KR100480245B1 - Apparatus and method for packet data path appointment in mobile elements - Google Patents

Abstract

The present invention relates to an apparatus and method for setting a packet data path between mobile terminals, and more particularly, to an apparatus and method for setting a packet data path using a short message. The mobile terminals wanting packet data communication request the packet data communication to the counterpart mobile terminal before the IP address is allocated. In response to the request, the other party's mobile station notifies the mobile station of the packet data communication whether or not to accept the packet data communication. In this case, if the other mobile terminal accepts, the mobile terminals are assigned an IP. In addition, when the other mobile terminal refuses to accept, the mobile terminals are not assigned an IP address.

Description

Apparatus and method for setting packet data path between mobile terminals {APPARATUS AND METHOD FOR PACKET DATA PATH APPOINTMENT IN MOBILE ELEMENTS}

The present invention relates to an apparatus and method for setting a path when transmitting packet data in a mobile communication system, and more particularly, to an apparatus and method for setting a packet data transmission path between mobile terminals using a short message.

  In general, a mobile communication system refers to a system that services voice or data through a wireless network. Such mobile communication systems can be distinguished by a multiplexing scheme. A typical example thereof is a code division multiple access (CDMA) mobile communication system, and the code division multiple access mobile communication system performs a mobile communication service using a code division multiple access method. Say the system. The CDMA mobile communication system has been developed in the IS-95 standard, which focuses on the transmission and reception of voice signals, and has been discussed in the CDMA-2000 standard, which enables high-speed data transmission as well as voice. The CDMA-2000 standard aims to provide services such as high quality voice, moving picture, and Internet search. As described above, in the mobile communication system, various methods for servicing information such as voice and data are implemented, and representative examples thereof may be classified into a circuit switched network and a packet switched network. The circuit switching network is a switching network that processes circuit data including voice, and circuit switching between mobile terminals is based on H324M. The packet switching network is a switching network that processes packet data, and the packet switching between the mobile terminals is based on H323. In general, a process of allocating an IP address to the mobile station in order to establish a packet data path is as follows. When the mobile station requests an IP address assignment, an IP address is allocated to each mobile station through a pointer-to-point protocol (PPP) negotiation between the mobile station and the switching network. do. As described above, the network configuration of the mobile communication system requires a network configuration capable of efficiently transmitting voice and data. This demand is more urgently required in the mobile communication system (CDMA-2000), which is expected to increase the amount of data transmitted as various services are made.

1 and 2 generally illustrate a packet data communication process between mobile terminals. Hereinafter, a packet data communication process between mobile terminals will be described in detail with reference to FIGS. 1 and 2.

1 illustrates a request for packet data communication from a mobile station 1 (100) to a mobile station 2 (102) via a network 104 including a packet data serving node (PDSN). In response to the request, the mobile terminal 2 102 accepts the packet data communication request, indicating that the packet data communication between the mobile terminal 1 100 and the mobile terminal 2 102 is performed.

FIG. 2 illustrates the packet data communication process performed in FIG. 1 in detail. 2 is composed of a mobile station 1 (100), a mobile station 2 (102) and a network 104 including a PDSN. It is apparent that the mobile terminal 1 100 and the mobile terminal 2 102 are mobile terminals capable of packet data communication.

In step 200 of packet data path establishment, the mobile station 1 100 is turned on. At the same time, the mobile station 1 (100) requests the PDSN network (104) (104) to allocate an Internet Protocol (IP) address.

In step 202 of the packet data path establishment, the PDSN network 104 allocates an available IP address to the mobile station 1 (100) stored in an IP address pool.

In step 204 of packet data path establishment, the mobile station 1 (100) registers the IP address and its mobile station number assigned in step 202 to the gate keeper. Steps 200 to 204 are performed in the same manner from step 206 to step 210 in the mobile terminal 2 (102).

 In step 212 of establishing a packet data path, the mobile station 1 100 requests the PDSN network 104 for packet data communication with the mobile station 2 102 via the PDSN network 104. In step 214 of the packet data path establishment, the PDSN network 104 requests the mobile station 2 102 a request for packet data communication requested by the mobile station 1 100 in step 212.

