JP2011085770A - Bicycle simulation device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bicycle simulation device which displays visual field video and explanatory texts appropriate for the age group and which can target wide range of age groups from children to adults. <P>SOLUTION: The bicycle simulation device 10 includes an input operation section 234, a monitor 200, and a controller 20, and allows a user to have a pseudo experience of running state of a bicycle. The controller 20 includes: an age acquisition section 242 acquiring user's age information based on the operation input concerning age from the input operation section 234; a background image display section 244 displaying background image information 260 in accordance with the age information on the monitor 200; and a guidance image display section 248 which changes, of the images of guidance in accordance with the operation input from the input operation section 234, combination of at least character images representing the meaning of the guidance in accordance with the age information and displays the images on the monitor 200. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a bicycle simulation apparatus that is used for traffic safety education, games, physical fitness training, and the like, and allows a user to experience a bicycle running state in a simulated manner.

  Recently, in order to simulate driving of airplanes, automobiles, motorcycles, bicycles, etc., simulation apparatuses corresponding to each vehicle have been proposed, and some of them have been put into practical use. Among these, a bicycle simulation device has been proposed in which a driver runs a pedal while straddling a saddle of a simulated bicycle and operates a handle to perform simulated driving (see Patent Document 1).

  Recently, there has been proposed a bicycle simulation device that can reproduce the getting-on / off operation, the stepping-on operation at the time of suspension, and the pushing-and-walking operation, and can have almost the same realistic feeling as the actual driving of the bicycle (Patent Literature). 2 and 3).

  Also, in the past, the target pulse value was determined by the exerciser's pulse and the age, sex, etc. of the exerciser, the exerciser's pulse was always detected, and the pulse value during exercise was determined by the age, sex, Power generation brake load means to determine the exercise load so that it becomes the target pulse value determined by, etc., and to feed back the pulse value during exercise so that the exercise load matching the individual physical fitness level of the exerciser can be maintained A step-type training machine that automatically controls the braking force is disclosed (see Patent Document 4).

Registered Utility Model No. 2558981 JP 2005-292172 A JP 2008-242248 A Japanese Patent Publication No.7-110289

  By the way, in the conventional motorcycle simulation apparatus for motorcycles, the age group (age) to be driven is relatively limited to adults. However, the bicycle simulation apparatus for bicycles covers a wide range of ages from infants to adults. . Therefore, it is necessary to display an appropriate running feeling corresponding to the difference in physique, a visual field image, and an explanatory text corresponding to reading comprehension. In addition, since the traffic regulations applied by age groups change, such as sidewalks are permitted in certain age groups, it is possible to perform simulated experiences according to the traffic regulations according to the driver's age group. I need it.

  Since the bicycle simulation apparatuses described in Patent Documents 1 to 4 described above are mainly applied to adults, there are no contrivances such as display of a field-of-view image or explanatory text according to the age group.

  The present invention has been made in consideration of such a problem, and can display a view image and an explanation according to an age group, and can be applied to a wide range of age groups from infants to adults. An object is to provide a bicycle simulation apparatus.

[1] The bicycle simulation apparatus according to claim 1 of the present invention includes a seat (34) where a user is seated, an input operation unit (234) operated by the user, and at least the input operation unit (234). ) And a control unit (20) that controls at least the input operation unit (234) and the display device (200). In the bicycle simulation apparatus that allows a person to experience a running state of a bicycle, the control unit (20) acquires the age information of the user based on an operation input related to age from the input operation unit (234). An age acquisition unit (242) for performing display, a background image display unit (244) for displaying background image information (260) corresponding to the age information on the display device (200), and the input operation. Guidance for displaying on the display device (200) a combination of at least a character image representing the meaning of the guidance among the guidance images corresponding to the operation input from the section (234), depending on the age information. And an image display unit (248). Note that the reference numerals in parentheses are appended to the reference numerals in the accompanying drawings for easy understanding of the present invention, and the present invention is not construed as being limited to the reference numerals. The same applies hereinafter.

[2] The invention according to claim 2 is the bicycle simulation apparatus according to claim 1, wherein the voice output device (236) further outputs the guidance according to the operation input from the input operation unit (234). The control unit (20) changes a combination of words constituting the guidance according to an operation input from the input operation unit (234) according to the age information, and the audio output device ( 236) has a guidance voice output unit (250).

[3] The invention according to claim 3 is the bicycle simulation apparatus according to claim 1, wherein the control unit (20) is operated by the user in response to an operation input from the input operation unit (234). A vehicle speed setting unit (256) for setting the vehicle speed of the bicycle on the background image information (260), and an acceleration setting unit (252) for setting an acceleration that is a basis of the calculation of the vehicle speed according to the age information It is characterized by having.

[4] The invention according to claim 4 is the bicycle simulation apparatus according to claim 3, wherein the bicycle is a simulated vehicle (12) including a pedal (82) operated by the user, and the input operation is performed. The unit (234) includes at least a rotating body (88) that rotates by an operation of the user, and a rotation speed sensor (210) that detects a rotation speed of the rotating body (88), and the acceleration setting section (252) Is the current speed reflecting the age information in the detected value from the rotational speed sensor (210), and the acceleration based on the value obtained by subtracting the previous speed (initial value = 0) from the current speed. The acceleration is sequentially set by repeating the process of setting the value obtained by integrating the acceleration as the previous speed, and the vehicle speed setting unit (256) sets the acceleration to the integrated value. Zui and characterized by calculating the vehicle speed.

[5] The invention according to claim 5 is the bicycle simulation apparatus according to claim 3 or 4, wherein a vehicle speed upper limit value for limiting an upper limit of the vehicle speed set by the vehicle speed setting unit (256) is set as the age information. And a vehicle speed upper limit setting unit (254) for setting a value corresponding to the vehicle speed.

[6] The invention according to claim 6 is the bicycle simulation apparatus according to claim 1, further comprising a memory (258) in which a plurality of preset background image information (260) is stored, and the background image The display unit (244) reads the background image information (260) corresponding to the age information from the plurality of background image information (260) from the memory (258) and displays the background image information (260) on the display device (200). It is characterized by.

[7] The invention according to claim 7 is the bicycle simulation apparatus according to claim 6, wherein the background image display unit (244) uses background image information (260) corresponding to the age information as the age information. Accordingly, the display is performed on the display device (200) based on the camera viewpoint in which the coordinates in the height direction are set.

[8] The invention according to claim 8 is the bicycle simulation apparatus according to claim 7, wherein the background image display unit (244) determines the background image based on virtual three-dimensional coordinates based on at least the camera viewpoint. The display device (200) displays the moving image as a background image of the screen coordinates obtained by the perspective transformation.

[9] The invention according to claim 9 is the information table (262) in which, in the bicycle simulation apparatus according to claim 1, a plurality of pieces of text data representing the meaning of the guidance are registered for one guidance. Has a memory (258) stored corresponding to the number of guidance prepared in advance, and the guidance image display unit (248) provides guidance according to the operation input from the input operation unit (234). Of the plurality of text data registered in the corresponding information table (262), text data corresponding to the age information is read out and displayed on the display device (200).

[10] The invention according to claim 10 is the bicycle simulation apparatus according to claim 2, wherein for one guidance, an information table (262) in which a plurality of text data representing the meaning of the guidance is registered, A memory (258) stored corresponding to the number of guidance prepared in advance is provided, and the guidance voice output unit (250) corresponds to guidance according to an operation input from the input operation unit (234). Of the plurality of text data registered in the information table (262), text data corresponding to the age information is read out and output to the voice output device (236).

