KR101580332B1 - Method and apparatus for transmitting and receiving data in a mobile communication system - Google Patents

Abstract

The present invention minimizes an RLC (Radio Link Control) layer malfunction due to a delay transmission of a PDU (Protocol Data Unit) before a RLC reset time. In the RLC transmission side, a transmission prohibition time is considered in consideration of a TTA And stops transmission of the RLC PDU from the time point at which the transmission prohibition time is subtracted at the RLC reset time until the RLC reset time, and thereafter transmits the RLC PDU. In addition, the RLC receiving side of the present invention determines the reception prohibition time in consideration of the TTA and stops receiving the RLC PDU from the RLC reset time point to the time point when the RLC reset time is added to the reception prohibition time, and thereafter.

RLC re-establishment, RLC layer, Time To Arrival (TTA), Protocol Data Unit (PDU)

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method and apparatus for transmitting / receiving data in a mobile communication system,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile communication system, and more particularly, to an apparatus and method for transmitting and receiving data when an RLC re-establishment occurs.

BACKGROUND ART Generally, a Universal Mobile Telecommunication Service (UMTS) system is based on a Global System for Mobile Communications (GSM) and a General Packet Radio Services (GPRS), which are European mobile communication systems, and a wideband code division multiple access : W-CDMA) is used as a third generation asynchronous mobile communication system.

The 3rd Generation Partnership Project (3GPP), which is in charge of UMTS standardization, is discussing LTE (Long Term Evolution) as a next generation mobile communication system of UMTS system. LTE is a technology to realize high-speed packet-based communication of about 100 Mbps with the target of commercialization in 2010 or so. Various schemes are being discussed for this purpose. For example, there are discussions to reduce the number of nodes located on the communication path by simplifying the structure of the network, and to approach the wireless protocols as much as possible to the wireless channel.

1 is a block diagram illustrating an example of a structure of an LTE mobile communication system.

1, an Evolved Radio Access Network (E-RAN) 110 includes an Evolved Node B (hereinafter referred to as 'ENB' or 'Node B') 120, 122, 124, 126 and 128, hereinafter, referred to as '120 to 128') and anchor nodes 130 and 132, respectively.

A user equipment (UE) 101 is connected to an Internet Protocol (IP) network by an E-UTRAN 110.

The ENBs 120 to 128 correspond to an existing Node B of the UMTS system and are connected to the UE 101 through a wireless channel. Unlike the existing node B, the ENBs 120 to 128 perform a more complex role. In LTE, all user traffic including real-time services such as Voice over Internet Protocol (VoIP) over the Internet protocol is serviced through a shared channel. Therefore, a device for collecting and scheduling the situation information of UEs is needed. ENBs 120 to 128 are responsible.

HARQ (Hybrid ARQ) is performed between the ENBs 120 to 128 and the UE 101 in LTE as in HSDPA or Enhanced-Dedicated Channel (E-DCH) An outer ARQ can be performed in the upper layer and the separate ARQ can also be performed between the UE 101 and the ENBs 120 to 128 Lt; / RTI >

In order to achieve transmission rates of up to 100 Mbps, LTE systems are expected to use Orthogonal Frequency Division Multiplexing (OFDM) as a radio access technology in a 20 MHz bandwidth. The LTE system uses an Adaptive Modulation and Coding (AMC) scheme that determines a modulation scheme and a channel coding rate according to a channel state of a UE.

Meanwhile, the W-CDMA standard is approved by the 3GPP (3rd Generation Partnership Project), and the Release phase is set according to the adopted technology. In principle, the upper release guarantees backward compatibility with the lower standard.

In a wireless mobile communication technology such as W-CDMA, data loss may occur due to signal deterioration in a wireless section, and therefore, a reliable data transmission / reception method between a receiving end and a transmitting end is required.

Power control is required to compensate for signal deterioration on the physical radio channel between the transmitter and the receiver and a protocol for reliable transmission and reception in the transport layer is required.

Therefore, in W-CDMA, a protocol called RLC (Radio Link Control) is provided to secure a reliable data transmission method between a transmitting end and a receiving end. Acknowledge Mode (AM) In the case of RLC, various procedures and control PDUs (Protocol Data Units) are used to perform in-sequence delivery in the order of a sequence number (SN).

