KR20200091255A - Virtual Reality Control System - Google Patents

Abstract

According to one aspect of the present invention, provided is a virtual reality control system capable of displaying a collision effect when there is collision between characters in a virtual space. The virtual reality control system includes: a first sensing unit which detects a first optical signal; a second sensing unit which detects a second optical signal; a first display for outputting an image to a first user; a second display for outputting an image to a second user; and at least one control unit for controlling the first display and the second display. The at least one control unit calculates first virtual location information of a first user based on the first optical signal and second virtual location information of a second user based on the second optical signal at a first viewpoint, calculates third virtual location information of the first user based on the first optical signal and fourth virtual location information of the second user based on the second optical signal at a second viewpoint, outputs a first image to at least one of the first display and the second display at the first viewpoint, and outputs a second image to at least one of the first display and the second display when the fourth virtual location information is located within a preset range from the second virtual location information in a state in which the third virtual location information is located within a preset range from the first virtual location information. The first image and the second image are different from each other.

Description

Virtual Reality Control System

The following embodiments relate to a virtual reality control system.

The virtual environment may be a technology that provides a user with virtual information by adding virtual information to the reality based on the reality or provides a state of an object in reality as a virtual reality image generated by a program.

The technology for providing a virtual environment may include a technology for generating a virtual space, a virtual character, and a virtual object by a program based on information about a state of an object such as a user or an object provided in reality, and various sensors are used. By using it, information about the state of the object is obtained.

On the other hand, when a virtual experience is provided to a plurality of users, it is necessary to reflect this in the virtual reality when the operation or manipulation of each user is linked to the collaboration. However, the collaboration made by a plurality of users has various types and methods, and a program suitable for each collaboration is required.

Accordingly, there is a need for a method of recognizing the movement or manipulation of multiple users in reality to determine whether collaboration has been established and reflecting it in a virtual environment.

One task is to provide a method for inducing collaboration from a plurality of users in a virtual reality or an image processing method for a case where a collaboration is performed by a plurality of users in a virtual reality since a virtual experience is provided to a plurality of users.

Another task is to provide a user with a method of displaying a collision effect when there is a collision between characters in a virtual space or a character and a virtual object in outputting the virtual space through the display device.

According to an aspect of the present invention, a first sensing unit for detecting a first optical signal, a second sensing unit for detecting a second optical signal, a first display for outputting an image to a first user, and an image for a second user And a second display to output, and at least one control unit to control the first display and the second display, wherein the at least one control unit controls the first user based on the first optical signal at a first time point. The second virtual location information of the second user based on the first virtual location information and the second optical signal is calculated, and the third virtual location information of the first user based on the first optical signal at the second time point and the second 2 Calculate fourth virtual location information of the second user based on the optical signal, output a first image to at least one of the first display and the second display at the first time point, and output the third virtual location information When the fourth virtual location information is located within a preset range from the second virtual location information while is located within a preset range from the first virtual location information, to at least one of the first display and the second display. A virtual reality control system may be provided in which a second image is output, but the first image and the second image are different images.

According to another aspect of the present invention, a first sensing unit for detecting a first optical signal, a second sensing unit for detecting a second optical signal, a first display for outputting an image to a first user, and an image for a second user And a second display to output, and at least one control unit to control the first display and the second display, wherein the at least one control unit calculates first virtual location information based on the first optical signal, and Calculate second virtual location information based on a second optical signal, and output the first image to the first display when the first virtual location information is located within a preset range with the third virtual location information of the first real object Then, after the first virtual location information is located within a preset range with the third virtual location information of the first real object, before the predefined time elapses, the second virtual location information is the fourth virtual of the second real object. When located within the location information and a preset range, a second image is output to the first display, and the first image and the second image may be provided with virtual reality control systems that are different images.

According to another aspect of the present invention, a sensing unit for detecting a first optical signal, a first display for outputting an image to a first user, a second display for outputting an image to a second user, the first display and the second And at least one control unit for controlling a display and an input device for transmitting an input signal by the input of the second user to the at least one control unit, wherein the at least one control unit is based on the first optical signal. Calculates first virtual location information of a first user, outputs a first image on at least one of the first display and the second display based on the first virtual location information, and the input signal is the at least one or more. When delivered to the control unit, a second image is output, but a virtual reality control system in which the first image and the second image are different images may be provided.

According to another aspect of the present invention, a first sensing unit for detecting a first optical signal, a second sensing unit for detecting a second optical signal, a first display for outputting an image to a first user, an image for a second user And a second display for outputting and at least one control unit controlling the first display and the second display, wherein the at least one control unit calculates first virtual location information based on the first optical signal, and Calculate second virtual location information based on a second optical signal, and generate a first rendering image based on the first virtual location information and the second virtual location information on at least one of the first display and the second display. 2 to output the rendered image, when the second virtual location information is within a preset range from the first virtual location information, a distance between the first virtual location information and the second virtual location information has a first distance In case the first rendered image is output, and when the distance between the first virtual location information and the second virtual location information has a second distance, a third rendered image is output, and the first rendered image and the third rendered image The appearance of the corresponding, the first distance may be provided with a virtual reality control system that is a distance greater than the second distance.

Since a specific operation or operation of each of a plurality of users is recognized as a collaboration under certain conditions, the degree of interest and immersion felt by the user in a virtual experience using multiplayer may be increased.

By providing a method for recognizing collaboration among multiple users and reflecting it in virtual reality, more various virtual experiences can be developed.

When a virtual experience is provided to a plurality of users, when a plurality of characters collide in a virtual space, the immersion level felt by the user may not be reduced.

1 is an environmental diagram illustrating a virtual reality control system according to an embodiment.
2 is a block diagram showing a detecting device according to an embodiment.
3 is a block diagram illustrating a server according to an embodiment.
4 is a block diagram illustrating an auxiliary computing device according to an embodiment.
5 is a block diagram illustrating a wearable display device according to an embodiment.
6 is an exemplary view showing an implementation of a virtual reality control system according to an embodiment.
7 is a schematic diagram illustrating a method for tracking an object according to an embodiment.
8 is a diagram illustrating that a virtual reality image according to an embodiment is output through a wearable display device.
9 is an exemplary view showing a real space before collaboration is performed according to an embodiment.
10 is an exemplary diagram illustrating a virtual reality image provided to a first user before collaboration is made according to an embodiment.
11 is an exemplary view showing a case where collaboration is performed by a plurality of users in a real space.
12 is an exemplary diagram illustrating a case where collaboration is performed by a plurality of users in a virtual space.
13 is an exemplary view showing a real space before collaboration is performed by a plurality of users using an input device.
14 is an exemplary view showing a real space after collaboration is performed by a plurality of users using an input device.
15 is an exemplary view showing a virtual space before collaboration is performed by a plurality of users using an input device.
16 is an exemplary view showing a virtual space after collaboration is performed by a plurality of users using an input device.
17 is an exemplary view showing a real space including a real object according to an embodiment.
18 is an exemplary diagram illustrating that collaboration is performed using at least one real object in a virtual space according to an embodiment.
19 is an exemplary view showing a real space when a virtual experience is provided to a user who wears a wearable display device and a user who does not wear the wearable display device according to an embodiment.
20 is an exemplary view illustrating a virtual space when a virtual experience is provided to a user who wears a wearable display device and a user who does not wear the wearable display device according to an embodiment.
21 is a flowchart illustrating a collaborative evaluation method for reflecting collaboration by multiple users in an evaluation result according to an embodiment.
FIG. 22 is an exemplary diagram illustrating that a rendered image is displayed in a virtual space upon contact between users at a relatively long distance from reality.
23 is an exemplary diagram illustrating that a rendered image is displayed in a virtual space upon contact between users at a relatively close distance in reality.
24 is an exemplary view illustrating an input device according to an embodiment.
25 is an exemplary diagram illustrating that an input device according to an embodiment is changed to different variable objects in a virtual space.
26 is an exemplary view illustrating a case where a second variable object is changed to a first variable object according to an embodiment.
27 is an exemplary diagram illustrating a method in which a shape of a variable object is changed according to a position of a character, according to an embodiment.
28 is an exemplary diagram illustrating a method in which a variable object corresponding to an input device is displayed on a virtual reality image, according to an embodiment.
29 is an exemplary diagram illustrating a situation before a collision occurs between virtual objects in a virtual space according to an embodiment.
30 is an exemplary view illustrating a case where a collision occurs between a collision object and an operation object according to an embodiment.
31 is an exemplary diagram illustrating a method of outputting a virtual reality image when a collision occurs between a collision object and a manipulation object, according to an embodiment.
32 is an exemplary diagram illustrating a method of displaying a plurality of manipulation objects in a virtual space, according to an embodiment.
33 is an exemplary diagram illustrating a method of changing a virtual place according to an embodiment.

The above-described objects, features and advantages of the present invention will become more apparent through the following detailed description in conjunction with the accompanying drawings. However, the present invention can be modified in various ways and can have various embodiments. Hereinafter, specific embodiments will be illustrated in the drawings and described in detail.

In the drawings, the thickness of the layers and regions are exaggerated for clarity, and the element or layer is “on” or “on” of another element or layer. What is referred to includes cases where other layers or other components are interposed in the middle as well as directly above other components or layers. Throughout the specification, the same reference numbers refer to the same components in principle. In addition, elements having the same functions within the scope of the same idea appearing in the drawings of the respective embodiments will be described using the same reference numerals.

If it is determined that a detailed description of known functions or configurations related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, the numbers used in the description process of the present specification (for example, first, second, etc.) are only identification numbers for distinguishing one component from other components.

In addition, the suffixes "module" and "part" for components used in the following description are given or mixed only considering the ease of writing the specification, and do not have a meaning or a role that is distinguished from each other.

Virtual reality may be an artificial environment created by a program unlike the real world.

Such a virtual reality is a virtual space that is separated from reality by a program, and VR that provides an image for this, AR that provides a virtual image based on the real world, and AR and the real world and virtual reality. It can be divided into MRs that fuse to provide a virtual space and provide images for it.

In describing the virtual reality described below, the virtual reality may mean a virtual environment providing various types of virtual spaces as well as VR, AR, and MR described above.

According to an embodiment of the present invention to solve the above-mentioned problems, the first sensing unit for detecting the first optical signal, the second sensing unit for detecting the second optical signal, the first to output an image to the user A first display, a second display for outputting an image to a second user, and at least one control unit for controlling the first display and the second display, wherein the at least one control unit includes the first light at a first point in time. Calculates first virtual location information of the first user based on a signal and second virtual location information of the second user based on the second optical signal, and the first user based on the first optical signal at a second time point The fourth virtual location information of the second user based on the third virtual location information and the second optical signal is calculated, and a first image is displayed on at least one of the first display and the second display at the first viewpoint. Output, and the first display when the fourth virtual location information is located within a preset range from the second virtual location information while the third virtual location information is located within a preset range from the first virtual location information And outputting a second image to at least one of the second displays, wherein the first image and the second image are different images, and a virtual reality control system may be provided.

According to an embodiment of the present invention, a first real object whose location is changed by the first user and a second real object whose location is changed by the second user, wherein the first sensing unit is the first A virtual reality control system may be provided that detects the first optical signal from a real object and the second sensing unit detects the second optical signal from the second real object.

According to an embodiment of the present invention, the first real object includes a first input unit that delivers a first input signal by the input of the first user to the at least one control unit, and the second real object is the And a second input unit which transmits a second input signal according to a second user's input to the at least one controller, among the first input signal and the second input signal between the first time point and the second time point. A virtual reality control system in which at least one is transmitted to the at least one control unit may be provided.

According to an embodiment of the present invention, the first virtual location information and the third virtual location information change according to the movement trajectory of the first real object between the first time point and the second time point, and the second A virtual reality control system may be provided in which virtual location information and the fourth virtual location information change according to a movement trajectory of the second real object between the first time point and the second time point.

According to an embodiment of the present invention, the first display is mounted on a first HMD worn on the first user, the second display is mounted on a second HMD worn on the second user, and the first The optical signal is detected at the first HMD, and the second optical signal is detected at the second HMD, and the first virtual location information and the third virtual location information are between the first time point and the second time point. Virtual reality changing according to the movement trajectory of the first HMD, and the second virtual location information and the fourth virtual location information changing according to the movement trajectory of the second HMD between the first time point and the second time point A control system can be provided.

According to an embodiment of the present invention, the first microphone for transmitting the first voice signal by the input of the first user to the at least one control unit and the second voice signal by the input of the second user by the at least one The second microphone includes a second microphone that is transmitted to the above controller, and when at least one of the first voice signal and the second voice signal is transmitted between the first time point and the second time point to the at least one control part, the first microphone A virtual reality control system in which a second image is output on at least one of a display and the second display may be provided.

According to an embodiment of the present invention, virtual location information of a real object at the first time point is within a preset range from the first virtual location information, and virtual location information of the real object at the second time point is the first time point. 4 A virtual reality control system existing within a preset range from virtual location information may be provided.

According to an embodiment of the present invention, a first sensing unit for detecting a first optical signal, a second sensing unit for detecting a second optical signal, a first display for outputting an image to a first user, and an image for a second user And a second display for outputting and at least one control unit controlling the first display and the second display, wherein the at least one control unit calculates first virtual location information based on the first optical signal, Calculate second virtual location information based on the second optical signal, and when the first virtual location information is located within a preset range with third virtual location information of the first real object, display a first image on the first display. Output, and after the first virtual location information is within a preset range with the third virtual location information of the first real object, the second virtual location information is the fourth of the second real object before a predefined time elapses. When located within the virtual location information and a predetermined range, a second image is output to the first display, and the first image and the second image may be provided with virtual reality control systems that are different images.

According to an embodiment of the present invention, the first real object and the second real object may be provided with the same virtual reality control system.

According to an embodiment of the present invention, the first image may be provided with a virtual reality control system including a first virtual object corresponding to the first real object.

According to an embodiment of the present invention, the control unit may include a first point in time at which the first virtual position information is located within a preset range from the third virtual position information and the fourth virtual position information in the second virtual position information. A virtual reality control system for counting scores based on a time difference between a second time point, which is a time point located within a preset range, may be provided.

According to an embodiment of the present invention, a sensing unit detecting a first optical signal, a first display outputting an image to a first user, a second display outputting an image to a second user, the first display and the agent 2 at least one control unit for controlling a display and an input device for transmitting an input signal by the input of the second user to the at least one control unit, wherein the at least one control unit is based on the first optical signal The first virtual location information of the first user is calculated, and a first image is output to at least one of the first display and the second display based on the first virtual location information, and the input signal is the at least one. When delivered to the above control unit, a second image is output, but a virtual reality control system in which the first image and the second image are different images may be provided.

According to an embodiment of the present invention, the sensing unit does not detect an optical signal from the second user, and the at least one control unit may be provided with a virtual reality control system that does not calculate virtual location information of the second user. have.

According to an embodiment of the present invention, the first image and the second image include a virtual object, wherein the virtual object has a first state in the first image and a second state in the second image. A control system can be provided.

According to an embodiment of the present invention, the first image and the second image include a virtual object, and the at least one control unit has a virtual reality control system displaying a preset effect on the virtual object in the second image. Can be provided.

