KR19990084804A - Rapid Reallocation of Radio Resources for Packet Data Services in Mobile Communication Systems - Google Patents

Abstract

In the mobile communication system, a fast reallocation method of radio resources for packet data services is provided to efficiently and rapidly reassign radio resources to support high speed packet data services so that mobile stations can use them immediately when desired. In the high speed reallocation method of radio resources for packet data services in a mobile communication system that transmits a channel allocation request signal to provide a packet data service and receives a channel, the packet data service is transmitted from a new mobile station. A first search step for searching for the presence of a spare channel according to the assigned channel allocation request signal (Channel Req), and if there is no spare channel as a result of the search in the first search step, whether there is a virtual activation channel among currently allocated channels; A second search step of searching; This is because the virtual activation channel reassignment step is performed when the virtual activation channel exists as a result of the search in the second search step.

Description

Rapid Reallocation of Radio Resources for Packet Data Services in Mobile Communication Systems

The present invention relates to a mobile communication system, and more particularly, to a fast reallocation method of radio resources for a packet data service in a mobile communication system.

Hereinafter, a method of allocating and releasing radio resources for a packet data service in a mobile communication system according to the related art will be described with reference to the accompanying drawings.

The process of requesting allocation of radio resources from the mobile station MS to the base station BS is as follows.

First, the mobile station (MS) transmits a channel allocation request signal (Channel request) for requesting the allocation of radio resources for the packet data service.

Then, the base station (BS) searches for radio resources according to the channel request signal (Channel request) transmitted from the mobile station and transmits a channel assignment signal (Acknowledgement) if there is an available channel.

The base station transmits a channel assignment reject signal if no channel is available as a result of the search.

Accordingly, the mobile station provides a packet data service through a traffic channel with another base station according to a channel assignment signal transmitted from the base station.

In addition, the mobile station may hold a channel even if there is no traffic with another base station according to a channel assignment signal transmitted from the base station.

On the other hand, the process of requesting the release of the radio resources allocated to the base station (BS) from the mobile station (MS) is as follows.

First, the mobile station (MS) transmits a channel release request (Channel release request) for requesting the release of radio resources for the allocated packet data service and also starts the timer.

The base station BS then transmits a channel assignment request signal for releasing the allocated radio resource according to the channel release request signal transmitted from the mobile station.

Accordingly, the mobile station releases the allocated radio resource according to the channel allocation request signal transmitted from the base station.

The mobile station also releases the allocated radio resource if the started timer has expired.

However, in the conventional mobile communication system, in the method of allocating and releasing radio resources for a packet data service, when the radio resources are not sufficient, the mobile station that has acquired the radio resources is not currently used but can use the radio resources. Therefore, there is a problem in that the efficiency of the radio resource is inferior.

In addition, the related art has a problem that radio resources cannot be allocated and reallocated at high speed.

In the prior art, there is a problem in that signaling overhead is large by releasing and re-allocating when allocating radio resources.

Accordingly, the present invention has been made to solve the above problems, and the mobile communication system to reallocate radio resources efficiently and at high speed in order to support high-speed packet data service so that the mobile station can use the radio resources immediately when desired. An object of the present invention is to provide a fast reallocation method of radio resources for a packet data service.

1 is a block diagram showing a protocol stack applied to a general mobile communication system

2 is a conceptual diagram illustrating a state transition of a state transition command according to a fast reallocation method of radio resources for a packet data service in a mobile communication system according to the present invention.

3 is a flowchart for a fast reallocation of radio resources between a base station and a mobile station according to a fast reallocation method of radio resources by a packet data service in a mobile communication system according to the present invention.

4 is a diagram illustrating a state transition of a state transition command of a base station according to a fast reallocation method of radio resources by a packet data service in a mobile communication system according to the present invention.

5 is a flowchart of a base station for fast reallocation of radio resources by a packet data service in a mobile communication system according to the present invention.

Explanation of symbols for main parts of the drawings

100: control plane 200: user plane

201: voice control entity 202: data control entity

203: Image control entity PHL: physical layer

MAC: Medium Access Control Sublayer IFC: Interface Control

UL: upper layer LAC 1,2: link access control sublayer

In the mobile communication system according to the present invention for achieving the above object, a feature of a fast reallocation method of radio resources for a packet data service is to allocate a channel by transmitting a channel assignment request signal to provide a packet data service. In a mobile communication system for receiving a packet data service, a fast reallocation method of radio resources for a packet data service, the method comprising: retrieving the presence of a spare channel according to a channel allocation request signal (Channel Req) transmitted from a new mobile station. A first search step, a second search step of searching for a virtual activation channel among currently allocated channels if there is no free channel as a result of the search in the first search step, and a virtual search result activation in the second search step Virtual activity to reassign channel to the new mobile station if channel exists There through interaction screen channel reassignment step.

Hereinafter, a preferred embodiment of a fast reallocation method of radio resources for a packet data service in a mobile communication system according to the present invention will be described with reference to the accompanying drawings.

1 is a block diagram illustrating a protocol stack applied to a next generation mobile communication system, and FIG. 2 is a diagram illustrating a state transition command according to a fast reallocation method of radio resources for a packet data service in a mobile communication system according to the present invention. 3 is a conceptual diagram illustrating a state transition, and FIG. 3 is a flowchart for fast reallocation of radio resources between a base station and a mobile station according to a fast reallocation method of radio resources by a packet data service in a mobile communication system according to the present invention. 4 is a diagram illustrating a state transition of a state transition command of a base station according to a fast reallocation method of radio resources by a packet data service in a mobile communication system according to the present invention, and FIG. Flow of Base Station for High Speed Reallocation of Radio Resources by Packet Data Service A bit.

