KR20230070397A - Vehicle overtaking control method and vehicle overtaking control device supporting the same - Google Patents

Abstract

In the present invention, a vehicle overtaking control apparatus collects vehicle information of a plurality of vehicles located in a vehicle driving management area defined as a communication range of a roadside base station, stores the collected vehicle information, and retrieves the stored vehicle information. Based on the step of setting occupied virtual areas on the road on which each vehicle is running, setting an overtaking virtual path for a second vehicle behind a first vehicle and a second vehicle in which the occupied virtual areas overlap, The setting of the overtaking virtual path may include setting a path to move in front of the first vehicle after moving from a driving lane in which the second vehicle travels to an overtaking lane, wherein the first occupied virtual area of the first vehicle and the A vehicle overtaking control method for setting the overtaking virtual path so that the second occupied virtual area of the second vehicle does not overlap, and a vehicle overtaking control device using the same are disclosed.

Description

Vehicle overtaking control method and vehicle overtaking control device supporting the same

The present invention relates to vehicle overtaking control, and more particularly, to a vehicle overtaking control method for a plurality of vehicles traveling on a road and a vehicle overtaking control device supporting the same.

Conventional vehicles use various sensors such as radar, lidar, and camera for collision warning, avoidance, and prevention. Although these various sensors are used to prepare for accidents, there is a limit to preparing for all the complex environments of the city only with control using sensors. In particular, when overtaking between vehicles is considered, it is necessary to collect various information such as the surrounding environment of the vehicle, the next lane and the road environment in front of the vehicle as well as the vehicle itself, and control based thereon. In addition, in terms of using and maintaining various sensors mounted on conventional vehicles, it can be a burden in terms of cost.

The present invention solves the above-mentioned conventional problems, for example, the present invention provides a vehicle overtaking control method and a vehicle overtaking control method that support safe overtaking control of vehicles equipped with only a GPS and a communication module within a range capable of communicating with RSU (road side units), and An object of the present invention is to provide a vehicle overtaking control device supporting this.

A vehicle overtaking control method according to an embodiment of the present invention includes the steps of, by a vehicle overtaking control apparatus, collecting vehicle information of a plurality of vehicles located in a vehicle driving management area defined as a communication range of a roadside base station; Storing, based on the stored vehicle information, setting occupied virtual areas on the road on which each vehicle is driving, overtaking virtual path of a second vehicle rearward among the first and second vehicles overlapping the occupied virtual areas The step of setting an overtaking virtual path includes setting a path to move in front of the first vehicle after moving from a driving lane in which the second vehicle travels to an overtaking lane, wherein the first vehicle The overtaking virtual path may be set so that the first virtual area occupied by the vehicle and the second virtual area occupied by the second vehicle do not overlap.

Here, the method may further include checking moving speeds of the plurality of vehicles and setting different sizes of the occupied virtual areas according to the moving speeds.

In this case, the method may further include setting a size of a virtual region occupied by a vehicle having a relatively fast moving speed among the plurality of vehicles to be larger than a virtual region occupied by a vehicle having a relatively slow moving speed. .

Meanwhile, in the method, when a third vehicle exists in front of the first vehicle, the distance between the first occupied virtual area of the first vehicle and the third occupied virtual area of the third vehicle is equal to that of the second vehicle. The method may further include adjusting a moving speed of the third vehicle to be larger than the size of the second occupied virtual area.

Alternatively, the method may include, when a fourth vehicle exists in the overtaking lane of the overtaking virtual route, the fourth virtual occupation of the fourth vehicle while the second virtual occupation area of the second vehicle moves along the virtual route. The method may further include adjusting a moving speed of the fourth vehicle so as not to overlap with the region.

An apparatus for controlling vehicle overtaking according to an embodiment of the present invention includes a server communication unit communicating with a roadwall base station, a server storage unit storing information received through the server communication unit, and a server functionally connected to the server communication unit and the server storage unit. A control unit, wherein the server control unit collects vehicle information of a plurality of vehicles located in a vehicle driving management area defined by a communication range of the roadside base station, stores the collected vehicle information, and based on the stored vehicle information Setting occupied virtual areas on the road on which each vehicle is driving, setting an overtaking virtual path of a second vehicle located at the rear of a first vehicle and a second vehicle overlapping the occupied virtual areas, and setting the overtaking virtual path In the process, after moving from the driving lane in which the second vehicle travels to the overtaking lane, a path to move in front of the first vehicle is set, wherein the first occupied virtual area of the first vehicle and the second vehicle's It is characterized in that the overtaking virtual path is set so that the two occupied virtual areas do not overlap.

Here, the server control unit may check the moving speed of the plurality of vehicles and differently set the sizes of the occupied virtual areas according to the moving speed.

In particular, the server control unit sets a size of a virtual region occupied by a vehicle having a relatively fast moving speed among the plurality of vehicles to be larger than a virtual region occupied by a vehicle having a relatively slow moving speed.

