KR100902371B1 - Dedicated Short Range Communication system and control method - Google Patents

Abstract

The DSRC system according to the present invention includes a link ID storage unit for storing a link ID of a DSRC terminal that transmits a connection request signal; And when the access request signal is received from the DSRC terminal, determines whether a link ID of the DSRC terminal which transmits the access request signal exists in the link ID storage unit. It includes the IKE module that stores the link ID storage unit and transmits it to the TKE module. By reducing the connection retries of the DSRC terminal by improving the connection success rate, the burden on the processing speed of subsequent business processes can be reduced. In addition, the network load can be reduced because the stability of the system can be secured by reducing the number of transmitted and received packets.

Description

DSR system and its control method {Dedicated Short Range Communication system and control method}

The present invention relates to a dedicated short range communication (DSRC) system and a control method thereof.

Since the 1990s, the popularity of automobiles has brought about the convenience of bringing convenience to people's lives, while the negative aspects of traffic congestion, accidents, and pollution are not overlooked. A more balanced development of infrastructure is required.

Information and communication technology as a foundation system has emerged as a core technology for solving the transportation problems in the 21st century.

As the number of automobiles increased by more than 20% every year, the economic loss due to chronic and nationwide road traffic congestion of 14 million cars soared from 760 billion won in 1988 to 12 trillion won in 1998, accounting for 3% of the total GNP. In 2000, it is expected to reach 20 trillion won.

The driver doesn't know why the roads on the road are blocked, how long the bypass is available, the public transit doesn't know when the bus arrives and where to change it, and the carriers don't know the location or transportation of their trucks. I don't know the time required.

Therefore, it is necessary to introduce ITS (Intelligent Transport System) which can expect more effective transportation effect using information technology, communication technology, sensor technology and control technology as a public society infrastructure supporting social life and economic activities. Do.

This will facilitate the flow of information between components of traffic systems such as roads, cars, and users, thereby improving disconnected traffic flows, minimizing logistics costs for traffic users, and shortening and utilizing travel time.

In order to build an intelligent transportation system, it is essential to introduce a system that collects and efficiently distributes high-quality traffic information.

ITS-only short-range wireless communication technology provides point-to-point or point-to-point communication between roadside base stations with communication ranges of several meters to hundreds of meters and on-board devices passing through these areas. Multipoint) As a two-way high-speed communication technology, unlike a public wireless communication network, it has the advantage of providing a relatively simple base station system to a vehicle running on the road and providing a cheap service to a user as a low-cost communication terminal. In addition, traffic information can be collected at low cost, enabling smooth distribution of human and material resources.

Representative short-range wireless communication technology applied to the current ITS service can be classified into a beacon method and a dedicated short-range communication (DSRC) communication method according to its purpose.

Beacon communication method is a low-speed (10Kbps or less) communication system mainly for one-way service (base station-> terminal, terminal-> base station) between the roadside base station and the vehicle terminal, it is possible to restrict bidirectional communication.

ITS-only short-range wireless communication (DSRC) technology using current information and communication technology has emerged as an alternative.

These DSRC methods are classified into passive DSRC and active DSRC.

The typical passive DSRC communication method currently presented has a communication cell size of a vehicle terminal and a roadside base station within 10 meters, a frequency band of 5.8 GHz band, and a maximum data rate of 500 Kbps for downlink and 250 Kbps for uplink.

This communication method supports multiple vehicle terminals and multiple access between the vehicle terminal and the roadside base station. However, half-duplex communication is performed because CW (continuous wave) of the base station must be provided when configuring uplink. Due to power, the distance between roadside base stations for frequency reuse should be more than 260 meters.

In addition, this method has a disadvantage that the cell size is limited to the ITS service within 10 meters.

On the other hand, the active DSRC communication method, which is being actively studied mainly in the United States and Japan, has a communication cell size of several meters to several hundred meters (m) and a frequency band in wireless data communication between a vehicle terminal and a roadside base station. It uses the 5.8GHz band and the data rate is a wireless packet communication method with a bidirectional link of 1Mbps or more.

This communication method supports one roadside base station to support multiple vehicle terminals and multiple accesses, and the distance between roadside base stations for frequency reuse is at least 60 meters. .

Active DSRC system can be used in general land transportation, as well as aircraft takeoff and landing, ship safety and distress ship rescue, and improves the efficiency of use of existing communication services such as personal mobile communication, pager, etc. Can be provided.

Such a conventional DSRC system is composed of at least one DSRC terminal 20, DSRC base station 10, as shown in Figure 1, the DSRC base station 10 is the IKE module 200, TKE module 300 ) And an Application module 400.

