JP2834546B2 - Motorcycle riding simulation device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a motorcycle riding simulation apparatus that performs a riding simulation using a model motorcycle on which a person can ride.

(Prior art) Conventionally, there has been known a game simulation device that combines a model motorcycle and a CRT display and changes a display screen in accordance with a steering wheel or an accelerator operation so that a game can be enjoyed as if riding. Japanese Patent Application Laid-Open No. 61-154689 and Japanese Utility Model Application Laid-Open No. 62-1688 also disclose a model motorcycle in which a model motorcycle can be tilted in a lateral direction in order to enhance a sense of reality.

(Problems to be Solved by the Invention) However, according to the above-mentioned publication, the vehicle body only tilts due to weight shift, and a feeling of turning and acceleration / deceleration when traveling on a corner portion, a behavior of the vehicle body during traveling, and the like. However, there is a problem that it is not possible to simulate the actual feeling of driving.

The present invention has been made in view of the above-described circumstances, and provides a riding simulation device for a motorcycle that can simulate an actual driving feeling and can be used not only for playing but also for driving education of a motorcycle. The purpose is to provide.

(Means for Solving the Problems) In order to achieve the above object, the present invention provides a model motorcycle which can be operated by a human being, and a video which is arranged in front of the model motorcycle and is stored in advance. A motorcycle riding simulation device comprising: a display device; and control means for controlling roll and pitch movement of the model motorcycle in accordance with operation and movement of a passenger on the model motorcycle. A function of controlling a video signal to change a video displayed on the device according to the simulated running state of the model motorcycle is provided, and the video is displayed in a direction opposite to the roll direction according to an increase in the roll angle of the body of the model motorcycle. The video signal to the display device was controlled to rotate.

(Operation) During actual running of the motorcycle, a centrifugal force is generated when the vehicle body is rolled, but this cannot be generated by the simulator.

To compensate for this point, the body of the model motorcycle is made less inclined than the actual motorcycle, and the horizontal line in the image on the screen is inclined in the direction opposite to the roll direction. Is added, thereby making the passenger sense the turning feeling. Further, by moving the image in the pitch direction in addition to the movement in the roll direction, the image viewed from the occupant at the time of cornering can be made to feel uncomfortable with an actual motorcycle.

Embodiment First, a mechanical configuration of the present invention will be described with reference to FIG. 1 to FIG. In these figures, reference numeral 1 denotes a base, and 2 denotes a pair of right and left guide rails 1a on the base 1 and rolling wheels 2a.
1 shows a movable table movably supported in the front-rear direction (in the direction of arrow AB) via a. On the base 1, the guide plate 1 b is erected on the outside of each guide rail 1 a, the upper edge of each guide plate 1 b is bent inward, and the guide roller 2 b supported by the movable base 2 is supported on the lower surface thereof. The rack member 3 having a large number of pins 3a arranged in a row is fixedly attached to the upper outer surface of each guide plate 1b.
A drive shaft 4 having pinions 4a meshing with the pins 3a is mounted on both sides. Here, the drive shaft 4 is rotated forward and backward by a motor 5 mounted on the movable base 2 via a gear box 5a to move the movable base 2 forward and backward along the guide rail 1a. The guide rail 1a is configured by a curved rail having a front end side and a rear end side curved upward, and thus the movable base 2 is tilted in the vertical direction (the direction of the arrow EF) as the movable base 2 moves back and forth. did. The movable table 2 is mounted with a pair of front and rear movable devices 6 that are independent of each other and that follow a movement function in two orthogonal directions in the horizontal direction (arrow CD direction) and the vertical direction (arrow EF direction). That is, each movable device 6 is slidably supported in a lateral direction on a guide rail 7a provided horizontally on the movable table 2, and is vertically slidable on a guide rail 8a fixed to the slide table 7. And an elevating frame 8 supported by the Here, the slide base 7 is moved left and right by forward and reverse rotation of a ball screw 9b connected via a gear box 9a to a motor 9 mounted on the moving base 2, while the lifting frame 8 is moved to the motor 10 mounted on the slide base 7. The ball screw 10b connected via the gear box 10a is vertically moved by forward and reverse rotation. As a result, the up-and-down movement and the left and right movement due to the movement of the slide table 7 are given to the lifting frame 8 which is the operating end of each movable device 6.

In this embodiment, as shown in FIG. 13, the movable structure of the movable base 2 may be omitted and fixed directly to the ground for cost reduction. In this case, the movement in the pitch direction is replaced by the vertical movement of the pitch movement of the vertically movable frame 8 of the guide rail 8a.

