KR20090126509A - Method and system for minimizing delay that is owing to hard hand-off in wireless communication system - Google Patents

Abstract

PURPOSE: A delay minimization method and a system thereof in a hard handoff in a wireless communications system are provided to minimize data transmission delay in hard handoff in a boundary area. CONSTITUTION: An AT(Access Terminal)(110) moves from first sub network to a second sub network in a wireless communication system. The first sub-network and the second sub network have versions different from each other. A GAN(150) buffers the packet data over the expected level. The GAN checks a packet sequence in the AT. If the hard handoff is completed by using the buffered data, the GAN transmits the packet transmitted in AT.

Description

Method for minimizing delay in hard handoff in wireless communication system and system therefor {METHOD AND SYSTEM FOR MINIMIZING DELAY THAT IS OWING TO HARD HAND-OFF IN WIRELESS COMMUNICATION SYSTEM}

The present invention relates to a wireless communication system, and more particularly, to a method and a system for minimizing a delay caused during FA handoff between sub-networks of different versions of a wireless communication network.

Mobile communication networks are evolving in the order of IS-95A, IS-95B, CDMA2000 1x, CDMA2000 1xEV-DO, CDMA2000 1xEV-DV, and WCDMA. The IS-95A / B network separated voice and line data at the exchange, and provided service by changing the line data into packet data by an interworking device (IWF). The data transmission rate reached about 64 Kbps as it reached the IS-95B. . In addition, in the CDMA2000 1x network, a data core network (DCN) was introduced to support high-speed data services, and a packet data service node (PDSN) was connected to the Internet, and data reception was introduced by the introduction of a home agent (HA). Mobility management has been made possible, and data transfer rates have reached up to 153.6 Kbps.

Meanwhile, CDMA2000 1xEV-DO network is a packet data dedicated network that supports the highest data transfer rate of 2.4576Mbps. It is implemented together with CDMA2000 1x system to provide voice service by CDMA2000 1x and share data core network with CDMA2000 1x. -Has a terminal authentication function by the authentication device (AN-AAA), and has a function of managing the terminal location by the data location register (DLR).

As such, the CDMA2000 1x service is a service capable of wireless Internet at a much higher speed than the speed supported by the IS-95A / B network by using the IS-95C network that has evolved from the existing IS-95A / B network. The CDMA2000 1xEV-DO system began with Qualcomm's announcement of a technology called IS-95 HDR, which is identical in frequency to the CDMA2000 1x, but with a completely different radio access standard for other modulation schemes. Although HDR technology adopts the CDMA scheme, in order to provide a packet data service, a modulation scheme of a signal is adopted in a completely new format to implement a kind of TDMA function on the forward link. This has attracted attention by providing a maximum data rate of 2.4 MHz using the same 1.25 MHz frequency band as the IS-95.

Specifically, the forward link of the CDMA2000 1x system transmits all channels multiplexed in the code direction so that the signals of all users are simultaneously occupied by all frequencies, while the forward link of the CDMA2000 1xEV-DO system only has one user at a time. The data is transmitted, and at the next moment, another user's signal is transmitted to form a multiplexed form of time division multiple access (TDMA) having a different signal transmission time for each user. In this case, the base station can set the transmission signal power for each user to the maximum value of the base station transmitter, so that in the time zone occupied by each user, the base station can transmit the signal with the most suitable signal for each user. As a result, data rates of up to 2.4576Mbps can be supported.

The CDMA2000 1xEV-DO system is now evolving from Rev.0, which was commercialized in 2002, to Rev.A, which is currently being commercialized. Rev.A is the original 1xEV-DO Rev. In addition to providing a higher peak data rate by upgrading only the channel card, the system also includes higher quality services, such as QoS, which was not implemented in Rev. 0. Provide infrastructure.

However, there is a problem that the quality of the communication service can be degraded in the border region of Rev. 0 and Rev. A by providing a mixture of the current 1xEV-DO Rev. 0 and Rev. A. That is, when the Rev. A terminal moves to the Rev. 0 region in the Rev. A region, the terminal performs handoff (hard handoff) between frequencies. That is, during hard handoff, the terminal disconnects the existing link and newly establishes a link through another FA in the mobile area. Therefore, a delay occurs as time according to the FA transition, and the data sequence number received from the existing serving cell is calculated. Therefore, there is a problem that a delay occurs due to a calculation time for sending subsequent data to a target cell.

This problem occurs as the wireless communication network standard evolves from version to version, and is not a problem in the CDMA2000 1xEV-DO system but also in other wireless communication systems such as a WCDMA system.

