KR100606662B1 - Method of resource assignment using packet service in mobile commuincation system - Google Patents

Abstract

In the present invention, when there is no traffic in the additional channel activation step, the dedicated channel is temporarily released so that the channel can be allocated to another user, and when the dedicated channel is released, all the codes used to set the dedicated channel are stored again. The present invention relates to a radio resource allocation method using packet services in a mobile communication system that can be quickly implemented. The radio resource allocation method according to the present invention is a radio resource allocation method through state management of a dedicated channel in a mobile communication system, wherein the mobile station is in an active state with respect to the dedicated channel for a predetermined time. Checking whether traffic occurs; And releasing the dedicated channel to transition from the active state to the virtual active state when no traffic occurs during the predetermined time.

Description

Radio resource allocation method using packet service in mobile communication system {Method of Resource Assignment Using Packet Service in mobile commuincation system}

The present invention relates to a radio resource assignment method in IMT-2000, a next-generation mobile communication system. In particular, a forward / reverse dedicated control channel using symmetric and asymmetric packet service ( Effectively manage dedicated channels such as Forward / Reverse-Dedicated Control Channel (F / R-DCCH) and Forward / Reverse-Supplemental Channel (F / R-SCH) to increase the utilization of radio resources. The present invention relates to a radio resource allocation method using packet services in a mobile communication system.

1 is a block diagram illustrating a protocol stack applied to a next generation mobile communication system.

Referring to FIG. 1, a protocol stack of a mobile communication system according to the present invention includes a physical layer (PHY), an upper layer (UL) for performing radio bearer control, radio resource control, and mobility management, and the upper layer (UL). Medium Access Control Sub-layer (MAC) that controls the intermediate connection between the physical layer (PHY) and the data between the Medium Access Control Sublayer (MAC) and the upper layer (UL). Interface Control Part (IFC) to interface.

The control plane 100 may include a call control entity (CC), a mobility management entity, a radio resource management entity, a packet management entity, and a packet management entity. ) And Link Access Control Sub-Layer (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. On the other hand, the user plane 200 is a voice control entity 201, a data control entity 202, an image control entity 203, and a link access control sub-layer LAC2. It consists of several alternative services, each optimized for the specific needs of each type of service.

In general, in the prior art of the code division multiple access (CDMA), GSM (Global System for Mobile Communication) wireless communication system, dedicated control channels (Dedicated Control CHannel), dedicated channels (Supplementary CHannel) Dedicated channels can be classified into idle and active states. Dedicated channels are always in an active state until they transition to an idle state. Thereby continuously occupying radio resources.

However, in the conventional method, since the allocated channel is maintained even without the traffic transmitted / received through the dedicated channel, the following problem occurs.

First, the utilization of radio resources is low because other users want to use the channel in the state allocated to the dedicated channel and cannot use the channel.

Second, in the state allocated to the dedicated channel, power consumption is not efficient because power is consumed even when the channel is not used.

Third, all the codes used to set the dedicated channel are released when the dedicated channel is released. Therefore, when the same dedicated channel is newly set up, it takes the same time as the initial setting.

The present invention is to solve the problems of the prior art described above, an object of the present invention is to temporarily release the dedicated channel when there is no traffic transmitted / received through the dedicated channel to increase the efficiency of the use of radio resources and power The present invention provides a radio resource allocation method using a packet service in a mobile communication system.

Another object of the present invention is to provide a method for allocating a radio resource using packet services in a mobile communication system to quickly reset a dedicated channel by storing resources used when setting up a dedicated channel when the dedicated channel is released.

Another object of the present invention is to provide a radio resource allocation method using packet services in a mobile communication system to provide symmetric and asymmetric packet services in a MAC layer of a user plane.

In one aspect of the present invention, a radio resource allocation method in a mobile communication system according to the present invention includes a radio resource allocation method through state management of a dedicated control channel (DCCH) in a mobile communication system. Establishing a dedicated control channel between the base station and transitioning to the first state; And changing the set state of the dedicated control channel according to the forward and reverse traffic conditions to transition from the first state to the second state.