Meanwhile, the server control unit determines that, when a third vehicle exists in front of the first vehicle, the distance between the first occupied virtual area of the first vehicle and the third occupied virtual area of the third vehicle is determined by the second vehicle. It is characterized in that the moving speed of the third vehicle is adjusted so as to be greater than the size of the second occupied virtual area of .

Alternatively, when the fourth vehicle exists in the overtaking lane of the overtaking virtual route, the server control unit may fourthly occupy the fourth vehicle while the second occupied virtual area of the second vehicle moves along the virtual route. It is characterized in that the moving speed of the fourth vehicle is adjusted so as not to overlap with the virtual area.

According to the vehicle overtaking control method according to the present invention and the vehicle overtaking control apparatus supporting the same, the present invention provides vehicle overtaking control through communication with the RSU using only a GPS module and network communication equipment without using various high-performance lidar, radar, and camera equipment. can be performed safely, it is possible to reduce the cost required for sensor placement and maintenance.

In addition, the present invention can support safer vehicle overtaking by performing vehicle overtaking control through overall road management using the RSU.

In addition, various effects supported by the present invention may be described along with descriptions of embodiments.

1 is a diagram illustrating an example of a vehicle overtaking control system related to vehicle overtaking control according to an embodiment of the present invention.
2 is a diagram illustrating an example of a configuration of a vehicle overtaking control device according to an embodiment of the present invention.
3 is a diagram showing an example of a vehicle configuration according to an embodiment of the present invention.
4 is a diagram illustrating an example of a signal flow between components of a vehicle overtaking control device related to vehicle overtaking control according to an embodiment of the present invention.
5 is a diagram illustrating an example of overtaking execution according to vehicle overtaking control according to an embodiment of the present invention.
6 is a diagram illustrating an example of a method of operating a vehicle overtaking control device related to vehicle overtaking control according to an embodiment of the present invention.

The present invention is to proceed with an application with the support of the tasks described below.

[Research Task 1] Assignment number 1345331604 Buddha name Ministry of Education Assignment management (professional) institution name National Research Foundation of Korea Research project name University-focused research institute support project Title of research project Data networking AI engine/component technology development for autonomous driving using renewable energy Name of the institution performing the task Chungbuk National University Industry-University Cooperation Foundation research period 2020.06.01. ~ 2029.05.31. to contribute 50%

[Research Task 2] Assignment number 1711125911 Buddha name Ministry of Science and ICT Assignment management (professional) institution name Information and Communications Planning and Evaluation Institute (IITP) Research project name Grand ICT Research Center Title of research project Grand ICT Research Center (Chungbuk National University) Name of the institution performing the task Chungbuk National University Industry-University Cooperation Foundation research period 2020.07.01. ~ 2027.12.31. to contribute 50%

It should be noted that in the following description, only parts necessary for understanding the embodiments of the present invention are described, and descriptions of other parts will be omitted without disturbing the gist of the present invention.

The terms or words used in this specification and claims described below should not be construed as being limited to ordinary or dictionary meanings, and the inventors have appropriately used the concept of terms to describe their inventions in the best way. It should be interpreted as a meaning and concept consistent with the technical spirit of the present invention based on the principle that it can be defined in the following way. Therefore, the embodiments described in this specification and the configurations shown in the drawings are only preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, so various equivalents that can replace them at the time of the present application It should be understood that there may be variations and variations.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a diagram illustrating an example of a vehicle overtaking control system related to vehicle overtaking control according to an embodiment of the present invention.

Referring to FIG. 1 , a vehicle overtaking control system 10 according to an embodiment of the present invention is driving on roads 59a and 59b and vehicles 201, which are in a state in which a user is on board or autonomously drive for the user to board, 202, 203, 204), a roadside base station network (51) comprising at least one roadside base station capable of communicating with the vehicles (201, 202, 203, 204), the vehicles (201, 202, 203, 204) ), and a vehicle overtaking control device 100 that controls overtaking of the vehicles 201, 202, 203, and 204.

The vehicles 201, 202, 203, and 204 include a vehicle body, various structures constituting an interior space in which a user can ride, a power device (eg, battery) that generates power for moving the vehicle body, and transmission from the power device. It may include a means of transportation (eg, wheels and axles) driven based on the generated power, a steering device that controls the direction of the vehicle body, an accelerator device that controls speed, and a brake device that controls speed deceleration. In particular, the vehicles 201, 202, 203, and 204 of the present invention may perform vehicle overtaking during autonomous driving under the control of the vehicle overtaking control device 100 or perform vehicle overtaking according to a request of a vehicle driver. , In this process, acceleration, deceleration, lane (eg, driving lane 59a and overtaking lane 59b) change and speed maintenance related to vehicle overtaking may be performed.

