KR20200135113A - Bicycle Simulator and block chain network system using the same - Google Patents

Abstract

The purpose of the present invention is to provide a bicycle simulator capable of sharing bicycle riding experiences together in cyberspace with riders located in different spaces. The present invention may provide a bicycle simulator comprising: a base part; a frame support part which is connected to the base part to be movable along one direction and supports a frame of a bicycle that is held, the frame connecting a front wheel and a rear wheel of the bicycle; a first sensor part for detecting a moving direction and a moving distance of the frame support part which moves along the one direction; a communications circuit for receiving the moving direction and the moving distance of the frame support part, the moving direction and the moving distance being detected in the first sensor part; a processor for generating a bicycle avatar, the riding direction of which changes according to the moving direction and the moving distance of the frame support part, the moving direction and the moving distance being transmitted from the communications circuit; and a display for displaying a riding state of the bicycle avatar.

Description

Bike Simulator and block chain network system using the same}

The present invention relates to a bicycle simulator for virtual driving and a block chain network system using the same, and more specifically, it is possible to virtually experience various driving paths in an indoor space, and riders in different spaces can experience the same cyber space. It relates to a bicycle simulator that allows you to virtually experience a bicycle driving experience in the world, and a blockchain network system that generates and trades cryptocurrency using the same.

In general, a bicycle exercise device called a bicycle trainer or a bicycle roller is an indoor exercise fitness equipment most widely used with a treadmill, and a rider riding a bicycle seated on a rotating roller or a cradle uses a pedal for rotational resistance ( Magnetic force, etc.) is intended to strengthen lower body strength by rotating the applied wheel.

Such a conventional bicycle exercise device has the advantage of providing a considerably high exercise effect to a rider with only a relatively short time of exercise through the adjustment of rotational resistance applied to the wheel regardless of the weather.

However, conventional bicycle exercise equipment simply continues the pedaling exercise to which rotational resistance is applied while facing the wall in an enclosed indoor space, so it is boring or boring as it does not provide the riders with the pleasure of actually riding a bicycle at all. Due to this, there was a problem that it was difficult to continue the continuous pedaling exercise.

In addition, the conventional bicycle exercise equipment has a problem in that the rider alone performs bicycle pedaling in an enclosed indoor space, thereby making it impossible to experience a bicycle driving experience with other riders.

An object of the present invention is to provide a bicycle simulator capable of experiencing the same driving experience as driving in an outdoor driving environment even indoors by changing the driving state of a bicycle avatar implemented on a display according to the driving state of a bicycle supported on a bicycle holder. Is to do.

In addition, an object of the present invention is to provide a bicycle simulator capable of sharing bicycle driving experiences in cyberspace with riders located in different spaces.

In addition, an object of the present invention is to provide a blockchain network system that generates cryptocurrency and transacts it by using the momentum data acquired using a bicycle simulator.

A bicycle simulator according to an embodiment of the present invention includes a base unit; A frame support part connected to the base part so as to be movable along one direction and supporting a frame of the bicycle that connects the front and rear wheels of the mounted bicycle; A first sensor unit detecting a moving distance and a moving direction of the frame support unit along the one direction; A communication circuit for receiving a moving distance and a moving direction of the frame support unit detected by the first sensor unit; A processor for generating a bicycle avatar whose driving direction is changed according to a moving distance and a moving direction of the frame support unit transmitted from the communication circuit; And a display displaying the driving state of the bicycle avatar.

A slide guide fixed to the base and extending along one direction; And a slide part fixed to one end of the frame support part and connected to be movable on the slide guide along the one direction, wherein the first sensor part comprises a moving direction of the slide part moving on the slide guide And it is possible to detect the moving distance.

The processor may determine a driving direction of the bicycle avatar according to a moving direction of the frame support unit, and may determine a position of the bicycle avatar on a driving path according to a moving distance of the frame support unit.

A front wheel roller supporting the front wheel of the bicycle and rotating together with the rotation of the front wheel; A rear wheel roller supporting the rear wheel of the bicycle and rotating together with the rotation of the rear wheel; And a second sensor unit configured to sense a rotation speed and a rotation distance of at least one of the front roller and the rear roller.

The processor may determine a running speed of the bicycle avatar according to a rotation speed of at least one of the front roller and the rear roller sensed by the second sensor unit, and the front wheel roller sensed by the second sensor unit and The driving distance of the bicycle avatar may be determined according to the rotation distance of at least one of the rear wheel rollers.

A weight measuring unit that measures the weight of a rider on the bicycle; And an input unit for inputting at least one of the model of the bicycle and information of a rider riding the bicycle.

The processor may generate a bicycle avatar according to the information of the rider and the bicycle input from the weight measurement unit and the input unit.

It may further include a third sensor unit disposed on both sides of the base unit and sensing contact between the slide unit and one side surface of the base unit.

The processor may adjust the driving path of the bicycle avatar so that the bicycle avatar travels along a specific path when a contact between either side of the slide part and the base part is detected by the third sensor part. .

The specific path is a driving environment including a forked road, and a driving direction of the forked road may be determined according to a side surface of the base part in contact with the slide part.

The processor may display a warning message on the display when the bicycle avatars are disposed to be adjacent to each other with an obstacle or another avatar at a predetermined interval or less.

The processor may determine a driving state of the bicycle avatar on a flat road and an inclined road on which the bicycle avatar travels, according to a rotation speed of at least one of the front roller and the rear roller detected by the second sensor unit. I can.

When the bicycle avatar drives in a driving environment including a forked road, the driving direction of the forked road may be determined according to a change in the moving direction sensed by the first sensor unit.

The block chain network system according to an embodiment comprises: a cryptocurrency issuing device for generating cryptocurrency according to exercise data obtained from the bicycle simulator; And a node computer that forms a blockchain network with the cryptocurrency issuing device.

The node computer is used by a rider who uses the bicycle simulator, and may include one or more user nodes that receive the cryptocurrency generated from the cryptocurrency issuing device.

The node computer may include one or more trader nodes for trading the cryptocurrency with the user node.

The scope of the blockchain network may be set differently according to the scope of a participant participating in the blockchain network among the one or more user nodes and the one or more trader nodes.

It may further include an exercise amount verification device for verifying the exercise amount data achieved using the bicycle simulator 　 and transmitting it to the cryptocurrency 　 issuing device.

A bicycle simulator according to an embodiment includes a base unit; A frame support part connected to the base part so as to be movable along one direction and supporting a frame of the bicycle that connects the front and rear wheels of the mounted bicycle; A first sensor unit detecting a moving distance and a moving direction of the frame support unit along the one direction; A communication circuit for receiving a moving distance and a moving direction of the frame support unit detected by the first sensor unit; A processor for generating a character whose driving direction is changed according to a moving distance and a moving direction of the frame support unit transmitted from the communication circuit; And a display displaying the driving state of the character.