A support frame 11 is provided between the lifting frames 8 of the movable devices 6, and a model motorcycle 13 is supported on the support frame 11 via a rolling shaft 12 which is long in the front-rear direction so as to be tiltable in the lateral direction. In FIG. 4, the rear end of the support frame 11 is connected to the upper part of the lifting frame 8 of the rear movable device 6 via the cross joint 14, and the ball joint 15 is connected to the upper part of the lifting frame 8 of the front movable device 6. The front end of the support frame 11 is slidably engaged with the linear guide 16 mounted on the guide rail 11a on its lower surface in the front-rear direction so as to be able to move up and down and left and right of the lifting frame 8 of each movable device 6. The support frame 11 can follow up and down and incline in the horizontal direction. A rolling shaft 12 is installed vertically at the center of the support frame 11 in the horizontal direction, and a motor 17 is mounted below the rolling shaft 12. The motor 17 rotates the rolling shaft 12 via a reduction gear 17a and a gear 17b. I am trying to do it. The frame 13a of the model motorcycle 13 is mounted on a seat 12a fixed to the center of the rolling shaft 12.

Reference numerals 18 and 19 denote shock absorbers for restricting the range of movement of the slide table 7 of each movable device 6 of the movable table 2.

The model motorcycle 13 imitates an actual motorcycle,
Accelerator, steering wheel,
Various sensors are provided for detecting operations such as brakes, clutches, gear changes, and weight shift. These sensors include an accelerator opening sensor 21, a clutch lever angle sensor
22, handle torque sensor 23, lean torque sensor 24,
Front brake pressure sensor 25 and rear brake pressure sensor
26 are provided. In addition, to simulate the actual driving situation, various handle switches such as lighting switch, dimmer switch, blinker switch, starter switch, horn switch, kill switch, etc.
27 and a gear position switch 28 are provided.

Further, in order to obtain a sense of realism, the electric fan 29, the vibration generator 30, the speaker 31 and the like for sending wind to the passenger are provided with the model motorcycle 13.
Mounted on Furthermore, in order to reproduce the actual driving condition of the motorcycle by sound and image, a total of four speakers 3 of R / L and two channels provided before and after the model motorcycle 13 are provided.
2 and a display device 33 provided in front thereof. The display device 33 may be provided separately from the base 1 and the movable base 2 as shown in FIG. 1, or may be connected to the movable base 2 as shown in FIG. 5 (a). In any case, the display device is designed to perform some movement in accordance with the movement of the simulator so that the image is easily captured by the passenger. Here, the signal from the sensor is input to a computer, the image on the display device 33 is changed by the computer according to the driving situation, and the motors 5, 9, 10, and 17 are controlled to provide an actual motorcycle. It is configured to reproduce the behavior that can be experienced as in.

Before describing the simulation control by the computer in detail, first, the overall operation of the present invention will be briefly described.

For example, when acceleration or deceleration is performed by an accelerator operation or a brake operation, the movable base 2 is moved back and forth by the motor 5, and the model motorcycle moves as shown in FIGS. 5 (b) and 5 (c). According to this, the model motorcycle 13 is mounted on the guide rail 1a.
Due to the curvature of the vehicle, the vehicle advances forward or backward and then reverses, giving the passenger a feeling of acceleration and deceleration. Also, when the display image goes to the corner and the passenger shifts weight,
Motorcycle 17 rotates rolling shaft 12 to model motorcycle
13 is tilted in the lateral direction, the two movable devices 6 and the motors 9 and 10 are operated, and the model motorcycle 13 is raised in the tilting direction by the combined operation of the slide table 7 and the lifting frame 8.
Gives the passenger a temporary sense of turning when cornering.

The yaw by moving the slide table 7 of both movable devices 6 in the left and right opposite directions, and the slip of the front wheel or the rear wheel by moving these slide tables 7 left and right alone, the lifting frame 8 of the both movable devices 6. By moving up and down independently
The cushion operation on the front wheel side or the rear wheel side is reproduced as shown in FIG. Further, as shown in FIGS. 5 (e) and (f),
You can bend forward and backward.

Next, the computer control in the present invention will be described in detail.