In step 216 of the packet data path establishment, the mobile station 2 102 responds to the PDSN network 104 in response to the request made in step 214. In step 218 of packet data path establishment, the PDSN network 104 notifies the mobile station 1 100 of the response notified by the mobile station 2 102 in step 216. By the above process, a path for packet data transmission is established between the mobile terminal 1 (100) and the mobile terminal 2 (102).

In step 220 of packet data path establishment, packet data communication is performed between the mobile station 1 (100) and the mobile station 2 (102). Of course, it is apparent that the packet data communication is made through the PDSN network 104.

As described above, in order to perform packet data communication between the mobile station 1 and the mobile station 2, the mobile station 1 and the mobile station 2 should be assigned the IP address. In addition, in order for packet data communication to be performed between the mobile station 1 and the mobile station 2 to which the IP address is assigned, the other mobile station should respond to the request of the mobile station for packet data communication. In this case, a counterpart mobile terminal does not want packet data communication with the mobile terminal that wants the packet data communication. In this case, the IP address assigned to each mobile terminal is assigned in an unused state. Therefore, this leads to waste of unnecessary IP addresses.

Accordingly, an object of the present invention is to propose an apparatus and method for allocating an IP address to a mobile terminal only when packet data communication is performed when establishing a packet data path between mobile terminals.

   Another object of the present invention is to propose an apparatus and method for preventing an IP address shortage by allocating an IP address to a mobile terminal only when packet data communication is performed.

It is another object of the present invention to propose an apparatus and method for preventing an error caused by a complicated operation structure in a terminal and a system by assigning an IP address only when necessary.

It is still another object of the present invention to propose an apparatus and method for confirming whether packet data is communicated through a short message before allocating an IP address.

In order to achieve the above object of the present invention, the mobile terminals that want packet data communication request the packet data communication to the other mobile terminal before the IP address is allocated. In response to the request, the other party's mobile station notifies the mobile station of the packet data communication whether or not to accept the packet data communication. In this case, when the other mobile terminal accepts, the mobile terminals are assigned an IP address. In addition, when the opposite mobile terminal rejects the acceptance, the mobile terminals are not assigned an IP address.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

3 shows a protocol layer for mobile terminals to which the present invention is applied to perform packet data communication. The mobile station 1 lowers the data to the IP layer when a user data packet is generated in an upper layer such as MIP and UDP. Then, the IP layer is divided according to the destination of the data to be transmitted and lowered to a Point to Point Protocol (PPP) layer. The PPP layer transmits the air over the LAC layer, the MAC layer, and the air link layer. Data transmitted over the airwaves is transmitted to the PDSN 104 via a base station and a base station controller. The data transmitted to the PDSN 104 is transmitted via airwaves to the mobile station 2 102 through the layers of the PDSN shown in FIG. Data transmitted to the mobile terminal 2 (102) is a data communication in the direction opposite to the execution direction in the mobile terminal 1 (100). As shown in FIG. 3, in order to perform packet data communication between mobile terminals, an IP address should be allocated to each mobile terminal.

4 is a diagram illustrating a process of setting a packet data path between mobile terminals performing packet data communication according to the present invention. As shown in FIG. 4, it can be seen that the mobile station 1 is composed of a mobile station 1 100, a mobile station 2 102, and a PDSN network 104. The mobile terminal 1 100 is a mobile terminal for packet data communication, and the mobile terminal 2 102 is a counterpart mobile terminal for which the mobile terminal 1 100 wants to perform packet data communication. Hereinafter, the packet data path setting process to which the present invention is applied will be described in detail with reference to the mobile terminal 1 (100) and the mobile terminal 2 (102). In addition, the present invention can be used for all communication methods based on IP address assignment in communication between mobile terminals.