In the conventional DSRC system, when the DSRC base station 10 receives a connection request signal from the DSRC terminal 10, the IKE module 200 of the DSRC base station 10 receives a connection response signal (BST) from the TKE module 300. To send).

Then, the TKE module 300 transmits a connection response signal (BST) to the DSRC terminal 20.

Subsequently, the DSRC terminal 20 transmits its access information signal VST to the DSRC base station 10. At this time, the access information signal (VST) transmitted from the DSRC terminal 20 is transmitted to the TKE module 300 of the DSRC base station 10 and again to the application module 400.

Then, the application module 400 transmits an application information signal for charging of the corresponding DSRC terminal 20 to the TKE module 300.

Subsequently, the TKE module 300 transmits an application information signal GET to the DSRC terminal 20. In this case, the application information signal includes information for charging of the terminal, and the information of the application varies in size depending on the application information, but occupies a substantial portion.

Then, the DSRC terminal 20 transmits an Application response signal corresponding to the Application information to the DSRC base station 10.

Thereafter, the DSRC base station 10 calculates the charging of the DSRC terminal 20 and transmits a charging request signal to the DSRC terminal 20.

Then, the charging result signal is transmitted from the DSRC terminal 20 to the DSRC base station 10.

Subsequently, the DSRC base station 10 transmits the information signal of the corresponding office to the DSRC terminal 20, and the corresponding DSRC terminal 20 transmits the response signal to the DSRC base station 10.

Thereafter, the DSRC base station 10 ends the communication by transmitting a connection termination signal to the DSRC terminal 20.

When the DSRC base station having a communication process performs DSRC communication with one DSRC terminal, no particular problem occurs.

However, as shown in FIG. 1, even when the DSRC base station 10 receives a second access request signal from another DSRC terminal 20-1 while the DSRC base station and an arbitrary DSRC terminal perform DSRC communication, the DSRC base station 10. 10 performs DSRC communication according to a scheduling.

In this case, while the DSRC base station 10 performs the DSRC communication according to the scheduled scheduling, the other DSRC terminal 20-1 transmitting the second access request signal to the DSRC base station 10 waits for a predetermined time and then accesses the DSRC base station 10. If the response signal BTC is not received, the secondary or tertiary access request signal is retransmitted to the DSRC base station 10 again.

In this way, the DSRC terminal 20-1 repeatedly transmits the access request signal to the DSRC base station 10 when the access response signal is not received within a predetermined time after transmitting the access request signal to the DSRC base station 10. There is a problem that a load occurs in the DSRC terminal 20-1.

As the DSRC base station also repeatedly receives the access request signal from the DSRC terminal, the DSRC base station must process (delete or respond) it, and if the DSRC base station repeatedly receives the access request signal as described above from the plurality of DSRC base stations, There was a problem with load.

In addition, there may be a problem that the transmission of the access response signal (BST) and the access information signal (VST) is delayed if there is data to be transmitted and received simultaneously based on the TKE module of the DSRC base station.

In this case, when the access response signal is delayed, the application of the DSRC terminal determines that the transmission of the access request signal has failed, and transmits the access request signal again.

When the transmission of the access information signal is delayed, the application of the DSRC terminal determines that the transmission of the access information signal VST has failed when the reception of the first application signal is delayed, and transmits the access request signal VST again. There was a problem starting from the first step.

Accordingly, the present invention is to solve the above-mentioned problems, the object of the present invention is to improve the response speed of the DSRC wireless communication connection to determine the connection failure in the DSRC terminal so as not to request a reconnection by the connection success rate of DSRC communication It is to provide a DSRC system and a control method for improving the system.

According to an aspect of the DSRC system according to the present invention for achieving the above object, a link ID storage unit for storing the link ID of the DSRC terminal transmitting the access request signal; And when the access request signal is received from the DSRC terminal, determines whether a link ID of the DSRC terminal which transmits the access request signal exists in the link ID storage unit. It includes the IKE module that stores the link ID storage unit and sends it to the TKE module.

Further, the TKE module checks whether a connection response signal is received from the IKE module while transmitting or receiving an application information signal or an application response signal with an application module, and receives a connection response signal of a new DSRC terminal from the IKE module. When the application information signal or application response signal being processed is processed, the new DSRC terminal access response signal is processed.

When the TKE module receives the access information signal from the DSRC terminal, the TKE module determines whether a link ID of the DSRC terminal stored in the link ID storage unit exists, while the link ID of the DSRC terminal is stored in the link ID storage unit. If so, delete the link ID and transmit the received access information signal to the application module.