FIG. 6 is a system block diagram showing an electrical configuration of one embodiment of the present invention. Here, the various sensors and the like 21 to
The output signal of 28 is input to the minicomputer 40. The minicomputer 40 includes a CPU (not shown), a ROM or a RAM for storing a control program, various data, and the like.Under the control of the minicomputer 40,
A six-axis servo motor for driving the model motorcycle 13 shown in FIG. 4, an electric fan 29, a vibration generator 30, speakers 31, 32, a display device 33, and a servo motor 35 for steering assist operate. The yaw angle y (FIG. 7 (a)), the roll angle r (FIG. 7 (b)), and the pitch angle p (FIG. 7 (c)) of the vehicle body of the model motorcycle 13 are driven by the six-axis servo motor.
Is controlled. Further, the lean torque sensor 24 for detecting the inclination of the vehicle body is constituted by a load cell or the like, and outputs an electric signal corresponding to the stress generated by tilting the vehicle body (that is, lean torque).

As shown in FIG. 1, a total of seven speakers are provided, including three speakers 31 provided on the vehicle body and the like and four speakers provided outside thereof. Here, in order to give a sense of realism, the speaker 31 provided on the vehicle body mainly reproduces low sounds, and the external speaker 32 reproduces high sounds.
On the other hand, the rotation speed of the electric fan 29 is controlled in proportion to the traveling speed by an inverter or the like, whereby the wind pressure blown on the passenger's face increases as the traveling speed increases. Similarly, the vibration generator 30 is controlled so that the generated vibration increases in proportion to the traveling speed.

FIG. 8 is a flowchart of a calculation process executed by the minicomputer 40 when the model motorcycle 13 actually performs the simulated traveling. Here, it is assumed that the simulation traveling is first started in a straight traveling state, and then the vehicle is inclined to perform the curved traveling. First, after setting data relating to various vehicle characteristics in step 100, when the occupant starts running, this is detected in step 101, and the computer processing proceeds to step 1 through step 102.
Enter 03.

Step 103 is a step of performing an automatic straight-ahead calculation, where acceleration / deceleration G, straight-ahead speed x, pitch angle p,
The vertical movement z, the engine speed Ne, the front wheel speed Nf, the rear wheel speed Nr, and the like are calculated. This calculation is performed by the minicomputer 40 in accordance with a predetermined program, based on the output of each sensor and the like. Specifically, the throttle opening, clutch stroke, gear position, front brake pressure and rear brake pressure are used as input information,
In addition, the characteristic data of the vehicle stored in advance include engine output torque characteristics, brake characteristics, wheel slip ratio, gear reduction ratio, air resistance, wheel rolling resistance, suspension characteristics, moment of inertia of the vehicle body, weight, and position of the vehicle center of gravity. Is used.

In this case, the six-axis servo motor drives the model motorcycle to perform a vertical movement while swinging, thereby giving a feeling of acceleration / deceleration to the occupant. In the early stage of the swinging motion, the acceleration / deceleration feeling can be further improved by adding a simple up / down movement (see FIG. 5 (d)) or forward / backward bending (see 5 (e) and (f)). In the present invention, in order to further improve the feeling of acceleration / deceleration, the image displayed on the screen of the display device 33 is changed. Usually, a display device gives an illusion to a passenger that a model motorcycle that does not actually travel is running, so that an image corresponding to the speed and traveling direction given to the model motorcycle (for example, the motorcycle is actually At a high speed, the video changes faster at high speeds, while the video changes slowly at low speeds. Preferably, the display device is fixed to the model motorcycle as shown in FIG.
It is better that the relative positional relationship between the passenger and the display does not change. However, in order to reduce the cost, it is possible to adopt a configuration in which the moving table 2 is directly placed on the ground as shown in FIG. In this case, as shown in FIGS. 13 (b) and 13 (c), the viewpoint of the occupant moves up and down due to the pitch movement when the vehicle is accelerated and decelerated. As shown in FIG. 9, the displayed image is shifted upward as compared with the case of traveling at a constant speed, while when the viewpoint is lowered due to deceleration, the displayed image is shifted downward. As described above, since the image is also shifted in the vertical direction in accordance with the vertical pitch movement of the model motorcycle accompanying the acceleration / deceleration, the occupant can obtain a sense of acceleration / deceleration without a sense of discomfort. Here, the display image is moved up and down as described above by adding a correction corresponding to the pitch angle of the model motorcycle to the sight line pitch angle of the occupant.

The height of the rotation sensor for the swing motion for acceleration / deceleration as shown in FIG. 5 (or FIG. 13) (b) and (c) is as follows:
It is good to be near the chest of the passenger. Because, in order to make the acceleration applied to the head feel the same as when actually traveling on a motorcycle, the height of the rotation sensor of the swing motion needs to be below the head and not far from the head Is determined by the experiment.

After calculating the straight running of the own vehicle as described above, the process proceeds to step 104 in FIG. 8, where the calculating of the turning of the own vehicle is performed.

