KR20180054535A - Method and apparatus for providing realistic service for riding - Google Patents

Abstract

Disclosed are a method and a device for providing a realistic riding service. The method for providing a realistic riding service comprises the following steps of: a realistic riding service server receiving riding information from a rider device; and the realistic riding service server providing the riding information to a realistic riding service indoor bicycle. The riding information includes riding video information which is imaged on a real riding course and riding additional information which is collected on the real riding course. The riding video information and the riding additional information are synchronized. A user of the realistic riding service indoor bicycle can receive the realistic riding service based on the riding video information and the riding additional information.

Description

TECHNICAL FIELD The present invention relates to a method and apparatus for providing realistic riding service,

The present invention relates to realistic service, and more particularly, to a method and apparatus for providing realistic riding service.

The realistic service can be an integrated representation of various types of elementary media information that can provide a sense of reality and immersion while overcoming space and time constraints in a virtual environment. The realistic service can be realized by generating, processing, storing, transmitting, reproducing, and the like multi-dimensional information including visual, auditory, and tactile information.

In addition, multidimensional realistic media information can maximize the sense of reality and immersion by real-time interaction through the network. Therefore, high quality realistic media service can be provided based on high performance network infrastructure.

Synchronization between media and devices is needed for realistic services. In order to provide a sense of immersion, a realistic service needs to integrate and synchronize with media data providing various sensory information (visual, auditory, tactile, etc.).

In addition to this, it is important to adjust the sensible media / devices adaptively to reflect the current environment of the user who receives the actual sensation service.

10-2010-0020907

It is an object of the present invention to provide a method for providing realistic riding services.

It is another object of the present invention to provide an apparatus for performing a method of providing realistic riding services.

A method of providing realistic riding service according to an aspect of the present invention includes receiving realizing riding service server's riding information from a rider device and providing the realizing riding service server with riding information to an actual riding service indoor bike Wherein the riding information includes riding motion picture information sensed on an actual riding course and riding additional information collected on the actual riding course, the riding motion picture information and the riding additional information are synchronized, The user of the indoor bicycle can receive the real-life riding service based on the riding motion picture information and the riding-side information.

The method and apparatus for providing realistic riding service according to the embodiment of the present invention adaptively reflects the situation according to the user's riding based on the riding video and riding part information generated in advance, You can provide an experience similar to riding a bicycle.

1 is a conceptual diagram illustrating a real-life riding service system according to an embodiment of the present invention.
2 is a conceptual diagram illustrating a real-life riding service method according to an embodiment of the present invention.
3 is a conceptual diagram illustrating a method of providing a moving image according to an embodiment of the present invention.
4 is a conceptual diagram illustrating a method in which a plurality of users simultaneously receive real-life riding services according to an embodiment of the present invention.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with an embodiment. It is also to be understood that the position or arrangement of the individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

In the embodiment of the present invention, when the indoor bicycle is used, the majority of the present indoor bicycles which provide only simple information such as speed, moving distance and calorie are displayed on the display, and the mountainous terrain and the flat road , Unpaved roads, etc.) can be provided through a dedicated display or television (TV), virtual reality (VR) glasses or the like located on the front side of the indoor bicycle.

The user can receive the same experience as that of the actual bicycle based on the indoor bicycle (hereafter, real bicycle riding service indoor bicycle) which provides realistic riding service . Information on the characteristics of the movement of the bicycle may include information on the speed of the bicycle, the tilt of the bicycle, the direction of the bicycle, and the automatic conversion of gears according to the level of the terrain of the bicycle.

Based on the linkage between these videos and the characteristics of the movement of the indoor bicycle, it is possible to provide the users of the indoor bicycle with the enjoyment of riding and the users who can not ride the bicycle in the outdoors due to the limitation of riding on the actual bicycle It is possible to experience a riding condition similar to the actual situation at a relatively low cost.

1 is a conceptual diagram illustrating a real-life riding service system according to an embodiment of the present invention.

Referring to FIG. 1, the realistic riding service system may include a realistic riding service indoor bicycle 150 and a realistic riding service server 100.

The sensory riding service indoor bicycle 150 may include an indoor bicycle 110, a display unit 120, a control unit 130, and a communication unit 140.

