KR20030056143A - Method for controlling hand-off in service boundary area - Google Patents

Abstract

PURPOSE: A method for controlling a hand-off at an inter generation network service boundary area is provided to improve a call complete rate according to the hand-off by appropriately adjusting T_COMP. CONSTITUTION: A mobile station is assigned to a channel of a 2.5G base station at a 2.5G service area for executing a call and continuously searches for the size of a valid channel pilot of a 2G base station(S21,S22). It is confirmed whether an Ec/lo value of the 2G base station is more than an Ec/lo value of the 2.5G base station as much as T_COMP/2(S23). The 2.5G base station transmits a PSMM(Pilot Strength Measurement Message) to a 2.5G switching center through a 2.5G base station controller(S24). A 2.5G switching center exchanges information with a 2G switching center(S25). The 2G switching center transmits an HDM(Handoff Direction Message) to the 2.5G switching center(S26). The 2.5G switching center orders a hand-off to the mobile station located at a boundary area(S27). The mobile station hands off to an assigned channel of the 2.5G base station and transmits an HCM(Handoff Completion Message) signal to the 2G switching center(S28).

Description

Method for controlling handoff in intergenerational network service boundary area

The present invention relates to a handoff control method in an intergenerational network service boundary area. More particularly, the present invention relates to an Ec / Io value of a source base station and an Ec / Io of a target base station when moving from a 2.5G service area to a 2G service boundary area. The present invention relates to a handoff control method in an intergenerational network service boundary area for controlling handoff and a computer-readable recording medium having recorded thereon a program for realizing the method.

In general, the handoff is to continuously maintain a call between the mobile station and the base station when the mobile station in the call moves out of the service area of the serving base station to another adjacent base station area. Off is largely divided into softer handoff, soft handoff and hard handoff.

Here, the softer handoff is generated when moving between sectors with the same frequency and the same frame offset value in the base station. The processing of the soft handoff is performed by setting a target sector and a new path while maintaining an existing path between the mobile station and the base station. It transmits through the passage and recovers the existing passage if the mobile station does not need to move sufficiently to the target sector to maintain the existing passage.

The soft handoff is generated when the mobile station moves with the same frequency and the same frame offset between neighboring base stations. The processing of the soft handoff establishes another path between the target mobile station cells while moving while maintaining a constant path between the existing mobile station and the base station. The voice packet is transmitted through several paths, and if the mobile station does not need to sufficiently move to the target sector and maintain the existing path, the existing path is recovered.

The hard handoff occurs when the frame offset is changed or when the frequency is changed when moving between neighboring base stations, and when the code division multiple access system moves from the mobile communication system to the analog system. Unlike softer handoffs and soft handoffs, you can't keep the existing channel and only use the newly established channel to send voice packets.

On the other hand, recently, the second generation mobile communication system based on IS-95 (hereinafter referred to as "2G system") and the second generation mobile communication system based on CDMA 2000 1X (hereinafter referred to as "2.5G system") In the boundary area between two households, call disconnection or location registration error occurs in the location registration, call processing and handoff procedure, especially when the mobile terminal moves from the 2.5G service area to the 2G service area. If the T-COMP is set unnecessarily high, unsatisfactory handoff does not occur and call quality deteriorates.

In general, when the T_COMP value is small, a signal of a base station to be moved, i.e., a target base station, is acquired quickly and handoff occurs at a time when two signal Ec / Io values are good. The disadvantage is that the data capacity is reduced.

On the other hand, if the T_COMP value is taken large, the handoff period is shortened, but the source base station Ec / Io value rapidly deteriorates when the target base station signal is acquired, thereby increasing the possibility of call drop.

Therefore, in the place where handoffs occur between 2.5G and 2G generations, most of them are in the outlying area, so the transmission level is lower than that in the urban area, while the Ec / Io value is good, so the T-COMP value of the boundary area is required to be adjusted. .

Accordingly, the present invention has been devised to meet the above-described demands, and it is desirable to adjust the T-COMP value in 2G and 2.5G service boundary areas appropriately when moving from 2.5G service area to 2G service boundary area. It is an object of the present invention to provide a hand-off control method in an intergenerational network service boundary area for handoff and a computer-readable recording medium recording a program for realizing the method.

