JPH09282599A - Travel controller for vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To discriminate the normality/abnormality of travel data for a device for following up a preceding vehicle by controlling the travel of a present vehicle based on the travel data transmitted from the preceding vehicle. SOLUTION: The travel data such as car speed, acceleration/deceleration and steering angle are transmitted from an oscillator 12 on a preceding vehicle 10. The travel data are received by a receiver 22 on a following vehicle 20 and supplied to a vehicle control computer 26. The vehicle control computer 26 estimates the car speed of the preceding vehicle from a change with the passage of time (relative speed) in the distance to the preceding vehicle 10 detected by an inter-car distance sensor 24 and the speed of the present vehicle and compares the result with the travel data. When both values match, the travel data are normal but when these values do not match, the travel data are discriminated as abnormal.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle drive control device, and more particularly to a control device for traveling following a preceding vehicle.

[0002]

2. Description of the Related Art Conventionally, there has been proposed a device for following a vehicle while maintaining a vehicle-to-vehicle distance from a preceding vehicle for the purpose of reducing a driving operation of a vehicle driver.

For example, Japanese Laid-Open Patent Publication No. 5-170008 discloses a system that detects the following distance from a preceding vehicle and follows the preceding vehicle so that the following distance is a predetermined value.
A technique is disclosed in which traveling data such as vehicle speed, acceleration, and gear position is received from a preceding vehicle, and the traveling of the own vehicle is controlled based on the received data.

[0004]

However, when some trouble occurs in the transmission system of the preceding vehicle and the accuracy of the traveling data is lowered, it is not always appropriate to follow the traveling data based on the traveling data. There was a problem that drivability was reduced because the vehicle did not run. For example, in the case where the inter-vehicle distance to the preceding vehicle is controlled to be a predetermined inter-vehicle distance, and the own vehicle speed is controlled to match the vehicle speed data transmitted from the preceding vehicle with the speed of the own vehicle (that is, the following vehicle). It is assumed that the vehicle speed data transmitted from the preceding vehicle shows a value higher than the actual vehicle speed of the preceding vehicle. In this case, the control device of the own vehicle accelerates to match the vehicle speed of the preceding vehicle with the own vehicle speed, while the actual vehicle speed of the preceding vehicle is smaller than that. It decreases, and this time shifts to deceleration control. As described above, when the traveling data of the preceding vehicle is different from the actual traveling state, there is a problem that the own vehicle repeats acceleration and deceleration, the tracking control is not stabilized, and the riding comfort is reduced as a result.

The present invention has been made in view of the above problems of the prior art, and an object of the present invention is to reliably judge whether or not the traveling data transmitted from the preceding vehicle is normal, and thereby to detect the traveling data based on the received traveling data. It is another object of the present invention to provide a vehicle travel control device capable of preventing a reduction in drivability by appropriately stopping the travel control.

[0006]

In order to achieve the above object, a first invention is a vehicular travel control device for controlling travel of an own vehicle by receiving travel data transmitted from a preceding vehicle. , Estimating means for estimating the traveling state of the preceding vehicle independently of the traveling data, and determining whether or not to follow the preceding vehicle based on the difference between the estimated traveling state and the traveling state indicated by the traveling data. It is characterized by having a judging means.

Note that "independently of the traveling data" means that the received traveling data is not used, and the traveling data of the preceding vehicle is based on other data which is guaranteed to be a normal value. Means to compute. And
If the calculated and estimated data and the received travel data match within a predetermined allowable range, it can be determined that the travel data transmitted by the preceding vehicle is normal, and if they do not match, it is abnormal. Can be determined.

A second aspect of the invention is the vehicle control system of the first aspect of the invention, further comprising an inter-vehicle distance detecting means for detecting an inter-vehicle distance between the preceding vehicle and the host vehicle, wherein the estimating means detects the detected inter-vehicle distance data. The running state of the preceding vehicle is estimated based on the above.