The indoor bicycle 110 may be implemented to provide the user with an experience similar to the actual riding. The indoor bicycle 110 may be implemented to have a motion characteristic matching with an image characteristic provided by the display unit 120. [ That is, the matching between the motion characteristics of the indoor bicycle 110 and the provided image information can be performed.

The display unit 120 may be implemented to provide a user with a riding video such as a dedicated display, television (TV), or virtual reality (VR) glasses. If the display 120 is implemented as VR glasses, the realism can be maximized.

The control unit 130 may be implemented to control the indoor low-volume 110 / the display unit 120 / the communication unit 140 based on the riding-side information synchronized with the riding motion picture.

The communication unit 140 may be implemented to receive riding motion picture information and riding supplementary information from the realistic riding service server 100.

The sensation riding service server 100 may be implemented to receive riding motion / riding incident information according to a user's request.

The photographing of the riding video to provide a sense similar to the actual riding to the user can be carried out in a mountain where the bicycle is possible to run, a flat ground, and the like. Riding videos can be generated by riding experts (hereinafter referred to as "riders") at various places by various seasons (spring, summer, autumn, etc.). The rider may perform the role of generating the riding video and riding side information. The riding motion picture can be performed based on a camera capable of 360-degree photographing, and the velocity, time, distance, centrifugal force, inertia, heart rate, pressure to press the pedal, That is, the riding unit information may be generated based on a sensor attached to the bicycle, a biometric sensor attached to the rider, or the like when generating the actual riding video. The riding motion picture information and the riding-side information can be synchronized with each other and matched. That is, the riding-side information at a specific position of a specific riding course may be matched. The term riding information may be used in the sense that it includes riding motion picture information and riding-side information.

The course provided by the riding video can be a mountainous terrain with excellent scenery, general paved roads, unpaved roads, bicycle-specific roads, etc., and each course can have one, And can be updated continuously. The maximum distance of each course provided by the riding video can be extended or shortened considering 10 km of mountain area and 20 km of plain or road in consideration of the amount of data, considering the characteristics of surrounding scenery and course.

The riding side information can be synchronized with the riding motion picture and can be generated as riding data together. The display 120 may display information such as altitude difference, position on the course, measurement of physical strength, speed, distance, etc. as additional information together with the moving image.

The indoor bicycle 110 is synchronized with the riding motion video currently being played based on the riding motion picture and the riding motion information, so that the height of the front and rear portions according to the current terrain, the inertia in the lateral direction, ≪ / RTI >

The user can select a course to be ridden through the display 120. [ The user can select a specific position among the courses provided by the riding video as a starting point for the course. The starting point for each course depends on the user's choice, but basically it can be the point where the video starts.

Synchronization of the riding motion picture and the indoor bicycle 110 can be performed by the control unit. The control unit 130 can control the movement of the indoor bicycle 110 based on the riding-side information corresponding to the playback position of the riding motion picture currently being played back on the display. The user can receive a feeling similar to the actual riding environment based on the control of the motion of the indoor bicycle 110.

According to the embodiment of the present invention, gravity acceleration is generated in addition to the number of revolutions of the pedal when the vehicle is descending on a course with a severe inclination, Can be considered. For example, when the vehicle is provided with a length riding video having an incline such as an uphill / downhill on the riding video, the pressure to step on the uphill / ) So that the pressure of the pedal is increased as the user climbs the actual uphill, and the pressure of the pedal can be reduced as the user actually goes downhill. In a rising terrain with a severe inclination, the saddle of the indoor bicycle may be raised to spread the pressure to the pedal so as to spread the knee, and in a descending terrain, a riding environment can be realized in which riding can be enjoyed regardless of the rotation of the pedal. Such a riding environment can be created when a rider who has taken a picture of a riding motion picture unfolds his or her knees in a real situation.

Also, the gears of the indoor bicycle 110 can be automatically changed based on the automatic conversion system / riding unit information that changes the number of gears by modulating the pressure transmitted to the pedals according to the inclination of each course. For example, when riding uphill on a course of a riding motion picture, the gear of the indoor bicycle 110 is set at a high stage based on the riding side information, and when the downward riding is being performed, have.

