JP3928277B2 - Preceding vehicle selection device, inter-vehicle control device, inter-vehicle alarm device, and recording medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a device for selecting a preceding vehicle to be subjected to inter-vehicle control or inter-vehicle warning, an inter-vehicle control device or inter-vehicle alarm device provided with the preceding vehicle selecting device, and a recording medium.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, as a technique for improving driving safety of a vehicle and reducing a driver's operation burden, an inter-vehicle distance control device that automatically follows a host vehicle to a preceding vehicle is known. There is also known an inter-vehicle warning device that informs the driver when the vehicle is too close to the preceding vehicle. In order to configure these inter-vehicle distance control devices and inter-vehicle distance alarm devices, it is necessary to have a device for selecting a preceding vehicle to be subjected to inter-vehicle distance control or inter-vehicle alarm.
[0003]
Conventionally, a laser radar device has been used as such a device. However, if the direction of the laser beam emitted from the laser radar is fixed, it is not possible to irradiate the lane far away while driving on a curve, and it travels in other lanes in addition to the roadside signs and reflectors. The detected vehicle may be detected as a preceding vehicle. As a solution to this problem, a scanning laser radar that scans a laser beam within a predetermined range has been proposed. When the preceding vehicle is selected using this scan type laser radar, the detected lateral position of the vehicle (horizontal position orthogonal to the traveling direction of the host vehicle) is used.
[0004]
Japanese Patent Application Laid-Open No. 10-205366 discloses a technique that uses the lateral speed of the preceding vehicle to determine whether or not there is an interrupting vehicle with respect to the own vehicle. This calculates the horizontal relative speed of the interrupting vehicle, calculates the time it takes for the interrupting vehicle to reach the host vehicle travel path (front of the host vehicle) from this lateral relative speed, and this time and the time when it reaches the host vehicle travel path. The presence / absence of an interrupt is determined from the inter-vehicle distance. In other words, judging from the lateral position at the time of detection, the vehicle is not on the own lane, but considering the lateral speed, in the future, it is determined that the vehicle is assumed to be in front of the own vehicle as an interrupted vehicle. So, it is to improve the response.
[0005]
[Problems to be solved by the invention]
However, the “method for determining the presence or absence of an interrupting vehicle relative to the host vehicle” described in JP-A-10-205366 has the following problems. For example, if your vehicle is traveling in the central lane of a road with three lanes, the preceding vehicle that was traveling in the right lane of your vehicle passes the central lane (that is, your lane) and lanes to the left lane of your vehicle. Consider the changing situation. In this situation, the preceding vehicle will eventually move to the left lane and deviate from its own lane, so it should not be subject to inter-vehicle distance control. The time to reach the front of the vehicle is calculated, and it is determined that the vehicle is the preceding vehicle to be controlled. Therefore, unnecessary deceleration control or the like occurs.
[0006]
In addition, from the viewpoint of selecting a preceding vehicle, there are several situations that should be taken into consideration in addition to such an interrupted vehicle.
For example, (1) Considering the case where the preceding vehicle changes lanes or turns left and right and goes out of the own lane, the selection as the preceding vehicle is canceled after the preceding vehicle leaves the lane. It becomes. (2) Considering the case where the vehicle goes out of the lane to change the lane for overtaking or to avoid the preceding vehicle turning left or right, the preceding vehicle on the original lane is After leaving the own lane, the selection as the preceding vehicle is canceled.
[0007]
In the case of (1) and (2), these are caused by the lane change of the preceding vehicle or the own vehicle. This leads to an unnecessary increase in processing load. In addition to an increase in processing load, for example, if inter-vehicle control or inter-vehicle warning is performed for a vehicle that will not be a preceding vehicle in the future, anxiety may be felt by the driver and other passengers in the vehicle. There is also the possibility of giving a sense of incongruity.
[0008]
Further, (3) when the own vehicle changes lanes, the preceding vehicle on the adjacent lane is not selected unless the own vehicle enters the lane to which the lane is changed (for example, the adjacent lane). That is, the selection as the preceding vehicle is delayed even if it is caused by a change in the lane of the own vehicle rather than dealing with the interrupted vehicle as in the prior art. The delay in the selection as the preceding vehicle leads to a delay in the timing of the inter-vehicle control and inter-vehicle warning that is performed for the selected preceding vehicle, and again, the driver and other passengers of the vehicle are anxious. And may give a sense of incongruity.
[0009]
In view of the above, an object of the present invention is to release a selection as a preceding vehicle at an early stage and to make sure that a preceding vehicle to be truly selected can be selected.
[0029]
[Means for Solving the Problems]
  Of the present inventionPredecessor selection deviceAccording toThe object recognition means calculates the relative position and relative speed of the recognition target object with respect to the own vehicle. Based on the relative position of the object calculated by the object recognition means, the selection means determines whether or not the object is in the own lane area defined with reference to the traveling direction of the own vehicle, and the determination result Based on this, the preceding vehicle is selected with respect to the own vehicle.
[0030]
  The object recognition means can also calculate the lateral movement speed, which is the relative speed of the object in the lateral direction orthogonal to the traveling direction of the host vehicle.. AndChoiceThe stage isThe size of the own lane area is corrected based on the current lateral position and the lateral movement speed that are the current lateral position, and the preceding vehicle selection process is performed based on the changed own lane area.
[0031]
  Regarding the change of the size of the own lane area, for example, claims2As shown in the figure, when an object goes out of the lane area, the lane area is narrowed by an amount expected to move laterally outside the lane area, while the object is outside the lane area. When entering the area from the road, it is conceivable to widen the own lane area by the amount predicted to move laterally inside the area.
[0032]
  ThislikeifIn addition, it is no longer necessary to select a preceding vehicle even if it does not become a preceding vehicle in the future, and an unnecessary increase in processing load is prevented. In addition, a vehicle that will be a preceding vehicle in the future can be selected at an early stage, and a delay in execution timing can be prevented when used for inter-vehicle control or inter-vehicle warning. These lead to reduction or elimination of the anxiety and discomfort that the passengers of the vehicle have when used for inter-vehicle control and inter-vehicle warnings.
[0033]
In addition, the function which implement | achieves the selection means in such a preceding vehicle selection apparatus with a computer system can be provided as a program started on the computer system side, for example. In the case of such a program, for example, the program is recorded on a computer-readable recording medium such as a floppy disk, a magneto-optical disk, a CD-ROM, or a hard disk, and is used by being loaded into a computer system and started up as necessary. it can. In addition, the ROM or backup RAM may be recorded as a computer-readable recording medium, and the ROM or backup RAM may be incorporated into a computer system and used.
