JP3602959B2 - Vehicle group running control system - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a vehicle group travel control system that travels on an expressway or the like while forming a vehicle group.
[0002]
[Prior art]
On an expressway, a dedicated road for automobiles, or the like, it has been considered that the driving of a car is automated, and a group of vehicles is formed as a unit by a plurality of vehicles forming a so-called platoon. Automated driving and formation of a group of vehicles and running in platoon are expected to reduce labor and ease traffic.
[0003]
For example, Japanese Patent Application Laid-Open Nos. 8-314541 and 7-334790 exist as prior arts for forming a group of vehicles and performing platoon running. In the traveling control system disclosed in Japanese Patent Application Laid-Open No. 8-314541, if a merging vehicle is detected when a group of vehicles passes a merging point during platooning, the inter-vehicle distance is increased so that merging into the platoon is facilitated. To control. In addition, in the traveling control system disclosed in Japanese Patent Application Laid-Open No. H7-334790, a following vehicle that is traveling independently monitors the behavior of a preceding vehicle. Control is performed to increase the distance so that the merged vehicle can smoothly enter the preceding vehicle.
[0004]
[Problems to be solved by the invention]
When a group of vehicles travels in a running lane, for example, and a large number of vehicles join the group of vehicles at a junction, the length of the group of vehicles in the running lane increases. In such a case, if the traffic volume in the overtaking lane is small, the flow of traffic on the entire road becomes slow, and the vehicle cannot travel efficiently. Therefore, in order to perform efficient traveling, if the length of the platoon of the vehicle group is increased to some extent, these are treated as one vehicle group, and the vehicle travels with the lane changed from the traveling lane to the overtaking lane, for example. Is desired.
[0005]
However, the above prior arts all enable vehicles that join at a junction to easily join a vehicle group, and do not form a single vehicle group and perform efficient traveling. It has been desired to realize a travel control system for performing such travel.
[0006]
SUMMARY OF THE INVENTION An object of the present invention is to provide a vehicle group traveling control system capable of forming an appropriate group of vehicles and allowing the vehicle to travel efficiently.
[0007]
[Means for Solving the Problems]
The present invention is a vehicle group travel control system in which a vehicle group is formed by a plurality of vehicles, and travel control information is transmitted between the vehicles in the formed vehicle group, whereby the vehicle group travels in a predetermined platoon. hand,
Group formation determining means for determining whether a predetermined number of vehicles or a predetermined group length has been formed, and lane changing means for performing lane change of the vehicle group,
The group formation determining unit and the lane changing unit are mounted on at least a leading vehicle of the vehicle group,
When the vehicle group reaches the number of vehicles or a predetermined group length, the group formation determining unit generates a group formation signal, and the lane changing unit generates a lane change signal based on the group formation signal, and the lane change signal , The leading vehicle changes lanes from a specific lane to another lane different from the specific lane.
[0008]
According to the present invention, when the number of vehicles in the vehicle group reaches a predetermined number, or when the group length reaches a predetermined length, the lane changing means generates a lane change signal, whereby the leading vehicle of the vehicle group moves from the specific lane to another lane. The lane is changed to the lane No., and the following vehicle also changes lanes following the leading vehicle. Therefore, the length of the vehicle group does not become longer than the predetermined range, such a vehicle group travels as one group, and thus the traffic flow is smooth, and the vehicle can travel efficiently. .
[0009]
The present invention also provides a vehicle group travel control system in which a vehicle group is formed by a plurality of vehicles, and travel control information is transmitted between the vehicles in the formed vehicle group, whereby the vehicle group travels in a predetermined platoon. So,
Group formation determining means for determining whether or not a predetermined number of vehicles or a predetermined group length has been formed; and a determination of a branch junction which is one or both of a branch point and a junction of a road. It comprises a junction merging point determining means, and a lane changing means for changing the lane of the vehicle group,
The group formation determining means, the junction point determining means and the lane changing means are mounted on at least the leading vehicle of the vehicle group,
When the vehicle group reaches the number of vehicles or a predetermined group length, the group formation determining means generates a group formation signal, and when the vehicle group approaches the branch point, the branch point determination means outputs the branch point. A signal is generated, the lane changing means generates a lane change signal based on the group formation signal and the junction point signal, and the leading vehicle is different from the specific lane from a specific lane based on the lane change signal. The vehicle group traveling control system is characterized in that the lane is changed to the lane of the vehicle group.
[0010]
According to the present invention, when the number of vehicles in the vehicle group reaches a predetermined number, or when the group length reaches a predetermined length, the lane changing means generates a lane change signal at the junction and thereby the leading vehicle in the vehicle group Changes lanes from a specific lane to another lane, and the following vehicle also changes lanes following the leading vehicle. Therefore, the length of the vehicle group is adjusted at the junction point, such a vehicle group travels as one group, and thus the traffic flow is smooth, and the vehicle can travel efficiently.
[0011]
The present invention is also characterized in that the junction point determination means generates the junction point signal based on branch junction map information from map data of a navigation device mounted on the vehicle.
[0012]
According to the present invention, map data in a navigation device can be used as information on a junction.
[0013]
Further, the present invention is characterized in that the junction point determination means generates the junction point signal based on a road information signal from a road device provided along the road.
[0014]
According to the present invention, a road information signal from a road device can be used as information on a junction point.
[0015]
Further, according to the present invention, each vehicle of the vehicle group includes a transmission unit and a reception unit, and when the lane changing unit of the leading vehicle generates the lane change signal, the leading vehicle performs the lane change before the leading vehicle changes the lane. The lane change signal generated in the step (1) is transmitted from the transmitting means to the receiving means of the following vehicle.
[0016]
According to the present invention, before the leading vehicle of the vehicle group changes lanes, the vehicle change signal generated by the lane changing unit is transmitted to the following vehicle, so that the following vehicle associated with the lane change of the leading vehicle is transmitted. The lane change can be performed smoothly.