In addition, the inclination of the left side and the right side of the indoor bicycle 110 can be changed according to the curvature of the course. The change of the tilt / steering wheel of the actual bicycle 110 may be measured based on the sensor installed on the actual bicycle 110 at the time of photographing the riding motion picture, so that the riding unit information may be generated. The inclination / handle of the indoor bicycle 110 can be controlled and changed based on the riding unit information.

In addition, the speed of the riding motion picture and the pedaling speed of the indoor bicycle 110 can be synchronized. When the user performs the pedaling of the indoor bicycle 110 relatively fast, the riding motion picture can be played relatively fast, and when the user performs the pedaling of the indoor bike 110 relatively slowly, It can be reproduced slowly. Realistic riding service In the indoor bicycle 150, a correction operation may be performed to prevent the image from being broken due to the difference between the speed of the riding motion picture and the pedaling speed of the indoor bike 110.

Further, when the brakes are present in the indoor bicycle 110 and the user uses the brakes of the indoor bicycle 110, the riding motion picture may also be stopped.

Also, the difficulty level of each riding course can be adjusted so that the degree of difficulty of each course can be adjusted based on the intermediate level. For example, as the difficulty level is relatively higher, the power for pedaling can be increased, The power to enter the pedal can be reduced. That is, even if the same uphill climb occurs, the power to enter the pedaling may vary depending on the degree of difficulty.

In addition, it is possible to allow five persons to be photographed at the same time when photographing the riding motion picture, so that the user can select from one person mode to five persons mode. For example, when the mode from 2 to 5 is selected, a plurality of users can provide a user the same experience as selecting one course at the same time and riding together.

In addition, an indoor game function can also be installed in the realistic riding service indoor bicycle 150, so that various situations can be provided together with the riding video or separately so that the user can play the game.

In addition, the number of gears of the indoor bicycle 110 can be set in consideration of the fun of the user's momentum and speed at the time of rise and fall. For example, if the user desires more momentum, a gear stage is set such that more force is applied to the user's pedaling, and if the user wants to enjoy speed rather than momentum, So that the gear speed can be set so that the speed can be increased.

In riding video, not only video information but also audio information tailored to the video can be provided. For example, when the image provided as image information is a video image for a forest, the sound information may include a forest water sound, a bird sound, and the like.

The riding video is stored in the real-life riding service server 100 of the supplier, managed and continuously updated, and can be downloaded through the communication unit 100 including a Wi-Fi (including mobile phone use) or a 4G communication module.

In addition, the ability between the rider participating in the video production and the user using the actual indoor bicycle can be corrected in real time, and the rider can compare the weight with the weight of the user, thereby setting the riding environment suitable for the weight of the user. For example, the user can be reset to the riding environment by comparing the information on the pedaling ability of the rider, the weight of the rider, the sex, and the information on the pedaling ability of the user, the weight of the user, and the gender of the user.

Specifically, the default riding environment of the user can be basically set based on the riding part information, and the default riding environment can be adjusted by considering the user's personal information (the user's pedaling ability, the weight of the user, have.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a concrete realistic riding service according to an embodiment of the present invention will be described.

2 is a conceptual diagram illustrating a real-life riding service method according to an embodiment of the present invention.

FIG. 2 shows a method for controlling the driving of an indoor bicycle based on generation of riding-side information and riding-side information.

Referring to FIG. 2, information on the pedaling pressure may be generated as the riding side information 200 by the rider generating the riding motion picture.

Information about the pedaling pressure may be determined based on sensing information sensed by an electromyographic sensor sensing the degree of contraction and relaxation of the muscles installed on the leg muscles of the rider, and heart rate information of the rider. The information about the pedaling pressure can be synchronized with the riding of the course performed by the rider. Specifically, the information on the pedaling pressure may be synchronized with the position information of the riding course, and may further include the position information of the riding course.

The information about the pedaling pressure can be corrected so that the user can be set as the default riding environment when riding the same course based on the indoor bicycle.

The rider who creates the riding video can be a professional rider, so the riding ability can be relatively better than the general user. Therefore, the default pedaling pressure set in the default riding environment can be set to about 60% to 100% of the pedaling pressure measured by the rider. As described above, the user can set the difficulty level, and the higher the difficulty level, the more the user can feel the pedaling pressure equal to or greater than the pedaling pressure measured by the rider. The riding environment additionally set by the user may be expressed in terms of a user-set riding environment.