One) RLC PDU  Size and Length Indicator ( LI ) size

The PDU used by the AM RLC layer is divided into an Acknowledged Mode Data (PDU) and a Control PDU.

In the case of the AMD PDU, a header including information such as an SN and a data indicator, which is a portion containing actual upper layer data, is composed of a Length Indicator (LI) And one LI field has a size of 7 bits or 15 bits. The Control PDU does not include the LI, and the remaining part of the PDU is considered to be padding, except for the part that has been effectively parsed according to predefined rules.

In the specification up to Release 6, the size of the RLC PDU is fixed, and its value is set in the upper layer. The size of the LI depends on the size of the determined PDU. For AMD PDUs, the 7-bit LI should be used when the PDU size is 126 bytes or less, and the 15-bit LI should be used when the PDU size is larger than 126 bytes. However, the upper layer specification implicitly assumes that only 7-bit LI is used when using the fixed RLC PDU size, and the terminal common environmental test standard does not describe the use of 15-bit LI when using fixed RLC PDU size.

In the Release 7 specification, the RLC PDU size can be fixed or flexible for the downlink. When a fixed size is used, the setting of the RLC PDU size and the method of determining the LI size are the same as in the previous specification. If the variable size is used, the upper layer sets the length indicator size to 7-bit or 15-bit instead of the PDU size. The RLC layer sets the LI size and the SDU (service data unit) The size of the PDU is considered. In this case, the size of the PDU can be changed every time the PDU is generated.

2) RLC  Condition to perform reset function

The RLC layer can perform the RLC reset function under the control of the upper layer, and the upper layer determines the point of time of execution through the mutual signal procedure. When the RLC resetting function is performed, the RLC layer initializes prescribed state variables, applies the parameters set in the upper layer, and can additionally perform a specific operation according to a predetermined condition.

The conditions for performing the RLC reset function in the upper layer and the problem in the case of not performing the RLC reset function are as follows.

(1) If the downlink RLC PDU size is fixed and the PDU size is changed to a PDU size different from the current PDU size, since the PDU size is changed in the RLC layer using the fixed RLC PDU size, There is a problem that reception is difficult.

(2) If the size of the downlink RLC PDU is variable and the LI size is changed to a size different from the current LI size, there is a problem that incorrect PDU analysis and RLC layer malfunction occur because the LI analysis rule is changed.

(3) When the downlink RLC PDU size is to be changed from the current variable to the fixed value, the RLC layer using the fixed RLC PDU size can not accommodate the variable size PDU.

(4) When the downlink RLC PDU size is changed from the current fixed value to the variable having the LI size of 15-bit, the LI analysis rule is changed, which causes a problem of incorrect PDU analysis and RLC layer malfunction.

On the other hand, in the following conditions, the RLC layer parameter is changed only without performing the RLC reset function. In this case, the PDU generated and transmitted through the pre-change parameter is changed in the peer entity, It is possible to ensure reception and interpretation correctly, so there is no need to perform the RLC reset function.

(5) If the downlink RLC PDU size is changed from the current fixed to the variable with the LI size of 7-bit, the RLC layer using the variable size can accommodate the fixed size PDU. Since the LI size is not changed, There is no problem in interpreting even the old PDU. When using fixed RLC PDU size, it is implicitly assumed that the LI size uses only 7-bit, so this condition can be established.

In other words, as can be seen from the above-mentioned conditions, when the RLC layer parameter is changed, if the PDU generated by applying the previous parameter is not sure that the packet can be correctly received and analyzed after the parameter change, After initializing the layer, it has the purpose of changing parameters and creating a new PDU and resuming transmission.

When the RLC reset function is performed, the RLC layer state variable is initialized and a new parameter is set. Therefore, if the PDU generated before the RLC reset function is processed after the function is performed, the RLC layer may malfunction. Conventionally, considering this, it is defined that the AMD PDU and the STATUS PDU (a kind of control PDU) that are waiting for processing in the RLC layer at the time of performing the RLC reset function are discarded. However, in the past, PDUs that have not arrived at the RLC layer at the time of performing the RLC reset function and stayed in the transmission period are not considered.