In step 400 of packet data path establishment, the mobile station 1 100 requests packet data communication to the mobile station 2 102. In this case, a packet data communication is requested to the mobile station 2 (102) by using a short message (hereinafter, referred to as SMS). However, it is apparent that the mobile terminal 1 100 and the mobile terminal 2 102 may be formed by a general mobile communication method without using the SMS. In addition, by setting a shortcut key only for the packet data communication request may be made by the method.

In step 402 of packet data path establishment, the mobile station 2 102 notifies the mobile station 1 100 of whether to accept the packet data communication requested by the mobile station 1 100 in step 400. In this case, the same communication method as that performed in step 400 is performed. In this case, the process moves to steps 404 and 406 only when the communication request is accepted.

In step 404 and step 406 of packet data path establishment, the mobile station 1 (100) and the mobile station 2 (102) request the IPSN allocation to the PDSN network (104).

In steps 408 and 410 of packet data path establishment, the PDSN network 104 assigns an IP address to the mobile station 1 (100) and the mobile station 2 (102). The IP address selects an available IP address from the IP address pool included in the PDSN network 104 and notifies the mobile station 1 100 and the mobile station 2 102. Table 1 below shows an example of the IP address pool.

IP address Whether or not to use IP address Whether or not to use 10.2.20.2 × 20.2.20.2 0 10.2.20.3 × 20.2.20.3 0 10.2.20.4 0 20.2.20.4 0 10.2.20.5 × 20.2.20.5 × 10.2.20.6 0 20.2.20.6 0 10.2.20.7 0 20.2.20.7 0 10.2.20.8 0 20.2.20.8 × 10.2.20.9 0 20.2.20.9 0

As shown in Table 1, it can be seen that there are 16 IP address lists in the IP address pool, and 11 IP addresses of the 16 IP address lists are in use. Therefore, according to Table 1, there are five available IP addresses. The five IP addresses are 10.2.20.2, 10.2.20.3, 10.2.20.5, 20.2.20.5, and 20.2.20.8. Accordingly, the PDSN network 104 selects two IP addresses among the five available IP addresses and assigns them to the mobile station 1 (100) and the mobile station 2 (102). The selection method records the usage time of each of the IP addresses, obtains the difference between the current time and the time when the use is stopped, and allocates the IP address having the largest value of the difference. Of course, in addition to this method, there may be a number of ways to select any one of the currently available IP addresses. In the present invention, for example, it is assumed that the mobile station 1 100 is assigned an IP address of 10.2.20.2, and the mobile station 2 102 is assigned an IP address of 10.2.20.5.

In steps 412 and 414 of packet data path establishment, the mobile station 1 (100) and the mobile station 2 (102) register each IP address assigned from the PDSN network (104) to a gate keeper. The gatekeeper registers telephone numbers of mobile terminals for packet data communication and IP addresses assigned to the mobile terminals. In addition, other IP addresses already in use are registered in the gatekeeper. Table 2 below shows an example of the gatekeeper.

Mobile phone number IP address Mobile phone number IP address 01 ×-000-0000 10.2.20.4 01 ×-0 * 0-0000 20.2.20.2 01 ×-000-000 * 10.2.20.6 01 × -0 * 0-000 * 20.2.20.3 01 ×-000-00 * 0 10.2.20.7 01 ×-0 * 0-00 * 0 20.2.20.4 01 ×-000-00 ** 10.2.20.8 01 ×-0 * 0-00 ** 20.2.20.6 01 ×-000-0 * 00 10.2.20.9 01 ×-00 *-0 * 00 20.2.20.7 01 ×-000-* 000 10.2.20.2 01 ×-00 *-* 000 20.2.20.9 01 ×-000-* 00 * 10.2.20.5

As shown in Table 2, the gatekeeper stores telephone numbers of respective mobile terminals and IP addresses assigned to the mobile terminals. In Table 2, it can be seen that the mobile number of the mobile terminal 1 (100) is 01 ×-000-* 000 and the assigned IP address is 10.2.20.2, and the telephone number of the mobile terminal 2 (102) is 01 ×-000. -* 00 * and the assigned IP address is 10.2.20.5.

