KR20050060586A - Adaptive handoff process method in mobile communication network - Google Patents

Abstract

The present invention relates to a handoff processing method in a next generation mobile communication network.

Since the traffic of the mobile communication network is not uniformly distributed for each cell, the traffic is concentrated to only one cell. This often occurs in urban areas where there are many floating populations.In this case, even though there is sufficient capacity to accept users from the system-wide perspective, it is possible to limit the users who can service due to the load on a specific cell or to degrade the overall service quality. Failure to provide adequate service. In addition, since the next-generation mobile communication network uses a common channel, the amount of service that a user can receive depends on the load of the cell, and thus cannot provide an appropriate service to users living in the cell.

Therefore, an object of the present invention is to increase the overall performance and user satisfaction by accepting more traffic in terms of the overall system through the traffic distribution effect including the load of each cell in handoff decision.

Description

Adaptive handoff process method in mobile communication network

The present invention relates to an adaptive handoff processing method in a next-generation mobile communication network. In detail, the present invention relates to a base station capable of actively coping with uneven traffic and maximizing system efficiency and minimizing degradation of service quality due to packet loss and delay. An adaptive handoff processing technique using the load information of is provided.

Handoff (handoff) is a function that keeps the connection is not disconnected when the terminal moves from one base station to another new base station.

The handoff is an operation performed between the base station and the terminal. Referring to FIG. 1, the conventional handoff processing procedure is as follows.

In a mobile-controlled handoff in which a terminal starts a handoff, the handoff procedure can be largely described as two steps of forward and reverse handoff.

The forward handoff is a preparation step for handoff. After the terminal 100 discovers a new base station with pilot signal strength (S10), that is, the terminal 100 can predict a new base station to be handed off in advance. In this case, it starts by sending a host tunnel initialization (H-TIN) message to the base station 200 to which the terminal is currently connected (S12).

After receiving the H-TIN message, the base station 200 transmits a tunnel initialization (Tunnel INitiation: TIN) message to the new base station 300 to which the terminal is to handoff (S14). As a result, the currently connected base station 200 In step S16, a tunnel is formed between the base stations 300 to be handed off.

If the base station 300 receives the TIN message and receives the handoff, the base station 300 receives a handoff hint (Handoff Hint: HH) message indicating that the terminal 100 is ready for handoff. Is sent (S18), and the forward handoff ends (S20).

Forward handoff is a possible technique for intra technology handoffs and is not necessary. Therefore, in case the forward handoff has not been performed, it is checked whether the forward handoff has occurred in the reverse handoff, and if it does not, the handoff is performed while compensating for the portion.

If the terminal does not know the new base station in advance, the handoff starts with the reverse handoff, and if the forward handoff occurs, the handoff process is performed to the end.

The reverse handoff starts by sending a host handoff request (hereinafter referred to as H-HR) message to the base station 300 to which the terminal 100 newly hands off (S22).

Next, it is checked whether the forward handoff has occurred in the reverse handoff, and if not, the handoff is performed while compensating for the portion (S24).

The base station 300 receiving the H-HR message transmits a handoff request (hereinafter referred to as HR) message to the base station 200 to which the terminal is currently connected. There is a tunnel between the 300 (S26 to S32). In this case, the base station 200 receiving the HR message sends a handoff initialization (Handoff Initiation: HI) message to the new base station 300 to be handed off if the handoff is possible. Send a rejection (Handoff Denial: HD) message (S30).

The new base station 300 continuously sends an HR message until the handoff is successful (S26). If the handoff is allowed, the new base station 300 sends an UPDate route (UPD) message to the base station 400 to which the current terminal is connected (S34). ), The base station 400 responds with an Update Ack (UPDAck) message (S36).

The new base station 300 receives the UPDAck message and sends a handoff Ack (HAck) message to the UE (S38), thereby ending the handoff process (S40).

In the above-described conventional handoff scheme, the terminal may try to handoff to a hot spot without considering the load when performing the handoff. However, since it is in a state where no more traffic of the base station can be accepted, the terminal to handoff cannot be accepted. That is, from the terminal's point of view, not only the traffic amount of the current cell but also the traffic amount of the neighboring cell are not known, so the terminal moves to the hot spot only by looking at the signal strength received from the base station. As a result, packet loss and delay are increased, resulting in poor service quality.

In addition, if traffic is concentrated in only one cell despite the margin of neighboring cells, the traffic that is acceptable in terms of system-wide capacity is not accepted in the cell, and thus does not fully utilize system resources. . In addition, from the user's point of view, packet loss and delay are more likely to be birthdays, and thus the overall quality of service is not guaranteed.

As described above, the existing handoff technology includes problems such as packet loss and delay in handoff due to passive response to traffic, reduction of overall system efficiency, and reduction of quality of service for the user.

