to the satisfied conditions according to the satisfied conditions (details will be described later).

The vibration conditions are arbitrary, and other conditions may be used in other embodiments. For example, the vibration condition may be that the pushing operation or the pulling operation is detected, or that an operation for a predetermined button of the right controller 4 is detected.

In the present embodiment, when the vibration condition is satisfied, the variable determination unit 302 determines the vibration model to be used and the value of the variable based on the corresponding information. FIG. 14 is a diagram showing an example of correspondence information. As shown in FIG. 14, the corresponding information shows the correspondence between the vibration condition, the vibration model used when the vibration condition is satisfied, and the value of each variable used when the vibration condition is satisfied. The variable determination unit 302 stores the correspondence information, and when the vibration condition is satisfied, the variable determination unit 302 determines the vibration model to be used and the value of the variable by referring to the correspondence information.

In the present embodiment, the variable determination unit 302 determines the variable so that when the first vibration condition is satisfied, the vibration of the vibration pattern defined by using the first vibration model is performed. Since the first vibration model includes four variables a1, f1, t1, and t2, in the above case, the variable determination unit 302 determines the values of these four variables. Similarly, when the second vibration condition is satisfied, the variable determination unit 302 applies the second vibration model to the second vibration model so that the vibration of the vibration pattern defined by the second vibration model is performed. Each included variable (specifically, variables a2, f2, t4, t5, t6) is determined. As shown in FIG. 14, when one vibration condition is satisfied, the variable determination unit 302 sets a plurality of sets of the vibration model and the value of each variable (in the example shown in FIG. 14, four sets). ) May be decided. Further, in the example shown in FIG. 14, one type of vibration model is used when one vibration condition is satisfied, but in other embodiments, a plurality of vibration models are used when one vibration condition is satisfied. A type of vibration model may be used. For example, when a certain vibration condition is satisfied, the variable determination unit 302 sets the first vibration model and the value of each variable corresponding thereto, and the second vibration model and the value of each variable corresponding thereto. You may decide each pair with.

In another embodiment, the ring-type expansion device 5 may be configured to include a variable storage unit that stores the values of variables to be applied to the vibration model. At this time, when the vibration condition is satisfied, the variable determination unit 302 determines a function according to the vibration condition from the functions stored in the function storage unit 301, and the value of the variable stored in the variable storage unit. Determine the value to be applied to the function from among them. In the present embodiment, the variable determination unit 302 stores the above-mentioned correspondence information, and it can be said that the value of the variable to be applied to the function of the vibration model is stored. It can also be said that it also serves as a variable storage unit that stores values.

In another embodiment, the ring type expansion device 5 does not need to store the values of the above variables in advance. In another embodiment, the variable determination unit 302 may calculate the value of the variable by calculation, or may, for example, calculate the value of the frequency variable from the number of operations. At this time, the variable determination unit 302 may store in advance a calculation formula for calculating the value of the frequency variable from the number of operations, and calculate the value of the variable when the vibration condition is satisfied.

When the variable determination unit 302 determines the vibration model and the value of the variable as described above, the function specification information for specifying the determined vibration model (that is, the frequency model function and / or the amplitude model function) and the determined variable The variable information indicating the value of is passed to the generation unit 303.

The generation unit 303 generates vibration information based on the function stored in the function storage unit 301 and the value of the variable determined by the variable determination unit 302. Specifically, the generation unit 303 uses the time change of the frequency obtained by applying (that is, substituting) the value of the determined variable to the frequency model function, and the value of the determined variable into the amplitude model function. Generates vibration information that indicates the vibration pattern defined by the time variation of the amplitude obtained by application. The frequency model function and the amplitude model function used to generate the vibration information are functions indicated by the function designation information sent from the variable determination unit 302. The generation unit 303 passes the generated vibration information to the vibration control unit 304.

As described above, in the present embodiment, the function storage unit 301 stores a plurality of types of frequency model functions showing time-varying vibration models (that is, first and second vibration models) having different frequencies from each other. The variable determination unit 302 determines the function specification information that specifies one of the plurality of types of frequency model functions. The generation unit 303 applies the determined value of the frequency variable and the determined value of the period variable to the frequency model function specified by the function specification information, and the vibration defined by the time change of the frequency obtained. Generate vibration information showing the pattern. Therefore, according to the present embodiment, by using a plurality of vibration models, the game system 1 can vibrate the vibrator 117 in various vibration patterns while suppressing the amount of data.

Further, when there are a plurality of sets of the vibration model and the value of the variable, a plurality of vibration patterns corresponding to each set are defined. In this case, the generation unit 303 generates vibration information indicating an integrated vibration pattern in which a plurality of vibration patterns are integrated into one, if necessary.

FIG. 15 is a diagram showing an example of an integrated vibration pattern in which a plurality of vibration patterns are integrated. FIG. 15 shows an example of integrating four vibration patterns defined when the first vibration condition is satisfied into one integrated vibration pattern. In the example shown in FIG. 15, four vibration patterns A to D are defined based on the variable information indicating the four sets of variables sent from the variable determination unit 302. At this time, the generation unit 303 generates vibration information indicating one integrated vibration pattern in which the four vibration patterns A to D are integrated, and passes the vibration information to the vibration control unit 304. Then, the vibration control unit 304 instructs the vibration pattern of the vibrator 117 based on the passed vibration information.

The method of integrating a plurality of vibration patterns into one integrated vibration pattern is arbitrary. In the present embodiment, as shown in FIG. 15, the generation unit 303 integrates by adding a plurality of vibration patterns whose vibration generation periods do not overlap each other. Therefore, the generation unit 303 can easily integrate a plurality of vibration patterns. In another embodiment, the generation unit 303 may integrate a plurality of vibration patterns whose vibration generation periods do not overlap with each other by adding appropriate calculations. Further, in another embodiment, the generation unit 303 may integrate a plurality of vibration patterns in which vibration generation periods overlap with each other. At this time, for example, in the period in which the periods in which vibrations occur overlap each other, the generation unit 303 sets the frequency in the integrated vibration pattern as the average value of the frequencies of the overlapping vibrations, and sets the amplitude in the integrated vibration pattern as the overlapping vibrations. It may be the total value (or the average value) of the amplitudes of.