According to an embodiment of the present invention, the sensing unit detects a second optical signal from the input device, and the at least one control unit calculates second virtual location information based on the second optical signal. When the first image is displayed on at least one of the first display and the second display is the first view, and when the second image is output is the second view, the second virtual location is from the first view. Information and the second virtual location information at the second time point may be provided with different virtual reality control systems.

According to an embodiment of the present invention, a first sensing unit for detecting a first optical signal, a second sensing unit for detecting a second optical signal, a first display for outputting an image to a first user, and an image for a second user And a second display for outputting and at least one control unit controlling the first display and the second display, wherein the at least one control unit calculates first virtual location information based on the first optical signal, Calculate second virtual location information based on the second optical signal, and based on the first rendered image based on the first virtual location information and the second virtual location information on at least one of the first display and the second display. When a second rendered image is output, and the second virtual location information is within a preset range from the first virtual location information, a distance between the first virtual location information and the second virtual location information determines a first distance. If it has, the first rendering image is output, and if the distance between the first virtual location information and the second virtual location information has a second distance, a third rendering image is output, and the first and third rendering images are rendered. The appearance of the image corresponds, and the virtual reality control system in which the first distance is greater than the second distance may be provided.

According to an embodiment of the present invention, a virtual reality control system in which the first rendered image and the third rendered image are rendered images having different sizes may be provided.

According to an embodiment of the present invention, a virtual reality control system may be provided in which the first rendered image and the third rendered image are rendered images corresponding to a body part of the first user.

According to an embodiment of the present invention, the first rendered image and the third rendered image may be provided with a virtual reality control system that contacts the second rendered image in a virtual space.

According to an embodiment of the present invention, a distance between the second rendered image and a fourth rendered image connected to the first rendered image, the distance between the first virtual location information and the second virtual location information When the distance between the fourth rendered image and the first virtual location information and the second virtual location information when the first distance has the second distance, the fourth rendered image has a different shape. Branches may be provided with a virtual reality control system.

According to an embodiment of the present invention, the first input device for transmitting a first input signal to the at least one control unit by the operation of the first user; And a second input device that transmits a second input signal to the at least one control unit by manipulation of the second user, wherein the first rendered image corresponds to the first input device, and the second rendered image. A virtual reality control system corresponding to the second input device may be provided.

In the above, the solution to the problem to be solved in the present invention has been described. Hereinafter, a solution will be described in detail with reference to the drawings.

Hereinafter, a virtual reality control system 10 for providing a virtual reality according to an embodiment will be described with reference to FIG. 1.

1 is an environmental diagram illustrating a virtual reality control system 10 according to an embodiment.

Referring to FIG. 1, the virtual reality control system 10 may include a detecting device 100, a server 200, an auxiliary computing device 300, a wearable display device 400 and an input device 500. have.

According to an embodiment, the detecting device 100 may be connected to the server 200.

The detecting device 100 may acquire the detecting information by tracking the object.

The object according to an embodiment may be an object that affects an image output through the wearable display device 400.

For example, the object may include at least one of a wearable display device 400, a user, an input device 500, an object positioned around the user, and an object having a reference point or a feature point.

Also, tracking an object according to an embodiment may mean obtaining information about the position of the object in a real environment.

For example, tracking of an object may acquire information about a position that changes according to the movement of the object in the real environment. The location information for the object may be obtained at a predetermined period, but is not limited thereto.

According to one embodiment, the detecting device 100 may provide the detecting information to the server 200.

According to an embodiment, the server 200 may be connected to the detecting device 100 and the auxiliary computing device 300.

The server 200 may acquire information from a connected configuration.

According to an embodiment, the server 200 may acquire at least one of the detection information, the image information acquired by the detection device 100, and the status information of the detection device 100 from the detection device 100. .

In addition, the server 200 may acquire various information according to some embodiments to be described later.

According to an embodiment, the server 200 may control a connected configuration.

According to an embodiment, the server 200 may control the auxiliary computing device 300 or the wearable display device 400.

For example, the server 200 may control driving of a program or application installed in the auxiliary computing device 300. For a more specific example, the server 200 may control the start and/or end of a program or application installed in the auxiliary computing device 300.

As another example, the server 200 may provide various settings necessary for the operation of the detecting device 100.

Also, the server 200 may generate location information of the object based on the detection information or virtual location information in a virtual environment corresponding to the location of the object.

In addition, the server 200 may perform authentication of a program or application running on the secondary computing device 300.

The function of the server 200 according to an embodiment is not limited to the functions described above, and the server 200 performing various functions may be provided according to an embodiment.

In addition, the server 200 according to an embodiment is not necessarily provided in one physical configuration, and may be provided as a plurality of devices that perform each function by subdividing the above-described functions.

For example, the server 200 is connected to the detecting device 100 to control the control of at least a part of the configuration provided to the detecting server and the virtual reality control system 10 to obtain location information based on the detecting information. It can be subdivided into a license server that performs authentication for a program or an application that is executed in at least one configuration of each of the components of the operation server and the virtual reality control system 10 to be performed and performed in each server.

Meanwhile, the server 200 may receive input signals based on the input signals or input signals obtained from the input device 500 by the auxiliary computing device 300.

The input information may include user's selection information on an object in a virtual reality, information on an operation input through the input device 500, and information on a direction of the input device 500.

The auxiliary computing device 300 may be connected to at least one of the detecting device 100, the server 200, the wearable display device 400, and the input device 500.

The auxiliary computing device 300 may calculate virtual location information based on the location information obtained from the server 200.

Alternatively, the auxiliary computing device 300 may process the detection information obtained from the detecting device 100 to calculate location information of the object or virtual location information.

The auxiliary computing device 300 may provide an image to the user through the wearable display device 400 through a pre-stored program or application.

Also, the auxiliary computing device 300 may provide sound information to be provided to the user through the wearable display device 400.

According to an embodiment, the auxiliary computing device 300 may acquire an image to be provided to a user based on location information through a pre-installed application or program.

Also, the auxiliary computing device 300 may obtain input information based on the input signal obtained from the input device 500.

Also, the auxiliary computing device 300 may acquire an image to be provided to the user in consideration of the acquired input information.

The wearable display device 400 may be connected to the secondary computing device 300.

The wearable display device 400 may provide an image of the virtual environment to the user.

The wearable display device 400 may visually output a virtual reality image acquired from the secondary computing device 300 to the user.

Also, the wearable display device 400 may output sound information acquired from the auxiliary computing device 300.

The input device 500 may acquire a signal for a user input to be reflected in a virtual environment.

The input device 500 may be connected to the auxiliary computing device 300.

The input device 500 may provide an input signal corresponding to a user's input to the auxiliary computing device 300.

The input device 500 is an acceleration sensor, a gyroscope, a gyroscope sensor, a MEMS, a geomagnetic sensor, an inertial sensor (IMU), an optical sensor, an illuminance sensor, a photo sensor, an infrared sensor, and a color for acquiring a signal corresponding to a user's motion It may include a sensor, a depth sensor and an electromagnetic wave sensor.

In addition, the input device 500 may include buttons, switches, jog shuttles, wheels, and the like for obtaining a signal for a user's selection.

Also, the input device 500 may be connected to the auxiliary computing device 300 in at least one of wired communication and wireless communication.

In addition, the input device 500 may include a communication module for communication with the auxiliary computing device 300.

Although the input device 500 is illustrated as being connected to the auxiliary computing device 300 in FIG. 1, the present invention is not limited thereto, and the input device 500 may be provided in various connection types according to selection.

For example, the input device 500 may be connected to components such as the server 200 and the wearable display 400 to provide an input signal.

Meanwhile, the input device 500 may provide haptic feedback.

The server 200 or the secondary computing device 300 may provide haptic feedback to the user through the input device 500.

Haptic feedback may include vibration, force, motion, heat or cold provided to the user as the user manipulates the input device 500.

The haptic feedback may include at least one of contact haptic feedback provided in direct contact with the user and non-contact haptic feedback provided at a distance from the user.

The input device 500 may include a tactile sensor, a vibration motor, an actuator, an ultrasonic module, and a thermoelectric element to provide haptic feedback.

The virtual reality control system 10 described above is only an example for convenience of description, and the virtual reality control system 10 according to an embodiment is not limited to the configuration and connection relationship illustrated in FIG. 1, depending on selection It can be provided in various forms.

For example, the secondary computing device 300 and the wearable display device 400 may be provided as one configuration, and in this case, an operation performed by the auxiliary computing device 300 may be implemented in the wearable display device 400. have.

However, in the following description of various embodiments, for convenience of description, the above-described virtual reality control system 10 will be described as an example.

Hereinafter, the detecting device 100 according to an embodiment will be described with reference to FIG. 2.

2 is a block diagram illustrating a detecting device 100 according to an embodiment.

Referring to FIG. 2, the detecting device 100 may include a light emitting unit 110 and a sensing unit 120.

The light emitting unit 110 may transmit a signal to or around the object for tracking the object.

For example, the light emitting unit 110 may be provided as a light emitting device that transmits light signals such as visible light and infrared light to the outside.

For a more specific example, the light emitting unit may be provided as a visible light LED and an infrared LED.

The sensing unit 120 may acquire a signal from the outside.

For example, the sensing unit 120 may acquire a signal corresponding to the signal transmitted by the light emitting unit 110.

As another example, the sensing unit 120 may acquire a signal for light reflected by the marker provided to the object.

For example, the sensing unit 120 may be provided as an image sensor, an optical sensor, an illuminance sensor, a photo sensor, an infrared sensor, a color sensor, a depth sensor, and an electromagnetic wave sensor.

3 is a block diagram illustrating a server 200 according to an embodiment.

Referring to FIG. 3, the server 200 may include a server communication unit 210, a server storage unit 220, a server input unit 230, a server control unit 240, and a server display unit 250.

The server communication unit 210 may be connected to at least one of the detecting device 100, the auxiliary computing device 300, the wearable display device 400, and the input device 500 to obtain or provide data.

The server communication unit 210 may be connected to at least one of the detecting device 100, the auxiliary computing device 300, the wearable display device 400, and the input device 500 by at least one of wired communication and wireless communication. Can.

For example, wireless communication includes Wi-Fi networks, 3G, LTE networks, 5G, and LoRa mobile networks, wave (Wireless Access in Vehicular Environment), beacons, zigbees, Bluetooth (Bluetooth) , BLE (Bluetooth Low Energy), and the like.

Also, the wired communication may include a twisted pair cable, a coaxial cable, or an optical cable.

The server communication unit 210 may be provided as a communication module for providing at least one communication method among wired communication and wireless communication.

The server storage unit 220 may store data.

The server storage unit 220 may store information obtained from the outside.

Also, the server storage unit 220 may store information necessary for the operation of the server 200.

For example, the server storage unit 220 may include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical media such as CD-ROMs, DVDs, and floptical disks. It may be provided with the same magneto-optical media, and ROM, RAM, flash memory, SSD, CD-ROM, DVD-ROM or USB.

The server input unit 230 may acquire a signal corresponding to the user's input.

The user input may be, for example, pressing, clicking, touching and dragging a button.

The server input unit 230 may be implemented with, for example, a keyboard, a keypad, a button, a jog shuttle, and a wheel.

The server control unit 240 may oversee the operation of the server 200.

For example, the server controller 240 may control the operation of the configuration included in the server 200.

The server display unit 250 may output visual information.

The server display unit 250 may be provided as a monitor, TV, display panel, etc. that outputs visual information.

In addition, when the server display unit 250 is provided as a touch screen, the server display unit 250 may perform a function of the server input unit 230.

4 is a block diagram illustrating an auxiliary computing device 300 according to an embodiment.

Referring to FIG. 4, the auxiliary computing device 300 may include an auxiliary computing communication unit 310, an auxiliary computing storage unit 320, an auxiliary computing input unit 330, and an auxiliary computing control unit 340.

The secondary computing communication unit 310 may be connected to at least one of the server 200, the wearable display device 400, and the input device 500.

The auxiliary computing communication unit 310 may be connected to at least one of the server 200, the wearable display device 400, and the input device 500 by at least one communication method between wired communication and wireless communication.

The secondary computing communication unit 310 may exchange information with at least one of the connected server 200, the wearable display device 400, and the input device 500.

For example, wireless communication includes Wi-Fi networks, 3G, LTE networks, 5G, and LoRa mobile networks, wave (Wireless Access in Vehicular Environment), beacons, zigbees, Bluetooth (Bluetooth) , BLE (Bluetooth Low Energy), and the like.

Also, the wired communication may include a twisted pair cable, a coaxial cable, or an optical cable.

The auxiliary computing communication unit 310 may be provided as a communication module for providing at least one communication method among wireless communication and wired communication.

The auxiliary computing storage 320 may store information acquired from the outside.

In addition, the auxiliary computing storage 320 may store data required for the operation of the auxiliary computing device 300.

In addition, the auxiliary computing storage 320 may store an application or program for providing a virtual experience to a user.

The auxiliary computing input unit 330 may acquire a signal corresponding to a user input.

The user input may be, for example, pressing, clicking, touching and dragging a button.

For example, the auxiliary computing input unit 330 may be implemented with a keyboard, a keypad, buttons, a jog shuttle and a wheel.

The auxiliary computing control unit 340 may generalize the operation of the auxiliary computing device 300.

5 is a block diagram illustrating a wearable display device 400 according to an embodiment.

5, the wearable display device 400 includes a wearable display communication unit 410, a wearable display storage unit 420, a wearable display sensor unit 430, a wearable display control unit 440 and a wearable It may include a display output unit 450.

The wearable display communication unit 410 may be connected to the secondary computing device 300.

The wearable display communication unit 410 may be connected to the secondary computing device 300 by at least one communication method between wired communication and wireless communication.

The wearable display storage unit 420 may store data.

The wearable display storage unit 420 may store an application or program required for the operation of the wearable display device 400.

In addition, the wearable display storage unit 420 may store information acquired from the outside.

The wearable display sensor unit 430 may acquire a signal corresponding to a state of the wearable display device 400 and a user's input.

The wearable display sensor unit 430 according to an embodiment may include a wearable display motion sensor module 431 and a wearable display acoustic sensor module 432.

The wearable display motion sensor module 431 may acquire a signal for the state of the wearable display device 400.

For example, the wearable display motion sensor module 431 may acquire rotation information about the rotation of the wearable display device 400.

As another example, the wearable display motion sensor module 431 may acquire movement information on the position movement of the wearable display device 400.

The wearable display motion sensor module 431 includes an acceleration sensor, a gyroscope, a gyro sensor, a MEMS, a geomagnetic sensor, an inertial sensor (IMIU), an image sensor, an optical sensor, an illuminance sensor, a photo sensor, an infrared sensor, a color sensor, and a depth sensor. Or an electromagnetic wave sensor.

The wearable display acoustic sensor module 432 may acquire a signal corresponding to sound coming from the outside.

For example, the wearable display acoustic sensor module 432 may be a microphone.

The wearable display control unit 440 may generalize the operation of the wearable display device 400.

The wearable display screen output unit 450 may output visual information to the user.

For example, the wearable display screen output unit 450 may output an image of virtual reality. Also, as another example, the wearable display screen output unit 450 may output an image of a 3D virtual reality.