In step 416 of setting a packet data path, the mobile station 1 100 and the mobile station 2 102 perform packet data communication using the assigned IP address. In this case, of course, the packet data communication is performed through the PDSN network 104.

FIG. 5 illustrates the above-described FIG. 4 for the packet data path setting to which the present invention is applied. 6 illustrates a process of releasing a path set for packet data communication. First, the process of establishing a packet data path will be described again with reference to FIG. 5.

In step 500 of setting a packet data path, the mobile station 1 100 requests packet data communication to the mobile station 2 102. In response to the request, the mobile station 2 102 determines whether to perform packet data communication with the mobile station 1 100. As a result of the determination, the mobile station 2 (102) notifies that the communication request is accepted when the mobile station 1 (100) wants the packet data communication, and accepts the communication request when the packet data communication is not desired. Notify not to do so. Mobile terminal 2 (102) notifying the acceptance does not return to the normal standby mode. In addition, the mobile terminal 1 100 notified of not wanting packet data communication from the mobile terminal 2 102 finds another mobile terminal or returns to the normal standby mode in the same manner as the mobile terminal 2 102.

In step 504 of packet data path establishment, the mobile station 1 (100) and the mobile station 2 (102) requests the PDSN network (104) to assign an IP address. The PDSN, which has been requested to allocate the IP address, selects an available IP address from the IP address pool and allocates the available IP address to the mobile station 1 (100) and the mobile station 2 (102).

In step 506 of packet data path establishment, the mobile station 1 (100) and the mobile station 2 (102) determines whether an IP address has been allocated from the PDSN network (104). When the IP addresses included in the IP address pool are insufficient, the IP addresses may not be allocated to the mobile terminal 1 100 and the mobile terminal 2 102. If the IP address is not assigned, the mobile station 1 (100) and the mobile station 2 (102) request a new IP address allocation at regular intervals. Of course, if the IP address is not assigned, the process may end in step 512.

In step 508 of packet data path establishment, the mobile station 1 (100) and the mobile station 2 (102) register the telephone number of each mobile station and the IP address assigned by the PDSN network (104) to the gatekeeper.

In step 510 of packet data path establishment, the mobile station 1 100 and the mobile station 2 102 perform packet data communication using the assigned IP address. The packet data communication includes a service based on IP address allocation, that is, a video call, a multimedia message system (MMS), and the like. If the packet data communication between the mobile terminal 1 (100) and the mobile terminal 2 (102) is terminated, go to step 512 to end. As shown in FIG. 5, mobile terminals that want packet data communication are assigned an IP address only when they receive packet data communication from the other mobile terminal and receive the packet data before receiving the IP address.

Hereinafter, a process of releasing the set packet data path after packet data communication between mobile terminals ends with reference to FIG. 6 will be described.

In step 600 of packet data path release, packet data communication between the mobile station 1 (100) and the mobile station 2 (102) is terminated.

In step 602 of packet data path release, the mobile station 1 100 and the mobile station 2 102 request the PDSN network 104 to release an IP address assigned thereto. The PDSN network 104 requested to release the IP address moves to step 604 to release the assigned IP address. The mobile station 1 (100) and the mobile station 2 (102) notifies that the allocated IP addresses have been deallocated to the IP address pool of Table 1. The IP address pool notified that the IP address allocation has been released records and stores the time when the allocated IP addresses are released. In this way, as described above, the release time of the allocated IP address is allocated when the IP address allocation is requested again in the order of the fastest IP address.

In step 606 of the packet data path release, the mobile terminal 1 100 and the mobile terminal 2 102 request deregistration of the telephone number and the assigned IP address registered in the gatekeeper. The gatekeeper requesting the deregistration performs deregistration of the registered telephone number and the assigned IP address. In this case, steps 602 to 606 may be performed as one process.

As shown in FIG. 6, the mobile terminals which have completed the packet data communication return the IP addresses assigned to them. In this way, the mobile stations other than the mobile terminals that want packet data communication can use the returned IP addresses when they want to perform packet data communication.

