JP6691434B2 - Content presentation device - Google Patents

Description

  The present invention relates to a content presentation device.

  Various proposals have been made to improve the sense of presence when presenting a content such as a moving image to a user (for example, Patent Document 1).

JP, 2013-174642, A

  In recent years, as virtual reality technology has attracted attention, a higher sense of realism may be required when presenting content to a user.

  The present invention has been made in view of the above, and an object thereof is to provide a content presentation device capable of presenting content with a more realistic sensation to the user.

  In order to achieve the above object, a content presentation device according to an aspect of the present invention includes a video presentation unit that presents video information indicating that the user moves along a predetermined course, and a pseudo traction force. And a presentation of the video information by the video presentation unit, and a presentation of the pseudo traction force by the pseudo traction presentation unit corresponding to the video information presented to the user. , And a system control unit for controlling.

  According to the above-mentioned content presentation device, while presenting the video information in which the user moves along the predetermined course to the user, by presenting the pseudo traction force corresponding to the video information, the presence is enhanced. Content can be presented to the user.

  Here, the system control unit causes the image presenting unit to provide the user with image information in which the user moves in a variation section included in the predetermined course included in the image information and in which a change occurs in the course. While presenting, the pseudo traction force presentation unit may control the image presentation unit and the pseudo traction force presentation unit so that the pseudo traction force presentation unit presents the pseudo traction force corresponding to the fluctuation section to the user.

  As described above, the pseudo traction force is presented to the user in association with the variable section included in the predetermined course, so that the user can have a realistic feeling in moving the variable section in the video information. To be enhanced.

  Further, the pseudo tractive force presenting section may present a mode in which the pseudo tractive force in the center direction of the curve is presented to the user corresponding to the curve section when the fluctuation section is a curve section. it can.

  As described above, when the variable section is a curve section, by providing the user with a pseudo traction force toward the center of the curve, it is possible to feel as if the user is actually moving in the curve section. Therefore, it is possible to enhance the sense of presence when the user presents the video information in the state of moving in the curved section to the user.

  In addition, the system control unit, based on a difference time from the presentation of the pseudo traction force by the pseudo traction force presenting unit until the user recognizes the pseudo traction force, the video information of the user moving in the fluctuation section based on the video information. The video presentation unit and the pseudo traction force are provided such that the pseudo traction force presentation unit presents the pseudo traction force corresponding to the fluctuation section to the user before the timing at which the presentation unit starts presenting to the user. The presenting unit may be controlled.

  As described above, in consideration of the difference time from the presentation of the pseudo traction force by the pseudo traction force presenting unit until the user recognizes the pseudo traction force, the pseudo traction force presenting unit is provided before the video information in which the user moves in the variable section is presented. By presenting the pseudo traction force, it is possible to more realistically reproduce the sensation experienced by the user when entering the fluctuation section, and further enhance the sense of presence.

  In addition, the system includes a user exercise unit in which the user can exercise, and a motion detection unit that detects the user's exercise in the user exercise unit, and the system control unit includes the user detection unit detected by the exercise detection unit. The video information presented to the user by the video presentation unit may be controlled in association with the exercise.

  As described above, the motion detection unit detects the user's motion, and in conjunction with the detected user's motion, the video information presented by the video presentation unit is configured to control the actual motion of the user, Since it is possible to present the content in a state of being associated with the movement of the user in the video information, it is possible to present the content that can enhance the realism of the user.

  Further, a user exercise unit in which the user can exercise, an exercise load presenting unit that presents an exercise load in the user exercise unit to the user, the system control unit, the system control unit, the predetermined course. While the video presenting unit presents the video information in which the user moves in the inclined section included in, the exercise load presenting section presents the exercise load corresponding to the inclined section to the user. As described above, the image presentation unit and the exercise load presentation unit can be controlled.

  As described above, with the configuration in which the exercise load is presented to the user in association with the inclined section included in the predetermined course, the sense of presence when the user moves in the inclined section in the video information is provided. To be enhanced.

  In addition, the system control unit, based on a difference time from the presentation of the exercise load by the exercise load presenting unit until the user recognizes the exercise load, the image information of the user moving the inclined section by the image. The image presentation unit and the exercise load are provided such that the exercise load presentation unit presents the exercise load corresponding to the inclined section to the user before the timing at which the presentation unit starts presenting to the user. The presenting unit may be controlled.

  As described above, in consideration of the differential time from the presentation of the exercise load by the exercise load presenting unit until the user recognizes the exercise load, the exercise load presenting unit is provided before the image information in which the user moves in the inclined section is presented. By presenting the exercise load, it is possible to more realistically reproduce the sensation experienced by the user when entering the inclined section, and the sense of presence is further enhanced.