The inter-vehicle distance data can be acquired by the inter-vehicle distance detecting means of the own vehicle without depending on the transmission data from the preceding vehicle, and the traveling state of the preceding vehicle can be estimated by calculation from the inter-vehicle distance data. For example, the time change of the inter-vehicle data indicates the relative speed between the preceding vehicle and the own vehicle, and the vehicle speed of the preceding vehicle can be estimated in combination with the own vehicle speed.

A third aspect of the invention is based on the first aspect of the invention, further has a receiving means for receiving the information transmitted from the information communication means provided on the roadside, and the estimating means is based on the received information. And estimating the traveling state of the preceding vehicle.

When the information transmitting means outputs the traveling instruction information to each vehicle and each vehicle is traveling in accordance with the instruction information, the instruction information itself can be used for estimating the traveling of the preceding vehicle. . If information about the shape of the road is output instead of the driving instruction information,
Since the preceding vehicle should also travel according to the running shape, this running shape information can also be used for estimation.

A fourth aspect of the invention is a vehicle traveling control device for controlling the traveling of the vehicle by receiving the traveling data transmitted from the preceding vehicle and the information transmitted from the information communication means provided on the roadside. And an inter-vehicle distance detecting means for detecting an inter-vehicle distance between the preceding vehicle and the own vehicle, a first estimating means for estimating a traveling state of the preceding vehicle based on the detected inter-vehicle distance data, and the information communication means. Between the second estimating means for estimating the traveling state of the preceding vehicle based on the information from the vehicle, the difference between the two traveling states estimated by the first and second estimating means, and the traveling state indicated by the traveling data. It is characterized by having a judging means for judging the presence or absence and the type of abnormality of the preceding vehicle based on the above, and a controlling means for controlling the traveling of the own vehicle according to the judgment result by the judging means.

That is, in the fourth aspect of the invention, the traveling state of the preceding vehicle is estimated by three methods. The first is the traveling data transmitted from the preceding vehicle, the second is the traveling state estimated from the inter-vehicle distance data, and the third is the traveling state based on the information from the information communication means. When an abnormality occurs in either the communication system or the traveling system of the preceding vehicle, the traveling data does not match the traveling state of the preceding vehicle indicated by the information from the information communication means. On the other hand, when the traveling system of the preceding vehicle is normal and the vehicle is traveling normally based on the information from the information communication means, the traveling state of the preceding vehicle indicated by the information and the traveling state estimated from the inter-vehicle distance data match. If there is an abnormality in the traveling system of the preceding vehicle and the vehicle is not traveling based on the information from the information communication means, the two do not match.
As described above, the results of the above three estimation methods differ depending on the cause of the abnormality of the preceding vehicle. Based on this difference, the cause of the abnormality of the preceding vehicle, specifically, for example, a communication system abnormality or traveling It is possible to determine whether the system is abnormal.

[0014]

Embodiments of the present invention will be described below with reference to the drawings.

<First Embodiment> FIG. 1 shows a block diagram of the present embodiment. The preceding vehicle 10 is provided with a transmitter 12 and transmits the traveling data of the own vehicle to the following vehicle. An infrared light emitter or the like can be used as the transmitter 12. Further, as the traveling data, the vehicle ID of the own vehicle, the vehicle speed, the acceleration, the steering angle, the traveling mode (automatic / manual), and the like are transmitted. On the other hand, the following vehicle 20 that is the following vehicle is
A receiver 22 that receives the traveling data transmitted from 0 and an inter-vehicle distance sensor 24 that detects the inter-vehicle distance with the preceding vehicle 10.
Is provided. As the inter-vehicle distance sensor 24, a radar such as laser light, infrared rays, radio waves, a camera, or the like can be used. The traveling data of the preceding vehicle 10 received by the receiver 22 and the inter-vehicle distance data with the preceding vehicle 10 detected by the inter-vehicle distance sensor 24 are supplied to the vehicle control computer 26. The vehicle control computer 26 includes a microprocessor, a memory, and an input / output interface, and determines the speed and acceleration of the vehicle based on the input data. In the present embodiment, the own vehicle is driven at the same speed as the vehicle speed of the preceding vehicle 10, and the acceleration of the own vehicle is determined so that the inter-vehicle distance from the preceding vehicle 10 is maintained at a constant value. In particular,

