KR20030063622A - Method for managing network in mobile communication system - Google Patents

Abstract

PURPOSE: A method for managing a network of a base station in a mobile communication system is provided to transmit a command of solely receiving a signal having a reassemble PN offset to a mobile communication terminal, if strength of a pilot signal is smaller than specific size, thereby controlling the number of sectors. CONSTITUTION: A base station creates an optional reassemble PN offset(101), and transmits a reassemble pilot signal to a mobile communication terminal(103). The terminal transmits a reassemble pilot signal strength response message to the base station(105). The base station transmits a traffic signal having an inherent PN offset with a traffic signal having the reassemble PN offset to the terminal(107). The terminal simultaneously receives the traffic signals(109). The base station increases strength of a reassemble pilot signal, and reduces strength of an inherent pilot signal, then transmits the signals to the base station(111), and transmits each pilot signal strength response message to the base station(113). The base station decides whether the strength of the inherent pilot signal is smaller than specific size(115). If so, the base station commands the terminal to solely receive signals only having the reassemble PN offset(117). The terminal stops receiving signals having the inherent PN offset, and receives the signals having the reassemble PN offset only(119).

Description

METHOD FOR MANAGING NETWORK IN MOBILE COMMUNICATION SYSTEM}

The present invention relates to a mobile communication system, and more particularly, to a network management method of a base station.

In a mobile communication system, when a cell serving as one base station serves to be divided into a plurality of service areas, each divided service area is referred to as a sector. Handoff between these sectors is called soft handoff. Soft handoff is achieved by reassigning only Walsh codes without newly assigning separate channel elements. At this time, the mobile communication terminal located in an area where the sectors overlap each other must receive power control in both sectors during the soft handoff.

In general, one cell is divided into three sectors. However, as the number of mobile communication subscribers increases, the number of subscribers that one base station must accommodate has increased. Accordingly, one cell has been changed into a multi-sector structure consisting of six sectors. As a result, the number of subscribers moving from one sector to another becomes frequent, resulting in an increase in handoff.

Increasing handoff has also resulted in an increase in handoff related signaling, which acts as a load on the base station. As a result, the call is disconnected when the inter-sector handoff occurs, which degrades the call quality. This problem occurs even when the number of subscribers actually located in one cell is small.

Accordingly, an object of the present invention is to provide a network management method for flexibly adjusting the number of sectors according to the load state of a base station according to the number of actual subscribers located in one cell.

Another object of the present invention is to provide a network management method for reducing call disconnection during handoff between sectors and increasing call quality due to reception diversity effect.

In order to achieve the above object, the present invention provides a base station for serving a plurality of basic sectors having different inherent PSI offsets, and a re-segmented pilot signal having a PSI offset to be divided into terminals located in the plurality of basic sectors. Transmitting the received response message for the re-divided pilot signal from the terminal, transmitting a traffic signal having the inherent PIN offset and a traffic signal having the re-divided PIEN offset to the terminal at the same time; Reducing the intensity of the unique pilot signal of the basic sector having the inherent PEN offset and increasing the intensity of the re-divided pilot signal to transmit to the terminal, and receiving information on the strength of each pilot signal from the terminal. Process, and the strength of the unique pilot signal If it is smaller than a certain size, it is characterized in that it has a process of transmitting a command for receiving a single signal having the re-divided Pien offset to the terminal.

1 is a block diagram of a base station according to an embodiment of the present invention;

2A illustrates a normal sector division state according to an embodiment of the present invention;

2B illustrates a basic sector combination state according to an embodiment of the present invention;

3 is a message flow diagram according to a process of combining basic sectors according to an embodiment of the present invention.

4 is a message flow diagram illustrating a process of recovering a combined sector to a normal sector division state according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, detailed description of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

According to an embodiment of the present invention, the base station 100 serves a cell divided into six basic sectors. This is shown in Figure 2a. 2A illustrates a normal sector division state according to an embodiment of the present invention. As shown in FIG. 2A, a cell served by the base station 100 is divided into α, β, γ, α ', β', and γ 'sectors.