In another aspect of the present invention, a method for allocating a radio resource in a mobile communication system according to the present invention is directed to a method for allocating a radio resource through state management of a dedicated channel in a mobile communication system, wherein the mobile station in a specific state is forwarded. Checking a reverse traffic condition; And changing the set state of the forward and reverse dedicated channels according to the forward and reverse traffic conditions to transition the state of the mobile station to another state.

Hereinafter, with reference to the accompanying drawings will be described the configuration, operation and effects of the present invention.

2 is a state diagram illustrating states of a dedicated control channel and a supplementary channel in a mobile station mode according to the present invention.

Referring to FIG. 2, the mobile station is continuously or periodically supported with synchronization information and system information from the base station in the initialization state S1.

Accordingly, the mobile station synchronizes with the base station and enters an idle state (S2) for establishing a bidirectional dedicated channel such as DCCH and SCH for incoming and outgoing calls after receiving system information.

The mobile station receives the bidirectional DCCH from the base station in the idle state (S2) and enters the DCCH activation state (S3). At this time, the base station checks whether a traffic occurs from the mobile station, and allocates a SCH to the mobile station.

When the mobile station does not generate a traffic in the DCCH activation state S3, the DCCH second timer T _{DCCH_S} is operated, and the mobile station communicates until the DCCH second timer expires. ) Is transitioned to the DCCH virtual activation state (S4) to temporarily release the DCCH of the mobile station.

The mobile station in the DCCH virtual activation state (S4) in which the DCCH is temporarily released, keeps a record of the allocation of the user long code for the released DCCH channel, and the mobile station generates a traffic again. As the DCCH is required, the bidirectional DCCH is reset with the allocation history stored in the DCCH virtual activation state S4.

In the DCCH virtual activation state (S4), if the mobile station does not continue to generate traffic until the operation time of the DCCH first timer T _{DCCH_L} expires, the bidirectional DCCH is not reset, and the DCCH channel is completely Will be released. This causes the mobile station to transition to the idle state S2.

If the mobile station does not generate a traffic in the state in which the SCH is activated between the mobile station and the base station (S5), the SCH second timer T _{SCH_S} operates and the operation time of the SCH second timer expires. As the mobile station does not continuously generate traffic until the mobile station transitions to the SCH virtual activation state S6, the SCH is temporarily released.

The mobile station in the SCH virtual activation state (S6) where the SCH is temporarily released keeps a record of the allocation of the user long code for the released SCH channel, and the mobile station generates a traffic again. As the SCH is required, the bidirectional SCH is reconfigured with the allocation history stored in the SCH virtual activation state S6.

In the SCH virtual activation state S6, the mobile station does not continue to generate a traffic until the operation time of the SCH first timer T _{SCH_L} expires, so that the bidirectional SCH is not reset, and the SCH channel is completely Is released. As a result, the mobile station transitions back to the DCCH activation state S3.

A dedicated channel such as DCCH and SCH in the mobile station mode described above is assigned a Walsh code for the forward link and a user long code for the reverse link.

In addition, in the state diagram showing the states of the DCCH and SCH in the mobile station mode described above, the mobile station and the Walsh Code for the channel are temporarily released while the mobile station temporarily releases dedicated channels such as the DCCH and the SCH. The long history code (User Long Code) of the allocation history (History) is kept in memory, and when a traffic occurs to reoccupy the dedicated channel, the recently allocated resource based on this allocation history (History) Use again to set and reset the dedicated channel.

However, when the DCCH first timer T _{DCCH_L} and the SCH first timer T _{SCH_L} expire, the dedicated channel is completely released, and the history of the Walsh code and the user long period code for the dedicated channel is also deleted. do.

3 is a channel transition state diagram for describing a channel state according to an embodiment of the present invention. The following description, citing FIG. 3, applies to both mobile stations and base stations.

Referring to FIG. 3, first, the additional channel activation state (SCH Active) is transferred from the dedicated control channel activation state (DCCH Active), and then transitions to the additional channel virtual activation state (SCH Virtual Active), or the additional channel virtual activation state (SCH). Virtual Active) may be transitioned back to the additional channel activation state (SCH Active).

In addition, the additional state of the additional channel activation state (SCH Active) is the forward / reverse additional channel activation state (F / R SCH Active) , the forward additional channel activation state (F-SCH Active), and the reverse additional channel activation state (R- SCH Active).