## EQU1 ## gt = gf + k1. (Lf-Lt) + k2. (Vf-V0) (1) where gt: target acceleration / deceleration gf: preceding vehicle acceleration / deceleration k1, k2: control gain Lf: inter-vehicle distance Lt: Target inter-vehicle distance Vf: Preceding vehicle speed V0: Own vehicle speed. The preceding vehicle acceleration / deceleration gf and the preceding vehicle speed Vf are data supplied from the receiver 22, that is, the data transmitted from the preceding vehicle 10 as traveling data, and the inter-vehicle distance Lf is supplied from the inter-vehicle distance sensor 24 of the own vehicle. Is. Then, the control amount required to drive the vehicle at the calculated target acceleration / deceleration gt is output to the actuator 28. The actuator 28 includes a steering actuator, a throttle actuator and a brake actuator.

Further, a roadside communication device 100 is arranged on the roadside, and transmits traveling instruction data such as speed and data such as curvature and gradient of the roadway to each vehicle. Roadside communication device 10
The information from 0 is received by the vehicle-mounted communication device 30 and supplied to the vehicle control computer 26. Vehicle control computer 2
6 is the target acceleration / deceleration gt of the own vehicle based on the above equation (1).
On the other hand, the traveling state of the preceding vehicle 10 is estimated independently of the traveling data transmitted from the preceding vehicle and compared with the received traveling data. The running state of the preceding vehicle is estimated based on the inter-vehicle distance data detected by the inter-vehicle distance sensor 24 or the information transmitted from the roadside communication device 100.
However, in the present embodiment, a case will be described in which the estimation is performed based on the inter-vehicle distance data detected by the inter-vehicle distance sensor 24.

The inter-vehicle distance data detected by the inter-vehicle distance sensor 24 is sequentially output to the vehicle control computer 26. The vehicle control computer 26 sequentially stores the input inter-vehicle distance data in the memory and calculates the change over time.
Since this time change indicates the relative speed with respect to the preceding vehicle, combining with the own vehicle speed V0,

## EQU2 ## The vehicle speed of the preceding vehicle can be estimated by Vf (estimation) = V0 + dLf / dt (2). Further, when the time change of the relative speed is calculated, this indicates the relative acceleration with respect to the preceding vehicle. Therefore, in combination with the own vehicle acceleration / deceleration g0,

## EQU3 ## By gf ^{(estimated) = g0 + d 2 Lf /} dt 2 ··· (3) can be estimated deceleration of the preceding vehicle. As can be seen from the calculation process, this estimated value is based only on the physical quantity that can be detected by the host vehicle, and therefore, as long as the detection sensor mounted on the host vehicle is normal, it indicates the true traveling state of the preceding vehicle. Therefore, by comparing the vehicle speed and acceleration / deceleration of the preceding vehicle thus estimated with the traveling data of the preceding vehicle received by the receiver 22, it is possible to determine whether the traveling data is normal or abnormal.