[0034]
  By the way, when it implement | achieves as an apparatus which performs distance control for the preceding vehicle selected by the preceding vehicle selection apparatus mentioned above, for example, a claim3The configuration shown in FIG. That is, claim 1Or 2The preceding vehicle selection device described above, acceleration means and deceleration means for accelerating and decelerating the host vehicle, and an actual inter-vehicle physical quantity that is a physical quantity corresponding to the distance between the preceding vehicle and the host vehicle selected by the preceding vehicle selection device; Driving and controlling the acceleration means and the deceleration means based on the inter-vehicle deviation, which is the difference between the target inter-vehicle physical quantity that is the physical quantity corresponding to the target inter-vehicle distance between the own vehicle and the preceding vehicle, and the relative speed between the own vehicle and the preceding vehicle. Accordingly, the vehicle distance control means for causing the host vehicle to travel following the preceding vehicle is provided. With this inter-vehicle distance control device, inter-vehicle distance control for items that will not become the preceding vehicle in the future is not executed, and an unnecessary increase in processing load can be prevented. In addition, since a vehicle that will be a preceding vehicle in the future can be selected at an early stage and the delay in the execution timing of the inter-vehicle control can be prevented, it is possible to reduce or eliminate the sense of anxiety and discomfort that the occupant has.
[0035]
As the actual inter-vehicle physical quantity, for example, when a configuration is adopted in which the time until the preceding vehicle is irradiated with a laser beam or a transmission wave and the reflected light or reflected wave is received is detected. As such, a value converted into an inter-vehicle distance may be used, or an inter-vehicle time divided by the vehicle speed may be used.
[0036]
  In addition to such inter-vehicle distance control function,4As shown in FIG. 5, the physical inter-vehicle physical quantity, which is a physical quantity corresponding to the actual inter-vehicle distance between the host vehicle and the preceding vehicle, is based on a predetermined alarm judgment value set based on at least the relative speed between the host vehicle and the preceding vehicle. It may be determined whether or not the vehicle physical quantity has become smaller, and when the actual inter-vehicle physical quantity becomes smaller than the alarm determination value, an inter-vehicle alarm means capable of executing an alarm process for the vehicle driver may be provided. By doing so, it is possible to prevent delays in the execution timing of the inter-vehicle control and inter-vehicle alarm. Further, an inter-vehicle warning is not executed for a vehicle that will not become a preceding vehicle in the future, and an unnecessary increase in processing load can be prevented. Further, not executing an unnecessary inter-vehicle warning can also prevent “dilution of an alarm effect due to unnecessary alarm execution”.
[0037]
  On the other hand, it is not premised on having an inter-vehicle distance control function, and can be realized as an inter-vehicle alarm device. That is, the claim5As shown in FIG.Or 2The preceding vehicle selection device described above, acceleration means and deceleration means for accelerating and decelerating the host vehicle, and a physical quantity between the actual vehicles, which is a physical quantity corresponding to the distance between the preceding vehicle and the host vehicle selected by the preceding vehicle selection device, It is determined whether or not the predetermined alarm judgment value set based on at least the relative speed between the host vehicle and the preceding vehicle has become smaller, and if the actual inter-vehicle physical quantity becomes smaller than the alarm judgment value, An inter-vehicle alarm device comprising inter-vehicle alarm means capable of executing an alarm process. With this inter-vehicle warning device, an inter-vehicle warning is not executed for a vehicle that will not become a preceding vehicle in the future, and an unnecessary increase in processing load can be prevented. Further, not executing an unnecessary inter-vehicle warning can also prevent “dilution of an alarm effect due to unnecessary alarm execution”. In addition, since a vehicle that will be a preceding vehicle in the future can be selected at an early stage and the delay in the execution timing of the inter-vehicle control can be prevented, it is possible to reduce or eliminate the sense of anxiety and discomfort that the occupant has.
[0038]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments to which the present invention is applied will be described below with reference to the drawings. Needless to say, the embodiments of the present invention are not limited to the following examples, and can take various forms as long as they belong to the technical scope of the present invention.
[0039]
FIG. 1 shows an electronic control device 2 for controlling distance between vehicles (hereinafter referred to as “vehicle distance control ECU”) and an electronic brake control device 4 (hereinafter referred to as “brake ECU”) as an embodiment to which the above-described invention is applied. It is a block diagram showing the schematic structure of the various control circuits mounted in the motor vehicle shown centering around.
[0040]
The inter-vehicle control ECU 2 is an electronic circuit mainly composed of a microcomputer, and includes a current vehicle speed (Vn) signal, a steering angle (str-eng, S0) signal, a yaw rate signal, a target inter-vehicle time signal, wiper switch information, idle Control state signals for control and brake control are received from the engine electronic control unit 6 (hereinafter referred to as “engine ECU”). Then, the inter-vehicle distance control ECU 2 estimates a curve curvature radius R or performs an inter-vehicle distance control calculation based on the received data.
[0041]
The laser radar sensor 3 is an electronic circuit mainly composed of a laser scanning range finder and a microcomputer. The angle and relative speed of the preceding vehicle detected by the scanning range finder and the inter-vehicle distance control ECU 2 Based on the received current vehicle speed (Vn) signal, curve curvature radius R, etc., the vehicle lane probability of the preceding vehicle is calculated as a part of the function of the inter-vehicle control device, and the preceding vehicle information including information such as relative speed is It transmits to control ECU2. The diagnostic signal of the laser radar sensor 3 itself is also transmitted to the inter-vehicle control ECU 2.
[0042]
The scanning distance measuring device scans and radiates a transmission wave or laser light within a predetermined angle range in the vehicle width direction, and based on the reflected wave or reflected light from the object, the distance between the vehicle and the front object is a scan angle. It is possible to detect corresponding to.
Further, the inter-vehicle control ECU 2 determines the preceding vehicle to be subjected to the inter-vehicle distance control based on the own lane probability included in the preceding vehicle information received from the laser radar sensor 3 as described above, and appropriately determines the inter-vehicle distance from the preceding vehicle. A target acceleration signal, a fuel cut request signal, an OD cut request signal, a third speed downshift request signal, and a brake request signal are transmitted to the engine ECU 6 as control command values for adjustment to Further, it determines whether an alarm has occurred and transmits an alarm sound request signal or transmits an alarm sound release request signal. Further, a diagnosis signal, a display data signal, and the like are transmitted. The inter-vehicle distance control ECU 2 corresponds to selection means, straight path conversion means, inter-vehicle distance control means, and inter-vehicle alarm means.