[0017]
Further, the present invention further comprises a plurality of junction points judging means for judging whether a plurality of the junction points are present in a predetermined distance range, and a lane selection means for selecting a lane. And the lane selecting means is provided at least in the leading vehicle, and the lane selecting means selects a lane based on the judgment result of the plurality of merging point judging means, and the leading vehicle is the lane selected by the lane selecting means. It is characterized in that the lane is changed.
[0018]
According to the present invention, the multiple junction point determination means determines whether or not a plurality of junction points are present within a predetermined distance range, and the lane selection means is based on the determination result of the multiple junction point determination means. Since the lane is selected, the lane is selected in consideration of the existing merging point, so that the vehicle group can travel comfortably.
[0019]
Further, in the present invention, the multiple junction point determination means determines the number of the junction points connected to each lane within the predetermined distance range, and the lane selection means selects a lane with a small number of junction points. It is characterized by the following.
[0020]
According to the present invention, since the lane selecting means selects a lane with a small number of merging points obtained by the plural merging point determining means, the lane change of the running vehicle group is small, and thereby the comfortable running of the vehicle group is achieved. It can be carried out.
[0021]
The present invention also provides a vehicle group travel control system in which a vehicle group is formed by a plurality of vehicles, and travel control information is transmitted between the vehicles in the formed vehicle group, whereby the vehicle group travels in a predetermined platoon. So,
Diversion point determining means for determining a diversion point of a road, diversion vehicle presence / absence determination means for determining whether or not there is a vehicle that diverts at a specific diversion point in the vehicle group, and lane selection means for selecting a lane. With
The shunt point determination means, the shunt vehicle presence / absence determination means, and the lane selection means are provided in at least a leading vehicle of the vehicle group,
When the vehicle group approaches the shunt point, the shunt point determination means generates a shunt point signal, and the shunt vehicle presence / absence determination means generates a shunt vehicle presence signal when a shunt vehicle exists in the vehicle group, and a lane selection means. Is a vehicle group traveling control system, wherein a lane in which the specific branch point exists is selected based on the branch point signal and the branch vehicle presence signal.
[0022]
According to the present invention, when a vehicle group includes a vehicle that diverges at a specific branch point, when the vehicle group approaches the specific branch point, the lane selecting means selects the lane where the specific branch point exists. Therefore, the vehicle group changes lanes to this lane, and the diverted vehicle can be smoothly diverted to the shunt channel at the specific shunt point.
[0027]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a first embodiment of a vehicle group traveling control system according to the present invention will be described with reference to the accompanying drawings. FIG. 1 is a block diagram schematically showing a main part of a first embodiment of a vehicle group traveling control system according to the present invention.
[0028]
Referring to FIG. 1, the illustrated vehicle group travel control system includes a travel control device indicated by reference numeral 2, and in this embodiment, such a travel control device 2 is mounted on each vehicle 4 (see FIG. 3). Is done. Each of the travel control devices 2 includes a communication control unit 8 (hereinafter, referred to as a “communication control ECU”) for transmitting information signals such as travel control information between vehicles 4 in a vehicle group 6 (see FIG. 3) forming a platoon; A vehicle control unit 12 (hereinafter, referred to as a “vehicle control ECU”) for controlling a traveling device 10 of a vehicle 4 on which the traveling control device 2 is mounted, and a traveling control unit 14 (hereinafter, referred to as a “travel”) for controlling a lane change of a vehicle group. The communication control ECU 8, the vehicle control ECU 12, and the travel control ECU 14 are configured by, for example, dedicated microprocessors.
[0029]
In connection with the communication control ECU 8, an optical communication device 16 for transmitting and receiving an optical signal is provided. The optical communication device 16 includes a light emitting device 18 for transmitting an optical signal and a light emitting device 18 for receiving an optical signal. The receiver 20 is connected. The light emitter 18 transmits a predetermined light signal to the vehicle 4 ahead, in this embodiment, a vehicle number signal and a vehicle length signal, and transmits a predetermined signal to the rear vehicle 4, which will be described later in this embodiment. Send lane change signal. The light receiver 20 receives the optical signals (vehicle number signal and vehicle length signal) from the rear vehicle 4 and receives a lane change signal from the front vehicle 4.
[0030]
In addition to the communication control ECU 8, a transmitter 22 and a receiver 24 are further provided. The transmitter 22 and the receiver 24 are for transmitting and receiving a predetermined signal to and from infrastructure equipment such as a beacon provided along the road 28 (see FIG. 3). The radio signal transmitted from the transmitter 22 is transmitted as a radio wave from the antenna 30, and the radio signal transmitted from the infrastructure equipment is received by the receiver 24 via the antenna 30.
[0031]
Further, a millimeter wave radar 32 and a CCD camera 34 are provided in association with the vehicle control ECU 12. The millimeter-wave radar 32 is for measuring the inter-vehicle distance with the preceding vehicle 4, transmits a high-frequency signal forward and receives a reflected signal from the preceding vehicle 4, and thereby receives the reflected signal from the preceding vehicle 4. Measure the distance between vehicles. The CCD camera 34 is for following the preceding vehicle 4 and recognizes the preceding vehicle 4.
[0032]
In addition to the vehicle control ECU 12, a navigation device 36 and a vehicle speed sensor 38 are further provided. Map data is stored in the navigation device 36, and the map data can be displayed on display means (not shown). In this embodiment, map data of the navigation device 36 is sent to the vehicle control ECU 12, and the traveling device 10 is controlled using the map data. The vehicle speed sensor 38 detects the traveling speed of the vehicle 4, and the detection signal is sent to the vehicle control ECU 12.