The present invention provides a method and apparatus for minimizing an RLC malfunction that may originate before a RLC re-establishment time but may be received by a remote RLC layer after an RLC re-establishment due to a transmission delay.

A method on a transmitting side according to an embodiment of the present invention is a method for processing data on a transmitting side in a mobile communication system, the method comprising: (a) transmitting a first PDU (packet data unit) to a receiving side; (B) determining a transmission prohibition time in consideration of a time taken for the first PDU to be transmitted from the transmitting side to the receiving side; (C) stopping the transmission of the second PDU from the time point at which the transmission prohibition time is subtracted at the RLC reset time to the RLC reset time, and transmitting the third PDU to the receiver after the transmission prohibition time, The transmitting side does not need to receive the PDU from the receiving side in order to perform the steps (a), (b), and (c).

A method on a receiving side according to an embodiment of the present invention is a method of processing data on a receiving side in a mobile communication system, the method comprising: receiving a first PDU (Packet Data Unit) from a transmitting side; (A) determining a reception prohibition time in consideration of a time taken for the first PDU to be received, and stopping the reception of the second PDU from the RLC reset time to the addition of the reception prohibition time from the RLC reset time, (C) receiving a third PDU from the transmitting side after the prohibition time, and the receiving side needs to transmit the PDU to the transmitting side in order to perform the steps (a), (b) .
The apparatus on the transmitting side according to the embodiment of the present invention is characterized in that in the data processing apparatus on the transmitting side in the mobile communication system, a transmission prohibition time is set in consideration of the time taken for transmitting the first PDU (Packet Data Unit) Wherein the first PDU is transmitted to the receiver and the second PDU is suspended from the RLC reset time until the RLC reset time is subtracted from the RLC reset time, And the transmitting side does not need to receive the PDU from the receiving side for the operation of the transmission prohibition time determining unit and the operation of the transmitting unit .
The apparatus on the receiving side according to the embodiment of the present invention is characterized in that in the data processing apparatus on the receiving side in the mobile communication system, considering the time taken for the first PDU (Packet Data Unit) to be received from the transmitting side to the receiving side, And a second PDU receiving unit that receives the first PDU from the transmitting side and stops receiving the second PDU from the RLC reset time point to the time point when the RLC reset time point is added to the reception prohibition time, And the receiving side does not need to transmit the PDU to the transmitting side for the operation of the reception prohibition time determiner and the operation of the receiver. do.

The present invention minimizes an RLC layer malfunction due to delayed transmission of a PDU before a RLC reset time, thereby preventing deterioration in network quality immediately after performing an RLC reset function.

Also, even if the present invention is applied to only one of the RLC layer, it is possible to minimize the RLC layer malfunction due to the delayed transmission of the PDU before the RLC reset time.

Also, the present invention can prevent loss of transmission data and improve transmission efficiency when a radio link control (RLC) re-establishment occurs in a mobile communication system.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The main point of the present invention is to minimize the RLC layer malfunction due to the delayed transmission of the PDU before the RLC reset time. In the first embodiment of the present invention, the transmission side transmits a first PDU, determines a transmission prohibition time of a packet to be transmitted thereafter, and transmits a second PDU in consideration of the determined transmission prohibition time. In the second embodiment of the present invention, the receiving side receives the first PDU, determines the reception prohibition time of the received packet, and receives the second PDU in consideration of the determined reception prohibition time. Therefore, even if the present invention is applied to only one of the RLC layer, it is possible to minimize the RLC layer malfunction due to the delayed transmission of the PDU before the RLC reset time.

Although the present invention is designed based on the 3GPP Release 7 standard, it should be noted that the present invention is not limited to the Release 7 standard and can be applied to both the upper and lower standards.

2 is a flowchart illustrating a PDU transmission method before a general RLC reset. That is, FIG. 2 shows a PDU transmission method between RLC carriers.