Accordingly, an object of the present invention is to provide an adaptive handoff processing method capable of actively coping with uneven traffic to maximize system efficiency and minimize degradation of service quality due to packet loss and delay.

The present invention relates to a method for processing a handoff that occurs when a mobile station moves from a first base station, which is a base station receiving a service, to a second base station, which is an adjacent base station, in which the terminal is configured to perform a handoff of the first base station. Receiving traffic load information; When the terminal sends a host tunnel initialization (H-TIN) message to the first base station, establishing a tunnel by sending a tunnel initialization (TIN) message to the second base station; And transmitting, by the second base station, the traffic load information of the second base station to the terminal together with the handoff hint message. And determining, by the terminal, the handoff time using the traffic load information of the first base station and the traffic load information of the second base station.

Further, when the second base station transmits the traffic load information of the second base station together with the handoff hint message to the terminal, the second base station through the formed tunnel if the transmission of the handoff hint message is impossible. Only traffic load information of may be transmitted to the terminal.

DETAILED DESCRIPTION A detailed description of preferred embodiments of the present invention will now be described with reference to the accompanying drawings. In the following description of the present invention, if 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.

The handoff processing method proposed in the present invention can be applied to a packet-based mobile communication network or a fourth generation mobile communication network based on FH-OFDM technology.

The present invention provides a mobile communication network including a mobile station (MS) 100 which is a device carried by subscribers using mobile communication, and a base station (BS) that performs direct communication with the terminal in the mobile communication network. For convenience, the base station is divided into a current base station (OBS) 200 that is a base station that the terminal 100 receives a service and a new base station (NBS) 300 that is an adjacent base station.

Adaptive Handoff Algorithm

The present invention provides two adaptive handoff algorithms in consideration of traffic volume, a simple adaptive handoff algorithm (hereinafter referred to as a simple AHL) algorithm and a dynamic adaptive handoff algorithm: Hereinafter referred to as dynamic AHL) algorithm.

The adaptive handoff algorithm determines a handoff time point by adaptively placing a handoff threshold when attempting to handoff to a hotspot or a coolspot in consideration of the load of the current cell and the cell to be handoffed.

Adaptive Handoff Procedure

3 shows a handoff procedure based on the algorithm proposed by the present invention. Here, the basic handoff procedure is shown in FIG. 1 and only changed until the process of determining the handoff before sending the H-HR message.

Information on the traffic load of the current base station 200 required in the present invention is periodically broadcasted through a downlink broadcast channel (hereinafter referred to as DLBCH) (S100).

After discovering a new base station with pilot signal strength (S102), the terminal 100 sends an H-TIN message to the current base station 200 to request a tunnel to the new base station 300 (S104). When receiving the H-TIN message, the current base station 200 forms a tunnel by sending a TIN message to the new base station 300 (S106 and S108).

The new base station 300 is to send a message to the HH, at this time to load the traffic load information on the HH message to send to the terminal 100 (S110). If the transmission of the handoff hint (HH) message is impossible, only the traffic load information of the new base station 300 can be transmitted to the terminal through the formed tunnel.

Through this process, the terminal 100 knows all of the load information of the current base station 200 and the load information of the new base station 300 to be handed off, thus adjusting the threshold value through this (S112) and determining the result of the handoff. In step S114, if the condition is met, an H-HR message is sent to start the handoff (S116).

How traffic is determined

This method is a method of determining the amount of traffic in a system using a shared traffic channel.

4 is a MAC state diagram used as a reference for determining the traffic amount in the present invention. Here, on is a state having both a downlink and an uplink traffic channel, and a hold is a state having a forward channel and a thin uplink channel, and the other Terminals in a state (Null, Sleep, Access) do not have a traffic channel. Therefore, when determining the traffic load in the present invention, the traffic load is measured by the number of terminals in the on and hold to divide the corresponding cell into a hot spot or a cool spot. That is, when the terminal corresponding to the on and hold is close to the number of on and hold that each base station can accept, it is considered as a hot spot, and when the corresponding terminal is small, it is considered as a cool spot.

Looking at the algorithm proposed in the present invention in more detail as follows.

Simple AHL algorithm

2 is a schematic diagram of a simple AHL algorithm proposed in the present invention, and FIG. 5 is a flowchart of a simple AHL algorithm.

Referring to FIG. 2, the simple AHL algorithm proposed by the present invention, when handing off from a hot spot to a cool spot, starts a handoff by only looking at hysteresis (HYS). Faster and faster handoff from cool spot to hot spot when the minimum threshold (Tmin) as well as hysteresis (HYS) is met. If both the cell connected and the cell to be handed off are not hot or cool spots, the handoff starts when the hysteresis (HYS) and the normal threshold (Tnorm) are satisfied.