The roadside base station network 51 is an Internet network, and may include a network capable of transmitting and receiving data at no cost or relatively low cost through a Wireless Local Area Network (WLAN) or Road Side Units (RSU). there is. The roadside base station network 51 may support transmission and reception of data related to vehicle overtaking while the vehicles 201, 202, 203, and 204 are moving, by arranging a plurality of RSUs for each predetermined section. The roadside base station network 51 establishes a communication channel between the vehicles 201, 202, 203, and 204 and the vehicle overtaking control device 100, and transmits data required for overtaking of the vehicles 201, 202, 203, and 204. can support the delivery of Meanwhile, in FIG. 1, it is described that the roadside base station network 51 supports the communication channel between the vehicles 201, 202, 203, and 204 and the vehicle overtaking control device 100, but the present invention is not limited thereto. That is, at least a part of the roadside base station network 51 can be replaced with a mobile communication network.

The GPS satellite 52 may transmit/receive signals for position calculation of the vehicles 201 , 202 , 203 , and 204 to and from the vehicles 201 , 202 , 203 , and 204 . In the illustrated drawings, it is shown in a form of communication with the first vehicle 201, but the present invention is not limited thereto. The GPS satellite 52 may transmit a signal for calculating the location of at least one vehicle equipped with a GPS module.

The vehicle overtaking control device 100 communicates with the vehicles 201, 202, 203, and 204 through the roadside base station network 51, and collects information related to the vehicles 201, 202, 203, and 204. Based on the information, overtaking of vehicles 201, 202, 203, 204 can be controlled. For example, the vehicle overtaking control device 100 performs driving control of the vehicles 201 and 202 located in the driving lane 59a, if a vehicle (eg, 203) that needs to be overtaken is needed, overtaking the vehicle Overtaking can be controlled by using the lane 59b. The vehicle overtaking control device 100 may be provided as a part of the roadside base station network 51 or may be provided in the form of a server device independent of the roadside base station network 51 . The vehicle overtaking control device 100 may include a configuration shown in FIG. 2 .

2 is a diagram illustrating an example of a configuration of a vehicle overtaking control device according to an embodiment of the present invention.

Referring to FIG. 2 , the vehicle overtaking control device 100 of the present invention may include a server communication unit 110 , a server storage unit 130 and a server control unit 150 .

The server communication unit 110 may include a component supporting a communication function of the vehicle overtaking control device 100 . For example, the server communication unit 110 may communicate with the roadside base station network 51 to form a communication channel with the plurality of vehicles 201 , 202 , 203 , and 204 . The server communication unit 110 transmits various pieces of information for overtaking control of the vehicles 201, 202, 203, and 204, for example, the road on which the vehicles 201, 202, 203, and 204 are running (e.g., driving lane 59a). ) and overtaking lane 59b), current location information of vehicles 201, 202, 203, 204, autonomous driving route information between the destination and starting point of vehicles 201, 202, 203, 204, Speed setting information of the vehicles 201 , 202 , 203 , and 204 on the autonomous driving route may be received and stored in the server storage unit 130 under the control of the server controller 150 . The server communication unit 110 collects and processes information periodically transmitted by the vehicles 201, 202, 203, and 204 through 1:N communication with the vehicles 201, 202, 203, and 204, and 201, 202, 203, 204) may transmit a command for safety management.

The server storage unit 130 may store information related to driving (eg, autonomous driving) and overtaking control of the vehicles 201 , 202 , 203 , and 204 . In this regard, the server storage unit 130 stores current location information and speed setting information of the vehicles 201 , 202 , 203 , and 204 received by the server communication unit 110 from the vehicles 201 , 202 , 203 , and 204 . etc. can be stored. In addition, the server storage unit 130 may store speed limit information of the road and safety distance information between vehicles according thereto. In addition, the server storage unit 130 may store information about a vehicle that needs to be overtaken among the vehicles 201 , 202 , 203 , and 204 , information about a vehicle that fails to overtake, and information about a vehicle that succeeds in overtaking.

The server controller 150 determines the locations of the vehicles 201, 202, 203, and 204 in relation to autonomous driving and overtaking of the plurality of vehicles 201, 202, 203, and 204 located within the roadside base station network 51. It collects information and speed setting information, considers whether or not the vehicles 201, 202, 203, and 204 need to overtake based on this, executes overtaking for a vehicle that needs to overtake, and adjusts the speed of the side and rear vehicles accordingly. You can control to control. In this regard, the server controller 150 may include a collection module 151, a resource configuration management module 153, a resource state management module 155, a stability management module 157, and a control module 159. .

The collection module 151 collects vehicle information periodically transmitted by vehicles 201 , 202 , 203 , and 204 and transmits it to the resource configuration management module 153 and the resource state management module 155 . Data transmitted to the resource configuration management module is information necessary for vehicle overtaking control, such as IP and port information for communication with vehicles 201, 202, 203, and 204, location information related to vehicle GPS information, and speed information. The information collected by the collection module 151 may be stored in a database included in the server storage unit 130 through the resource configuration management module 153 and the resource state management module 155 .