[11] The invention according to claim 11 is the bicycle simulation apparatus according to any one of claims 1 to 10, wherein the age information is division information obtained by dividing an assumed longest age into a plurality of age groups. It is characterized by being.

[12] The invention according to claim 12 is the bicycle simulation apparatus according to claim 1, wherein the control unit (20) is further configured to cause at least the user to perform an operation input related to the age. A setting screen display unit (240) for displaying the screen (230) is provided.

[13] The invention according to claim 13 is the bicycle simulation apparatus according to claim 1, wherein the control unit (20) is further configured based on an operation input related to height from the input operation unit (234). It has a camera viewpoint correction part (246) which acquires a user's height information and correct | amends the camera viewpoint set according to the said age information at least according to the said height information.

[14] The invention according to claim 14 is the pedal (82) provided in the simulated bicycle (12), the rotating body (88) rotated by the pedal (82), and the rotation of the rotating body (88). Bicycle comprising a sensor (210) for detecting the number and a control device (20) for controlling the image displayed on the display unit (14) provided in front of the simulated bicycle (12) from the output of the sensor (210) In the simulation apparatus, the input operation unit (234) capable of inputting setting information according to the age of the user and the detected number of rotations of the rotating body (88) are multiplied by a coefficient calculated from the setting information or Vehicle speed calculating means for calculating the vehicle speed of the bicycle by dividing and integrating the value, and the control device (20) displays on the display unit (14) according to the calculated vehicle speed. Displayed image And controlling the.

[15] The invention according to claim 15 is the bicycle simulation apparatus according to claim 14, wherein the coefficient is based on a tire size of the bicycle assumed to be used by the user of the age indicated by the setting information. It is characterized by being set.

[16] The invention according to claim 16 is the bicycle simulation apparatus according to claim 15, wherein the coefficient is reached by an operation on the pedal (82) corresponding to approximately a half rotation of the rotating body (88). The calculated vehicle speed is set so as to substantially match the expected vehicle speed.

  According to the first aspect of the present invention, the background image information corresponding to the age information is displayed, and among the guidance images corresponding to the operation input, a combination of at least a character image representing the meaning of the guidance, Since the display is changed according to the age information, it is possible to display a visual field image and an explanatory text according to the age group, and a wide range of ages from infants to adults can be displayed with one bicycle simulation device. Can be targeted.

  According to the second aspect of the present invention, since the combination of words constituting the guidance according to the operation input is changed according to the age information and is output as a voice, the user can use, for example, an infant or an elementary school lower grade If this is the case, the guidance for the content prompting the stoppage can be output as a sentence that can be understood even by young children and lower grades, and the user's level of understanding can be increased.

  According to the invention described in claim 3, the vehicle speed on the background image information of the bicycle operated by the user is set, and the acceleration that is the basis of the calculation of the vehicle speed is set according to the age information. Therefore, it is possible to make a simulated experience similar to that when the user actually travels a bicycle.

  According to the fourth aspect of the present invention, the detected value from the rotation speed sensor that detects the rotation speed of the rotating body that is rotated by the user's operation reflects the age information as the current speed, and the current speed. Since the acceleration was set based on the value obtained by subtracting the previous speed (initial value = 0) from the previous value, and the value obtained by integrating the acceleration was set to the previous speed, and the acceleration was sequentially set. It is possible to obtain acceleration corresponding to the current vehicle speed, and to experience a simulated driving feeling similar to that when actually riding a bicycle according to the age group.

  According to the invention described in claim 5, when the vehicle speed is set, the upper limit value of the vehicle speed is limited according to the age information, so that it is possible to set the maximum speed performance according to the age. You can have a simulated experience of cycling in a close situation.

  According to the sixth aspect of the present invention, since the background image information corresponding to the age information is read out and displayed from among the plurality of preset background image information, the vehicle can travel depending on the age group according to traffic regulations. When there is a place that cannot be used, it is possible to display background image information limited to places that can be driven according to the age group, and one bicycle simulation device provides traffic safety education to a wide range of age groups be able to.

  According to the seventh aspect of the present invention, the background image information corresponding to the age information is displayed based on the camera viewpoint in which the height direction coordinates are set according to the age information. On the other hand, it is possible to simulate a feeling of running similar to the case where the user actually runs a bicycle.

  According to the invention described in claim 8, background image information based on virtual three-dimensional coordinates is displayed as a background image of a moving image based on screen coordinates obtained by performing perspective transformation based on at least a camera viewpoint. So, a virtual city that imitates a real city, a virtual city where various points that are educational keys such as crossroads (with and without traffic lights), T-shaped roads, sidewalks, etc. are arranged at important points. It is possible to display a moving image as if a user on a bicycle is traveling.

  According to the ninth aspect of the present invention, the sentence data corresponding to the age information is read and displayed among the plurality of sentence data registered in the information table corresponding to the guidance according to the operation input from the input operation unit. So, if the user is, for example, an infant or an elementary school student, guidance (character images) that prompts the user to stop can be displayed in a sentence that can be understood even by an infant or an elementary school student. You can speed up.

  According to the tenth aspect of the present invention, the sentence data corresponding to the age information is read out from the plurality of sentence data registered in the information table corresponding to the guidance corresponding to the operation input from the input operation unit, and the voice is output. For example, if the user is an infant or an elementary school student, the guidance for urging content can be output as a sentence that can be understood even by an infant or elementary school student. You can speed up.

  According to the invention described in claim 11, since the age information is classified information in which the assumed maximum age is divided into a plurality of age groups, the lower age group is subdivided and divided, or the older age group is subdivided. It becomes possible to classify and classify, and it becomes possible to target a wide age group from infants to elderly people.

  According to the twelfth aspect of the present invention, since a setting screen for causing at least the user to input an operation related to age is displayed, the user is prompted to input an operation related to age at the initial setting stage. be able to.

  According to the thirteenth aspect of the present invention, the user's height information is acquired based on the height-related operation input from the input operation unit, and at least the camera viewpoint set according to the age information is determined according to the height information. Even if you are an elementary school student or a tall child, or an adult or a short person, the background image is as close to reality as possible, that is, a background image from a familiar perspective Can be displayed.

  According to the fourteenth aspect of the present invention, the vehicle speed of the bicycle is obtained by multiplying or dividing the rotational speed of the rotating body by a coefficient calculated from setting information corresponding to the age of the user and integrating the value. Since the image of the display unit is controlled according to the calculated vehicle speed, the user is caused to experience a driving feeling similar to that when the user actually runs a bicycle. be able to.

  According to the invention of claim 15, since the coefficient is set based on the tire size of the bicycle that is assumed to be used by the user of the age indicated by the setting information, the viewpoint that is usually familiar to the user is used. The image can be viewed.

  According to a sixteenth aspect of the present invention, the calculated vehicle speed substantially matches the vehicle speed expected to reach the coefficient by an operation on the pedal corresponding to approximately a half rotation of the rotating body. Therefore, it is possible to simulate a feeling of running similar to the case where the user actually runs a bicycle.