An RLC layer for transmitting a PDU at a specific point in time will be referred to as an RLC transmitter 210 and an RLC layer for receiving a PDU will be referred to as an RLC receiver 200. [

The RLC transmitting side 210 transmits the RLC PDU (1) to the RLC receiving side 200 in step 201. The time required until the RLC PDU (1) is received from the RLC receiving side 200 is referred to as a TTA (Time To Arrival). After the RLC transmitting side 210 transmits the RLC PDU 2 to the RLC receiving side 200 in step 203 and before the RLC receiving side 200 receives the RLC PDU 2, At this time, there is a problem that a malfunction may occur in the RLC receiving side 200 receiving the RLC PDU (2).

The present invention proposes a scheme for each of the RLC layers of the transmitting / receiving side in consideration of the above points.

One) RLC PDU Transmitting side  action

3 is a flowchart illustrating a PDU transmission method before RLC reset according to the first embodiment of the present invention. That is, FIG. 3 shows a PDU transmission method between RLC carriers.

As in FIG. 2, an RLC layer for transmitting a PDU at a specific time is referred to as an RLC transmitter 210, and an RLC layer for receiving a PDU is referred to as an RLC receiver 200.

For example, the STATUS PDU including the MRW_ACK SUFI (Moving Receiving Window ACK Super-Field) is transmitted from the receiver in the standard and received by the sender. In the present invention, in this case, the RLC layer that transmits the PDU, i.e., the layer named as the receiver in the specification, is referred to as the RLC transmitting side.

The RLC transmitting side 210 transmits the RLC PDU (1) to the RLC receiving side 200 in step 301. Then, the RLC transmitting side 210 determines the time required until the RLC receiving side 200 receives the RLC PDU (1) from the RLC receiving side 200 in order to block the possibility that the RLC receiving side 200 malfunctions due to the delayed PDU (T_PRX_TX_PDU) is determined in consideration of a time to arrival (TTA) which is a transmission time limit (TTA). The transmission prohibition time T_PRX_TX_PDU includes a constant considering the TTA or a function value derived from the TTA.

Also, the RLC transmission side 210 stops transmission of the RLC PDU (2) during the transmission prohibition time. That is, the RLC transmitter 210 notifies the RLC transmitter 210 that the RLC reset time has been determined to be T1 in the upper layer. Then, the transmitting RLC layer 210 stops the PDU transmission (2) from the T1 - transmission prohibited time (T_PRX_TX_PDU) to the T1 time.

If the RLC resetting is performed at time T1, the RLC transmitting side 210 changes the RLC PDU (2) from this point in time (here, from the point in time at which the transmission prohibition time is subtracted from the RLC reset point to the RLC reset operation point Which means that it is discarded. The RLC receiving side 200 may transmit the RLC PDU 2 'generated by applying the new parameter after the RLC resetting to the RLC receiving side 200 in step 305 from the RLC transmitting side 210, (2 ') can normally be received.

2) RLC PDU Receiving side  action

4 is a flowchart illustrating a PDU receiving method before RLC reset according to a second embodiment of the present invention. That is, FIG. 4 shows a PDU receiving method between RLC carriers.

2 and 3, an RLC layer for transmitting a PDU at a specific time is referred to as an RLC transmitter 210, and an RLC layer for receiving a PDU is referred to as an RLC receiver 200. FIG.

When the RLC transmitting side 210 does not operate according to the first embodiment of the present invention, if the RLC transmitting side 210 transmits the RLC PDU (2) without considering the RLC reset performing time, The RLC receiving side 200 can receive the RLC PDU (2). If the RLC receiving side 200 regards the RLC PDU as a normal PDU, it may cause malfunction of the receiving side.

Therefore, in the second embodiment of the present invention, a method of minimizing the possibility of a malfunction by discarding PDUs received during the reception prohibition time (T_PRX_RX_PDU) immediately after the RLC reset is performed in the RLC receiving side is proposed.

First, the RLC receiving side 200 receives the RLC PDU (1) from the RLC transmitting side 210 in step 401. Then, the RLC receiving side 200 determines a reception prohibition time (T_PRX_RX_PDU) 407 in consideration of a time to arrival (TTA) time required for receiving the RLC PDU (1) from the RLC transmitting side 210 . The TTA includes a constant considering the TTA or a function derived from the TTA.