The resource configuration management module 153 stores information collected from vehicles 201, 202, 203, and 204 in conjunction with a database included in the server storage unit 130, and manages information necessary for safety management by managing resource states. It serves to pass to the module 155. The resource configuration management module 153 provides lane information of vehicles 201, 202, 203, and 204 with GPS information collected from the vehicle 200, location information in the corresponding lane, and positional relationship information with surrounding vehicles. You can check. The resource configuration management module 153 periodically updates and manages the information collected from the vehicles 201, 202, 203, and 204 in the database of the server storage unit 130, and when there is a request for history data, the DB (Database) is retrieved and transmitted. Basic information related to the road can be directly stored and managed by the RSU. The resource configuration management module 153 determines that the vehicles 201, 202, 203, and 204 are out of the RSU range (or out of the control range for vehicle overtaking control). Among the vehicles 201 , 202 , 203 , and 204 , in the case of a vehicle out of the RSU range, the resource configuration management module 153 may delete corresponding vehicle information from the database of the server storage unit 130 . The resource configuration management module 153 transfers the vehicle information stored in the server storage 130 to the resource state management module 155 to calculate information for supporting processing related to overtaking and acceleration/deceleration of the vehicle in terms of stability. convey At this time, the transmitted information may include lane information, nearby vehicle information, speed, and location information.

The resource state management module 155 detects the amount of change in speed of the vehicles 201, 202, 203, and 204 for the safety of the vehicles 201, 202, 203, and 204 based on vehicle information received periodically, and the preceding vehicle , comparison of the speed difference between the vehicles behind, and periodic monitoring of the state of the vehicle through the positional relationship with the vehicle on the side. The resource state management module 155 is a resource configuration management module (153 ), or previous speed data of vehicles, environment information related to lane information, vehicle surrounding information, etc. may be collected from the resource configuration management module 153. The resource state management module 155 calculates an accident risk or transfers information related to overtaking and deceleration to the stability management module 157. To this end, the resource state management module 155 uses the stability management module 157 to determine the speed and location of other vehicles adjacent to the center of the specific vehicle, lane information of the specific vehicle, a front list of the specific vehicle, a rear vehicle list of the specific vehicle, and Speed and location information of a specific vehicle can be provided.

The stability management module 157 is a module that calculates the risk of an accident through calculation related to the safety of the vehicles 201 , 202 , 203 , and 204 . The stability management module 157 may perform collision risk comparison, vehicle deceleration calculation, and overtaking range calculation. The stability management module 157 requests speed and location information between the two vehicles to the resource state management module 155 in order to compare the risk of collision between the two vehicles, and then returns whether or not a collision is possible as a result. The stability management module 157 requests the speed and distance information of the front and rear vehicles to the resource state management module 155 to calculate the deceleration of the vehicles 201, 202, 203, and 204, and as a result, the vehicle's Returns the deceleration speed. To calculate the overtaking range and overtaking possibility, the stability management module 157 requests information on the current vehicle, the preceding vehicle and the vehicle in the next lane according to the speed to the resource state management module 155, and as a result, the overtaking range and overtaking possibility returns The stability management module 157 may transmit related setting change information to the control module 159 when vehicle setting is required as a result of the calculation. As described above, the stability management module 157 may monitor the surrounding environment for overtaking control of a specific vehicle (eg, a vehicle with a higher speed than the preceding vehicle) and perform calculations for controlling vehicles for overtaking control.

The control module 159 is a part that processes commands related to controlling the vehicles 201 , 202 , 203 , and 204 . The control module 159 controls lane change, overtaking, acceleration/deceleration, etc. of the vehicles 201, 202, 203, 204 based on information received from the resource state management module 155 and the stability management module 157 can do. That is, the control module 159 transmits a message and a control command to a vehicle requiring control for vehicle safety, and transmits the message to the vehicle through the roadside base station network 51 so that the vehicle can execute the corresponding command of the RSU. . The control module 159 may instruct the vehicle's lane change timing calculated by the stability management module 157 and a deceleration command for the vehicle and surrounding vehicles during this process. The control module 159 may issue a command to maintain the current lane and speed of the vehicle as a result of the stability management module 157 calculation. The control module 159 may induce a lane change of the vehicle according to a control sequence when overtaking is performed as a result of calculating an overtaking range.

3 is a diagram showing an example of a vehicle configuration according to an embodiment of the present invention.

