KR100352893B1 - A method of adjusting traffic of an user equipment in an asynchronous IMT-2000 system - Google Patents

Abstract

The present invention provides a priority for a plurality of logical channels existing in a single mobile terminal in an asynchronous next generation mobile communication system so as to differentially set the traffic amount according to the priority. A method for controlling traffic of a network, the method comprising: providing a medium access control layer with priority information for each logical channel of a radio link control layer; A second step of designating and requesting the size and number of transport blocks for each logical channel from the medium access control layer to the radio link control layer based on the priority of each logical channel; Transmitting, by the radio link control layer, a required number of transport blocks for each logical channel to the medium access control layer; And a fourth process of, at the medium access control layer, mapping the received transport blocks of each logical channel to one transport channel and transmitting the same to a base station. Adjust the amount.

Description

A method of adjusting traffic of an user equipment in an asynchronous IMT-2000 system}

The present invention relates to a traffic control method of a single mobile terminal in an asynchronous next generation mobile communication system, and more particularly, to control the priority of a plurality of logical channels existing in a single mobile terminal in an asynchronous IMT-2000 system. It relates to a method to adjust the amount of traffic to send.

The standardization of next-generation mobile communication called IMT-2000 is being promoted by ITU-T and ITU-R, and IMT-2000, which is in charge of ITU-R TG8 / 1, covers a range of 20m ~ 300m radius with one base station radio wave. It is a mobile communication system that improves the frequency utilization efficiency and enables uninterrupted voice and data communication anytime, anywhere, including the ground and satellites.

As the standardization of IMT-2000 is compressed into two global standards, Europe and Japan vs. USA, the 3rd Generation Partnership Project (3GPP), led by Europe and Japan, is the third generation GSM network and its asynchronous W-CDMA access. Technology and terminal technology. The US-led 3GPP-2 is studying synchronous CDMA 2000 access technology and terminal technology based on the ANSI-41 network.

The IMT-2000 standard defined by 3GPP includes various protocols such as Radio Resource Control (RRC), Radio Link Control (RLC), and Medium Access Control (MAC).

In addition, 3GPP defines a logical channel and a transport channel for transmitting data (including user data and signaling messages).

However, the current 3GPP only defines the priority for the logical channel, the medium access control protocol does not provide a way to control the priority.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described conventional situation, and provides priority to a plurality of logical channels existing in a single mobile terminal in an asynchronous next-generation mobile communication system to differentially set the traffic amount according to the priority. An object of the present invention is to provide a traffic control method of a single mobile terminal in an asynchronous next generation mobile communication system.

1 is a diagram illustrating signaling between a protocol and transport block transmission for each logical channel for explaining a traffic control method of a single mobile terminal according to an embodiment of the present invention;

2 is a flowchart illustrating a traffic regulation method of a single mobile terminal according to an embodiment of the present invention.

※ Explanation of code for main part of drawing

10: radio link control layer 12: medium access control layer

14: radio resource control layer

In order to achieve the above object, the traffic regulation method of a single mobile terminal in an asynchronous next generation mobile communication system according to a preferred embodiment of the present invention, the priority information for each logical channel of the radio link control layer medium access control layer The first process to provide; A second step of designating and requesting the size and number of transport blocks for each logical channel from the medium access control layer to the radio link control layer based on the priority of each logical channel; Transmitting, by the radio link control layer, a required number of transport blocks for each logical channel to the medium access control layer; And a fourth process in the medium access control layer, mapping the received transport blocks of each logical channel to one transport channel and transmitting the same to a base station.

Hereinafter, a traffic control method of a single mobile terminal in an asynchronous next generation mobile communication system according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a diagram illustrating signaling between protocols and transport block transmission for each logical channel for explaining a traffic control method of a single mobile terminal according to an embodiment of the present invention.

The radio link control layer 10 transmits data through each logical channel, and the medium access control layer 12 transmits data received from the radio link control layer 10 to a corresponding transport channel or vice versa from the transport channel. The received data is transmitted to each logical channel of the radio link control layer 10. That is, the medium access control layer 12 maps and transmits a transport channel and a logical channel.

The radio resource control layer 14 assigns a logical channel to the radio link control layer 10 and a transport channel to the medium access control layer 12.

The radio resource control layer 14 assigns a logical channel and a transport channel to the radio link control layer 10 and the medium access control layer 12 for one mobile terminal. Allocate That is, one mobile terminal is assigned several logical channels with different service characteristics (three in the embodiment of the present invention), which are mapped to one transport channel. At this time, the radio resource control layer 14 gives priority to each logical channel, and sends the value of the priority for each logical channel to the medium access control layer 12.

In addition, a basic unit that the radio link control layer 10 processes a logical channel and delivers it to the medium access control layer 12 is called a transport block (TB), and a bundle of these transport blocks is transmitted. The medium access control layer 12 receives the transport block from each logical channel (logical channels 1, 2, and 3) and transmits it to the corresponding transport channel (ie, transport channel 1). Map and transmit to the base station (not shown).