It is a perspective view which shows the bicycle simulation apparatus which concerns on this Embodiment. It is a side view which shows the bicycle simulation apparatus which concerns on this Embodiment. It is explanatory drawing which shows an example of the keyboard layout of a controller. It is a functional block diagram which shows the bicycle simulation apparatus which concerns on this Embodiment. It is explanatory drawing which shows an example of the setting screen displayed on a monitor. It is a flowchart which shows the processing operation of the bicycle simulation apparatus which concerns on this Embodiment. It is a flowchart which shows an acceleration setting process. It is a characteristic view which shows the change of the coefficient set according to a speed value. It is explanatory drawing which shows an example of the coefficient set according to the selected age group, the size of a bicycle wheel, and the viewpoint height in a main monitor. FIG. 10A is a characteristic diagram showing a change in deceleration according to the brake stroke amount, and FIG. 10B is a characteristic diagram showing a change in deceleration according to the speed value.

  Hereinafter, an embodiment of a bicycle simulation apparatus according to the present invention will be described with reference to FIGS.

  As shown in FIG. 1, the bicycle simulation apparatus according to the present embodiment gives the driver (occupant) a pseudo-sensation of actually driving a bicycle. It can be used for game machines and training equipment.

  As shown in FIG. 1, a bicycle simulation apparatus 10 is a main monitor that displays a simulated bicycle 12 having a body structure similar to an actual bicycle and a scene (video) ahead of the driver according to the driving of the simulated bicycle 12. (Front display unit) 14, a front stand (stand) 16 that supports the main monitor 14, a rear monitor (rear display unit) 18 that displays a scene behind the driver, and overall control of the bicycle simulation apparatus 10. The control apparatus (control part) 20 to perform is provided.

  The bicycle simulation apparatus 10 has a structure (a four-part structure) in which the simulated bicycle 12, the main monitor 14, the front stand 16, and the rear monitor 18 can be divided. Each element can be easily divided and assembled by bolt fastening or the like. It can be carried out.

  The main monitor 14 is supported by the upper part of the front stand 16 and can be adjusted in the vertical direction (height direction) by the monitor position adjusting mechanism 22. A pair of sub-monitors 24 and 24 are provided on the left and right sides of the main monitor 14 to display the left rear and right rear scenes of the driver driving the simulated bicycle 12, respectively. Therefore, in the following description, when the main monitor 14, the sub monitor 24, and the rear monitor 18 are collectively referred to, they are simply referred to as a monitor 200 (display device: see FIG. 4).

  The front stand 16 includes a pipe-shaped main body frame 17, a leg portion 13 provided at the bottom of the main body frame 17, a wheel 21, and the like, and a fixing portion 19. The front stand 16 is disposed above an upper plate 23 that forms a substantially horizontal plane. The main monitor 14 is attached via the monitor position adjusting mechanism 22.

  The control device 20 is disposed on the under plate 25 of the front stand 16, and the driver's operation information (travel information) is input by sensors attached to each part of the simulated bicycle 12, so that the front stand 16 and the sub monitor 24. Various images corresponding to the situation are displayed on the rear monitor 18.

  The rear monitor 18 is connected to the rear of the simulated bicycle 12 by a pipe-shaped rear stand (rear stand) 30 connected to a main frame 26 connected to the lower portion of the front stand 16 and extending to the lower portion of the simulated bicycle 12 by a connecting portion 28. Provided. As shown in FIG. 2, the rear monitor 18 is installed corresponding to the approximate center position of the adjustment range h <b> 1 of the main monitor 14 by the monitor position adjusting mechanism 22, and one side from the center line in the longitudinal direction of the vehicle body of the simulated bicycle 12. It is installed at a position slightly offset to the side (the right side of the vehicle body in this embodiment).

  As shown in FIG. 1, the simulated bicycle 12 is fixed to the floor and the lower portion of the front stand 16 to constitute a vehicle body of the simulated bicycle 12, and a seat post (saddle side pipe) 32 to the main frame 26. A saddle 34 (seat portion) connected via a head, a handle 40 rotatable about a head pipe 38 fixed to a handle post (handle-side pipe) 36 connected to the main frame 26, and rubber. And a dummy rear wheel 42 fixed on the floor surface by a tire such as a tire, and a drive unit 43 is disposed on the rear side of the vehicle body. The saddle 34 can be adjusted in the vertical direction (height direction) by the saddle position adjusting mechanism 44, and the handle 40 can be adjusted in the vertical direction (height direction) by the handle position adjusting mechanism 46. is there.

  The main frame 26 is connected to the lower part of the front stand 16 by a pair of connecting portions 47, 47 at both ends, and is fixed to the floor. The main frame 26 extends from the center of the support pipe 48 to the rear side of the vehicle body. An underpipe 50 wound around the surface, a handle-side base pipe 52 and a saddle-side base pipe 54 extending upwardly from the underpipe 50 with a forward inclination and a rear inclination, respectively, and between the handle-side base pipe 52 and the saddle-side base pipe 54 And a pair of front forks 58, 58 connecting the handle-side base pipe 52 and the support pipe 48 to constitute a vehicle body of the simulated bicycle 12.

  As shown in FIG. 2, a first control box 60 covered with a case of resin or the like is attached below the head pipe 38. Inside the first control box 60, a handle resistance generator that gives an appropriate response to the turning operation of the handle 40, a rudder angle sensor 202 that detects the rudder angle of the handle 40 (see FIG. 4), and the vertical direction of the handle 40 A vertical detection sensor 204 (see FIG. 4) and the like for detecting an operation on is stored.

  In a substantially triangular space formed between the handle-side base pipe 52 and the front fork 58, a second control box 62 covered with a case of resin or the like is attached. Inside the second control box 62, the amount of operation of the front wheel brake is detected by the amount of sliding of the brake resistance generator or the front wheel brake wire 66 that gives an appropriate response to the swing operation of the front wheel brake lever 64 provided on the handle 40. A brake sensor 206 (refer to FIG. 4) is stored. A rear wheel brake wire 70 from the rear wheel brake lever 68 (see FIG. 1) extends through the second control box 62 to the rear wheel side (see FIG. 2). The first control box 60 and the second control box 62 are connected to the main monitor 14 and the control device 20 via a harness 72 and the like. In the following description, the front wheel brake lever 64 and the rear wheel brake lever 68 are collectively referred to simply as the brake lever 208 (see FIG. 4).

  The drive unit 43 is supported by a pipe-like under stay 74 and an upper stay 76 that support the rear wheel 42 with a pair of left and right truss structures extending rearward from the saddle side base pipe 54. At the front end of the understay 74, a pair of cranks 80, 80 connected to the left and right of a rotating shaft (crankshaft) 78 and pedals 82, 82 provided at the tips of the cranks 80, 80 are rotatable. It is pivotally supported.

  Therefore, in the drive unit 43, when the driver strokes the pedal 82, an endless drive chain (not shown) wound around a front sprocket (not shown) coupled to the crank 80 is driven. The drive chain is wound around a rear sprocket (not shown) provided on a rotation shaft (not shown) of a flywheel 88 (rotary body) rotatably attached to the rear side of the vehicle body of the pedal 82. Thus, the flywheel 88 is rotationally driven with the driver's pedal operation. In place of the drive chain, a belt made of resin or metal may be used.

  A pedal load adjusting mechanism 92 having a roller that rotates in contact with the outer peripheral surface of the flywheel 88 is attached to the front of the vehicle body of the flywheel 88. By adjusting the rotational resistance of the flywheel 88, the pedal is adjusted. It is possible to change the pedaling force required for the rotation of 82, that is, the pedal load.