[0043]
The brake ECU 4 is an electronic circuit mainly composed of a microcomputer, and includes a steering sensor 8 as a steering angle detection means for detecting a steering angle of the vehicle, a yaw rate sensor 10 for detecting a yaw rate as a vehicle turning detection means, and each A steering hydraulic pressure and a yaw rate are obtained from a wheel speed sensor 12 that detects the speed of the wheel, and these data are transmitted to the inter-vehicle distance control ECU 2 via the engine ECU 6 and are provided in the brake hydraulic circuit for controlling the braking force. A brake actuator 25 that controls the opening / closing of the pressure increase control valve / pressure reduction control valve is controlled. The brake ECU 4 sounds the alarm buzzer 14 in response to an alarm request signal from the inter-vehicle control ECU 2 via the engine ECU 6. Therefore, the brake ECU 4 and the alarm buzzer 14 correspond to an inter-vehicle alarm means.
[0044]
The engine ECU 6 is an electronic circuit mainly composed of a microcomputer, and includes a throttle opening sensor 15, a vehicle speed sensor 16 as vehicle speed detection means for detecting vehicle speed, a brake switch 18 for detecting whether or not the brake is depressed, The cruise control switch 20 corresponding to the “start switch”, the cruise main switch 22 corresponding to the “preparation switch”, and the wiper switch information and tail switch information received via the detection signal from the other sensors and switches or the body LAN 28 In addition, a steering angle (str-eng, S0) signal and a yaw rate signal from the brake ECU 4, or a target acceleration signal, a fuel cut request signal, an OD cut request signal, a third speed shift down request signal from the inter-vehicle control ECU 2, Alert request No., diagnosis signal, which receives display data signals and the like.
[0045]
The engine ECU 6 adjusts the throttle actuator 24 for adjusting the throttle opening of the internal combustion engine (in this case, the gasoline engine) as the drive means according to the operating state determined from the received signal, and the actuator drive stage of the transmission 26. In response to this, a drive command is output. With these actuators, it is possible to control the output, braking force or shift shift of the internal combustion engine. The transmission 26 in this embodiment is a 5-speed automatic transmission, the 4-speed reduction ratio is set to “1”, and the 5-speed reduction ratio is smaller than the 4-speed (for example, 0.7). The so-called 4-speed + overdrive (OD) configuration is set. Therefore, when the above-described OD cut request signal is issued, if the transmission 26 is shifted to the fifth speed (that is, the overdrive shift position), it is shifted down to the fourth speed. When a downshift request signal is issued, the transmission 26 is shifted down to the third speed if the transmission 26 is shifted to the fourth speed. As a result, a large engine brake is generated by these downshifts, and the vehicle is decelerated by the engine brake.
[0046]
Further, the engine ECU 6 transmits necessary display information to a display device (not shown) such as an LCD provided in the dashboard via the body LAN 28 for display or displays the current vehicle speed (Vn). ) Signal, steering angle (str-eng, S0) signal, yaw rate signal, target inter-vehicle time signal, wiper switch information signal, idle control and brake control state signals are transmitted to the inter-vehicle control ECU 2.
[0047]
In this embodiment, the engine ECU 6 corresponds to “acceleration means”, and the engine ECU 6 and the brake ECU 4 correspond to “deceleration means”.
Next, the preceding vehicle selection process performed by the laser radar sensor 3 will be described.
FIG. 2 shows the entire process of selecting a preceding vehicle.
[0048]
When the processing is started, first, distance / angle measurement data by a scanning distance measuring device provided in the laser radar sensor 3 is read (S800). Next, a forward obstacle recognition process is performed (S900).
In this forward obstacle recognition processing, the forward object recognition type, the object width W, the object center position XY coordinates, and the relative speed Vr are obtained based on the current vehicle speed Vn and the result of scanning the object ahead. The recognition type can be recognized as a moving object when, for example, the relative position of the object has hardly moved despite the host vehicle traveling. Also, an object that gradually moves away can be recognized as a moving object. When the relative position of the object approaches the host vehicle at the same speed (absolute value) as the current vehicle speed Vn, it can be recognized as a stopped object. Other objects, such as an object that has not been recognized for a long time since it appears, are recognized as unknown objects. Note that the front obstacle recognition process itself is well known to those skilled in the art.
[0049]
After the front obstacle is thus recognized, each process of lateral position own lane determination (S1000), lateral movement own lane determination (S2000), and integrated own lane determination (S3000) is performed. Hereinafter, it demonstrates in order.
In the lateral position own lane determination process (S1000) shown in FIG. 3, first the own vehicle route is calculated (S1100). In this own vehicle route calculation, first, the center position / object width data (X0, Y0, W0) of all objects obtained in the forward obstacle recognition process (S900) is converted into a straight route. That is, based on the curve curvature radius R received from the inter-vehicle distance control ECU 2, the coordinates of the object when the curve is a straight path are obtained. The conversion is performed by converting the coordinates according to the following equations 1-3.
[0050]
X ← X0− (Y0 ^ 2 / 2R) [Formula 1]
Y ← Y0 ... [Formula 2]
W ← W0 ... [Formula 3]
In other words, here, only the X coordinate is substantially converted.
[0051]
In subsequent S1200, the own lane region is set. For example, an area of 5 m on the left and right and 100 m on the front is set based on the own vehicle. The “own lane area” means the area of the own vehicle width or the own vehicle width + the margin (personal space) with respect to the traveling direction of the own vehicle, and is separated by a white line on the road. It is not necessarily the same as the lane width given.
[0052]
By the processing of S1100 and S1200, for example, as shown in FIG. 20 (A), the own lane region assuming the own vehicle course on a curve is converted into the own lane region as shown in FIG. 20 (B). This own lane area is an area used for the selection process of the preceding vehicle. In this way, for example, the positional relationship of the preceding vehicle can be easily grasped by the coordinate position by setting the vehicle width direction as the X axis (xR) and the vehicle traveling direction as the Y axis (yR) with the own vehicle as the origin. can do.
[0053]
In step S1300, the position of the object that is a candidate for the preceding vehicle is collated with the own lane area, and the own lane determination based on the lateral position is performed. Specifically, based on the current object position (X, Y) and the object width W, it is determined whether at least a part of the object exists in the own lane region.
[0054]
With this, the lateral position own lane determination ends, and the process proceeds to S2000 to perform lateral movement own lane determination.
The lateral movement own lane determination process (S2000) shown in FIG. 4 is a determination performed based on the current lateral position, the lateral position expected after a predetermined time (predicted lateral position), and the lateral movement speed. There are four situations (A) to (D) shown below in this determination.
(A) Present in the own lane and stay in the own lane after a predetermined time.
(B) Currently in the own lane, but moves out of the own lane after a predetermined time and does not exist in the own lane.
(C) Present outside the own lane, stays outside the own lane after a predetermined time, and does not exist within the own lane.
(D) Presently outside the own lane, but moves into the own lane after a predetermined time and does not exist in the own lane.