Further, as described above, in the present embodiment, the generation unit 303 generates vibration information indicating one integrated vibration pattern obtained by integrating a plurality of vibration patterns based on one frequency model function. According to this, the game system 1 can vibrate the vibrator 117 with a more complicated vibration pattern by integrating a plurality of vibration patterns obtained from one vibration model. For example, in the example shown in FIG. 15, the first vibration model can be used to vibrate the vibrator 117 in a complicated vibration pattern in which four vibrations are generated while gradually increasing the frequency. That is, if the function storage unit 301 stores the first vibration model in which one vibration occurs, it is not necessary to separately store the vibration model in which vibrations having the same tendency occur four times.

Here, in the present embodiment, as the period variable, the vibration model uses start variables (variables t1 and t4 described above) indicating the time from the start time to the start of vibration in the time change model indicated by the frequency model function. Including. Thereby, the game system 1 can adjust the time point at which the vibration is started in the vibration pattern.

Further, in the present embodiment, since the start variable is used when integrating a plurality of vibration patterns, the game system 1 starts vibration in one vibration pattern by appropriately adjusting the start variable. It is possible to set the interval between the time point and the time point when vibration is started in another vibration pattern. For example, in the example shown in FIG. 15, by setting the variable t1 in the four vibration patterns to the interval of 75 [ms], the interval at which the four vibrations are started can be easily aligned. Here, in the case of vibrating the vibrator 117 with the four vibration patterns shown in FIG. 15, if vibration information is individually generated and transmitted for each of the four vibration patterns, the generation unit 303 vibrates one vibration. The timing of transmitting the vibration information indicating the pattern to the vibration control unit 304 and the timing of transmitting the vibration information indicating the next vibration pattern to the vibration control unit 304 are adjusted, and the processing of generating and transmitting the vibration information is performed. It may be complicated. On the other hand, in the present embodiment, by using the above start variable when integrating a plurality of vibration patterns, it is possible to easily adjust the interval at the start time of vibration in the plurality of vibration patterns.

In the present embodiment, the generation unit 303 generates a plurality of unit vibration information for each predetermined period (specifically, one frame period (for example, 10 [ms])) as vibration information indicating the vibration pattern. Specifically, the generation unit 303 generates unit vibration information indicating a vibration pattern in the frame period at a rate of once in one frame period, and vibrates the unit vibration information each time the unit vibration information is generated. It is passed to the control unit 304. In the present embodiment, since the generation unit 303 is provided in the ring type expansion device 5 and the vibration control unit 304 is provided in the right controller 4, the unit vibration information is transmitted from the ring type expansion device 5 to the right via the terminal 214. It is transmitted to the controller 4. Although details will be described later, the generation unit 303 may transmit two unit vibration information showing different vibration patterns to the vibration control unit 304 in one frame period.

FIG. 16 is a diagram showing an example of a method of generating unit vibration information. In the example shown in FIG. 16, the vibration pattern in the frame period p1 to p10 from the start time is shown. In the present embodiment, the generation unit 303 generates unit vibration information for each frame period. Here, the generation unit 303 generates information indicating the amplitude and frequency of a portion of the vibration pattern in the frame period as unit vibration information indicating the vibration pattern in a certain frame period. For example, in the example shown in FIG. 16, in the period p1, the generation unit 303 generates unit vibration information indicating that the amplitude is 0 and the frequency is 0. Further, in the period p6, the generation unit 303 generates unit vibration information indicating that the amplitude is 1 and the frequency is 523.

As described above, in the present embodiment, the generation unit 303 does not generate the vibration information indicating the entire vibration pattern at once, but repeatedly generates the unit vibration information indicating the vibration pattern for one frame period. Generates vibration information that shows the entire vibration pattern. That is, the unit vibration information is repeatedly generated during the period in which the vibration pattern is defined, and the generated plurality of unit vibration information (in other words, the vibration information composed of the plurality of unit vibration information) indicates the vibration pattern. .. Further, it can be said that the generation unit 303 divides the vibration information indicating the vibration pattern into unit vibration information and transmits it to the vibration control unit 304.

As described above, the generation unit 303 generates the unit vibration information once in a predetermined unit period (that is, the frame period). When the generation unit 303 generates the unit vibration information in a certain unit period, the generation unit 303 generates the unit vibration information indicating the portion of the vibration pattern in the unit period. According to this, it is possible to reduce the amount of vibration information data per unit time regardless of the length of the generated vibration pattern.

Further, the vibration information (and unit vibration information) in the present embodiment includes information on the amplitude and frequency of the vibration pattern. Here, in other embodiments, the vibration information may include other information. For example, in the present embodiment, the vibration control unit 304 vibrates the vibrator 117 with a sine wave vibration waveform, but in other embodiments, the vibration control unit 304 has a plurality of types of basic waveforms (for example, , Sine wave and triangular wave) may be able to vibrate the oscillator 117. At this time, the generation unit 303 may specify the basic waveform that vibrates the vibrator 117. That is, the generation unit 303 may generate vibration information including information indicating the basic waveform.

The vibration control unit 304 controls the vibration of the vibrator 117 based on the vibration information sent from the generation unit 303. That is, the vibration control unit 304 vibrates the vibrator 117 in the vibration pattern indicated by the unit vibration information sent from the generation unit 303. Specifically, the vibration control unit 304 gives the vibrator 117 a drive signal showing a vibration waveform defined by the vibration pattern indicated by the unit vibration information. In the present embodiment, the drive signal is an electric signal that vibrates the vibrator 117 with a sinusoidal vibration waveform having an amplitude and a frequency indicated by unit vibration information.