FIG. 2 shows a flow chart of a normal / abnormal determination process executed based on the basic idea described above and a process based on the determination result. First, the receiver 22 receives the traveling data transmitted from the preceding vehicle 10 and extracts the vehicle speed Vf and the acceleration / deceleration gf from the traveling data (S101). Next, the vehicle speed V0 and acceleration / deceleration g0
And the inter-vehicle distance Lf between the own vehicle and the preceding vehicle is detected (S10).
2, S103). And based on these data,
The vehicle speed Vf of the preceding vehicle is calculated using the above equations (2) and (3).
(Estimate) and acceleration / deceleration gf (estimate) of the preceding vehicle are estimated (S
104). After estimating the vehicle speed and the acceleration / deceleration of the preceding vehicle by calculation, it is determined whether the estimated vehicle speed and the estimated acceleration / deceleration match the vehicle speed and the acceleration / deceleration indicated by the travel data (S).
105, S106). Specifically, the predetermined allowable values Vth and gth are set, and the difference between the estimated vehicle speed and the traveling data Vf-
If the absolute value of Vf (estimation) is less than the vehicle speed allowable value Vth,
And the difference between the acceleration / deceleration estimated value and the traveling data gf-gf
If the absolute value of (estimation) is equal to or less than the acceleration / deceleration allowable value gth, the estimated value and the traveling data match and it is determined that the vehicle is normal. When it is determined that the traveling data is normal, the follow-up control is permitted (S107), and the follow-up control based on the above equation (1) is executed (S108).

On the other hand, when the absolute value of the difference between the estimated value and the travel data is larger than the allowable value, the two do not match and it is determined that the travel data is abnormal. When it is determined that the traveling data is abnormal, the follow-up control based on the equation (1) is prohibited (S109). This can reliably prevent the control from becoming unstable.

When the follow-up control is prohibited in S109, it is possible to arbitrarily determine what control the follower vehicle 20 performs. For example, (A) the follow-up control itself is stopped and the mode is changed to the manual running mode. (B) The follow-up running is performed based on the information transmitted from the roadside communication device 100 without adopting the running data from the preceding vehicle 10. That is, the preceding vehicle speed Vf and the preceding vehicle acceleration / deceleration gf in the equation (1) are replaced with the information from the roadside communication device 100 to perform follow-up control. (C) The offset error included in the traveling data is calculated from the difference between the estimated value and the traveling data. For example, it is possible to perform follow-up control based on the equation (1) by using the corrected vehicle speed correction acceleration / deceleration obtained by calculating and correcting this offset error from the traveling data. Whichever method is used, the follow-up control that directly uses the traveling data transmitted from the preceding vehicle 10 is stopped, so that instability of the control can be prevented and traveling with high drivability can be maintained.

In this embodiment, the vehicle speed and the acceleration / deceleration are estimated, and the estimated values are compared with the traveling data to judge whether the traveling data is normal or abnormal. It may be compared with the data, or only the acceleration / deceleration may be estimated and compared with the travel data.

Further, in this embodiment, since the inter-vehicle distance data with the preceding vehicle is used to estimate the traveling state of the preceding vehicle, it is premised that the inter-vehicle distance data is normal. Therefore, it goes without saying that it is necessary to secure the reliability of the inter-vehicle distance data itself in advance, and it may be preferable to configure the inter-vehicle distance sensor with a redundant system of a radar and a camera in order to improve the reliability.

<Second Embodiment> In the above-described first embodiment, the running state of the preceding vehicle is estimated based on the inter-vehicle distance data detected by the inter-vehicle distance sensor of the host vehicle. A case where the traveling state of the preceding vehicle is estimated based on the information from 100 will be described.

The configuration of this embodiment is the same as that shown in FIG. Then, the information transmitted from the roadside communication device 100 is received by the vehicle-mounted communication device 30 of the following vehicle 20 and supplied to the vehicle control computer 26. Roadside communication device 10
From 0, instruction information of speed and acceleration / deceleration for each vehicle,
Alternatively, the track shape data such as the curvature and gradient of the track is transmitted. Therefore, the vehicle control computer 26 determines that the preceding vehicle 1
0 is also regarded as controlling the traveling based on these information, and the traveling state of the preceding vehicle is estimated based on this information.

For example, when the vehicle speed instruction is transmitted from the roadside communication device 100 to each vehicle so as to travel at the vehicle speed Vt, it is assumed that the preceding vehicle 10 is also traveling at the vehicle speed Vt according to this instruction. And the estimated vehicle speed V of the preceding vehicle
f (estimate) is Vt. Therefore, the vehicle speed data Vf and Vt included in the travel data transmitted from the preceding vehicle 10 are compared, and if they match within a predetermined allowable range, it can be determined that the travel data is normal. Can be determined to be abnormal.

