KR101655822B1 - Method and program for accessing internet protocol, and telematics device and computer readable medium for performing the same - Google Patents

Abstract

Disclosed are a method and a program for accessing internet protocol of a vehicle, and a telematics device and computer readable medium for performing the same. After attempting to access a telematics server by using new IP information issued in a private mobile communication environment of commutable strong electric field, the present invention provides a mechanism for attempting to access the IP to the telematics server again by using previously stored existing IP information which is issued in the private mobile communication environment among the starting of the vehicle, the resetting of a terminal, or weak electric field when the telematics server is not accessed.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle access method and program, a telematics terminal for executing the same, and a computer readable recording medium.

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a vehicle IP connection technology, and more particularly, to a vehicle IP connection method and program using a mobile communication network connected to a vehicle, and a telematics terminal and a computer readable recording medium for executing the same.

The telematics service connects the mobile communication technology and the location tracking technology (GPS) of each country to the automobile to provide the ACN service and the rescue request service (SOS service), the music streaming service and the agent call service as well as the transportation service and the navigation service to the driver .

Here, in order to receive the above-described service, it is only necessary to make IP connection to the telematics server built in the telematics management center (TMS) through the mobile communication network. However, due to unstable network conditions that cover very large areas, or because of reasons for network management policies, there were many restrictions on IP access to telematics servers.

For example, in some countries, in accordance with the network management policy, an IP connection is made using only a 'private server' which is not an 'public server' used by a mobile terminal user to access a TMS center in a telematics terminal I could. An example of this type can be shown in FIG.

The telematics terminal shown in FIG. 1 is connected only to a private mobile communication network (which refers to a communication method for connecting to a private server through a mobile communication network), then accesses a DNS server using stored host information, However, there has been a problem in that a connection to a private server is not properly performed through a private communication network in a weak electric field area (indicating a state in which radio wave detection capability is low).

As an alternative to this, an existing telematics terminal may access a public server through a public mobile communication network (usually referred to as a wireless communication method using a widely known mobile terminal) by WiFI connection during a mobile terminal, And attempts to access the telematics server through the private mobile communication network using the public IP, but the IP connection is not established in time.

Accordingly, since the above-mentioned phenomena are still maintained until the vehicle is re-started or reset, there is a problem that ACN service or SOS service required in case of emergency is impossible.

Korean Unexamined Patent Publication No. 2007-0039461, entitled " Method and Apparatus for Communication of Terminal using IP Address in Mobile Communication System. Korean Patent No. 1404280, entitled " Method and apparatus for maintaining connection between client and server using periodic transmission packet in connection continuous service.

In order to solve the above-described problems, the present disclosure is directed to a vehicle IP access method and program that can effectively control the operation of a connection IP with poor communication access environment and increase the success rate of connection to a telematics server, a telematics terminal And an object of the present invention is to provide a readable recording medium.

According to an embodiment of the present disclosure, there is provided a method for controlling a telematics terminal, comprising: acquiring first new IP information issued from a telematics server in a private telecommunication network of a strong electric field system after booting the terminal, Attempting to reconnect IP to the telematics server using existing IP information previously issued from the telematics server when the IP connection to the telematics server fails; and if the IP reconnection is greater than a predetermined number, And acquiring second new IP information issued from the telematics server in the telematics terminal.

The method may further include acquiring the existing IP information in at least one of a vehicle start-up, a terminal reset, and a weak electric field before acquiring the first new IP information.

The weak electric field may be equal to or less than -104 dBm, and the strong electric field may have an electric field value equal to or greater than -103 dBm.

The acquiring of the first new IP information may acquire the first new IP information through the private mobile communication network connected using the vehicle modem.

The attempting reconnection may determine whether the first new IP information obtained is compared with the existing IP information to determine whether the first IP information is identical to the IP information to be stored in the memory.

The reconnecting step may store the first new information in the memory in place of the existing IP information stored in the memory when it is determined that the reconnection is the same as a result of the comparison.

Wherein the step of attempting reconnection further comprises storing the existing IP information stored in the memory in a past memory if the comparison result indicates that the IP address is not identical, IP information can be stored in the memory.