The vibration control unit 304 receives unit vibration information from the generation unit 303 every frame period, and vibrates the vibrator 117 based on the received unit vibration information. Here, if the amplitude and / or frequency suddenly changes at the boundary between a certain frame period and the next frame period, noise may be generated or the user may feel uncomfortable. Therefore, the vibration control unit 304 performs interpolation processing so that the amplitude and / or frequency continuously changes at the boundary of the frame period, and vibrates the vibrator 117 with a vibration waveform having the amplitude and frequency after the interpolation processing. It may be. For example, when the amplitude and frequency change from one frame period to the next, the vibration control unit 304 continuously adjusts the amplitude and frequency so as to gradually approach the amplitude and frequency indicated by the unit vibration information in the next frame period. A drive signal whose frequency changes may be generated.

As described above, in the present embodiment, the generation unit 303 can transmit two unit vibration information to the vibration control unit 304 in one frame period. When two unit vibration information is transmitted, the vibration control unit 304 vibrates the vibrator 117 with a vibration waveform obtained by synthesizing the two vibration waveforms indicated by the two unit vibration information. Specifically, the vibration control unit 304 generates a drive signal corresponding to the vibration waveform obtained by synthesizing the two vibration waveforms and gives the drive signal to the vibrator 117. As described above, in the present embodiment, the game system 1 can vibrate the vibrator 117 with a vibration waveform obtained by synthesizing two types of vibration waveforms having different frequencies.

FIG. 17 is a diagram showing an example of vibrating an oscillator based on vibration information showing two vibration patterns. In the present embodiment, when the second vibration condition is satisfied, the variable determination unit 302 includes function designation information for designating a function indicating the second vibration model, and patterns A to D 4 shown in FIG. Four sets of variable information representing one vibration pattern are passed to the generation unit 303. At this time, four vibration patterns A to D are defined based on the frequency model function and the amplitude model function indicating the second vibration model and the four sets of variable information. Here, the vibration pattern A assumes that the period in which the vibration occurs overlaps with the other three vibration patterns B to D, and the vibration patterns B to D assume that the periods in which the vibration occurs do not overlap with each other (see FIG. 17). ). Further, it is assumed that the frequencies of the vibration patterns A to D are 160 [Hz], 587 [Hz], 659 [Hz], and 698 [Hz], respectively.

As described above, in the present embodiment, the vibration control unit 304 can synthesize two vibration waveforms indicated by the two unit vibration information, while based on the variable determined by the variable determination unit 302. Three or more vibration patterns may be defined (FIG. 17). In this case, the generation unit 303 integrates some of the three or more vibration patterns to generate vibration information indicating the two vibration patterns. In the example shown in FIG. 17, as a result of integrating the four vibration patterns A to D, two vibration informations showing the two vibration patterns are generated, but in other embodiments, the result of the integration is One vibration information indicating one vibration pattern may be generated.

In the present embodiment, the generation unit 303 generates vibration information indicating an integrated vibration pattern in which vibration patterns whose vibration generation periods do not overlap each other are integrated among the above three or more vibration patterns. In the example shown in FIG. 17, the generation unit 303 generates vibration information indicating one integrated vibration pattern in which vibration patterns B to D whose vibration generation periods do not overlap each other are integrated (second shown in FIG. 17). Vibration pattern). Further, with respect to the vibration pattern A, since the period in which the vibration is generated overlaps with the vibration patterns B to D, the generation unit 303 generates the vibration information indicating the vibration pattern A as it is without integrating the vibration pattern A. (See the first vibration pattern shown in FIG. 17). The generation unit 303 transmits two unit vibration information corresponding to the above two vibration information to the vibration control unit 304. The vibration control unit 304 that has received the above two unit vibration information vibrates the vibrator 117 with a vibration waveform that combines two vibration waveforms based on the two unit vibration information (see the vibration pattern of the composite waveform shown in FIG. 17). ..

The method of determining which vibration pattern to integrate among the three or more vibration patterns is arbitrary. For example, when a set of vibration patterns whose vibration generation periods do not overlap each other is known among the three or more vibration patterns, the vibration patterns included in the set may be integrated into one. Further, for a plurality of vibration patterns whose frequencies are equal to or higher than a predetermined threshold, the periods in which vibrations occur do not overlap each other, and for a plurality of vibration patterns whose frequencies are less than a predetermined threshold, the periods in which vibrations occur are mutual. If they do not overlap (that is, if the variables are determined so that such vibration patterns are defined), the vibration patterns whose frequencies are above the threshold are integrated and the frequencies are below the threshold. They may be integrated with each other. For example, in the example shown in FIG. 17, the frequency of the vibration pattern A is 160 [Hz], and the frequencies of the vibration patterns B to D are 587 to 698 [Hz], which is larger than 160 [Hz] and 587 [Hz]. A threshold value smaller than [Hz] (for example, 320 [Hz]) may be set. At this time, since the four vibration patterns A to D can be divided into a group having a frequency less than the threshold value and a group having a frequency equal to or higher than the threshold value, the generation unit 303 integrates the vibration patterns included in the group. Vibration information indicating the pattern may be generated.

As described above, in the present embodiment, the vibrator 117 can vibrate with a waveform obtained by synthesizing each vibration waveform corresponding to the vibration information of the first predetermined number (here, 2) which is 2 or more. The variable determination unit 302 determines a set of a second predetermined number (4 in the example shown in FIG. 17) larger than the first predetermined number as a set of the value of the frequency variable and the value of the period variable. At this time, the generation unit 303 integrates two or more vibration patterns out of the second predetermined number of vibration patterns based on the determined set into one vibration pattern, so that the first predetermined number of vibration patterns are combined. A first predetermined number of vibration information indicating the above is generated. According to the above, regardless of the number of vibration patterns defined according to the set of variables determined by the variable determination unit 302, the vibration information of the number (that is, the first predetermined number) that the oscillator 117 can handle is obtained. Can be generated.

Further, in the present embodiment, the generation unit 303 generates vibration information indicating one vibration pattern obtained by integrating a plurality of vibration patterns whose vibration generation periods do not overlap with each other among the plurality of vibration patterns. .. This facilitates the computational process of integrating the vibration patterns.

[3. Specific example of vibration control processing]
Next, a specific example of the vibration control process will be described. FIG. 18 is a flowchart showing an example of vibration control processing executed by the ring type expansion device 5. In the present embodiment, the series of vibration control processes shown in FIG. 18 is started in response to the start of the above-mentioned independent operation mode.