[0055]
Therefore, it is determined whether the predicted lateral position is outside the own lane or inside the own lane by lateral movement.
[Outside lane judgment]
Whether or not the predicted lateral position is out of its own lane due to lateral movement is determined in S2100 for the amount of movement to the right lane, and in S2200 is determined for the amount of movement to the left lane. In addition, the processing for the movement to the right lane in S2100 is performed by setting / resetting the right lateral movement own lane outside flag based on whether the predetermined condition is satisfied or not, and the movement to the left lane in S2200. The processing sets / resets the left lateral movement own lane flag based on whether or not a predetermined condition is met.
[0056]
The conditions used for the determination in S2100 and S2200 are as follows.
(A-11) The lateral movement speed is outward and the absolute value is equal to or greater than a predetermined value (in this case, the outer side and the inner side mean the direction with respect to the center of the own lane. The same applies hereinafter).
(A-12) The current lateral position is the same as the outward direction at the time of (a-11) determination, and the absolute value is equal to or greater than a predetermined value.
(A-13) The predicted lateral position is the same as the outward direction at the time of (a-11) determination, and the absolute value is equal to or greater than a predetermined value.
(A-21) Lateral speed is not the same as the outward direction at the time of (a-11) determination
(A-22) The current lateral position is the same as the outward direction at the time of (a-11) determination
(A-23) If the predicted lateral position is in the same direction as the outward direction at the time of (a-11) determination, the absolute value is equal to or less than the predetermined value, or all cases where the absolute value is not the same direction
(A-24) The current lateral position is not the same as the outward direction at the time of (a-11) determination
Of these, FIG. 12A illustrates the physical meaning of the determination conditions (a-11), (a-12), and (a-13).
[0057]
In the determination of the amount of movement to the right lane in the lateral movement own vehicle lane determination shown in FIG. 5, in the case of all positive determinations in S2110, S2120, and S2130, that is, the above-described conditions (a-11) and (a-12) , (A-13) is set only when the right lateral movement own lane flag is set (S2140). On the other hand, if a negative determination is made in any of S2110, S2120, and S2130, the process proceeds to S2150. If all the determinations in S2150, S2160, and S2170 are affirmative, that is, if all of the above conditions (a-21), (a-22), and (a-23) are satisfied, the right lateral movement own lane flag is not set. Is reset (S2180). Even if a negative determination is made in any of S2150, S2160, and S2170, or a positive determination is made in S2190, that is, only the condition (a-24) is satisfied, the right lateral movement own lane flag is reset. (S2180).
[0058]
The same processing is performed in the determination of the amount of movement to the left lane in the lateral movement own lane determination shown in FIG. That is, the right lateral movement off-lane flag is only determined when all of the determinations at S2210, S2220, and S2230 are affirmative, that is, when the above-described conditions (a-11), (a-12), and (a-13) are all satisfied. Is set (S2240). On the other hand, if all the determinations in S2250, S2260, and S2270 are affirmative, that is, if the above-described conditions (a-21), (a-22), and (a-23) are all satisfied, affirmative determination is made in S2290, that is, the condition ( The right lateral movement own lane flag is reset in any of cases where only a-24) is established (S2280).
[0059]
[In-lane judgment]
Whether or not the predicted lateral position is within the own lane due to lateral movement is determined in S2300 for the amount of movement from the right lane, and in S2400, the amount of movement from the left lane is determined. The processing for the movement from the right lane in S2300 is performed by setting / resetting the flag in the right lateral movement own lane based on whether the predetermined condition is satisfied or not, and the movement from the left lane in S2400. The processing sets / resets the left lateral movement own lane flag based on whether a predetermined condition is satisfied or not.
[0060]
The conditions used for the determination in S2300 and S2400 are as follows.
(B-11) The lateral movement speed is inward, and the absolute value is equal to or greater than a predetermined value.
(B-12) If the current lateral position is in the same direction as the inward direction at the time of (b-11) determination, the absolute value is equal to or less than the predetermined value, or all cases are not applicable
(B-13) If the predicted lateral position is in the same direction as the inward direction at the time of (b-11) determination, the absolute value is equal to or less than the predetermined value, or all cases where the absolute value is not the same direction
(B-21) The lateral speed is not the same as the inner direction at the time of (b-11) determination.
(B-22) The current lateral position is not the same as the inner direction at the time of (b-11) determination.
(B-23) The predicted lateral position is not the same sign as the inner direction at the time of (b-11) determination, and the absolute value is equal to or greater than a predetermined value.
(B-24) The current horizontal position is the same as the inner direction at the time of (b-11) determination
Of these, FIG. 12B illustrates the physical meaning of the determination conditions (b-11), (b-12), and (b-13).
[0061]
In the determination of the amount of movement from the right lane in the lateral movement own lane determination shown in FIG. 7, in the case of all positive determinations in S2310, S2320, S2330, that is, the above-described conditions (b-11) and (b-12) , (B-13) is set only when the right side lateral movement own lane flag is set (S2340). On the other hand, if a negative determination is made in any of S2310, S2320, and S2330, the process proceeds to S2350. If all of the determinations in S2350, S2360, and S2370 are affirmative, that is, if all of the above-described conditions (b-21), (b-22), and (b-23) are satisfied, the right lateral movement own lane flag Is reset (S2380). Even if a negative determination is made in any of S2350, S2360, and S2370, or a positive determination is made in S2390, that is, only the condition (b-24) is satisfied, the right lateral movement own lane flag is reset. (S2380).
[0062]
Similar processing is also performed in the determination of the amount of movement from the left lane in the lateral movement own lane determination shown in FIG. That is, the right lateral movement own lane flag is only determined when all of the determinations at S2410, S2420, and S2430 are affirmative, that is, when the above-described conditions (b-11), (b-12), and (b-13) are all satisfied. Is set (S2440). On the other hand, if S2450, S2460, S2470 are all affirmative, that is, if the above-described conditions (b-21), (b-22), and (b-23) are all satisfied, or S2490 is affirmative, that is, the condition ( The right lateral movement own lane flag is reset in any of cases where only b-24) is established (S2480).
[0063]
When the lateral movement own lane determination (S2000) is completed in this way, the process proceeds to the integrated own lane determination in FIG. 3000.
In the integrated own lane determination, as shown in detail in FIG. 9, first, based on the determination result of the lateral position own lane determination (see S1000), it is determined whether or not the vehicle is in the own lane (S3100), and is in the own lane. In this case (S3100: YES), it is determined whether or not the right lateral movement own lane flag is set in S3200, and whether or not the left lateral movement own lane flag is set in S3300, and both flags are set. If not (S3200: NO, S3300: NO), it is determined that the vehicle is in the own lane (S3400). If at least one of both flags is set, it is determined that the vehicle is out of the own lane (S3500).