A configuration of a base station 100 serving a cell having the above structure will be described with reference to FIG. 1. 1 is a block diagram of a base station according to an embodiment of the present invention. As shown in FIG. 1, the base station includes a controller 10, a PN offset (Pseudo Noise Offset) generator 20, a channel card unit 30, and an analog common card (ACC) unit 40. , A transceiver unit 50 and a radio frequency (RF) unit 60.

The controller 10 controls the overall operation of the base station 100, and generates a plurality of PN offsets by controlling the PN offset generator 20 to divide sectors according to the subscriber processing capability of the current base station according to the present invention. do. The PN offset generator 20 generates a plurality of repartitioned PN offsets and unique PN offsets under the control of the controller 10 and outputs them to each ACC constituting the ACC unit 40. The unique PN offset is a PN offset that is multiplied by an arbitrary channel corresponding to each sector to distinguish a basic sector constituting one cell. The repartitioned PN offset is a PN offset for newly dividing a cell by combining a basic sector according to the subscriber processing capability of the current base station according to the present invention. The channel card unit 30 spreads each channel to be transmitted to the mobile communication terminal through the Walsh code under the control of the controller 10, outputs the channels to the ACC unit 40, and despreads the received channels. The ACC unit 40 is composed of a plurality of ACCs corresponding to the basic sectors. Each ACC multiplies a different channel by spreading different PN offsets, thereby splitting one cell into multiple sectors. Therefore, the ACC unit 40 is composed of αACC, βACC, γACC, α'ACC, β'ACC, γ'ACC, and the unique PN offset of each sector is αPN offset, βPN offset, γPN offset, α'PN offset. , β'PN offset and γ 'PN offset. According to the present invention, each ACC is spread by multiplying any channel output from the channel card section 30 by a unique PN offset provided from the PN code generator 20 or by multiplying by a repartitioned PN offset. The transceiver unit 50 is composed of an α transceiver, a β transceiver, a γ transceiver, an α 'transceiver, a β' transceiver, and a γ 'transceiver which are transceivers TX corresponding to each sector. Each transceiver converts an intermediate frequency (IF) signal to an RF signal for the forward link, and also an RF signal for the reverse link. Then, the strength of the received input signal is measured. The RF unit 60 is composed of RF stages corresponding to each sector, amplifies the RF signal input from the transceiver unit 50 with a constant gain, and transmits the RF signal to a mobile communication terminal (subscriber) existing in each sector.

As described above, the base station 100 combines the basic sectors with the subscriber processing capability of the current base station, or divides the combined basic sectors into a normal state and divides the sectors flexibly. When the cell is repartitioned by combining the base sectors, the controller 10 controls the PN offset generator 20 to generate a repartitioned PN offset according to the number of sectors to be repartitioned. The generated repartitioned PN offset is equally provided to a plurality of ACCs corresponding to the basic sectors to be combined according to the number of sectors to be repartitioned. Through a series of processes, a plurality of basic sectors use the newly generated same PN offset, and a plurality of basic sectors using the same PN offset become one repartitioned sector. For example, to subdivide a cell divided into six basic sectors into three sectors, as shown in FIG. 2B, the control unit 10 divides three different subdivisions so that the two basic sectors use the same PN offset. PN offsets are generated to provide each generated PN offset to a pair of ACCs. As a pair of ACCs use a common PN offset, two basic sectors are combined and one cell is divided into three sectors. FIG. 2B is a diagram illustrating a sector division state according to an exemplary embodiment of the present invention, in which a gamma 'sector and an alpha sector, a beta sector and a gamma sector, and an alpha' sector and a beta 'sector are respectively divided into three new sectors. Is shown.

Meanwhile, the ACC multiplies the received repartitioned PN offset by an arbitrary channel, and accordingly, a repartitioned pilot signal having the repartitioned offset is transmitted to the mobile communication terminal existing in the sector through the sector-by-sector antenna via the corresponding transceiver and the corresponding RF terminal. When the mobile communication terminal receives the re-division pilot signal, the mobile communication terminal transmits the size of the re-division pilot signal to the base station 100 through the reception response message. The control unit 10 of the base station 100 transmits a traffic signal having a unique PN offset and a traffic signal having a repartitioned PN offset, and then, when the size of the pilot signal having a unique PN offset is smaller than a predetermined size, the mobile communication terminal is repartitioned. By allowing only traffic signals with PN signals to be received, new cell repartitioning is completed. The predetermined size is a size of a pilot signal that guarantees a minimum call quality to a user when a call is connected through a corresponding traffic channel.