[0033]
The vehicle control ECU 12 controls the operation of the traveling device 10 to control the actual traveling state of the vehicle. The traveling device 10 includes, for example, an engine, a brake, and a steering of the vehicle, and these are controlled by the vehicle control ECU 12.
[0034]
Referring also to FIG. 2, traveling control ECU 14 includes a vehicle number counter 40, a vehicle number storage unit 42, a vehicle group length calculation unit 44, and a group length storage unit 46. The vehicle number counter 40 counts the number of vehicles 4 that form a vehicle group 6 (see FIG. 3) that runs in a platoon. The number-of-groups storage means 42 stores the number of vehicles 4 constituting the platoon, for example, five, and one group of vehicle groups is formed based on the number stored in the number-of-groups storage means 42. Further, the vehicle group length calculating means 44 calculates the length of the vehicle group 6 that runs in a platoon. The group length storage means 46 stores the length of the vehicle group 6 constituting the platoon, for example, 25 m, and one group of vehicle groups is formed based on the group length stored in the group length storage means 46. Is done.
[0035]
The travel control ECU 14 further includes a vehicle information storage unit 48, a group formation determination unit 50, and a lane change unit 52. The vehicle information storage means 48 stores information about the vehicle, for example, the total length of the vehicle. Further, the group formation determining means 50 determines whether or not the vehicle group 6 forming the row should be formed. In this embodiment, the number of vehicles counted by the vehicle number counter 40 is compared with the number of groups stored in the group number storage means 42, and when the number of vehicles in the vehicle number counter 40 becomes the number of groups, the group formation determining means 50 Generates a group formation signal. Further, the group length calculated by the vehicle group length calculation means 44 is compared with the group length stored in the group length storage means 46, and the calculation group length by the vehicle group length calculation means 44 is determined as the storage group length. , Or when the storage group length is exceeded, the group formation determining means 50 generates a group formation signal.
[0036]
Next, the lane changing operation of the vehicle group in the vehicle group traveling control system described above will be described with reference to FIGS.
[0037]
As shown in FIG. 3, the vehicle 4 normally travels in a traveling lane 54, for example, a specific lane. When the number of vehicles increases, the vehicle 4 forms a vehicle group 6 and travels in a row. During this traveling, it is determined whether or not a predetermined number of vehicle groups 6 form a platoon. When the number of the vehicle groups 6 forming the platoon reaches a predetermined number (the number counted by the vehicle number counter 40), that is, five in this embodiment, the process proceeds from step S-1 to step S-2, and the group formation determining means 50 Generates a group formation signal.
[0038]
On the other hand, if the number of vehicle groups 6 forming the platoon is less than the predetermined number in step S-1, the process proceeds to step S-3, and the group length of the vehicle group 6 forming the platoon (vehicle group length calculating means) It is determined whether or not the group length calculated by 44) exceeds the predetermined group length or exceeds the predetermined group length. Then, when the calculated length of the vehicle group 6 is equal to or longer than the storage group length, the process proceeds to step S-2, and the group formation determining unit 50 forms a group formation signal as described above. In step S-3, if the length of the vehicle group 6 is shorter than the predetermined group length, the process proceeds to step S-4, and the vehicles 4 constituting the vehicle group 6 continue to travel on the traveling lane 54.
[0039]
In this embodiment, in the traveling control ECU 14 of the leading vehicle 4 of the vehicle group 6 forming the platoon, the vehicle number counter 40, the group number storage means 42, the vehicle group length calculation means 44, the group length storage means 46, the vehicle information All of the storage means 48, the group formation determination means 50, and the vehicle changing means 52 function, and when the lane change to the overtaking lane 56 is necessary, the leading vehicle 4 changes lanes as described later. On the other hand, in the traveling control ECU 14 of the succeeding vehicle 4 following the leading vehicle 4, the vehicle number counter 40, the vehicle group length calculating means 44, and the vehicle information storage means 48 function, and the group number storage means 42, the group length The storage unit 46, the group formation determining unit 50, and the lane changing unit 52 do not substantially function, and the following vehicle 4 runs following the leading vehicle 4. As described above, the control regarding the lane change is performed in the leading vehicle 4 of the vehicle group 6. In the vehicle group 6 forming the platoon, in the case of the last vehicle 4, since this vehicle 4 is the last vehicle, the vehicle counter 40 counts one vehicle as a group number for the own vehicle and sets the vehicle group length. The calculation means 44 calculates the total length of the vehicle stored in the vehicle information storage means 48 as a calculation group length for the own vehicle. The group number information and the group length information of the rearmost vehicle 4 are transmitted from the light emitter 18 to the vehicle 4 ahead of the vehicle 4 via the communication control ECU 8 and the optical communication device 16 in the vehicle 4, and the vehicle 4 Receives transmission information from the rearmost vehicle 4 via the light receiver 20. When received in this manner, in the case of the second vehicle 4 from the last, the group number information from the last vehicle 4 is received, so the vehicle counter 40 in this vehicle 4 counts two vehicles as the group number for the own vehicle. At the same time, since the group length information from the last vehicle 4 is received, the vehicle group length calculating means 44 of the vehicle 4 determines the total length of the vehicle stored in the vehicle information storage means 48 in the group length information and The calculation is performed as the calculation group length for the own vehicle by adding the inter-vehicle distance. In this manner, the vehicle counter 40 of the leading vehicle 4 counts the number of vehicles 4 constituting the vehicle group 6, and the vehicle group length calculating means 44 calculates the group length of the vehicle group 6. When the vehicle 4 is further attached behind the rearmost vehicle 4 of the vehicle group 6, the newly attached vehicle 4 becomes the rearmost vehicle, and the number of vehicles in the vehicle group 6 is counted and the vehicle group length is calculated. Are performed to update these numerical values.