The attempting of reconnection may attempt to connect IP to the telematics server connected to the private mobile communication network using the first new IP information stored in the memory and to reset the existing IP information stored in the fast memory upon successful connection have.

The attempted reconnection may include attempting IP connection to the telematics server connected to the private mobile communication network using the first new IP information stored in the memory, And may be stored in the memory in place of the new IP information.

The step of acquiring the second new IP information may initialize a counter for the number of times when the reconnection fails by the preset number of times, and may attempt to reconnect the IP if successful.

The obtaining of the second new IP information may acquire the second new IP information corresponding to the initialization.

Further, according to an embodiment, there is provided a program stored in a recording medium for realizing a vehicle IP connection method for each of the above-described methods executed through a processor.

Further, according to an embodiment, there is provided a computer-readable recording medium on which the above-described program is recorded.

According to an embodiment of the present invention, there is provided a first IP information acquiring unit for acquiring first new IP information issued from a telematics server in a private network of a strong electric field network after booting the terminal, An IP reconnecting unit that attempts to reconnect IP to the telematics server using existing IP information previously issued from the telematics server when the IP connection to the telematics server fails, There is provided a telematics terminal including a second IP information obtaining unit for deleting IP information and obtaining second new IP information issued from the telematics server.

Also according to one embodiment, there is provided a computer program product comprising: a memory for storing at least one program; And a processor for controlling the memory, wherein the processor obtains first new IP information issued from a telematics server in a private telecommunication network of a strong electric system after booting the terminal, When the IP connection to the telematics server is failed using the IP information, an attempt is made to reconnect IP to the telematics server using the existing IP information previously issued from the telematics server, and after the IP reconnection is attempted, The at least one program including an instruction to delete the first new IP information and the existing IP information and acquire second new IP information issued from the telematics server when the IP reconnection fails.

The processor may obtain the existing IP information in at least one private mobile communication network of the vehicle starting, the terminal resetting and the weak electric field before acquiring the first new IP information.

The weak electric field may be equal to or less than -104 dBm, and the strong electric field may have an electric field value equal to or greater than -103 dBm.

The processor may obtain the first new IP information through the private mobile communication network connected using the vehicle modem.

The processor may determine whether the first new IP information obtained is the same as the existing IP information, and determine IP information to be stored in the memory.

The processor may store the first new information in the memory in place of the existing IP information stored in the memory when it is determined that the information is the same as a result of the comparison.

Wherein the processor further stores the existing IP information stored in the memory in a past memory and stores the first new IP information in place of the existing IP information in the past memory, It can be stored in memory.

The processor may attempt to connect to the telematics server connected to the private mobile communication network by using the first new IP information stored in the memory to reset the existing IP information stored in the fast memory upon successful connection.

The processor attempts to connect to the telematics server connected to the private mobile communication network using the first new IP information stored in the memory, and when the connection fails, the existing IP information stored in the fast memory stores the first new IP information May be stored in the memory.

The processor may initialize a counter for the number of times when the reconnection fails by the predetermined number of times, and may attempt to reconnect the IP if successful.

The processor may obtain the second new IP information in response to the initialization.

As described above, the embodiments prevent Wi-Fi tethering from being connected to the public server through the WiFi tethering connected to the mobile terminal and the telematics terminal, thereby preventing the IP from being issued from the telematics server through WiFi tethering. Accordingly, the driver can receive a stable telematics service through the private mobile communication network.

In addition, in the embodiments of the present invention, when the telematics server fails to connect, it can increase the success rate of the IP connection by attempting to reconnect to the telematics server using the last (existing) IP using the Fail Safety Function.

In the past, if the connection to the telematics server failed, the telematics server could not be connected until the terminal was reset or the vehicle restarted. In case of emergency, the driver could not receive security services such as ACN and SOS on time.

In addition, the embodiments of the present invention can improve the reliability of the service by increasing the success rate of the IP connection required for the agent call connection and the remote control service through the Stabile Call Connection Logic.

1 is a diagram illustrating a method of connecting a vehicle IP of a conventional telematics terminal.
2 is a flowchart schematically showing a method of connecting a vehicle IP according to an embodiment.
FIG. 3 and FIG. 4 are flowcharts showing a concrete example of each step of the vehicle IP connection method of FIG.
FIG. 5 is a block diagram illustrating a telematics terminal according to an exemplary embodiment of the present invention. Referring to FIG.
FIG. 6 is a block diagram illustrating a telematics terminal according to another embodiment of the present invention. Referring to FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout.