Next, referring to FIG. 5, first, the strength of pilot signals received from the current base station 200 and the new base station 300 is measured (S200), and the signal strength (RSScur) received from the current base station 200 and the new base station 200 are measured. In operation S202, it is checked whether the difference in the signal strength RSSS received from the base station 300 is greater than the hysteresis value HYS.

If the above conditions are met, the load information of both base stations is measured (S204), and it is checked whether the traffic load (LOADcur) of the current base station 200 is greater than the traffic load (LOADnew) of the new base station 300 (206).

If the traffic load LOADcur of the current base station 200 is greater than the traffic load LOADnew of the new base station 300, a handoff is requested (S208). Otherwise, the pilot received from the current base station 200 is requested. In step 210, the signal strength RSScur is smaller than the threshold value Tmin.

In step 210, if the strength RSScur of the pilot signal received from the current base station 200 is less than the threshold value Tmin, a handoff is requested (S208), otherwise, the flow returns to step 200.

As described above, the simple AHL algorithm uses the amount of traffic of the currently connected cell and the amount of traffic of the cell to be handed off and the amount of traffic to be handed off. The terminal distributes the traffic amount of the hot spot to the surrounding cells by making it as fast as possible.

In the case of the simple AHL algorithm, there is an advantage in that it is possible to distribute traffic in a transparent and congested area since it is not necessary to change the simple and existing handoff technique.

Dynamic AHL Algorithm

The dynamic AHL algorithm is a more aggressive algorithm for distributing traffic than the simple AHL algorithm. The dynamic AHL algorithm dynamically adjusts the threshold according to the traffic volume between two base stations. By applying this dynamic AHL algorithm, the traffic volume is balanced with the surrounding cells so that the hot spots can be adjusted as much as possible.

6 is a flowchart of the dynamic AHL algorithm.

First, the strength of the pilot signal received from the current base station 200 and the new base station 300 (S300), the signal strength (RSScur) received at the current base station 200 and the signal received at the new base station 300 It is checked whether the difference between the intensities RSS is greater than the hysteresis value HYS (S302).

If the conditions are met, the load of both stations is measured (S304), and the adaptive threshold Tadj is calculated based on the measured load (S304).

Next, it is checked whether the calculated adaptive threshold Tadj is greater than the signal strength RSScur measured at the new base station 300 (S308).

If the adaptive threshold Tadj is greater than the strength RScur of the signal measured at the new base station 300, a handoff is requested (S208), and if not, the flow returns to step 300.

7 is a diagram illustrating an adaptive algorithm proposed by the present invention, and FIG. 8 is a state transition diagram when applying the dynamic AHL algorithm.

7 and 8, when the hysteresis is satisfied, the dynamic AHL algorithm transitions from the SERVE_CURRENT state to the HANDOFF_READY state. At this time, the pilot signal strength of the BS currently being serviced is determined as the maximum threshold value (Tmax). In the HANDOFF_READY state, the adaptive threshold Tadj is calculated linearly or exponentially depending on the load of the current base station and the new base station to be handed off between Tmax and Tmin. Decide

If the signal strength difference does not satisfy the hysteresis in the HANDOFF_READY state, the state transitions to the SERVE_CURRENT state again. This algorithm can more clearly distribute the load of traffic to the surrounding cells, and can reduce the likelihood of hot spots by more actively preventing traffic from converging.

The method of calculating the threshold in the range between Tmax and Tmin is as follows.

When the load of the current cell is L _s and the load of the cell to be handed off is L _t , and the load is a value between 0 and 1, L _s -L _t is a value between -1 and 1. Will have In this case, the adaptive threshold Tadj may be obtained by the following equations.

In the case of linear determination, the following equation is used.

(Equation 1)

If it is determined exponentially, it is obtained by any one of the following Equations (2) to (5).

(Equation 2)

or

(Equation 3)

or

(Equation 4)

or

(Equation 5)

In consideration of the situation, by applying one of the above equations, an appropriate adaptive threshold Taj may be determined according to the load difference between the current cell and the cell to be handed off. Here, FIG. 9 is a diagram illustrating a relation for determining an adaptive threshold Tadj.

Example

10 shows the experimental results for a simple algorithm during adaptive handoff.

This experiment compares hysteresis only and compares hysteresis and minimum threshold together, measures how fast the handoff is compared to handoff, and indirectly distributes the load. This was done to see if it was. The parameters used in the experiment are as follows.

Table 1

As described above, by using the adaptive handoff processing method according to the present invention, by appropriately distributing the load to each cell, it is possible to improve the overall system performance than in one cell, and improve the quality of service that the user feels.

1 is a flow chart illustrating a conventional handoff processing procedure.