[0040]
When the group formation signal is generated by the group formation determining unit 50 of the traveling control ECU 14 in the leading vehicle 4 of the vehicle group 6, the process proceeds to step S-5, and the lane changing unit 52 of the leading vehicle 4 is based on the group formation signal. To generate a lane change signal. Then, the lane change signal is sent to the vehicle control ECU 12, and the vehicle control ECU 12 automatically operates the steering (not shown) of the vehicle based on the lane change signal. As shown by 58 (FIG. 3), the lane is changed to the overtaking lane 56 (step S-6), so that the following vehicle 4 also follows and changes lanes to the overtaking lane 56 (step S-7).
[0041]
Thus, the vehicle group 6 formed in a short platoon travels in the traveling lane 54. When the platoon reaches a predetermined number or a predetermined group length, the vehicle group 6 forms one group and changes lanes to the passing lane 56. Therefore, the traveling of the vehicle is smooth, and efficient traveling is possible.
[0042]
In the first embodiment described above, when the vehicle group 6 forming the platoon reaches a predetermined number or a predetermined group length, the vehicle group 6 is formed at that time and the lane is changed. Alternatively, it is also possible to form the vehicle group 6 and change lanes when the vehicle group 6 approaches the branch channel and / or the merging channel in a state where the vehicle group 6 has a predetermined number or a predetermined length.
[0043]
FIG. 5 is a block diagram schematically showing a second embodiment of the vehicle group traveling control system according to the present invention. In the second embodiment, members that are substantially the same as those in the first embodiment are given the same reference numerals, and descriptions thereof are omitted.
[0044]
In FIG. 5, in the second embodiment, the map data from the navigation device 36 is sent to the vehicle control ECU 12, and the map data is further sent from the vehicle control ECU 12 to the drive control ECU 14. I have. Then, the lane change of the vehicle group 6 is performed based on the merging and merging map information from the map data of the navigation device 36. In connection with this, the travel control ECU 14 further controls the merging and merging point determination means (not shown). Including. Other configurations in the second embodiment are substantially the same as those in the first embodiment.
[0045]
Next, the lane changing operation of the vehicle group in the vehicle group traveling control system of the second embodiment will be described with reference to FIGS.
[0046]
As shown in FIG. 6, the vehicle 4 normally travels in a traveling lane 54 that is a specific lane, for example. When the number of vehicles 4 increases, the vehicle 4 forms a vehicle group 6 and travels in a row. During this traveling, it is determined whether or not a predetermined number of vehicle groups 6 form a platoon. When the number of vehicles 6 forming a platoon reaches a predetermined number, the process proceeds from step S-11 to step S-12, and the group formation determining unit 50 generates a group formation signal. On the other hand, if the number of vehicle groups 6 forming the platoon is less than the predetermined number in step S-11, the process proceeds to step S-13, and the group length of the vehicle group 6 forming the next platoon is the predetermined group length, or It is determined whether or not the length exceeds the predetermined group length. When the calculated length of the vehicle group 6 is equal to or longer than the storage group length, the process proceeds to step S-12, and the group formation determining unit 50 generates a group formation signal as described above. The counting of the number of vehicles in the vehicle group 6 and the calculation of the vehicle group length are performed in the same manner as in the first embodiment. If the length of the vehicle group 6 is shorter than the predetermined group length in step S-13, the process proceeds to step S-14, and the vehicles 4 constituting the vehicle group 6 continue to travel on the traveling lane 54.
[0047]
When the group formation signal is generated in step S-12, the process proceeds to step S-15, and it is determined whether the vehicle group 6 has approached the junction. In this embodiment, map data from the navigation device 36 mounted on the vehicle 4 is used as the point information on the junction. The navigation device 36 stores various information related to road information. The stored information is transmitted to the vehicle control ECU 12, and the branching and merging map information of the information, that is, the position of the branching point and the position of the merging point is stored. Information is sent to the travel control ECU 14. For example, when the vehicle group 6 approaches the merging point 72 as shown in FIG. 6, for example, 500 m before the merging point as shown in FIG. (Not shown) generates a junction signal based on the junction map information from the navigation device 36. When the group formation signal and the junction point signal are generated as described above, the lane changing unit 52 of the traveling control ECU 14 generates a lane change signal based on these signals (step S-16). Then, prior to the lane change of the leading vehicle 4 of the vehicle group 6, the generated lane change signal is transmitted to the following vehicle 4 of the vehicle group 6. The transmission of the lane change signal is performed from the light emitting device 18 by the operation of the communication control ECU 16 and the optical communication device 16 of the leading vehicle 4. The following vehicle 4 following the leading vehicle 4 transmits the lane changing signal from the light emitting device 18. Is received by the light receiver 20 and the received lane change signal is sent to the travel control ECU 12 via the communication control ECU 8, and further from the light emitter 18 to the following vehicle by the action of the communication control ECU 8 and the optical communication device 16. The lane change signal is transmitted to the following vehicles 4 of the vehicle group 6 in this way, and each vehicle 4 of the vehicle group 6 receives the lane change signal from the leading vehicle 4 (step S-18).
[0048]
When the lane change signal is transmitted to the succeeding vehicle 4 in this manner, the process proceeds to step S-19, and the leading vehicle 4 of the vehicle group 6 moves from the traveling lane 54 to the overtaking lane 56 as indicated by an arrow 74 (FIG. 6). (Step S-19), whereby the following vehicle 4 also follows and changes lanes to the overtaking lane 56 (step S-20). In this way, by causing the leading vehicle 4 to change lanes after the subsequent vehicle 4 receives the lane change signal, the vehicle group 6 can smoothly change lanes.