Referring to FIG. 3 , a vehicle 200 according to an embodiment of the present invention may correspond to at least one of the vehicles 201 , 202 , 203 , and 204 described above with reference to FIG. 1 . The vehicle 200 may include a vehicle communication unit 210, a GPS module 220, a vehicle storage unit 230, a display 240, an accelerator 260, a steering device 270, and a vehicle controller 250. can Additionally, the vehicle 200 may further include a power device (eg, a battery) that generates power necessary for operating the accelerator. In addition, the vehicle 200 may further include various devices (eg, a vehicle body, power means (eg, wheels and axles, etc.) driven by power generated by the power unit, brake devices, etc.).

The vehicle communication unit 210 may be configured to support a communication function of the vehicle 200 . The vehicle communication unit 210 may form a communication channel with, for example, the roadside base station network 51 and provide vehicle information to the vehicle overtaking control device 100 . The vehicle communication unit 210 may transmit a control signal provided by the vehicle overtaking control device 100 to the vehicle controller 250 . Also, the vehicle communication unit 210 may provide current location information collected by the GPS module 220 to the vehicle overtaking control device 100 .

The GPS module 220 may obtain current location information of the vehicle 200 using the GPS satellite 52 . The GPS module 220 may provide the acquired current location information of the vehicle 200 to the vehicle overtaking control device 100 under control of the vehicle controller 250 .

The vehicle storage unit 230 may store various data and programs necessary for driving the vehicle 200 . For example, the vehicle storage unit 230 may store location information and speed information of the vehicle 200 . In addition, the vehicle storage unit 230 may store source information and destination information according to user settings, travel time setting information from the source to the destination, and user desired travel speed. The vehicle storage unit 230 may store at least one control signal provided by the vehicle overtaking control device 100 . The vehicle storage unit 230 may store an autonomous driving algorithm for autonomous driving of the vehicle 200 .

The display 240 may output at least one screen related to driving of the vehicle 200 . For example, the display 240 may display a screen showing the on-off state of the vehicle 200, a screen showing the autonomous driving state, an input screen of at least one of a starting point and a destination for route planning, and a moving time constraint input screen. can be printed out. Also, the display 240 may output information received from the vehicle overtaking control device 100 . For example, the display 240 may display, in real time, information on surrounding roads of a location where the vehicle 200 is located, current location information of other vehicles on the surrounding roads, an overtaking state or an overtaking situation of other vehicles, and the like.

The acceleration device 260 may adjust acceleration or deceleration of the vehicle 200 . For example, the accelerator 260 may include, for example, an accelerator. The accelerator 260 may be adjusted without user manipulation (or automatically) according to the control of the vehicle overtaking control device 100 during autonomous driving of the vehicle 200 .

The steering device 270 may include a handle for adjusting the direction of the vehicle 200 . In addition, the steering device 270 may support light control related to direction control of the vehicle 200 . The steering device 270 may be automatically (or without user manipulation) controlled by the vehicle overtaking control device 100 during autonomous driving of the vehicle 200 .

The vehicle control unit 250 provides information to the vehicle overtaking control device 100 in relation to overtaking control of the vehicle 200, and accelerates, decelerates, and direction according to a control signal received from the vehicle overtaking control device 100. You can control steering, lane change, and more. For example, when the vehicle 200 is located in an area managed by the vehicle overtaking control device 100 (eg, an area where RSU communication is possible) and in an autonomous driving state, the vehicle control unit 250 provides identification information of the vehicle 200; Current location information of the vehicle 200 and acceleration state information of the vehicle 200 may be provided to the vehicle overtaking control device 100 . Also, the vehicle controller 250 may provide speed setting information of the vehicle 200 to the vehicle overtaking control device 100 . The speed setting information is the speed at which the vehicle 200 should move on a road within the current management area, and may be determined by a user-inputted travel request time between a starting point and a destination, or may be determined by user-inputted speed information. The speed setting information may be adjusted according to road conditions or the vehicle overtaking control device 100 .

Additionally, the vehicle 200 may further include an input unit. For example, the input unit may include a touch screen. In addition, the input unit may include a microphone to support voice input and an audio processor capable of processing recognition of an input voice.

4 is a diagram illustrating an example of a signal flow between components of a vehicle overtaking control device related to vehicle overtaking control according to an embodiment of the present invention.

Referring to FIG. 4 , the signal flow between each component for overtaking control of vehicles of the vehicle overtaking control apparatus of the present invention is, first, in step 401, the collection module 151 detects vehicles 201 and 202 within the management area of the RSU. , 203, 204) is entered, vehicle information is collected through the RSU, and the corresponding information is transmitted to the resource configuration management module 153 and the resource state management module 155.

In step 403, the resource configuration management module 153 stores the vehicle information delivered by the collection module 151 in the DB of the server storage unit 230.

In step 405, the resource state management module 155 requests and receives history data of the vehicles 201, 202, 203, and 204 from the resource configuration management module 153, and analyzes the received vehicle speed data. In step 407, the resource state management module 155 may perform speed comparison between the speed of the entering vehicle and the vehicle ahead of the entering vehicle.