In the present embodiment, the processor of the control unit 213 of the ring-type expansion device 5 executes the processing of each step shown in FIG. 18 by executing the program stored in the memory included in the control unit 213. explain. However, in another embodiment, a processor (for example, a dedicated circuit or the like) different from the processor of the controller unit 213 may execute a part of the processes of each of the above steps. The processor of the right controller 4 (for example, the communication control unit 111) may execute the execution. Further, the processing of each step shown in FIG. 18 (the same applies to FIG. 20 described later) is merely an example, and the processing order of each step may be changed as long as the same result can be obtained. , In addition to (or instead of) the processing of each step, another processing may be executed.

Further, the control unit 213 executes the processing of each step shown in FIG. 18 by using the memory. That is, the control unit 213 stores the information (in other words, data) obtained by each processing step in the memory, and when the information is used in the subsequent processing steps, the information is read from the memory and used. ..

When the vibration control process is started, the processor repeatedly executes the series of processes of steps S1 to S6 once in one frame period.

In step S1, the processor determines whether any of the above vibration conditions are met. In the present embodiment, the determination in step S1 can be performed based on the number of operations for the ring-type expansion device 5. Here, the processor calculates the amount of deformation of the ring-type expansion device 5 based on the distortion value output from the strain detection unit 211, and detects a pushing operation or a pulling operation based on the amount of deformation. Specifically, the training device detects the pushing operation when the deformation amount in the pushing direction becomes larger than the predetermined pushing threshold value, and pulls when the deformation amount in the pulling direction becomes larger than the predetermined pulling threshold value. Detect the operation. Further, the processor counts so as to increase the number of operations by 1 each time a pushing operation or a pulling operation is detected. Then, when the number of operations reaches the above-mentioned number of divisions (that is, when the number of operations becomes equal to the number of divisions), the processor determines that the first vibration condition is satisfied. Further, when the number of operations reaches the above upper limit number (that is, when the number of operations becomes equal to the upper limit number of times), the processor determines that the second vibration condition is satisfied. It should be noted that the vibration condition is determined to be satisfied in step S1 when the number of operations is increased from the previous step S1 and the number of divisions or the upper limit is equal to the number of divisions. If the number of operations has not increased since the previous determination in step S1, the determination result in step S1 is negative because the vibration condition has already been satisfied even if the number of operations is equal to the number of divisions or the upper limit. .. If the determination result in step S1 is affirmative, the process in step S2 is executed. On the other hand, if the determination result in step S1 is negative, the processes in steps S2 to S4 are skipped, and the process in step S5 described later is executed.

In step S2, the processor determines the vibration model based on the conditions satisfied in step S1. As mentioned above, the vibration model is determined by reference to the corresponding information. After step S2, the process of step S3 is executed.

In step S3, the processor determines the value of the variable based on the conditions satisfied in step S1. As mentioned above, the value of the variable is determined by referring to the correspondence information. After step S3, the process of step S4 is executed.

In step S4, the processor determines a vibration pattern defined based on the function indicating the vibration model determined in step S2 (that is, the frequency model function and the amplitude model function) and the values of the variables determined in step S3. Generates the vibration information shown. The vibration information is generated according to the method described in "[2. Outline of vibration control processing]" above. Specifically, the processor generates unit vibration information in the current frame period for the vibration pattern. That is, the processor generates unit vibration information indicating the amplitude and frequency of the portion of the vibration pattern in the current frame period. If there is no vibration pattern corresponding to the current frame period, the processor may or may not generate unit vibration information indicating that the amplitude and frequency are 0. Good. Further, in step S4, the processor may generate two unit vibration information as described above. After step S4, the process of step S5 is executed.

In step S5, the processor transmits the unit vibration information generated in step S4 to the right controller 4. In response to this, the right controller 4 that has received the vibration information vibrates the vibrator 117 based on the vibration information. By repeatedly executing the process of step S5 every one frame period, the vibrator 117 vibrates in the vibration pattern indicated by the vibration information generated in step S4. After step S5, the process of step S6 is executed.

In step S6, the processor determines whether or not to end the vibration control process. For example, the processor determines whether or not a user input indicating an instruction to end the independent operation mode has been detected. If the determination result in step S6 is affirmative, the processor ends the vibration control process. On the other hand, if the determination result in step S6 is negative, the process in step S1 is executed again. After that, the processor repeatedly executes a series of processes of steps S1 to S6 until the determination result of step S6 becomes affirmative.

[4. Action effect and modification example of this embodiment]
In the above embodiment, the information processing system (specifically, the game system 1) including the oscillator 117 has the following configuration.
-A function storage unit 301 that shows a model of time change with respect to the frequency of vibration and stores a frequency model function having a frequency variable indicating the frequency of a certain period in the model and a period variable related to the period as variables.
-Variable determination unit 302 that determines the value of the frequency variable and the value of the period variable
-Generation unit 303 that generates vibration information indicating a vibration pattern defined by the time change of the frequency obtained by applying the determined value of the frequency variable and the value of the determined period variable to the frequency model function.
-Vibration control unit 304 that controls the vibration of the vibrator 117 based on the vibration information.
According to the above configuration, the game system 1 can generate vibration information using the frequency model by storing the frequency model function. According to this, when the vibrator 117 is vibrated by a plurality of types of vibration patterns, it is used for controlling the vibrator 117 as compared with the method of storing the vibration waveform data for vibrating the vibrator 117. The amount of data can be reduced.

Further, in the above embodiment, the function storage unit 301 shows a model of time change with respect to the amplitude of vibration, and further stores an amplitude model function having an amplitude variable indicating the amplitude of vibration as a variable. The variable determination unit 302 further determines the value of the amplitude variable. The generation unit 303 applies the determined frequency variable value and the determined period variable value to the frequency model function to obtain the time change of the frequency and the determined amplitude variable value to the amplitude model function. Generates vibration information that indicates the vibration pattern defined by the time variation of the amplitude obtained by applying to. According to this, the information processing system can generate vibration patterns having different amplitudes in addition to the frequency from one vibration model, and can vibrate the vibrator 117 with more various vibration patterns.