As described above, according to the present invention, IP address allocation is performed only when the counterpart mobile terminal desires packet data communication. In this manner, IP addresses are prevented from being wasted because IP addresses are not assigned to mobile terminals that attempt to communicate packet data but are not successful. In addition, IP addresses are assigned only when necessary, so that smooth IP address management is achieved.

1 is a diagram illustrating a process of establishing a packet data path between mobile terminals in general.

FIG. 2 is a diagram illustrating a packet data path setting procedure of FIG. 1 and showing the order of control flow; FIG.

3 is a diagram illustrating a hierarchical structure for setting a packet data path between mobile terminals.

4 is a diagram illustrating a process of setting a packet data path between mobile terminals to which the present invention is applied.

FIG. 5 is a block diagram illustrating a process of setting a packet data path between mobile terminals of FIG. 4. FIG.

FIG. 6 is a block diagram illustrating a process of releasing a packet data path between mobile terminals that have been established. FIG.

Claims (10)

delete A method for setting a packet data path from a first mobile terminal to a second mobile terminal to which data communication is desired, the method comprising: Requesting packet data communication from the first mobile terminal to the second mobile terminal; Determining whether to accept the request received by the second mobile terminal and notifying the first mobile terminal; Allocating an Internet Protocol (IP) address for the packet data communication only when the second mobile terminal accepts the packet data communication with the first mobile terminal, When the second mobile terminal accepts the packet data communication request, the first mobile terminal and the second mobile terminal request the Internet Protocol (IP ) address allocation to a packet data serving node (PDSN) network; The method. A method for setting a packet data path from a first mobile terminal to a second mobile terminal to which data communication is desired, the method comprising: Requesting packet data communication from the first mobile terminal to the second mobile terminal using a short message; Determining whether to accept the request received by the second mobile terminal and notifying the first mobile terminal; And allocating an Internet Protocol (IP) address for the packet data communication only when the second mobile terminal accepts the packet data communication with the first mobile terminal. 4. The method of claim 3, further comprising: registering the allocated IP address and the telephone numbers of the respective mobile terminals with the gatekeeper when the IP addresses are allocated to the first mobile terminal and the second mobile terminal. The method. 1. A method of performing packet data communication between a first mobile terminal and a second mobile terminal for which data communication is desired. Requesting packet data communication from the first mobile terminal to the second mobile terminal; Determining whether to accept the request received by the second mobile terminal and notifying the first mobile terminal; Allocating an Internet Protocol (IP) address for the packet data communication only when the second mobile terminal accepts the packet data communication with the first mobile terminal; And releasing the IP address assigned to each mobile terminal after completing the packet data communication. An apparatus for setting a packet data path from a first mobile terminal to a second mobile terminal for data communication, the apparatus comprising: The first mobile terminal for requesting packet data communication to the second mobile terminal; The second mobile terminal determining whether to accept the request and notifying the first mobile terminal; And a packet data serving node (PDSN) network for allocating an Internet Protocol (IP) address for the packet data communication only when the second mobile terminal accepts the packet data communication with the first mobile terminal. Said device. The method of claim 6, wherein the first mobile terminal and the second mobile terminal, And if the second mobile terminal packet data communication request is accepted, requesting the IP address allocation to the PDSN network. The method of claim 7, wherein the first mobile terminal,  And requesting packet data communication to the second mobile terminal using a short message. The method of claim 8, wherein the mobile terminal 1 and the mobile terminal 2, And the phone number of the assigned IP address and each mobile terminal is registered in the gatekeeper. An apparatus for performing packet data communication between a first mobile terminal and a second mobile terminal for data communication, the apparatus comprising: The first mobile terminal performing packet data communication using an assigned Internet Protocol (IP) address when the second mobile terminal accepts the packet data communication request, and requesting release after the completion of the execution; The second mobile terminal for performing packet data communication using the assigned IP address when the packet data communication request is accepted and requesting release after completion of the execution; Allocating an IP address for the packet data communication only when the second mobile terminal accepts the packet data communication with the first mobile terminal and performing an IP address release by the request for releasing the allocated IP address. The apparatus comprising a packet data serving node (PDSN) network.