The TKE module transmits the received access information signal to the corresponding application module if the link ID of the DSRC terminal that transmitted the access information signal does not exist in the link ID storage unit.

According to an aspect of the DSRC communication control method according to the present invention, when the IKE module of the DSRC base station receives the access request signal from the DSRC terminal, the DSRC is stored through the TKE module after storing the link ID of the DSRC terminal transmitting the access request signal. Transmitting a connection response signal to a terminal; When the TKE module of the DSRC base station receives the access information signal from the DSRC terminal, deleting the link ID of the stored DSRC terminal and transmitting the access information signal to the application module; And communicating, by the Application module of the DSRC base station, the DSRC data with the DSRC terminal through the TKE module.

 The application module of the DSRC base station to communicate the DSRC data with the DSRC terminal through the TKE module, the TKE module of the DSRC base station to determine whether the access request signal received from the new DSRC terminal while performing the DSRC data communication step; And when a new connection request signal is received in the step of determining whether a connection request signal received from the new DSRC terminal is received, the new DSRC terminal after processing the transmission and reception of an application information signal or an application response signal being processed by the TKE module. And processing a connection request signal of the TKE module, if the new connection request signal is not received in the step of determining whether a connection request signal received from the new DSRC terminal is received. And transmitting to the application module 400.

And when the TKE module of the DSRC base station receives the access information signal from the DSRC terminal, deleting the link ID of the stored DSRC terminal and transmitting the access information signal to the application module, wherein the TKE module access information from the DSRC terminal. Determining whether a link ID of a DSRC terminal stored in the link ID storage unit exists when receiving a signal; And if there is a link ID of the DSRC terminal in the step of determining the existence of the link ID of the DSRC terminal, the TKE module deletes the link ID of the DSRC terminal and transmits the received access information signal to the application module. If the link ID of the DSRC terminal does not exist in determining the existence of the link ID of the DSRC terminal, the TKE module includes transmitting the received access information signal to a corresponding application module.

As described above, according to the DSRC system and the control method thereof according to the present invention, by reducing the number of connection request retries of the DSRC terminal by improving the connection success rate, it is possible to reduce the burden on the subsequent processing speed, and Since the number of packets can be reduced to ensure the stability of the system, there is an excellent effect of reducing the network load.

Hereinafter, exemplary embodiments of a DSRC system and a control method thereof according to the present invention will be described in detail with reference to the accompanying drawings. At this time, it will be understood by those of ordinary skill in the art that the system configuration described below is a system cited for the purpose of the present invention and does not limit the present invention to the following system.

2 is a view showing the configuration of a DSRC system according to the present invention, the DSRC system according to the present invention includes a link ID storage unit 100, IKE module 200, TKE module 300 and Application module 400 It includes a DSRC base station 10, at least one DSRC terminal 20.

First, the link ID storage unit 100 stores the link ID of the DSRC terminal 20 that transmits the access request signal.

When the access request signal is received from the DSRC terminal 20, the IKE module 200 determines whether there is a link ID of the DSRC terminal 20 that transmits the access request signal to the link ID storage unit 100. If not, the link ID of the DSRC terminal 20 that transmits the access request signal is stored in the link ID storage unit 100 and then transmitted to the TKE module 300.

In addition, the TKE module 300 checks whether a connection response signal is received from the IKE module 200 while transmitting and receiving an application information signal or an application response signal with the application module 400, and the IKE module 200. When the connection response signal of the new DSRC terminal 20-1 is received, the transmission and reception of the application information signal or the application response signal being processed are processed and the connection response signal of the new DSRC terminal 20-1 is processed.

The TKE module 300 determines whether a link ID of the DSRC terminal 20 stored in the link ID storage unit 100 exists when receiving the access information signal from the DSRC terminal 20, and stores the link ID. If the link ID of the corresponding DSRC terminal 20 is stored in the unit 100, the link ID is deleted and the received connection information signal is transmitted to the application module 400, and the DSRC terminal has transmitted the access information signal. If the link ID of 20 does not exist in the link ID storage unit 100, the received access information signal is transmitted to the corresponding application module 400.

General functions and respective detailed operations of the above-described components will be omitted, and the operations will be described with reference to FIGS. 3A and 3B based on the operations corresponding to the present invention.

First, the DSRC terminal 20 transmits the access information signal BST to the IKE module 200 of the DSRC base station 10. Here, the access information signal transmitted by the DSRC terminal 20 to access the DSRC base station 10 is transmitted to the IKE module 200.

Then, the IKE module 200 of the DSRC base station 10 stores the link ID of the DSRC terminal 20 transmitting the access response signal in the link ID storage unit 100, and stores the access response signal in the TKE module. Send to 300.