The wearable display screen output unit 450 may be provided as an image output device such as a liquid crystal display (LCD), electronic paper, LED display, OLED display, curved display, stereoscopic (three-dimensional display using binocular parallax).

The wearable display sound output unit 460 may output auditory information.

The wearable display sound output unit 460 may be provided as a sound device such as a tuner, a playback device, an amplifier, and a speaker.

6 is an exemplary view showing an implementation of the virtual reality control system 10 according to an embodiment.

Referring to FIG. 6, the virtual reality control system 10 may be provided with a tracking area 600 for a virtual experience to at least one user 800.

Also, at least one of the secondary computing device 300, the wearable display device 400, and the input device 500 may be provided to the user 800 in the tracking area 600.

In addition, a marker may be provided to an object provided to the user 800.

For example, when the object is the wearable display device 400 and the input device 500, the wearable display device 400 and the input device 500 may be provided with markers of different patterns.

The pattern provided with the marker will be described later.

Also, the tracking area 600 may be provided with at least one detecting device 100.

For example, as illustrated in FIG. 6, a plurality of detecting devices 100 may be provided in the tracking area 600.

The detecting device 100 may be provided spaced apart at predetermined intervals around the periphery of the tracking area 600.

In addition, the detecting device 100 may be provided spaced apart from the ground by a predetermined height.

In addition, the detecting device 100 may be provided to direct the tracking area 600.

The detecting device 100 may be fixed and installed in a frame F pre-installed.

The frame F may provide a space for the user 800 to experience virtually.

The frame F may include a plurality of pillars.

The frame F may be composed of a plurality of trusses.

In one embodiment, the frame (F) may provide a polygonal or causal columnar space.

The frame F may support the detecting device 100.

As an example, as shown in FIG. 6, a frame F for installing the detecting device 100 may be provided around the tracking area 600. In addition, the detecting device 100 may be fixed to the frame F and installed.

The detecting device 100 may acquire detecting information for the tracking area 600.

For example, the sensing unit 120 included in the detecting device 100 may acquire detecting information for at least a part of the tracking area 600.

The detecting device 100 may provide the detecting information to the server 200 or the auxiliary computing device 300.

For example, the detecting device 100 may provide the detecting information acquired by the sensing unit 120 to the server 200.

The server 200 may acquire real-time location information of the object based on the detection information.

As shown in FIG. 6, when a plurality of detecting devices 100 are provided in the tracking area 600, the server 200 or the auxiliary computing device 300 receives detection information from the plurality of detecting devices 100. It can be acquired, and the current location information of the object can be obtained based on the acquired detection information.

Also, the server 200 or the auxiliary computing device 300 may obtain virtual location information for at least one object based on the location information of the objects.

For example, the secondary computing device 300 may acquire coordinates in the virtual reality corresponding to coordinates included in the location information in the user's reality as virtual location information of the character corresponding to the user 800 in the virtual reality. Can be.

The server 200 may provide at least one of object location information and virtual location information to the secondary computing device 300.

The auxiliary computing device 300 may calculate virtual location information based on the acquired location information.

Also, the auxiliary computing device 300 may obtain a virtual reality image based on the virtual location information.

For example, the secondary computing device 300 acquires a virtual reality image area in the virtual environment based on the acquired virtual location information, in which a virtual environment required for a virtual experience is built by a program or application stored in the secondary computing storage unit 320. can do. The secondary computing device 300 may obtain a virtual reality image for the virtual reality image area.

The secondary computing device 300 may provide a virtual reality image to the wearable display device 400.

The wearable display device 400 may output a virtual reality image to the user 800.

In addition, the server 300 may provide a virtual reality image to the monitoring display 700.

The server 300 may provide the virtual reality image acquired from the secondary computing device 300 to the connected monitoring display 700.

In addition, when the server 300 is connected to the plurality of auxiliary computing devices 300, the server 300 may acquire a virtual reality image from at least one auxiliary computing device 300 among the plurality of auxiliary computing devices 300, The acquired virtual reality image may be provided to the connected monitoring display 700.

For example, the server 300 may obtain a selection of the secondary computing device 300 from which the virtual reality image is acquired from the secondary computing device 300 connected to the server 300 through the server input unit 230, and the selected secondary The virtual reality image acquired from the computing device 300 may be provided to the monitoring display 700.

In addition, the server 300 may acquire virtual location information from the secondary computing device 300 and may acquire a virtual reality image based on the acquired virtual location information and a virtual camera location in a preset virtual environment.

In addition, the server 300 may provide the acquired virtual reality image to the connected monitoring display 700.

The monitoring display 700 may output a virtual reality image acquired from the server 300.

Also, the input device 500 may be provided in connection with at least one of the server 200, the auxiliary computing device 300, and the wearable display device 400.

Also, the input device 500 may be provided with at least one marker.

The input device 500 may be provided to be possessed by each user 800.

For example, the user 800 may carry the input device 400 in hand.

According to an embodiment, the server 200 may acquire location information of the input device 500 based on the detection information obtained from the detection device 100. In addition, the location information of the input device 500 may include at least one of the location information of the input device 500 in the tracking area 600 and the direction information of the input device 500.

The auxiliary computing device 300 may determine the orientation direction of the virtual object corresponding to the input device 500 in the virtual environment based on the location information of the input device 500.

Also, the auxiliary computing device 300 may obtain a virtual image in which a directional direction of a virtual object corresponding to the input device 500 is considered in a virtual environment.

For example, the auxiliary computing device 300 may obtain a virtual image in which a gun corresponding to the input device 500 in a virtual environment is directed in a direction corresponding to the direction of the input device 500.

In addition, the auxiliary computing device 300 may obtain a virtual image in which an event is generated according to an event generation command of the user 800 through the input device 500 in a virtual environment.

For example, when the switch provided to the input device 500 is pressed by the user 800, the secondary computing device 300 may acquire a virtual image of firing a gun possessed by a character corresponding to the user 800 in a virtual environment. Can be.

7 is a schematic diagram illustrating a method for tracking an object according to an embodiment.

Referring to FIG. 7, the method for tracking an object may acquire information about the object using a sensor provided externally, and determine the position of the object based on the obtained information about the object.

Hereinafter, a case where the object is the wearable display device 400 will be described with reference to FIG. 7.

Referring to FIG. 7, a marker M for identifying an object may be provided to the object.

The marker M may be provided to the subject to provide a criterion for identifying and tracking the subject.

In order to track an object, it is necessary to identify the object and the non-object configuration, and it is possible to identify the object by providing a marker M to the object.

In addition, when a plurality of objects are provided, it is necessary to identify each object, and for this purpose, the marker M provided to one object may be provided to be distinguishable from the marker M provided to the other object.

For example, the marker M provided to one object may be provided in a different pattern from the marker M provided to another object.

In addition, the pattern may include patterns having various meanings, such as a pattern formed by providing a plurality of markers M at different positions and an optical pattern provided on a display panel.

The pattern may be formed by marker coordinates of the marker M.

For example, three markers M are tracked by the detecting device 100, and the first marker coordinates MP1-1, the second marker coordinates MP1-2, and the third marker coordinates MP1 are detected information. -3) may be obtained, and the first marker coordinates MP1-1 to third marker coordinates MP1-3 may form a triangular pattern.

Also, the marker M may be provided as a passive marker that reflects or absorbs the optical signal transmitted from the light emitting unit 110 and an active marker capable of transmitting the optical signal itself.

As an example, the passive marker may include a three-dimensional model to which a light-reflecting material is attached, paper on which a recognizable code is printed, reflective tape and the like.

In addition, the active marker may include an LED module, a radio wave generator, and the like.

According to an embodiment, the object may be provided with at least one marker (M).

For example, when the virtual reality control system 10 tracks the position of only one object, only one marker M may be provided to the object.

In addition, even if the virtual reality control system 10 tracks the location of only one object, a plurality of markers M may be provided to the object.

In addition, when the virtual reality control system 10 tracks positions with respect to a plurality of objects, a plurality of markers M may be provided to one object to form a pattern to identify each of the plurality of objects.

For example, when an object tracking a position in the virtual reality control system 10 is provided as two types of a wearable display device 400 and an input device 500, the wearable display device 400 has a marker as a first pattern ( M) may be provided, and the input device 500 may be provided with a marker (M) in a second pattern.

The first pattern and the second pattern are different from each other, and when the first pattern is detected when tracking the location, the first pattern and the second pattern may be identified as the wearable display device 400, and when the second pattern is detected, the input device 500 can do.

In the above, when a plurality of objects are provided, it has been described that markers M provided to each of the plurality of objects are provided by forming a pattern to identify each of the plurality of objects, but is not limited thereto, and one object is provided. Even in the case, markers M provided to the object may be provided by forming a pattern.

In addition, the pattern of the marker M provided to the object may be used to identify the user 800.

For example, the first pattern may be identified as a wearable display device worn by the first user, and the second pattern may be identified as an input device carried by the first user. Also, the third pattern may be identified as a wearable display device worn by the second user, and the fourth pattern may be identified as an input device carried by the second user.

When describing the tracking of the object, the server 200 may obtain information about the object from the detecting device 100, and may acquire detecting information about the position of the object based on the obtained information. In addition, the server 200 may calculate location information of the object based on the detection information.

When describing a technology in which the detecting device 100 provides information about an object to the server 200, the light emitting unit 110 of the detecting device 100 transmits a signal to at least a part of the tracking area 600 can do.

For example, when the light emitting unit 110 is an infrared LED, the light emitting unit 100 may transmit an infrared signal to at least a portion of the tracking area 600.

In addition, the sensing unit 120 may provide information obtained from the outside to the server 200.

For example, when the sensing unit 120 is a camera, the sensing unit 120 may provide an image signal acquired from the outside to the server 200.

Although only one sensing unit 120 is illustrated in FIG. 7, the present invention is not limited thereto, and as described in FIG. 6, a plurality of sensing units 120 may be provided, and each of the plurality of sensing units 120 may be provided. May provide the obtained information to the server 200.

The server 200 may determine the location of the object based on the information obtained from the sensing unit 120.

The server 200 may determine whether information about the marker M is included in the information obtained from the sensing unit 120. In addition, the server 200 may identify an object based on the pattern of the marker M when the information obtained from the sensing unit 120 includes information about the marker M.

For example, when the first pattern is included in the information obtained from the sensing unit 120, the server 200 may identify that it is a wearable display device 400.

A plurality of patterns may exist in the information obtained from one sensing unit 120, and the server 200 may identify a plurality of patterns.

Such a pattern may be stored in advance in the server 200, and the server 200 may determine that the corresponding pattern exists when a previously stored pattern exists in the acquired information, and identify an object corresponding to the pattern. Can be.

The server 200 may determine the location of the object based on the information obtained from the sensing unit 120.

Meanwhile, a representative point RP may be set for each pattern previously stored in the server 200.

The representative point RP may be a point representing a pattern.

The representative point RP may exist outside the pattern.

For example, the representative point RP may be set to a point spaced apart from a plane formed by the first marker coordinates MK1-1, the second marker coordinates MK1-2, and the third marker coordinates MK1-3. have.

When a pattern through a plurality of markers M is provided, coordinate information for a plurality of markers M included in the pattern is obtained, and the server 200 is an object provided with a representative point RP representing the pattern It can be obtained with location information.

Therefore, the server 200 may track the object by obtaining the position information of the object.

Position tracking of an object according to an embodiment is not limited to the above-described method, and various types of position tracking methods may be used depending on selection.

According to an embodiment, when the sensing unit 120 is provided as an image sensor, the sensing unit 120 may acquire an image for the outside and may acquire location information about an object based on the acquired image. .

As an example, when the sensing unit 120 illustrated in FIG. 7 is provided to the wearable display device 400, the sensing unit 120 is provided on one side of the wearable display device 400 so that the sensing unit 120 is provided on the wearable display device 400. It is possible to obtain image information on the outside of the wearable display device 400 by pointing from the inside to the outside.

Also, the wearable display device 400 may provide image information acquired by the auxiliary computing device 300.

According to an embodiment, the wearable display device 400 may provide image information to the auxiliary computing device 300 at a predetermined cycle.

For example, the wearable display device 400 may provide image information to the secondary computing device 300 in the same cycle as the cycle of obtaining image information through the sensing unit 120.

The auxiliary computing device 300 may acquire at least one feature point from the acquired image information.

According to an embodiment, the auxiliary computing device 300 may acquire an object included in image information as a feature point.

According to an embodiment, the auxiliary computing device 300 may acquire an object having a predetermined size or more among objects included in image information as a feature point.

The auxiliary computing device 300 may identify an object included in the image information, and acquire an object having a predetermined size or more among the identified objects as a feature point. Also, the auxiliary computing device 300 may determine the size of the object based on the number of pixels occupied by the object included in the image information.

According to an embodiment, the auxiliary computing device 300 may acquire a preset type of objects among the objects included in the image information as feature points.

For example, when a ball type object is previously set, the auxiliary computing device 300 may acquire a ball type object, such as a baseball ball, a soccer ball, and a basketball ball, included in image information as a feature point.

According to an embodiment, the auxiliary computing device 300 may acquire a marker included in image information as a feature point.

The secondary computing device 300 may acquire markers such as barcodes and QR codes included in image information as feature points.

Also, the auxiliary computing device 300 may determine the location of the feature point included in the image information.

The auxiliary computing device 300 may determine at least one of a position change and a size change of the feature point based on image information obtained from the wearable display device 400.

The auxiliary computing device 300 may determine a moving direction and a moving distance of the wearable display device 400 based on the position change direction, the position change amount, and the size change amount of the feature point.

For example, the auxiliary computing device 300 may determine a change in the location of the feature point based on image information obtained from the wearable display device 400.

The auxiliary computing device 300 may determine a moving direction and a moving distance of the wearable display device 400 based on the amount of change in the position of the feature point.

The auxiliary computing device 300 may determine a moving direction and a moving distance of the wearable display device 400 based on the position change direction, the position change amount, and the size change amount of the feature point.

For example, the secondary computing device 300 may determine the location of the feature points included in the first image information obtained at the first time point and the location of the feature points included in the second image information obtained at a second time point after the first time point. As a result of comparison, when the position of the feature point of the first image information moves to the right in the second image information, it may be determined that the wearable display device 400 has moved to the left.

In addition, when the location of the feature point is changed, the auxiliary computing device 300 may determine the moving distance of the feature point.

The auxiliary computing device 300 may determine a moving distance of the feature point based on the number of pixels between the location of the feature point in the first image information and the location of the feature point in the second image information.

Alternatively, the auxiliary computing device 300 may determine the moving distance of the feature points based on the coordinates of the feature points in the first image information and the coordinates of the feature points in the second image.

In addition, as an example, the auxiliary computing device 300 may determine a moving direction and a moving distance of the wearable display device 400 based on the size change amount.

The auxiliary computing device 300 compares the size of the feature points included in the first image information obtained at the first time point with the size of the feature points included in the second image information obtained at a second time point that is later than the first time point. As a result, when the position of the feature point of the first image information moves to the right in the second image information, it may be determined that the wearable display device 400 has moved to the left.