When the roadside communication device 100 transmits the curvature data at each point on the road to each vehicle, the preceding vehicle 10 is determined from the curvature data at each point and the inter-vehicle distance data between the preceding vehicle 10. The curvature data of the running point will be known. Therefore, the vehicle speed Vf of the preceding vehicle 10
The steering angle θf (estimated) of the preceding vehicle is estimated from (equal to the instructed vehicle speed Vt transmitted from the roadside communication device 100), and this θf
By comparing (inference) with the steering angle data θf included in the traveling data transmitted from the preceding vehicle 10, it is possible to determine whether the traveling data is normal or abnormal. The specific method for estimating the steering angle is

Equation 4] .theta.f ^{(estimation) = (c1 -c2 / Vt 2} ) / R ··· (4) where, c1, c2: coefficient R: may be used curve radius.

FIG. 3 shows a flow chart of a normal / abnormal determination process executed based on the basic idea described above and a process based on the determination result. First, the vehicle speed instruction data and the road shape data are received from the roadside communication device 100. The designated vehicle speed is Vt, and the road shape data is the curve radius R (S201). However, the curve radius R is the curve radius at the point where the preceding vehicle 10 is traveling, and the curve radius data (or curvature data) for each point transmitted from the roadside communication device 100 is converted into the inter-vehicle distance data with the preceding vehicle. It is the data selected based on this. After acquiring the vehicle speed Vt (estimated to be equal to the actual vehicle speed of the preceding vehicle) and the curve radius R, next, traveling data is received from the preceding vehicle 10 (S202). The traveling data received is the vehicle speed data Vf.
And steering angle data θf. Then, according to the equation (4), the steering angle of the preceding vehicle 10 is estimated based on the Vt and R acquired in S201 (S203). The preceding vehicle 10 estimated based on the vehicle speed data Vf transmitted from the preceding vehicle, the steering angle data θf, and the information from the road surface transmitter 100.
After the vehicle speed Vf (estimation) = Vt and the steering angle θf (estimation) are obtained, these are compared with each other (S204, S205).
Specifically, when the predetermined allowable values Vth2 and θth are set and the absolute value of the difference Vf-Vt between the estimated vehicle speed value and the travel data is less than or equal to the allowable vehicle speed value Vth2, and the difference between the estimated steering angle value and the travel data. When the absolute value of gf-gf (estimation) is equal to or smaller than the steering angle allowable value θth, the estimated value and the traveling data match and it is determined that the vehicle is normal. When it is determined that the traveling data is normal, the follow-up control is permitted (S2
06), follow-up control is executed (S207).

On the other hand, when the absolute value of the difference between the estimated value and the travel data is larger than the allowable value, the two do not match and it is determined that the travel data is abnormal. Then, when it is determined that the traveling data is abnormal, the follow-up control is prohibited (S208). This can reliably prevent the control from becoming unstable.

When the follow-up control is prohibited in S208, what control the follower vehicle 20 performs can be arbitrarily determined as in the first embodiment.

Further, in the present embodiment, the vehicle speed and the steering angle are estimated, and the estimated values are compared with the traveling data to judge whether the traveling data is normal or abnormal. However, of course, only the vehicle speed or the steering angle is determined. You may estimate and compare with driving data.

<Third Embodiment> In the second embodiment,
The steering angle of the preceding vehicle 10 is estimated based on the information from the roadside communication device 100, and whether the traveling data from the preceding vehicle matches the steering angle is judged to be normal / abnormal. It is also possible to determine whether the traveling data is normal / abnormal from the steering angle data of the preceding vehicle without using the information from the communication device 100. That is, when the following vehicle (own vehicle) 20 travels on the same traveling locus as the preceding vehicle 10, the steering angle of the preceding vehicle 10 and the following vehicle 2 when traveling on a certain curved road
The steering angles of 0 should match. Therefore, the steering angle data transmitted from the preceding vehicle is compared with the steering angle of the own vehicle when the following vehicle 20 reaches the curved road where the preceding vehicle transmits the steering angle data. The travel data from 10 can be determined to be normal. Of course, in order to make this determination, it is necessary to accurately detect the point at which the preceding vehicle 10 transmitted the traveling data, but the inter-vehicle distance data with the preceding vehicle 10 when the traveling data is received by the receiver 22 is Since it can be detected by the inter-vehicle distance sensor 24, the point can be easily recognized.