Even if the RLC receiving entity 200 receives the RLC PDU 2 from the RLC transmitting entity 210 in step 403, the RLC receiving entity 200 discards the RLC PDU 2 because the RLC PDU 2 is received within the reception prohibition period after the RLC re-establishment time. RLC resetting is performed at time T2 according to control of the upper layer of the RLC receiving side 200 and the RLC receiving side 200 ignores PDUs received from the T2 time point to the (T2 + reception prohibited time (T_PRX_RX_PDU)) time point . Then, the operation of ignoring the received PDU is stopped after (T2 + reception prohibited time (T_PRX_RX_PDU)).

After the reception prohibition time, the RLC receiving side 200 can normally receive the RLC PDU (3) from the RLC transmitting side 210 in step 405.

5 is a diagram illustrating a PDU transmission method in an RLC transmission side according to the first embodiment of the present invention.

In step 501, the RLC transmitting side 210 transmits the first RLC PDU to the RLC receiving side 200. The RLC transmitting side 210 transmits the first RLC PDU to the RLC receiving side 200 from the RLC transmitting side 210 to prevent the RLC receiving side 200 from malfunctioning due to the delayed PDU in step 503, (T_PRX_TX_PDU) is determined in consideration of a time to arrival (TTA), which is the time required to transmit the RLC PDU. The transmission prohibition time T_PRX_TX_PDU includes a constant considering the TTA or a function value derived from the TTA. The PDU transmission is suspended until the RLC reset time from the time when the transmission prohibition time is subtracted from the RLC reset time.

In step 505, the RLC transmitter 210 transmits the second RLC PDU to the RLC receiver 200 after the RLC reset time, after subtracting the transmission prohibition time from the RLC reset time.

6 is a diagram illustrating a PDU receiving method in an RLC receiving side according to a second embodiment of the present invention.

As in FIG. 5, an RLC layer for transmitting a PDU at a specific time is referred to as an RLC transmitter 210, and an RLC layer for receiving a PDU is referred to as an RLC receiver 200. FIG.

First, the RLC receiving side 200 receives the first RLC PDU from the RLC transmitting side 210 in step 601. [ In step 603, the RLC receiving side 200 determines a reception prohibition time (T_PRX_RX_PDU) 407 in consideration of a time to arrival (TTA) time required for receiving the RLC PDU (1). The TTA includes a constant considering the TTA or a function derived from the TTA.

From the RLC re-establishment time T2 to the time point T2 plus the reception prohibition time, and after the RLC re-establishment time T2 from the T2 to the reception prohibition time, 200 normally receives the second RLC PDU from the RLC transmitter 210 in step 605. [

7 is a block diagram of a PDU transmitting / receiving apparatus to which the present invention is applied.

The RLC transmission side 210 includes a transmission unit 760, a transmission prohibition time determination unit 750, and a control unit 740.

The transmission prohibition time determiner 750 determines whether or not the RLC receiver 200 has received the first RLC message from the RLC transmitter 210 to the RLC receiver 200 in order to prevent the RLC receiver 200 from malfunctioning due to the delayed PDU. (T_PRX_TX_PDU) is determined in consideration of a time to arrival (TTA), which is the time required to transmit the PDU. At this time, the transmission prohibition time includes a constant considering a TTA (Time TO Arrival) or a function value derived as a factor of a TTA (Time TO Arrival).

The transmitting unit 760 transmits the first RLC PDU to the RLC receiving side 200, and after the RLC reset time from the RLC reset time minus the transmission prohibition time, the second RLC PDU to the RLC receiving side 200 ).

The first controller 740 transmits the first PDU to the RLC receiver 200 from the RLC transmitter 210 and determines a transmission prohibition time of a packet to be transmitted thereafter and considers the determined transmission prohibition time And controls the transmission unit 760 and the transmission prohibition time determination unit 750 to transmit the second PDU.

On the other hand, the RLC receiving side 200 includes a receiving unit 730, a receiving prohibition time determining unit 720, and a second controlling unit 710.

The reception prohibition time determiner 720 determines the reception prohibition time T_PRX_RX_PDU in consideration of the time to arrival (TTA), which is the time taken until the RLC PDU (1) (407).

The receiving unit 730 receives the first RLC PDU from the RLC transmitting side 210 and receives the second RLC PDU from the RLC transmitting side 210 after the RLC reset time T2, PDU is normally received.