A slide guide disposed to be fixed between both side portions of the base portion and extending along one direction; And a slide part fixed to one end of the frame support part and connected to be movable on the slide guide along the one direction, wherein the first sensor part comprises a moving direction of the slide part moving on the slide guide And it is possible to detect the moving distance.

The processor may determine a moving direction of the character according to a moving direction of the frame support unit, and may determine a position of the character according to a moving distance of the frame support unit.

A front wheel roller supporting the front wheel of the bicycle and rotating together with the rotation of the front wheel; A rear wheel roller supporting the rear wheel of the bicycle and rotating together with the rotation of the rear wheel; And a second sensor unit configured to sense a rotation speed and a rotation distance of at least one of the front roller and the rear roller.

The processor may determine the forward or backward movement of the character according to a rotation speed of at least one of the front roller and the rear roller detected by the second sensor unit.

The processor may determine whether or not the projectile launched from the character is fired or a firing speed according to a rotation speed of at least one of the front roller and the rear roller detected by the second sensor unit.

According to the present invention, by changing the driving state of the bicycle avatar implemented on the display according to the driving state of the bicycle supported on the bicycle holder, it is possible to virtually experience the same state as the outdoor driving environment indoors. You can enjoy a more realistic ride indoors.

In addition, by sharing bicycle driving experiences with riders located in different spaces in cyberspace, riders can be provided with a more realistic and exciting virtual riding environment.

In addition, it is possible to form a blockchain network system that generates cryptocurrency and transacts it by using the momentum data acquired using a bicycle simulator.

1 is a perspective view of a bicycle simulator according to an embodiment of the present invention.
2 is a block diagram of a bicycle simulator according to an embodiment of the present invention.
3A is a schematic diagram of an input unit according to an exemplary embodiment.
3B is a display screen displaying a bicycle avatar according to an exemplary embodiment.
4A is a partial perspective view of a bicycle simulator according to an embodiment.
4B is an enlarged view of a bicycle simulator according to an embodiment.
5A to 5B are display screens displaying a change in a driving path of a bicycle avatar according to a change in a driving path of the bicycle.
6A to 6B are schematic plan views of a bicycle simulator according to steering of a bicycle.
7 is a partial perspective view of a bicycle simulator according to an embodiment.
8A is a display screen showing a change in a driving path of a bicycle avatar according to a change in the driving speed of the bicycle.
8B is a display screen showing a bicycle avatar driving on an inclined driving path according to an exemplary embodiment.
9 is a display screen showing a change in a driving path of a bicycle avatar according to an exemplary embodiment.
10 is a partial perspective view of a bicycle simulator according to an embodiment.
11 is a plan view of a bicycle simulator according to an embodiment.
12 is a display screen showing a driving state of a bicycle avatar.
13A to 13C are display screens showing a game progress state according to an exemplary embodiment.
14 is a block diagram illustrating a block chain network system related to a bicycle simulator according to an embodiment.

Hereinafter, the following embodiments will be described in detail with reference to the accompanying drawings, and when describing with reference to the drawings, the same or corresponding components are assigned the same reference numerals, and redundant descriptions thereof will be omitted.

Since the present embodiments can apply various transformations, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. Effects and features of the present embodiments, and a method of achieving them will become apparent with reference to the contents described later in detail together with the drawings. However, the present embodiments are not limited to the embodiments disclosed below and may be implemented in various forms.

In the following embodiments, terms such as first and second are not used in a limiting meaning, but are used for the purpose of distinguishing one component from another component.

In the following embodiments, a singular expression includes a plurality of expressions unless the context clearly indicates otherwise.

In the following embodiments, the upper (upper), lower (lower), left and right (lateral or lateral), front (front, front), rear (belly, rear), etc., which refer to the direction, are not intended to be limited to the right. For the sake of convenience, it is determined based on a relative position between the drawings and configurations, and each direction described below is based on this, except for cases specifically limited differently.

In the following embodiments, the terms include or have means that the features or components described in the specification are present, and do not preclude the possibility of adding one or more other features or components in advance.

In the drawings, components may be exaggerated or reduced in size for convenience of description. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of description, and thus the following embodiments are not necessarily limited to those shown.

The embodiments described herein may have an aspect that is entirely hardware, partially hardware and partially software, or entirely software. In the present specification, “unit”, “module”, “device” or “system” refers to a computer-related entity such as hardware, a combination of hardware and software, or software. For example, in the present specification, the unit, module, device, or system is a running process, processor, object, executable file, thread of execution, program, and/or computer. It may be (computer), but is not limited thereto. For example, both an application running on a computer and a computer may correspond to a unit, module, device, or system of the present specification.

In the present specification, the blockchain network system may be entirely hardware, or may have a side that is partially hardware and partially software, and may be composed of one or more servers, computers, terminals, and the like. The method according to an embodiment of the present invention may be implemented in the form of a computer program for performing a series of processes, and the computer program may be recorded in a computer-readable recording medium.

In addition, in the present specification, a "node" is a block chain participant, and may be a server, a personal computer, a terminal, or other electronic equipment capable of various communication.

In addition, in this specification, a certain amount of random data propagated on the blockchain is accumulated to form block data, and the formed block data is verified by nodes in the blockchain and then connected to the previous block data. In addition, in this specification, arbitrary data propagated to the blockchain are stored in the participating nodes of the blockchain, and data of each participating node can be compared periodically/aperiodically to verify whether the data is forged or altered.

1 is a perspective view of a bicycle simulator according to an embodiment of the present invention. 2 is a block diagram of a bicycle simulator according to an embodiment of the present invention.

In the bicycle simulator 1 according to an embodiment of the present invention, the rider R boarding the bicycle 10 supported by the bicycle simulator 1 can virtually experience the same state as the actual driving environment, This allows you to enjoy realistic riding regardless of the outdoor driving environment.

The bicycle 10 mentioned above is a concept that is not only specially manufactured for the bicycle simulator 1 according to an embodiment of the present invention, but also encompasses all bicycles 10 commercially available from various manufacturers. Such a bicycle 10, a bicycle frame 11 constituting the body of the bicycle 10, a front wheel 12 and a rear wheel 13 rotatably mounted on the bicycle frame 11, and pedaling of the rider R It may include a drive system (crank, chain, transmission, etc.) that converts to the rotational force of the rear wheel (13).

Bicycle simulator 1 according to an embodiment of the present invention, in order to implement the functions or actions as described above, the base portion 20, the frame support portion 30, the front roller 40, the rear roller 50 , A sensor module 60, an input unit 71, a memory 73, a communication module 80, a processor 90, and a display 95.

Hereinafter, each configuration described above will be described in detail.