If the speed of the approaching vehicle is higher than that of the preceding vehicle, in step 409, the stability management module 157 may compare the risk of collision between the entering vehicle and the preceding vehicle. When there is no risk of collision, the control module 159 may transmit a current lane and speed maintenance command to each of the vehicles 201 , 202 , 203 , and 204 in step 411 . Meanwhile, in step 407, as a result of comparing the speeds of the preceding vehicle and the approaching vehicle, even if the approaching vehicle is later than the preceding vehicle, the control module 159 determines the current status of each of the vehicles 201, 202, 203, and 204 in step 411. It can handle lane and speed maintenance commands.

On the other hand, in step 409, in the collision risk comparison process with the preceding vehicle, if there is a collision risk, the stability management module 157 transfers it to the resource state management module 155, and the resource state management module 155 In step 413, the intention of the vehicle to overtake may be confirmed. In this regard, the vehicle overtaking control apparatus 100 sends a message asking whether to perform an overtaking operation to the preceding vehicle, and when receiving an overtaking progress in response to the message, it is determined that the approaching vehicle has the intention to overtake. can Alternatively, the entering vehicle checks the arrival time and current time to its destination and maintains the current driving speed or, when the driving speed needs to be increased, provides a message including a willingness to overtake to the vehicle overtaking control device 100. can do.

In step 413, if the approaching vehicle has no intention of overtaking (or if the approaching vehicle gives up overtaking), in step 415, the stability management module 157 calculates the amount of deceleration of the approaching vehicle and transmits it to the control module 159. , The control module 159 may deliver a message including a deceleration command to the entering vehicle in step 417 . An entering vehicle receiving a deceleration command may perform vehicle deceleration in response to the deceleration value calculated by the stability management module 157 . Thereafter, the entering vehicle may maintain the current lane and speed in step 411 .

In step 413, when the overtaking intention of the vehicle is confirmed, when there is an overtaking intention, or when a message is received indicating a situation in which the entering vehicle must maintain the current speed or accelerate above the current speed, the resource state management module 155 In step 419, the speed and location of the overtaking vehicle may be checked.

In step 421, the resource state management module 155 may check the current lane of the entering vehicle. If the current lane of the approaching vehicle is a normal lane (or driving lane 59a), in step 423, the stability management module 157 may calculate a vehicle overtaking range according to the speed of the approaching vehicle. In step 425, the stability management module 157 may check whether the overtaking lane can be changed. In this regard, the stability management module 157 may check whether there is another vehicle in the adjacent overtaking lane 59b and, if there is another vehicle, whether the approaching vehicle may overlap during an overtaking operation. If the overtaking lane change is possible, in step 427, the control module 159 creates a message for inducing a lane change (eg, lane change from the driving lane 59a to the overtaking lane 59b) and transmits the message to the approaching vehicle. . Then, the stability management module 157 may calculate a vehicle overtaking range according to the speed. Meanwhile, in step 421, when the current lane is an overtaking lane, the stability management module 157 directly enters step 429 and may calculate the vehicle overtaking range according to the speed.

Next, in step 431, the stability management module 157 may check whether the general lane (or driving lane 59a) can be changed. That is, the stability management module 157 may check whether a collision with another vehicle driving in the driving lane 59a may occur in the process of changing the lane from the overtaking lane 59b to the driving lane 59a. If a normal lane change is possible in step 431, in step 433, the control module 159 creates a message for inducing a lane change (eg, lane change from the overtaking lane 59b to the driving lane 59a) and delivers it to the approaching vehicle. can When the entering vehicle changes lanes from the overtaking lane 59b to the driving lane 59a, it branches to step 411 to process the current lane and speed maintenance.

In step 431, if normal lane change is impossible, the stability management module 157 calculates the amount of deceleration of the entering vehicle in step 435, and the control module 159 creates a deceleration command message for the entering vehicle in step 437 to enter the vehicle. can be forwarded to Thereafter, the vehicle overtaking control apparatus 100 may add the entering vehicle to the overtaking failure list in step 439 and then execute an overtaking control algorithm. That is, the vehicle overtaking control device 100 may check whether a vehicle moving from the overtaking lane 59b can change lanes to the driving lane 59a, and control the approaching vehicle to change lanes when possible. Alternatively, the vehicle overtaking control device 100 checks whether overtaking is possible when an approaching vehicle moving in the overtaking lane 59b has a risk of colliding with another vehicle in front of the overtaking lane 59b, and It is also possible to control the overtaking operation in . The vehicle overtaking control apparatus 100 may control the vehicle to attempt until overtaking is successful.

5 is a diagram illustrating an example of overtaking execution according to vehicle overtaking control according to an embodiment of the present invention.