Looking at the above-mentioned degradation of quality in more detail, unlike hard handoff, unlike the soft handoff, since the existing link is disconnected and transitions to another FA, link loss may occur during handoff. After that, the data may not be transmitted for a certain time. That is, due to the instantaneous loss of the link, flow control operates inside the system, and thus throughput may decrease for a certain period of time even after the link is established. There is also a problem that the throughput is also lowered by calculating and requesting retransmission to the higher node if it is lost.

Therefore, from the operator's point of view, the quality degradation is improved by improving the delay that may occur during hard handoff between versions in the border area between different sub-networks (for example, between Rev. 0 and Rev. A) of different versions of the wireless communication network. It is important to prevent.

Accordingly, the present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide a wireless communication system capable of minimizing data transmission delay during hard handoff at a border area between sub networks forming different versions of a wireless communication network. A method and system for minimizing delay during hard handoff are provided.

Another object of the present invention, in the case of hard handoff between base stations between different sub-networks of the wireless communication network, recognizing that a hard handoff is requested, and checks the sequence of packets checked by the terminal until the link is established, As soon as the link setting between the target base station and the terminal is completed, the base station of the first sub-network and the base station of the second sub-network are allowed to transmit the packet after the completion of the transmission, so that data can be transmitted without delay according to the sequence calculation. The present invention provides a method and system for minimizing delay during hard handoff in a wireless communication system capable of minimizing delay during handoff.

Method for minimizing delay during hard handoff in a wireless communication system according to the first aspect of the present invention for achieving the above object is a method for minimizing delay during hard handoff in a wireless communication system, a) from the GAN to the terminal Buffering the transmitted packet data more than a predetermined level; And b) when a hard handoff request is generated from the terminal, the GAN checks the packet sequence confirmed by the terminal, and when the handoff is completed, the GAN uses the data buffered by step a). And transmitting the transmitted packet to the terminal.

Preferably, the GAN is characterized in that to perform the packet sequence check at a predetermined period.

Also preferably, the step a) is performed by a buffer installed in the RPP board of the GAN.

More preferably, the step b) is b-1) when the handoff request from the terminal is generated, determining whether the handoff is a hard handoff in the GAN; b-2) when the handoff request is a hard handoff, as a result of the determination of step b-1), checking a packet sequence checked by the terminal; And b-3) when the handoff is completed, the GAN transmits an untransmitted packet to the terminal based on the result of step b-2.

In the wireless communication system according to the second aspect of the present invention, a method for minimizing delay during hard handoff may include: a) buffering packet data transmitted from a GAN to a UE in a buffer of an RPP board of a predetermined level or more; b) when the handoff request from the terminal is generated, determining whether the handoff is a hard handoff between FAs in the GAN; c) as a result of the determination of step a), if the handoff request is a hard handoff, checking a packet sequence checked by the terminal at predetermined intervals; And d) determining whether the hard handoff is completed and the terminal completes link establishment with a target base station. And e) when the terminal completes link establishment with the target base station as a result of the step d), the GAN based on the check result of the step c), transmitting the untransmitted packet to the terminal. It features.

According to a third aspect of the present invention, a system for minimizing a delay during a hard handoff includes a GAN for buffering packet data to be transmitted to a terminal over a predetermined level in a wireless communication system, wherein the GAN is from the terminal. When the hard handoff request is generated, the packet sequence checked by the terminal is checked, and when the handoff is completed, an untransmitted packet is transmitted to the terminal by using the buffered data. .

Preferably, the GAN is characterized in that to perform the packet sequence check at a predetermined period.

Also preferably, the GAN further comprises a buffer for buffering the packet data.

More preferably, the buffer is characterized in that installed on the RPP board of the GAN.

According to a fourth aspect of the present invention, a system for minimizing a delay during a hard handoff is a wireless communication system. The system includes a buffer installed on an RPP board to buffer packet data to be transmitted to a terminal over a predetermined level. When the handoff request from the terminal is generated, the GAN determines whether the handoff is a hard handoff between FA, If the determination result, the handoff request is a hard handoff, The packet sequence checked by the terminal is checked at predetermined intervals, and when the terminal completes link establishment with the target base station according to the hard handoff request, the unsent packet is transmitted to the terminal based on the check result. Characterized in that the transmission.

According to the present invention, upon hard handoff between a base station of a first sub network and a base station of a second sub network in a border area between sub networks forming different versions of a wireless communication network, a link is established by recognizing that a hard hand off is requested. By checking the sequence of the packet confirmed by the terminal until the end of the link, as soon as the link setting between the target base station and the terminal is completed, it is possible to transmit the packet after the transmission is completed, it is possible to transmit data without delay according to the sequence calculation In addition, data transmission delay during hard handoff can be minimized.

Hereinafter, the present invention will be described in more detail with reference to the following examples.

In a wireless communication system according to the present invention, a system for minimizing a delay during hard handoff includes a GAN for buffering packet data to be transmitted to a terminal over a predetermined level.