[0064]
On the other hand, if it is determined that the vehicle is outside the own lane based on the determination result based on the lateral position (S3100: NO), whether or not the right lateral movement own lane flag is set in S3600, and in the left lateral movement own lane in S3700. It is determined whether or not the flag is set. If both flags are not set (S3600: NO, S3700: NO), it is determined that the vehicle is outside the own lane (S3800). If at least one of both flags is set, it is determined that the vehicle is in the own lane (S3900).
[0065]
These are summarized as follows.
▲ 1 ▼ [Inside own lane AND (Reset right side movement outside lane flag AND Reset left side movement outside lane flag)]
→ Judged as in the own lane
▲ 2 ▼ [Current in-lane AND (Right lateral movement own lane flag set OR Left lateral movement own lane flag set)]
→ Judge as out of lane
(3) [Outside current lane AND (Right side movement own lane flag reset AND Left side movement own lane flag reset)]
→ Judge as out of lane
▲ 4 ▼ In the case of [Outside current lane AND (Right side lateral movement own lane flag set OR Left side lateral movement own lane flag set)]
→ Judged as in the own lane
In this way, it is determined whether an object that can be a candidate for the preceding vehicle is in the own lane or outside the own lane, and only those determined to be “in the own lane” are selected as the preceding vehicle. Information about the selected preceding vehicle (preceding vehicle information) is transmitted from the laser radar sensor 3 to the inter-vehicle distance control ECU 2. The inter-vehicle control ECU 2 receives the preceding vehicle information and executes an inter-vehicle control process.
[0066]
FIG. 10 is a flowchart showing the entire inter-vehicle distance control process.
First, in the first step S110, it is determined whether the current control is being performed. If the current control is not currently being performed (S110: NO), it is determined whether the control start switch has been set (S140). If the cruise control switch 20 is turned on, the control start switch is set. If the control start switch is not set (S140: NO), the process proceeds to S600, the acceleration / deceleration device non-control output is executed, and further, the alarm sounding stop (S700) is executed, and then the main The process ends. Details of the acceleration / deceleration device non-control output process in S600 will be described later.
[0067]
Further, when the control is not being performed (S110: NO) and the control start switch is set (S140: YES), the process proceeds to S130.
In S130, it is determined whether the control end switch is set. If the cruise control switch 20 is turned off, the control end switch is set. If the control end switch is set (S130: YES), the process proceeds to S600 to execute the output at the time of non-control of the acceleration / deceleration device, and further stop the alarm blower (S700), and then end the main process. To do.
[0068]
If the control end switch is not set (S130: NO), the target vehicle distance is calculated (S150), and then the target acceleration calculation (S200), acceleration / deceleration control (S300), and acceleration / deceleration device drive output (S400). After executing each process relating to the inter-vehicle distance control, and further executing an alarm determination and alarm output process (S500), the main process is terminated.
[0069]
The above is the description of the entire processing, and then the processing contents of S200 to S700 will be described in detail.
First, the target acceleration calculation subroutine in S200 will be described with reference to the flowchart of FIG.
[0070]
In the first step S201, it is determined whether or not the preceding vehicle is being recognized. If the preceding vehicle is not being recognized (S201: NO), the value when the preceding vehicle has not been confirmed is set as the target acceleration (S205), and this subroutine is terminated.
On the other hand, if the preceding vehicle is being recognized (S201: YES), the process proceeds to S202 and the inter-vehicle deviation is calculated. This inter-vehicle deviation is obtained by subtracting the target inter-vehicle distance from the current inter-vehicle interval.
[0071]
In step S203, the relative speed is calculated. In step S204, the target acceleration is obtained by referring to the control map based on both parameters of the inter-vehicle deviation and the relative speed respectively obtained in steps S202 and S203. Thereafter, this subroutine is terminated.
Next, the acceleration / deceleration control in S300 of FIG. 10 will be described. This acceleration / deceleration control is terminated by sequentially performing throttle control, accelerator-off control, shift-down control, and brake control. Each control will be described.
[0072]
First, in throttle control, the value obtained by multiplying the acceleration deviation by the throttle control gain K11 is added to the previous throttle opening instruction value to obtain the current throttle opening instruction value. The acceleration deviation is a value obtained by subtracting the target acceleration from the actual acceleration.
[0073]
Further, in the case of the accelerator off control, it is determined whether or not the acceleration deviation is smaller than a predetermined reference value Aref11. If the acceleration deviation <Aref11, the accelerator off operation is instructed. On the other hand, if acceleration deviation ≧ Aref11, it is determined whether the acceleration deviation is larger than the reference value Aref12. If acceleration deviation> Aref12, the accelerator off operation cancellation is instructed, but if acceleration deviation ≦ Aref12, nothing is instructed.
[0074]
In the case of the shift down control, it is determined whether the acceleration deviation is smaller than the reference value Aref21. If the acceleration deviation is smaller than Aref21, the shift down operation is instructed, and the accelerator off operation is instructed. On the other hand, if acceleration deviation ≧ Aref21, it is determined whether the acceleration deviation is larger than the reference value Aref22. If acceleration deviation> Aref22, an instruction to cancel the downshift operation is issued. If acceleration deviation ≦ Aref22, nothing is instructed.
[0075]
Next, brake control will be described. First, it is determined whether the acceleration deviation is smaller than the reference value Aref31. If acceleration deviation <Aref31, the brake operation is instructed, and the accelerator-off operation is instructed. If the brake operation instruction is being issued, the value obtained by multiplying the acceleration deviation by the throttle control gain K21 is added to the previous brake pressure instruction value to obtain the current brake pressure instruction value. The brake pressure command value is set to 0.
[0076]
On the other hand, if acceleration deviation ≧ Aref31, it is determined whether or not the acceleration deviation is larger than the reference value Aref32. If acceleration deviation> Aref32, an instruction to release the brake is given, but if acceleration deviation ≦ Aref32, no instruction to release the brake is given. If the brake operation instruction is being issued, the value obtained by multiplying the acceleration deviation by the throttle control gain K21 is added to the previous brake pressure instruction value to obtain the current brake pressure instruction value. The brake pressure command value is set to 0.
[0077]
Next, the acceleration / deceleration device drive output in S400 of FIG. 10 will be described.
First, it is determined whether or not an accelerator-off operation instruction has been issued. If an accelerator-off operation instruction has not been issued, the drive output for releasing the brake, the drive output for releasing the downshift, and the feedback of the throttle opening The drive output is sequentially performed, and then this process is terminated.