In the above embodiment, the information processing system includes a first device (specifically, the right controller 4) including an oscillator and a second device (specifically, a ring) that communicates with the first device. Includes type expansion device 5). The second device includes a function storage unit 301, a variable determination unit 302, a generation unit 303, and a transmission unit (specifically, a control unit 213 that executes step S6) that transmits vibration information to the first device. Be prepared. The first device controls the vibration of the vibrator based on the receiving unit (specifically, the terminal 64 and the communication control unit 111) that receives the vibration information from the second device and the vibration information received by the receiving unit. It is provided with a vibration control unit 304. According to the above configuration, the amount of data used for controlling the oscillator in the second device can be reduced. According to this, since it is not necessary for the second device to include a storage device having a large storage capacity, the manufacturing cost of the second device can be reduced.

(Modification example in which the oscillator 117 is controlled by the main body device 2)
In the above embodiment, the case where the ring type expansion device 5 controls the vibrator 117 of the right controller 4 by the vibration pattern using the vibration model has been described as an example, but in other embodiments, the vibration model is used. The main body device 2 may control the vibrator 117 by a vibration pattern. Hereinafter, as a modification of the above embodiment, an example in which the main body device 2 controls the vibrator 117 will be described.

FIG. 19 is a block diagram showing a functional configuration of the main body device 2 and the right controller 4 regarding vibration control of the vibrator 117. In this modification, an example in which the main body device 2 wirelessly communicates with the right controller 4 and vibrates the vibrator 117 of the right controller 4 will be described. In this modification, the ring-type expansion device 5 is not related to the process of vibrating the vibrator 117, so that the right controller 4 does not need to be mounted on the ring-type expansion device 5.

As shown in FIG. 19, the main body device 2 includes a variable determination unit 311. Further, the right controller 4 includes a function storage unit 312, a generation unit 313, and the vibration control unit 304 and the vibrator 117 described above. The variable determination unit 311 is realized by, for example, the processor 81 and the DRAM 85. Further, the function storage unit 312 is realized by, for example, the memory 112, and the generation unit 313 is realized by, for example, the communication control unit 111 and the memory 112.

The variable determination unit 311 has the same function as the variable determination unit 302 in the above embodiment. That is, the variable determination unit 311 determines the vibration model and the value of the variable according to the satisfied condition according to the condition that the predetermined vibration condition is satisfied. The vibration conditions used by the variable determination unit 311 of the main body device 2 may be different from or the same as the vibration conditions used by the variable determination unit 302 of the ring type expansion device 5. The vibration condition used by the variable determination unit 311 of the main body device 2 may be, for example, a condition related to a game executed in the main body device 2 (for example, a predetermined condition is satisfied in the game).

In this modification, the variable determination unit 311 passes the function specification information that specifies the determined vibration model and the variable information that indicates the value of the determined variable to the generation unit 313 of the right controller 4. That is, the variable determination unit 311 wirelessly transmits these information to the right controller 4.

The function storage unit 312 has the same function as the function storage unit 301 in the above embodiment. The function storage unit 312 stores the function corresponding to the vibration model indicated by the function designation information transmitted from the main unit device 2. The function stored in the function storage unit 312 of the right controller 4 and the function stored in the function storage unit 301 of the ring-type expansion device 5 may be different.

The generation unit 313 has the same function as the generation unit 303 in the above embodiment. That is, the generation unit 313 generates vibration information based on the function stored in the function storage unit 312 and the value of the variable determined by the variable determination unit 311.

In this modification as well, as in the above embodiment, the generated vibration information is passed to the vibration control unit 304, and the vibration control unit 304 controls the vibration of the vibrator 117 based on the vibration information. As a result, in the present modification as well, the game system 1 can vibrate the vibrator 117 with a vibration pattern based on the vibration model, as in the above embodiment.

FIG. 20 is a flowchart showing an example of vibration control processing in this modified example. The series of vibration control processes shown in FIG. 20 is executed by the right controller 4. In this modification, the series of vibration control processes shown in FIG. 20 is started, for example, when the game application is started in the main body device 2.

In this modification, it is assumed that the processor of the communication control unit 111 of the right controller 4 executes the processing of each step shown in FIG. 20 by executing the program stored in the memory 112. Further, the processor executes the processing of each step shown in FIG. 20 using the memory. That is, the processor stores the information (in other words, data) obtained by each processing step in the memory, and when the information is used in the subsequent processing steps, the processor reads the information from the memory and uses it.

When the vibration control process is started, the processor repeatedly executes the series of processes of steps S11 to S17 once in one frame period.

In step S11, the processor determines whether or not the function designation information and the variable information have been received from the main unit device 2. In this modification, when any of the vibration conditions is satisfied, the main body device 2 transmits the function designation information and the variable information corresponding to the satisfied conditions to the right controller 4. The processor determines whether or not this information has been received wirelessly. If the determination result in step S11 is affirmative, the process in step S12 is executed. On the other hand, if the determination result in step S11 is negative, the processes in steps S12 to S14 are skipped, and the process in step S15, which will be described later, is executed.

In step S12, the processor transmits a confirmation notification indicating that the information has been received from the main body device 2 in step S1 to the main body device 2. After step S12, the process of step S13 is executed.

Here, in the present modification, if the confirmation notification from the right controller 4 is not received within a predetermined time after the function designation information and the variable information are transmitted, the main unit device 2 transmits the function designation information and the variable information. resend. The main unit device 2 repeatedly executes the transmission of the function designation information and the variable information until the confirmation notification is received from the right controller 4. As described above, in this modification, in the wireless communication between the main body device 2 and the right controller 4, until it is confirmed in the main body device 2 that the function designation information and the variable information are received in the right controller 4. The function specification information and variable information are transmitted. According to this, it is possible to improve the possibility of acquiring the function specification information and the variable information in the right controller 4.

The processes of steps S13 to S15 in this modification are different from each other (although the execution subject is the processor of the ring-type expansion device 5 or the processor of the right controller 4), respectively, in step S2 in the above embodiment. Since it is the same as the processing of ~ S4, detailed description thereof will be omitted.