  ADVANTAGE OF THE INVENTION According to this invention, the content presentation apparatus which can present the content with which the user's presence was heightened is provided.

It is a functional block diagram of the content presentation device concerning one form of the present invention. It is a figure which shows the specific example of a content presentation apparatus. It is a figure explaining the hardware constitutions of a content presentation device. It is a flowchart explaining the content presentation method in a content presentation apparatus. It is a flow figure explaining correspondence of image information, pseudo tractive force, and exercise load in a contents presentation device.

  Hereinafter, a mode for carrying out the present invention will be described in detail with reference to the accompanying drawings. In the description of the drawings, the same elements will be denoted by the same reference symbols, without redundant description.

  FIG. 1 is a functional block diagram illustrating functions of the content presentation device according to an aspect of the present invention. Further, FIG. 2 is a diagram schematically showing a usage state of the content presentation device.

  The content presentation device 1 according to the present embodiment is a device that presents a pseudo haptic sensation and an exercise load together with video information as content to a user. That is, the “content” presented to the user in the present embodiment is a combination of video information, pseudo force sense, and exercise load. In the present embodiment, the content of the content provided to the user indicates a situation in which the user rides on a vehicle or the like and moves on a predetermined course. The content presentation apparatus 1 presents audiovisual information related to content by presenting video information to the user. In addition, the content presentation device 1 is characterized in that the user is provided with a pseudo force sensation corresponding to the video information to enhance the user's sense of presence in the situation presented by the video information.

  As shown in FIG. 2, in the content presentation device 1 according to the present embodiment, when the user P rides on a bicycle-like device (fitness bike) and pedals, the user virtually moves within the course included in the content. It is a device that imitates doing. That is, the content presentation device 1 detects the motion of the user P by the rotation of the pedal, and presents the video information linked to the motion of the user P to the user P. Then, the content presentation device 1 presents a pseudo force sense that a pulling force is applied to the user P when the image information is presented, that is, a pseudo pulling force. As a result, the user P can experience the movement along the course while the sense of realism is enhanced.

  Therefore, as shown in FIGS. 1 and 2, the content presentation device 1 includes a system control unit 11, a video presentation unit 12, a pseudo traction force presentation unit 13, and an exercise control unit 14 (exercise detection unit, exercise load presentation unit). ), And have.

  Physically, the content presentation device 1 is, as shown in FIG. 3, an auxiliary device exemplified by a CPU 101, a RAM 102 and a ROM 103 that are main storage devices, a communication module 104 that is a data transmission / reception device, a hard disk, a flash memory, and the like. It is configured as a computer system including a storage device 105, an input device 106 exemplified by a touch panel and a keyboard that are input devices, an output device 107 such as a display, and the like. In the content presentation device 1, the communication module 104, the input device 106, and the output device 107 are operated under the control of the CPU 101 by loading predetermined computer software on the hardware such as the CPU 101 and the RAM 102 shown in FIG. At the same time, by reading and writing data in the RAM 102 and the auxiliary storage device 105, a series of functions in each device is realized.

  Returning to FIG. 1, the function of each unit will be described. The system control unit 11 of the content presentation device 1 has a function of controlling a series of processes related to presentation of content to the user. Specifically, the system control unit 11 transmits a signal related to video information presented to the user to the video presentation unit 12 described below. The system control unit 11 also transmits to the pseudo-traction force presenting unit 13 a pseudo-force control signal relating to the presentation of the pseudo-traction force corresponding to the video information. Furthermore, the system control unit 11 has a function of receiving a signal relating to the user's exercise from the exercise control unit 14 and transmitting an exercise load control signal for applying a load to the user's exercise in accordance with the image information. The details of a series of processes related to content presentation by the system control unit 11 will be described later. As shown in FIG. 2, the system control unit 11 may be integrated with a video presenting unit 12 that presents a video to the user P. Further, it may be provided as a control device at a position different from that of other functional units. The system control unit 11 transmits / receives information to / from the video presentation unit 12, the pseudo-traction force presentation unit 13, and the exercise control unit 14 (user exercise unit, exercise detection unit, exercise load presentation unit) by wired or wireless communication. To do.