1 and 2, the base portion 20 according to an embodiment of the present invention is a support member that is fixed to the ground and capable of supporting the bicycle 10. As an example, the base portion 20 may be provided in the shape of a square frame in which the front roller 40 and the rear roller 50 to be described later can be seated. However, the present disclosure is not limited thereto, and the front roller 40 and the rear roller 50 may be provided with an arbitrary support member on which the front roller 40 and the rear roller 50 can be seated. In addition, in the base portion 20 according to an example, a support frame 21 to which the frame support portion 30 can be connected may be disposed across both sides of the base portion 20.

The frame support part 30 is a support member that is coupled to the bicycle frame 11 so as to be detachable to stably fix the position of the bicycle 10. As an example, the frame support part 30 may be implemented as a linear rod-shaped support member extending along one direction.

A clamp device 310 is disposed at one end of the frame support part 30 so that one side (down tube) of the bicycle frame 11 may be detachably coupled. In this case, the clamp device 310 may be provided in a detachable form so that one side (down tube) of the bicycle frame 11 may be detachably coupled. However, the present disclosure is not limited thereto, and may be implemented with another type of locking device capable of supporting one side of the bicycle frame 11. The other end of the frame support part 30 may be disposed to be movable along one direction with respect to the support frame 21 provided on the base part 20.

The front roller 40 is a cylindrical component that supports the front wheel 12 of the bicycle 10 mounted on the bicycle simulator 1 and rotates together with the rotation of the front wheel 12, and the mounted bicycle ( Both ends may be rotatably connected to the base portion 20 so as to be freely rotated forward or backward based on 10).

The rear roller 50 is a cylindrical component that supports the rear wheels 13 of the bicycle 10 mounted on the bicycle simulator 1 and rotates together with the rotation of the rear wheels 13, and is a mounted bicycle ( Both ends may be connected to be rotatable with respect to the base portion 20 so as to be freely rotated forward or backward based on 10).

The sensor module 60 is a sensing device for detecting a driving state of the bicycle 10 mounted on the bicycle simulator 1. As an example, the sensor module 60 includes a first sensor unit 610 capable of detecting a driving direction of the bicycle 10, a second sensor unit capable of detecting a driving speed and a driving distance of the bicycle 10 ( 620) and a third sensor unit 630 capable of detecting whether the bicycle 10 is rotated. Matters related to detecting the driving state of the bicycle 10 using the sensor module 60 will be described in more detail with reference to FIGS. 4A to 11.

The input unit 71 may receive a command of the rider R for controlling the bicycle simulator 1 and body information of the rider R. As an example, the input of the input unit 71 is an input to manipulate a button, a keypad, a mouse, a trackball, a jog switch, a knob, etc., an input to touch a touch pad or a touch screen, a voice input, a motion input, a living body. Information input (eg, iris recognition, fingerprint recognition, etc.) may be included, but is not limited thereto.

The memory 73 is an input to at least one component of the bicycle simulator 1 (for example, various data used by the processor 90 or the 　 sensor module 60, for example, software and instructions related thereto It is possible to store data or output data. The 　 memory 73 may include a volatile 　 memory or a non-volatile 　 memory.

The communication module 80 establishes a wired or wireless communication channel between the bicycle simulator 1 and an external electronic device (for example, another bicycle simulator 1-1 or server 2), and communicates through the established communication channel. Can support practice. The communication module 80 may include one or more communication processors operating independently of the processor 90 (eg, an application processor) and supporting wired communication or wireless communication. According to an embodiment, the communication module 80 is a wireless communication module (eg, a cellular communication module, a short-range wireless communication module, or a global navigation satellite system (GNSS) communication module) or a wired communication module (eg, a local area network (LAN)). ) A communication module or a power line communication module), and a network 3 (e.g., Bluetooth, WiFi direct, or a short-range communication network such as IrDA (infrared data association) or a cellular network, the Internet, using a corresponding communication module) Alternatively, it may communicate with external electronic devices through a computer network (for example, a telecommunication network such as a LAN or WAN). The various types of communication modules 80 described above may be implemented as a single chip, or may be implemented as separate chips.

The processor 90 may control at least one other component (eg, hardware or software component) connected to the processor 90 by driving software, for example, and may perform various data processing and operations. have. The processor 90 loads and processes commands or data received from other components (for example, the sensor module 60 or the communication module 80) into a memory 73, for example, a volatile memory, and processes the result data. (73), for example, it can be stored in non-volatile memory.

The display 95 is a component that visually conveys the driving environment or operating system program for the course of a bicycle competition to the rider R, and is a size that encompasses all of the front viewing angle of the rider R as shown in FIG. It may be a curved display or a goggles type display device (not shown) worn by the rider R. As an example, the display 95 may display various objects such as other riders R and obstacles as well as a bicycle driving path.

3A is a schematic diagram of an input unit according to an exemplary embodiment. 3B is a display screen displaying a bicycle avatar according to an exemplary embodiment.

2, 3A, and 3B, the input unit 71 according to an embodiment includes a command of the rider R for controlling the bicycle simulator 1 and body information of the rider R, for example, You can receive information such as gender, age, height, race, hair color, and weight. In addition, the input unit 71 according to an embodiment may receive a model of the bicycle 10 mounted on the bicycle simulator 1. In addition, the bicycle simulator 1 according to an embodiment may secure body information of the rider R without input using the input unit 71 by arranging a weight measurement unit (not shown) under the frame support unit 30. have.

As an embodiment, the input unit 71 is an input to manipulate a button, a key pad, a mouse, a trackball, a jog switch, a knob, etc. integrally formed in the bicycle simulator 1, an input that touches a touch pad or a touch screen , Voice input, motion input, biometric information input (for example, iris recognition, fingerprint recognition, etc.). In addition, the input unit 71 according to an embodiment may be implemented as the user's mobile phone 71-1 as shown in FIG. 3B. The user's mobile phone 71-1 may be connected to the communication module 80 to transmit information input from the user to the processor 90.

In the memory 73, the body information of the rider R input through the input unit 71, the model of the bicycle 10, and the shape of the person and bicycle corresponding to the body information of the rider R detected by other sensing units. It can be stored for each of these types. Accordingly, the processor 90 displays a bicycle avatar T including a shape of a person and a shape of a bicycle corresponding to the body information of the rider R and the model of the bicycle 10 as shown in FIG. 3B ( 95). In this specification, the bicycle avatar T corresponds to the rider R using the bicycle simulator 1 and the bicycle 10 mounted on the bicycle simulator 1, and is defined as a shape displayed on the display 95. As described above, the bicycle avatar T corresponding to the rider R and the bicycle 10 is formed on the cyber, so that the user can virtually experience the same state as the outdoor driving environment even indoors. You can enjoy a more realistic ride indoors.

4A is a partial perspective view of a bicycle simulator according to an embodiment. 4B is an enlarged view of a bicycle simulator according to an embodiment.