1 is an exemplary system configuration for explaining control of handoff in an intergenerational network service boundary area to which the present invention is applied;

2 is a flowchart illustrating a handoff control method in an intergenerational network service boundary area according to the present invention.

※ Explanation of code for main part of drawing

100: A base station 110: B base station

120: A base station controller 130: B base station controller

140: exchange bureau 150: location register

The method of the present invention for achieving the above object, in the hand-off control method in the inter-generational network service boundary region, performing the call through the next-generation intelligent network base station, and searching for the adjacent base station having the same frequency Stage 1; A second step of measuring an Ec / Io value of the searched neighbor base station; Transmitting a pilot strength measurement message (PSMM) when the measured Ec / Io value of the neighboring base station is T_COMP / 2 or more than the Ec / Io value of the next-generation next-generation intelligent network base station; And performing a handoff to the neighboring base station by receiving the handoff indication message (HDM), and delivering a handoff complete message (HCM) to the base station which has turned off.

Meanwhile, the present invention provides a first terminal for performing a call through a next-generation intelligent network base station to a terminal device having a processor for handoff control in an intergenerational network service boundary area, and searching for an adjacent base station having the same frequency. function; A second function of measuring an Ec / Io value of the searched neighbor base station; A third function of transmitting a pilot strength measurement message (PSMM) when the measured Ec / Io value of the neighboring base station is T_COMP / 2 or more than the Ec / Io value of the next-generation next-generation intelligent network base station; And a computer readable recording program for realizing a fourth function of receiving the handoff indication message (HDM) to perform a handoff to an adjacent base station, and delivering a handoff complete message to the handed off base station. Provide the medium.

Hereinafter, a preferred embodiment of a handoff control method in an intergenerational network service boundary area according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating an example of a network configuration for controlling handoff in an intergenerational network service boundary area to which the present invention is applied.

As shown in Figure 1, the network configuration diagram, 2.5G base station 100, 2G base station 110, 2.5G base station controller 120, 2G base station controller 130, 2.5G switching center 240 and 2G A switching center 150, wherein the 2.5G switching station 240 and the 2G switching station 150 are connected with the location registers 145 and 155, respectively.

The 2.5G base station 100, the 2.5G base station controller 120 and the 2.5G switching center 140 is a system built for high-speed data communication, the voice data and text data, as well as the video data connection to the terminal at a very high speed Configure for communicating via.

The 2G base station 110, the 2G base station controller 130, and the 2G switching center 150 are configured to communicate IS 95 based voice data and text data currently being operated through a call connection with a terminal.

In this case, the 2.5G service network and the 2G service network are mixed and continuously operate the idle channel pilot size of the terminal connected to the 2.5G service network, that is, the 2G terminal 110 which is a base station adjacent to the terminal capable of ultra-high speed data communication. Search with. At this time, the 2G base station 110 has the same frequency as the 2.5G base station 100 to which the terminal is currently connected and has a different offset.

Accordingly, the terminal checks parameters for handoff based on the Ec / Io value of the neighboring base station, that is, the 2G base station 110 and the Ec / Io value of the 2.5G base station while moving.

Here, when the Ec / Io value of the 2G base station 110 is determined to be T_COMP / 2 or more than the Ec / Io value of the 2.5G base station, this time is recognized as a handoff time point, and the PSMM (Pilot) is applied to the 2.5G base station 100. Strength Measurement Message: transmits a pilot signal strength measurement message. Then, the 2.5G base station 100 exchanges the PSMM signal with the 2G switch station 150 and the 2G base station controller 130 through the 2.5G base station controller 120 and the 2.5G switch 140.

In this information exchange, terminal information currently moving and channel information available in the 2G base station 110 come and go.

At this time, the 2G switch station 150 confirms the call channel assigned to the 2G base station 110, and handoff direction message: HDM (Handoff Direction Message) to the 2.5G switch station 140 to hand off the terminal to the assigned call channel. ) Transmit the signal. Then, the 2.5G switching center 140 instructs the terminal located in the boundary area through the 2.5G base station controller 120 and the 2.5G base station 100 to hand off.

Accordingly, the terminal hands off to the assigned channel of the 2.5G base station 100 and finally transmits a HCM (Handdff Completion Message) signal to the 2G switching center 150 through the 2G base station controller 130.