  A one-way clutch (not shown) is disposed between the rotating shaft of the flywheel 88 and the rear sprocket attached to the rotating shaft, and can reproduce inertial running similar to that of a normal bicycle. . Further, by detecting the rotational speed of the flywheel 88 with a rotational speed sensor 210 (see FIG. 4) attached to the vehicle body, the pseudo speed of the simulated bicycle 12 is calculated by the control device 20. Further, a drum brake (not shown) operated by a rear wheel brake wire 70 (see FIG. 2) from the rear wheel brake lever 68 is attached to the flywheel 88, and the flywheel that is actually rotationally driven. By braking 88, it is possible to obtain a feeling of rear brake operation that is close to actual driving.

  Such a flywheel 88 is rotatably supported around a rotation axis with respect to a support plate (not shown) fixed to the understay 74 and the upper stay 76. The drum brake that applies a braking force to the flywheel 88 is configured such that when the swing arm connected to the rear wheel brake wire 70 is pulled forward by the operation of the rear wheel brake lever 68, the brake shoe (see FIG. (Not shown) is pressed to generate a frictional force. The brake system may be configured to use a disc type brake, a cantilever type rim brake that sandwiches the outer periphery of the flywheel, and the like.

  The rear stand 30 that supports the rear monitor 18 includes a connecting pipe (connecting portion) 170 that is connected to the end portion of the under pipe 50 of the main frame 26 by a connecting portion 28, and the other end side of the connecting pipe 170 in the vertical direction. In order to stably support the rear monitor 18 by reinforcing the vertical pipe (holding portion) 172 to which the rear monitor 18 is fixed at the upper end side and reinforcing the vicinity of the rising base end portion of the vertical pipe 172, the floor surface It is comprised from the annular pipe (holding | maintenance part) 174 fixed to.

  As shown in FIGS. 1 and 2, the connection pipe 170 has a portion close to the connection portion 28 along the longitudinal direction of the vehicle body of the simulated bicycle 12, and the rear side thereof is bent from the front of the rear wheel 42 of the simulated bicycle 12. It extends to the right rear of the car body.

  In the connecting portion 28, the under pipe 50 and the connecting pipe 170 of the main frame 26 are rod-like pipes on the under pipe 50 side, and are hollow pipes having slits on the connecting pipe 170 side. The ends of the pipes 50 are inserted, and are connected to each other by being fastened by the connecting bolts 176 (see FIG. 2) from the outer periphery of the connecting pipe 170.

  As shown in FIG. 1 and FIG. 2, the harness 178 from the rear monitor 18 is passed from the vertical pipe 172 into the connecting pipe 170, and externally from the hole 171 formed near the end of the connecting pipe 170. The USB connector (connector) 179 at the tip is connected to a USB terminal (connector) 180 provided at the lower part of the simulated bicycle 12. The harness 184 after being connected to the USB terminal 180 is connected to a USB connector 186 provided in front of the simulated bicycle 12, and a USB connector (connector) 190 of a harness (188) extending from the control device 20 provided below the main monitor 14. As a result, the rear monitor 18 can be displayed and controlled by the control device 20 arranged on the main frame 26 side (front stand 16). Thus, by connecting the wiring (harness) from the rear monitor 18 to the control device 20 via each connector, the parts of the bicycle simulation device 10 can be disassembled and assembled more easily. That is, each of the rear stand 30, the simulated bicycle 12, and the main monitor 14 can be separated by the connector, and wiring processing when disassembling each is facilitated. In this case, the harness 184 from the USB terminal 180 passes from the center frame 56 into the second control box 62 and is led out to the front of the simulated bicycle 12. The harness 184 can be protected by providing rubber or the like grommets at the entrance and exit of the harness 184 to the center frame 56, the handle-side base pipe 52, and the second control box 62.

  When the USB connector 178a or the like is disconnected, it is preferable to display the location on the main monitor 14 and restart it by reconnecting. Of course, the rear monitor 18 and the control device 20 may be connected by a connection method other than USB connection.

  As shown in FIG. 1, in the simulated bicycle 12, the drive unit 43 is covered with a cover 99 made of resin or the like to prevent the driver from contacting the drive chain or the like.

  On the other hand, a controller 220 is attached to the center portion of the handle 40. As shown in FIG. 3, the controller 220 includes up and down direction keys 222, three numbered buttons (first button 224a to third button 224c), and a button for requesting termination (end button 226). And have.

  The first button 224a to the third button 224c mainly function as selection buttons for selecting an item from a selection screen displayed on a monitor or inputting an answer in, for example, a quiz (three choices) related to a bicycle. The third button 224c also functions as a determination button. The end button 226 is used to end the bicycle simulation program or return to the previously displayed selection screen. The handle 40 also functions as an operation switch for selecting an item 232 in the setting screen 230 when the setting screen 230 (see FIG. 5) is displayed on the monitor 200. This will be described later.

  Therefore, as shown in FIG. 4, the controller 220, the handle 40, the brake lever 208, the pedal 82 (flywheel 88) and the like described above function as an input operation unit 234 for performing operation input to the control device 20. In addition, the bicycle simulation apparatus 10 includes a speaker 236 (voice output device: see FIG. 4) that outputs a voice according to an operation input from the input operation unit 234.

  Then, as shown in FIG. 4, the control device 20 includes a setting screen display unit 240, an age acquisition unit 242, a background image display unit 244, a camera viewpoint correction unit 246, a guidance image display unit 248, and a guidance sound. The output unit 250 includes an acceleration setting unit 252, a vehicle speed upper limit setting unit 254, a vehicle speed setting unit 256, and a memory 258.

  The memory 258 stores a plurality of preset background image information 260. One background image information 260 is three-dimensional image information of one city set for bicycle education, and when displayed on the monitor 200, the tertiary image on the background image of the bicycle operated by the user. Based on the original coordinates (that is, the three-dimensional coordinates of the camera viewpoint) and the three-dimensional coordinates of the focal point, the image is converted into an image of the screen coordinate system and displayed. At this time, when the user operates the pedal 82, the three-dimensional coordinates on the background image of the camera viewpoint change every moment. Therefore, the user riding on the bicycle travels on the monitor 200 as if traveling on the street. A moving image is displayed.

  The background image information 260 (three-dimensional image information) stored in the memory 258 includes, for example, three-dimensional image information of a virtual city that imitates a city that actually exists, a crossroad (with or without traffic light), a T-junction, There are three-dimensional image information of a virtual town where various points that are educationally important, such as sidewalks, are arranged at important points. In particular, in the present embodiment, a plurality of three-dimensional image information corresponding to the age group is prepared in consideration of traffic regulations. That is, three-dimensional image information mainly based on traveling on a bicycle on a street, three-dimensional image information mainly based on traveling on a sidewalk in the city, and the like.

  The memory 258 stores a sentence information table 262 in which a plurality of pieces of sentence data representing the meaning of the guidance are registered for one guidance, corresponding to the number of prepared guidances. Yes. Here, guidance mainly means guidance, including warnings, cautions and requests, as well as text excerpts from traffic laws and regulations.

  For example, the sentence data registered in one sentence information table 262 is a sentence that an adult can understand, a sentence that an adult can understand, a sentence that an elementary school student can understand, a sentence that a junior high school student can understand, and a sentence that an elementary school student can understand. It is created for each age group, such as a sentence that an infant can understand.

  The setting screen display unit 240 displays a setting screen 230 on the monitor 200 for at least allowing the user to perform an operation input regarding age. As shown in FIG. 5, the setting screen 230 has a display form in which a plurality of items (four items 232 in the example of FIG. 5) are arranged along one circumference. Each item 232 includes a frame 231 and characters 233 indicating the age group arranged in the frame 231. In order for the selection / non-selection of the item 232 to be clearly understood by various age groups, the color of the item being selected (the item that has been selected but not input-set) is, for example, yellow The colored display is made and the whole is enlarged and the non-selected item is displayed with the color in the frame 231 colored, for example, gray.