[0049]
Thus, the vehicle group 6 formed in a short platoon travels in the traveling lane 54. When the platoon reaches a predetermined number or a predetermined group length, the vehicle group 6 forms one group and changes lanes to the passing lane 56. Therefore, similarly to the above-described first embodiment, the traveling of the vehicle becomes smooth and the traveling can be performed efficiently. When the number of vehicles in the vehicle group 6 is large (or the length of the vehicle group is long), a predetermined number (or a predetermined group length) of the vehicle groups 6 constitute one group and change lanes, and the remaining vehicle groups are changed. At 6, the control operation shown in FIG. 7 is performed. If the number of vehicles in the remaining vehicle group 6 is equal to or larger than a predetermined number (or a predetermined group length), one vehicle group 6 is constituted by the predetermined number (or a predetermined group length). The lane change is performed, and such an operation is repeatedly performed on the remaining vehicle groups 6.
[0050]
In the second embodiment, it is determined whether or not the vehicle has approached the junction by using the map data of the navigation device 36 mounted on the vehicle 4. However, instead of this, for example, along the road 28, It is also possible to use a road information signal transmitted from an infrastructure device 78 such as a ground device installed, for example, a beacon. In such a case, the road information signal includes the branching information signal, the road information signal from the infrastructure equipment 78 is received by the receiver 24 via the antenna 30, and the received road information signal is It is sent to the travel control ECU 14 via the control ECU 8, and the junction point determination means (not shown) determines that the vehicle has approached the junction point based on the road information signal and generates a junction point signal. . Even with such a configuration, when approaching the junction, the vehicle group 6 changes lanes as required. It should be noted that information on the merging point of both the navigation device 36 and the ground infrastructure equipment 78 may be used.
[0051]
Further, in the second embodiment, the lane change is performed at both the merging point between the traveling lane 54 and the merging channel 80 and the merging point between the traveling lane 54 and the merging channel (not shown). The same effect can be achieved by changing lanes at one of the merging point and the branch point.
[0052]
The travel control ECU can be configured, for example, as shown in FIG. 8. In such a configuration, the vehicle can travel smoothly even if a plurality of junctions exist within a predetermined distance range. FIG. 8 is a block diagram schematically showing a first modification of the travel control ECU, FIG. 9 is a simplified diagram for explaining a travel state, and FIG. 10 is a block diagram of the travel control ECU of FIG. It is a flowchart which shows the control operation at the time of using. Note that members that are substantially the same as those in the above-described embodiment are given the same reference numerals, and descriptions thereof are omitted.
[0053]
In FIG. 8, the traveling control ECU 102 according to the first modified example includes a plurality of merging point judging means 104 and a lane selecting means 106 in addition to the various means 40 to 52 shown in FIG. 2. The multi-junction point judging means 104 judges whether there are a plurality of junctions in a predetermined distance range, for example, a range of 4 km, by using a road information signal from the infrastructure equipment 78 as a ground device, and If it is determined, the number of divergence points 112 (points to which the diverging path 108 is connected) and convergence points 114 (points to which the diverging path 110 is connected) existing in each lane is determined. The lane selecting means 106 selects a lane in which the vehicle group 6 travels based on the number of merging points obtained by the plural merging point judging means 104. Such a travel control ECU 102 is used in place of the travel control ECU 14 in the first embodiment.
[0054]
Next, the lane changing operation of the vehicle group in the vehicle group traveling control system using the traveling control ECU 102 of the first modification will be described with reference to FIGS.
[0055]
As shown in FIG. 9, the vehicle 4 normally travels in a traveling lane 54 that is a specific lane, for example. When the number of vehicles 4 increases, the vehicle 4 forms a vehicle group 6 to form a row and travels. Then, when the number of vehicle groups 6 exceeds a predetermined number (or a predetermined group length) or more, the vehicle groups 6 form a row as described above, and the vehicle group 6 changes lanes to the passing lane 56. Therefore, it is determined whether or not the vehicle group 6 forming the platoon constitutes the predetermined vehicle group 6, and when the vehicle group 6 constitutes the predetermined vehicle group 6, the vehicle travels on the passing lane 56, Proceed to step S-32. On the other hand, when the vehicle group 6 does not form the predetermined vehicle group 6, the process proceeds from step S-31 to step S-33, and the vehicle group 6 (including one vehicle) travels on the traveling lane 54.
[0056]
When the vehicle group 6 approaches the branch point 112 or the junction 114, the leading vehicle 4 of the vehicle group 6 receives the road information signal transmitted from the infrastructure equipment 78 as a ground device provided along the road 28. (Step S-32), this road information signal is sent to the travel control ECU 102. The road information signal includes information on the junction, and when there are a plurality of junctions in a predetermined distance range H on the front side in the traveling direction from the junction, for example, a range of 4 km, a plurality of junctions are determined. Contains information about the junction. When the information on the multiple junctions is sent to the travel control ECU 102, the multiple junction determination means 104 determines that the multiple junctions exist based on the above-mentioned information, and The number of junctions existing in each of the lanes 54 and 56 within H is obtained (step S-34). For example, on the road 28 shown in FIG. 9, the number of the junctions 54 in the traveling lane 54 is determined by the plural junctions determining means 104 and the number of the junctions 56 in the passing lane 56 is one. Can be When the number of junctions in each of the lanes 54 and 56 is obtained in this manner, the lane selection means 106 selects the lane in which the vehicle group 6 travels based on the number obtained by the plural junctions determination means 104. I do. In this embodiment, the lane selection means 106 selects a lane with a small number of junctions within the predetermined distance range H, that is, an overtaking lane 56 (step S-35).