The second control unit 710 receives the first PDU from the receiving side, determines a reception prohibition time of a packet received thereafter, and determines the reception prohibition time to allow reception of the second PDU in consideration of the determined reception prohibition time The control unit 720, and the reception unit 730, respectively.

1 is a block diagram showing an example of the structure of an LTE mobile communication system;

2 is a flowchart illustrating a PDU transmission method before a general RLC reset,

FIG. 3 is a flowchart illustrating a PDU transmission method before RLC reset according to the first embodiment of the present invention.

FIG. 4 is a flowchart illustrating a PDU receiving method before RLC reset according to a second embodiment of the present invention;

FIG. 5 is a flowchart illustrating a PDU transmission method before RLC reset according to the first embodiment of the present invention;

6 is a flowchart illustrating a PDU receiving method before RLC reset according to a second embodiment of the present invention.

7 is a block diagram of a pre-RLC reset PDU transceiver to which the present invention is applied.

Claims (12)

A method for processing data on a transmitting side in a mobile communication system, (A) transmitting a first PDU (packet data unit) to a receiver; (B) determining a transmission prohibition time in consideration of a time taken for the first PDU to be transmitted from the transmitting side to the receiving side; (C) stopping the transmission of the second PDU from the time when the RLC reset time is subtracted from the transmission prohibition time to the RLC reset time, and transmitting the third PDU to the receiver after the transmission prohibition time, Wherein the transmitting side does not need to receive a PDU from the receiving side for performing the steps (a), (b), and (c). The method according to claim 1, The transmission prohibition time is a time A method for processing data on a transmitting side including a constant taking into account a TTA (Time TO Arrival). The method according to claim 1, The transmission prohibition time is a time And a function value derived from a TTA (Time TO Arrival) as a factor. A method for processing data on a receiving side in a mobile communication system, Receiving a first PDU (Packet Data Unit) from a transmitting end; (A) determining a reception prohibition time in consideration of a time taken for the first PDU to be received from the transmission side to the reception side; (C) stopping reception of a second PDU from the RLC reset time to a point of time when the RLC reset time is added to the reception prohibition time, and receiving a third PDU from the transmission side after the reception prohibition time, Wherein the receiver does not need to transmit a PDU to the transmitter for performing the steps (a), (b), and (c). 5. The method of claim 4, The reception prohibition time is a time A data processing method on a receiving side including a constant taking into account a TTA (Time TO Arrival). 5. The method of claim 4, The reception prohibition time is a time And a function value derived as a factor of TTA (Time TO Arrival). A data processing apparatus on a transmitting side in a mobile communication system, A transmission prohibition time determiner for determining a transmission prohibition time in consideration of a time required for transmitting the first PDU (Packet Data Unit) from the transmitting side to the receiving side; Transmits the first PDU to the receiver, stops the transmission of the second PDU from the time when the RLC reset time minus the transmission prohibition time to the RLC reset time, and transmits the third PDU to the receiver after the transmission prohibition time And a transmission unit Wherein the transmitting side does not need to receive the PDU from the receiving side for the operation of the transmission prohibition time determining unit and the operation of the transmitting unit. 8. The method of claim 7, The transmission prohibition time is a time A data processing apparatus on the transmitting side including a constant considering a TTA (Time TO Arrival). 8. The method of claim 7, The transmission prohibition time is a time And a function value derived from a TTA (Time TO Arrival) as a factor. A data processing apparatus on a receiving side in a mobile communication system, A reception prohibition time determination unit for determining a reception prohibition time in consideration of a time taken for the first PDU (Packet Data Unit) to be received from the transmission side to the reception side; Receiving the first PDU from the transmission side and stopping the reception of the second PDU from the RLC reset time point to the time point at which the reception prohibition time is added at the RLC reset time point, And a control unit Wherein the receiving side does not need to transmit a PDU to the transmitting side for the operation of the receiving-prohibited-time determining unit and the operation of the receiving unit. 11. The method of claim 10, The reception prohibition time is a time A data processing apparatus on a receiving side including a constant taking into account a TTA (Time TO Arrival). 11. The method of claim 10, The reception prohibition time is a time And a function value derived as a factor of TTA (Time TO Arrival).

Images