The following description of the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting. For example, the first new IP information and the second new IP information are used as an element to distinguish different elements.

It is also to be understood that the singular " above " used in the description of the embodiments and the claims includes plural referents unless the context clearly dictates otherwise.

It is also to be understood that the term "and / or" described herein includes any and all possible combinations of one or more of the listed related items.

Further, the 'private mobile communication network' described herein is used as a concept for allowing a telematics terminal connected through a public network or a private network to be connected to a private server and / or a telematics server.

If the telematics terminal is not connected after attempting to connect to the telematics server using new IP information issued in a private mobile communication environment capable of communicating, the telematics terminal is informed that it is issued in a private mobile communication environment of a vehicle start, a terminal reset, And provides a mechanism for attempting IP connection to the telematics server using existing IP information previously stored in advance.

 Hereinafter, the above-described mechanism will be described in more detail in terms of the vehicle IP connection technique and hardware.

≪ Example of vehicle IP connection method >

FIG. 2 is a flowchart schematically showing a method of connecting a vehicle IP according to an embodiment, and FIGS. 3 and 4 are flowcharts showing a specific example of each step of the vehicle IP connection method of FIG.

Referring to FIG. 2, the method 100 for connecting a vehicle IP according to an exemplary embodiment includes steps S110 to S140.

First, in one embodiment, step S110 checks at least one of a vehicle start, a terminal reset, and a weak electric field, as shown in FIGS. 2 and 3.

As a result of the check, if the vehicle is started and the terminal is reset or the weak electric field is considered to be less than or equal to -104dBm, the telematics terminal can acquire the existing IP information from the telematics server connected through the pre- connected private mobile communication network.

However, the step S110 starts again when it is judged that the condition of the private mobile communication network environment is not satisfied.

Here, the obtained existing IP information is stored in the memory and is given as the name 'existing' in that it is acquired before the first new IP information or the second new IP information to be described later.

On the other hand, the name 'New' in the first new IP information or the second new IP information is a result given in that the first new IP information or the second new IP information is acquired after the existing IP information is acquired.

In one embodiment, as shown in FIG. 2, after the terminal is booted, the first new IP information issued from the telematics server in the private mobile communication network of the strong electric field is obtained in the telematics terminal.

More specifically, step S120 may include steps S121 to S124 as shown in FIG.

That is, in step S 120, after the telematics terminal is booted, the telematics terminal may first check whether the telematics terminal is in an electric field capable of communicating with the telematics terminal, for example, a strong electric field state.

As a result of the check, if the strong electric field has an electric field value equal to or greater than -103 dBm, step S121 connects the telematics terminal to the private mobile communication network of the strong electric field system, and then transmits the first new IP information issued from the telematics server to the private mobile communication network . ≪ / RTI >

At this time, the first new IP information may be acquired using the vehicle modem installed in the vehicle (S122). In this case, in step S120, after connecting to the host server using the vehicle modem in step S123, the first new IP information issued from the DNS server is obtained in the telematics terminal (steps S124 and S125).

However, as a result of the determination in step S121, if it is determined that the electric field is not the above-described electric field value, it is checked again whether the state is the strong electric field state, as shown in FIG.

In one embodiment, the telematics terminal determines whether IP connection to the telematics server is made using the first new IP information obtained in step S120, thereby determining IP information to be stored in the memory, If the IP connection fails, IP reconnection to the telematics server is attempted using the existing IP information previously issued by step S110.

To this end, step S130 may include steps S131 to S139 as shown in FIG. 3 and FIG.

That is, as shown in FIG. 3, the comparison between the existing IP information stored in the memory and the first new IP information obtained in step S120 may determine whether the IP information is identical to the IP information to be stored in the memory (S131).

As a result of the determination in step S131, if it is determined to be the same, the first new information is overwritten with the existing IP information stored in the memory to store the first new information in the memory (S132). As a result, by replacing the existing IP information stored in the memory with the first new information, the first new information is stored in the memory (S132).