Referring to FIG. 5 , in the vehicle overtaking control environment 11, the vehicle overtaking control device 100 includes vehicles 201 including a GPS module and a communication module capable of communicating with the RSU (or roadside base station network 51). , 202, 203, 204 and periodically communicate with each vehicle (201, 202, 203, 204) information is collected. The vehicle overtaking control device 100 may manage the road by dividing it into virtual lines having a predetermined standard. The vehicle overtaking control apparatus 100 defines the occupied virtual areas 201a, 202a, 203a, and 204a of each of the vehicles 201, 202, 203, and 204 according to the vehicle speed, and if the occupied virtual areas 201a and 202a , 203a, 204a) are judged to have a collision risk if they overlap. For example, an area 209 may exist where a part of the second occupied virtual area 202a of the second vehicle 202 and a part of the fourth occupied virtual area 204a of the fourth vehicle 204 overlap. If this overlapping area 209 exists, the vehicle overtaking control device 100 may determine that there is a risk of collision between the second vehicle 202 and the fourth vehicle 204 . Meanwhile, the occupied virtual areas 201a, 202a, 203a, and 204a may have different sizes according to the moving speed of vehicles.

In the illustrated figure, it may be regarded as a situation in which the fourth vehicle 204 has entered a management area where the vehicle overtaking control device 100 manages control of vehicles through the roadside base station network 51 . In this case, the vehicle overtaking control device 100 calculates the speed difference between the second vehicle 202 and the fourth vehicle 204 to determine whether there is a risk of a collision, and if there is no risk of a collision, each vehicle ( 201, 202, 203, 204) can be controlled to maintain the current lane and speed.

If a collision due to a speed difference between the fourth vehicle 204 and the second vehicle 202 is expected, the vehicle overtaking control apparatus 100 performs overtaking of the fourth vehicle 204 through the virtual path 204b. can be controlled as much as possible.

Here, the vehicle overtaking control device 100 may determine overtaking failure of the fourth vehicle 204 according to the speeds and positions of the first vehicle 201 and the third vehicle 203 . In the overtaking failure process, the vehicle overtaking control apparatus 100 performs a first step so that a space as much as the fourth occupied virtual area 204a of the fourth vehicle 204 is secured between the first vehicle 201 and the second vehicle 202 . Adjusting the speed of the vehicle 201 (eg, accelerating the first vehicle 201), while the fourth vehicle 204 overtakes and enters between the first vehicle 201 and the second vehicle 202 ( Example: Overtaking virtual path 204b) Adjusting the speed of the third vehicle 203 so that the third occupied virtual area 203a and the fourth occupied virtual area 204a of the third vehicle 203 do not overlap (eg, the third occupied virtual area 203a). acceleration of the vehicle 203) may be controlled.

Alternatively, after controlling the deceleration of the fourth vehicle 204 through deceleration calculation, the vehicle overtaking control apparatus 100 may control attempting to overtake again when a predetermined time elapses.

As described above, the vehicle overtaking control apparatus 100 performs overtaking and driving based on the calculated result based on the positions of the vehicles 201, 202, 203, and 204, the moving speed, the size of the occupied virtual area, and the virtual path. You can slow down and change lanes. Here, the vehicle overtaking control apparatus 100 is no longer involved in a vehicle outside the management area defined as a communication range through the roadside base station network 51 .

6 is a diagram illustrating an example of a method of operating a vehicle overtaking control device related to vehicle overtaking control according to an embodiment of the present invention.

Referring to FIG. 6 , according to the operating method of the vehicle overtaking control device according to an embodiment of the present invention, in step 601, the vehicle overtaking control device 100 checks a management area defined as a communication range for vehicle overtaking control. and collect vehicle information about vehicles within the management area.

In step 603, the vehicle overtaking control device 100 may determine whether there is a vehicle that needs to be overtaken. In order to identify a vehicle that needs to be overtaken, the vehicle overtaking control device 100 may define occupied virtual regions of vehicles based on the collected vehicle information, and determine whether there is a vehicle that overlaps the occupied virtual regions assigned to each vehicle.

When there are vehicles with overlapping occupied virtual areas, in step 605, the vehicle overtaking control apparatus 100 may perform overtaking control of a rear vehicle. Regarding the overtaking control of the rear vehicle, the vehicle overtaking control apparatus 100 sets a virtual path according to overtaking of the rear vehicle, and sets a virtual path moving from the driving lane to the front of the preceding vehicle via the overtaking lane. can

Meanwhile, in step 603, when there is no vehicle requiring overtaking, that is, when the occupied virtual areas do not overlap, in step 607, the vehicle overtaking control apparatus 100 may control the current speed and lane keeping of each vehicle.

Next, in step 609, the vehicle overtaking control device 100 may determine whether there is a vehicle within the management area. When there is no vehicle in the management area, the vehicle overtaking control apparatus 100 may end the vehicle overtaking control. If there is a vehicle in the management area, it branches to step 601 and can be controlled to re-perform the following operation.