[0078]
On the other hand, if the accelerator-off operation instruction is given, it is determined whether or not a shift-down action instruction is given. If the downshift operation instruction has not been issued, it is determined whether or not the brake operation instruction has been issued. If the brake operation instruction has not been issued, a drive output for releasing the brake, a drive output for releasing the downshift, and a drive output for fully closing the throttle are sequentially performed, and then this process is terminated. If a brake operation instruction has been issued, a drive output for fully closing the throttle, a drive output for releasing the downshift, and a feedback drive output for the brake pressure are sequentially performed, and then this process is terminated.
[0079]
On the other hand, if there is an accelerator-off operation instruction and a shift-down operation instruction, it is determined whether or not a brake operation instruction has been issued. If the brake operation instruction has not been issued, the drive output for releasing the brake, the drive output for fully closing the throttle, and the shift-down drive output are sequentially performed, and then this process is terminated. If a brake operation instruction has been issued, a drive output for fully closing the throttle, a shift-down drive output, and a feedback drive output of the brake pressure are sequentially performed, and then this process is terminated.
[0080]
Next, the acceleration / deceleration device non-control output in S1100 will be described.
Since this process is a process when the acceleration / deceleration device is not controlled, the drive output for fully closing the throttle, the drive output for releasing the downshift, and the drive output for releasing the brake are sequentially performed. The process ends.
[0081]
Next, alarm determination and alarm device output processing in S900 of FIG. 2 will be described.
First, it is determined whether the target acceleration is shorter than a predetermined alarm determination value Aref41. If target acceleration <alarm determination value Aref41, the alarm device (alarm buzzer 14) is sounded. On the other hand, if the target acceleration ≧ the alarm determination value Aref41, the alarm sounding is stopped.
[0082]
As described above, according to the system of the present embodiment, the following measures are taken with respect to selection of the preceding vehicle to be subjected to the inter-vehicle control and inter-vehicle alarm (selection start / deselection, etc.). In other words, when the current lateral position exists in the own lane area but the predicted lateral position exists outside the own lane area, the selection as the preceding vehicle is canceled. In addition, when the current lateral position is in the own lane area and the predicted lateral position is also in the own lane area, the selection as the preceding vehicle is continued. If the current lateral position is outside the own lane area and the predicted lateral position is also within the own lane area, selection as a preceding vehicle is started. Further, when the current lateral position is outside the own lane area and the predicted lateral position is also outside the own lane area, the vehicle is not selected as the preceding vehicle.
[0083]
By taking the predicted lateral position into account in this way, an appropriate preceding vehicle can be selected in various situations, and an appropriate inter-vehicle control or inter-vehicle warning can be obtained.
This will be specifically described with reference to FIGS.
[Situation where the preceding vehicle leaves the lane after changing lanes]
FIG. 13A shows a case where the preceding vehicle is selected only in the lateral position in this situation. When the preceding vehicle changes its lane to the rampway while decelerating, since the preceding vehicle is the preceding vehicle subject to inter-vehicle control, the host vehicle also decelerates as the preceding vehicle decelerates. Then, since the preceding vehicle selection is canceled after the preceding vehicle has changed to the lane for ramp-away, the deceleration control is canceled and the acceleration control is resumed. In other words, as a result, it is not necessary to decelerate the preceding vehicle whose lane is to be changed, but in reality it decelerates, so it can be used for the feeling of the passengers including the driver of the vehicle. It will not fit.
[0084]
On the other hand, if the predicted lateral position is also taken into account by using the lateral position and the lateral movement speed together as in the case of the present embodiment, as shown in FIG. The selection as a preceding vehicle can be canceled at an early stage, and the host vehicle can be smoothly accelerated to the set vehicle speed without the deceleration control. As a result, it is no longer necessary to select a preceding vehicle that will not become a preceding vehicle in the future, and an unnecessary increase in processing load can be prevented. In addition, it is possible to prevent inter-vehicle control for a vehicle that will not be a preceding vehicle in the future, and to reduce or eliminate the anxiety and discomfort that the driver and other passengers of the vehicle have. Of course, the same applies to the inter-vehicle warning.
[0085]
[Situation where the vehicle changes lanes for overtaking]
FIG. 14A shows a case where the preceding vehicle is selected only in the lateral position in this situation. Since the preceding vehicle is traveling at a low speed, when the vehicle changes lanes in order to overtake the preceding vehicle, the preceding vehicle selection is canceled for the previous preceding vehicle after the vehicle has left the lane, Until then, it will not accelerate. Therefore, the overtaking operation is delayed.
[0086]
On the other hand, if the predicted lateral position is also taken into account by using the lateral position and the lateral movement speed together as in the case of the present embodiment, as shown in FIG. 14 (B), the own vehicle is out of the own lane. Even if the vehicle does not exist, the preceding vehicle selection is canceled by the behavior of the host vehicle trying to change lanes. Therefore, acceleration can be started before going out of the own lane, and overtaking can be performed smoothly.
[0087]
[Situation where the preceding vehicle enters the own lane by interrupting from the adjacent lane]
FIG. 15A shows a case where the preceding vehicle is selected only in the lateral position in this situation. If a low-speed vehicle traveling in the adjacent lane has interrupted, it will be selected as the preceding vehicle when the interrupted vehicle enters the own lane, so the vehicle will start deceleration control for the first time at that time. . For this reason, a situation in which the vehicle is too close to the preceding vehicle is likely to occur, and the occupant of the vehicle has a sense of anxiety.
[0088]
On the other hand, if the predicted lateral position is also taken into account by using the lateral position and the lateral movement speed together as in the case of the present embodiment, the interrupt vehicle enters the own lane as shown in FIG. Even when it is not, it can be selected as a preceding vehicle (early). Therefore, since deceleration control can be started before the interrupted vehicle enters the own lane and an appropriate distance can be maintained, it is possible to prevent the passenger of the own vehicle from feeling uneasy.
[0089]
[Situation where own vehicle cuts into adjacent lane]
FIG. 16A shows a case where the preceding vehicle is selected only in the lateral position in this situation. When the vehicle is entering the adjacent lane, the vehicle must start deceleration control for the first time at that point in order to select the vehicle traveling in front of that lane as the preceding vehicle. It becomes. For this reason, a situation in which the vehicle is too close to the preceding vehicle is likely to occur, and the occupant of the vehicle has a sense of anxiety.
[0090]
On the other hand, if the predicted lateral position is also taken into account by using the lateral position and the lateral movement speed together as in the case of the present embodiment, as shown in FIG. 16 (B), the own vehicle has entered the adjacent lane. Even when there is no time (early), a vehicle traveling in front of the lane (adjacent lane) can be selected as the preceding vehicle. For this reason, deceleration control is started before the vehicle enters the adjacent lane, and appropriate distance can be maintained when entering the adjacent lane, preventing the passengers of the vehicle from feeling uneasy. it can.