However, if it is determined in step S131 that it is not the same, the existing IP information stored in the memory is further stored in the past memory, and the first new IP information is replaced with the existing IP information stored in the memory, New new IP information may be stored in the memory (S133).

Accordingly, in step S130, IP connection to the private server and / or the telematics server is attempted using the new IP information stored in the memory according to the result of step S132 or step S133 as shown in FIG. 4 (S134). After the IP connection is attempted, the telematics terminal receives the connection result from the private server and / or the telematics server (S134a), and determines whether the connection is successful according to the connection result (S135).

For example, if the IP connection to the private server and / or the telematics server is successfully performed using the first new IP information stored in the memory, the existing IP information stored in the fast memory may be reset (S136). Accordingly, the first new IP information stored in the memory can be maintained (S137).

However, if it is determined in step S130 that the IP connection to the telematics server connected to the private mobile communication network is attempted using the first new IP information stored in the memory, the existing IP information stored in the fast memory is stored in the first new IP information So that new existing IP information is stored in the memory (S138).

If the IP connection fails, the counter provided to the telematics terminal can be incremented by the number of failures, for example, by one counter (S139). Accordingly, the existing IP information stored in the memory may be used to attempt IP reconnection to the telematics server.

Lastly, in one embodiment, step S140 may be considered as a reconnection failure if the number of times of the IP reconnection (failure counter) is greater than a predetermined counter number (e.g., 1) after the IP reconnection attempt as shown in FIG. 2 and FIG. And initializes the failure counter (S141), and starts the above-described step S110 again.

When the failure counter is initialized, the existing IP information stored in the memory is deleted, and the second new IP information such as the first new IP information can be issued again from the telematics server. Therefore, the telematics terminal obtains new second new IP information.

However, if the IP reconnection is less than or equal to the predetermined number of counters after the IP reconnection attempt, step S140 may be regarded as a successful reconnection.

As described above, in the present embodiment, when the connection to the telematics server fails using the first new IP information, the connection success rate can be increased by retrying the IP connection using the existing conventional IP information.

The embodiments described above can be implemented in the form of program instructions that can be executed through various computer components and recorded in a computer-readable recording medium. The recording medium mentioned above may be a ROM, a magnetic disk or a compact disk, but is not limited thereto.

<Examples of telematics terminals>

FIG. 5 is a block diagram illustrating a telematics terminal according to an exemplary embodiment of the present invention. Referring to FIG.

5, the telematics terminal 100 includes an existing IP information acquisition unit 110, a first IP information acquisition unit 120, an IP connection unit 130, a second IP information acquisition unit 140 ), A memory 150, and a fast memory 160.

First, in one embodiment, the existing IP information obtaining unit 110 checks at least one of the private mobile communication network environment of the vehicle starting, the terminal resetting, and the weak electric field, and if the result is a vehicle start and a terminal reset state, It is possible to acquire the existing IP information from the telematics server 220 connected through the private mobile communication network that is connected in advance.

However, the existing IP information acquiring unit 110 regards it as a condition of the above-described private mobile communication network environment as a result of the check and starts again.

Here, the obtained existing IP information is stored in the memory 150, and is a result given with the name 'existing' in that it is acquired before the first new IP information or the second new IP information to be described later.

On the other hand, the name 'New' in the first new IP information or the second new IP information is a result given in that the first new IP information or the second new IP information is acquired after the existing IP information is acquired.

The first IP information obtaining unit 120 may obtain the first IP information from the private server 210 and / or the telematics server 220 in the private mobile communication network of the strong electric system after booting the telematics terminal 100 IP information.

More specifically, after the telematics terminal 100 is booted, the first IP information obtaining unit 120 can check whether it is in a communicable electric field environment, for example, a strong electric field state.

As a result of the check, if the strong electric field has an electric field value equal to or greater than -103 dBm, the first information obtaining unit 120 may detect that the telematics terminal 100 is connected to the private mobile communication network of the strong electric field, The first new IP information issued from the telematics server 220 can be obtained through the previously-connected private mobile communication network.

At this time, the first new IP information may be acquired using a vehicle modem installed in the vehicle. For example, the first information obtaining unit 120 may obtain the first new IP information issued from the DNS server (not shown) after being connected to the host server using the vehicle modem.