Accordingly, the auxiliary computing device 300 may track the position of the object based on a change in the relative position of the object from a preset initial position.

8 is a diagram illustrating that a virtual reality image 452 is output through the wearable display device 400 according to an embodiment.

Referring to FIG. 8, the virtual reality providing system 10 may provide a virtual reality image 452 of at least a portion of the virtual environment to the user 800 through the wearable display device 400.

The virtual environment may include a background, a virtual structure, virtual objects and characters.

The virtual environment may be built by the secondary computing device 300 using location information of an object tracked in reality as illustrated in FIG. 6.

For example, a character corresponding to the user 800 is provided in the virtual environment, and the character is based on location information obtained by tracking the wearable display device 400 and the input device 500 worn by the user 800. It can be generated through computer graphics technology using skeletons, polygon meshes, etc.

More specifically, the secondary computing device 300 generates the rendered image of the character's head and hands using the virtual location information of the wearable display device 300 and the input device 500 and based on the generated rendered image By creating rendered images of different body parts, the character can be implemented in a virtual environment. As a result, a portion of the body part of the user 800 that is not tracked by the detecting device 100 or where location information is not obtained may also be displayed as a rendered image in a virtual environment.

As another example, the virtual environment may be provided with a virtual object such as a hand corresponding to the input device 500 carried by the user 800 and a tool necessary for a character in the virtual environment.

As another example, the virtual object may include an object that is implemented in a virtual environment and used by the user 800 during a virtual experience.

The virtual structure can be provided at a predetermined location in the virtual environment.

In addition, a preset function may be executed or a preset effect may occur by the character using the virtual structure.

The virtual structure will be described in more detail later.

The character may include an NPC character and a user character provided by an application or program stored in advance in the auxiliary computing device 300.

In a virtual environment, the location information of a character or object may be represented as virtual location information.

Meanwhile, in reality, the location information may include at least one of an object's location coordinate and a directional direction.

For example, the location information may be the location coordinates of the object located on the tracking area 600.

The server 200 may store coordinate values for the tracking area 600 in advance.

The server 200 may store in advance a coordinate system for the tracking area 600. The coordinate system may be at least one of a plane coordinate system, an orthogonal coordinate system, a polar coordinate system, a spatial coordinate system, a cylindrical coordinate system, and a spherical coordinate system.

The server 200 may obtain coordinate values in the tracking area 600 of the object based on the detection information and the coordinate system for the tracking area 600. In addition, the server 200 may acquire coordinate values in the tracking area 600 of the acquired object as location information.

For example, when the detection information is an infrared image, the server 200 detects the tracking area 600 of the marker based on the location of the marker corresponding to the object in the infrared image and the installation location of the detecting device 100 that provided the infrared image. ). In addition, the server 200 may determine a pattern formed by the marker based on the coordinate values in the tracking area 600 of the marker, and may identify an object corresponding to the pattern formed by the marker. In addition, the server 200 may acquire the representative point RP of the object based on the pattern formed by the marker and the coordinate value in the tracking area 600 of the marker, and obtain the coordinate value of the representative point RP of the object. It can be obtained by the location information of the object.

The server 200 may provide location information to the secondary computing device 300.

The auxiliary computing device 300 may store coordinate values for the virtual environment in advance.

The auxiliary computing device 300 may previously store a coordinate system for a virtual environment. The coordinate system may be at least one of a plane coordinate system, an orthogonal coordinate system, a polar coordinate system, a spatial coordinate system, a cylindrical coordinate system, and a spherical coordinate system.

The auxiliary computing device 300 may obtain coordinate values in the virtual environment of the object based on the location information and the coordinate system for the virtual environment. In addition, the auxiliary computing device 300 may acquire coordinate values in the virtual environment of the acquired object as virtual location information.

For example, the auxiliary computing device 300 may acquire coordinate values in a virtual environment corresponding to coordinate values included in location information, and obtain coordinate values in the obtained virtual environment as virtual location information.

The secondary computing device 300 may obtain a virtual reality image 452 to be output to the user 800 based on the virtual location information.

The virtual reality image 452 may constitute at least a part of an image of the virtual reality provided to the user 800 through the wearable display device 400.

According to an embodiment, the auxiliary computing device 300 may acquire virtual location information of the wearable display device 400 as virtual location information of the virtual camera, based on the virtual location information of the virtual camera and the orientation direction of the virtual camera By obtaining the viewing range 451 of the virtual camera.

The secondary computing device 300 may obtain the directional direction of the virtual camera based on the directional direction included in the location information of the wearable display device 400.

In addition, the auxiliary computing device 300 may acquire a predetermined region in the directional direction of the virtual camera as the field of view 451 of the virtual camera.

Meanwhile, the field of view 451 of the virtual camera may be obtained by specific virtual location information in the virtual environment in addition to the virtual location information of the wearable display device 400.

In addition, the auxiliary computing device 300 may acquire a virtual reality image 452 corresponding to the field of view 451 of the virtual camera in the virtual environment.

The secondary computing device 300 may provide the virtual reality image 452 to the wearable display device 400.

The wearable display device 400 may output the acquired virtual reality image 452 to the user 800 through the wearable display screen output unit 450. As the virtual reality image 452 is continuously output, the user 800 may be provided with a virtual reality or a virtual experience.

Hereinafter, when a virtual reality or a virtual experience is provided to at least two or more users 800 by the virtual reality control system 10 with reference to FIGS. 9 to 23, rules of each of the plurality of users 800 are set in advance. In the case of satisfying, a collaborative system in which a preset effect or function occurs or is performed will be described.

Virtual spaces, virtual reality, and virtual experiences to be described below may be mixed in the same meaning, and virtual location information and virtual location may be mixed in the same meaning.

The collaboration system may include a method of generating a collaboration effect in the virtual reality or performing a collaboration function in consideration of at least one of an absolute or relative time and a location or behavior of at least two or more users 800 receiving virtual reality. have. At this time, the position change or action of the user 800 may be implemented as a change or action of the virtual position of the character 900 corresponding to the user 800 in the virtual space.

The collaboration system may be implemented by changing the virtual reality image 452 provided to the user 800 through the wearable display device 400 by at least one of the secondary computing device 300 and the server 200.

For example, when two or more users 800 move to a specific location before a certain period of time has elapsed, an effect of destroying a virtual object in virtual reality is output to the wearable display device 400 or each user 800 is fixed. When the input device 500 is moved from top to bottom at a time interval, a function of moving a virtual structure in virtual reality output to the wearable display device 400 may be performed.

9 to 12 show that when a plurality of users 800 according to an embodiment moves to a preset position in the tracking area 600 described in FIG. 6, an effect occurs on the target object V1 in virtual reality It is a figure to show.

Hereinafter, the user 800 may include a first user 801 and a second user 802, and the character 900 may include a first character 901 and a second character 902, The secondary computing device 300 may include a first secondary computing device 301 and a second secondary computing device 302, and the wearable display device 400 may include a first wearable display device 401 and a second The wearable display device 402 may be included, and the input device 500 may include a first input device 501 and a second input device 502. In addition, parts that overlap with the contents described above may be omitted for more detailed description.

9 is an exemplary view showing a real space before collaboration is performed according to an embodiment.

Referring to FIG. 9, virtual reality may be provided to the first user 801 and the second user 802 in the tracking area 600 by the virtual reality control system 10.

The first user 801 and the second user 802 may share the same virtual space while sharing one tracking area 600 or receive the same virtual space in different tracking areas 600.

For example, the first user 801 and the second user 802 share the tracking area 600 in the same real space or the server 200 while receiving different tracking areas 600 in separate real spaces , The same virtual space may be shared through the auxiliary computing device 300 and the wearable display device 400.

At least one of the first auxiliary computing device 301, the first wearable display device 401, and the first input device 501 may be provided to the first user 801 as the user 800 in FIG. 6. have. Similarly, at least one of the second auxiliary computing device 302, the second wearable display device 402, and the second input device 502 may be provided to the second user 802.

The tracking area 600 may include a collaboration area 610.

The collaboration area 610 may include an area in which the user 800 should move in reality according to the collaboration system.

The collaboration area 610 may be located within the tracking area 600. Meanwhile, the collaboration area 610 may be located outside the boundary of the tracking area 600 or the tracking area 600.

The collaboration area 610 may be recognized as coordinates in the tracking area 600 or may be recognized as polygons or circles having a certain area.

At least one of the secondary computing device 300 and the server 200 may recognize that the user 800 is located in the collaboration area 610.

For example, the secondary computing device 300 uses the location information or the detection information obtained from the server 200 or the detecting device 100 and the location information of the collaboration area 610 to allow the user 800 to collaborate. It can be determined whether it is located within 610.

The collaboration area 610 may include a first collaboration area 611 and a second collaboration area 612.

When a collaboration system is provided to the first user 801 and the second user 802, the first user 801 is located in the first collaboration area 611 and the second user 802 is the second collaboration area 612 ), a collaboration effect or a collaboration function may be generated or performed.

The first collaboration area 611 and the second collaboration area 612 may be implemented at different locations within the tracking area 600. However, the first collaboration area 611 and the second collaboration area 612 may include the same or overlapping areas.

10 is an exemplary diagram illustrating a virtual reality image 452 provided to a first user 801 before collaboration is made according to an embodiment.

The virtual reality image 452 may include an image corresponding to a field of view of a virtual camera existing in a virtual space generated by the secondary computing device 300.

Referring to FIG. 10, the virtual reality image 452 provided to the first user 801 includes the first character 901, the second character 902, the first character virtual location 911, and the second character virtual location ( 912), a target object V1, a line C representing a virtual coordinate system, a first virtual collaboration area 621, and a second virtual collaboration area 622.

The first auxiliary computing device 301 sets the virtual coordinate system C in the virtual space and the first character 901, the second character 902, and the first character virtual location 911 based on the virtual coordinate system C. , The second character virtual location 912, the target object V1, the first virtual collaboration area 621, and the second virtual collaboration area 622 may be set or disposed.

The line C representing the virtual coordinate system may be a line representing a virtual coordinate system that is at least one of a coordinate system that can be considered by a person skilled in the art, such as a Cartesian coordinate system (a Cartesian coordinate system), a polar coordinate system, and a spherical coordinate system.

The line C representing the virtual coordinate system may or may not be expressed in the virtual reality image 452.

The first character 901 and the second character 902 may respectively correspond to the first user 801 and the second user 802 in the virtual space.

The first character 901 and the second character 902 use the virtual location information calculated based on the location information of the first user 801 and the second user 802 to use the server 200 and the auxiliary computing device ( 300).

As an example, the first auxiliary computing device 301 is a first corresponding to the first user 801 in the virtual space based on the virtual location information of the first wearable display device 401 and the first input device 501. Character 901 can be created. At this time, the head and body parts of the first character 901 are based on the virtual location information of the first wearable display device 401 and the hand and arm parts of the first character 901 are the first input device 501. It can be generated based on the virtual location information.

The virtual reality image 452 provided to the first user 801 may include all of the first character 901 or only a part of the first character 901 according to the position of the virtual camera in the virtual space. Alternatively, the virtual reality image 452 may not include the first character 901.

In one embodiment, the virtual reality image 452 may display only a body part such as the upper body or hand of the first character 901.

The first character virtual location 911 and the second character virtual location 912 correspond to the positions of the first user 801 and the second user 802 in reality, so that the first characters 901 and the second in the virtual space. It may indicate the position of the character 902.

Meanwhile, the first character virtual location 911 and the second character virtual location 912 are based on the detection information of the first user 801 and the second user 802 tracked by the detecting device 100. As calculated by the auxiliary computing device 300 or the server 200, the first character virtual location information and the second character virtual location information may be used in the same sense.

The first character virtual location 911 and the second character virtual location 912 may or may not be displayed in the virtual reality image 452.

The first virtual collaboration area 621 and the second virtual collaboration area 622 may include areas corresponding to the first collaboration area 611 and the second collaboration area 612 of FIG. 9.

The first virtual collaboration area 621 and the second virtual collaboration area 622 may be implemented in virtual coordinates in a virtual space or may be implemented in a preset shape.

In one embodiment, the first virtual collaboration area 621 may be implemented as a virtual structure, and the second virtual collaboration area 622 may be implemented as part of the background constituting the virtual space.

The first virtual collaboration area 621 and the second virtual collaboration area 622 may or may not be displayed in the virtual space.

On the other hand, since the collaboration system is provided to the first user 801 and the second user 802, the secondary computing device 300 is worn to induce collaboration between the first user 801 and the second user 802. A guide mark may be output through the type display device 400.

For example, in the virtual reality image 452 output to the first wearable display device 401, a method of moving from the first character 901 to the first virtual collaboration area 621 is indicated by an arrow or the like, or the first virtual A glittering effect may be displayed on the collaboration area 621 differently from other surrounding areas. At this time, the second virtual collaboration area 622 may also display the above-described effects and the like in the same way.

The target object V1 may include a virtual object that is an object for which an effect is displayed according to collaboration between the first user 801 and the second user 802.

The target object V1 has a preset shape, but the shape may be changed according to collaboration. Alternatively, the target object V1 does not exist prior to collaboration, but may be generated after collaboration and displayed on the wearable display device 400.

The target object V1 may be implemented as part of the background constituting the virtual space.

11 and 12 are exemplary views illustrating a case where collaboration is performed by the first user 801 and the second user 802 in real and virtual spaces.

Referring to FIG. 11, the first user 801 is located in the first collaboration area 611 and the second user 802 is located in the second collaboration area 612, so that collaboration can be achieved.

In one embodiment, the first user 801 and the second user 802 are located outside the collaboration area 610 as shown in FIG. 9 at the first time point and the first user 801 as shown in FIG. 11 at the second time point. Is located in the first collaboration area 611 and the second user 802 is located in the second collaboration area 612, the secondary computing device 300 may include the first user 801 and the second user ( 802).

In another embodiment, the first user 801 and the second user 802 are located in the collaboration area 610 as shown in FIG. 11 at the first time point, and the first user 801 as shown in FIG. 9 at the second time point. ) Is located in the first collaboration area 611 and the second user 802 is located outside the second collaboration area 612, the secondary computing device 300 may include the first user 801 and the second user at the second time point. According to (802), it can be determined that collaboration has been achieved.

If the location of the user 800 is changed outside or within the collaboration area 610, at least one moving method may be used.

For example, the user 800 may move in or out of the collaboration area 610 using various movement paths.

Meanwhile, the first user 801 and the second user 802 may collaborate by being located in the first collaboration area 611 and the second collaboration area 612 while satisfying a preset condition, respectively.

The preset condition may include a condition for at least one of a location order, method, and time.

For example, the preset condition may include a condition in which the first user 801 is first located in the first collaboration area 611 and the second user 802 is located in the second collaboration area 612 before a predetermined time elapses. Can.

As another example, the preset condition may include a condition in which the first user 801 is first located in the first collaboration area 611 and a second user 802 is located in the second collaboration area 612 after a certain time has elapsed. have.

As another example, the preset condition is that either one of the first user 801 or the second user 802 is first the first collaboration area 611 or the second collaboration area 612 either the collaboration area 610 It may include a condition that is located in the other user is located in the rest of the collaboration area (610).