[0091]
These are described in the example of the inter-vehicle control, but the same applies to the inter-vehicle alarm.
Although it is basic to select the preceding vehicle based on the current lateral position and the predicted lateral position as described above, the following measures are taken to make a more appropriate selection.
(A) The above-described conditions (a-11) and (b-11) are conditions indicating that the absolute value of the lateral movement speed is equal to or greater than a predetermined value. When this condition is not satisfied, the selection as a preceding vehicle is not started or canceled. For example, the lateral movement speed is obtained by differentiating the lateral position, but measurement noise is likely to occur due to the differential operation. Therefore, it is possible to suppress execution of unnecessary preceding vehicle selection processing due to such noise.
[0092]
(B) The condition (a-12) described above is a condition for determining whether or not the vehicle stays in the own lane area for a predetermined time or more. When the predicted lateral position is outside the own lane area, the selection as the preceding vehicle is not canceled when the vehicle has not stayed in the own lane area for a predetermined time or longer.
[0093]
This takes into consideration that even if the predicted lateral position exists outside the own lane region, there is actually a case where the predicted lateral position will remain within the own lane region in the future. For example, a situation is assumed in which a lane is rapidly changed from the lane on the left side of the own vehicle to the own lane on a road having three or more lanes. In this situation, as shown in FIG. 17 (A), not only when changing to the right lane of the vehicle at a stretch, but also changing to the lane as shown in FIG. 17 (B) and traveling on the lane for a while. Then, the lane may be changed to the right lane. When traveling on the own lane, the lateral movement speed will also gradually decrease. However, if the lane change at a high speed toward the own lane is grasped instantaneously, the lane of the lane will be uniform. It is predicted that the lane will change to the right lane.
[0094]
However, as shown in FIG. 17 (B), the vehicle passes from the left lane to the own lane as shown in FIG. 17 (A), rather than changing to the right lane after driving once on the own lane. In the case where the lane is changed to the right lane, the time spent in the own lane area is shortened. Focusing on this point, in the situation considered to reflect the behavior when changing the lane from the adjacent lane to the own lane, the preceding vehicle selection is not excessively canceled. Therefore, a more appropriate preceding vehicle selection process can be executed.
[0095]
(C) The condition (b-12) described above is a condition for determining whether or not the vehicle stays outside the own lane area for a predetermined time or more. If the vehicle has not stayed in the lane adjacent to the lane area for a predetermined time or longer, the selection as the preceding vehicle is not started even if the predicted lateral position exists in the lane area. ing.
[0096]
This takes into account that even if the predicted lateral position exists within the own lane region, in reality, there may be cases where the predicted lateral position will remain outside the own lane region in the future. For example, a situation is assumed in which a lane is rapidly changed from a lane adjacent to the own vehicle to a lane next to the vehicle on a road having three or more lanes. In this situation, not only the case where the vehicle eventually travels on the own lane as shown in FIG. 18 (A), but also the lane change to the lane next to the own lane as shown in FIG. 18 (B). Then, it may be possible to run for a while and then change lanes to the own lane. When traveling in the next lane, the lateral movement speed will gradually decrease, but the state where the lane is rapidly changed from the second lane to the next lane is instantaneous. If caught, it is predicted that the lane will be changed to the own lane.
[0097]
However, as shown in FIG. 18 (B), when the lane is changed from one adjacent lane to the own lane as shown in FIG. 18 (A), the lane is changed at a stretch from the next lane to the own lane. The person who stays in the lane next to the own lane area becomes shorter. Focusing on this point, in a situation that seems to reflect the behavior when changing lanes from two adjacent lanes to one adjacent lane, the preceding vehicle is not selected excessively. Therefore, a more appropriate preceding vehicle selection process can be executed.
[0098]
[Another embodiment]
In the case of the above embodiment, the concept of the predicted lateral position is introduced based on the lateral movement speed generated by the movement of the own vehicle or the preceding vehicle, and the preceding vehicle is selected based on the relationship between the predicted lateral position and the own lane area, etc. However, if the own lane area in that case is set in S1200 of FIG. 3, it is fixed thereafter. On the other hand, the direction of the own lane region can be corrected and dealt with. That is, in this other embodiment, the size of the own lane area is corrected based on the current lateral position and the lateral movement speed, and the preceding vehicle selection process is performed based on the corrected own lane area.
[0099]
As for the correction of the size of the own lane area, for example, when a vehicle subject to selection (start or release) of a preceding vehicle goes out of the own lane area, as shown in FIG. In addition, the lane area is narrowed by an amount that the object is expected to move laterally outside the area. On the other hand, when the vehicle enters the area from the outside of the own lane area, as shown in FIG. 19B, it is considered to widen the own lane area by the amount predicted to move laterally inside the area. It is done.
[0100]
Thus, the same effect as in the case of the first embodiment can also be obtained by enlarging / reducing the own lane region having the same meaning as considering the predicted lateral position. That is, it is no longer necessary to select a preceding vehicle that will not become a preceding vehicle in the future, and an unnecessary increase in processing load is prevented. In addition, a vehicle that will be a preceding vehicle in the future can be selected at an early stage, and a delay in execution timing can be prevented when used for inter-vehicle control or inter-vehicle warning. These lead to reduction or elimination of the anxiety and discomfort that the passengers of the vehicle have when used for inter-vehicle control and inter-vehicle warnings.
[0101]
[Others]
(1) Regarding the determination process of “whether or not it exists in the own lane area”, the probability of existing in the own lane area is calculated first, not the binary determination of whether or not it suddenly exists. It may be determined whether or not it exists based on the probability. Furthermore, instead of the binary determination of whether or not the vehicle exists in the own lane area, the possibility of existing may be determined step by step. In this case, for example, it is conceivable to calculate the probability of existing in the own lane area and determine the possibility of existing in stages based on the calculated probability. Note that a method for calculating the probability of existing in the own lane region is disclosed in, for example, Japanese Patent Laid-Open No. 8-27999.
[0102]
(2) In the above embodiment, the system is implemented as a system for executing the inter-vehicle control and the inter-vehicle alarm for the selected preceding vehicle, but may be a system that performs only the inter-vehicle control or only the inter-vehicle alarm. Furthermore, if it is a system which needs to select the preceding vehicle as a control object, the preceding vehicle selecting device can be applied to a system other than the inter-vehicle control and the inter-vehicle warning.