  The video presentation unit 12 of the content presentation device 1 has a function of presenting video information related to the content to the user based on an instruction from the system control unit 11. FIG. 2 shows an example in which the image presentation unit 12 is realized as a so-called head mounted display (HMD). In the example illustrated in FIG. 2, the video presenting unit 12 has a display that displays an image at a position corresponding to the eyes of the user and a speaker at a position corresponding to the ears of the user. This provides the user with video information and audio information related to the content. The image presentation unit 12 is not limited to the head mounted display type described above, and may be, for example, a CAVE type display having a plurality of surfaces, or a liquid crystal display applied to a television, a tablet terminal or the like. . Further, as in the case of a head-mounted display type, by presenting the audio information in combination with the video information, it is possible to enhance the sense of presence, but the audio information may not be presented.

  The pseudo traction force presentation unit 13 has a function of presenting the pseudo traction force in a predetermined direction as a pseudo force sensation to the user based on an instruction from the system control unit 11 in association with the image information. When the pseudo traction force is presented, the user can feel that the user is given a feeling of being pulled in a predetermined direction. FIG. 2 shows an example in which the pseudo traction force presentation unit 13 is held by the user's hand. In the example illustrated in FIG. 2, the operation of the pseudo traction force presenting unit 13 presents the user with a sensation that the pseudo traction force is applied to the hand of the user holding the pseudo traction force presenting unit 13, and the user has a predetermined feeling. Feels to be pulled with a certain amount of force in the direction of. The method by which the pseudo traction force presenting unit 13 generates traction force for the user is not particularly limited. It is known that when a positive or negative asymmetrical motion is presented to the user, the user has an illusion that the user is being towed, and a device that presents a pseudo-traction force has a mechanism for generating such an asymmetrical motion. I often do The pseudo tractive force presenting unit 13 according to the present embodiment can also be realized by a device having a configuration for presenting the above-described asymmetric motion to the user.

  If the pseudo-traction force presenting unit 13 is configured to be able to change the magnitude of the pseudo-traction force to be given to the user, finer control of the pseudo-traction force to be presented to the user can be performed, which further enhances the sense of presence for the user. Can be increased. However, even if the magnitude of the pseudo traction force presented to the user is constant, it is possible to enhance the user's sense of presence by adjusting the timing or the like at which the pseudo traction force is generated. Further, if the pseudo traction force presenting unit 13 is configured to be able to change the direction of the pseudo traction force presented to the user, finer control of the pseudo traction force presented to the user is possible, further enhancing the sense of presence for the user. be able to. However, even when the direction of the pseudo traction force given to the user is previously determined to be a predetermined direction, the timing of generating the pseudo traction force is adjusted and the way the user holds the pseudo traction force presenting unit 13 is adjusted. Thus, by adjusting the presentation direction of the pseudo traction force presentation unit 13 presented to the user, it is possible to enhance the user's sense of presence.

  The exercise control unit 14 has a function as a user exercise unit in which the user can exercise in response to the movement of the user in the video information presented by the video presentation unit 12. The exercise control unit 14 also has a function as an exercise detection unit that detects the user's exercise and notifies the system control unit 11 of the notification. Further, the exercise control unit 14 has a function as an exercise load presenting unit having a function of presenting an exercise load to the user based on an instruction from the system control unit 11. The exercise control unit 14 preferably has a function capable of performing exercise corresponding to the movement of the user in the content. FIG. 2 shows an example in which the exercise control unit 14 is a device having a pedal that the user can row, which corresponds to content that is supposed to be moved by the user riding a bicycle. That is, the user exercise unit corresponds to a bicycle-like device. Further, in the example shown in FIG. 2, the user detects the number of pedals (not shown), the speed, etc., as information related to the user's exercise, and notifies the system control unit 11 of the information. Further, the exercise control unit 14 presents the exercise load to the user by giving the user a load related to the rotation of the pedal as the exercise load linked with the image information, based on the instruction from the system control unit 11. Have. The exercise control unit 14 is not limited to a bicycle-like device, and may be realized by, for example, a motorcycle-like device, an automobile-like device, or the like. That is, the configuration is not particularly limited as long as it is a device that corresponds to the moving means used when the user moves a predetermined course in the content. As described above, by providing the movement control unit 14 with a device corresponding to the moving means assumed in the content, the user's sense of presence can be enhanced. Further, since the content of the exercise of the user is changed according to the device configuration of the exercise control unit 14, the method of detecting the amount of exercise of the user and the way of giving the exercise load to the user are also changed according to the content of the exercise. It

  In the content presentation device 1 described above, the content is presented to the user under the control of the system control unit 11 based on the user's exercise detected by the exercise control unit 14. Specifically, under the control of the system control unit 11, the video presentation unit 12 presents the video information corresponding to the user's exercise, and the pseudo tractive force presentation unit 13 simulates the user in association with the video information. The traction force is presented, and the exercise control unit 14 presents the exercise load to the user. As a result, the user can enjoy the content while receiving the pseudo traction force and the exercise load corresponding to the video information.