Subsequently, the TKE module 300 transmits a connection response signal BST to the DSRC terminal 20.

Thereafter, the DSRC terminal 20 transmits a access information signal VST to the DSRC base station 10, and the access information signal VST transmitted from the DSRC terminal 20 is transmitted through the TKE module 300. It is sent to the Application module 400.

At this time, the TKE module 300 checks whether the link ID of the DSRC terminal 20 that has transmitted the access information signal VST is stored in the link ID storage unit 100.

If the link ID of the DSRC terminal 20 that transmits the access information signal is stored in the link ID storage unit 100, the link ID storage unit simultaneously transmits the received access information signal to the application module 400. The link ID of the corresponding DSRC terminal 20 stored in 100 is deleted.

When the mutual confirmation work between the DSRC base station 10 and the DSRC terminal 20 as described above is finished, mutually necessary DSRC data is transmitted / received.

That is, the application module 400 of the DSRC base station 10 receiving the access information signal transmits an application information signal for charging the corresponding DSRC terminal 20 through the TKE module 300 to the DSRC terminal 20. To send.

Then, the DSRC terminal 20 transmits an application response signal (entry office, car model, vehicle number, etc., GET) corresponding to the application information signal (GET) to the DSRC base station 10.

At this time, the TKE module 300 of the DSRC base station 10 determines whether a new second connection response signal BST is received from the IKE module 200. Here, the method for determining whether the TKE module 300 receives the connection response signal may be determined by determining whether a link ID stored in the link ID storage unit 100 exists.

If the connection response signal is received from the IKE module 200, the TKE module 300 transmits the received DSRC second signal after completing the transmission of the application information signal being processed as shown in FIG. 3A. The new DSRC terminal 20-1 transmits the second access information signal to the DSRC base station 10.

Thereafter, the application module 400 of the DSRC base station 10 transmits a charging request signal to the DSRC terminal 20 after performing the charging calculation.

Then, the DSRC terminal 20 transmits the charging result signal to the DSRC base station 10. At this time, the DSRC terminal 20 is connected to the payment card and secures the charging result from the card.

Subsequently, the DSRC base station 10 transmits a business information signal to the DSRC terminal 20, and after the DSRC terminal 20 responds to the DSRC base station 10, the DSRC base station 10 receives the DSRC terminal 20. DSRC communication is terminated by sending a connection termination signal.

If a new connection request signal or a connection response signal is not received, as shown in FIG. 3B, the TKE module 300 transmits and receives DSRC data by scheduling.

Here, the application information signal includes an information signal (GET), a charging request signal, a sales office information signal, and a connection termination signal for charging of the terminal. The application response signal is the response information of the terminal. GET including number information, billing result information, and response information.

Next, a DSRC communication control method according to the present invention having the above configuration will be described with reference to FIG. 4.

First, when the IKE module of the DSRC base station receives the access request signal from the DSRC terminal, it stores the link ID of the DSRC terminal that transmitted the access request signal, and then transmits the access response signal to the corresponding DSRC terminal through the TKE module (S1).

Subsequently, when the TKE module of the DSRC base station receives the access information signal from the DSRC terminal, the TKE module deletes the link ID of the stored DSRC terminal and transmits the access information signal to the application module (S2).

Hereinafter, when the TKE module of the DSRC base station receives the access information signal from the DSRC terminal, it deletes the link ID of the stored DSRC terminal and transmits the access information signal to the application module (S2). This will be described with reference to.

First, when the TKE module 300 receives the access information signal from the DSRC terminal 20, it is determined whether a link ID of the DSRC terminal 20 stored in the link ID storage unit 100 exists (S21).

At this time, if there is a link ID of the DSRC terminal 20 in the step S21 of determining the existence of the link ID of the DSRC terminal 20 (YES), the TKE module 300 is a link ID of the DSRC terminal 20 On the other hand, and transmits the received access information signal to the application module 400 (S22).

On the other hand, if the link ID of the DSRC terminal 20 does not exist in step S21 of determining the existence of the link ID of the DSRC terminal 20 (NO), the TKE module 300 corresponds to the received access information signal. Transfer to the application module 400 (S22).

Thereafter, the application module of the DSRC base station communicates the DSRC data with the DSRC terminal through the TKE module (S3).

 Hereinafter, the step (S3) of the Application module of the DSRC base station to communicate the DSRC data with the DSRC terminal through the TKE module will be described with reference to FIG.

First, it is determined whether a TKE module of the DSRC base station receives an access request signal from a new DSRC terminal while performing DSRC data communication (S31).