FIG. 4 shows a flow chart of a normal / abnormal determination process executed based on the basic idea described above and a process based on the determination result. First, the steering angle data θf is received from the preceding vehicle 10 (S301).
Then, the inter-vehicle distance data Lf and the own vehicle speed V0 at this time
Then, the time t0 until the preceding vehicle 10 reaches the point where the steering angle data is transmitted is calculated (S302). After calculating the time t0, the timer is operated to determine whether or not the time t0 has elapsed (S303). When the time t0 elapses, that is, when the own vehicle, which is the following vehicle 20, reaches the position of the preceding vehicle 10 that has transmitted the traveling data, the steering angle θ of the own vehicle and the steering of the preceding vehicle at that time The angle data θf are compared (S304). This steering angle θ (self) of the own vehicle corresponds to, so to speak, θf (estimation) of the second embodiment, and when the absolute value of the difference between the two is less than or equal to the predetermined allowable value θth, the estimated value And the traveling data match, and it can be determined to be normal. When it is determined that the traveling data is normal, the follow-up control is executed (S305). On the other hand, when the absolute value of the difference between the estimated value and the travel data is larger than the allowable value, the two do not match, so that it is determined that the travel data is abnormal and the follow-up control is prohibited (S306).

Also in this embodiment, since the traveling state of the preceding vehicle is estimated independently of the traveling data and compared with the traveling data, the normality / abnormality of the traveling data is surely determined to make the control unstable. Can be prevented.

<Fourth Embodiment> In the above-described first to third embodiments, whether the traveling data is normal or abnormal is determined, but even if the traveling data is abnormal, the cause of the abnormality is not detected. . In other words, whether the transmission data is abnormal due to an abnormality in the transmission system of the preceding vehicle 10, or the transmission data is abnormal because the transmission system itself is normal but the traveling system of the preceding vehicle 10 has a problem. Can't be identified. Therefore, if an abnormality occurs in the traveling data due to an abnormality in the traveling system itself of the preceding vehicle 10, for example, a mode in which the traveling data from the preceding vehicle is corrected and the following vehicle is followed is set. If selected, control of the vehicle may become unstable again.

Therefore, in the present embodiment, a case will be described in which, in addition to the normality / abnormality determination of the first to third embodiments, the cause of the abnormality is also recognized and the control is switched to more appropriate control.

The configuration of this embodiment is similar to that of FIG. 1, and the vehicle control computer 26 is supplied with the vehicle speed data Vf transmitted from the preceding vehicle 10 and the instruction vehicle speed Vt transmitted from the roadside communication device 100. It Then, the vehicle control computer 26 compares the vehicle speed data Vf with the instructed vehicle speed Vt, and compares the vehicle speed Vf (estimated) of the preceding vehicle estimated using the equation (2) of the first embodiment with the instructed vehicle speed Vt. . That is,

[Equation 5] | Vf −Vt |> Vth3 (5)

[Equation 6] | Vf (estimate) -Vt |> Vth4 (6) It is determined whether or not it is satisfied. However, Vth3 and Vth4 are predetermined allowable threshold values. Of the above two inequalities,
In the case of (5), if the travel data is abnormal regardless of the communication system and the travel system, the threshold value is exceeded, but in the case of (6), the communication system is abnormal and the preceding vehicle 10 itself gives an instruction. Vehicle speed Vt
If the vehicle is traveling normally in accordance with the above, the threshold value is below the threshold value. become. This is because Vf (estimation) is calculated from the inter-vehicle distance data with respect to the preceding vehicle 10 as can be seen from the equation (2), and therefore the threshold value is set only when the preceding vehicle 10 is not traveling according to the instructed vehicle speed Vt. This is because the value exceeds the value.
It is assumed that you are traveling according to).