In this way, the pedal pressure that the rider actually felt while riding the course can be sensed by the user receiving the realistic riding service.

The information about the pedaling pressure synchronized with the riding motion picture can be transmitted to the user by adjusting the pressure of the pedal of the indoor bicycle based on the pedaling pressure set by the user.

The user may adjust the pedaling pressure by directly setting the riding environment, but the pedaling pressure may be adjusted in consideration of the user's personal information. For example, information on the user's existing pedaling capability 220 is collected, and the control unit can set a customized riding environment for the user in consideration of the existing pedaling ability 220 of the collected user. The information on the user's existing pedaling ability 220 can be generated based on the record of the existing user's actual riding service indoor bicycle.

For example, by comparing the information on the pedaling ability 220 of the rider who created the riding motion picture, the information on the rider's weight and sex, and the information on the pedaling ability of the user, the weight of the user and the gender of the user, A reset may be performed.

If the pedal capability of the rider is 100 and the pedaling ability of the collected user is 70, the pressure for pedaling in the default riding environment can be set to 70% of the pedaling pressure of the rider based on the pedaling pressure of the rider. Specifically, the pressure for pedaling can be set in consideration of the user's riding endurance, strength, and the like. For example, adjustments to the specific pedaling pressure may be performed by separately measuring the rider's endurance / riding strength. Riding endurance is a constant pedaling ability, and riding strength can be the strength to withstand high pedal pressure.

Information about the user's riding ability and the riding endurance / riding strength can be collected separately. If the user's riding endurance is 90% of the rider's endurance and the user's riding strength is 60% of the rider's strength, the setting for the riding environment is such that the pedaling pressure in the general flat ground is 90 %, And the pedaling pressure on the uphill is set to 60% based on the pedaling pressure of the rider so that the pressure of the pedal of the real bicycle pedal can be adjusted adaptively to the user's pedaling ability.

Also, the pedaling pressure may be set by comparing the weight of the user with the weight of the rider. If the weight of the rider is 70 kg and the weight of the user is 60 kg, the difference in the pedaling ability due to the weight can be corrected, so that the user can be provided with a more realistic riding environment.

By setting the specific pedaling pressure, the user can perform the pedaling according to his / her physical ability / body condition.

In addition to this, the pedaling pressure may be changed in consideration of the current state of the user.

If the user is exhausted from continuous pedaling, the realistic riding service indoor bicycle may temporarily reduce the pedaling pressure to reduce fatigue caused by the user's pedaling. For example, if the user's pedaling pressure is reduced to less than 60% of the user's normal pedaling pressure and the condition persists for more than a certain threshold time, the user's condition may be determined to be tired. Realistic riding service The indoor bicycle can adaptively change the pedaling pressure to a value lower than the pedaling pressure of the set setting riding environment in consideration of the state of the user.

Pedal Pressure and Impression Riding Services Regarding the gear conversion of indoor bikes, riders can usually have the following riding patterns:

In the case of flat ground, increasing the pedal pressure (increasing the number of revolutions) in a constant gear state increases the speed of the bicycle. In this case, the rider can reduce the pressure by shifting the gear to reduce speed and maintain fitness. In the elevated terrain, the pressure of the pedal increases sharply in the same gear when changing from a flat to a rising terrain. However, it is difficult to say that the pressure increase increases the speed as in the flat area. There is a high possibility of shifting gears to maintain muscle strength. In descending terrain, when the bike starts to descend, the bike will descend by gravity even if the rider does not step on the pedal, and the pedal pressure can be zero as long as the pedal pressure is maintained. Indoor bikes do not have to turn pedals.

Therefore, at the time of shooting a moving image, the rider can perform the riding by selecting the optimal riding condition that is less likely to consume the physical strength and as much as possible to the strength. For example, a rider may have a riding pattern that shifts gears when the pedal pressure is increased to reduce pressure and rides on the same gear in the flat.

