KR20020034529A - Method for allocating resource atm multirate asymmetric type in mobile communication system - Google Patents

Abstract

PURPOSE: A method for assigning an ATM(Asynchronous Transfer Mode) resource multi-speed asymmetric type in a mobile communication system is provided to prevent the waste of an ATM bandwidth by assigning an asymmetric ATM bandwidth with reference to forward/reverse bandwidths. CONSTITUTION: If origination/termination call control messages are received from a terminal or a CN(Core Network), a BTS(Base Transceiver Station) transmits a band setting request signal including inter-different forward/reverse bandwidth request values to a BSC(Base Station Controller)(S10). The BSC receives the band setting request signal from the BTS, determines whether band assignment to the inter-different forward/reverse bandwidth request values is admitted, and transmits a band setting acknowledge signal corresponding to the result to the BTS(S20).

Description

METHODO FOR ALLOCATING RESOURCE ATM MULTIRATE ASYMMETRIC TYPE IN MOBILE COMMUNICATION SYSTEM}

The present invention relates to a multi-rate asymmetric Asynchronous Transfer Mode (ATM) resource allocation method in a mobile communication system. More particularly, the present invention relates to different forward / reverse directions in a resource allocation step in call setup. The present invention relates to a multi-rate asymmetric ATM resource allocation method in a mobile communication system that allocates bandwidth in consideration of all bandwidths.

As is well known, mobile communication systems are currently developing into asynchronous multimedia systems such as the International Mobile Telecommunication (IMT) -2000 system. In this case, the next generation IMT-2000 system is based on ATM having asymmetric characteristics, and provides not only voice service but also multi-rate services such as text and video. Therefore, when allocating resources (bandwidth) at the time of initial call setup, different bandwidth allocations for the forward / reverse direction should be made.

In the conventional mobile communication system, since the multi-rate asymmetric ATM signaling method does not asymmetrically request the bandwidth required for resource allocation at the time of call setup, both forward and reverse resources (bandwidth) are secured in the same amount. Therefore, in case of focusing on the image downloading service, although the forward traffic requires several times the bandwidth of the reverse or backward traffic, the reserved bandwidth is forward and Since all resources are allocated in the reverse direction, resources of the reverse link are wasted.

As another example, the problem of the multi-rate asymmetric ATM signaling method in the conventional mobile communication system is described. In the case where there is a service for transmitting a remote sensed video image on the reverse link, the reverse direction is lower than the forward direction. Although a significant proportion of the bandwidth is required, the reserved bandwidth is allocated the same resource in both the forward and reverse directions, which also causes a problem of wasting ATM resources.

Therefore, in the past, due to the waste of the forward / reverse bandwidth as described above, despite the fact that additional bandwidth can be allocated, rejection of bandwidth requests frequently occurs, which causes a significant decrease in the quality of mobile communication services. There was a problem.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to prevent waste of ATM bandwidth by allocating in consideration of different forward / reverse bandwidths when allocating an asymmetric ATM bandwidth. To provide a multi-rate asymmetric ATM resource allocation method in a mobile communication system.

In order to achieve the above object, the multi-rate asymmetric ATM resource allocation method in the mobile communication system according to the present invention includes a mobile communication having a first network element and a second network element each performing its own call processing operation. In the multi-rate asymmetric ATM resource allocation method in a system,

A tenth step of transmitting a bandwidth setting request signal including different forward / reverse bandwidth request values to the second network element when the first network element receives a call control message; And

When the second network element receives the band setting request signal from the first network element and determines whether to accept the band allocation for the different forward / reverse bandwidth request values in the request signal, the band setting is confirmed according to the result. And a 20th step of transmitting a signal to the first network element.

1 is a functional block diagram showing the configuration of a multi-rate asymmetric ATM resource allocation apparatus in a mobile communication system according to an embodiment of the present invention;

2 is an operation flowchart showing a multi-rate asymmetric ATM resource allocation method in a mobile communication system according to an embodiment of the present invention;

FIG. 3 is an operation flowchart illustrating a detailed operation of the twentieth step S20 in the multi-rate asymmetric ATM resource allocation method in the mobile communication system according to FIG. 2;

4 is a diagram illustrating a configuration of a band setting request signal in the multi-rate asymmetric ATM resource allocation method in the mobile communication system according to FIG. 2.

<Explanation of symbols for the main parts of the drawings>

100: base station 200: control station

Hereinafter, a multi-speed asymmetric ATM resource allocation method in a mobile communication system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings, and the first and second network elements to be described below. Is defined as one element of a base station, a control station, or an exchange station, which is mounted in a mobile communication system and performs its own call processing operation.