In summary, when the expressions (5) and (6) are both satisfied: Abnormality in the traveling system When the expression (5) is satisfied but the expression (6) is not satisfied: An abnormality in the communication system is caused. , The vehicle control computer 26 (5)
By determining whether equation (6) and equation (6) are established or not, it is possible to discriminate whether the abnormality is caused by the communication system of the preceding vehicle 10 or the traveling system itself when the abnormality occurs in the traveling data. It becomes possible to do.

When the above algorithm determines that an abnormality has occurred in the traveling data transmitted due to an abnormality in the communication system, the vehicle control computer 26 determines which of (A) to (C) in the first embodiment. I moved to that mode,
When it is determined that the traveling data has an abnormality due to an abnormality in the traveling system, (C) is not appropriate, and therefore the mode may be shifted to either (A) or (B). Of course, it may be possible to notify the roadside communication device 100 of the abnormality of the preceding vehicle 10 by using the in-vehicle communication device 30 and to notify the preceding vehicle 10 of the abnormality of the communication system or the traveling system.

As described above, in this embodiment, the follower vehicle 20
Since it is possible to perform abnormality diagnosis of the preceding vehicle 10, it is possible to further enhance safety when a plurality of vehicles travel in a single stage (platoon travel).

[0040]

As described above, according to the present invention, it is surely determined whether or not the traveling data transmitted from the preceding vehicle is normal, and thereby the traveling control based on the received traveling data is appropriately stopped. It is possible to prevent a decrease in drivability.

[Brief description of drawings]

FIG. 1 is a configuration diagram of an embodiment of the present invention.

FIG. 2 is a processing flowchart of the first embodiment.

FIG. 3 is a processing flowchart of a second embodiment.

FIG. 4 is a processing flowchart of a third embodiment.

[Explanation of symbols]

10 preceding vehicle, 12 oscillator, 20 following vehicle (own vehicle),
22 receiver, 24 inter-vehicle distance sensor, 26 vehicle control computer, 28 actuator, 30 vehicle-mounted communication device,
100 Roadside communication device.

Claims (4)

[Claims] 1. A travel control device for a vehicle, which receives travel data transmitted from a preceding vehicle to control the travel of the own vehicle, wherein the estimation is for estimating a traveling state of a following vehicle independent of the travel data. A vehicle travel control device comprising: means for determining whether or not to follow the preceding vehicle based on a difference between the estimated travel state and the travel state indicated by the travel data. 2. An inter-vehicle distance detecting means for detecting an inter-vehicle distance between the preceding vehicle and the own vehicle is further provided, and the estimating means estimates the traveling state of the preceding vehicle based on the detected inter-vehicle distance data. The traveling control device for a vehicle according to claim 1, wherein: 3. A receiving means for receiving information transmitted from an information communication means provided on a road side, wherein the estimating means estimates the traveling state of the preceding vehicle based on the received information. The vehicle traveling control device according to claim 1, wherein the vehicle traveling control device is a vehicle traveling control device. 4. A vehicle traveling control device for controlling traveling of an own vehicle by receiving traveling data transmitted from a preceding vehicle and information transmitted from an information communication means provided on a roadside, wherein the preceding vehicle An inter-vehicle distance detecting means for detecting an inter-vehicle distance between the vehicle and the host vehicle; a first estimating means for estimating a traveling state of the preceding vehicle based on the detected inter-vehicle distance data; Second estimating means for estimating the traveling state of the preceding vehicle, and the preceding vehicle based on the difference between the two traveling states estimated by the first and second estimating means and the traveling state indicated by the traveling data. And a control unit for controlling the traveling of the host vehicle according to the determination result of the determination unit.