As shown in FIG. 1, the frame 11 of the bicycle mounted on the bicycle simulator 1 according to an embodiment is supported by the frame support 30. When the driving direction of the bicycle 10 mounted on the bicycle simulator 1 changes, the frame 11 of the bicycle and the frame support 30 supported by the frame 11 of the bicycle may be formed along the first direction Y. You can move left and right. Accordingly, when detecting the moving direction and the moving distance of the frame support part 30 in the first direction Y, the change in the driving direction and the driving path of the bicycle 10 can be checked. Hereinafter, the change in the driving direction of the bicycle 10 and the driving path of the bicycle 10 are checked using the first sensor unit 610 capable of detecting the moving direction and the moving distance in the first direction Y of the frame support unit 30. How to do it will be described in more detail.

4A to 4B, the bicycle simulator 1 according to an embodiment is fixed to one end of the slide guide 210 and the frame support 30 disposed between both sides of the base 20, It may further include a slide unit 220 connected to be movable along the slide guide 210 and a first sensor unit 610 capable of detecting a moving direction and a moving distance of the slide unit 220.

The slide guide 210 may be formed as a slide rail extending along the first direction Y. As an example, the slide guide 210 may be disposed to be fixed between both sides of the base unit 20. The slide part 220 may be fixed to one end of the frame support part 30 and move together with the frame support part 30 along the first direction Y. Accordingly, the first sensor unit 610 may detect the movement of the slide unit 220 along the first direction Y, thereby detecting the movement of the frame support unit 30 along the first direction Y. In this case, the slide unit 220 may be disposed to be inserted into the slide guide 210, and accordingly, the slide unit 220 may be moved along the slide guide 210.

The first sensor unit 610 may be a distance sensor capable of detecting and tracking a movement interval generated by the slide unit 220 moving along the slide guide 210. As an example, the first sensor unit 610 may be a Time-of-Flight (ToF) sensor, which is a type of distance sensor. For example, when the first sensor unit 610 is implemented as a Time-of-Flight (ToF) sensor, the first sensor unit 610 includes a light source 611 that irradiates a predetermined light and the light source 611 ) May include a light-receiving unit 612 that detects reflected light that is reflected on a part of the slide unit 220 and returned. In the above-described embodiment, a Time-of-Flight (ToF) sensor is disclosed as an example of the first sensor unit 610, but the present invention is not limited thereto. The first sensor unit 610 according to an example may be implemented as an arbitrary sensing device capable of detecting and tracking a movement interval of the slide unit 220 with respect to the base unit 20.

According to an example, the first sensor unit 610 may be disposed to be fixed to one or more of both sides of the base unit 20. Accordingly, the first sensor unit 610 may detect a moving distance and a left and right movement direction of the slide unit 220 with respect to the base unit 20. The driving direction of the bicycle 10 may be detected according to the moving direction of the slide unit 220 sensed by the first sensor unit 610, and the slide unit 220 sensed by the first sensor unit 610 The driving position may be detected according to the moving distance of. Hereinafter, a change in the driving direction of the bicycle 10 and a technical feature in which the driving direction of the bicycle avatar displayed on the display 95 changes by sensing the change in the driving direction of the bicycle 10 will be described with reference to FIGS. 5A to 6B.

5A to 5B are display screens for displaying a change in the driving path of the bicycle avatar according to the change in the driving path of the bicycle. 6A to 6B are schematic plan views of a bicycle simulator according to steering of a bicycle.

Referring to FIG. 5A, a first bicycle avatar T ₁ for a bicycle 10 mounted on a bicycle simulator 1 and a rider R using the bicycle 10 may be displayed on the display 95 according to an exemplary embodiment. have. At this time, on the display 95, as shown in FIG. 2, a second bicycle avatar T ₂ aboard the bicycle simulator 1-1 accessed from another space using the network 3 may be displayed together. have. Accordingly, a plurality of riders located in different spaces may share the same bicycle driving experience using the bicycle simulators 1 and 1-1, thereby providing a more realistic and interesting virtual riding environment.

As an example, when the second bicycle avatar T ₂ and the first bicycle avatar T ₁ are running in parallel, the rider R corresponding to the first bicycle avatar T ₁ increases the speed to a second You may want to overtake the bicycle avatar T ₂ . At this time, when the rider R increases the speed in the same direction and drives, it may collide with the second bicycle avatar T ₂ . In order to prevent a collision with the second bicycle avatar T ₂ , the rider R may change the driving path from the driving road D to the right, for example, as shown in FIG. 5A, and then, the first bicycle As illustrated in FIG. 5B, the avatar T ₁ may perform bicycle driving through a driving path different from that of the second bicycle avatar T ₂ .

As described above, the first sensor unit 610 according to an exemplary embodiment includes the frame support unit 30, more specifically, the first direction (Y) of the slide unit 220 moving together while supporting the frame support unit 30 By detecting the movement along the line, the driving direction of the first bicycle avatar T ₁ displayed on the display 95 may be changed by recognizing a change in the driving direction of the bicycle 10 mounted on the bicycle simulator 1.

As an example, referring again to FIG. 1, when the rider R on the bicycle simulator according to an embodiment of the present invention changes the driving direction of the bicycle 10 to the right, as shown in FIG. 6A The front wheel 12 can rotate clockwise. Thereafter, the frame support part 30 may be moved to the right along the first direction Y along the moving direction of the front wheel 12. Thereafter, the rear wheels 13 may move along the moving direction of the frame support part 30 so that the position of the bicycle 10 may be moved relative to the base part 20 in a state as shown in FIG. 6B. At this time, as shown in FIG. 4B, the first sensor unit 610 fixed to the base unit 20 detects a change in movement along the first direction Y of the frame support unit 30 with respect to the base unit 20 can do.

As an example, after the front wheel 12 rotates in the clockwise direction, when the frame support 30 moves to the right along the first direction Y along the moving direction of the front wheel 12, the frame support 30 ) Fixed to the slide unit 220 may also move to the right along the first direction Y with respect to the base unit 20. At this time, the first sensor unit 610 may detect that the slide unit 220 moves to the right along the first direction (Y), and accordingly detects that the driving direction of the bicycle 10 changes to the right. can do.

In addition, the first sensor unit 610 may detect a changed driving path when the moving state in which the slide unit 220 moves to the right along the first direction Y is completed. As an example, as illustrated in FIG. 6B, when the movement of the slide unit 220 is completed, the first sensor unit 610 may detect the moving distance of the slide unit 220, and the processor 90 is As shown in 5b, the changed driving route may be recognized and the first bicycle avatar T ₁ may be displayed on a driving route different from the second bicycle avatar T ₂ .

Accordingly, a change in the driving direction of the rider R on the bicycle 10 and a change in the driving path according thereto can be detected in real time by the first sensor unit 610, and the driving direction and the driving path of the bicycle 10 The change in the driving direction and the driving route of the first bicycle avatar T ₁ corresponding to the change may also be reflected in real time and implemented on the display 95.