However, if the first IP information obtaining unit 120 is not the above-mentioned electric field value, it again checks whether it is a strong field system state.

In one embodiment, the IP connection unit 130 determines whether IP connection to the private server 210 and / or the telematics server 220 is established using the acquired first new IP information, and transmits the IP information to be stored in the memory 150 As a result of the determination, if the IP connection fails, IP reconnection to the private server 210 and / or the telematics server 220 may be attempted using the already-issued existing IP information.

More specifically, the IP connection unit 130 compares the existing IP information stored in the memory 150 with the acquired first new IP information to determine whether the same is identical or not. The IP connection unit 130 overwrites the existing IP information stored in the memory 150 and stores the first new information in the memory 150. [

In other words, by replacing the existing IP information stored in the memory 150 with the first new information, the first new information is newly stored in the memory 150. [

However, if it is determined that they are not the same, the IP connection unit 130 further stores the existing IP information stored in the memory 150 in the fast memory 160, and the first new IP information is stored in the memory 150 , &Lt; / RTI &gt; Therefore, new new IP information is stored in the memory 150. [

Accordingly, the IP connection unit 130 can attempt IP connection to the private server 210 and / or the telematics server 220 using the new IP information finally stored in the memory according to the above-described determination result.

After the IP connection is attempted, the IP connection unit 130 receives the connection result from the private server 210 and / or the telematics server 220, and determines whether or not the connection is successful according to the connection result.

For example, when the IP connection to the private server 210 and / or the telematics server 220 is successfully performed using the first new IP information stored in the memory 150, the IP connection unit 130 transmits the IP address to the fast memory 160 The stored existing IP information can be reset. Accordingly, the first new IP information stored in the memory 150 can be maintained.

However, the IP connection unit 130 tries to access the private server 210 and / or the telematics server 220 connected to the private mobile communication network by using the first new IP information stored in the memory, It is possible to replace the first new IP information with the existing IP information stored in the fast memory 160. In this case, the memory 150 stores new existing IP information.

As described above, when the IP connection fails, the counter provided in the telematics terminal 100 increases the number of times the counter is counted by the number of failures. Accordingly, the existing IP information stored in the memory 150 may be used to attempt IP reconnection to the private server 210 and / or the telematics server 220 as follows.

That is, in one embodiment, the second IP information obtaining unit 140 determines whether or not the reconnection succeeds due to the IP reconnection attempt after the IP reconnection is attempted. For example, the IP reconnecting unit 132 initializes the failure counter by considering the reconnection failure when the IP reconnection is greater than the predetermined counter number after attempting to reconnect the IP, The state of the mobile communication network is checked again.

When the failure counter is initialized, the second IP information acquiring unit 140 deletes the existing IP information stored in the memory 150 and acquires the first new IP information from the private server 210 and / or the telematics server 220 The second new IP information may be issued again to obtain the second new IP information.

However, if the number of times of the IP reconnection (failure counter) is less than or equal to a preset counter number (e.g., 1) after the IP reconnection is attempted, the second IP information obtaining unit 140 may regard the reconnection success have.

As described above, in this embodiment, when the connection to the private server 210 and / or the telematics server 220 fails using the first new IP information, the IP connection is retried using the existing conventional IP information Thus, the connection success rate can be increased.

Finally, the memory 150 and the fast memory 160 described above can store the processed result from each of the above-described configurations in the form of programs, modules, and data structures.

The memory 150 and the fast memory 160 may include a DRAM (including a dynamic random access memory, a synchronous DRAM, a double data rate (DDR) SDRAM, a DDR2 SDRAM, and a RDRAM (Rambus DRAM) High speed random access memory such as DDR RAM or other random access solid state memory devices.

Moreover, memory 150 and fast memory 160 may include non-volatile memory such as at least one magnetic disk storage device, optical disk storage device, flash memory device, or other non-volatile solid state storage device.

<Other examples of telematics terminals>

FIG. 6 is a block diagram illustrating a telematics terminal according to another embodiment of the present invention. Referring to FIG.