If the new connection request signal is received in step S31 of determining whether the access request signal received from the new DSRC terminal is received (YES), the TKE module transmits and receives an application information signal or an application response signal being processed. After processing, the access request signal of the new DSRC terminal is processed (S32).

On the other hand, if a new connection request signal is not received in step S31 of determining whether a connection request signal received from the new DSRC terminal is received (NO), the TKE module transmits and receives an application information signal or an application response signal being processed. After processing, the next scheduled DSRC data communication is performed (S33).

Although the present invention has been described in detail only with respect to the specific embodiments described, it will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the present invention, and such modifications and modifications belong to the appended claims. .

1 is a signal flow diagram of a conventional DSRC system.

2 is a functional block diagram illustrating a DSRC system according to the present invention.

3A is a signal flow diagram when a new connection request signal is generated in the DSRC system according to FIG. 2.

3b is a signal flow diagram when no new connection request signal is generated in the DSRC system according to FIG. 2;

Figure 4 is a flow chart showing a DSRC communication control method according to the present invention.

5 is a flowchart showing the detailed steps of the second step (S2) of the DSRC communication control method according to FIG.

6 is a flowchart illustrating the detailed steps of the third step S3 of the method of controlling DSRC communication according to FIG. 4.

<Explanation of symbols for the main parts of the drawings>

10: DSRC base station 20: DSRC terminal

100: link ID storage unit 200: IKE module

300: TKE module 400: Application module

Claims (9)

In the DSRC system, A link ID storage unit for storing a link ID of a DSRC terminal which has transmitted a connection request signal; When the access request signal is received from the DSRC terminal, it is determined whether the link ID of the DSRC terminal which has transmitted the access request signal exists in the link ID storage unit. An IKE module storing the ID storage unit and transmitting the ID to the TKE module; And It is checked whether a connection response signal is received from the IKE module while transmitting or receiving an application information signal or an application response signal with an application module, and when a connection response signal of a new DSRC terminal is received from the IKE module, the application information signal being processed or A DSRC system including a TKE module that processes the transmission and reception of the application response signal and then processes the connection response signal of the new DSRC terminal. delete The method of claim 1, The TKE module, Upon receiving the access information signal from the DSRC terminal, it is determined whether the link ID of the DSRC terminal stored in the link ID storage unit exists. If the link ID of the DSRC terminal is stored in the link ID storage unit, the link ID is deleted. On the other hand, DSRC system characterized in that for transmitting the received access information signal to the Application module. The method of claim 3, wherein The TKE module, And if the link ID of the DSRC terminal which has transmitted the access information signal does not exist in the link ID storage unit, the received access information signal is transmitted to a corresponding application module. In the DSRC communication control method, When the IKE module of the DSRC base station receives the access request signal from the DSRC terminal, storing the link ID of the DSRC terminal transmitting the access request signal and transmitting the access response signal to the corresponding DSRC terminal through the TKE module; When the TKE module of the DSRC base station receives the access information signal from the DSRC terminal, deleting the link ID of the stored DSRC terminal and transmitting the access information signal to the application module; And The Application module of the DSRC base station DSRC communication control method comprising the step of communicating the DSRC data with the DSRC terminal through the TKE module. The method of claim 5, The application module of the DSRC base station communicating the DSRC data with the DSRC terminal through the TKE module, Determining whether an access request signal is received from a new DSRC terminal while the TKE module of the DSRC base station performs DSRC data communication; And In the step of determining whether the access request signal received from the new DSRC terminal is received, when the new access request signal is received, the TKE module processes the transmission and reception of the application information signal or the application response signal being processed, and then of the new DSRC terminal. DSRC communication control method comprising the step of processing a connection request signal. The method of claim 6, If the new access request signal is not received in the step of determining whether the access request signal received from the new DSRC terminal is received, the TKE module includes the step of transmitting the received access information signal to the application module 400; DSRC communication control method. The method of claim 5, When the TKE module of the DSRC base station receives the access information signal from the DSRC terminal, deleting the link ID of the stored DSRC terminal and transmitting the access information signal to the application module, When the TKE module receives the access information signal from the DSRC terminal, determining whether a link ID of the DSRC terminal stored in the link ID storage unit exists; And If the link ID of the DSRC terminal exists in the step of determining the presence of the link ID of the DSRC terminal, the TKE module deletes the link ID of the DSRC terminal, and transmitting the received access information signal to the Application module; DSRC communication control method. The method of claim 8, If the link ID of the DSRC terminal does not exist in the step of determining the presence of the link ID of the DSRC terminal, the TKE module comprises the step of transmitting the received access information signal to the application module.

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