As another example, the preset condition is that after the first user 801 operates on the first input device 501 while the first user 801 is located in the first collaboration area 611, the second user 802 determines the second collaboration area 612. ) And may include conditions for operating the second input device 502.

Referring to FIG. 12, when collaboration is performed by the first user 801 and the second user 802, a preset effect may be generated on the target object V1 in the virtual space.

The first character 901 and the second character 902 are respectively moved as the first user 801 and the second user 802 move in and out of the first collaboration area 611 and the second collaboration area 612, respectively. The first virtual collaboration area 621 and the second virtual collaboration area 622 may be moved.

When the first character 901 and the second character 902 are located in the first virtual collaboration area 621 and the second virtual collaboration area 622, the shape of the target object V1 may be changed. At this time, the secondary computing device 300 may determine whether collaboration has been performed using the first character virtual location 911 and the second character virtual location 912.

For example, in the secondary computing device 300, the second character virtual location 912 is the second virtual collaboration area (with the first character virtual location 911 within the first virtual collaboration area 621 or within a predetermined range). 622) or within a certain range, the first user 801 and the second user 802 determine that the collaboration has been made and change the shape of the target object V1 or apply a special effect to the target object V1. Can occur.

In the context as described with respect to FIG. 11, before and after the first character 901 and the second character 902 are located in the first virtual collaboration area 621 and the second virtual collaboration area 622, respectively. Collaboration can take place if the conditions are met.

For example, the secondary computing device 300 receives the first input signal by the first input device 501 while the first character virtual location 911 is in the first virtual collaboration area 621, and a predetermined time If the second input signal is transmitted by the second input device 502 while the second character virtual location 912 is in the second virtual collaboration area 622 after the elapse, it is determined that the collaboration has been performed and the target object V1 ) Can be manipulated.

In the above, it has been described that the target object V1 may be changed when collaboration is performed, but the background, the virtual structure, etc. constituting the virtual space may be changed, generated, and removed.

Hereinafter, a process of collaborating through operations of the plurality of users 800 will be described with reference to FIGS. 13 to 16.

13 is an exemplary view showing a real space before collaboration is performed by a plurality of users 800 using the input device 500.

14 is an exemplary view showing a real space after collaboration is performed by a plurality of users 800 using the input device 500.

15 is an exemplary view showing a virtual space before collaboration is performed by a plurality of users 800 using the input device 500.

16 is an exemplary view illustrating a virtual space after collaboration is performed by a plurality of users 800 using the input device 500.

13 and 14, an operation of the user 800 for collaboration may be recognized according to a change in the position of the input device 500. At this time, the secondary computing device 300 may track the operation of the user 800 using the location information of the input device 500 and determine that the collaboration has been performed when the operation of the user 800 satisfies a specific condition. .

The first user 801 and the second user 802 may have the first input device 501 and the second input device 502, respectively, and are illustrated in FIGS. 13 and 14 as an example of an operation for collaboration. As described above, the first user 801 and the second user 802 may perform an operation of lowering the first input device 501 and the second input device 502 from above the head, respectively.

As another example, the first user 801 and the second user 802 may perform an operation of moving the input device 500 in the form of a virtual figure.

The operations of the first user 801 and the second user 802 may be performed simultaneously or at a predetermined time difference.

The operations of the first user 801 and the second user 802 may be performed singly or repeatedly in a predetermined order.

Meanwhile, the operations of the first user 801 and the operations of the second user 802 for collaboration may be different operations or may include different partial operations.

For example, the first input device 501 moves up/down by the first user 801 and the second input device 502 moves left/right by the second user 802 after a predetermined time elapses. When the moving operation is performed, the auxiliary computing device 300 may determine that collaboration has been performed by the first user 801 and the second user 802.

Collaboration by the plurality of users 800 may be achieved by satisfying additional conditions in addition to the operation of the input device 500.

The secondary computing device 300 inputs the first input to at least one of a time before the first user 801 and the second user 802 start a specific operation, an intermediate time at which the operation is performed, and a time when the operation ends. At least one input signal of the signal and the second input signal may be received. The input signal may be transmitted to the secondary computing device 300 when the input device 500 is operated by the user 800.

For example, a button provided on the first input device 501 is pressed by the first user 801 and the position of the first input device 501 is changed at the same time, and after a certain time elapses, the second input device 502 The position of the second input device 502 may be changed at the same time that the provided button is pressed by the second user 802. At this time, the secondary computing device 300 may include the first user 801 and the second user. According to (802), it can be determined that collaboration has been achieved.

15 and 16, the virtual reality image 452 output to the first user 801 through the first wearable display device 401 includes a first character 901, a second character 902, and a first The first character virtual location 921, the second character virtual location 922, and the first collaboration object V2_1 to the third collaboration object V2_3 may be included.

The virtual reality image 452 may indicate the viewpoint of the virtual camera in the virtual space.

For example, as illustrated in FIG. 15, the virtual reality image 452 may include an image at the first person view point of the first character 901. At this time, a virtual object corresponding to the first input device 501 carried by the first user 801 is displayed on the virtual reality image 452, and the virtual object is a hand shape as a body part of the first character 901 It may include.

The first character virtual location 921 and the second character virtual location 922 are based on the location information of the first user 801 and the second user 802 in reality, the secondary computing device 300 or the server 200 Can be calculated by

For example, the first character virtual location 921 and the second character virtual location 922 may be calculated based on location information obtained by tracking at least one of the wearable display device 400 and the input device 500. .

Hereinafter, the first character virtual location 921 and the second character virtual location 922 are the first input device 501 and the second input device to describe in more detail the process of collaboration by the operation of the user 800. It is assumed that it is calculated based on the location information of 502.

The first character virtual location 921 and the second character virtual location 922 may or may not be displayed on the virtual reality image 452 in a dot shape, a cube shape, or the like.

The first collaboration object V2_1 to the third collaboration object V2_3 are virtual objects required for collaboration by the first user 801 and the second user 802, and virtual or virtual effects that are changed or displayed by the collaboration. It may include at least one of the objects.

For example, the first collaboration object V2_1 and the second collaboration object V2_2 may include a lever-shaped or switch-shaped virtual object that the first character 901 and the second character 902 can operate. .

Meanwhile, at least one of the first collaboration object V2_1 to the third collaboration object V2_3 may include a virtual object corresponding to the real object, as described later.

When the first collaboration object V2_1 to the third collaboration object V2_3 have at least one state and a specific condition is satisfied, the state may be changed from one state to another state by the auxiliary computing device 300.

As an example, the first collaboration object V2_1 has a lever shape, but has an inactive state and an active state as illustrated in FIGS. 15 and 16, and operates when the first collaboration object V2_1 is in an inactive state or an active state When the condition is satisfied, it is changed to an active state or an inactive state, and a shape may be changed correspondingly. In the operating condition, the first character virtual location 921 is moved from the top to the bottom according to the movement of the first input device 501 while the first character virtual location 921 is located within a predetermined range from the first collaboration object V2_1. It may include conditions for moving in the direction.

The state of the third collaboration object V2_3 may be changed by the first collaboration object V2_1 and the second collaboration object V2_2.

As an example, the first collaboration object V2_1 and the second collaboration object V2_2 are switch-shaped and have an active state and an inactive state, respectively, and the third collaboration object V2_3 is a door shape and may have an open state and a closed state. . At this time, as shown in FIGS. 15 and 16, the first collaboration object V2_1 and the second collaboration object V2_2 are simultaneously or constant in an inactive state by the first character 901 and the second character 902. When each time is changed to an active state at a time interval, the third collaboration object V2_3 is changed from a closed state to an open state and a shape can be changed correspondingly.

In the above, the case in which the operation of the user 800 for collaboration is dependent on the position change of the input device 500 is described, but is not limited thereto, and the position change of the object that can be recognized by the detecting device 100 The operation of the user 800 may be recognized. At this time, the object may be continuously provided to the user 800 while the virtual experience is provided to the user 800 or may be separated from the user 800 during the virtual experience.

Hereinafter, a collaboration system using a real object (RO) will be described with reference to FIGS. 17 and 18.

17 is an exemplary view illustrating a real space including a real object RO according to an embodiment.

18 is an exemplary diagram illustrating that collaboration is performed using at least one real object (RO) in a virtual space according to an embodiment.

The real object RO may include an object existing in the real space.

The real object RO may be disposed within the tracking area 600 to be tracked by the detecting device 100. Meanwhile, the real object RO may be fixedly disposed in a preset area in the tracking area 600 while the virtual reality is provided to the user 800 or may be moved or moved by the user 800 or itself. Further, the real object RO may be moved or moved in or out of the tracking area 600 while the virtual reality is provided to the user 800.

A marker M may be attached to the real object RO to be tracked by the detecting device 100 like an object. Alternatively, the real object RO may be tracked by the detecting device 100 using the feature points described above without the marker M.

The server 200 or the secondary computing device 300 may implement a virtual object corresponding to the real object RO in the virtual space using the detection information of the real object RO tracked by the detecting device 100. have.

For example, the auxiliary computing device 300 may calculate virtual location information in the virtual space using the location information of the marker M attached to the real object RO and implement the virtual object based on this.

As another example, the real object RO is disposed in the real space, and the auxiliary computing device 300 may implement a virtual object in a shape corresponding to a position corresponding to the real object RO.

The real object RO may include objects or objects that humans contact, such as devices, mechanical structures, models, and industrial facilities.

For example, as illustrated in FIG. 17, the real object RO may include piping equipment. More specifically, the Real Object (RO) is a valve model and may include a threaded handle to regulate the flow of fluid. At this time, the user 800 may operate the screw handle included in the real object RO while the virtual experience is being provided.

The virtual reality control system 10 may provide the user 800 with a virtual experience corresponding to the shape and type of at least one real object RO disposed in the real space.

For example, as illustrated in FIG. 17, a tracking area 600 in which factory equipment is disposed may be provided to the first user 801 and the second user 802 in the real space, and may be provided in response to the real space. 1 user 801 and second user 802 may be provided with a virtual experience of a gas spill incident response training that may occur in a factory.

Collaboration using a real object (RO) may be performed while a virtual experience is provided to the first user 801 and the second user 802.

Collaboration by the first user 801 and the second user 802 is performed according to the location or operation of each user as described in FIGS. 9 to 16, but the real object RO is processed in the process. Can be used.

For example, as illustrated in FIG. 18, the first character 901 corresponding to the first user 801 and the second character 902 corresponding to the second user 802 have a gas outflow condition due to a piping abnormality. The generated virtual environment can be provided. In the virtual environment, the first collaboration object V2_1 and the second collaboration object V2_2 correspond to the valve-shaped real object RO, and the third collaboration object V2_3 corresponds to the pipe-shaped real object RO. Can. At this time, gas may be leaked from the third collaboration object V2_3, the first collaboration object V2_1 is operated by the first character 901, and the second collaboration object V2_2 by the second character 902 ) Is operated, the third collaboration object V2_3 may no longer leak gas, and the collaboration may be performed.

Meanwhile, in addition to recognizing the location or motion of the user 800, the secondary computing device 300 recognizes the movement of the real object RO itself using the detecting device 100 or a mechanical device and based on this, collaboration is performed. You can also determine whether it has been done.

The real object RO and the corresponding virtual object may not have the same shape. For example, the real object (RO) is a rotatable handle shape for the user 800 to contact and operate, but the corresponding virtual object may include a handle but a valve shape including a joint to be attached to the pipe. .

When the real object RO corresponds to the virtual object in the virtual space, an effect occurring in the virtual object may occur in the real object RO in the same or similar manner.

For example, as illustrated in FIG. 18, when gas is generated in the third collaboration object V2_3, gas may be generated in the real object RO having a corresponding pipe shape in the real space. At this time, the gas generated in the real space is harmless to the human body, unlike the gas generated in the virtual space, but can increase the immersion of the virtual experience by stimulating the sense of touch or smell by contacting the user 800.

Hereinafter, with reference to FIGS. 19 and 20, some of the plurality of users 800 wear the wearable display device 400 while others do not wear the wearable display device 400. ), how the virtual experience is provided by the virtual reality control system 10 will be described.

19 is an exemplary view illustrating a real space when a virtual experience is provided to a user who wears the wearable display device 400 according to an embodiment and a user who does not wear the wearable display device 400.

Referring to FIG. 19, the first user 801 is attached to the tracking area 600 while having the first auxiliary computing device 301, the first wearable display device 401, and the first input device 501. Located and the second user 802 may be located in the manipulation area 630 while holding the manipulation device 520.

The first user 801 and the second user 802 may be provided with the same virtual experience by the virtual reality control system 10. At this time, the first user 801 is through the first wearable display device 401, the second user 802 is the virtual reality image 452 for the virtual experience through the manipulation device 520 or a separate display device ).

The first user 801 and the second user 802 may be provided with different virtual reality images 452 even though they are provided with the same virtual experience.

For example, the first user 801 is provided with an image looking at the virtual space from the first person point of view of the first character 901 corresponding to the first user 801, but the second user 802 is provided with the first character ( In 901), an image of a virtual space viewed from a third person view or an omniscient point of view may be provided.

The first user 801 may be tracked, such as location or movement by the detecting device 100 in the manner mentioned in FIG. 6, and the first auxiliary computing device 301 may be connected to the location information of the first user 801. Based on this, the virtual reality image 452 may be provided to the first user 801 through the first wearable display device 401.

The second user 802 may control the virtual experience provided to the first user 801 using the manipulation device 520.

The manipulation device 520 may include electronic devices or electronic devices capable of transmitting and receiving manipulation signals according to the manipulation of the user 800.

For example, the manipulation device 520 may include at least one of an input device such as a keyboard, mouse, joystick, or touch pad, and a terminal such as a tablet PC or a mobile phone.

The manipulation device 520 may transmit an manipulation signal to at least one of the server 200 and the first auxiliary computing device 301.

The manipulation device 520 may communicate with at least one of the server 200 and the first auxiliary computing device 301 through wired or wireless communication.

The manipulation device 520 may transmit an manipulation signal to at least one of the server 200 and the first auxiliary computing device 301 according to the manipulation of the second user 802.

When receiving the manipulation signal from the manipulation device 520, the first auxiliary computing device 301 may reflect it in the virtual experience provided to the first user 801 or the second user 802.

The manipulation area 630 is an area where the second user 802 is located, and may be separately located within a range for communicating with at least one of the first auxiliary computing device 301 and the server 200 and the manipulation device 520. .

Meanwhile, the manipulation area 630 may be included in the tracking area 600. At this time, a marker M is provided to the second user 802 so that the location or movement of the second user 802 can be tracked, and the first auxiliary computing device 301 is the location of the second user 802 Movement or movement may be reflected in a virtual experience provided to the first user 801 or the second user 802.

20 is an exemplary diagram illustrating a virtual space when a virtual experience is provided to a user who wears the wearable display device 400 according to an embodiment and a user who does not.

Referring to FIG. 20, a virtual reality image 452 including a first character 901 and a target object V1 may be provided to the first user 801 through the first wearable display device 401. . At this time, when an operation signal is transmitted from the operation device 520 to the first auxiliary computing device 301 by the operation of the second user 802, the operation effect E may be displayed on the target object V1.