  Next, a content presentation method by the content presentation device 1 will be described. In the content presentation device 1, when the video information related to the content on the assumption that the user travels the predetermined course is acquired from the external device or the like, the information related to the pseudo traction force and the information related to the exercise load to be presented together with the video information are displayed. Corresponds to video information. After that, a set of video information, pseudo traction force and exercise load is presented to the user as contents. Here, the series of processes described above will be described with reference to FIG. As described above, the content presented by the content presentation device 1 of the present embodiment indicates a situation in which the user moves on a predetermined course by using a moving means such as a bicycle. Then, in the content presentation device 1, when the user approaches a variable section included in a predetermined course, the content presenting apparatus 1 presents the pseudo traction force to the user according to the status of the variable section and the moving status of the user.

  In the present embodiment, the “variable section” refers to a section in which the course changes. For example, when the predetermined course is a course assuming a straight and horizontal course, the variable section is a section where a change occurs from a straight and horizontal situation, that is, a section where a curve or a slope occurs. Etc. Further, in the case of a course such as a slide on which descending at a straight line and at a predetermined inclination is premised, a section in which the angle of inclination changes can be treated as a variable section. As described above, the variable section refers to a section in which the course shape that is assumed changes. Depending on how the presumed course shape is set, the variable section also changes. In the content presentation method by the content presentation device 1 of the present embodiment described below, a curve section in a course is set as a change section, and when the user approaches a curve section included in a predetermined course, the situation of the curve and the user's A case will be described in which the pseudo traction force according to the moving situation is presented to the user.

  Further, in the content presentation device 1, when the user approaches an inclined section such as an uphill or a downhill of the course, the user is presented with an exercise load according to the shape of the inclination and the like. As described above, the content presentation device 1 creates a state in which the user feels the course presented by the image information more realistically by using the pseudo traction force and the exercise load.

  First, the content presentation device 1 acquires video information related to content to be presented to the user from an external device or the like. The image information acquired by the content presentation device 1 defines the course shape (curve and slope). However, the video information does not stipulate information such as pseudo traction force presented by the content presentation device 1. It should be noted that the fact that the video information includes information related to the shape of the course means that, for a curve section on the course, the video information includes information about the radius of curvature, the direction, and the start and end points of the curve. That is. The information that specifies these curves is information related to the presentation of the pseudo traction force, and is therefore referred to as traction force meta information in the present embodiment. Similarly, with respect to the slope section on the course, the video information includes information specifying the up / down slope, the slope angle, and the start and end points of the slope. The information that specifies these inclinations is information related to the presentation of the exercise load, and is referred to as exercise load meta information in this embodiment.

  When the content presentation device 1 acquires the video information, it associates the traction force control signal with the traction force control signal based on the traction force meta information such as the shape of the course included in the video information (S01). That is, the section in which the pseudo traction force is generated is specified and the control signal is associated. Further, since the traction force control signal needs to include the direction and magnitude of generating the pseudo traction force, these are also set based on the traction force meta information (S02). Further, based on the exercise load meta-information corresponding to the inclination of the course included in the image information, the same processing relating to the association of the exercise load control vibration is performed (S03). The addition of the traction force control signal and the exercise load control signal (S01 to S03) may be performed after the video information is acquired and before the content is presented to the user. Therefore, the above processing (S01 to S03) may be performed at least once for one video information, but the processing may be performed every time the content is presented to the user. Further, since the application of the traction force control signal (S01, S02) and the application of the exercise load control signal (S03) can be performed independently, they need not be performed in the order shown in FIG. 4 and can be performed simultaneously.

  The process of applying the traction force control signal and the exercise load control vibration to the image information can be manually performed by the user of the content presentation device 1 or the like, but can also be automatically performed by the content presentation device 1. it can. When processing is performed by the content presenting apparatus 1, the content presenting apparatus 1 performs the processing in the order shown in FIG.

  Since the traction force control signal and the exercise load control vibration can be individually applied, they will be individually described with reference to FIG. First, the application of the traction force control signal associated with the video information will be described. The system control unit 11 acquires tractive force meta information from the video information (S11). As described above, if the traction force meta information is associated in advance with each curve of a predetermined course included in the video information, this traction force meta information can be used. However, when the tractive force meta information is not associated with the video information, it is necessary to generate the tractive force meta information about the curve from the information included in the video information for identifying a predetermined course.