  As the item 232, as shown in FIG. 5, “more than junior high school students”, “higher grades of elementary school”, “lower grades of elementary school”, “senior” and the like can be cited. “Senior” is assumed to be over 70 years old. Of course, "infant" may be added to this, and other items may be added. In addition, items such as “3 years old and under 6 years old” “6 years old and under 9 years old”, “9 years old and under 12 years old”, “12 years old and under 70 years old”, “70 years old and over”, etc. You may make it show the range of age. That is, each item represents an age group, and is category information in which the assumed longest age is divided into a plurality of age groups. As for the way of classification, it is possible to target a wide range of age groups from infants to elderly people by subdividing and classifying the younger age group or subdividing the older age group.

  The age acquisition unit 242 acquires the age information of the user based on the operation input related to the age from the input operation unit 234. For example, when the setting screen 230 is displayed on the monitor 200, the item is selected in the clockwise direction by moving the handle 40 upward (by inputting a detection signal indicating the upward direction from the vertical detection sensor 204). The item is selected in the counterclockwise direction by moving the handle 40 downward (by inputting a detection signal indicating the downward direction from the vertical detection sensor 204). Of course, the item 232 can be similarly selected by operating the direction key 222 of the controller 220. After selecting one item 232, for example, by pressing the third button 224c of the controller 220, a determination signal is supplied from the third button 224c to the age acquisition unit 242. Based on the supply of the determination signal, the age acquisition unit 242 stores a numerical value corresponding to the selected item 232 in the first register R1.

  The background image display unit 244 displays background image information 260 corresponding to the age information on the monitor 200. That is, the background image display unit 244 reads out the background image information 260 corresponding to the age information from the plurality of background image information 260 stored in the memory 258 from the memory 258 and displays it on the monitor 200. In this case, the background image display unit 244 displays the background image information 260 corresponding to the age information on the monitor 200 based on the camera viewpoint in which the height direction coordinates are set according to the age information. Specifically, the background image information 260 based on virtual three-dimensional coordinates is displayed on the monitor 200 as an image based on screen coordinates obtained by performing perspective transformation based on at least the camera viewpoint.

  Of the three-dimensional coordinates of the bicycle on the background image information 260 (that is, the three-dimensional coordinates of the camera viewpoint), the X coordinate (left and right) and the Z coordinate (depth) change every moment according to the steering operation of the user and the traveling speed. To do. On the other hand, the Y coordinate (height direction) is selected and set according to the age information, and is maintained at a constant coordinate until the next setting change.

  The setting of the camera viewpoint in the background image display unit 244 is performed as follows, for example. That is, the memory 258 stores a camera viewpoint information table 264 in which a plurality of Y coordinates are registered for the camera viewpoint. The background image display unit 244 reads the Y coordinate corresponding to the age information among the plurality of Y coordinates registered in the camera viewpoint information table 264, and sets it as the Y coordinate of the camera viewpoint. Further, since the camera viewpoint vector is obtained based on the detection signal from the rudder angle sensor 202 and vehicle speed information (vehicle speed value stored in the fifth register R5) described later, the camera viewpoint X is obtained. The coordinates and the Z coordinate are obtained, and as a result, the three-dimensional coordinates of the camera viewpoint on the selected background image information 260 are obtained.

  Then, the background image display unit 244 extracts, from the background image information 260, background image information that enters the field of view in the vector direction from the camera viewpoint based on the obtained three-dimensional coordinates of the camera viewpoint and the vector, and screen coordinates A system image is converted and displayed on the monitor 200. By repeating this process, a moving image is displayed on the monitor 200 as if the user on the bicycle is traveling in the city. The display of the background image information 260 on the monitor 200 may be displayed with a first person (first person viewpoint) or a third person (third person viewpoint).

  In particular, in this embodiment, a plurality of camera viewpoint Y coordinates are prepared and registered in the camera viewpoint information table 264, and when the age information setting is completed, the Y coordinates corresponding to the age information are read out, and the background The Y coordinate of the camera viewpoint for displaying the image information 260 is used. Therefore, for example, when the user is in the lower grades of elementary school, the Y coordinate of the camera viewpoint can be set lower than that of an adult, and the user can simulate a running feeling similar to that when the user actually runs a bicycle. be able to.

  The camera viewpoint correction unit 246 obtains the height information of the user based on the operation input related to the height from the input operation unit 234 (for example, the controller 220), and uses the camera viewpoint set according to the age information as the height information. Correct accordingly. Even if you are an elementary school student, there are tall children and even adults who are short, so if you set the camera viewpoint only with age information, it will be displayed on the monitor for tall children and short people In some cases, a sense of incongruity may occur with respect to the background image. Therefore, the camera viewpoint correction unit 246 displays a background image that is as close to reality as possible, that is, a background image that is familiar to the user, by correcting the camera viewpoint set according to the age information according to the height information. can do.

  The guidance image display unit 248 displays, on the monitor 200, a combination of at least character images representing the meaning of the guidance among the guidance images corresponding to the operation input from the input operation unit 234, according to the age information. To do. Specifically, the guidance image display unit 248 displays the sentence data corresponding to the age information among the plurality of sentence data registered in the sentence information table 262 corresponding to the guidance according to the operation input from the input operation unit 234. Read out and display on the monitor 200. For example, when the vehicle stops driving with a red light and does not switch to the green light, the monitor 200 displays a sentence indicating the content that prompts the stop as guidance. If the displayed text includes expressions that have not yet been learned by infants or lower grades, adults may be able to understand them but may not be understood by infants or lower grades. Therefore, in the present embodiment, text data corresponding to age information is read out and displayed on the monitor 200. In other words, among the guidance images, at least a combination of character images representing the meaning of the guidance is displayed on the monitor 200 in accordance with the age information. As a result, if the user is, for example, an infant or an elementary school student, the guidance of the content prompting the suspension can be displayed in a sentence that can be understood even by an infant or an elementary school student, and the degree of understanding of the user can be accelerated. .

  The guidance voice output unit 250 changes the combination of words constituting the guidance according to the operation input from the input operation unit 234 according to the age information, and outputs it to the speaker 236. Specifically, the guidance voice output unit 250 selects sentence data corresponding to age information from among a plurality of sentence data registered in the sentence information table 262 corresponding to guidance according to an operation input from the input operation unit 234. Read out and output to the speaker 236. As a result, if the user is an infant or an elementary school grader, for example, the guidance for urging the stoppage can be output as a sentence that can be understood even by the infant or the elementary school grader.

  The acceleration setting unit 252 sets an acceleration serving as a basis for calculating the vehicle speed according to the age information. Specifically, the acceleration setting unit 252 reflects the age information in the detection value from the rotation speed sensor 210 to obtain the current speed value, and the previous speed value (stored in the second register R2) from the current speed value. Acceleration value is obtained based on the value obtained by subtracting the initial value = 0), the acceleration value is stored in the third register R3, and the value obtained by integrating the acceleration value in the third register R3 is the previous speed value. Are stored in the second register R2, and the acceleration is sequentially set.

  The vehicle speed upper limit setting unit 254 sets the vehicle speed upper limit value that limits the upper limit of the vehicle speed set by the vehicle speed setting unit 256 described later to a value according to the age information. There are at least two types of processing in the vehicle speed upper limit setting unit 254 (first processing and second processing).