The second user 802 may be provided with an image regarding a virtual experience provided to the first user 801 through the manipulation device 520, and may operate the manipulation device 520 in real time.

The target object V1 may include a virtual object, object structure, or background constituting a virtual space existing around the first character 901.

The operation effect E can be displayed on the target object V1 by operating the operation device 520.

For example, when the second user 802 touches the portion where the target object V1 is displayed in the image displayed on the manipulation device 520, the target object V1 may have a glowing effect and the first character 901 ) May recognize the glowing object V1.

In addition to the target object V1, the manipulation effect E may be displayed on the first character 901 and at the same time may be displayed on the plurality of target objects V1.

The manipulation effect E is a visual effect displayed on the virtual reality image 452 provided to the first user 801 or the second user 802 and an auditory effect that can be provided through the first wearable display device 301. It may include at least one of the enemy effects.

The time when the operation effect E is displayed or generated may be when the second user 802 operates the manipulation device 520 immediately or after a certain time has elapsed.

In the process where the first user 801 is provided with the virtual experience, the second user 802 uses the manipulation device 520 to generate the manipulation effect E on the target object V1 so that the first user 801 It is possible to increase immersion in the virtual experience or assist the first user 801 to experience the virtual reality smoothly.

In a process in which the first user 801 is provided with the virtual experience, the manipulation device 520 is operated by the second user 802 so that the first user 801 and the second user 802 can collaborate. .

Collaboration by the first user 801 and the second user 802 is similar to that described with reference to FIGS. 9 to 16, as the position change or operation of the first user 801 over time and the second user 802 It can be made through the operation of the operation device 520.

In the above, the case where the second user 802 affects the virtual reality provided to the first user 801 by operating the manipulation device 520 is not limited thereto, and instead of the manipulation device 520 or A microphone, a mechanical device, etc. may also be used together.

Hereinafter, a description will be given of a method in which the collaboration made by the plurality of users 800 described above is reflected in the evaluation system, because the virtual experience to which the evaluation system is applied is provided to the plurality of users 800.

The virtual experience provided to the user 800 by the virtual reality control system 10 may have various concepts, types, genres, or themes depending on the purpose or method of providing.

As an example, the virtual experience may include survival, disaster/accident response training, shooting, sports, first-person shooter (FPS), role-playing game (RPG), medical simulation, or shopping content.

The evaluation system is applied to a specific virtual experience, and after the virtual experience is ended, the user 800 may be provided with evaluation results calculated based on the experience process of the user 800.

The evaluation result may be provided to the user 800 with scores, visual information such as pictures, or acoustic information such as sounds.

For example, when a fire response training virtual experience is provided to the user 800, an evaluation result may be calculated based on whether a character corresponding to the user 800 in a virtual space responds in a predetermined order to a given fire situation. . At this time, the secondary computing device 300 may provide the evaluation result to the user 800 by numerically outputting the evaluation result calculated according to the evaluation system to the wearable display device 400. More specifically, the secondary computing device 300 tracks the position change and motion of the user 800 and evaluates it based on whether the character corresponding to the user 800 performs a predetermined operation in a predetermined area in the virtual space. Results can be estimated.

When a plurality of users 800 are provided with the same virtual experience by the virtual reality control system 10, the evaluation result may reflect whether collaboration by the plurality of users 800 has been performed. At this time, the secondary computing device 300 may reflect the collaboration by the multiple users 800 in the evaluation result according to the collaboration evaluation method described below.

21 is a flowchart illustrating a collaborative evaluation method for reflecting collaboration by multiple users 800 in an evaluation result according to an embodiment.

Referring to FIG. 21, the collaboration evaluation method may include a collaboration recognition step (S100 ), a collaboration success number measurement step (S200 ), and a collaboration evaluation result calculation step according to the number of collaborations (S300 ).

In the recognition step (S100), the secondary computing device 300 may determine whether collaboration has been made by a plurality of users 800 as described above with reference to FIGS. 9 to 20. In this case, when the collaboration is performed, the secondary computing device 300 may determine whether the collaboration is successful or not and accuracy according to a preset determination criterion. In this case, the accuracy may be determined based on at least one of the location information of the object calculated by the auxiliary computing device 300, the virtual location information, and the time elapsed from the start time of the virtual experience provided to the user 800.

In the measurement step (S200), the secondary computing device 300 may measure or record the number of collaborations to be reflected in the collaboration evaluation result based on the success and accuracy of the collaboration determined in the recognition step (S100).

In the calculation step (S300), the secondary computing device 300 may calculate a collaboration evaluation result based on the number of collaboration successes obtained through the recognition step (S100) and the measurement step (S200) and reflect it in the existing evaluation system. .

The collaborative evaluation result may be provided to the user 800 in a manner that can be easily used by scores, pictures, or a person skilled in the relevant field, similar to the evaluation result, but may be provided separately from the evaluation result or included in the evaluation result. .

For example, as the number of successful collaborations increases, the scores obtained by the plurality of users 800 after the virtual experience ends may increase. As such, the virtual reality control system 10 may induce the multiple users 800 to collaborate for better evaluation results by differently providing evaluation results according to the collaboration of the plurality of users 800. In addition, the user 800 may increase interest by receiving better evaluation results through collaboration.

Hereinafter, with reference to FIGS. 22 and 23, when at least one user 800 is provided with a virtual experience by the virtual reality providing system 10 in the same tracking area 600, among the bodies of the user 800 in the real space A description will be given of a method in which a portion not tracked by the detecting device 100 is represented in a virtual space.

22 is an exemplary diagram illustrating that a rendered image 930 is displayed in a virtual space upon contact between the users 800 at a relatively distant distance from reality.

FIG. 23 is an exemplary diagram illustrating that a rendered image 930 is displayed in a virtual space upon contact between the users 800 at a relatively close distance in reality.

Hereinafter, for convenience of description, as illustrated in FIGS. 22 and 23, the virtual reality image 452 provided to the user 800 displays the first person view point of the character 900 corresponding to the user 800. do. At this time, at least a part of the character 900 may be displayed on the virtual reality image 452.

Referring to FIG. 22, a part of the first character 901 contacting the second character 902 may be displayed as a rendered image 930.

The rendered image 930 may include a virtual image for representing the character 900 in the virtual space corresponding to the user 800 in the real space. Alternatively, the rendered image 930 may include a virtual image for representing a virtual object in a virtual space corresponding to an object tracked by the detecting device 100 in real space.

The secondary computing device 300 may generate, implement, or change the rendering image 930 in the virtual space based on the detection information or location information of the object tracked by the detection device 100.

The auxiliary computing device 300 may generate a rendering image 930 including an area in which location information is not detected based on the object's detection information.

The rendered image 930 may include an image corresponding to an area where location information is detected and an image corresponding to an area where location information is not detected. That is, the rendered image 930 may be an image rendered based on the skeleton generated based on the detected location information.

One object tracked by the detecting device 100 may be displayed as at least one rendering image 930.

For example, referring to FIG. 22, when the first user 801 in the real space places a hand on the shoulder of the second user 802, the first character 901 in the virtual space is on the shoulder of the second character 902. A virtual reality image 452 raising a hand may be provided to the first user 801 through the first wearable display device 401. At this time, the wearable display device 400 may display a rendered image 930 corresponding to the arm of the first user 801 based on the location information of the first user 801 and the second user 802. have.

The rendered image 930 may be displayed differently according to a positional relationship between objects.

22 and 23, the rendered image 930 may be displayed based on at least one of the first character virtual location 911, the second character virtual location 912, and the reference virtual location 921.

The reference virtual location 921 may include virtual location information that can be used when the secondary computing device 300 generates a rendering image 930 for an object that is not tracked by the detecting device 100. .

The reference virtual location 921 may include virtual location information calculated based on the location information of the object tracked by the detecting device 100 in the real space.

For example, the reference virtual location 921 may include virtual location information calculated based on location information obtained by tracking the first input device 501 operated by the first user 801.

As another example, the reference virtual location 921 may include virtual location information calculated based on location information obtained by tracking the marker M attached to the body of the user 800.

The rendered image 930 may be implemented based on the reference virtual location 921 and the first character virtual location 911.

For example, as illustrated in FIG. 22, when the reference virtual location 921 is virtual location information calculated based on location information of the first input device 501, a first character corresponding to the first user 801 The rendered image 930 for implementing the arm portion of the body part of 901 may be implemented based on the reference virtual location 921 and the first character virtual location 911. In this case, the rendered image 930 may include an extended arm shape in consideration of the distance between the reference virtual location 921 and the first character virtual location 911.

The shape of the rendered image 930 may be changed according to changes in the reference virtual location 921 and the first character virtual location 911.

For example, as illustrated in FIG. 23, when the distance between the reference virtual location 921 and the first character virtual location 911 is closer than that illustrated in FIG. 22, the rendered image 930 may include a curved arm shape. Can be. At this time, when the first user 801 bends the arm, the distance between the reference virtual location 921 and the first character virtual location 911 is shortened, and accordingly, the first auxiliary computing device 301 wears the first An image in which the first character 901 bends the arm may be output to the type display device 401. In this way, by displaying the joints in displaying the first character 901 in the virtual space, the separation between the real space and the virtual space felt by the first user 801 is reduced, and the immersion degree of the virtual experience of the first user 801 is reduced. Can be increased.

Meanwhile, the auxiliary computing device 300 may be implemented by varying the size of the rendered image 930 based on the reference virtual location 921 and the first character virtual location 911.

For example, when the reference virtual location 921 is virtual location information calculated based on location information of the first input device 501, a hand portion of the first character 901 corresponding to the first input device 501 The rendering image 930 for realizing may be displayed smaller as the distance between the reference virtual location 921 and the first character virtual location 911 increases, and larger as the distance approaches.

The rendered image 930 may be implemented based on the first character virtual location 911 and the second character virtual location 912. At this time, the second character virtual location 912 may include virtual location information of the corresponding contact portion when the first user 801 contacts the second user 802.

For example, the second character virtual location 912 may include virtual location information calculated based on the location information of the object attached to the second user 802 while being tracked by the detecting device 100. The method of implementing the rendering image 930 based on the 1 character virtual location 911 and the 2nd character virtual location 912 is rendered using the reference virtual location 921 and the first character virtual location 911 described above. It may include a method for implementing the image 930. At this time, the second character virtual location 912 may correspond to the reference virtual location 921.

Meanwhile, the auxiliary computing device 300 may implement different sizes of the rendered image 930 based on the first character virtual location 911 and the second character virtual location 912.

For example, the secondary computing device 300 may generate a rendering image 930 corresponding to a part or all of the body of the second character 902 based on the location information of the second wearable display device 402. In this case, the rendered image 930 may be displayed smaller as the distance between the first character virtual location 911 and the second character virtual location 912 increases, and larger as the distance increases.

In the above, the case where the plurality of users 800 are in the same tracking area 600 is mainly described, but the present invention is not limited thereto, and the plurality of users 800 control the virtual reality in the tracking area 600 separated from each other. Even when the same virtual experience is provided by the system 10, the above-described method for implementing the rendered image 930 may be used.

In addition, in the above, the method of using the rendered image 930 as a method of displaying a character, a virtual object or a virtual structure or a background in a virtual space has been mainly described, but the present invention is not limited thereto, and a skeleton, polygon, or mesh, etc. Computer graphic technology that can be easily used by those skilled in the art may also be used.

Hereinafter, a method of displaying one input device 500 as at least one variable object 1000 in a virtual space will be described with reference to FIGS. 24 to 28.

24 is an exemplary view illustrating an input device 500 according to an embodiment.

Referring to FIG. 24, the input device 500 may include a marker M and a button B.

The shape of the input device 500 may include a shape that can be gripped by the user 800. As a gripping method, the user 800 may include a method of wrapping the input device 500 by hand, a gripping method as if holding a writing tool, or a gripping method with both hands.

For example, the input device 500 may include a rod shape having a predetermined length.

A marker M is attached to the input device 500 so that the input device 500 can be tracked by the detecting device 100.

At least one marker M may be attached to the input device 500, and the plurality of markers M may be distinguished from other objects such as the wearable display device 400 by forming a specific pattern.

Meanwhile, the marker M may be omitted, and in this case, the detecting device 100 tracks the feature points of the input device 500 or the input device 500 through wireless communication between the input device 500 and the server 200. ) Can be distinguished from other subjects. At this time, the input device 500 may include a wireless communication module.

The user 800 may transmit an input signal to the server 200 or the secondary computing device 300 through the button B provided in the input device 500.

The button B may include a first button B1 and a second button B2 transmitting different input signals.

The first button B1 and the second button B2 may be spaced apart from the input device 500.

For example, when the input device 500 has a rod shape having a predetermined length, the first button B1 and the second button B2 may be disposed at both ends of the input device 500.

At least one of the first button B1 and the second button B2 may be omitted.

Button (B) is a mechanical button using a physical pressure as a means for transmitting the input signal from the input device 500 to the server 200 or the secondary computing device 300, pressure-sensitive, capacitive, infrared, ultrasonic, etc. It may include a touch button or a switch button.

The auxiliary computing device 300 may display the virtual object corresponding to the input device 500 in the virtual space using the location information of the marker M of the input device 500.

The input device 500 may be displayed as a tool that can be used by a character corresponding to the user 800 in the virtual space.

The input device 500 may be displayed in a different shape according to a virtual experience provided to the user 800 in the virtual space.

For example, when a virtual medical surgery experience is provided to the user 800, the input device 500 is displayed as a virtual object having a shape of a medical tool, and when a virtual survival experience is provided, the input device 500 is configured such as a gun or a knife. When displayed as a weapon and a virtual cooking experience is provided, the input device 500 may be displayed as a hand or a cooking tool.

25 is an exemplary diagram illustrating that an input device 500 according to an embodiment is changed to a different variable object 1000 in a virtual space.

The variable object 1000 may include a virtual object implemented by the auxiliary computing device 300 on the virtual space based on the virtual location information calculated based on the location information of the input device 500.

The variable object 1000 may include a first variable object 1001 and a second variable object 1002 according to a shape, characteristic, or shape.

When the shapes of the first variable object 1001 and the second variable object 1002 are different, characteristics and functions may be different.

The variable objects 1000 may each have predetermined characteristics or functions in a virtual space.

For example, as illustrated in FIG. 25, when a virtual experience related to medical surgery is provided to the user 800 by the virtual reality control system 10, the first variable object 1001 has a scalpel shape and a sharp portion. And can be used to dissect or dissect the body in virtual space. In addition, the second variable object 1002 has a syringe shape and includes a pointed portion, and may be used to inject drugs into the body in a virtual space.

The variable object 1000 may change shape based on predetermined characteristics or functions or as used by the character 900.

The variable object 1000 may have a different shape according to the type or nature of the virtual experience provided to the user 800 by the virtual reality control system 10.

The variable object 1000 may have two or more shapes even during the same virtual experience, and when the shape of the variable object 1000 is changed, properties, characteristics or functions of the virtual object 1000 may be changed accordingly. Can.

Hereinafter, a case in which the shape of the variable object 1000 in the virtual space is changed will be described with reference to FIGS. 26 and 27.