[0057]
When the traveling lane is selected in this way, it is determined in step S-36 whether or not the vehicle group 6 is traveling on the selected lane. In this embodiment, if the vehicle group 6 is traveling on the passing lane 56, there is no need to change lanes, so the process proceeds to step S-37, and the vehicle group 6 continues traveling on the passing lane 56. . If the overtaking lane 56 has more junctions than the traveling lane 54, the traveling lane 54 is selected by the lane selecting means 106. In this case, the vehicle group 6 moves to the selected lane, that is, the traveling lane 54. Change lanes (S-38). As described above, when a plurality of junctions are present within the predetermined distance range H, a lane having a small number of junctions is selected, so that the vehicle group 6 does not frequently change lanes, and Smooth running becomes possible. In addition, since the vehicle travels on a lane with a small number of junctions, the vehicle group 6 is less likely to hinder the vehicles 4 to be merged. If it is determined in step S-34 that a plurality of junctions do not exist, the process proceeds to step S-37, and the traveling state is maintained.
[0058]
In the above-described embodiment, whether or not there are a plurality of junctions is determined using the road information signal from the infrastructure equipment 78 as a road device, but is mounted on the vehicle 4 instead. The junction point information in the map data of the navigation device 36 can also be used.
[0059]
The traveling control ECU 102 of FIG. 8 is further provided with a specific shunt point determining means (not shown) for determining a specific shunt point and a shunt vehicle presence / absence determining means (not shown), whereby the shunt vehicle 4 at the shunt point is divided. 109 can be smoothly performed. In this case, the lane change is performed according to the flowchart shown in FIG.
[0060]
First, in step S-41, it is determined whether or not the vehicle 4 that diverges in the branch channel 108 (see FIG. 9) is included in the vehicle group 6. When such a shunt vehicle 4 is included in the vehicle group 6, a shunt signal from the shunt vehicle 4 is transmitted to the leading vehicle 4 of the vehicle group 6, and the shunt vehicle presence / absence determining means ( (Not shown) determines that the vehicle group 6 includes the vehicle 4 that branches off at the specific branch point, and proceeds to step S-42. On the other hand, when the vehicle group 4 does not include the branch vehicle 4, the process proceeds to step S-43, and the vehicle group 6 travels on the passing lane 56. As described above, when the number of vehicle groups 6 exceeds a predetermined number (or a predetermined group length) or more, one group is formed as described above to form a platoon, and the vehicle group 6 becomes a lane in the overtaking lane 56. change. Therefore, when the vehicle group 6 constitutes the predetermined vehicle group 6, the vehicle travels on the passing lane 56, and when the vehicle group 6 does not constitute the predetermined vehicle group 6, the vehicle group 6 (one vehicle) ) Is traveling in the traveling lane 54.
[0061]
In step S-42, it is determined whether or not the vehicle group 6 approaches a specific branch point, that is, a point where the branch vehicle 4 branches. Then, when the vehicle group 6 approaches a specific branch point, for example, a branch point 112 (see FIG. 9), the leading vehicle 4 of the vehicle group 6 is transmitted from the infrastructure equipment 78 as a ground device provided along the road 28. The received road information signal is sent to the travel control ECU 102. When the information signal relating to the specific branch point is sent to the travel control ECU 102, the branch point determining means (not shown) determines that the vehicle has approached the specific branch point, and generates a branch point signal. Thus, the shunt point signal is sent to the lane selection means 106, and the lane selection means 106 selects the lane in which the shunt point 112 (see FIG. 9) exists, that is, the traveling lane 54, based on the shunt point signal. (Step S-44).
[0062]
When the traveling lane is selected in this way, it is determined in step S-45 whether or not the vehicle group 6 is traveling on the selected lane. In this embodiment, if the vehicle group 6 is traveling in the passing lane 56, it is necessary to change lanes, so the process proceeds to step S-46, and the vehicle group 6 moves from the passing lane 56 to the traveling lane 54. change. When the vehicle group 6 is traveling in the traveling lane 54, the vehicle group 6 continuously travels in the traveling lane 54 because there is no need to change lanes.
[0063]
As described above, when the vehicle group 6 including the branch vehicle 4 approaches the specific branch point, the vehicle group 6 changes the lane to the lane including the specific branch point, so that the branch vehicle 4 included in the vehicle group 6 includes: From the specific branch point, the vehicle can smoothly branch into the branch channel 108.
[0064]
In the above-described embodiment, it is determined whether or not there are a plurality of specific junctions using the road information signal from the infrastructure equipment 78 as the on-road device. 4 can also use the junction point information in the map data of the navigation device 36 mounted on the navigation device 36.
[0065]
Hereinafter, embodiments related to the embodiments of the present invention will be described.
The lane change at the lane decrease point (the lane change to the non-decreasing lane) is performed as required by further providing the lane decrease point determining means (not shown) for judging the lane decrease point in the travel control ECU 102 of FIG. Can be done. In this case, the lane change is performed according to the flowchart shown in FIG.
[0066]
First, in step S-51, it is determined whether the vehicle has approached the lane reduction point. For example, at locations where the number of lanes on the road is decreasing due to a small number of vehicles traveling, or at locations where the number of lanes under construction is temporarily reduced due to road construction, etc. (Not shown). Therefore, when the vehicle group 6 (see FIG. 9) approaches the lane reduction point, the leading vehicle 4 of the vehicle group 6 receives the road information signal transmitted from the infrastructure equipment provided on the road, and receives the road information signal. Is sent to the travel control ECU 102 (see FIG. 8). When the information signal regarding the lane reduction point is sent to the travel control ECU 102, the lane reduction point determination means (not shown) determines that the vehicle is approaching the lane reduction point, and generates a lane reduction point signal. Thus, the lane reduction point signal is sent to the lane selection unit 106, and the lane selection unit 106 selects a lane whose lane is not reduced, that is, a lane on which the vehicle can travel, based on the lane reduction point signal (step). S-52).