  The first process uses the upper limit information table 270 stored in the memory 258. A plurality of upper limit values are registered in the upper limit value information table 270. Then, the vehicle speed upper limit setting unit 254 reads the upper limit value corresponding to the age information among the plurality of upper limit values registered in the upper limit value information table 270, and stores it in the fourth register R4.

  The second process uses the map address information table 272 stored in the memory 258. In this map address information table 272, the top addresses of a plurality of maps 274 are registered. The map 274 is obtained by converting a gain curve or a gain line for correcting the vehicle speed once obtained in accordance with the corresponding upper limit value. For example, when the gain line is taken as an example, the map 274 is once obtained on the horizontal axis. When the corrected vehicle speed is set on the vertical axis, the corrected vehicle speed corresponding to the once calculated vehicle speed can be obtained from the gain line. The memory 258 stores a plurality of maps 274 having different characteristics according to a plurality of upper limit values, and the top address of each map 274 is registered in the map address information table 272. The vehicle speed upper limit setting unit 254 reads out a map address corresponding to the age information among the plurality of map addresses registered in the map address information table 272, and stores it in the fourth register R4.

  The vehicle speed setting unit 256 sets the vehicle speed on the background image of the bicycle operated by the user in accordance with the operation input from the input operation unit 234. The vehicle speed setting unit 256 calculates a deceleration value based on the brake input value from the brake sensor 206 based on the operation of the brake lever 208 which is one of the input operation units 234, and the speed stored in the second register R2 The vehicle speed (vehicle speed value) is calculated by subtracting the deceleration value from the value. The calculated vehicle speed value is stored in the fifth register R5 as the vehicle speed once obtained.

  Furthermore, if the vehicle speed upper limit value setting unit 254 stores the upper limit value in the fourth register R4 by the first process, the vehicle speed setting unit 256 obtains the vehicle speed value and the upper limit value stored in the fifth register R5. In comparison, if the vehicle speed value is equal to or lower than the upper limit value, the vehicle speed value in the fifth register R5 is maintained as it is, and if the vehicle speed value exceeds the upper limit value, the vehicle speed value in the fifth register R5 is rewritten to the upper limit value. If the vehicle speed upper limit setting unit 254 stores the map address in the fourth register R4 by the second process, the corresponding map 274 is read based on the map address, and the fifth register is read based on the map 274. The vehicle speed value stored in R5 is corrected. By these processes, the upper limit value of the vehicle speed once obtained is limited by the upper limit value set by the vehicle speed upper limit value setting unit 254. The vehicle speed value stored in the fifth register R5 is used for displaying the background image information 260 on the background image display unit 244.

  Next, the operation of the bicycle simulation apparatus 10 according to the present embodiment will be described with reference to FIGS.

  First, in step S <b> 1 of FIG. 6, the setting screen display unit 240 displays a setting screen 230 on the monitor 200 for allowing the user to input an operation related to age, as shown in FIG. 5.

  In step S <b> 2, the age acquisition unit 242 waits for an operation input related to age from the input operation unit 234. The corresponding item 232 is selected according to the up / down operation of the handle 40 by the user and the operation of the direction key of the controller 220. Then, the third button 224c of the controller 220 is operated, and the process proceeds to the next step S3. In step S3, the age acquisition unit 242 stores a numerical value (operational information) corresponding to the selected item, that is, a numerical value (age information) corresponding to the currently selected item, in the first register R1. If necessary, an operation input regarding height is performed in step S4.

  In step S5 and subsequent steps, the simulation operation is started. When simulating driving, a monitor, a practice course (a course that runs in a virtual city by bicycle), difficulty setting, a case study course (a course to practice while predicting danger and avoidance practice), a bicycle quiz A selection screen is displayed for the user to select, and the user selects a corresponding item. The simulated driving displays a practice course screen, a case study course screen, and a quiz screen according to the selected item. The user operates the simulated bicycle according to the displayed screen and guidance.

Table 1 below shows an example of a table displayed on a selection screen for selecting a course. “○” is a selectable course. The courses that can be selected vary depending on the age group. For example, only 4 easy courses can be selected for lower grades of elementary school, 4 courses for seniors can be selected, and 3 courses for case studies can be selected. It has become. Of course, it may be possible to select four courses that are easy for seniors and can be changed as appropriate according to the specifications.

  In this simulated driving process, first, an operation process of the own vehicle (bicycle operated by the user) is performed from step S5 to step S7, an operation process of the other vehicle is performed in step S8, and steps S9 and S10 are performed. Guidance processing is performed at. Thereafter, in step S11, it is determined whether or not there is a termination request (such as operation of a termination button or power off). If it is not a termination request, the processing from step S5 is repeated.

  Specifically, processing at the acceleration setting unit 252 is performed at step S5, processing at the vehicle speed upper limit setting unit 254 is performed at step S6, processing at the vehicle speed setting unit 256 is performed at step S7, and step In S8, processing in the background image display unit 244 is performed. In step S10, the guidance image display unit 248 performs processing. In step S11, the guidance voice output unit 250 performs processing.

  That is, in step S5, the acceleration setting unit 252 sets an acceleration that is a basis for calculating the vehicle speed according to the age information.

  Here, specific processing in the acceleration setting unit 252 will be described with reference to FIG. First, in step S101 in FIG. 7, the speed value (initial value = 0) is read from the second register R2. Thereafter, in step S102, it is determined whether or not the speed value is less than a predetermined value. Usually, acceleration increases during the process of shifting from a stopped state to a traveling state or at a low speed. Therefore, it is determined whether or not the speed is low. In this embodiment, the predetermined value is set to 5 km / h, for example.

  If the speed value is greater than or equal to a predetermined value, the coefficient ha is stored in a sixth register (not shown) in step S103, and if the speed value is less than the predetermined value, the coefficient is stored in the sixth register in step S104. hb (= ha × 3.0) is stored. The characteristics of the set coefficient ha and coefficient hb are shown in FIG. An example of hb = ha × 3 is a characteristic indicated by a solid line La in FIG. In addition, the coefficients ha and hb may be indicated by a one-dot chain line Lb. The coefficient ha may be a characteristic indicated by a broken line Lc or a characteristic indicated by a two-dot chain line Le, or the coefficient hb may be a characteristic indicated by a dotted line Ld. In the case of the characteristic indicated by the alternate long and short dash line Lb, the values of the coefficient ha and the coefficient hb decrease linearly as the speed value increases, which is favorable for obtaining a smooth running feeling. In the case of the characteristic indicated by the broken line Lc, the value of the coefficient hb linearly decreases as the speed value increases within a range of less than 5 km / h. Is suitable for operation. In the case of the characteristics indicated by the dotted line Ld, the followability of the rising of the vehicle speed is improved in the range of a high vehicle speed of 5 km / h or more. In this case, it is necessary to consider overshoot. In the case of the characteristics indicated by the two-dot chain line Le, the rising of the vehicle speed can be made steeper in the range of less than 5 km / h compared to the case of the solid line La.

  Thereafter, in step S105, the acceleration α is obtained by the following arithmetic expression.