26 is an exemplary view illustrating a case where the second variable object 1002 is changed to the first variable object 1001 according to an embodiment.

Referring to FIG. 26, the virtual reality image 452 provided to the user 800 includes a character 900, a first variable object 1001 or a second variable object 1002, a variable object virtual location 1010 and virtual An extension line 1100 may be included.

The character 900 may be output based on the location information of the user 100 in the virtual space. The virtual reality image 452 may display a field of view of a virtual camera located in a virtual space.

For example, the first person view point of the character 900 may be displayed on the virtual reality image 452, and only a hand among body parts of the character 900 may be displayed.

The variable object 1000 may be displayed on the virtual reality image 452 corresponding to the input device 500.

For example, when the user 800 has the input device 500, the virtual reality image 452 displays the variable object 1000 corresponding to the input device 500 as being carried by the character 900. Can be.

The variable object virtual location 1010 may include virtual location information calculated by the secondary computing device 300 based on the detection information obtained by the detecting device 100 tracking the input device 500.

For example, the variable object virtual location 1010 may include virtual location information of the marker M attached to the input device 500.

Alternatively, the variable object virtual location 1010 may include virtual coordinates constituting the variable object 1000 corresponding to the input device 500 or virtual coordinates spaced apart from the variable object 1000.

For example, when the variable object 1000 is in the shape of a syringe, the variable object virtual position 1010 may include virtual position information or virtual coordinates of the tip of the injection needle.

The variable object virtual location 1010 may or may not be displayed on the virtual reality image 452 in a dot shape, a cube shape, or the like.

The variable object virtual location 1010 may include an operation start location 1011 and an operation end location 1012.

The operation start position 1011 may include virtual position information of the variable object 1000 at the first time point, and the operation end position 1012 may include virtual position information of the variable object 1000 at the second time point. At this time, the first time point and the second time point may be the same or different time points.

When the input device 500 is moved by the user 800, the variable object 1000 may be moved by the character 900 in the virtual space displayed on the virtual reality image 452.

The virtual extension line 1100 may include a virtual line formed by the variable object 1000 moving by the character 900.

The virtual extension line 1100 may include an operation start position 1011 and an operation end position 1012.

The virtual extension line 1100 may or may not be displayed on the virtual reality image 452.

The variable object 1100 may be changed in shape by moving in a movement path preset by the character 900.

The movement path may be composed of at least one of a straight line, a curve, and a combination of a straight line and a curve. Also, the movement path may be set by the auxiliary computing device 300 based on the characteristic or function of the shape to be changed after the variable object 1100 is moved.

For example, as illustrated in FIG. 26, when a virtual experience related to medical surgery is provided to the user 800, the first variable object 1001 may be a scalpel shape, and the second variable object 1002 may be a syringe shape. Can. When the character 900 is in possession of the second variable object 1002 in the virtual space, if the input device 500 moves in a straight path similar to using the scalpel by the user 800, the second in the virtual space. The variable object 1002 may move in a straight line correspondingly. When the movement of the second variable object 1002 ends, the second variable object 1002 may be displayed by changing to the first variable object 1001. At this time, the variable object virtual position 1010 of the second variable object 1002 may move from the operation start position 1011 to the operation end position 1012, and the auxiliary computing device 300 may start the operation start position 1011 Based on and the operation end position 1012, it may be determined whether the second variable object 1002 is replaced with the first variable object 1001 and displayed.

Meanwhile, the auxiliary computing device 300 may change the shape of the variable object 1100 in consideration of a moving speed or a moving time when the variable object 1100 moves in a preset movement path by the character 900.

Alternatively, the shape of the variable object 1100 may be changed by the user 800 operating the button B provided in the input device 500.

For example, when the input device 500 is operated by the user 800 and the secondary computing device 300 or the server 200 acquires an input signal, the secondary computing device 300 displays the shape of the variable object 1100. It can be changed and displayed.

Alternatively, the shape of the variable object 1100 may be changed according to the elapsed time after the virtual experience is provided to the user 800 by the virtual reality control system 10.

For example, when a virtual experience of performing medical surgery is provided to the user 800, the shape of the variable object 1100 may be changed at a time when another operation starts after a certain time after the operation is started in virtual reality.

27 is an exemplary diagram illustrating a method in which the shape of the variable object 1000 is changed according to the position of the character 900 according to an embodiment.

Referring to FIG. 27, the shape of the variable object 1000 may be changed according to the reference object V3 disposed around it.

The reference object V3 may be a virtual object existing in the virtual space.

The reference object V3 may be a virtual object corresponding to the real object RO in the real space.

The reference object V3 may have a different shape according to the type of virtual experience provided to the user 800.

The reference object V3 may be used by the character 900 in virtual space.

The reference object V3 may include a first reference object V3_1 and a second reference object V3_2.

The first reference object V3_1 and the second reference object V3_2 may have the same shape or different shapes.

For example, when a virtual experience related to a cooking experience is provided to the user 800, the first reference object V3_1 may include a cutting board shape, and the second reference object V3_2 may include a frying pan shape.

When the character 900 is located within a predetermined range from the reference object V3, the variable object 1000 carried by the character 900 may be changed in shape corresponding to the reference object V3.

For example, referring to FIG. 27, when the user 800 is provided with a virtual experience related to cooking practice, a character 900 and a cutting board shape are included in the virtual reality image 452 displayed through the wearable display device 400. A first reference object V3_1 having a, a second reference object V3_2 having a frying pan shape, and a variable object 1000 may be displayed. When the character 900 is located within a predetermined range from the first reference object V3_1, the auxiliary computing device 300 may use the first variable object 1001 having a kitchen knife shape as a virtual object corresponding to the input device 500. Can be displayed. Thereafter, when the character 900 moves within the preset range from the second reference object V3_2, the secondary computing device 300 changes the first variable object 1001 to a second variable object 1002 having an inverted shape. Can be displayed.

On the other hand, the secondary computing device 300 is the shape of the variable object 1000 corresponding to the input device 500 based on the virtual location information in the virtual space of the character 900, regardless of the arrangement or presence of the reference object V3. Can be changed.

When the character 900 corresponding to the user 800 in the virtual space uses the variable object 1000, haptic feedback may be provided to the user 800 through the input device 500 by the auxiliary computing device 300. have. In this case, haptic feedback having different strengths and types may be provided according to the shape of the variable object 1000.

For example, when the character 900 uses the second variable object 1002 in the shape of a syringe than the case in which the first variable object 1001 in the form of a scalpel is used, the vibration or resistance of a larger size to the user 800 This can be provided.

28 is an exemplary diagram illustrating a method in which a variable object 1000 corresponding to the input device 500 is displayed on a virtual reality image 452 according to an embodiment.

Referring to FIG. 28, in the real space, the input device 500 may be located outside the viewing range 451 of the virtual camera according to a method held by the user 800.

The field of view 451 of the virtual camera may include a portion to be output through the wearable display device 400 in a virtual space constructed by the auxiliary computing device 300.

The viewing range 451 of the virtual camera may correspond to the viewing range of the user 800 in the real space.

Meanwhile, as illustrated in FIG. 28, even when the input device 500 is positioned outside the field of view 451 of the virtual camera by the user 800, the virtual reality image 452 has a variable corresponding to the input device 500. The object 1000 may be displayed.

The variable object 1000 may be implemented as a virtual object that is relatively bulky or has a longer length than the input device 500.

Alternatively, the variable object 1000 may include a virtual object extending from the input device 500.

The variable object 1000 displayed on the virtual reality image 452 may include a visible portion 1000a and an invisible portion 1000b.

The visible portion 1000a is a portion of the variable object 1000 included in the field of view 451 of the virtual camera and displayed on the virtual reality image 452, and the invisible portion 1000b is the field of view 451 of the virtual camera It may be a part that is not included and is not displayed in the virtual reality image 452.

The visible part 1000a and the invisible part 1000b may constitute the variable object 1000.

The visible portion 1000a and the invisible portion 1000b are not fixed and may be changed as some or all of the input device 500 is moved by the user 800.

For example, as illustrated in FIG. 28, when the variable object 1000 has a surgical tool shape in length, the input device 500 is lifted by the user 800 and lifted into the field of view 451 of the virtual camera. When exposed more than before, the visible portion 1000a may increase and the invisible portion 1000b may decrease.

Each of the user 800 and the input device 500 may be plural, and in this case, the above-described variable object 1000 shape change method or the variable object 1000 display method may be used.

In the above, for convenience of description, it has been described that the input device 500 may be displayed as at least one or more variable objects V3 in a virtual space, but the present invention is not limited to this, and the real object RO instead of the input device 500 is described. May be used.

Hereinafter, a method of displaying collisions between virtual objects in the virtual space on the virtual reality image 452 will be described with reference to FIGS. 29 to 33.

29 is an exemplary diagram illustrating a situation before a collision occurs between virtual objects in a virtual space according to an embodiment.

Referring to FIG. 29, a virtual structure 1200, a collision object 1300, a collision object virtual location 1310, a manipulation object 1400, and a manipulation object virtual location 1410 may be displayed on the virtual reality image 452. .

The virtual structure 1200 may include a structure, structure, or background constituting a virtual space.

The virtual structure 1200 may vary depending on the type of virtual experience provided to the user 800.

For example, when a virtual experience of a surgical practice is provided to the user 800, the virtual structure 1200 may include an operating room including an operating table, a medicine storage box, or a large intestine including a tumor.

As another example, when a virtual experience related to cooking practice is provided to the user 800, the virtual structure 1200 may include a cooking room equipped with cooking tools, a kitchen, and the like.

The virtual structure 1200 may be implemented by the auxiliary computing device 300.

The virtual structure 1200 may be implemented in real space corresponding to the real object RO.

The virtual structure 1200 may include a collision object 1300 or be connected to the collision object 1300.

The collision object 1300 may include a virtual object in which a collision may occur in a virtual space while a virtual experience is provided to the user 800.

The collision object 1300 may be implemented based on the virtual location information calculated based on the location information of the real object RO or may be implemented regardless of the real object RO.

The collision object 1300 may be implemented by the auxiliary computing device 300.

The collision object virtual location 1310 may include virtual location information of the collision object 1300. The auxiliary computing device 300 may determine whether a collision has occurred based on the collision object virtual location 1310.

The collision object virtual location 1310 may or may not be displayed on the virtual reality image 452 in a dot shape, a cube shape, or the like.

The manipulation object 1400 may include a virtual object manipulated by the character 900 in virtual space.

The manipulation object 1400 may be implemented by the auxiliary computing device 300 based on the location information of the input device 500 carried by the user 800. Alternatively, the manipulation object 1400 may be implemented by the auxiliary computing device 300 based on the location information of the real object RO possessed by the user 800. The manipulation object 1400 may be implemented based on virtual location information calculated from location information of the real object RO possessed by the user 800. Alternatively, the manipulation object 1400 may be implemented in a form of occupying an area extended from the virtual location information. The manipulation object 1400 may be implemented in a form of occupying an area extending in one direction from the virtual location information. The manipulation object 1400 may be implemented in a form of occupying a direction extending from the arrangement direction of the real object RO.

The manipulation object 1400 may include at least one shape according to the type of virtual experience provided to the user 800.

For example, as illustrated in FIG. 29, the manipulation object 1400 may be implemented in an endoscopic shape when the user 800 is provided with a virtual experience regarding surgical practice.

The manipulation object virtual location 1410 may include virtual position information of the manipulation object 1400. The auxiliary computing device 300 may determine whether a collision has occurred based on the manipulation object virtual location 1410.

The manipulation object virtual location 1410 may or may not be displayed on the virtual reality image 452 in a dot shape, a cube shape, or the like.

A collision may occur between the collision object 1300 and the manipulation object 1400 while the virtual experience is provided to the user 800. The collision in the virtual space refers to a case where at least two or more virtual objects in the virtual space implemented by the secondary computing device 300 or the server 200 meet or contact, and at this time, virtual location information constituting each virtual object that collides Can overlap each other. Alternatively, the collision object 1300 and the manipulation object 1400 may each have a virtual occupied area in the virtual space, and the virtual occupied area of the collision object 1300 overlaps with the virtual occupied area of the manipulation object 1400 A collision may occur between the object 1300 and the manipulation object 1400.

Meanwhile, the collision object 1300 that contacts or collides may correspond to the real object RO. At this time, when a collision occurs in the virtual space, a collision between the real objects RO in the real space may occur.

The secondary computing device 300 may determine whether a collision or a contact has occurred between the collision object 1300 and the manipulation object 1400 based on the collision object virtual position 1310 and the manipulation object virtual position 1410. . More specifically, the secondary computing device 300 may determine that a collision or contact has occurred when the manipulation object 1410 is located within a preset range from the collision object virtual location 1310.

30 is an exemplary diagram illustrating a case where a collision occurs between a collision object 1300 and an operation object 1400 according to an embodiment.

Referring to FIG. 30, when a collision occurs between the collision object 1300 and the manipulation object 1400, a shape in which a part of the collision object 1300 and the manipulation object 1400 are overlapped may be displayed on the virtual reality image 452. . At this time, the secondary computing device 300 or the server 200 may provide a collision notification 1500 to the user 800.

For example, a virtual experience related to endoscopic surgery is provided to the user 800, such that the virtual structure 1200 of the internal shape of the body, the collision object 1300 of the tumor shape, and the manipulation object 1400 of the endoscopic shape are provided to the virtual reality image 452. ) May be displayed. At this time, the input device 500 is operated by the user 800 and corresponding to the position information of the input device 500, the manipulation object virtual position 1410 exists within a preset range from the collision object virtual position 1310. In this case, as illustrated in FIG. 30, the manipulation object 1400 may penetrate the collision object 1300.

The collision notification 1500 may inform the user 800 that a collision has occurred between the collision object 1300 and the manipulation object 1400.

The collision notification 1500 may be implemented as at least one of visual effects such as text and picture special effects, acoustic effects such as sound and sound, and tactile effects such as vibration by an actuator.

For example, the collision notification 1500 may be displayed as a message box image described as'Warning' or'Warning' in a preset area in the virtual reality image 452.

As another example, the collision notification 1500 may be output through at least one of a warning voice and a warning sound through the wearable display device 400.

As another example, the collision notification 1500 may include a special effect of periodically displaying red lighting in the virtual reality image 452.

As another example, when a collision occurs between the collision object 1300 and the manipulation object 1400, the auxiliary computing device 300 uses the actuator provided in the input device 500, the real object RO, and the like to the user 800. Can provide haptic feedback such as vibration and resistance. At this time, the auxiliary computing device 300 may set the intensity or direction of the haptic feedback provided to the user 800 according to the moving speed of the manipulation object 1400 before the collision.

On the other hand, when the virtual experience provided by the virtual reality control system 10 to the user 800 includes the evaluation system, the above-described number of collision occurrences, the collision process, the speed of the virtual object before the collision, etc., will be reflected in the evaluation result. Can.

31 is an exemplary diagram illustrating a method of outputting a virtual reality image 452 when a collision occurs between a collision object 1300 and an operation object 1400 according to an embodiment.

Referring to FIG. 31, when a collision occurs between the collision object 1300 and the manipulation object 1400, the secondary computing device 300 or the server 200 may include at least one of the collision object 1300 and the manipulation object 1400. The shape can be changed and displayed.