7 is a partial perspective view of a bicycle simulator according to an embodiment. 8A is a display screen showing a change in a driving path of a bicycle avatar according to a change in the driving speed of the bicycle. 8B is a display screen showing a bicycle avatar driving on an inclined driving path according to an exemplary embodiment.

As shown in FIG. 1, the front wheels 12 and the rear wheels 13 of the bicycle mounted on the bicycle simulator 1 according to an embodiment are supported by the front rollers 40 and the rear rollers 50, respectively. As the front wheel 12 and the rear wheel 13 rotate, the front roller 40 and the rear roller 50 can also rotate, so the front wheel 12 and the rear wheel of the bicycle 10 mounted on the bicycle simulator 1 When the rotation speed and rotation distance of 13) change, the rotation speed and rotation distance of the front roller 40 and the rear roller 50 may also be changed. Therefore, when detecting the rotation speed and rotation distance of the front roller 40 and the rear roller 50, the running speed and the running distance of the bicycle 10 can be checked. Hereinafter, the change in the driving speed and the driving distance of the bicycle 10 are checked by using the second sensor unit 620 capable of detecting the rotational speed and rotation distance of at least one of the front roller 40 and the rear roller 50. How to do it will be described in more detail.

Referring to FIG. 7, the bicycle simulator 1 according to an embodiment further includes a second sensor unit 620 capable of detecting a rotation speed and a rotation distance of at least one of the front roller 40 and the rear roller 50. Can include.

The second sensor unit 620 according to an embodiment of the present invention may be implemented as a magnetic encoder including a magnetic flux sensor, and may include a plurality of permanent magnets 621 and 622 and a rotation speed detection unit 623. I can. As an example, permanent magnets 621 and 622 having different poles are alternately magnetized along the outer peripheral surface of the front wheel roller 40. At this time, the permanent magnets 621 and 622 are formed as an integral type in which half of the front roller 40 is formed as an N pole and the other half is formed as an S pole, or are formed of a plurality of independent permanent magnets arranged at regular intervals along the outer circumferential surface. Can be. As an example, the second sensor unit 620 detects the magnetic flux linkage of the permanent magnets 621 and 622 with respect to the rotation speed detecting unit 623 that regularly changes as the front roller 40 rotates It can be output as a signal. Thereafter, the output signal is applied to the processor 90 to detect the rotation speed and rotation distance of the front roller 40. In an embodiment of the present invention, the second sensor unit 620 is illustrated as a magnetic encoder including a magnetic flux sensor, but the present invention is not limited thereto. As an example, the second sensor unit 620 may be implemented as an optical encoder having a light source and a light receiving unit, and at this time, a reflective member capable of reflecting light incident from the light source is disposed on the outer circumferential surface of the front wheel roller 40 It could be. In addition, the second sensor unit 620 according to an example may be disposed on the rear roller 50 as well as the front roller 40, or may be disposed on the front roller 40 and the rear roller 50.

As described above, the second sensor unit 620 may sense the rotational speed and rotation distance of at least one of the front roller 40 and the rear roller 50 and transmit it to the processor 90, and the processor 90 (12) From the size of the circumference of the rear wheel 13 and the number of rotations of the front wheel 12 and the rear wheel 13 per unit time, the driving speed and the driving distance of the bicycle 10 may be calculated.

Referring to FIG. 8A, a first bicycle avatar T ₁ and a second bicycle avatar T ₂ may be displayed together on the display 95 according to an exemplary embodiment. Since the matters related to the first bicycle avatar T ₁ and the second bicycle avatar T ₂ are substantially the same as those described in FIGS. 5A and 5B, the description will be omitted here.

As an example, when the second bicycle avatar T ₂ and the first bicycle avatar T ₁ run in parallel, bicycles corresponding to the first bicycle avatar T ₁ and the second bicycle avatar T ₂ According to the driving speed of (10), the adjacent distances of the _first and second bicycle avatars T ₁ and T ₂ may be displayed differently. For example, the driving speed of the bicycle 10 corresponding to the first bicycle avatar T ₁ by the second sensor unit 620 is the driving speed of the bicycle 10 corresponding to the first bicycle avatar T ₁ If it is faster, the first bicycle avatar T ₁ may be displayed on the display 95 so as to be driven closer to the second bicycle avatar T ₂ . In addition, the current driving speed and driving distance of the bicycle 10 may be displayed in real time on the display 95 to check the amount of exercise of the rider R.

Referring to FIG. 8B, on the display 95 according to an exemplary embodiment, a bicycle avatar T disposed on a slope having a predetermined slope angle θ may be displayed. As an example, when the bicycle avatar T travels on an uphill driving path having a predetermined inclination angle θ, the bicycle avatar T drives the uphill driving path according to the driving speed of the bicycle 10 corresponding to the bicycle avatar T. The driving state of the bicycle avatar T may be displayed differently.

For example, when the driving path is changed from flat to an uphill with a predetermined inclination angle θ on the display 95, the front roller 40 and the rear roller detected by the second detection unit 620 on the flat ground If the rotation speed of the front roller 40 and the rear roller 60 detected by the second detection unit 620 on an uphill slope is higher than the rotation speed of 60, the bicycle avatar T on the display 95 is It can be marked to go uphill. However, than the rotation speed of the front roller 40 and the rear roller 60 sensed by the second detector 620 on a flat ground, the front roller 40 and the front roller 40 sensed by the second detector 620 on an uphill slope If the rotational speed of the rear roller 60 is slower, the bicycle avatar T on the display 95 may be displayed so as not to climb the uphill driving path or to be pushed back.

In addition, for example, when the driving path is changed from a flat surface to a downhill slope having a predetermined inclination angle (not shown) on the display 95, the front wheel roller 40 detected by the second detection unit 620 and Even when the rotation speed of the rear roller 60 and the rotation speed of the front roller 40 and the rear roller 60 detected by the second detection unit 620 on the downhill are the same, the bicycle avatar T on the display 95 May be displayed to go down the downhill road at a faster speed. As described above, by sensing the running speed of the bicycle 10 using the second sensor unit 620 and reflecting it on the display 95, the user does not travel on a slope having an actual inclination angle, You can experience the same driving experience as driving on an actual slope.

9 is a display screen showing a change in a driving path of a bicycle avatar according to an exemplary embodiment. 10 is a partial perspective view of a bicycle simulator according to an embodiment. 11 is a plan view of a bicycle simulator according to an embodiment.