1 is a functional block diagram of an apparatus for allocating a multi-rate asymmetric ATM resource in a mobile communication system according to an embodiment of the present invention, which is a multi-rate asymmetric ATM resource allocation in a mobile communication system according to an embodiment of the present invention. The apparatus is composed of a base station 100 as a first network element and a control station 200 as a second network element.

In this case, when the base station 100, which is the first network element, receives an outgoing / incoming call control message from a terminal or a core network (CN), the base station 100 transmits a bandwidth setting request signal including different forward / reverse bandwidth request values to the second network. It transmits to the control station 200 which is an element to perform an asymmetric ATM resource allocation operation.

In addition, when the control station 200, the second network element, receives the band setting request signal from the base station 100, the first network element, accepts bandwidth allocation for different forward / reverse bandwidth request values in the request signal. After determining whether or not to transmit a band setting confirmation signal to the base station 100, the first network element corresponding to the result.

Then, a multi-rate asymmetric ATM resource allocation method in a mobile communication system according to an embodiment of the present invention using a multi-rate asymmetric ATM resource allocation apparatus in a mobile communication system having the above configuration is illustrated in FIG. 2 and FIG. 3, it will be described with reference to FIG.

First, when the base station 100, which is the first network element, receives an outgoing / incoming call control message from a terminal or a core network (CN), the base station 100 receives a band setting request signal including different forward / reverse bandwidth request values. It transmits to the control station 200 which is a network element (S10). Here, as shown in FIG. 4, the band setting request signal 10 may have different forward bandwidths along with an audio service field 10a in which audio service information is stored and multi-rate service information. Multirate service field (10b) storing the request value (b _f ) and the reverse bandwidth request value (b _b ), the SAR stored the maximum packet size information processed at a time for the forward (Segmentation and Reassembly; hereinafter referred to as "SAR".) The confirmation service field (10c), and the SAR unconfirmed service field (10d) that stores the maximum packet size information processed at one time for the reverse direction, the multi-rate The different forward bandwidth request values b _f and reverse bandwidth request values b _b stored in the service field 10b each have a size of 3 bytes.

Then, the control station 200 receives the band setting request signal from the base station 100, which is the first network element, and determines whether to accept the band allocation for different forward / reverse bandwidth request values in the request signal. The band setting confirmation signal is transmitted to the base station 100 in accordance with the result (S20).

Hereinafter, a detailed operation process of the above-described twentieth step S20 will be described with reference to FIG. 3.

First, the control station 200 receives a band setting request signal including different forward / reverse bandwidth request values b _f and b _b from the base station 100 (S21).

Thereafter, the control station 200 determines whether its current state is assignable to the forward bandwidth request value b _f requested by the base station 100 using Equation 1 below. (S22).

b _f + B _f <B _f ^T

Here, b _f represents a forward bandwidth request value requested by the first network element, B _f represents a forward bandwidth currently being used by the second network element, and B _f ^T represents the second network element. Represents the maximum forward bandwidth that can be used.

At this time, if the current state of the user in the twenty-second step (S22) is assignable to the forward bandwidth request value (b _f ) requested by the base station 100 (YES), the control station 200 is present It is determined using Equation 2 below whether or not the state of the mobile station can be allocated to the reverse bandwidth request value b _b requested by the base station 100 (S23).

b _b + B _b <B _b ^T

Here, b _b represents a reverse bandwidth request value requested by the first network element, B _b represents a reverse bandwidth currently in use in the second network element, and B _b ^T in the second network element Represents the maximum backward bandwidth that can be used.

In the twenty-third step (S23), if its current state is assignable to the reverse bandwidth request value (b _b ) requested by the base station 100 (YES), the control station 200 is in the forward direction currently in use. thereby updating / uplink bandwidth (b _f, b _b) in the forward / reverse bandwidth request value _{(b f,} b b) each summing to forward / reverse bandwidth (b _f, b _b) are currently used as the zoom (S24) .

Then, the control station 200 notifies the base station 100 that the allocation of the forward / reverse bandwidth request values b _f and b _b is possible through the band setting confirmation signal (S25).

On the other hand, in the twenty-second step (S22) the current own state is not assignable to the forward bandwidth request value (b _f ) requested by the base station 100 (NO), or in the twenty-third step (S23) If its current state is not assignable to the reverse bandwidth request value b _b requested by the base station 100 (NO), the control station 200 transmits the forward / reverse bandwidth request value through a band setting confirmation signal. The base station 100 notifies that the allocation of (b _f , b _b ) is impossible (S26).

In addition, the above description is just one embodiment of the present invention, where the first network element is the base station 100 and the second network element is the control station 200. In some cases, the first network element is the control station and the second network element. The network element may be a base station, or the first network element may be a control station and the second network element may be an exchange, or the first network element may be an exchange, and the second network element may be a control station.