Alternatively, when a collision occurs between the collision object 1300 and the operation object 1400, the secondary computing device 300 or the server 200 may control the virtual occupation area of the collision object 1300 and the virtual occupation area of the operation object 1400. At least one of them.

The virtual occupied area may be an area including virtual objects. Alternatively, the virtual occupied area may be an area occupied by the virtual object.

As at least one shape of the collision object 1300 and the manipulation object 1400 is changed, the collision object 1300 and the manipulation object 1400 that do not collide may be displayed on the virtual reality image 452.

For example, as described in FIG. 30, when a virtual experience of endoscopic surgery is provided to the user 800 and a collision occurs between the tumor-shaped collision object 1300 and the endoscopic-shaped manipulation object 1400, FIG. As illustrated, the colliding portion of the manipulation object 1400 may be curved and displayed.

In the process of changing the shape of at least one of the collision object 1300 and the manipulation object 1400 to avoid collision in the virtual space, the server 200 or the secondary computing device 300 operates the collision object virtual location 1310 and manipulation At least one of the object virtual locations 1410 may be changed and an image may be displayed, or an image different from before a collision may be displayed without changing each virtual location information. As a result, the collision object virtual location 1310 and the manipulation object virtual location 1410 exist within a preset range of each other, but the collision object 1300 and the manipulation object 1400 displayed on the virtual reality image 452 are preset with each other. It may not be within range.

32 is an exemplary diagram illustrating a method of displaying a plurality of manipulation objects 1400 in a virtual space, according to an embodiment.

Referring to FIG. 32, the virtual reality image 452 includes a virtual structure 1200, a collision object 1300, a first manipulation object 1401, a second manipulation object 1402, a first manipulation object virtual location 1411, and The second manipulation object virtual location 1412 may be displayed.

The virtual reality control system 10 may provide the first input device 501 and the second input device 502 according to the type of virtual experience provided to the user 800.

The auxiliary computing device 300 may implement the first manipulation object 1401 and the second manipulation object 1402 in the virtual space based on the location information of the first input device 501 and the second input device 502. .

The first manipulation object 1401 and the second manipulation object 1402 may be implemented in the same shape or may be implemented in different shapes.

For example, when the virtual experience of endoscopic surgery is provided to the user 800, the first input device 501 and the second input device 502 may be provided to the user 800, and the wearable display device 400 may be provided. The virtual reality image 452 output through () includes a first manipulation object 1401 in the form of a tumor removal tool corresponding to the first input device 501 and a second endoscope shape corresponding to the second input device 502. The manipulation object 1402 may be displayed. At this time, the tumor removal operation may be performed in the virtual space by the user 800 operating the first input device 501 and the second input device 502.

The input device 500 and the corresponding manipulation object 1400 may have the same volume or the same length, or different volumes or different lengths.

For example, when the manipulation object 1400 has an endoscope shape, it is implemented to extend from the input device 500 and only the extended portion is displayed on the virtual reality image 452 output through the wearable display device 400. Can.

The first manipulation object virtual location 1411 and the second manipulation object virtual location 1412 are based on the location information of the first input device 501 and the location information of the second input device 502, respectively. ) May include virtual location information.

The first manipulation object virtual position 1411 and the second manipulation object virtual position 1412 may or may not be displayed on the virtual reality image 452 in a dot shape, a cube shape, or the like.

A collision may occur between the first manipulation object 1401 and the second manipulation object 1402 in the virtual space according to the movement of the first input device 501 and the second input device 502 while the virtual experience is being provided. .

The collision between the first manipulation object 1401 and the second manipulation object 1402 may occur similarly to the collision occurring between the collision object 1300 and the manipulation object 1400 described in FIGS. 31 and 32.

For example, when the first operation object virtual location 1411 and the second operation object virtual location 1412 exist within a preset range of each other, the auxiliary computing device 300 may include the first operation object 1401 and the second operation object. It can be determined that a collision has occurred between 1402.

As another example, if the virtual occupied area occupied by the first manipulation object 1401 in the virtual space set by the secondary computing device 300 overlaps the virtual occupied area occupied by the second manipulation object 1402, the secondary computing device ( 300 may determine that a collision has occurred between the first manipulation object 1401 and the second manipulation object 1402.

Meanwhile, the collision is not only between the first manipulation object 1401 and the second manipulation object 1402, but also among the first manipulation object 1401, the second manipulation object 1402, the collision object 1300, and the virtual structure 1200. It can also occur between at least two or more.

When a collision occurs between the first manipulation object 1401 and the second manipulation object 1402, the wearable display device 400 and the input device 500 are provided to the user 800 similarly as described in FIG. 30. The collision notification 1500 may be provided through at least one.

When a collision occurs between the first operation object 1401 and the second operation object 1402, similar to that described in FIG. 31, the secondary computing device 300 may include the first operation object 1401 and the second operation object. At least one shape of 1402 may be changed.

By changing the shape of at least one of the first manipulation object 1401 and the second manipulation object 1402, the first manipulation object 1401 and the second manipulation object 1402 that do not collide with the virtual reality image 452 are displayed. Can be.

In the process of changing the shape of at least one of the first manipulation object 1401 and the second manipulation object 1402 in order to avoid collision in the virtual space, the server 200 or the secondary computing device 300 is configured to virtualize the first manipulation object. At least one of the location 1411 and the second manipulation object virtual location 1412 may be changed and an image may be displayed, or each virtual location information may be displayed with a different image from before the collision. As a result, the first manipulation object virtual position 1411 and the second manipulation object virtual position 1412 exist within a preset range of each other, but the first manipulation object 1401 and the second manipulation displayed on the virtual reality image 452 The objects 1402 may not exist within a preset range of each other.

On the other hand, a collision and collision processing method between at least two or more virtual objects in the virtual space illustrated in FIGS. 29 to 32 is provided when a virtual experience is provided to a plurality of users 800 operating at least one input device 500 Can also be applied to

For example, in FIG. 32, the first manipulation object 1401 includes a virtual object corresponding to the first input device 501 operated by the first user 801, and the second manipulation object 1402 is a second user A virtual object corresponding to the second input device 502 manipulated by 802 may be included.

Hereinafter, a method of changing the virtual place 1700 implemented in the virtual space using the real object RO will be described with reference to FIG. 33.

33 is an exemplary diagram illustrating a method of changing a virtual place 1700 according to an embodiment.

Referring to FIG. 33, a virtual place 1700, a character 900, and a conversion object 1600 may be displayed on the virtual reality image 452.

The virtual place 1700 may include a virtual image indicating a specific place as a place or background where the character 900 exists in the virtual space by the auxiliary computing device 300.

The virtual place 1700 may include a first virtual place 1701 and a second virtual place 1702.

The conversion object 1600 may include a virtual object disposed in the virtual space by the auxiliary computing device 300.

The conversion object 1600 may include a virtual object corresponding to the real object RO in the real space.

For example, when the door is placed in the tracking area 600 in the real space, the secondary computing device 300 shapes the door in the virtual space based on the detection information obtained by the detecting device 100 tracking the door. The conversion object 1600 can be implemented.

The character 900 may change the virtual place 1700 using the conversion object 1600.

For example, the virtual reality image 452 provided to the user 800 may include a first virtual background 1701 and a conversion object 1600 that displays the lake shore. When the switching object 1600 is a virtual object corresponding to the real object RO of the door shape, when the user 800 opens the real object RO of the door shape in the real space and passes through the door, the corresponding virtual object When the character 900 opens and passes the door-shaped transition object 1600 in space, the first virtual background 1701 may be changed to the second virtual background 1702.

Due to this, the user 800 can move to various places in the virtual space while the virtual experience is provided using the real object RO. In this case, the real object RO disposed in the real space may also be rendered as another virtual image by changing the virtual space. For example, one real object RO in the real space may be rendered as a first virtual image in the first virtual background 1701 and a second virtual image in the second virtual background 1702.

As described above, although the embodiments have been described by a limited embodiment and drawings, those skilled in the art can make various modifications and variations from the above description. For example, the described techniques are performed in a different order than the described method, and/or the components of the described system, structure, device, circuit, etc. are combined or combined in a different form from the described method, or other components Alternatively, even if replaced or substituted by equivalents, appropriate results can be achieved.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Virtual reality control system 10 detecting device 100
Server 200 Secondary Computing Device 300
Wearable display device 400 Input device 500

Claims (22)

A first sensing unit detecting a first optical signal;
A second sensing unit detecting a second optical signal;
A first display for outputting an image to a first user;
A second display outputting an image to a second user; And
It includes at least one control unit for controlling the first display and the second display,
The at least one control unit,
Calculating first virtual location information of the first user based on the first optical signal and second virtual location information of the second user based on the second optical signal at a first time point,
Calculating third virtual location information of the first user based on the first optical signal and fourth virtual location information of the second user based on the second optical signal at a second time point,
Outputting a first image to at least one of the first display and the second display at the first time point,
When the fourth virtual location information is located within a preset range from the second virtual location information while the third virtual location information is located within a preset range from the first virtual location information, the first display and the first 2 Output a second image to at least one of the displays,
The first image and the second image are virtual reality control systems that are different images.
According to claim 1,
And a first real object whose position is changed by the first user and a second real object whose position is changed by the second user,
The first sensing unit detects the first optical signal from the first real object,
The second sensing unit detects the second optical signal from the second real object,
Virtual reality control system.
According to claim 2,
The first real object includes a first input unit that delivers a first input signal by the first user to the at least one control unit,
The second real object includes a second input unit that delivers a second input signal by the second user to the at least one control unit,
Between the first time point and the second time point, at least one of the first input signal and the second input signal is transmitted to the at least one control unit,
Virtual reality control system.
According to claim 2,
The first virtual location information and the third virtual location information change according to a movement trajectory of the first real object between the first time point and the second time point,
The second virtual location information and the fourth virtual location information change according to a movement trajectory of the second real object between the first time point and the second time point,
Virtual reality control system.
According to claim 1,
The first display is mounted on a first HMD worn by the first user,
The second display is mounted on a second HMD worn by the second user,
The first optical signal is detected by the first HMD,
The second optical signal is detected by the second HMD,
The first virtual location information and the third virtual location information change according to the movement trajectory of the first HMD between the first time point and the second time point,
The second virtual location information and the fourth virtual location information change according to a movement trajectory of the second HMD between the first time point and the second time point,
Virtual reality control system.
According to claim 1,
A first microphone for transmitting a first audio signal from the input of the first user to the at least one control unit and a second microphone for transmitting a second audio signal from the input of the second user to the at least one control unit Including,
When at least one of the first voice signal and the second voice signal is transmitted to the at least one control unit between the first time point and the second time point, a second time is applied to at least one of the first display and the second display. Video is output,
Virtual reality control system.
According to claim 1,
The virtual location information of the real object at the first time point is within a preset range from the first virtual location information, and the virtual location information of the real object at the second time point is within a preset range from the fourth virtual location information. Present,
Virtual reality control system.
A first sensing unit detecting a first optical signal;
A second sensing unit detecting a second optical signal;
A first display for outputting an image to a first user;
A second display outputting an image to a second user; And
It includes at least one control unit for controlling the first display and the second display,
The at least one control unit,
Calculate first virtual location information based on the first optical signal, calculate second virtual location information based on the second optical signal,
When the first virtual location information is located within a preset range with the third virtual location information of the first real object, a first image is output on the first display,
After the first virtual location information is located within a preset range with the third virtual location information of the first real object, before the predefined time elapses, the second virtual location information is the fourth virtual location information of the second real object And when located within a preset range, outputs a second image to the first display,
The first image and the second image are different images,
Virtual reality control system.
The method of claim 8,
The first real object and the second real object are the same,
Virtual reality control system.
The method of claim 8,
The first image is a virtual reality control system including a first virtual object corresponding to the first real object.
The method of claim 8,
The control unit includes a first time point at which the first virtual location information is located within a preset range from the third virtual position information and a time point at which the second virtual location information is located within a preset range from the fourth virtual position information. A virtual reality control system that counts scores based on time differences between the second time points.
A sensing unit for detecting the first optical signal;
A first display for outputting an image to a first user;
A second display outputting an image to a second user;
At least one control unit controlling the first display and the second display; And
And an input device that delivers an input signal by the second user to the at least one control unit,
The at least one control unit,
Calculate first virtual location information of the first user based on the first optical signal,
And outputting a first image to at least one of the first display and the second display based on the first virtual location information.
When the input signal is transmitted to the at least one control unit, a second image is output,
The first image and the second image are different images,
Virtual reality control system.
The method of claim 12,
The sensing unit does not detect an optical signal from the second user,
The at least one control unit does not calculate the virtual location information of the second user,
Virtual reality control system.
The method of claim 12,
The first image and the second image include a virtual object,
The virtual object has a first state in the first image and a second state in the second image,
Virtual reality control system.
The method of claim 12,
The first image and the second image include a virtual object,
The at least one control unit displays a preset effect on the virtual object in the second image,
Virtual reality control system.
The method of claim 12,
The sensing unit detects a second optical signal from the input device,
The at least one control unit,
Calculating second virtual location information based on the second optical signal,
When the time point at which the first image is output to the at least one of the first display and the second display is the first time point and the time point at which the second image is output is the second time point, the second time point is the second time point The virtual location information and the second virtual location information at the second time point are different,
Virtual reality control system.
A first sensing unit detecting a first optical signal;
A second sensing unit detecting a second optical signal;
A first display for outputting an image to a first user;
A second display outputting an image to a second user; And
It includes at least one control unit for controlling the first display and the second display,
The at least one control unit,
Calculate first virtual location information based on the first optical signal, calculate second virtual location information based on the second optical signal,
Outputting a first rendered image based on the first virtual location information and a second rendered image based on the second virtual location information on at least one of the first display and the second display,
When the second virtual location information is within a preset range from the first virtual location information, a first rendered image is output when the distance between the first virtual location information and the second virtual location information has a first distance And output a third rendered image when the distance between the first virtual location information and the second virtual location information has a second distance,
The appearances of the first rendered image and the third rendered image correspond,
The first distance is greater than the second distance
Virtual reality control system.
The method of claim 17,
The first rendered image and the third rendered image are rendered images having different sizes,
Virtual reality control system.
The method of claim 17,
The first rendering image and the third rendering image are rendering images corresponding to a body part of the first user,
Virtual reality control system.
The method of claim 17,
The first rendered image and the third rendered image are in contact with the second rendered image in virtual space,
Virtual reality control system.
The method of claim 20,
And a fourth rendering image spaced apart from the second rendering image and connected to the first rendering image,
When the distance between the first virtual location information and the second virtual location information has the first distance, the distance between the fourth rendered image and the first virtual location information and the second virtual location information is the first The fourth rendered image in the case of having two distances has different shapes,
Virtual reality control system.
The method of claim 17,
A first input device that transmits a first input signal to the at least one control unit by manipulation of the first user; And
A second input device for transmitting a second input signal to the at least one control unit by the operation of the second user,
The first rendered image corresponds to the first input device, and the second rendered image corresponds to the second input device,
Virtual reality control system.

Images