[0067]
When the traveling lane is selected in this way, it is determined in step S-53 whether or not the vehicle group 6 is traveling on the selected lane. If the vehicle group 6 is traveling in a lane where the number of lanes has not decreased, that is, in the selected lane, there is no need to change lanes, so the process proceeds to step S-54, and the vehicle group 6 continues Drive in the lane. On the other hand, if the vehicle group 6 is traveling in a lane where the lane is decreasing, it is necessary to change the lane. Therefore, the process proceeds from step S-53 to step S-55, and the vehicle group 6 has the lane decreasing. The lane is changed to another lane.
[0068]
If the vehicle group 6 does not approach the lane reduction point, the process proceeds from step S-51 to step S-56, and the vehicle group 6 continues to travel on the running lane without changing lanes.
[0069]
As described above, when approaching the lane decrease point, the vehicle group 6 automatically changes lanes to the lane where the lane is not decreasing, so that safe driving can be performed even when such a point exists.
[0070]
In such a vehicle group traveling control system, it is desirable to forcibly prohibit the lane change from the traveling lane to the overtaking lane when the traffic volume of the specific lane, for example, the overtaking lane is large. In this case, for example, the travel control ECU 102 shown in FIG. 8 is further provided with a traffic volume determining means for determining the traffic volume in a predetermined range of the lane and a lane change prohibiting means for prohibiting the lane change by the lane changing means. In this case, the lane change is prohibited according to the flowchart shown in FIG.
[0071]
First, in step S-61, the traffic volume in a predetermined range of each lane is detected. The detection of the traffic volume can be performed by the ground device provided on the road. When the traffic volume is detected as described above, the traffic volume detected by the ground device is transmitted to the leading vehicle 4 of the vehicle group 6. The traffic volume can also be detected by mutual communication from vehicles traveling around. When such detection is performed, it can be directly detected in the leading vehicle of the vehicle group.
[0072]
When the traffic volume is detected as described above, the process proceeds to step S-62, and it is determined whether the traffic volume in each lane is equal to or more than a predetermined volume. If possible, it is determined whether or not the number is 90 or more. In this embodiment, when the traffic volume judging means (not shown) judges that the traffic volume in the specific lane is equal to or more than the predetermined amount, the process proceeds to step S-63, and the lane change prohibiting means (not shown) returns to the above-mentioned judgment. A lane change prohibition signal is generated based on the lane change prohibition signal. Thus, the generation of the lane change signal in the lane changing means 52 is forcibly prohibited, and the lane change of the vehicle group from the lane other than the specific lane to the specific lane is forcibly prohibited, whereby the vehicle travels in the specific lane. An increase in the number of traveling vehicles can be prevented, and the vehicle group 6 can travel efficiently and efficiently.
[0073]
The traffic volume can be detected based on the vehicle length, for example, instead of the number of vehicles. In this case, if a vehicle group is formed over 90% or more of the predetermined range, the traffic volume is reduced. It can be determined that the amount is equal to or more than the predetermined amount.
[0074]
The embodiments of the vehicle group traveling control system according to the present invention and the related embodiments have been described above. However, the present invention is not limited to these embodiments, and various modifications and corrections can be made without departing from the scope of the present invention. Is possible.
[0075]
For example, in the above-described embodiment, the lane change is performed based on the number of vehicles in the vehicle group and the group length of the vehicle group. However, instead of this, the number of vehicles in the vehicle group or the group is changed. A similar effect can be achieved by configuring the lane change based on either one of the lengths.
[0076]
【The invention's effect】
According to the vehicle group traveling control system of the first aspect of the present invention, when the number of vehicles in the vehicle group reaches a predetermined number, or when the group length reaches a predetermined length, the lane changing means generates a lane change signal. The leading vehicle in the vehicle group changes lanes from a specific lane to another lane, and the following vehicles also change lanes following the leading vehicle. Therefore, the length of the vehicle group does not become longer than the predetermined range, such a vehicle group travels as one group, and thus the traffic flow is smooth, and the vehicle can travel efficiently. .
[0077]
According to the vehicle group traveling control system of the second aspect of the present invention, when the number of vehicles in the vehicle group reaches a predetermined number or when the length of the group reaches a predetermined length, the lane changing means at the junction joins the lane change signal. Is generated, whereby the leading vehicle of the vehicle group changes lanes from a specific lane to another lane, and the following vehicles also change lanes following the leading vehicle. Therefore, the length of the vehicle group is adjusted at the junction point, such a vehicle group travels as one group, and thus the traffic flow is smooth, and the vehicle can travel efficiently.
[0078]
Further, according to the vehicle group traveling control system of the third aspect of the present invention, map data in the navigation device can be used as information on the junction.
[0079]
Further, according to the vehicle group traveling control system of the fourth aspect of the present invention, a road information signal from a road device can be used as information on a junction.
[0080]
Further, according to the vehicle group traveling control system of the present invention, the vehicle change signal generated by the lane changing means is transmitted to the following vehicle before the leading vehicle of the vehicle group changes lanes. Thus, the lane change of the following vehicle accompanying the lane change of the leading vehicle can be performed smoothly.
[0081]
According to the vehicle group traveling control system of the sixth aspect of the present invention, the multiple merging point judging means judges whether or not a plurality of merging points exist within a predetermined distance range. Since the lane is selected based on the judgment result of the junction point judging means, the lane is selected in consideration of the existing junction point, so that the vehicle group can travel comfortably.
[0082]
According to the vehicle group traveling control system of the present invention, the lane selecting means selects a lane with a small number of merging points obtained by the plural merging point determining means. Thus, the vehicle group can travel comfortably.
[0083]
According to the vehicle group traveling control system of the eighth aspect of the present invention, when a vehicle group includes a vehicle that diverges at a specific branch point, when the vehicle group approaches the specific branch point, the lane selecting means is switched. Select the lane where the specific branch point is located. Therefore, the vehicle group changes lanes to this lane, and the diverted vehicle can be smoothly diverted to the shunt channel at the specific shunt point.