As described above, the operating method of the vehicle overtaking control device according to an embodiment of the present invention performs overtaking control of a vehicle equipped only with GPS and network communication equipment through a communication system (eg, RSU) capable of communicating with vehicles. It is possible to support more improved and stable vehicle overtaking control by detecting the risk of vehicle collision based on whether the virtual areas occupied by vehicles overlap or not, and performing overtaking control of the rear vehicle.

On the other hand, the embodiments disclosed in this specification and drawings are only presented as specific examples to aid understanding, and are not intended to limit the scope of the present invention. In addition to the embodiments disclosed herein, it is obvious to those skilled in the art that other modifications based on the technical idea of the present invention can be implemented.

10: vehicle overtaking control system
51: network
52: GPS satellites
100: vehicle overtaking control device
110: server communication unit
130: server storage unit
150: server control unit
151: collection module
153: resource configuration management module
155: resource state management module
157: stability management module
159: control module
200, 201, 202, 203, 204: vehicle
210: vehicle communication department
220: GPS module
230: vehicle storage unit
240: display
250: vehicle control unit
260: accelerator
270: steering device

Claims (10)

collecting, by a vehicle overtaking control device, vehicle information of a plurality of vehicles located within a vehicle driving management area defined as a communication range of a roadside base station;
storing the collected vehicle information;
setting occupied virtual areas on the road on which each vehicle is driving based on the stored vehicle information;
Setting an overtaking virtual path for a second vehicle behind the first vehicle and the second vehicle in which the occupied virtual areas overlap;
The step of setting the overtaking virtual path
After moving from the driving lane in which the second vehicle travels to the overtaking lane, a path moving in front of the first vehicle is set, wherein the first occupied virtual area of the first vehicle and the second occupied virtual area of the second vehicle are set. The method of controlling vehicle overtaking, characterized in that the overtaking virtual path is set so that the areas do not overlap. According to claim 1,
The vehicle overtaking control method of claim 1 , further comprising checking moving speeds of the plurality of vehicles and setting different sizes of the occupied virtual regions according to the moving speeds. According to claim 2,
and setting a size of a virtual region occupied by a vehicle having a relatively fast moving speed among the plurality of vehicles to be larger than a virtual region occupied by a vehicle having a relatively slow moving speed; method. According to claim 1,
When a third vehicle exists in front of the first vehicle, the distance between the first occupied virtual area of the first vehicle and the third occupied virtual area of the third vehicle is the second occupied virtual area of the second vehicle. and adjusting the moving speed of the third vehicle to be greater than the size of the vehicle overtaking control method. According to claim 1,
When a fourth vehicle exists in the overtaking lane of the overtaking virtual path, the second occupied virtual area of the second vehicle does not overlap with the fourth occupied virtual area of the fourth vehicle while moving along the virtual path. The vehicle overtaking control method further comprising adjusting the moving speed of the fourth vehicle. a server communication unit that communicates with the furnace wall base station;
a server storage unit for storing information received through the server communication unit;
Including; a server control unit functionally connected to the server communication unit and the server storage unit;
The server control unit
Collecting vehicle information of a plurality of vehicles located in a vehicle driving management area defined by a communication range of the roadside base station;
Store the collected vehicle information,
Based on the stored vehicle information, occupied virtual areas on the road on which each vehicle is traveling are set;
Setting an overtaking virtual path for a second vehicle rearward among the first and second vehicles overlapping the occupied virtual areas;
In the process of setting the overtaking virtual path, after moving from the driving lane in which the second vehicle travels to the overtaking lane, a path moving in front of the first vehicle is set, wherein the first occupied virtual area of the first vehicle and setting the overtaking virtual path so that the overtaking virtual path does not overlap with the second occupied virtual area of the second vehicle. According to claim 6,
The server control unit
The vehicle overtaking control apparatus of claim 1 , wherein moving speeds of the plurality of vehicles are checked, and sizes of the occupied virtual areas are set differently according to the moving speeds. According to claim 7,
The server control unit
The vehicle overtaking control device of claim 1 , wherein a size of a virtual region occupied by a vehicle having a relatively fast moving speed among the plurality of vehicles is set larger than a virtual region occupied by a vehicle having a relatively slow moving speed. According to claim 6,
The server control unit
When a third vehicle exists in front of the first vehicle, the distance between the first occupied virtual area of the first vehicle and the third occupied virtual area of the third vehicle is the second occupied virtual area of the second vehicle. The vehicle overtaking control device, characterized in that for adjusting the moving speed of the third vehicle to be greater than the size of. According to claim 6,
The server control unit
When a fourth vehicle exists in the overtaking lane of the overtaking virtual path, the second occupied virtual area of the second vehicle does not overlap with the fourth occupied virtual area of the fourth vehicle while moving along the virtual path. A vehicle overtaking control device characterized in that it adjusts the moving speed of the fourth vehicle.

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