Acceleration α = {(I / k) −v} × z
Here, I is a detected value from the rotation speed sensor 210, k is a coefficient set according to age information (value stored in the first register R1), and v is a speed value stored in the second register R2. , Z are coefficients stored in the sixth register and are ha or hb. The coefficient k is increased step by step in the order of infants, lower grades, upper grades, junior high school students, and so on. The value of can be adopted. The coefficient k can be set according to the tire size (26 inches, 24 inches, 22 inches, etc.) inputted by the selection operation separately from the age information. This will be described later. Infants and lower grades have low kicking power (the power to depress the pedal), so the acceleration is not so high compared to adults. The same applies to seniors. Further, the acceleration changes greatly when the vehicle speed is low, and the change in acceleration is small when the vehicle speed is medium or high. Therefore, by calculating the acceleration as described above, it is possible to obtain an acceleration according to the age group and according to the current vehicle speed. In addition, since the acceleration changes depending on the tire size, the coefficient k is set according to the tire size in addition to the age information as described above, so that the acceleration corresponds to the age group and the tire size. In addition, an acceleration corresponding to the current vehicle speed can be obtained.

  FIG. 9 shows a setting example of a constant k corresponding to button selection (age group selection), a bicycle wheel size assumed in the background image displayed on the main monitor, and a viewpoint height. The constant k is preferably set to a value corresponding to the increase in the vehicle speed due to the operation of the pedal 82 corresponding to approximately half of the rotation of the flywheel 88 in accordance with the set value of the bicycle wheel size.

  Thereafter, in step S106, the deceleration by the brake is calculated based on the brake input value from the brake sensor 206 based on the operation of the brake lever 208 and the characteristics shown in FIG. 10A, and further the speed value (vehicle speed). The deceleration due to the running resistance that increases each time increases is calculated based on the speed value (I / k in the above equation) and the characteristics shown in FIG. 10B. Then, the deceleration due to the brake and the deceleration due to the running resistance are added together to obtain the deceleration β and stored in a seventh register R7 (not shown).

  After that, in step S107 of FIG. 7, the acceleration (α−β) is calculated by subtracting the deceleration β stored in the seventh register from the acceleration α obtained by the arithmetic expression, and this acceleration (α−β) is calculated. β) is integrated, and the integrated value is stored in the second register R2 as a velocity value.

  Returning to the description of FIG. 6, in step S6, the vehicle speed upper limit value setting unit 254 passes the first process or the second process described above, and the upper limit value corresponding to the age information or the map address corresponding to the age information in the fourth register R4. Is stored.

  In step S7, the vehicle speed setting unit 256 calculates a deceleration value based on the brake input value from the brake sensor 206, and subtracts the deceleration value from the speed value stored in the second register R2 to obtain the vehicle speed (vehicle speed value). And the vehicle speed value obtained by the computation is stored in the fifth register R5 as the vehicle speed once obtained. Furthermore, if the vehicle speed upper limit value setting unit 254 stores the upper limit value in the fourth register R4 by the first process, the vehicle speed setting unit 256 obtains the vehicle speed value and the upper limit value stored in the fifth register R5. In comparison, if the vehicle speed value is equal to or lower than the upper limit value, the vehicle speed value in the fifth register R5 is maintained as it is, and if the vehicle speed value exceeds the upper limit value, the vehicle speed value in the fifth register R5 is rewritten to the upper limit value. If the vehicle speed upper limit setting unit 254 stores the map address in the fourth register R4 by the second process, the corresponding map is read based on the map address, and the fifth register R5 is read based on the map. The stored vehicle speed value is corrected. By these processes, the upper limit value of the vehicle speed once obtained is limited by the upper limit value set by the vehicle speed upper limit value setting unit 254.

  As described above, the maximum speed is not so high compared to adults because infants and lower grades have low kick power (the power to depress the pedal). The same applies to seniors. Therefore, by limiting the upper limit value of the vehicle speed as described above, it is possible to simulate a bicycle traveling in a vehicle speed according to the age group, that is, in a situation close to reality.

  In step S8, the background image display unit 244 displays the background image information 260 corresponding to at least the age information on the monitor. The background image display unit 244 reads from the memory 258 the background image information 260 corresponding to the selected course among the plurality of background image information 260 stored in the memory 258 and corresponding to the age information, and monitors the monitor 200. To display. At this time, the background image display unit 244 displays the background image information 260 on the monitor 200 based on the camera viewpoint in which the three-dimensional coordinates are set by the age information and the vehicle speed value. If an operation input related to height has been performed in step S4 described above, the camera viewpoint correction unit 246 acquires the user's height information based on the operation input related to height, and sets the camera viewpoint set according to the age information. Correct according to height information. Therefore, the background image display unit 244 displays the background image information 260 on the monitor 200 based on the camera viewpoint corrected by the height information.

  In step S10, the guidance image display unit reads out the text data corresponding to the age information from the plurality of text data registered in the text information table corresponding to the guidance according to the operation input from the input operation unit, and displays it on the monitor. indicate.

  In step S11, the guidance voice output unit reads the sentence data corresponding to the age information from among the plurality of sentence data registered in the information table corresponding to the guidance according to the operation input from the input operation unit, and outputs the voice data. Output to.

  When it is determined in step S12 described above that there is an end request, the processing in this bicycle simulation apparatus ends.

  As described above, in the bicycle simulation apparatus according to the present embodiment, the user's age information is acquired based on the operation input related to the age from the input operation unit, and the camera viewpoint is changed according to the age information to change the background. Since the image information is displayed on the monitor, it is possible to cause the user to experience a driving experience similar to the case where the user actually drives the bicycle. In addition, by correcting the camera viewpoint set according to age information according to height information, even if it is an elementary school student or a tall child, or an adult or a short person, it is as realistic as possible. A background image close to, i.e., a background image from a familiar viewpoint can be displayed.

  Further, in the present embodiment, when displaying the guidance, the sentence data corresponding to the age information is read and displayed on the monitor 200, or the voice is output to the speaker. If it is a school year, it is possible to display the guidance of the content prompting the suspension as a sentence that can be understood even by an infant or a lower grade, and the user's degree of understanding can be accelerated.

  In the present embodiment, since the kick power (the power to step on the pedal) is low in the infant and the lower grades, the acceleration is not so large as compared with the adult. The same applies to seniors. Further, the acceleration changes greatly when the vehicle speed is low, and the change in acceleration is small when the vehicle speed is medium or high. Therefore, by calculating the acceleration as described above, it is possible to obtain an acceleration according to the age group and according to the current vehicle speed.

  In the present embodiment, when the vehicle speed is set, the upper limit value of the vehicle speed is limited according to the age information, so that it is possible to simulate a bicycle traveling in a situation close to reality.

  In the present embodiment, since the background image information 260 corresponding to the age information is read out and displayed from among the plurality of preset background image information 260, the place where the vehicle can travel depending on the age group according to traffic regulations. When there is a place that cannot be used, the background image information 260 limited to places that can be driven according to the age group can be displayed, and a single bicycle simulation device 10 can provide traffic safety education for a wide range of age groups. It can be carried out.

  In the present embodiment, the background image information 260 corresponding to the age information is displayed based on the camera viewpoint in which the coordinate in the height direction is set according to the age information. The driving feeling similar to that when the user actually runs the bicycle can be simulated.

  In the present embodiment, the background image information 260 based on the virtual three-dimensional coordinates is displayed as a moving image background image based on the screen coordinates obtained by performing perspective transformation based on at least the camera viewpoint. Bicycles in virtual towns that imitate real-world towns, virtual towns with various points that are key to education, such as crossroads (with and without traffic lights), T-shaped roads, sidewalks, etc. It is possible to display a moving image as if the user riding on the vehicle is traveling.

  In this embodiment, since the age information is classified information in which the assumed maximum age is divided into a plurality of age groups, the lower age group is subdivided and the older age group is segmented. It becomes possible to target a wide age group from infants to elderly people.