Referring to FIG. 6, the telematics terminal according to an exemplary embodiment may access the telematics server 210 using the new IP information issued in the private mobile communication environment of a strong communication system capable of communication, And a mechanism for attempting IP connection to the telematics server 210 using the existing IP information previously stored in the private mobile communication environment of the reset or weak electric field.

The telematics terminal includes a wireless communication unit 310, a memory 320 including at least one computer-readable recording medium, a fast memory 330, a display unit 340, at least one core A power supply 360, and a counter 370. The processor 350 may be a microprocessor,

The wireless communication unit 310 may be connected to a private communication network by supporting a local communication module for connecting to a public network, for example, a WiFi communication module or a mobile communication module for connecting to a private network. When connected to a private mobile communication network, the telematics terminal may be connected to a private server and / or a telematics server.

The memory 320 and the fast memory 330 may store information and programs processed by the processor 350.

For this, the memory 320 and the fast memory 330 may include a DRAM (including a dynamic random access memory, a synchronous DRAM (SDRAM), a double data rate (DDR) SDRAM, a DDR2 SDRAM, and a Rambus DRAM) High speed random access memory such as DDR RAM or other random access solid state memory devices.

Moreover, the memory 320 and the fast memory 330 may include non-volatile memory such as at least one magnetic disk storage device, an optical disk storage device, a flash memory device, or other non-volatile solid state storage device.

The memory 320 and the fast memory 330 may be implemented as part of the processor 350.

The display unit 340 is for displaying information input by the user or information provided to the user and various kinds of graphical user interfaces (GUIs) of the telematics terminal, and the graphical user interface may be any one of shapes, texts, icons, Lt; / RTI &gt;

The display unit 340 may include a display panel 341. The display panel 341 can be selectively formed of an LCD (Liquid Crystal Display) and an OLED (Organic Light-Emitting Diode). Here, the display panel 341 may be configured to realize output and input functions as two independent parts.

The processor 350 is a control center of the telematics terminal and is connected to each part via various interfaces and circuits and executes or activates software programs and / or information stored in the memory 320 and the fast memory 330 And realizes execution and data processing of various functions of the telematics terminal through calling information stored in the memory 320 and the fast memory 330. [

To this end, the processor 350 checks a private mobile communication network connected to at least one of the vehicle start, the terminal reset, and the weak electric field, and if it is determined that the vehicle start and terminal reset state or the weak electric field is less than or equal to -104 dBm Acquires the existing IP information from the telematics server connected through the private mobile communication network connected in advance, and resumes when the condition of the private mobile communication network environment is considered as a result of checking.

Here, the obtained existing IP information is stored in the memory and is given as the name 'existing' in that it is acquired before the first new IP information or the second new IP information to be described later.

On the other hand, the name 'New' in the first new IP information or the second new IP information is a result given in that the first new IP information or the second new IP information is acquired after the existing IP information is acquired.

In one embodiment, the processor 350 may obtain the first new IP information issued from the telematics server in the private mobile telecommunication network of the strong system after booting of the telematics terminal.

More specifically, after the telematics terminal is booted, the processor 350 may check whether the telematics terminal is in an electric field environment in which the telematics terminal can communicate, for example, a strong electric field state.

As a result of the check, if the strong electric field has an electric field value equal to or larger than -103 dBm, the processor 350 connects the first new IP information issued from the telematics server to the private mobile communication network of the strong electric field, Can be acquired through a mobile communication network.

At this time, the first new IP information may be acquired using a vehicle modem installed in the vehicle. For example, the processor 350 may access the host server using the vehicle modem, and then obtain the first new IP information issued from the DNS server. However, when the processor 3500 is not in the electric field value described above, it again checks whether it is a strong electric field state.

In one embodiment, the processor 350 determines whether IP access to the telematics server is established using the acquired first new IP information, determines IP information to be stored in the memory 320, , And attempts to reconnect IP to the telematics server using the previously issued existing IP information.

More specifically, the processor 350 determines whether the same is true by comparing the existing IP information stored in the memory 320 with the acquired first new IP information. The processor 350 overwrites the existing IP information stored in the memory 320 and stores the first new information in the memory 320. [

In other words, by replacing the existing IP information stored in the memory 320 with the first new information, the first new information is newly stored in the memory 320. [

However, if it is determined that they are not the same, the processor 350 further stores the existing IP information stored in the memory 320 in the fast memory 330, and the first new IP information is stored in the memory 320, It is possible to replace the existing IP information stored in the IP address information storage unit. Accordingly, new new IP information is stored in the memory 320. [

Accordingly, the processor 350 attempts IP connection to the private server and / or the telematics server using the new IP information finally stored in the memory 320 according to the above-described determination result, and determines whether the IP connection is successful .