The F / R SCH Active enters the F / R SCH Active when there is traffic on both the forward and reverse links, and when there is traffic only on the forward link, enters the F-SCH Active. When there is traffic only on the reverse link, the UE enters a reverse side channel activation state (R-SCH Active).

In the forward / reverse additional channel activation state (F / R SCH Active), both the forward link channel and the reverse link channel are configured. Only the forward channel is set in the forward side additional channel activation state (F-SCH Active), and only the reverse channel is set in the reverse side additional channel activation state (R-SCH Active). In the forward secondary channel activation state, the reverse link channel is temporarily released. Likewise, in the reverse side additional channel activation state, the forward link channel is temporarily released. Thus, if a user wants to use this temporarily released dedicated channel at the time of temporary release, it allocates.

If there is no traffic on both the forward link and the reverse link, it enters the SCH Virtual Active state, releases both the forward link channel and the reverse link channel, and when there is traffic, activates the additional channel activation state (SCH). Active).

At this time, a Walsh code is assigned to the forward channel and a user long period code is assigned to the reverse channel.

While all channels are temporarily released, allocating records such as Walsh codes and user long-period codes for that channel continue to be remembered. This saves time by setting and resetting (establish / re-establish).

In all the above, the physical channel is a dedicated control channel and an additional channel, and the logical channel is a dedicated MAC channel (dmch), a dedicated signaling channel (dsch), and a dedicated traffic channel (dtch). to be.

That is, the MAC layer manages the state of the dedicated channel and in the additional channel activation additional state, the radio resource setup / reset / release management is performed by the control field of the dmch of the MAC, and is always the upper layer RBC (radio bearer) through dsch. report to control).

According to the present invention described above, the channel is temporarily released while there is no traffic, so three effects can be obtained.

First, since a dedicated channel temporarily released by another user can be used, the utilization of radio resources can be improved.

Second, when the dedicated channel is not used, power consumption can be reduced, thus enabling efficient power consumption management.

Third, when releasing a dedicated channel, when the channel needs to be reset by preserving activity records such as wash codes and user long-period codes, this information can be used to immediately connect without additional signal, thereby reducing the reset time. .

1 is a block diagram illustrating a protocol stack applied to a next generation mobile communication system.

2 is a state diagram showing states of a dedicated control channel and an additional channel in a mobile station mode according to the present invention;

3 is a channel transition state diagram for explaining a channel state according to an embodiment of 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

PHY: Physical Layer MAC: Medium Access Control Sublayer

IFC: Interface control unit UL: Upper layer

LAC1,2: Link Access Control Sublayer

Claims (11)

In a radio resource allocation method through state management of a dedicated control channel (DCCH) in a mobile communication system, The mobile station establishing a dedicated control channel with the base station and transitioning to the first state; And And changing a configuration state of the dedicated control channel according to forward and reverse traffic conditions to transition from the first state to the second state. The method of claim 1, And releasing the dedicated control channel to transition to the second state when the forward and reverse traffic do not occur for a predetermined time. The method of claim 2, wherein the transition from the first state to the second state comprises: Driving a timer for counting the predetermined time if the forward and reverse traffic does not occur; And transitioning from the first state to the second state if forward and reverse traffic do not occur until the operation time of the timer expires. The method of claim 2, And when the dedicated control channel is released, the mobile station further stores information for setting the dedicated control channel. The method of claim 4, wherein And retransforming the dedicated control channel to the first state by using the stored dedicated control channel configuration information when traffic occurs. The method of claim 1, And the mobile station is in an idle state and sets the dedicated control channel to transition to the first state. The method of claim 6, And retransitioning to an idle state when no traffic occurs for a specific time after the mobile station transitions to the second state. The method of claim 4, wherein The dedicated channel configuration information includes a information on a Walsh code (walsh code) and a user long code (user long code). The method of claim 8, And the Walsh code is used for the forward direction, and the long period code is used for the reverse direction.  The method of claim 1, And wherein the first state is a DCCH activated state and the second state is a DCCH virtual activated state. The method of claim 1, State management of the dedicated control channel is performed at a medium access control (MAC) layer of the mobile station.