Accordingly, the 2.5G switching center 140 may continuously maintain the call through the 2G base station 110 that is handed off as the channel allocated to the 2.5G base station 100 is recovered.

2 is a flowchart illustrating a handoff control method in an intergenerational network service boundary area according to the present invention.

As shown in FIG. 2, the terminal continuously searches for the idle channel pilot size of the 2G terminal 110 which is an adjacent base station while performing a call by being allocated to a channel of the 2.5G base station () in the 2.5G service area (S21). S22).

At this time, the mobile station checks a parameter for handoff based on the Ec / Io value of the neighboring base station, that is, the 2G base station 110 and the Ec / Io value of the 2.5G base station, where the Ec of the 2G base station 110 is located. If the / Io value is determined to be T_COMP / 2 or more than the Ec / Io value of the 2.5G base station (S23), this is recognized as the time of handoff, and the PSG (Pilot Strength Measurement Message: pilot signal) is transmitted to the 2.5G base station 100. Intensity measurement message) signal. Then, the 2.5G base station 100 transmits the PSMM signal to the 2.5G switch 140 through the 2.5G base station controller 120 (S24).

At this time, the 2.5G switch 140 performs information exchange through communication of the 2G switch station 150 based on the received PSMM signal. In this information exchange, terminal information currently moving and channel information available in the 2G base station 110 come and go (S25).

At this time, the 2G switch station 150 confirms the call channel assigned to the 2G base station 110, and handoff direction message: HDM (Handoff Direction Message) to the 2.5G switch station 140 to hand off the terminal to the assigned call channel. ) Signal is transmitted (S26). Then, the 2.5G switching center 140 instructs the terminal located in the border area through the 2.5G base station controller 120 and the 2.5G base station 100 to hand off (S27).

Accordingly, the terminal hands off to the assigned channel of the 2.5G base station 100 and finally transmits a HCM (Hand off Completion Message) signal to the 2G switching center 150 through the 2G base station controller 130 (S28).

Accordingly, the 2.5G switching center 140 may continuously maintain the call through the 2G base station 110 that is handed off as the channel allocated to the 2.5G base station 100 is recovered.

As mentioned above, preferred embodiments of the present invention are disclosed for purposes of illustration, and those skilled in the art can improve and change various other embodiments within the technical spirit and technical scope of the present invention disclosed in the appended claims below. , Replacement or addition would be possible.

In the inter-generation network service boundary region according to the present invention, the handoff control method compares an Ec / Io value of a source base station with an Ec / Io of a target base station when moving from a 2.5G service region to a 2G service boundary region. By controlling the handoff is a useful invention that can improve the call completion rate according to the handoff.

Claims (3)

A handoff control method in an intergenerational network service boundary area, Performing a call through a next generation intelligent network base station and searching for neighboring base stations having the same frequency; A second step of measuring an Ec / Io value of the searched neighbor base station; Transmitting a pilot strength measurement message (PSMM) when the measured Ec / Io value of the neighboring base station is T_COMP / 2 or more than the Ec / Io value of the next-generation next-generation intelligent network base station; And A fourth step of receiving the handoff indication message (HDM) to perform a handoff to an adjacent base station, and delivering a handoff completion message to the handed off base station; Hand off control method in the intergenerational network service boundary area including a. The method of claim 1, The handoff between the next generation intelligent network base station and the adjacent base station, A method for handoff control in an intergenerational network service boundary region, wherein the transmission level occurs in a region having a low transmission level and a relatively high Ec / Io value. In the terminal device having a processor for handoff control in the intergenerational network service boundary area, A first function of performing a call through a next generation intelligent network base station and searching for neighboring base stations having the same frequency; A second function of measuring an Ec / Io value of the searched neighbor base station; A third function of transmitting a pilot strength measurement message (PSMM) when the measured Ec / Io value of the neighboring base station is T_COMP / 2 or more than the Ec / Io value of the next-generation next-generation intelligent network base station; And A fourth function of receiving the handoff indication message (HDM) to perform a handoff to a neighboring base station, and delivering a handoff completion message to the handed off base station; A computer-readable recording medium having recorded thereon a program for realizing this.