The radio resource control layer 14 assigns the medium access control layer 12 to the medium access control layer 12 a transport block set size, which is a total size to be transmitted through a transport channel, and a number of TBs. In addition, the radio resource control layer 14 may map and assign a plurality of logical channels to one transport channel. Each logical channel is given a relative priority, and the priority value is in the range of 1 to 8. Specifies a value with

And, if a plurality of logical channels are mapped to one transport channel, the transport block size of each logical channel is constant, for example, 10 bits.

In the embodiment of the present invention, the transport block size of each logical channel is set to 10 bits, but may be set as 20 bits, 25 bits, 30 bits, etc. as necessary.

The medium access control layer 12 requests the radio link control layer 10 the size of the transport block and the number of transport blocks to be transmitted to the medium access control layer 12 every transmission time interval. The radio link control layer 10 transmits data to the medium access control layer 12 as many times as the number of transport blocks of the size of the transport block requested by the medium access control layer 12.

2 is a flowchart illustrating a traffic control method of a single mobile terminal in an asynchronous next generation mobile communication system according to an embodiment of the present invention.

First, FIG. 2 illustrates a case where three logical channels are mapped to one transport channel, and the priority of each logical channel is assigned to "1", "2", and "4". Here, it is assumed that the priority "1" is the highest priority and the priority "4" is the lowest.

First, the radio resource control layer 14 specifies the size of the transport block set to 70 bits and the number of transport blocks having a length of 10 bits to 7 to the medium access control layer 12, and then the radio link control layer 10 A signal is transmitted to the medium access control layer 12 indicating that the priority Pi of each of the logical channels of " 1 " is assigned to " 1 "

The medium access control layer 12 arranges a number from the priority Pi of the smallest value to the priority Pi of the largest value (step S12). That is, the value of priority P1 of logical channel 1 is "1", the value of priority P2 of logical channel 2 is "2", and the value of priority P4 of logical channel 3 is "4". ", The array of numbers is [1, 2, 4].

Then, the medium access control layer 12 inverts the numerical sequence and arranges it backwards (step S14). This is to allocate a large number of transport blocks to a high-priority logical channel.

The medium access control layer 12 maps the numerical array (i.e., [4, 2, 1]) that is the result of the reversal to the priority Pi of each logical channel, and maps the value to the number of transport blocks NumofTBi. ) "(Step S16). As a result of the mapping, the number of transport blocks corresponding to priority 1 is "4", the number of transport blocks corresponding to priority 2 is "2", and the number of transport blocks corresponding to priority 4 is "1".

The medium access control layer 12 requests the radio link control layer 10 the number of transport blocks for each logical channel determined as described above (step S18).

Accordingly, the radio link control layer 10 transmits the required number of transport blocks for each logical channel to the medium access control layer 12 (step S20).

The medium access control layer 12 maps the transport blocks of each received logical channel to one transport channel and transmits the same to a base station (not shown) (step S22). In this case, a separate header is added to the signal format transmitted from the medium access control layer 12 to the base station through the transport channel 1 to determine the number of logical channels, the number of transport blocks in each logical channel, and the like.

As described in detail above, according to the present invention, the radio resource control layer assigns the transport block size and the number of transport blocks for each logical channel to the medium access control layer at the time of channel allocation, and the medium access control layer is configured for each transmission period. The number of transport blocks determined for the logical channel of the radio link control layer is requested, and the radio link control layer transmits the transport blocks required by the medium access control layer for each logical channel. You can control the amount of traffic you send.

In addition, the priority control of each logical channel can be performed in this manner, thereby providing a user with a service closer to the actual situation.

On the other hand, the present invention is not limited only to the above-described embodiment, but can be modified and modified within the scope not departing from the gist of the present invention, the technical idea to which such modifications and variations are also applied to the claims Must see

Claims (5)

A first step of providing priority information for each logical channel of the radio link control layer to the medium access control layer; A second step of designating and requesting the size and number of transport blocks for each logical channel from the medium access control layer to the radio link control layer based on the priority of each logical channel; Transmitting, by the radio link control layer, a required number of transport blocks for each logical channel to the medium access control layer; And In the medium access control layer of the single mobile terminal in the asynchronous next-generation mobile communication system, characterized in that it comprises a fourth step of mapping the received transport block of each logical channel to one transport channel to transmit to the base station side How to regulate traffic. The method of claim 1, Priority information for each logical channel is provided by a radio resource control layer, traffic control method for a single mobile terminal in an asynchronous next generation mobile communication system. The method of claim 1, The second process is A first step of arranging the priority values for each logical channel in a predetermined order; And And a second step of mapping the inverted value to the priority of each logical channel and setting the mapping result as the number of transport blocks for each logical channel. Traffic control method of a single mobile terminal. The method of claim 3, wherein The predetermined order is a traffic control method for a single mobile terminal in an asynchronous next generation mobile communication system, characterized in that the priority value of each logical channel is arranged in order from the smallest value to the largest value. The method of claim 1, Traffic of a single mobile terminal in an asynchronous next generation mobile communication system, characterized in that the sum of all priority values assigned to each logical channel and the sum of the number of transport blocks determined for each logical channel are the same. How to adjust.