  Specifically, first, a section corresponding to a curve is extracted from a predetermined course included in the video information. Specifically, when the course on which the user moves is straight, the section is excluded because it is not included in the curve section. Then, when the course bends in either direction, the direction of the tangent line of the line at the end of the course on the inner side of the course (or the right side if curved to the right) is the traveling direction of the user. At this time, when the change (difference) in the inclination in the traveling direction for each unit distance is equal to or larger than a predetermined threshold value, the section is set as a curve section, and the curve start point and the curve end point are specified. The curve start point and curve end point are calculated based on the distance from the course start point. By specifying the curve start point and the curve end point, the information included in the pulling force meta information such as the radius of curvature and the direction can be obtained from the information about the course of the section.

  Next, the setting for applying the pseudo traction force is determined for each curve included in the course in the video information. First, the traction force meta information of a specific curve is referred to, and the direction of the pseudo traction force is determined based on the information that specifies the direction of the curve (S12). For example, in a curve that bends to the right, a right-sided pseudo traction force (a traction force that pulls to the right) is generated. In this way, the direction of the pseudo traction force is determined according to the direction of the curve. If the direction in which the pseudo traction force is generated is set to be the center direction of the curve as described above, a force that is more similar to the force applied to the user when actually moving in the curve section is set by the pseudo traction force by the user. Can be presented to.

  Next, a section in which the pseudo traction force is generated (presented to the user) is determined (S13). The section in which the pseudo traction force is generated may simply be a curved section on the course. However, it is assumed that the timing at which the user recognizes the pseudo traction force is slightly delayed with respect to the timing at which the pseudo traction force is presented to the user. Therefore, the difference time of this timing (delay time until the user recognizes the pseudo traction force) is set to t (seconds), and the timing of presenting the pseudo traction force in consideration of the difference time t (especially the timing of starting the presentation of the pseudo traction force) ) Is preferably determined. Specifically, assuming that the position of the start point of the curve (distance from the start point) is x1, the traction force presentation start point x10 is calculated using the mathematical expression x10 = x11-vt (v: moving speed of the user). Preferably. A mode is conceivable in which the pseudo traction force is presented to the user when the user moves in the section from the traction force presentation start point x10 to the curve end point.

  The difference time until the user recognizes the pseudo traction force may vary depending on the user. Therefore, instead of presetting the difference time t as a constant, the difference time t may be measured in advance for each user every time the content is presented to the user. For example, before starting the presentation of the content, as a preliminary measurement, the pseudo-traction force presenting unit 13 presents the pseudo-traction force to the user, and then recognizes the user and makes some response (pushing of a button, utterance, etc.). The difference time t for each user can be measured in advance by measuring the time up to and calculating the average value as necessary. With such a configuration, it is possible to set the presentation timing of the pseudo traction force to the user more finely and accurately.

  Next, the magnitude of the pseudo traction force presented to the user in the section in which the pseudo traction force determined above is generated is determined (S14). The magnitude of the pseudo traction force can be determined by using the traction force meta information of the course if the magnitude of the pseudo traction force presented by the pseudo traction force presenting unit 13 can be changed. When the magnitude of the pseudo traction force presented by the pseudo traction force presentation unit 13 is constant (cannot be changed), the process relating to the determination of the magnitude is omitted.

Although various methods of setting the magnitude of the pseudo traction force presented by the pseudo traction force presenting unit 13 are possible, for example, it can be set based on the moving speed of the user on the course and the radius of curvature of the curve. The maximum value of the centrifugal force F that the user receives when moving the curve is described as F = mv ² / r where v is the moving speed of the user, r is the radius of curvature, and m is the weight of the user. be able to. Therefore, by presenting the pseudo traction force corresponding to the centrifugal force F to the user, it is possible to illusion that the user has received the force corresponding to the centrifugal force. Ideally, the timing of calculating the maximum value of the centrifugal force F is preferably calculated based on the moving speed of the user at the traction force presentation start point x10. However, the time to acquire the information on the moving speed of the user, the time to calculate the maximum traction force, and the traction force control from the detection of the moving speed of the user in the content presentation device 1 to the presentation of the pseudo traction force. It is considered that the processing is delayed by the total time for transmitting the signal. Therefore, when the above-mentioned delay time is Δt, the pseudo tractive force of the user is calculated based on the information from the motion control unit 14 at the point where the current position x of the user is x = x10−v · Δt (moving speed of the user). It is conceivable that the configuration is such that the calculation of the maximum value is started.

  The magnitude of the pseudo traction force presented to the user by the pseudo traction force presenting unit 13 is the largest from the start of the presentation of the pseudo traction force to the curve start point, and then the traction force is linearly reduced with respect to the distance traveled by the user. Then, a method of setting it so that it becomes 0 at the end point of the curve can be considered. However, the method of changing the pseudo traction force is not limited to the above, and can be appropriately set according to the shape of the curve and the like.