Information on the actual riding pattern of the rider (pedal pressure change information, gear change information) is collected in synchronization with the riding section, and when the rider of the room rides, the pedal pressure change (for example, gear change) Can be performed. Such a pressure change may require correction of the difference in ability between the rider and the user at the time of shooting to maximize the sense of presence. The pedal pressure and gear amount should be collected at the time of video recording by Ride, and after synchronizing, it may appear only to pedestal pressure change (gear shift) to the indoor user. However, the indication of pedal pressure and number of gears on the display may be possible.

3 is a conceptual diagram illustrating a method of providing a moving image according to an embodiment of the present invention.

3, a method of providing a riding motion picture according to a user's pedaling speed is disclosed.

If the user performs relatively fast pedaling, the riding video changes relatively quickly, and if the user performs relatively slow pedaling, the riding video must change relatively slowly. It can have a feeling similar to riding.

Therefore, the control unit of the realistic riding service indoor bicycle can adjust the reproduction speed and the reproduction method of the riding motion picture provided through the display, so that the user can receive realistic riding service more realistically.

The playback speed of the basic riding video may be the same as the speed of the rider that generated the riding video. The playback speed of a basic riding video can be expressed in terms of a default playback speed.

Realistic riding service Indoor bikes can calculate the difference between the current user's speed and the rider's speed. The speed of the rider depending on the position of the rider on the course in the riding video may exist as the riding part information, and the speed of the user may be determined based on the speed of the user's pedaling.

If the user's speed is relatively faster than the speed of the rider, the riding video can play the riding video at a faster playback speed than the default speed, and conversely, if the user's speed is relatively slower than the rider's speed, Can play back the riding motion picture at a slower playback speed than the default playback speed.

In addition to this, correction for the image can be performed for reproduction of a natural image.

For example, if a playback speed that is slower than the default playback speed is required, additional generation of the frame may be performed to provide the user with a non-uniform image. For example, if 60 frames are reproduced at 1 second at the default playback speed, if frames are played back slower than the default playback speed, frames may be additionally generated at that rate. For example, in the case of 1/2 of the default playback speed, frames corresponding to 120 frames corresponding to 60 frames per second can be increased.

At this time, 120 frames can be predicted based on 60 frames. If 60 frames are indicated as frame 1 to frame 60, 60 frames that are additionally generated for 120 frames can be predicted and generated between frames 1 to 60. [ For example, frame 1-1 may be generated through inter-picture prediction between frame 1 and frame 2, and frame 2-1 may be generated by inter-picture prediction between frame 2 and frame 3. [ A frame generated through inter-view prediction may be generated based on a motion vector of an intermediate value considering a motion vector of a previous frame temporally and temporally later. In this way, additional frames 1-1 to 60-1 can be additionally generated.

In addition, the number of frames to be generated may vary depending on the required playback speed. In the example described above, 60 additional generated frames are illustratively disclosed, but 30 additional generated frames may be required depending on the required playback speed. The additional generated frame can be inserted proportionally between the frames 1 to 60.

Conversely, when a playback speed faster than the default playback speed is required, erasure of a frame may be performed to provide a user with a non-uniform image. For example, if 60 frames are reproduced at 1 second at the default reproduction speed, if the reproduction speed is faster than the default reproduction speed, the frame can be deleted and reproduced by the ratio. For example, in the case of twice the default playback speed, 30 frames out of 60 frames per second can be proportionally deleted. For example, even-indexed frames (frame 2, frame 4, frame 6, frame 8, etc.) may be deleted and only odd index frames may be provided.

4 is a conceptual diagram illustrating a method in which a plurality of users simultaneously receive real-life riding services according to an embodiment of the present invention.

4, a method for receiving a real-life riding service by a plurality of users at the same time is disclosed.

Referring to FIG. 4, a realistic riding service is provided to enable a plurality of users to receive the same course at the same time and to feel the same riding course by checking the appearance of another user on the display.

First, each of the plurality of users can perform a synchronization request to the realistic riding service server 400. For example, each of a plurality of real-life riding service indoor bicycles of each of a plurality of users may transmit a synchronization request signal to the real-life riding service server, and the synchronization request signal may include identification information of each of the plurality of real- have.