As shown in FIG. 1, a medium access control sub-layer for controlling an intermediate connection between a physical layer (PHL) and an upper layer (UL) and a physical layer (PHL). MAC, an Interface Control Part (IFC) for interfacing data between the Medium Access Control Sublayer (MAC) and the Upper Layer (UL), and Radio Barrier Control, Radio Resource Control and Mobility Management. It consists of a higher layer (UL) that performs

Herein, the control plane 100 may include a CC entity (Call Control (CC)), an MM entity (Mobility Management (MM)), an RM entity (Radio Management (RM)), a PM entity (Packet Management (PM)), and link access. It consists of a Link Access Control Sub-Layer1 (LAC1), which is common to all applications and provides a very reliable transport link of internal control signals and a limited amount of user information traffic.

In contrast, the user plane 200 includes a voice control entity 201, a data control entity 202, an image control entity 203, and a link access control sub-layer 2. In turn, it provides several alternative services, each of which is optimized for the specific needs of each type of service.

As described above, a method for re-assigning a radio resource for a packet data service in a mobile communication system according to the present invention will be described in detail with reference to the accompanying drawings.

First, when a plurality of mobile stations is turned on, the base station sets the bidirectional DCCH and SCH for transmitting the synchronization information and the system information continuously or periodically to the idle state for the plurality of mobile stations.

Thereafter, when a channel allocation request signal (Channel Req) for providing a packet data service is transmitted from a plurality of mobile stations, the base station allocates the set bidirectional DCCH to the mobile station and transitions to the DCCH activation state.

At this time, the plurality of mobile stations are driven by the first and second timers of the base station and the mobile station according to the allocation of the bidirectional DCCH, and the base station is assigned to the mobile station of the channel where traffic is generated before the first timer expires due to channel assignment. The UE transitions to the DCCH activation state and then allocates the bidirectional SCH to transition to the SCH activation state to provide packet data service.

The base station searches for the first timer while providing the packet data service in the SCH activated state and transitions to the SCH virtual activation state when the second timer expires, and transitions to the DCCH activated state when the second timer expires.

In addition, the base station searches for the first timer for the mobile station in which the traffic does not occur, and when it expires, the base station transitions from the DCCH activation state according to the bidirectional DCCH allocation to the DCCH virtual activation state to hold the channel.

The first timer is a short-term timer and the second timer is a long-term timer.

In this state, when a channel allocation request signal (Channel Req) for providing a packet data service is transmitted from the new first mobile station, the base station searches for the presence of a spare channel (S1, S2).

If there is a free channel as a result of the search, the base station allocates a channel to the mobile station, and if there is no free channel, the base station searches for a currently allocated channel to search for the existence of a virtual activation channel (S3 and S4).

In this case, the presence of the virtual activation channel is in the virtual activation state until the second timer expires by transitioning from the activation state to the virtual activation state when the first timer expires, so the existence of the channel where the first timer expires. Decide whether or not.

If the virtual activation channel does not exist as a result of the search, the base station rejects the channel allocation according to the channel allocation request signal Channel Req (S5).

In addition, if the virtual activation channel exists as a result of the search, the base station determines the priority of the virtual activation channel and transmits a channel transition command signal (STC) to the mobile station (here, the second mobile station) that has obtained the lowest priority channel ( S6, S7).

That is, the base station transmits a channel transition command signal (STC command) after resetting the bidirectional DCCH to the mobile station that has obtained the virtual priority channel of the lowest priority of the DCCH virtual activation state.

Then, when the base station receives a channel transition command acknowledgment signal (STC Command ACK) according to the channel transition command signal (STC Command) from the second mobile station, the base station reassigns the channel obtained from the first mobile station to the first mobile station to perform packet data service. It provides (S8, S9).

Meanwhile, the base station searches for a second timer in the DCCH virtual activation state, transitions to an idle state when it expires, and then repeats the above process when a signal for requesting channel allocation is transmitted from another mobile station.

As described above, in the fast reallocation method of radio resources for packet data services in the mobile communication system according to the present invention, in order to support high speed packet data services, the radio resources can be efficiently and fast in the virtual activation state after channel allocation. Reassignment to reduce signaling overhead and have the advantage that the mobile station can use the radio resources immediately when desired.

Claims (3)

In a mobile communication system for transmitting a channel assignment request signal to provide a packet data service and receiving a channel to provide a packet data service, A first retrieval step of retrieving the presence or absence of a spare channel according to a channel allocation request signal (Channel Req) transmitted from a new mobile station; A second search step of searching for a virtual activation channel among currently allocated channels if there is no free channel as a result of the search in the first search step; In the second search step, if a virtual activation channel exists, a virtual activation channel reallocation step of reallocating a channel to the new mobile station is performed. Reassignment Method. The method of claim 1, The virtual activation channel reassignment step may further include a prioritization step of determining the priority of the virtual activation channel if the search result virtual activation channel exists in the second search step. Fast reallocation of radio resources for packet data services. The method of claim 2, The priority determining step may include: a channel transition command signal transmitting step of transmitting a channel transition command signal (STC command) to a mobile station that acquires a virtual activation channel having the lowest priority among the virtual activation channels whose priority is determined; When a channel transition command acknowledgment signal (STC Command ACK) is received according to a channel transition command signal (STC command) transmitted in the channel transition command signal transmission step, the virtual activation channel is reassigned to the new base station. A method for reallocating radio resources to a packet data service in a mobile communication system, characterized by further comprising a channel reallocation step.