  As described above, the presentation timing and the magnitude of the pseudo traction force presented by the pseudo traction force presentation unit 13 use not only the information included in the video information but also the real-time information related to the user's exercise provided by the exercise control unit 14. Is set. Therefore, in the system control unit 11, how to associate the information obtained from the information relating to the user's exercise acquired in real time from the exercise control unit 14 with the information of the course included in the video information in the pre-processing. , Is determined and held in association with the video information.

  The determination of the direction of the pseudo traction force (S12), the determination of the section for presenting the pseudo traction force (S13), and the determination of the magnitude of the pseudo traction force (S14) are performed for each curve provided on the course. Be seen. Therefore, if there is traction force meta information related to the next curve, that is, if it is not the end of the meta information (S20-NO), the above series of processes (S12 to S14) is repeated for the next curve. . Further, when there is no traction force meta information related to the next curve, that is, when it is the end of the meta information (S20-YES), the process ends.

  Next, the application of the exercise load control signal will be described. The application of the exercise load control signal can be processed in the same way as the application of the traction force control signal. First, the system control unit 11 acquires the exercise load meta information from the video information (S21). As described above, similar to the traction force meta information, if the exercise load meta information generated for each inclination (hill) of the course is associated with the video information in advance, this exercise load meta information is used. If the exercise load meta information is not created in advance, it is necessary to specify the section having the inclination from the information for specifying the course included in the video information to generate the exercise load meta information.

  Specifically, when the change (difference) in inclination for each unit distance on the course is equal to or larger than a predetermined threshold value, the section is set as a slope section, and the inclination start point and the inclination end point are specified. The slope start point and slope end point are calculated based on the distance from the start point of the course. By specifying the slope start point and the slope end point, the information included in the exercise load meta information such as the slope direction (uphill, downhill) and the degree of substantial slope can be calculated from the information of the course of the section. You can ask.

  Next, the plus or minus of the exercise load is determined based on the information identifying the direction of the inclination by referring to the exercise load meta information of the specific inclination included in the video information (S22). If the slope is uphill, increase the load (plus). On the other hand, the load is reduced (minus) on the downhill. In this way, the plus or minus of the exercise load is determined according to the direction of inclination.

  Next, the section in which the exercise load is presented to the user is determined (S23). It is conceivable that the section presenting the exercise load is simply the inclined section specified in the previous stage. However, like the pseudo traction force, it is assumed that the timing at which the user recognizes the change in the exercise load is slightly delayed with respect to the timing at which the exercise load is presented to the user. Therefore, it is preferable that the difference time of this timing (delay time until the user recognizes the exercise load) is t (seconds), and the time for presenting the exercise load is determined in consideration of the difference time t. Specifically, assuming that the position of the start point of the inclination is x11, it is preferable that the exercise load presentation start point x20 be calculated using the mathematical expression x20 = x21-vt (v: moving speed of the user). A mode is conceivable in which, when the user moves in the section from the exercise load presentation start point x20 to the slope end point, the exercise load is presented to the user.

  Next, the magnitude of the exercise load presented to the user in the section in which the exercise load determined above is generated is determined (S24). The magnitude of the exercise load presented to the user can be determined by using the exercise load meta information of the course as long as the magnitude of the exercise load presented by the exercise control unit 14 can be changed. If the magnitude of the exercise load presented by the exercise control unit 14 is constant (cannot be changed), the process for determining the magnitude is omitted. Although various methods of setting the magnitude of the exercise load presented by the exercise control unit 14 can be considered, they can be set based on the magnitude of the inclination, for example. Note that, similarly to the pseudo traction force, it may be set in consideration of the moving speed of the user.

  As described above, the presentation timing and the magnitude of the exercise load presented by the exercise control unit 14 use not only the information included in the image information but also the real-time information regarding the exercise of the user provided from the exercise control unit 14. Is set. Therefore, in the system control unit 11, how to associate the information obtained from the information relating to the user's exercise acquired in real time from the exercise control unit 14 with the information of the course included in the video information in the pre-processing. , Is determined and held in association with the video information.

  It should be noted that the above-mentioned determination of plus or minus of the exercise load (S22), determination of the section presenting the exercise load (S23), and determination of the magnitude of the exercise load (S24) are performed for each slope (slope) on the course. To be done. Therefore, when there is the exercise load meta information related to the next inclination, that is, when it is not the end of the meta information (S20-NO), the above series of processing (S22 to S24) is repeated for the next inclination. Be done. Further, when there is no exercise load meta information related to the next inclination, that is, when it is the end of the meta information (S20-YES), the process ends.