As shown in FIG. 9, when a specific path, for example, a crossroad is displayed among the driving paths of the bicycle avatar T displayed on the display 95 according to an embodiment, the rider R travels in one direction of the crossroads. You can continue cycling by selecting a route. As an example, when the driving path displayed on the display 95 is a rotational driving path that continuously rotates in one direction, as shown in Figs. 6A and 6B, the frame support unit 30 detects movement in one direction. 1 The rotation driving direction of the bicycle 10 may be detected by the sensor unit 610. In addition, as an example, detection of the rotational driving direction of the bicycle 10 is disposed on both inner sides of the base unit 20 as well as the first sensor unit 610 so that it is disposed on either side of the slide unit 220. It may be sensed by a contact sensor that is sensed by sensing a contact. Referring to FIG. 10, a bicycle simulator 1 according to an embodiment includes a slide guide 210 and a frame disposed on the base portion 20. It is fixed to one end of the support part 30, is disposed on both inner sides of the slide part 220 and the base part 20 connected to be movable along the slide guide 210, any of the two sides of the slide part 220 It may further include a third sensor unit 630 capable of detecting a contact with one. Since the matters related to the slide guide 210 and the slide unit 220 are the same as those shown in FIGS. 4A and 4B, a description thereof will be omitted.

It may be a contact sensor disposed at both inner sides of the third sensor unit 630 and capable of detecting contact with either side of the slide unit 220. As an example, the third sensor unit 630 may be implemented in the form of two micro switches and may be disposed on both inner sides of the base unit 20, respectively. In this case, the third sensor unit 630 may be disposed at positions corresponding to both sides of the slide unit 220, respectively. In the above-described embodiment, a micro switch is disclosed as an example of the third sensor unit 630, but the present invention is not limited thereto. The third sensor unit 630 according to an example may be implemented as an arbitrary sensing device capable of detecting and tracking a contact between an inner surface of the base unit 20 and a side surface of the slide unit 220. .

Referring back to FIGS. 9 and 11, when the rider R according to an embodiment selects a driving path in the right direction among a forked road, the rider R may select the driving direction of the bicycle 10 in the right direction. have. At this time, the frame support part 30, more specifically, the slide part 220 that supports the frame support part 30 and moves together may also move to the right. In a rotating driving path such as a forked road, the rider R can continuously select the driving direction of the bicycle 10 to the right, and accordingly, one side of the slide unit 220 is disposed on the right side of the base unit 20. The third sensor unit 630 may be contacted. When the contact between the third sensor unit 630 disposed on the right side of the base unit 20 and the slide unit 220 is detected, the processor 90 confirms that the driving path of the bicycle 10 is selected to the right, The driving path of the bicycle avatar T at the forked road may be determined to the right. The above-described driving route selection method may be used not only for a forked road route but also for all rotational routes that continuously rotate along one direction.

As described above, by changing the driving state of the bicycle avatar implemented on the display according to the driving state of the bicycle, the rider of the bicycle simulator 1 can virtually experience the same state as the outdoor driving environment indoors. Riders can enjoy a more realistic ride indoors. In addition, by sharing bicycle driving experiences with riders located in different spaces in cyberspace, riders can be provided with a more realistic and exciting virtual riding environment.

12 is a display screen showing a driving state of a bicycle avatar.

As illustrated in FIG. 12, in the bicycle driving path displayed on the display 95 according to an exemplary embodiment, in addition to the bicycle avatar T, obstacles K such as driving roads, trees, and curbs may be disposed. The processor 90 may recognize a position in which the bicycle avatar T is disposed in the bicycle driving path displayed on the display 95. At this time, the processor 90 may identify the distance between the coordinates in which the bicycle avatar T is placed and the coordinates in which the obstacles are placed, and when an obstacle is disposed within a predetermined range and a collision risk is recognized, the processor 90 ) May display a warning message on the display 95 to realize the driving experience of the rider R more realistically.

13A to 13C are display screens showing a game progress state according to an exemplary embodiment.

As shown in FIG. 4B, the bicycle simulator 1 according to an embodiment is fixed to one end of the slide guide 210 and the frame support 30 disposed on the base part 20, and the slide guide ( It may further include a slide unit 220 connected to be movable along 210 and a first sensor unit 610 capable of detecting a moving direction of the slide unit 220. Since the matters related to the slide guide 210 and the slide unit 220 are the same as those shown in FIGS. 4A and 4B, a description thereof will be omitted.

Referring to FIG. 13A, a character Z that can move left and right according to the driving direction of the bicycle 10 may be displayed on the display 95 according to an exemplary embodiment. As an example, the character Z is displayed in the shape of an airplane, but the present specification is not limited thereto. In the present specification, the character Z may be displayed on the display 95 and may be defined as an arbitrary shape that may move together according to the left and right movement of the bicycle 10.

As an example, as shown in FIG. 6B, when the bicycle 10 moves along the first direction Y, the first sensor unit 610 may be applied to the slide unit 220 with respect to the base unit 20. One can detect a change in movement along the direction (Y). The processor 90 may receive a change in the movement of the bicycle 10 by the first sensor unit 610, and using the processor 90, the character moves from the first position (Z ₁ ) before moving It may move to the right to the second position Z ₂ .

In addition, as shown in FIG. 7, the bicycle simulator 1 according to an embodiment includes a second sensor unit 620 capable of detecting a rotation speed and a rotation distance of at least one of the front roller 40 and the rear roller 50. ) May be further included. The second sensor unit 620 according to an example may sense a rotation speed and a rotation distance of at least one of the front roller 40 and the rear roller 50 and transmit it to the processor 90, and the processor 90 (12) It is possible to calculate the running speed of the bicycle 10 from the size of the circumference of the rear wheels 13 and the number of rotations of the front wheels 12 and rear wheels 13 per unit time.

Referring to FIG. 13B, a character Z capable of moving forward and backward according to the driving speed of the bicycle 10 may be displayed on the display 95 according to an exemplary embodiment. As an example, when accelerating from the first driving speed of the bicycle 10 to the second driving speed, the acceleration state of the bicycle 10 may be detected using the second sensor unit 620. The processor 90 may receive a change in the speed of the bicycle 10 by the second sensor unit 620, and by using the processor 90, the character moves from the first position (Z ₁ ) before moving. It is possible to move forward to the second position Z ₂ .

As described above, the character Z may move up and down and move left and right on the display 95 according to the change in the speed of the bicycle 10 and the change in left and right movement. Accordingly, the bicycle simulator according to an exemplary embodiment may implement movement on a two-dimensional plane of the character Z displayed on the display 95 by using a change in speed of the bicycle 10 and a change in left and right movement. Accordingly, the bicycle simulator according to an embodiment may be used in place of a control device such as a joystick used in a game machine. However, the present disclosure is not limited thereto, and the bicycle simulator according to an exemplary embodiment may be used as an arbitrary control device for controlling the two-dimensional movement of the character Z displayed on the display 95.

In the above-described embodiment, a change in movement of the character Z according to a change in speed of the bicycle 10 and a change in left and right movement was controlled, but the operating state of the character Z according to a change in the speed of the bicycle 10 or a change in left and right movement You can also control it.