FIG. 3 illustrates a sector combination process for cell repartition. 3 is a message flow diagram illustrating a process of combining basic sectors according to an embodiment of the present invention.

Referring to FIG. 3, the base station 100 generates a random repartitioned PN offset in step 101 and proceeds to step 103. In step 103, the base station 100 transmits the repartitioned pilot signal having the repartitioned PN offset to the mobile communication terminal present in the sector to be combined. When the mobile communication terminal receives the redistributed pilot signal, in step 105, the mobile communication terminal transmits a redistributed pilot signal strength response message having information on the strength of the redistributed pilot signal to the base station 100. When the base station 100 receives the repartitioned pilot signal strength response message, in step 107, the base station 100 transmits a traffic signal having a unique PN offset and a traffic signal having a repartitioned PN offset to the mobile communication terminal. The mobile communication terminal simultaneously receives each traffic signal in step 109. In step 111, the base station increases the strength of the re-divided pilot signal and decreases the strength of the unique pilot signal to transmit to the mobile communication terminal. In step 113, the mobile communication terminal transmits each pilot signal strength response message to the base station 100. In step 115, the base station determines whether the unique pilot signal strength is smaller than a specific size and proceeds to step 117 when it is smaller than the specific size. If the intrinsic pilot signal strength is greater than a certain size, the process proceeds to step 111 and steps 111 to 115 are repeated until the intrinsic pilot signal intensity becomes smaller than a specific size. In step 117, the base station 117 instructs the mobile communication terminal to receive only a signal having the PN offset to be repartitioned. In step 119, the mobile communication terminal stops receiving the signal having the unique PN offset according to the command of the base station 100, and receives only the signal having the repartitioned PN offset, thereby combining the basic sectors.

The process of dividing the combined sectors into a steady-state cell structure is similar to the process of combining the basic sectors. The base station 100 controls the PN offset generator 20 to generate a unique PN offset corresponding to each basic sector and provide it to each ACC. Each ACC multiplies the channel by the received unique PN offset to spread the channel so that each sector uses a unique PN offset. 4 shows a process of dividing the combined sectors into a steady state cell structure.

In step 201, the base station 100 transmits a unique pilot signal having a unique PN offset to a mobile communication terminal existing in a sector to be divided. In step 203, the mobile communication terminal transmits a unique pilot signal strength response message to the base station 100. In step 205, the base station 100 transmits a traffic signal having a unique PN offset and a traffic signal having a repartitioned PN offset to a mobile communication terminal. In step 207, the mobile communication terminal simultaneously receives each traffic signal. In step 209, the base station 100 increases the original pilot signal strength, decreases the re-division pilot signal strength, and transmits the same to the mobile communication terminal. In step 211, the mobile communication terminal transmits each pilot signal strength response message to the base station 100. In step 213, the base station 100 determines whether the re-division pilot signal strength is smaller than a specific size, and if it is smaller than the specific size, the base station 100 proceeds to step 215. If the re-partitioned pilot signal strength is greater than a certain size, the process proceeds to step 209 and repeats step 209 to step 213 until the re-partitioned pilot signal strength becomes smaller than the specific size. In step 215, the base station 100 instructs the mobile communication terminal to receive only a signal having a unique PN offset. In step 217, the mobile communication terminal stops receiving a signal having a sector repartitioning PN offset and receives only a signal having a unique PNoff signal, thereby being divided into a basic sector.

In the above description of the present invention, specific embodiments have been described, but various modifications can be made without departing from the scope of the present invention. For example, the base station may be configured to automatically divide / divide the cells at a predetermined time. Therefore, the scope of the present invention should not be defined by the described embodiments, but should be determined by the equivalent of claims and claims.

As described above, the present invention provides a method of dividing sectors, and accordingly, the number of sectors can be flexibly adjusted according to the load state of the base station according to the number of real subscribers located in one cell, and the call quality can be increased.