2 is a diagram illustrating a simple AHL algorithm proposed in the present invention.

3 is a flowchart showing a handoff procedure based on the algorithm proposed by the present invention.

4 is a MAC state diagram used as a reference for determining the amount of traffic in the present invention.

5 is a flow chart of a simple AHL algorithm in accordance with the present invention.

6 is a flowchart of a dynamic AHL algorithm in accordance with the present invention.

7 is a diagram illustrating an adaptive algorithm proposed in the present invention.

8 is a state transition diagram when applying the dynamic AHL algorithm.

9 is a diagram illustrating a relationship for determining an adaptive threshold Taj.

10 is a graph showing experimental results for a simple algorithm during adaptive handoff in accordance with the present invention.

※ Explanation of code about main part of drawing ※

MS: terminal

OBS: Current Base Station

NBS: New Base Station

Claims (9)

A method of processing handoff that occurs when a mobile station moves from a first base station, which is a base station receiving a service, to a second base station, which is an adjacent base station, in a mobile communication network, Receiving, by the terminal, traffic load information of the first base station from the first base station; When the terminal sends a host tunnel initialization (H-TIN) message to the first base station, establishing a tunnel by sending a tunnel initialization (TIN) message to the second base station; And Transmitting, by the second base station, the traffic load information of the second base station to the terminal with a handoff hint message; And And determining, by the terminal, the handoff time using the traffic load information of the first base station and the traffic load information of the second base station. The method of claim 1, wherein the traffic load information of the first base station is periodically broadcasted through a downlink broadcast channel (DLBCH). The method according to claim 1, Measuring, by the terminal, the strength (RSScur) of the pilot signal received from the first base station and the strength (RSSnew) of the pilot signal received from the second base station; Check whether the difference between the strength of the pilot signal received from the second base station (RSSnew) and the strength of the pilot signal received from the first base station (RSScur) is greater than the hysteresis value (HYS), and the strength of the pilot signal received from the second base station Measuring a traffic load (LOADcur, LOADnew) of the first and second base stations if the difference between the RSSnew and the strength RSScur of the pilot signal received from the first base station is greater than the hysteresis value HYS; Checking whether the traffic load LOADcur of the first base station is greater than the traffic load LOADnew of the second base station; And And requesting a handoff if the traffic load (LOADcur) of the first base station is greater than the traffic load (LOADnew) of the second base station. The method according to claim 3, wherein if the traffic load (LOADcur) of the first base station is not greater than the traffic load (LOADnew) of the second base station, whether the strength (RSScur) of the pilot signal received from the first base station is less than the minimum threshold value (Tmin) The method may further include the step of checking, and requesting handoff when the strength of the pilot signal received from the first base station (RSScur) is less than the minimum threshold value (Tmin). . The method according to claim 1, Measuring, by the terminal, the strength (RSScur) of the pilot signal received from the first base station and the strength (RSSnew) of the pilot signal received from the second base station; Checking whether a difference between the strength (RSSnew) of the pilot signal received from the second base station and the strength (RSScur) of the pilot signal received from the first base station is greater than the hysteresis value (HYS); If the difference between the strength of the pilot signal received from the second base station (RSSnew) and the strength of the pilot signal received from the first base station (RSScur) is greater than the hysteresis value (HYS), the traffic load of the first and second base station is measured step; Calculating an adaptive threshold Taj based on the traffic load of the first base station and the traffic load of the second base station; Checking whether the strength (RSScur) of the pilot signal received from the first base station is less than the adaptive threshold Tadj; And And requesting handoff if the strength (RSScur) of the pilot signal received from the first base station is less than the adaptive threshold Tadj. The method according to claim 5, The calculating of the adaptive threshold Tadj based on the traffic load of the first base station and the traffic load of the second base station may be performed when the load of the first base station is L _s and the load of the second base station is L _t . An adaptive handoff processing method in a mobile communication network, characterized in that it is performed linearly in the range between the threshold value Tmax and the minimum threshold value Tmin as follows. The method according to claim 5, The calculating of the adaptive threshold Taj based on the traffic load of the first base station and the traffic load of the second base station is performed when the load of the first base station is L _s and the load of the second base station is L _t . An adaptive handoff processing method in a mobile communication network, characterized in that it is performed exponentially in a range between a threshold value Tmax and a minimum threshold value Tmin as follows. or or or The method of claim 1, wherein the second base station transmits the traffic load information of the second base station to the terminal with a handoff hint message, If it is impossible to transmit a handoff hint (HH) message, only the traffic load information of the new base station (300) through the formed tunnel, the adaptive handoff processing method in a mobile communication network, characterized in that. The method according to claim 3 or 5, The traffic load is adaptive handoff processing method in a mobile communication network, characterized in that measured by the number of terminals on and hold (hold).