FIG. 10 is a flowchart showing details of the calculation of the vehicle turning. As shown in steps 201 and 202, in order to perform this own vehicle turning calculation, first, the lean torque of the model motorcycle is calculated.
T1 and the steering torque Ts are detected.

As is well known, a motorcycle uses a weight shift of a passenger to change its traveling direction. That is, the occupant operates the steering wheel and, at the same time, shifts in weight in the direction in which the occupant wants to turn, and turns. For this reason, in the present simulator, the lean torque sensor 24 for detecting a weight shift is provided as an operation input of the occupant separately from the input by the steering. This sensor is constituted by the load cell as described above, detects the force applied thereto, that is, the weight shift of the occupant, and outputs an electric signal according to the detection result to the minicomputer 40.

Next, the steering input will be described. As the steering input, a steering angle and a steering force of a steering wheel can be considered. In this simulator, the steering force detected by the steering wheel torque sensor 23 is used as the steering input, and the steering angle is calculated based on the steering input.

That is, the steering angle of the steering wheel of the two-wheeled vehicle is much smaller than that of the four-wheeled vehicle, and greatly differs between a low speed and a high speed. In the low speed range, a large cutting angle becomes a small cutting angle in the middle and high speed ranges. Therefore, when the steering angle is used as a steering input, the accuracy required of the sensor greatly changes depending on the vehicle speed. On the other hand, in the case of the steering force, the sensor accuracy range is about 5 kg or less, and the sensitivity of the steering force is generally hardly affected by the vehicle speed. For this reason, in this embodiment, the steering force is used as the steering input. Also, by using the steering force as the steering input, for example, when the passenger drives the model motorcycle away from the vehicle, the vehicle can be driven only with the lean torque accompanying the weight shift, and the steering force at that time is 0 kgm, It is possible to reproduce hand-off driving.

Next, in step 203 of FIG. 10, the input values T1 and Ts are smoothed. This smoothing is necessary to remove noise included in the sensor detection value. Thereafter, at step 204, it refers to the role gain table stored in advance, in a next step 205, based on the following equation (1), to calculate the roll angle r _1.

r ₁ = T1 * GoL + Ts * GoS (1) In step 206, the calculated roll angle r1 is corrected using the own vehicle roll angle correspondence table to obtain the actual roll angle r. In step 207, it obtains the yaw rate y _R (deg / sec) using a constant g, the roll angle r and the vehicle speed v, obtaining a further turning radius Ra on the basis of the yaw rate.

_{y R = g · tan (r} ) / v ... (2) Ra = v / y R ... (3) In the next step 208, the coordinates X _n indicating the current yaw angle y _n and the current vehicle travel position, Calculate the integral of Y _n .

y _n = y _n-1 + y _R · △ t (4) X _n = X _n-1 -Ra [sin (y _n-1 ) -sin (y _n )] (5) Y _n = Y _{n- 1 -Ra [cos (y n-} 1) -cos (y n)] ... (6) by the way, to reproduce the inclination feeling and centrifugal force or the like by the roll movement of the model motorcycle in the simulator, set the following conditions ing.

(1) It is desirable that the regular roll angle be within 15 °. That is,
This is because a roll movement of 15 mm or more makes it difficult for a passenger riding a model motorcycle to hold his body on the motorcycle. In actual motorcycles, the body may lean by more than 15mm, but in order to reproduce this, in this simulator, in addition to the inclination of the model motorcycle, by tilting the image as described later, it will be more realistic. I have to.

(2) The rotation sensor of the roll motion is changed according to the vehicle speed. In this simulator, as shown in Fig. 11, when stopped, the rotation sensor of the roll is used as the ground point of the model motorcycle,
It will increase as the vehicle speed increases, but the upper limit is 600 mm from the ground contact point.

(3) In the low-speed range of 25 km / h or less, the movement in the yaw direction is operated in synchronization with the roll. At this time, the operation direction of the yaw is opposite to that of the roll. For example, when rolling to the right, yaw is generated to the left. In this case, the yaw rotation sensor is located immediately below the butt of the occupant.

Next, the coordinates X _n , Y _n of the own vehicle obtained by the calculation of the user's own curve as described above are converted into the world coordinate system (X ₀ , Y ₀ ) in step 105 of FIG. The world coordinates are coordinates corresponding to data such as the world map and the scenery stored therein, and the scenery is reproduced on the display device as an image based on the current world coordinates. In the next step 106, calculation of a simulation amount / movable amount for controlling the video, generation of an audio signal, and the like are performed. Thereafter, in step 107, control of the model motorcycle, the display device, and the like is performed based on the various control signals calculated so far.