Claims (6)

A base station serving a plurality of basic sectors having different unique noise offsets, Transmitting a re-division pilot signal having a re-division pien offset to terminals located in the plurality of basic sectors; Receiving a response message for the re-division pilot signal from the terminal; Transmitting a traffic signal having the inherent pien offset and a traffic signal having the repartitioned pien offset to the terminal at the same time; Reducing the intensity of the unique pilot signal of the basic sector having the inherent PEN offset and increasing the strength of the re-divided pilot signal to transmit to the terminal; Receiving information on each pilot signal strength from the terminal; And if the strength of the unique pilot signal is smaller than a certain size, transmitting a command for receiving a single signal having the subdivided PEN offset to the terminal. The method of claim 1, Generating a unique PEN offset corresponding to each basic sector and transmitting the unique pilot signal to a terminal located at each basic sector; Receiving a reception response message for the unique pilot signal from the terminal; Transmitting a traffic signal having the inherent pien offset and a traffic signal having the repartitioned pien offset to the terminal at the same time; Increasing the strength of the inherent pilot signal and decreasing the strength of the redistributed pilot signal having the redistribution PIN offset and transmitting the same to the terminal; Receiving information on each pilot signal strength from the terminal; And if the intensity of the re-division pilot signal is smaller than a certain size, transmitting a command for receiving a single signal having the unique PEN offset to the terminal. A base station serving a plurality of basic sectors having different unique noise offsets, Transmitting, by the base station, a repartitioned pilot signal having a repartitioned Pien offset to a terminal located in the plurality of basic sectors; Transmitting, by the terminal, a response message for the re-divided pilot received signal to the base station; When the base station receives the reception response message, simultaneously transmitting a traffic signal having a unique PEN offset and a traffic signal having the subdivided PEN offset to the terminal; Reducing the intensity of the unique pilot signal of the basic sector having the inherent PEN offset and increasing the strength of the re-divided pilot signal to transmit to the terminal; Transmitting information on each pilot signal strength received by the terminal to the base station; Receiving, by the base station, information on each pilot signal strength; If the strength of the unique pilot signal is less than a certain size, transmitting a command to receive a signal having the subdivided PIEN offset to the terminal; And the terminal stops receiving the signal having the inherent PEN offset according to the command. The method of claim 3, Generating, by the base station, a unique PEN offset corresponding to each of the basic sectors, and transmitting a pilot signal having the unique PEN offset to a terminal located in each of the basic sectors; Transmitting, by the terminal, a response message for a unique pilot received signal to the base station; When the base station receives the response message, simultaneously transmitting the traffic signal having the unique PEN offset and the traffic signal having the subdivided PEN offset to the terminal; Transmitting, by the base station, the strength of the unique pilot signal, decreasing the strength of the re-divided pilot signal having the PI offset, to the terminal, and transmitting information on the strength of each pilot signal received by the terminal to the base station; Transfer process, Receiving, by the base station, information on each pilot signal strength; Transmitting, by the base station, a command for receiving a single signal having the inherent PEN offset to the terminal when the strength of the subdivided pilot signal is smaller than a specific size; And the terminal stops receiving the signal having the subdivided PEN offset according to the command. The method according to claim 3 or 4, wherein the specific size of each pilot signal is a size of a pilot signal that guarantees a minimum call quality when a call is connected through a corresponding traffic channel. A terminal located in a cell consisting of a plurality of basic sectors having different inherent Pseudo Noise offsets, Receiving a re-division pilot signal having a re-division pien offset from a base station serving the cell; Transmitting a response message to the base station in response to the received re-division pilot signal; Simultaneously receiving from the base station a traffic signal having a unique pien offset and a traffic signal having the subdivided pien offset; Receiving a unique pilot signal of the basic sector having the inherent PIEN offset whose signal strength has been relatively reduced under control of the base station, and the redistributed pilot signal having a relatively increased signal strength; Transmitting information on received pilot signal strengths to the base station; Receiving a command for receiving a single signal having the subdivided Pien offset from the base station; And stopping the reception of the signal having the inherent PEN offset according to the command.