  Returning to FIG. 4, the traction force control signal and the exercise load control signal are given (S01 to S03) in advance by the procedure as described above. After that, when the content is actually presented to the user, the procedure is as follows.

  First, information related to the user's exercise is sent from the exercise controller 14 to the system controller 11 according to the user's exercise (pedaling in the present embodiment). Based on the information from the motion control unit 14, the system control unit 11 determines the moving speed and the moving amount (distance) of the user on the course included in the video information. Then, a signal related to the video information according to the movement of the user is sent from the system control unit 11 to the video presentation unit 12. Based on this, the video presentation unit 12 displays the video, and the video information is presented to the user (S04).

  Here, when the user reaches a state where the traction force presentation start point x10 set in advance near the curve on the course included in the image information due to the user's exercise, the system control unit 11 causes the pseudo traction force presentation unit 13 to operate. To the traction force control signal. When the user reaches the preset exercise load presentation start point x20 near the inclination on the course, the system control unit 11 transmits an exercise load control signal to the exercise control unit 14 (S05). ). Upon receiving the traction force control signal, the pseudo traction force presenting unit 13 presents the user with the pseudo traction force having a predetermined direction and a predetermined magnitude, in accordance with the instruction included in the signal. Similarly, the exercise control unit 14 that has received the exercise load control signal presents a predetermined exercise load to the user according to the instruction included in the signal (S06). As a result, the user receives the presentation of the pseudo-traction force according to the curve of the course and the exercise load according to the inclination.

  The traction force control signal may be configured to be continuously transmitted from the system control unit 11 to the pseudo traction force presenting unit 13 while the user moves in the section for presenting the pseudo traction force, or in response to a specific curve. When the user reaches the section for presenting the pseudo traction force, a signal summarizing information on the pseudo traction force presented to the user in the curve section may be transmitted to the pseudo traction force presenting unit 13. The system control unit 11 creates a traction force control signal to be transmitted to the pseudo traction force presenting unit 13 by using the information (for example, moving speed) related to the user's exercise transmitted from the exercise control unit 14. When configured, the information related to the exercise of the user transmitted from the exercise control unit 14 is appropriately used to create the information to be transmitted to the pseudo traction force presenting unit 13.

  Similarly, the exercise load control signal may be configured to be continuously transmitted from the system control unit 11 to the exercise control unit 14 while the user moves in the section in which the exercise load is presented, or at a specific inclination. When the user arrives at the section in which the exercise load is correspondingly presented, a signal summarizing the information of the exercise load presented to the user in the section of the inclination may be transmitted to the exercise control unit 14. . The system control unit 11 uses the information (moving speed, etc.) related to the user's exercise transmitted from the exercise control unit 14 to create an exercise load control signal to be transmitted to the exercise control unit 14. If so, the information related to the user's exercise from the exercise control unit 14 is appropriately used to create the information to be transmitted to the exercise control unit 14.

  As described above, according to the content presentation device 1 according to the present embodiment, the video presenting unit 12 presents to the user the video information in which the user moves along a predetermined course, while the pseudo traction force presenting unit 13 is provided. Thus, by presenting the pseudo traction force corresponding to the video information, it is possible to present the content with a higher sense of presence to the user.

  More specifically, the pseudo tractive force presenting unit 13 presents the pseudo tractive force to the user in association with the curve segment included in the predetermined course in the video information, so that the user moves through the curve segment. The sense of presence when presenting the image information of the state to the user is enhanced.

  Further, the content presentation device 1 is configured to present the pseudo traction force toward the center of the curve to the user in the curve section in the video information, so that the user feels that the user is actually moving in the curve section. Therefore, it is possible to enhance the user's sense of presence when presenting the video information moving in the curved section to the user.

  Further, in the content presentation device 1, in consideration of the difference time from the presentation of the pseudo traction force by the pseudo traction force presenting unit 13 to the recognition of the pseudo traction force by the user, before the presentation of the video information in which the user moves in the curve section. By controlling the pseudo traction force presenting unit 13 to present the pseudo traction force, it is possible to more realistically reproduce the sensation experienced by the user when moving in the curve section, particularly when entering the curve section, and the sense of presence is increased. Further enhanced.

  Further, in the content presentation device 1, the exercise control unit 14 as an exercise detection unit detects the exercise of the user, and the video information presented by the video presentation unit 12 is controlled in association with the detected exercise of the user. With such a configuration, it is possible to present the content in a state where the actual exercise of the user and the movement of the user in the video information are associated with each other, so that the content with a high sense of presence for the user can be provided. Can be presented.