  In the present embodiment, since the setting screen 230 for causing at least the user to perform an operation input related to age is displayed, the user is prompted to input an operation related to age in the initial setting stage. it can.

  Therefore, in the present embodiment, it is possible to display field of view images and explanatory texts according to the age group, and even one bicycle simulation apparatus 10 can target a wide range of age groups from infants to adults. . Further, when viewed from the viewpoint of traffic safety education, by changing the height of the camera viewpoint in accordance with age information and height, it is possible to teach a user a dangerous event due to age difference or physique difference.

  Of course, the bicycle simulation apparatus according to the present invention is not limited to the above-described embodiment, and various configurations can be adopted without departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 10 ... Bicycle simulation apparatus 12 ... Simulated bicycle 20 ... Control apparatus (control part) 34 ... Saddle 200 ... Monitor (display apparatus) 230 ... Setting screen 232 ... Item 234 ... Input operation part 240 ... Setting screen display part 242 ... Age acquisition part 244 ... Background image display unit 246 ... Camera viewpoint correction unit 248 ... Guidance image display unit 250 ... Guidance voice output unit 252 ... Acceleration setting unit 254 ... Vehicle speed upper limit setting unit 256 ... Vehicle speed setting unit 258 ... Memory 260 ... Background image information 262 ... Text information table 264 ... Camera viewpoint information table 270 ... Upper limit information table 272 ... Map address information table 274 ... Map

Claims (16)

A seating section (34) where a user is seated, an input operation section (234) operated by the user, and a display device (200) that displays at least an image corresponding to an operation input from the input operation section (234) And a control unit (20) that controls at least the input operation unit (234) and the display device (200), and allows the user to experience a bicycle running state in a simulated manner.
The control unit (20)
An age acquisition unit (242) that acquires age information of the user based on an operation input related to age from the input operation unit (234);
A background image display unit (244) for displaying background image information (260) corresponding to the age information on the display device (200);
Of the guidance images corresponding to the operation input from the input operation unit (234), a combination of at least character images representing the meaning of the guidance is changed according to the age information to the display device (200). A bicycle simulation apparatus comprising a guidance image display unit (248) for displaying. The bicycle simulation apparatus according to claim 1,
Furthermore, it has an audio output device (236) for outputting the guidance according to an operation input from the input operation unit (234).
The control unit (20)
A guidance voice output unit (250) that outputs a combination of words constituting the guidance according to an operation input from the input operation unit (234) to the voice output device (236) by changing according to the age information. A bicycle simulation apparatus comprising: The bicycle simulation apparatus according to claim 1,
The control unit (20)
A vehicle speed setting unit (256) for setting a vehicle speed on the background image information (260) of the bicycle operated by the user in response to an operation input from the input operation unit (234);
A bicycle simulation apparatus, comprising: an acceleration setting unit (252) that sets an acceleration that is a basis for calculating the vehicle speed according to the age information. The bicycle simulation apparatus according to claim 3, wherein
The bicycle is a simulated car (12) provided with a pedal (82) operated by the user,
The input operation unit (234) includes at least a rotating body (88) that rotates by a pedal operation of the user, and a rotation speed sensor (210) that detects a rotation speed of the rotating body (88),
The acceleration setting unit (252)
The detected value from the rotation speed sensor (210) is set to the current speed reflecting the age information, and the acceleration is set based on a value obtained by subtracting the previous speed (initial value = 0) from the current speed. Then, by repeating the process of setting the value obtained by integrating the acceleration as the previous speed, the acceleration is sequentially set,
The bicycle speed setting unit (256) calculates the vehicle speed based on a value obtained by integrating the acceleration. The bicycle simulation apparatus according to claim 3 or 4,
And a vehicle speed upper limit setting unit (254) for setting a vehicle speed upper limit value for limiting the upper limit of the vehicle speed set by the vehicle speed setting unit (256) to a value corresponding to the age information. Simulation device. The bicycle simulation apparatus according to claim 1,
A plurality of preset background image information (260) each having a memory (258) stored;
The background image display unit (244) reads out background image information (260) corresponding to the age information from the plurality of background image information (260) from the memory (258) and stores it in the display device (200). A bicycle simulation apparatus characterized by displaying. The bicycle simulation apparatus according to claim 6, wherein
The background image display unit (244) displays the background image information (260) corresponding to the age information based on the camera viewpoint in which coordinates in the height direction are set according to the age information. Bicycle simulation device characterized by being displayed on the screen. The bicycle simulation apparatus according to claim 7, wherein
The background image display unit (244) includes the display device (200) as a background image of a moving image based on screen coordinates obtained by perspective-transforming the background image based on virtual three-dimensional coordinates based on at least the camera viewpoint. ) Is displayed on the bicycle simulation apparatus. The bicycle simulation apparatus according to claim 1,
An information table (262) in which a plurality of pieces of text data representing the meaning of the guidance is registered for one guidance has a memory (258) stored corresponding to the number of guidance prepared in advance. And
The guidance image display unit (248) corresponds to the age information among a plurality of sentence data registered in the information table (262) corresponding to the guidance according to the operation input from the input operation unit (234). A bicycle simulation apparatus, wherein text data is read and displayed on the display device (200). The bicycle simulation apparatus according to claim 2, wherein
An information table (262) in which a plurality of text data representing the meaning of the guidance is registered for one guidance has a memory (258) stored corresponding to the number of guidances prepared in advance.
The guidance voice output unit (250) corresponds to the age information among a plurality of sentence data registered in the information table (262) corresponding to the guidance according to the operation input from the input operation unit (234). A bicycle simulation apparatus that reads out sentence data and outputs the sentence data to the voice output device (236). In the bicycle simulation apparatus according to any one of claims 1 to 10,
The bicycle simulation apparatus according to claim 1, wherein the age information is division information obtained by dividing the assumed maximum age into a plurality of age groups. The bicycle simulation apparatus according to claim 1,
The control unit (20)
The bicycle simulation apparatus further comprises a setting screen display unit (240) for displaying a setting screen (230) for causing at least the user to perform an operation input related to the age. The bicycle simulation apparatus according to claim 1,
The control unit (20)
Furthermore, the user's height information is acquired based on an operation input related to height from the input operation unit (234), and at least the camera viewpoint set according to the age information is corrected according to the height information. A bicycle simulation apparatus comprising a camera viewpoint correction unit (246). A pedal (82) provided on the simulated bicycle (12), a rotating body (88) rotated by the pedal (82), a sensor (210) for detecting the number of rotations of the rotating body (88), and the sensor In the bicycle simulation apparatus comprising the control device (20) for controlling the image displayed on the display unit (14) provided in front of the simulated bicycle (12) from the output of (210),
An input operation unit (234) capable of inputting setting information according to the age of the user;
Vehicle speed calculating means for calculating the vehicle speed of the bicycle by multiplying or dividing the detected rotation number of the rotating body (88) by a coefficient calculated from the setting information and integrating the value; ,
The bicycle simulation device, wherein the control device (20) controls an image displayed on the display unit (14) according to the calculated vehicle speed. The bicycle simulation apparatus according to claim 14, wherein
The bicycle simulation apparatus, wherein the coefficient is set based on a tire size of a bicycle assumed to be used by the user of the age indicated by the setting information. The bicycle simulation apparatus according to claim 15, wherein
The coefficient is set so that the calculated vehicle speed substantially coincides with the vehicle speed expected to be reached by operating the pedal (82) corresponding to approximately half rotation of the rotating body (88). A bicycle simulation apparatus characterized by that.

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