In step S16, the processor vibrates the oscillator 117 based on the unit vibration information generated in step S15. By repeatedly executing the process of step S16 every one frame period, the vibrator 117 vibrates in the vibration pattern indicated by the vibration information generated in step S15. After step S16, the process of step S17 is executed.

In step S17, the processor determines whether or not to end the vibration control process. For example, the processor determines whether or not an instruction to end the game processing in the game application has been transmitted from the main device 2. If the determination result in step S17 is affirmative, the processor ends the vibration control process. On the other hand, if the determination result in step S17 is negative, the process in step S11 is executed again. After that, the processor repeatedly executes a series of processes of steps S11 to S17 until the determination result in step S17 becomes affirmative.

Although not shown in FIG. 20, the right controller 4 may execute a process of transmitting the above-mentioned operation data to the main body device 2 while the game application is being executed in the main body device 2.

As described above, in the above modification, the information processing system includes a first device (specifically, the right controller 4) including an oscillator and a second device (specifically) that performs wireless communication with the first device. Includes the main body device 2). The second device includes a variable determination unit 311 and a variable transmission unit (specifically, a controller communication unit 83) that transmits the determined frequency variable and period variable to the first device. In addition, the first device has the following configuration.
-Variable receiving unit (specifically, communication control unit 111) that receives frequency variables and period variables from the second device.
-Generation unit 313 that generates vibration information based on the frequency variable and period variable received by the variable receiver.
・ Vibration control unit 314
According to the above, the frequency model function is stored in the first device, and the vibration information is generated by using the frequency model function, so that the amount of data used for controlling the oscillator in the first device can be reduced. it can. Further, according to the above, since the second device transmits the information indicating the variable to the first device, compared with the case where the vibration information or the data indicating the vibration waveform itself is transmitted to the first device every frame period. At least one of the amount of communication between the devices and the frequency of communication can be reduced. Further, according to the above, the second device may first transmit the above variable at the start of vibrating the vibrator, and the second device does not need to communicate with the first device during the vibration of the vibrator. It is not necessary that the second device is activated during the vibration. Therefore, in the above modification, it is possible to save power by putting the second device into a sleep state while the right controller 4 is vibrating.

Further, in another embodiment, the main body device 2 may include a variable determination unit and a function storage unit, and the right controller 4 may not include a function storage unit but may include a generation unit and a vibration control unit. At this time, the main body device 2 transmits to the right controller 4 a function indicating a vibration model corresponding to the satisfied vibration condition and a value of a variable applied to the function according to the satisfaction of the vibration condition. .. The generation unit of the right controller 4 generates a vibration pattern based on the above function and the value of the variable received from the main body device 2. With the above configuration, the amount of data used for controlling the oscillator in the first apparatus can be reduced as in the above modification. Further, at least one of the communication amount and the communication frequency between the devices can be reduced. In another embodiment, the main body device 2 shows the result (that is, the vibration pattern) of applying the value of the variable to the function instead of transmitting the function and the value of the variable to the right controller 4. The function) may be transmitted to the right controller 4.

Further, in the above modification, the right controller 4 returns to the main body device 2 in response to the reception of the frequency variable and the period variable from the main body device 2 (step S12). At this time, if the response from the right controller 4 to the transmission of the frequency variable and the period variable is not received within a predetermined time from the transmission, the main unit 2 retransmits the frequency variable and the period variable to the right controller 4. According to this, even when wireless communication is performed between the main body device 2 and the right controller 4, the possibility that the vibrator 117 can be vibrated can be improved. When the information is retransmitted as described above, the amount of communication between the devices increases as compared with the case where the retransmitting is not performed. However, in the above modification, since variable information with a small amount of data is transmitted from the main unit 2 to the right controller 4, there is little possibility that the amount of communication will be excessive even if the information is retransmitted. In addition, the main body device 2 may determine whether or not the reply is within the predetermined time from the transmission by measuring the time after the reply is made, and corresponds to the time. It may be performed using an index (for example, the number of frames elapsed since the reply was made).

If vibration information is transmitted from the main unit 2 to the right controller 4 for each frame period, among a plurality of vibration information transmitted from the main unit 2 due to the loss of packets that occur in wireless communication. Some vibration information may not be received by the right controller 4. At this time, the vibration pattern instructed by the main body device 2 (that is, the vibration pattern defined by the information transmitted by the main body device 2) may not be correctly reproduced in the vibrator 117. On the other hand, in the above modification, the variable information is transmitted by the communication method of retransmitting, and the vibration information is generated in the right controller 4 on the receiving side based on the variable information. According to this, it is less likely that the vibration information generated on the receiving side shows contents different from the vibration pattern instructed by the main body device 2.

Further, in another embodiment, the main body device 2 and the right controller 4 may be able to operate in either the first mode in which the vibration model is used and the second mode in which the vibration model is not used. In the first mode, as shown in the above modification, the main unit 2 transmits the variable information to the right controller 4, and the right controller 4 of the vibrator 117 is based on the vibration information generated based on the variable information. Control vibration. On the other hand, in the second mode, the main body device 2 transmits vibration information indicating a predetermined vibration pattern to the right controller 4 (for example, unit vibration information is transmitted once in one frame period), and the right controller. 4 controls the vibration of the vibrator 117 based on the vibration information transmitted from the main body device 2. Here, the vibration information in the second mode is generated in the main body device 2 by any method other than the method using the vibration model. For example, the vibration information in the second mode may be included in the program of the application being executed in the main device 2. Further, for example, the vibration information in the second mode is vibration information generated based on the user's input in the main body device 2 (for example, vibration indicating a vibration pattern that vibrates at each input timing when the user makes a series of inputs). Information). According to the above, the game system 1 can reduce the amount of data used for controlling the vibrator 117 by using the vibration model in the first mode, and is generated from the vibration model in the second mode. The oscillator 117 can also be vibrated by a vibration pattern that cannot be achieved.