Next, the display device will be described. As for this display method, when using a CRT display,
Alternatively, various methods such as projecting light from a three-primary-color projector onto a screen can be considered. In addition, as described above, a moving image such as a scenery viewed from a moving vehicle or the like that is photographed and stored in advance is used, and this is changed according to the running condition of the model motorcycle, so that the passenger travels on the actual motorcycle. The video control is performed so as to give a sense as if the user is performing.

For example, when a passenger rolls a model motorcycle by weight shift for cornering, simply tilting the image does not match the actual running feeling. For this reason,
As shown in Fig. 12, by adding the pitch angle component of the passenger's line of sight corresponding to about 20% of the roll angle, the horizontal line of the image is lowered to express the feeling of actual running. This is a display control that simulates that the position of the occupant's eyes is lower during cornering than when traveling straight. As described above, the actual roll angle of the model motorcycle is limited, but in order to compensate for this, when the roll angle of the vehicle body increases, the image is inclined in the direction opposite to the roll direction. This gives the passenger a sense of roll.

(Effect of the Invention) As described above, according to the present invention, the present invention provides a model motorcycle that can be operated by a human being, and a display device that is disposed in front of the model motorcycle and displays a previously stored image. And a control means for controlling roll and pitch movement of the model motorcycle in accordance with the operation and movement of a passenger on the model motorcycle, wherein the control means includes: Provide a function to control the video signal so that the displayed video is changed according to the simulated running state of the model motorcycle, and rotate the video in the direction opposite to the roll direction as the roll angle of the body of the model motorcycle increases. Since the display device is controlled so as to cause the occupant to sense the roll motion of the vehicle body at the time of cornering, etc. and the sense of turning thereof, the passenger can be realistically sensed. It has the effect of being able to.

[Brief description of the drawings]

1 is a side view of a motorcycle riding simulation apparatus according to an embodiment of the present invention, FIG. 2 is a view of the apparatus of the present invention viewed from the rear, and FIG. 3 is a plan view of the apparatus of the present invention with a model motorcycle removed. FIG. 4 is a perspective view of a support frame portion,
5 and 13 are diagrams showing various operations of the device of the present invention,
6 is a system block diagram of the present invention, FIG. 7 is a diagram showing yaw, roll, and pitch operations of the model motorcycle, FIGS. 8 and 10 are flowcharts showing calculation processing performed by the minicomputer, 9 and 12 are diagrams showing image control according to the present invention, and FIG. 11 is a graph showing a relationship between a rotation sensor of roll motion and a vehicle speed. 1 ... Base, 1a ... Guide rail, 2 ... Movable table, 6 ...
… Movable device, 8… lift frame, 11… support frame, 12… rolling shaft, 13… model motorcycle, 21-26 …… various sensors,
31,32 …… Speaker, 33 …… Display device, 40 ……
Mini computer.

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Keigo Yoshida 1-4-1, Chuo, Wako-shi, Saitama Prefecture Honda Technical Research Institute Co., Ltd. (56) References JP-A-61-154689 (JP, A) (58) Field surveyed (Int.Cl. ⁶ , DB name) G09B 9/058 G09B 9/05 G09B 9/04 A63F 9/22

Claims (4)

(57) [Claims] 1. A model motorcycle that can be operated by a human being on board.
A display device disposed in front of the model motorcycle and displaying a pre-stored image, and control means for controlling roll and pitch movement of the model motorcycle according to the operation and movement of a passenger on the model motorcycle. In the motorcycle riding simulation device comprising: the control means is provided with a function of controlling an image signal so as to change an image displayed on the display device according to a simulated traveling state of the model motorcycle; A riding simulation device for a motorcycle, wherein the display device is controlled to rotate an image in a direction opposite to the roll direction according to an increase in a roll angle of the vehicle body. 2. The video signal to the display device is controlled so that when the body of the model motorcycle is rolled while tilted, the video is also moved in the pitch direction according to the roll angle. Item 2. A motorcycle simulation device according to item 1. 3. A motorcycle riding simulation apparatus according to claim 1, wherein an image signal to said display device is controlled so as to move the image in a pitch direction according to a simulated acceleration of said model motorcycle. 4. The display according to claim 1, wherein when the model motorcycle is rolled, the actual roll angle of the vehicle body is within a predetermined angle range. A riding simulation apparatus for a motorcycle, wherein a video signal to the apparatus is controlled.