When real-life riding service server 400 receives a plurality of synchronization request signals from each of a plurality of real-life riding service indoor bicycles, real-life riding service server 400 performs synchronization on a plurality of real- The synchronization completion signal may be transmitted to the real-life riding service indoor bicycle.

Thereafter, the real-life riding service server 400 may request the plurality of real-life riding service indoor bicycles to select one real-life riding service indoor bicycle among the plurality of real-life riding service indoor bicycles as the master real-life riding service indoor bicycle.

Master Realistic Riding Service A course is selected by an indoor bike, and a realistic riding service synchronized with a plurality of realistic riding service indoor bicycles according to the course can be provided.

In order to provide realistic riding services synchronized with a plurality of realistic riding service indoor bicycles, the realistic riding service server 400 can receive the respective situations of the plurality of realistic riding service indoor bicycles and transmit them to the respective real bicycle riding service indoor bicycles .

For example, the riding information of the first realistic riding service indoor bicycle 410 may be transmitted to the second realistic riding service indoor bicycle 420, the second realistic riding service indoor bicycle 420 may be transmitted to the first real riding service indoor bicycle 420, The riding condition of the indoor bicycle 410 can be known. Conversely, the riding information of the second sensible riding service indoor bicycle 420 may be transmitted to the first sensible riding service indoor bicycle 410, the first sensible riding service indoor bicycle 410 may be transmitted to the second sensible riding service indoor bicycle 410, The user can know the riding situation of the driver 420.

The sensation riding service server 400 monitors a riding situation between a first user riding the first sensation riding service indoor bicycle 410 and a second user riding the second sensation riding service indoor low vehicle 420, Can be displayed on the screen.

If the real life riding service indoor bicycle lags behind the actual real life riding service indoor bicycle, the real life riding service server 400 may propose a pedaling speed / gear stage to catch up with the actual real life riding service indoor bicycle . The user of the indoor bicycle lagging behind the specific realistic riding service can perform the riding according to the proposed pedaling speed and the number of gears.

In addition, the sensation riding service server 400 may provide a separate item to the riding course for competition between the plurality of sensation riding service indoor bicycles. When the item is acquired, a plurality of real-life riding service indoor bicycles can receive the riding service based on various items such as a speed twice as fast as the user's pedaling or a separate shortcut route is provided.

Realistic riding service methods can be implemented in an application or implemented in the form of program instructions that can be executed through various computer components and recorded on a computer readable recording medium. The computer-readable recording medium may include program commands, data files, data structures, and the like, alone or in combination.

The program instructions recorded on the computer-readable recording medium may be those specially designed and configured for the present invention and may be those known and used by those skilled in the computer software arts.

Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape, optical recording media such as CD-ROMs and DVDs, magneto-optical media such as floptical disks, media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like.

Examples of program instructions include machine language code such as those generated by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware device may be configured to operate as one or more software modules for performing the processing according to the present invention, and vice versa.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined in the appended claims. It will be possible.

Claims (2)

A method for providing realistic riding service,
The real life riding service server receiving riding information including riding moving picture information and riding part information photographed while riding on an actual riding course provided by the rider device; And
Wherein the actual riding service server provides the riding information to a real bicycle riding service indoor bicycle,
The realistic riding service indoor bicycle
Displaying the riding motion picture information and the riding motion information on a display in synchronization with each other,
The riding position information, and the gear ratio in accordance with the riding-side information synchronized with the riding motion picture information, and varies the speed, time, distance, centrifugal force and inertia information of the riding-side information according to the pedal pressure of the user, And controlling the riding image displayed on the display unit. A realistic riding service server for providing realistic riding service,
Wherein the realistic riding service server comprises a processor,
The processor receives riding information from the rider device,
The realistic riding service is implemented to provide the riding information to the indoor bicycle,
Wherein the riding information includes riding motion picture information captured on an actual riding course and riding side information collected on the actual riding course,
The realistic riding service indoor bicycle
Displaying the riding motion picture information and the riding motion information on a display in synchronization with each other,
The riding position information, and the gear ratio in accordance with the riding-side information synchronized with the riding motion picture information, and varies the speed, time, distance, centrifugal force and inertia information of the riding-side information according to the pedal pressure of the user, And controlling the riding image displayed on the realistic riding service server.

Images