(Variation example of vibration model)
The content of the vibration model is arbitrary, and in other embodiments, a vibration model different from the first and second vibration models may be used. FIG. 21 is a diagram showing another example of the vibration model. The vibration model shown in FIG. 21 shows a model of a vibration pattern in which the amplitude and frequency change as shown in (a) to (d) below.
(A) No vibration is generated during the period from the start time to the lapse of time t11.
(B) In the period from the time when the time t11 elapses to the time when the time t12 elapses, the amplitude increases from 0 to a11 (specifically, it increases in an increase mode in which the amount of increase per unit time is constant). And, the vibration is performed at the frequency f11.
(C) During the period from the time when the time t12 elapses to the time when the time t13 elapses, vibration is performed with a constant amplitude a11 and a frequency f12.
(D) In the period from the time when the time t13 elapses to the time when the time t14 elapses, the amplitude decreases from a11 to a12 (specifically, it decreases in a decrease mode in which the amount of decrease per unit time is constant). And, the vibration is performed at the frequency f3.
The time t11 to t14, the frequencies f11 to f13, and the amplitudes a11 and a12 are variables, respectively. By using the vibration model shown in FIG. 21, the game system 1 can generate a wider variety of vibration patterns.

As described above, the amplitude variable may include an end amplitude variable (ie, variable a12) indicating the amplitude at the end of the vibration model (see FIG. 21). According to this, the game system 1 can define a vibration pattern in which the amplitude at the end point is not 0 while the amplitude gradually decreases before the end point. Further, the game system 1 can define an integrated vibration pattern in which two vibration patterns are integrated so that another vibration pattern continues immediately after the above vibration pattern. For example, at this time, if the amplitude at the start of the vibration pattern immediately after the continuation is set to the above-mentioned end amplitude variable (that is, the variable a12), the vibration pattern in which the vibrations in the two vibration patterns are continuous can be defined. The variation of the vibration pattern based on the vibration model can be increased.

Further, in the vibration model shown in FIG. 21, although the vibration model in which the amplitude changes continuously is shown, the vibration model in which the frequency changes continuously may be used. FIG. 22 is a diagram showing another example of the vibration model. FIG. 22 shows a model of a vibration pattern in which the frequency changes as shown in (e) to (h) below.
(E) Vibration is performed at the frequency f21 during the period from the start point to the elapse of the time t21.
(F) In the period from the time when the time t21 elapses to the time when the time t22 elapses, the frequency increases from f21 to f22 (specifically, it increases in an increasing mode in which the amount of decrease per unit time is constant). Vibrate.
(G) During the period from the time when the time t22 elapses to the time when the time t23 elapses, vibration is performed at a constant frequency f22.
(H) In the period from the time when the time t23 elapses to the time when the time t24 elapses, the frequency decreases from f22 to f23 (specifically, it decreases in a decrease mode in which the amount of decrease per unit time is constant). Vibrate.
The time t21 to t24 and the frequency f21 to f23 are variables, respectively. By using the vibration model shown in FIG. 22, the game system 1 can define a vibration pattern in which the frequency changes continuously. Further, in another embodiment, when the vibration model shown in FIG. 22 is used, the vibration model shown in FIG. 21 may be used with respect to the amplitude. That is, the game system 1 may use the function shown in FIG. 22 as the frequency model function and the function shown in FIG. 21 as the amplitude model function. This makes it possible to increase the variation of the vibration pattern based on the vibration model.

(Variable example of vibration model variables)
In other embodiments, the function indicating the vibration model (ie, the frequency model function and the amplitude model function) may be a function having a repeating variable as a variable. The repeating variable is a variable indicating the number of times the vibration pattern defined by other variables (that is, the frequency variable, the amplitude variable, and the period variable) other than the repeating variable is repeated. When the function indicating the vibration model includes a repeating variable, the variable determination unit 302 determines the value of the repeating variable in addition to the other variables described above. The generation unit 303 performs the vibration pattern defined by the time change of the frequency and the amplitude obtained by applying the other determined variables to the frequency model function and the amplitude model function as many times as the determined repeating variable indicates. Vibration information showing the repeated vibration pattern obtained by repeating is generated.

For example, when defining a vibration pattern in which the vibration pattern of pattern B shown in FIG. 15 is repeated three times, in the above embodiment, the variable determination unit 302 is composed of four variables (that is, variables a1, f1, t1, t2). Three sets will be decided. On the other hand, when the function includes a repeating variable, the game system 1 can define the vibration pattern by determining only one set of four variables and one repeating variable. .. In this way, by using the repeating variable, the repeating vibration pattern can be defined with a smaller amount of data.

Further, when the vibration model includes a period in which the frequency or amplitude increases or decreases with time, the function indicating the vibration model may include a variable indicating the change mode of the increase or decrease. This variable indicates whether the mode of change is, for example, a linear change, a change along a parabola, a change along a sine curve, and the like. By using the above variables, the game system 1 can change the frequency and amplitude in the vibration pattern in various ways, and can vibrate the vibrator in more various vibration patterns.

(Modification example related to controller)
In the above-described embodiment and modification, the case of controlling the vibration of the vibrator 117 included in the right controller 4 has been described as an example, but the vibrator included in the left controller 3 can also be controlled in the same manner as the right controller 4. it can. For example, when the left controller 3 can be mounted on the ring type expansion device 5, the ring type expansion device 5 can control the vibrator of the left controller 3 by the same processing as the vibrator 117 of the right controller 4. it can. Further, the main body device 2 can control the oscillator of the left controller by wireless communication by the same processing as the oscillator 117 of the right controller 4. Further, the main body device 2 may control the oscillators of the two controllers 3 and 4 at the same time by communicating with both the right controller 4 and the left controller 3.

Further, in the above embodiment, there is a case where the control for the vibrator is performed by another device (that is, the ring type expansion device 5 or the main body device 2) different from the device provided with the vibrator (that is, the right controller 4). It was explained as an example. Here, in another embodiment, the process of controlling the oscillator may be executed by the device itself including the oscillator. That is, in another embodiment, the single information processing device including the oscillator may be configured to include the function storage unit, the variable determination unit, the generation unit, and the vibration control unit.