The GAN according to the present invention checks the packet sequence confirmed by the terminal when a hard handoff request is generated from the terminal. At this time, the GAN performs the packet sequence check at a predetermined cycle. Subsequently, when the handoff is completed, the GAN transmits an untransmitted packet to the terminal using the buffered data according to the packet sequence check result.

1 is a diagram illustrating an example of a system to which a method for minimizing delay in hard handoff is applied in a wireless communication system according to the present invention.

Referring to FIG. 1, in a wireless communication system according to a preferred embodiment of the present invention, a system to which a method for minimizing delay in hard handoff is applied may include a first sub network and a second sub network having different versions from among wireless communication systems. The system can be mixed.

When the wireless communication system is a 1xEV-DO system, the first sub network may be Rev. A and the second sub network may be Rev. 0.

In the system, each of the base station (AN) 120 and 130 of the first sub-network and the second sub-network has a terminal (AT) according to the standard of each of the first and second sub-networks of the wireless communication network. Access Terminal): Supports communication between IP networks (not shown) of 110). In addition, the ANC / PCFs 131 and 132 include a SC / MM (Session Control and Mobility Management) function, and are a base station controller for providing a packet data service and exchange control signals and traffic information for a packet data service.

AN-AAA (Access Network Authentication, Authorization and Accounting) 140 performs authentication and charging functions of the terminal 110 for the base station 120 and 130. In addition, the Packet Data Serving Node (PDSN) 160 is connected to the base stations 120 and 130 through the ANC / PCF 131 and 132 to provide a packet data service to the terminal 110.

The system also includes a GAN 150. The GAN 150 is connected to the ANC / PCFs 131 and 132 to perform mobility maintenance and session control functions for subscribers, and according to the present invention, packet data to be transmitted to the terminal 110 according to the present invention. Buffer above a certain level.

Preferably, the GAN 150 includes a buffer installed on an RPP board to buffer the packet data.

When the handoff request from the terminal 110 is generated, the GAN 150 determines whether the handoff is a hard handoff between FAs. As a result of determination, when the handoff request is a hard handoff, the GAN 150 checks the packet sequence checked by the terminal 110 at predetermined time intervals. Thereafter, when the terminal completes link setup with the target base station according to the hard handoff request, the GAN 150 transmits the untransmitted packet to the terminal 110 according to the check result.

Accordingly, the system may establish a link when a hard handoff is performed between the first sub-network base station 120 and the second sub-network base station 130 of the wireless communication system in a bordering area of a sub-network forming a different version of the wireless communication network. By checking the sequence of packets confirmed by the terminal until the link setting between the target base station 130 and the terminal 110 is completed, it is possible to transmit the packet after the transmission is completed, without delay according to the sequence calculation Can be transmitted.

Hereinafter, a method and system for minimizing delay in hard handoff in a wireless communication system according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a flowchart illustrating an operation of the apparatus illustrated in FIG. 1.

Referring to FIG. 2, the GAN 150 according to the present invention mounts a buffer on an APP board in order to minimize delay in hard handoff according to the present invention, and a packet transmitted to the terminal 110 in the buffer. Data is buffered (S1).

As the terminal 110 approaches the base station 130 of the second sub network, which is the target base station, from the base station 120 of the first sub network, which is the source base station, the terminal 110 determines a handoff (S2). .

If the handoff is determined, the terminal 110 transmits a route update message to the base station 120 of the first sub-network for handoff (S3).

When receiving a route update message for the handoff from the terminal 110 at the base station 120 of the first sub-network designated as a boundary cell. The base station 120 of the first sub network requests a handoff from the GAN 150 through the source ANC / PCF 131 (S4).

When receiving the handoff request, the GAN 150 determines whether the handoff is an inter-FA hard handoff, that is, a handoff from a version of a first subnetwork to a version of a second subnetwork (S5). . For example, the GAN 150 compares the PN included in the route update message with the PN of the target base station requested for handoff to determine whether the handoff is a hard handoff.

Subsequently, in response to the handoff request, the GAN 150 requests a handoff from the target ANC / PCF 132 to the base station 130 of the second sub-network, which is a target AN. When the off request is a hard handoff, the packet sequence checked by the terminal is checked at predetermined intervals (S5 and S6).

Subsequently, when the handoff is completed between the terminal 110 and the target base station 130 and a handoff completion message is received from the target base station 130, that is, a link is established between the terminal and the target base station 130. When this is completed, the GAN 150 transmits the untransmitted packet to the terminal 110 based on the check result of the step S7).