For example, the processor 350 can reset the existing IP information stored in the fast memory if the IP connection to the private server and / or telematics server is successful using the first new IP information stored in the memory 320 . Accordingly, the first new IP information stored in the memory 320 can be maintained.

However, when the processor 350 attempts to connect to the telematics server connected to the private mobile communication network using the first new IP information stored in the memory 320, the processor 350 transmits the first new IP information stored in the memory 320 And replaces it with the existing IP information stored in the fast memory 330. In this case, the existing IP information is stored in the memory 320.

In this way, when the IP connection fails, the counter 370 increments the counter count by 1 for each failure count. Accordingly, the existing IP information stored in the memory 320 may be used to attempt IP reconnection to the telematics server as follows.

That is, in one embodiment, the processor 350 determines whether reconnection succeeds due to the IP reconnection attempt after attempting the IP reconnection described above. For example, after the IP reconnection attempt, the processor 350 regards the IP reconnection (failure counter) as a re-connection failure when the number of times is greater than a predetermined counter number (e.g., 1), initializes the failure counter, The status of the network is checked again.

When the failure counter is initialized, the processor 350 deletes the existing IP information stored in the memory 320, issues the second new IP information such as the first new IP information from the telematics server again from the telematics server, Information can be obtained.

However, if the number of times of the IP reconnection (failure counter) is less than or equal to a predetermined counter number (e.g., 1) after attempting to reconnect the IP, the processor 350 may regard the reconnection as successful.

As described above, in the present embodiment, when the connection to the telematics server fails using the first new IP information, the connection success rate can be increased by retrying the IP connection using the existing conventional IP information.

As such, the processor 350 for processing the vehicle IP connection method may be composed of one or a plurality of cores. For example, the operation processor and the modem processor that process the vehicle-access method described above can be integrated and configured. The operation processor mainly handles the OS, the user interface and the safety driving induction method, and the modem processor mainly handles wireless communication. However, the modem processor may not be integrated into the processor 350.

Lastly, the power supply unit 360 supplies power to the above-described configurations, is logically connected to the processor 350 through the power management system, and can realize charging and discharging management and power management through the power management system .

The power supply 360 may be comprised of at least one DC or AC power source, a recharging system, a power failure detection circuit, a power converter or inverter, a power state indicator, and the like.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the exemplary embodiments or constructions. You can understand that you can do it. The embodiments described above are therefore to be considered in all respects as illustrative and not restrictive.

100: telematics terminal 110: existing IP information acquisition unit
120: first IP information obtaining unit 130: IP connection unit
140: second IP information obtaining unit 150: memory
160: Fast memory 310: Wireless communication unit
320: memory 330: fast memory
340: Display unit 350: Processor
360: Power source 370: Counter

Claims (25)