[0103]
(3) Although the inter-vehicle distance is used as it is as the “inter-vehicle physical quantity corresponding to the inter-vehicle distance” in the above embodiment, time is used as the inter-vehicle physical quantity, and the same control is executed with the detected real time and the target time. Alternatively, the same control may be executed for the actual inter-vehicle time and the target inter-vehicle time using inter-vehicle time (a value obtained by dividing the inter-vehicle distance by the vehicle speed of the host vehicle) as another inter-vehicle physical quantity. When the target inter-vehicle distance is made variable according to the vehicle speed and the target inter-vehicle distance is set almost in proportion to the vehicle speed, the target time or the target inter-vehicle time is adjusted instead of adjusting the target inter-vehicle distance. However, the same effect can be obtained.
[Brief description of the drawings]
FIG. 1 is a system block diagram of an inter-vehicle distance control apparatus according to an embodiment.
FIG. 2 is a flowchart showing an overall process for selecting a preceding vehicle.
FIG. 3 is a flowchart showing a subroutine for lateral position own lane determination executed during the entire preceding vehicle selection process.
FIG. 4 is a flowchart showing a subroutine of lateral movement own lane determination executed during the entire preceding vehicle selection process.
FIG. 5 is a flowchart showing a subroutine for a process for moving to the right lane in the lateral movement own lane out-of-side determination executed during the lateral movement own lane determination.
FIG. 6 is a flowchart showing a subroutine for a process of moving to the left lane in the lateral movement own lane determination performed during the lateral movement own lane determination.
FIG. 7 is a flowchart showing a subroutine for a process for moving from the right lane in the in-lateral movement own lane determination executed during the lateral movement own lane determination.
FIG. 8 is a flowchart showing a subroutine for processing for moving from the left lane in the lateral movement own lane determination executed during the lateral movement own lane determination.
FIG. 9 is a flowchart showing an integrated own lane determination subroutine executed during the preceding vehicle selection overall process.
FIG. 10 is a flowchart showing an overall process of inter-vehicle distance control.
FIG. 11 is a flowchart showing a subroutine for target acceleration calculation executed during inter-vehicle distance control.
FIG. 12 is an explanatory diagram of determination conditions used for selecting a preceding vehicle.
FIG. 13 is an explanatory diagram showing the contents of the preceding vehicle selection and inter-vehicle control in time series in a situation where the preceding vehicle changes lanes and leaves the own lane.
FIG. 14 is an explanatory diagram showing the contents of preceding vehicle selection and inter-vehicle control in a time series in a situation where the own vehicle changes lanes for overtaking.
FIG. 15 is an explanatory diagram showing the contents of the preceding vehicle selection and inter-vehicle control in time series in a situation where the preceding vehicle enters from the adjacent lane and enters the own lane.
FIG. 16 is an explanatory diagram showing the contents of the preceding vehicle selection and the inter-vehicle control in a time series in a situation where the own vehicle interrupts the adjacent lane.
FIG. 17 is an explanatory diagram showing a situation in which it is necessary not to cancel the selection of the preceding vehicle excessively.
FIG. 18 is an explanatory diagram showing a situation in which it is necessary not to select a preceding vehicle excessively.
FIG. 19 is an explanatory diagram of a method for correcting the own lane region in another embodiment.
FIG. 20 is an explanatory diagram showing a state where a lane area on a curve is converted into a lane area on a straight path.
[Explanation of symbols]
2 ... Electronic control device for inter-vehicle distance control 3 ... Laser radar sensor
4 ... Brake electronic control device 6 ... Engine electronic control device
8 ... Steering sensor 10 ... Yaw rate sensor
12 ... Wheel speed sensor 14 ... Alarm buzzer
15 ... Throttle opening sensor 16 ... Vehicle speed sensor
18 ... Brake switch 20 ... Cruise control switch
22 ... Cruise main switch 24 ... Throttle actuator
25 ... Brake actuator 26 ... Transmission
28 ... Body LAN

Claims (6)

Object recognition means for calculating the relative position and relative speed of the object to be recognized with respect to the vehicle;
Based on the relative position of the object calculated by the object recognition means, it is determined whether or not the object is present in the own lane region determined with reference to the traveling direction of the own vehicle, and based on the determination result A selection means for selecting a preceding vehicle relative to the own vehicle;
A preceding vehicle selection device comprising:
The object recognition means can also calculate a lateral movement speed, which is a relative speed of the object in a lateral direction orthogonal to the traveling direction of the own vehicle,
The selection means corrects the size of the own lane region based on the current lateral position that is the current lateral position and the lateral movement speed, and performs the preceding vehicle selection process based on the changed own lane region. To do the
The preceding vehicle selection device characterized by. In the preceding vehicle selection device according to claim 1,
The selection means narrows the lane area by an amount that is predicted to move laterally outside the area when the object goes out of the lane area, while the object When entering the area from outside the own lane area, widen the own lane area by the amount expected to move laterally inside the area ,
The preceding vehicle selection device characterized by. The preceding vehicle selection device according to claim 1 or 2 ,
Acceleration means and deceleration means for accelerating and decelerating the host vehicle;
An actual inter-vehicle physical quantity that is a physical quantity corresponding to the distance between the preceding vehicle and the own vehicle selected by the preceding vehicle selection device, and a target inter-vehicle physical quantity that is a physical quantity corresponding to the target inter-vehicle distance between the own vehicle and the preceding vehicle; A vehicle distance control means for driving the vehicle to follow the preceding vehicle by driving and controlling the acceleration means and the deceleration means based on the inter-vehicle deviation that is the difference between the vehicle and the relative speed between the own vehicle and the preceding vehicle;
A vehicle-to-vehicle control device comprising: In the inter-vehicle control apparatus according to claim 3,
further,
Judges whether the actual inter-vehicle physical quantity, which is the physical quantity equivalent to the actual inter-vehicle distance between the host vehicle and the preceding vehicle, has become smaller than a predetermined warning judgment value set based on at least the relative speed between the own vehicle and the preceding vehicle And, when the actual inter-vehicle physical quantity becomes smaller than the alarm determination value, comprising inter-vehicle alarm means capable of executing an alarm process for a vehicle driver,
An inter-vehicle control device characterized by the above. The preceding vehicle selection device according to claim 1 or 2,
Acceleration means and deceleration means for accelerating and decelerating the own vehicle, and an actual inter-vehicle physical quantity that is a physical quantity corresponding to the distance between the preceding vehicle and the own vehicle selected by the preceding vehicle selection device is at least the own vehicle and the preceding vehicle It can be determined whether or not the predetermined alarm judgment value set based on the relative speed of the vehicle has become smaller, and when the actual inter-vehicle physical quantity becomes smaller than the warning judgment value, the warning process for the vehicle driver can be executed. Vehicle-to-vehicle warning means,
A vehicle-to-vehicle alarm device comprising: The computer-readable recording medium which recorded the program for functioning a computer system as a selection means in the preceding vehicle selection apparatus of Claim 1 or 2.

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