On the other hand, in the handoff process, in the present invention, the first network element may be a serving base station and the second network element may be a target base station, or the first network element may be a serving control station and the second network element may be a target control station.

As described above, according to the multi-rate asymmetric ATM resource allocation method in the mobile communication system according to the present invention, when allocating the asymmetric ATM bandwidth in consideration of different forward / reverse bandwidths, the waste of the ATM bandwidth is prevented. In addition to this, it has a remarkable effect of significantly improving the quality of mobile communication services.

Claims (12)

In the multi-rate asymmetric ATM resource allocation method in a mobile communication system having a first network element and a second network element each of which performs its own call processing operation, A tenth step of transmitting a bandwidth setting request signal including different forward / reverse bandwidth request values to the second network element when the first network element receives a call control message; And When the second network element receives the band setting request signal from the first network element and determines whether to accept the band allocation for the different forward / reverse bandwidth request values in the request signal, the band setting is confirmed according to the result. And a 20th step of transmitting a signal to the first network element. The method of claim 1, The band setting request signal may include an audio service field in which audio service information is stored; A multi-rate service field storing different forward bandwidth request values (b _f ) and reverse bandwidth request values (b _b ) together with the multi-rate service information; A SAR acknowledgment service field that stores maximum packet size information processed at a time for the forward direction; And A method for allocating a multi-rate asymmetric ATM resource in a mobile communication system, comprising a SAR unacknowledged service field in which maximum packet size information processed at a time for reverse direction is stored. The method of claim 1, The twenty-first step may include: a twenty-first step of receiving, by the second network element, a band setting request signal including different forward / reverse bandwidth request values (b _f , b _b ) from the first network element; A twenty-second step of determining, by the second network element, whether its current state is assignable to a forward bandwidth request value (b _f ) requested by the first network element; In step 22, if the current own state is assignable to the forward bandwidth request value b _f requested by the first network element, the second network element is currently in its first network element. A twenty-third step of determining whether or not an allocated state is available for the requested reverse bandwidth request value (b _b ); In the twenty-third step, if its current state is assignable to the reverse bandwidth request value b _b required by the first network element, the forward / reverse bandwidth B _f , which is currently in use by the second network element, may be used. b _b) in the forward / reverse bandwidth request value _(f b, b _b) of claim 24, the step of updating the forward / reverse bandwidth (b _f, b _b) are currently used in each of the summation to zoom; And And a twenty-fifth step of notifying the first network element that the second network element can allocate a forward / reverse bandwidth request value (b _f , b _b ) through a band setting confirmation signal. Multi-rate asymmetric ATM resource allocation method in system. The method of claim 3, wherein In the twenty-second step, the method for determining whether the second network element is currently in an assignable state with respect to the forward bandwidth request value b _f requested by the first network element is represented by Equation 1 below. A multi-speed asymmetric ATM resource allocation method in a mobile communication system, characterized in that is determined using [Equation 1] b _f + B _f <B _f ^T Here, b _f represents a forward bandwidth request value requested by the first network element, B _f represents a forward bandwidth currently being used by the second network element, and B _f ^T represents the second network element. Represents the maximum forward bandwidth that can be used. The method of claim 3, wherein In the twenty-third step, a method of determining whether the current state of the second network element is assignable to the reverse bandwidth request value (b _b ) requested by the first network element is as follows. A multi-speed asymmetric ATM resource allocation method in a mobile communication system, characterized in that the determination is performed using [Equation 2] b _b + B _b <B _b ^T Here, b _b represents a reverse bandwidth request value requested by the first network element, B _b represents a reverse bandwidth currently in use in the second network element, and B _b ^T in the second network element Represents the maximum backward bandwidth that can be used. The method of claim 3, wherein In step 22, the current own state is not assignable to the forward bandwidth request value b _f requested by the first network element, or in step 23, the current own state is determined by the first network element. If it is not possible to allocate the requested reverse bandwidth request value (b _b ), the second network element is unable to allocate the forward / reverse bandwidth request value (b _f , b _b ) through a band setting confirmation signal. And a twenty sixth step of notifying the first network element. The method of claim 1, And wherein the first network element is a base station, and the second network element is a control station. The method of claim 1, And wherein the first network element is a control station and the second network element is a base station. The method of claim 1, And wherein the first network element is a control station and the second network element is a switching station. The method of claim 1, And wherein the first network element is a switching center and the second network element is a control station. The method of claim 1, In the handoff process, the first network element is a serving base station, and the second network element is a target base station. The method of claim 1, And wherein said first network element is a serving control station and said second network element is a target control station during handoff processing.