Obtaining existing IP information in at least one private mobile communication network among a vehicle start, a terminal reset, and a weak electric field;
After the terminal is booted, acquiring first new IP information issued from a telematics server in a private telecommunication network of a strong electric system in a telematics terminal;
Attempting IP reconnection to the telematics server using the existing IP information previously issued from the telematics server when IP connection to the telematics server is failed using the acquired first new IP information; And
Deleting the existing IP information when the IP reconnection is greater than a predetermined number and acquiring second new IP information issued from the telematics server in the telematics terminal
And connecting the vehicle IP. delete The method according to claim 1,
Wherein the weak electric field is equal to or less than -104 dBm and the strong electric field has an electric field value equal to or greater than -103 dBm. The method according to claim 1,
Wherein the obtaining of the first new IP information comprises:
And acquiring the first new IP information through the private mobile communication network connected using the vehicle modem. The method according to claim 1,
Wherein the attempting to reconnect comprises:
And comparing the obtained first new IP information with the existing IP information to determine whether the first new IP information is identical to the IP information to be stored in the memory. 6. The method of claim 5,
Wherein the attempting to reconnect comprises:
Storing the first new IP information replacing the existing IP information stored in the memory in the memory when it is determined as the comparison result. The method according to claim 6,
Wherein the attempting to reconnect comprises:
Storing the existing IP information stored in the memory in a past memory and storing the first new IP information in place of the existing IP information in the memory The method comprising: 8. The method of claim 7,
Wherein the attempting to reconnect comprises:
And attempting IP connection to the telematics server connected to the private mobile communication network using the first new IP information stored in the memory to reset the existing IP information stored in the fast memory upon successful connection. 8. The method of claim 7,
Wherein the attempting to reconnect comprises:
The first IP information stored in the memory is replaced with the new IP information stored in the fast memory when an attempt to connect to the telematics server connected to the private mobile communication network is made using the first new IP information stored in the memory, A method of connecting a vehicle IP stored in a memory. The method according to claim 1,
Wherein the obtaining of the second new IP information comprises:
Initializing a counter for the number of times when the reconnection fails by the predetermined number of times, and if successful, attempting to reconnect the IP is attempted. 11. The method of claim 10,
Wherein the obtaining of the second new IP information comprises:
And acquires the second new IP information in response to the initialization. A program stored in a recording medium for realizing a vehicle IP connection method according to any one of claims 1 to 11, which is executed through a processor. A computer-readable recording medium having recorded thereon the program according to claim 12. An existing IP information acquisition unit for acquiring existing IP information in at least one private mobile communication network among a vehicle start, a terminal reset, and a weak electric field;
A first IP information acquiring unit for acquiring first new IP information issued from a telematics server in a private mobile communication network of a strong electric field after booting the terminal;
An IP reconnection unit for attempting to reconnect IP to the telematics server using the existing IP information previously issued from the telematics server when IP connection to the telematics server is failed using the acquired first new IP information; And
A second IP information obtaining unit for deleting the existing IP information when the IP reconnection is greater than a preset number of times and acquiring second new IP information issued from the telematics server,
And a telematics terminal. A memory for storing at least one program; And a processor for controlling the memory,
The processor comprising:
Obtains the existing IP information in at least one of the private mobile communication network of the vehicle starting, the terminal reset, and the weak electric field, obtains the first new IP information issued from the telematics server in the private mobile communication network of the strong electric field after booting the terminal, Attempting IP reconnection to the telematics server using the existing IP information previously issued from the telematics server when the IP connection to the telematics server fails using the first new IP information,
And an instruction to delete the first new IP information and the existing IP information when the IP reconnection fails a predetermined number of times after attempting the IP reconnection and acquire second new IP information issued from the telematics server And the at least one program is executed. delete 16. The method of claim 15,
Wherein the weak electric field is equal to or less than -104 dBm and the strong electric field has an electric field value equal to or greater than -103 dBm. 16. The method of claim 15,
The processor comprising:
And obtains the first new IP information through the private mobile communication network connected using the vehicle modem. 16. The method of claim 15,
The processor comprising:
And comparing the obtained first new IP information with the existing IP information to determine whether the first new IP information is identical to the IP information to be stored in the memory. 20. The method of claim 19,
The processor comprising:
And stores the first new IP information replacing the existing IP information stored in the memory in the memory when it is determined as the result of the comparison. 20. The method of claim 19,
The processor comprising:
Storing the existing IP information stored in the memory in a past memory and storing the first new IP information in place of the existing IP information in the memory Telematics terminal. 22. The method of claim 21,
The processor comprising:
Wherein the first IP information stored in the memory is used to attempt IP connection to the telematics server connected to the private mobile communication network to reset existing IP information stored in the fast memory upon successful connection. 22. The method of claim 21,
The processor comprising:
The first IP information stored in the memory is replaced with the new IP information stored in the fast memory when an attempt to connect to the telematics server connected to the private mobile communication network is made using the first new IP information stored in the memory, Telematics terminal stored in memory. 16. The method of claim 15,
The processor comprising:
Initializes a counter for the number of times when the reconnection fails by the predetermined number of times, and attempts to reconnect the IP when it succeeds. 25. The method of claim 24,
The processor comprising:
And obtains the second new IP information in response to the initialization.

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