Referring to FIG. 13C, a projectile Q, for example, a missile launched from the character Z according to the driving speed of the bicycle 10 may be displayed on the display 95 according to an exemplary embodiment. As an example, the projectile Q is indicated as a missile, but the present specification is not limited thereto. In the present specification, the projectile (Q) is an arbitrary state of the character (Z) that can be changed according to the running speed of the bicycle (10), for example, the firing of the projectile (Q) from the character (Z), the character (Z) It may be defined as a change in the firing speed of the projectile (Q) fired from.

As an example, when accelerating from the first driving speed of the bicycle 10 to the second driving speed, the acceleration state of the bicycle 10 may be detected using the second sensor unit 620. The processor 90 may receive a change in the speed of the bicycle 10 by the second sensor unit 620, and using the processor 90, the projectile Q is launched from the character Z or the projectile ( Q)'s rate of fire can be increased.

As described above, by using the first sensor unit 610 and the second sensor unit 620 to detect the driving speed and driving direction of the bicycle 10 and reflect this on the character Z on the display 95, The rider R using the bicycle simulator according to an exemplary embodiment may experience the same virtual experience as manipulating the movement and state change of another character Z while exercising while driving the bicycle 10.

14 is a block diagram illustrating a block chain network system 1000 related to a bicycle simulator according to an embodiment.

Referring to FIG. 14, a block chain network system 1000 according to an embodiment may include one or more node computers 1100 forming a block chain network and one or more 　 cryptocurrency 　 issuing devices 1200. Blockchain network is a network in which node computers 1100 are connected to each other in a peer-to-peer (P2P) method through the Internet. To form and manage a blockchain network, and to support each node computer 1100 to perform the function of 　 cryptocurrency 　 transaction, a blockchain management server (not shown) can be connected to the blockchain network if necessary. The node computer 1100 to join the blockchain network may be registered in the blockchain network by the blockchain management server. The cryptocurrency 　 issuing device 1200 may be the same as the block chain management server or may be installed separately from the block chain management server.

The node computer 1100 belonging to the blockchain network is not particularly limited as long as it performs general computing functions. For example, the node computer 1100 may include a smartphone or tablet PC capable of accessing the Internet through mobile communication or Wi-Fi, a desktop PC capable of accessing the Internet through LAN or Wi-Fi, and a notebook PC. have.

The node computer 1100 according to an embodiment may include user nodes 111-1130 and trader nodes 1141 and 1142. The user nodes 1110-1130 may be servers used by the rider R who uses the bicycle simulator 1. In this case, there may be one or more user nodes connected to the blockchain network 1000. For example, when there are three lighters R using the bicycle simulator 1, a first user node to a third user node 1110-1130 may be formed.

As an example, the trader nodes 1141 and 1142 may be servers used by a transaction target that transacts the cryptocurrency generated by the cryptocurrency generating device 1200 with the user node 1110-1130. For example, the trader node may be a public period node 1141 or a financial institution node 1142 that wants to trade the rider R's exercise information. For example, a public institution may be a health insurance corporation that can use the rider's health information using the rider's exercise information, a national health care institution, or a health care-related institution included in various local governments, but is limited thereto. It does not become. In addition, for example, the financial institution may be a private medical insurance company and a private medical insurance institution that can use the health information of the rider R by using exercise information of the rider R, but is not limited thereto.

In the above-described embodiment, the targets that may be included in the node compuator 1100 are set to the user node 111-1130, the public institution node 1141, and the financial institution node 1142, but the present invention is not limited thereto. . An object that can be included in the node computer 1100 is an arbitrary party that can use the momentum data generated using the bicycle simulator 1, and may be a server used by the party.

The exercise amount verification device 1300 is a device owned by the owner of the node computer 1110 belonging to the blockchain network, and may be installed or connected to the bicycle simulator 1 according to an embodiment of the present invention. The driving route, the driving distance, the driving speed, the driving time, etc. of the rider R driven by using the bicycle simulator 1 may be used as data proving the amount of exercise by the exercise amount proof device 1300. At this time, since the owner of the user node 1110-1130, that is, the rider R using the bicycle simulator 1, receives the newly issued 　 cryptocurrency by the cryptocurrency 　 issuing device 1200, in this specification 　 cryptocurrency Named the recipient. The momentum proof device 1300 is the same as the owner of the node computer 1100 so that it can be confirmed that the momentum proof device 1300 and the node computer 1100 according to an embodiment are owned or managed by the same owner. Information about the recipient, such as ID, can be stored.

The exercise amount verification device 1300 transmits the exercise amount data achieved using the bicycle simulator 1 to the 　 cryptocurrency 　 issuing device 1200. At this time, when the momentum verification device 1300 and the node computer 1100 are the same device, the momentum verification device 1300 and the node computer 110 must belong to the same blockchain network. However, the present disclosure is not limited thereto, and when the momentum proof device 1300 and the node computer 1100 are formed separately, the momentum proof device 1300 does not necessarily need to belong to a blockchain network, and other communication networks, eg For example, it may be connected to the 　 cryptocurrency 　 issuing device 1200 through the Internet.

In addition, the momentum verification device 1300 may be implemented in the form of a dAPP (Distributed Application, that is, a distributed application program) and connected to a blockchain network. In this case, not only one specific node computer connected to the blockchain network becomes the 　 cryptocurrency 　 issuing device 1200, but one or more node computers 1100 connected to the blockchain network can operate as the 　 cryptocurrency 　 issuing device 1200. .

The cryptocurrency 　 issuing device 1200 receives and verifies the momentum data and issues a new cryptocurrency proportional to the achieved exercise and pays the cryptocurrency to the recipient. At this time, that the newly issued 　 cryptocurrency is paid to the 　 cryptocurrency 　 recipient, a new block is created by the 　 cryptocurrency 　 issuing device 1200 or the node computer 1100, and such a block is transferred to another node computer 1100 By verification, the payment of the newly issued 　 cryptocurrency is confirmed, and it means that the transaction details are stored in all or some node computers 1100 belonging to the blockchain network. Thereafter, the same 　 cryptocurrency 　 recipient can check the amount of 　 cryptocurrency paid using their node computer (1100) or other computing device, and also, after moving the paid 　 cryptocurrency to an electronic wallet 　 cryptocurrency 　 can be used for transactions. have.

According to an embodiment, the range of a new blockchain network formed by the cryptocurrency issuing device 1200 and the node computer 1100 may be set differently. As an example, when the node computer 1100 includes one or more user nodes 1110-1130 and one or more trader nodes 1141, 1142, the scope of the blockchain network according to the scope of participants participating in the blockchain network. Can be set differently.

For example, if the cryptocurrency formed by the cryptocurrency issuing device 1200 is used only by a specific financial institution, the range (B1) of the new blockchain network that forms the cryptocurrency is the user node (1110-1130) and the public It can be set to the engine 1141. Cryptocurrencies created in the range (B1) of the new blockchain network can be generated only between user nodes 111-1130 and public institutions 1142. In addition, after moving the paid 　 cryptocurrency to the electronic wallet 　 can only be used in cryptocurrency 　 transactions between the user node (1110-1130) and the public institution (1142).