[Brief description of the drawings]
FIG. 1 is a block diagram schematically showing a first embodiment of a vehicle group traveling control system according to the present invention.
FIG. 2 is a block diagram schematically showing a traveling control ECU 14 in the vehicle group traveling control system of FIG.
FIG. 3 is a simplified diagram for explaining a lane change of a vehicle group.
FIG. 4 is a flowchart illustrating a vehicle changing operation in the vehicle group traveling control system of FIG. 1;
FIG. 5 is a block diagram schematically showing a second embodiment of the vehicle group traveling control system according to the present invention.
FIG. 6 is a simplified diagram for explaining a lane change by the vehicle group traveling control system of FIG. 5;
FIG. 7 is a flowchart illustrating a vehicle changing operation in the vehicle group traveling control system of FIG. 5;
FIG. 8 is a block diagram schematically showing a first modification of the travel control ECU.
FIG. 9 is a simplified diagram for explaining traveling of a vehicle group by the traveling control ECU of FIG. 8;
FIG. 10 is a flowchart illustrating traveling of a vehicle group when the traveling control ECU of FIG. 8 is used.
FIG. 11 is a flowchart illustrating traveling of a vehicle group including a branch vehicle.
FIG. 12 is a flowchart illustrating traveling of a group of vehicles when approaching a lane reduction point.
FIG. 13 is a flowchart illustrating traveling of a vehicle group when the traffic volume is large.
[Explanation of symbols]
2 Travel control device
4 vehicles
6 vehicle group
8 Communication control ECU
12 Vehicle control ECU
14,102 Travel control ECU
28 Road
36 Navigation equipment
40 Vehicle counter
44 Vehicle group length calculation means
50 Group formation judgment means
52 Lane changing means
54 driving lanes
58 Overtaking Lane
72,114 junction
78 Infrastructure equipment
80,110 Combined channel
104 Multiple junction point judgment means
106 Lane selection means
108 branch channel
112 diversion point

Claims (8)

A vehicle group is formed by a plurality of vehicles, travel control information is transmitted between the vehicles of the formed vehicle group, thereby a vehicle group travel control system in which the vehicle group performs a predetermined platooning,
Group formation determining means for determining whether a predetermined number of vehicles or a predetermined group length has been formed, and lane changing means for performing lane change of the vehicle group,
The group formation determining unit and the lane changing unit are mounted on at least a leading vehicle of the vehicle group,
When the vehicle group reaches the number of vehicles or a predetermined group length, the group formation determining unit generates a group formation signal, and the lane changing unit generates a lane change signal based on the group formation signal, and the lane change signal A vehicle group travel control system, wherein the leading vehicle changes lanes from a specific lane to another lane different from the specific lane based on A vehicle group is formed by a plurality of vehicles, travel control information is transmitted between the vehicles of the formed vehicle group, thereby a vehicle group travel control system in which the vehicle group performs a predetermined platooning,
Group formation determining means for determining whether or not a predetermined number of vehicles or a predetermined group length has been formed; and a determination of a branch junction which is one or both of a branch point and a junction of a road. It comprises a junction merging point determining means, and a lane changing means for changing the lane of the vehicle group,
The group formation determining means, the junction point determining means and the lane changing means are mounted on at least the leading vehicle of the vehicle group,
When the vehicle group reaches the number of vehicles or a predetermined group length, the group formation determining means generates a group formation signal, and when the vehicle group approaches the branch point, the branch point determination means outputs the branch point. A signal is generated, the lane changing means generates a lane change signal based on the group formation signal and the junction point signal, and the leading vehicle is different from the specific lane from a specific lane based on the lane change signal. A vehicle group travel control system characterized in that a lane change is performed for a given lane. 3. The vehicle group travel control according to claim 2, wherein the branching point determination unit generates the branching point signal based on branching map information from map data included in a navigation device mounted on the vehicle. system. 3. The vehicle group traveling control system according to claim 2, wherein the junction point determination unit generates the junction point signal based on a road information signal from a road device provided along the road. Each vehicle in the vehicle group includes a transmitting unit and a receiving unit, and when the lane changing unit of the leading vehicle generates the lane changing signal, the vehicle is generated by the leading vehicle before the leading vehicle changes lanes. The vehicle group traveling control system according to any one of claims 1 to 4, wherein the lane change signal is transmitted from the transmitting unit to a receiving unit of a subsequent vehicle. A multi-junction point judging means for judging whether a plurality of the merging points exist in a predetermined distance range, and a lane selecting means for selecting a lane; Means are provided at least in the leading vehicle, the lane selecting means selects a lane based on the judgment result of the plural junction point judging means, and the leading vehicle changes lanes to the lane selected by the lane selecting means. The vehicle group traveling control system according to any one of claims 2 to 5, wherein The multi-junction point determination means obtains the number of the junction points connected to each lane within the predetermined distance range, and the lane selection means selects a lane with a small number of the junction points. The vehicle group traveling control system according to claim 6. A vehicle group is formed by a plurality of vehicles, travel control information is transmitted between the vehicles of the formed vehicle group, thereby a vehicle group travel control system in which the vehicle group performs a predetermined platooning,
Diversion point determining means for determining a diversion point of a road, diversion vehicle presence / absence determination means for determining whether or not there is a vehicle that diverts at a specific diversion point in the vehicle group, and lane selection means for selecting a lane. With
The shunt point determination means, the shunt vehicle presence / absence determination means, and the lane selection means are provided in at least a leading vehicle of the vehicle group,
When the vehicle group approaches the shunt point, the shunt point determination means generates a shunt point signal, and the shunt vehicle presence / absence determination means generates a shunt vehicle presence signal when a shunt vehicle exists in the vehicle group, and selects the lane. The vehicle group traveling control system, wherein the means selects a lane in which the specific branch point exists based on the branch point signal and the branch vehicle presence signal.

Images