In the above embodiment, the vibrator 117 is a linear vibration motor, and can output sound together with vibration (in other words, sound is output by vibration). In the above embodiment, the vibration output by the vibrator 117 may be vibration output as sound (that is, vibration including frequencies within the human audible band) or vibration not output as sound (that is, vibration). Vibration that does not include frequencies within the human audible band) may be used.

The above embodiment can be used, for example, in a game system or a game program for the purpose of reducing the amount of data used for controlling the oscillator.

1 Game system 2 Main unit 4 Right controller 5 Ring type expansion device 81 Processor 111 Communication control unit 112 Memory 116 Codec unit 117 Oscillator 213 Control unit 301, 312 Function storage unit 302,311 Variable determination unit 303 Generation unit 304 Vibration control unit

Claims (14)

An information processing system including a game controller including an oscillator and a device capable of communicating with the game controller.
A function storage unit that shows a model of time change related to vibration and stores a model function in which the first variable indicating the frequency and / or amplitude of a certain period in the model and the second variable related to the period are variables.
A variable determination unit that determines the value of the first variable and the value of the second variable,
The vibration pattern defined by the function indicating the time change of the frequency and / or the amplitude obtained by applying the determined value of the first variable and the determined value of the second variable to the model function. A generator that generates the vibration information shown,
An information processing system including a vibration control unit that controls the vibration of the vibrator based on the vibration information. The function storage unit stores a plurality of types of model functions showing models of time-varying frequencies and / or amplitudes different from each other.
The variable determination unit further determines the function specification information that specifies one of the plurality of types of model functions.
The generator applies the determined value of the first variable and the determined value of the second variable to the model function specified by the determined function designation information, and obtains a frequency and a frequency. / Or the information processing system according to claim 1, which generates the vibration information indicating a vibration pattern defined by a function indicating a time change of amplitude. The information processing system according to claim 1 or 2, wherein the second variable includes a start variable indicating the time from the start time of the model of time change indicated by the model function to the start of vibration. The model function according to any one of claims 1 to 3, wherein the model function is a function in which the time length of the vibration pattern is determined by applying the value of the second variable to the model function. Information processing system. The information processing system according to any one of claims 1 to 4, wherein the first variable includes an end amplitude variable indicating the amplitude at the end point in the model of time change with respect to the amplitude of vibration. The variable determination unit determines a plurality of pairs of the value of the first variable and the value of the second variable.
The generation unit integrates a plurality of vibration patterns based on a plurality of determined sets of the values of the first variable and the values of the second variable, and a plurality of vibration patterns in which the periods in which vibration occurs do not overlap each other. The information processing system according to any one of claims 1 to 5, which generates the vibration information indicating one vibration pattern obtained by the above. The vibrator can vibrate with a waveform obtained by synthesizing each vibration waveform corresponding to each of two or more first predetermined number of vibration information.
The variable determination unit determines a second predetermined number larger than the first predetermined number as a set of the value of the first variable and the value of the second variable.
The generation unit integrates two or more vibration patterns out of the second predetermined number of vibration patterns based on the determined set into one vibration pattern, thereby forming the first predetermined number of vibration patterns in total. The information processing system according to claim 6, which generates the first predetermined number of vibration information shown. The model function further uses a repeating variable as a variable.
The variable determination unit further determines the value of the iterative variable.
The generator is defined by a function indicating the time variation of frequency and / or amplitude obtained by applying the determined value of the first variable and the determined value of the second variable to the model function. The information processing system according to any one of claims 1 to 7, which generates vibration information indicating a repetitive vibration pattern obtained by repeating the vibration pattern to be performed the number of times indicated by the determined repetitive variable. .. The device is
The function storage unit and
The variable determination unit and
With the generator
A transmission unit that transmits the vibration information to the game controller is provided.
The game controller
A receiving unit that receives the vibration information from the device,
The information processing system according to any one of claims 1 to 8, further comprising the vibration control unit that controls the vibration of the vibrator based on the vibration information received by the receiving unit. The device is
The variable determination unit and
It includes a transmitter that transmits the determined value of the first variable and the value of the second variable to the game controller.
The game controller
A receiver that receives the value of the first variable and the value of the second variable from the device, and
The generation unit that generates the vibration information based on the value of the first variable and the value of the second variable received by the reception unit, and the generation unit.
The information processing system according to any one of claims 1 to 8, further comprising the vibration control unit. The game controller can communicate with the main unit and
The information processing system according to any one of claims 1 to 10, wherein the device is a device different from the main body device. A device that can communicate with a game controller equipped with an oscillator,
A function storage unit that shows a model of time change related to vibration and stores a model function in which the first variable indicating the frequency and / or amplitude of a certain period in the model and the second variable related to the period are variables.
A variable determination unit that determines the value of the first variable and the value of the second variable,
The vibration pattern defined by the function indicating the time change of the frequency and / or the amplitude obtained by applying the determined value of the first variable and the determined value of the second variable to the model function. A generator that generates the vibration information shown,
A device including a transmission unit that transmits the vibration information to the game controller. An information processing program executed on a computer of an information processing device capable of communicating with a game controller equipped with an oscillator.
The information processing device shows a model of time change related to vibration, and stores a model function in which the first variable indicating the frequency and / or amplitude of a certain period in the model and the second variable related to the period are variables.
The information processing program
A variable determining means for determining the value of the first variable and the value of the second variable,
The vibration pattern defined by the function indicating the time change of the frequency and / or the amplitude obtained by applying the determined value of the first variable and the determined value of the second variable to the model function. The computer is made to function as a generation means for generating the vibration information shown.
The oscillator is an information processing program that is controlled based on the vibration information. An information processing method executed in an information processing system including a game controller including an oscillator and a device capable of communicating with the game controller.
The information processing system shows a model of time change related to vibration, and stores a model function in which the first variable indicating the frequency and / or amplitude of a certain period and the second variable related to the period are variables. Cage,
A variable determination step for determining the value of the first variable and the value of the second variable,
The vibration pattern defined by the function indicating the time change of the frequency and / or the amplitude obtained by applying the determined value of the first variable and the determined value of the second variable to the model function. The generation step to generate the vibration information shown and
An information processing method including a vibration control step for controlling the vibration of the vibrator based on the vibration information.

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