In the above, although specific embodiments of the present invention have been described and illustrated, the present invention is not limited to the described embodiments, and various modifications and variations can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have. Therefore, such modifications or variations should not be individually understood from the technical spirit or viewpoint of the present invention, and the modified embodiments should be said to belong to the claims of the present invention.

1: bike simulator
10: bicycle
11: bicycle frame
12: front wheel
13: rear wheel
20: base portion
21: support frame
30: frame support
40: front wheel roller
50: rear wheel roller
60: sensor module
71: input
73: memory
80: communication module
90: processor
95: display
210: slide guide
220: slide part
610: first sensor unit
620: second sensor unit
630: third sensor unit

Claims (24)

Base portion;
A frame support part connected to the base part so as to be movable along one direction and supporting a frame of the bicycle that connects the front and rear wheels of the mounted bicycle;
A first sensor unit detecting a moving distance and a moving direction of the frame support unit along the one direction;
A communication circuit for receiving a moving distance and a moving direction of the frame support unit detected by the first sensor unit;
A processor for generating a bicycle avatar whose driving direction is changed according to a moving distance and a moving direction of the frame support unit transmitted from the communication circuit; And
Including; a display for displaying the driving state of the bicycle avatar
Bike simulator. The method of claim 1,
A slide guide disposed to be fixed between both side portions of the base portion and extending along one direction; And
A slide part fixed to one end of the frame support part and connected to be movable on the slide guide along the one direction; further comprising,
The first sensor unit detects a moving direction and a moving distance of the slide unit moving on the slide guide,
Bike simulator. The method of claim 1,
The processor,
Determining the driving direction of the bicycle avatar according to the moving direction of the frame support unit, and determining the position of the bicycle avatar in the driving path according to the moving distance of the frame support unit,
Bike simulator. The method of claim 1,
A front wheel roller supporting the front wheel of the bicycle and rotating together with the rotation of the front wheel;
A rear wheel roller supporting the rear wheel of the bicycle and rotating together with the rotation of the rear wheel; And
A second sensor unit for sensing the rotational speed and rotation distance of at least one of the front roller and the rear roller; further comprising
Bike simulator. The method of claim 4,
The processor,
Determining a running speed of the bicycle avatar according to a rotation speed of at least one of the front roller and the rear roller detected by the second sensor unit,
Determining a driving distance of the bicycle avatar according to a rotation distance of at least one of the front roller and the rear roller detected by the second sensor unit,
Bike simulator. The method of claim 1,
A weight measuring unit that measures the weight of a rider on the bicycle; And
An input unit for inputting at least one of the model of the bicycle and the information of the rider riding the bicycle; further comprising,
Bike simulator. The method of claim 6,
The processor,
Generating a bicycle avatar according to the information of the rider and the bicycle input from the weight measurement unit and the input unit,
Bike simulator. The method of claim 2,
A third sensor unit disposed on both sides of the base unit and sensing contact between the slide unit and one side surface of the base unit; further comprising,
Bike simulator. The method of claim 8,
The processor,
When a contact between either side of the slide part and the base part is detected by the third sensor part, adjusting the driving path of the bicycle avatar so that the bicycle avatar travels along a specific path,
Bike simulator. The method of claim 9,
The specific path is a driving environment including a forked road, and the driving direction of the forked road is determined according to a side surface of the base part in contact with the slide part.
Bike simulator. The method of claim 1,
The processor,
When the bicycle avatars are arranged to be adjacent to each other with an obstacle or another avatar at a predetermined interval or less, a warning message is displayed on the display.
Bike simulator. The method of claim 4,
The processor,
Determining a driving state of the bicycle avatar on a flat road and an inclined road on which the bicycle avatar travels, according to a rotation speed of at least one of the front and rear rollers sensed by the second sensor unit,
Bike simulator. The method of claim 1,
When the bicycle avatar is driving in a driving environment including a forked road, the driving direction of the forked road is determined according to the change in the moving direction detected by the first sensor unit.
Bike simulator. A cryptocurrency issuing device that generates cryptocurrency according to the momentum data obtained from the bicycle simulator according to claim 1; And
Including; a node computer forming a blockchain network with the cryptocurrency issuing device
Blockchain network system. The method of claim 14,
The node computer,
It is used by a rider using the bicycle simulator and includes at least one user node that receives the cryptocurrency generated from the cryptocurrency issuing device.
Blockchain network system. The method of claim 15,
The node computer,
Including one or more trader nodes for trading the cryptocurrency with the user node
Blockchain network system. The method of claim 16,
The scope of the blockchain network is,
It is set differently according to the range of participants participating in the blockchain network among the one or more user nodes and the one or more trader nodes,
Blockchain network system. The method of claim 14,
Further comprising an exercise amount verification device for verifying the exercise amount data achieved using the bicycle simulator and transmitting to the cryptocurrency issuing device,
Blockchain network system. Base portion;
A frame support part connected to the base part so as to be movable along one direction and supporting a frame of the bicycle that connects the front and rear wheels of the mounted bicycle;
A first sensor unit detecting a moving distance and a moving direction of the frame support unit along the one direction;
A communication circuit for receiving a moving distance and a moving direction of the frame support unit detected by the first sensor unit;
A processor for generating a character whose driving direction is changed according to a moving distance and a moving direction of the frame support unit transmitted from the communication circuit; And
Including; a display for displaying the driving state of the character
Bike simulator. The method of claim 19,
A slide guide disposed to be fixed between both side portions of the base portion and extending along one direction; And
A slide part fixed to one end of the frame support part and connected to be movable on the slide guide along the one direction; further comprising,
The first sensor unit detects a moving direction and a moving distance of the slide unit moving on the slide guide,
Bike simulator. The method of claim 19,
The processor,
Determining the moving direction of the character according to the moving direction of the frame support, and determining the position of the character according to the moving distance of the frame support,
Bike simulator. The method of claim 19,
A front wheel roller supporting the front wheel of the bicycle and rotating together with the rotation of the front wheel;
A rear wheel roller supporting the rear wheel of the bicycle and rotating together with the rotation of the rear wheel; And
A second sensor unit for sensing the rotational speed and rotation distance of at least one of the front roller and the rear roller; further comprising
Bike simulator. The method of claim 22,
The processor,
Determining the forward or backward movement of the character according to the rotational speed of at least one of the front roller and the rear roller sensed by the second sensor unit,
Bike simulator. The method of claim 22,
The processor,
Determining whether or not a projectile launched from the character is fired or a firing speed according to a rotation speed of at least one of the front roller and the rear roller sensed by the second sensor unit,
Bike simulator.

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