  In addition, the exercise control unit 14 as the exercise load presenting unit is configured to present the exercise load to the user in association with the slope section included in the predetermined course included in the image information. In particular, the sense of presence when the user moves in the inclined section is enhanced.

  Further, in consideration of the difference time from the presentation of the exercise load by the exercise control unit 14 as the exercise load presenting unit until the user recognizes the exercise load, before presenting the video information in which the user moves in the inclined section, By presenting the exercise load to the user, it is possible to more realistically reproduce the sensation experienced by the user when entering the inclined section, and to further enhance the sense of presence.

  The present invention has been described in detail above based on the embodiments. However, the present invention is not limited to the above embodiment. The present invention can be modified in various ways as described below without departing from the scope of the invention.

  For example, in the above embodiment, the case where the content presentation device 1 controls the video information presented to the user based on the information related to the user's exercise from the exercise control unit 14 has been described. The configuration may not be interlocked with. That is, the image information may be presented to the user without having a correspondence between the user's exercise and the image information. Even in that case, the provision of the configuration for presenting the pseudo traction force can enhance the user's sense of presence as compared with the case where only the video information is presented as the content. Further, the content presentation device 1 may be configured not to present the exercise load to the user.

  Further, in the above-described embodiment, the content presentation device 1 has described the configuration in which the curve section of the predetermined course in the video information is set as the variable section and the pseudo traction force is presented in the curve section, but it is assumed in the video information. The section in which the pseudo traction force is presented can be changed by the moving means of the user. For example, when presenting to the user video information assuming a situation in which the user moves in a predetermined course while moving in the vertical direction, a section in which the user moves in the vertical direction is set as a variable section, In the section, when the video information is presented to the user, it is possible to sensuously guide the user's vertical movement by presenting the pseudo traction force in the upward or downward direction in combination. In this way, it is possible to appropriately change the fluctuation section according to the moving means and moving direction of the user assumed in the video information. Further, the direction, magnitude, etc. of the pseudo traction force presented to the user in the changing section can be changed as appropriate.

  DESCRIPTION OF SYMBOLS 1 ... Content presentation apparatus, 11 ... System control part, 12 ... Video presentation part, 13 ... Pseudo tractive force presentation part, 14 ... Exercise control part.

Claims (5)

A video presenting unit that presents to the user video information indicating that the user moves along a predetermined course;
A pseudo-traction force presenting unit that presents the pseudo-traction force to the user,
A system control unit that controls the presentation of the video information by the video presentation unit and the presentation of the pseudo traction force by the pseudo traction force presentation unit corresponding to the video information presented to the user;
Have a,
The system control unit,
While the video presentation unit presents to the user the video information in which the user moves a fluctuation section included in the predetermined course included in the video information and in which the course changes, the pseudo-traction force presenting unit Controlling the image presentation unit and the pseudo traction force presentation unit so that the pseudo traction force corresponding to the variation section is presented to the user,
Based on the difference time from the presentation of the pseudo traction force by the pseudo traction force presenting unit until the user recognizes the pseudo traction force, the video presenting unit provides the user with the video information in which the user moves in the fluctuation section. Controlling the video presenting unit and the pseudo traction force presenting unit so that the pseudo traction force presenting unit presents the pseudo traction force corresponding to the variable section to the user before the presentation start timing; ,
A content presentation device for performing . The pseudo traction presentation unit, when the fluctuation period is curve section, in correspondence with the curve section, the content of claim 1 to present a pseudo traction toward the center of the turn to the user Presentation device. A user exercise unit in which the user can exercise,
A motion detection unit that detects the motion of the user in the user motion unit,
The content presentation according to claim 1 or 2 , wherein the system control unit controls the image information presented to the user by the image presentation unit, in association with the user's exercise detected by the exercise detector. apparatus. A user exercise unit in which the user can exercise,
An exercise load presenting unit that presents an exercise load in the user exercise unit to the user,
The system control unit allows the exercise load presenting unit to correspond to the inclined section while the image presenting unit presents image information in which the user moves in an inclined section included in the predetermined course to the user. the exercise stress to present to the user, content presentation device according to any one of claims 1 to 3 for controlling the said video presentation unit the exercise presentation unit. The system control unit, based on the difference time from the presentation of the exercise load by the exercise load presenting unit until the user recognizes the exercise load, the image presenting unit provides the image information in which the user moves in the inclined section. So that the exercise load presenting section presents the exercise load corresponding to the inclined section to the user before the timing at which the exercise starts to be presented to the user. The content presentation device according to claim 4 , which controls

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