Therefore, according to the above configuration, when the hard handoff between the base station of the first sub-network and the base station of the second sub-network in the wireless communication system in the border area of the sub-network constituting a different version of the wireless communication network, a hard handoff is requested. Recognizes and checks the sequence of packets confirmed by the terminal until the link is established, as soon as the link setting between the target base station and the terminal is completed, it is possible to transmit the packet after the completion of the transmission, without delay according to the sequence calculation Data can be transferred.

As described above, according to the present invention, a method for minimizing delay during hard handoff in a wireless communication system capable of minimizing data transmission delay during hard handoff in a border area of a subnetwork constituting a different version of the wireless communication network and the same The system can be realized.

Although the present invention has been described in detail by the above embodiments, the present invention is not limited thereto, and variations and improvements can be made without departing from the ordinary knowledge of those skilled in the art.

In addition, the present invention, when the hard handoff between the base station of the first sub-network and the base station of the second sub-network in the wireless communication system in the border area of the sub-network that forms a different version of the wireless communication network, After checking the sequence of the packet confirmed by the terminal until the link is established, as soon as the link setting between the target base station and the terminal is completed, it is possible to transmit the packet after the transmission is completed, so that the data can be transmitted without delay according to the sequence calculation. In order to be able to transmit and to minimize data transmission delay during hard handoff, the invention is an industrially available invention because the possibility of commercialization or business is not only sufficient but also practically obvious.

1 is a diagram illustrating an example of a system to which a delay minimization method is applied during a hard handoff in a wireless communication system according to an exemplary embodiment of the present invention.

FIG. 2 is a flowchart illustrating an operation of the apparatus illustrated in FIG. 1.

<Explanation of symbols for main parts of the drawings>

110: AT 120: Source AN Rev.A

130: Target AN Rev. 0 131: Source ANC / PCF

132: target ANC / PCF 140: AN AAA

150: GAN 160: PDSN

Claims (10)

In a wireless communication system, A terminal for locating from a first sub network that forms a different version of the wireless communication system to a second sub network; And GAN for buffering the packet data to be transmitted to the terminal above a predetermined level, The GAN, When a hard handoff request is generated from the terminal, the packet sequence checked by the terminal is checked, and when the handoff is completed, transmitting an untransmitted packet to the terminal using the buffered data. A system for delay minimization during hard handoff in a wireless communication system. 2. The system of claim 1, wherein the GAN performs the packet sequence check at a predetermined cycle. 3. The system of claim 1 or 2, wherein the GAN further comprises a buffer for buffering the packet data. 4. The system of claim 3, wherein the buffer is installed on an RPP board of the GAN. In a wireless communication system, A terminal for locating from a first sub network that forms a different version of the wireless communication system to a second sub network; And And a GAN including a buffer installed on an RPP board to buffer packet data to be transmitted to the terminal over a predetermined level. The GAN, When a handoff request is generated from the terminal, it is determined whether the handoff is a hard handoff between FAs. When the determination result indicates that the handoff request is a hard handoff, the packet sequence confirmed by the terminal is determined. In the wireless communication system characterized in that for checking at a predetermined period, and when the terminal completes the link setting with the target base station in response to the hard handoff request, based on the check result, the untransmitted packet is transmitted to the terminal. Minimize delay during hard handoff. A method for minimizing delay in hard handoff in a wireless communication system, a) buffering packet data transmitted to a GANDL terminal in the wireless communication system by a predetermined level or more; And b) When a hard handoff request is generated from the terminal, the GAN checks the packet sequence confirmed by the terminal, and when the handoff is completed, the GAN does not transmit using the data buffered by step a). And transmitting the decoded packet to the terminal. 7. The method of claim 6, wherein the GAN performs the packet sequence check at a predetermined cycle. The method of claim 1, wherein the step a) is performed by a buffer installed in an RPP board of the GAN. The method according to any one of claims 6 to 8, Step b) is b-1) when a handoff request is generated from the terminal, determining whether the handoff is a hard handoff in the GAN; b-2) when the handoff request is a hard handoff, as a result of the determination of step b-1), checking a packet sequence checked by the terminal; And b-3) when the handoff is completed, the GAN comprises transmitting an untransmitted packet to the terminal based on the result of step b-2). How to minimize delay on handoff. a) buffering, by the GAN in the wireless communication system, packet data transmitted to the terminal to a buffer of the RPP board at a predetermined level or more; b) when the handoff request from the terminal is generated, determining whether the handoff is a hard handoff between FAs in the GAN; c) as a result of the determination of step a), if the handoff request is a hard handoff, checking a packet sequence checked by the terminal at predetermined intervals; And d) determining whether the hard handoff is completed and the terminal completes link establishment with a target base station; e) when the terminal completes link setting with the target base station as a result of the determination of step d), the GAN includes transmitting an untransmitted packet to the terminal based on the check result of step c). A delay minimization method during hard handoff in a wireless communication system.

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