ES2359221T3 - HARQ PROCESSING METHOD CONSIDERING A MEASUREMENT PAUSE. - Google Patents

Abstract

Method for a HARQ (hybrid automatic repeat request) operation processed by a terminal in a mobile communication system, the method comprising: receiving an uplink grant signal from a base station (S801); transmitting an uplink signal to the base station based on the uplink grant signal (S802); the method being characterized by understanding: determining if there is a measurement pause at the time of receiving feedback information for the transmission of the uplink signal, in which the terminal performs a measurement operation during the measurement pause; and adjust the feedback information to acknowledgment or non-acknowledgment when it is determined that the measurement pause is set at the time of receiving the feedback information such that the terminal cannot receive the feedback information (S803) .

Description

HARQ processing method considering a measurement pause

Technical sector

The present application claims the benefit of U.S. provisional applications No. 61 / 036,455 and 61 / 039.095, filed on March 13, 2008 and March 24, 2008, respectively.

The present application claims the benefit of Korean patent application No. 10-2009-0018399, filed on 4 March 2009

The present invention relates to technology HARQ processing, and more particularly, to a method of HARQ operation considering a measurement pause. Although the The present invention is appropriate for a wide range of applications, it is particularly appropriate to solve a problem caused in the event that a measurement pause interrupts the uplink / downlink transmission overlaps with the instant of time when feedback information is received HARQ (hybrid automatic repeat request) in a system mobile communication

State of the art

First, a schematic description is made 3GPP LTE communication system (Association Project 3rd Generation) Long-term evolution: hereinafter document called "LTE") as a communication system mobile in which the present invention is applicable.

Figure 1 is a schematic diagram of a E-UMTS network structure as an example of a mobile communication system

Referring to figure 1, E-UMTS (universal telecommunications system mobile evolved) is the system that has evolved from UMTS (universal mobile telecommunications system) and its standardization Basic is being done by 3GPP. Generally the E-UMTS can be called LTE system.

An E-UMTS network can be divided mainly in E-TRAN (101) and (CN 102) (network of nucleus). The E-UTRAN (101) (radio access network terrestrial UMTS evolved) consists of a user equipment (103) (below in this EU abbreviated document), a station (104) base (below in this document called eNode B or eNB), and an access gateway (105) (then in the present abbreviated document AG) located at an end point of the network to connect externally to an external network. The AG (105) can be divided into a party responsible for processing user traffic and other part for traffic processing of control. In this case, the AG for the traffic processing of new user and the AG for control traffic processing They can communicate with each other using a new interface.

In an eNode B there can be at least one cell. Between eNodes B an interface can be used for transmission of control or user traffic. Also, the CN (102) may consist of a node for user registrations of the AG (105) and another UE (103). In addition, an interface is available to discriminate between the E-UTRAN (101) and the CN
(102).

The layers of a radio interface protocol between a user equipment and a network can be divided into L1 (first layer), L2 (second layer) and L3 (third layer) based on the three lower layers of the interconnection reference model of open system (OSI) widely known in the field of communications systems A physical layer belonging to the first layer provides an information transfer service Using a physical channel. A radio resource control (a continued in this abbreviated document RRC) located in the third layer plays a role in controlling the resources of radio between the user equipment and the network. To do this, the RRC layers exchange RRC messages between the user equipment and the network. The RRC layers can be distributed over network nodes including the eNode (104) B, AG (105) and the like. In addition the RRC layer can provided to eNode (104) B or AG (105) only.

Figure 2 and Figure 3 are diagrams of structures of a radio interface protocol between a team of user and a UTRAN based on the network specifications of 3GPP radio access.

Referring to figure 2 and figure 3, a radio interface protocol consists, horizontally, of a physical layer, a data link layer and a network layer. Also, the radio interface protocol consists, vertically, in a user plane for the transfer of data information and a control plane for the delivery of control signals (signaling). In particular, Figure 2 shows the layers respective of the control plane of the radio protocol and the figure 3 shows the respective layers of the protocol user plane radio The layers of the radio protocol shown in Figure 2 and Figure 3 can be divided into L1 (first layer), L2 (second layer) and L3 (third layer) based on the three lower layers of the Open System Interconnection Reference Model (OSI) widely known in the field of systems communications

The respective layers of the control plane of the radio protocol shown in figure 2 and the respective layers of the radio protocol user plane shown in figure 3 They are explained as follows.

First, a physical layer (PHY) of a first layer provides a top layer with a service of transfer of information using a physical channel. Physical layer (PHY) is connected to a media access control (MAC) layer in an upper layer through a transport channel. Likewise, data is transported between the media access control layer (MAC) and the physical layer (PHY) through the transport channel. In In this case, the transport channel can be classified into a channel of dedicated transport or a common transport channel depending on whether a channel It is shared or not. In addition, data is transported through the physical channel between different physical layers, that is, between a layer physics of a transmission side and a physical layer of a side of reception.

There are several layers in the second layer. In first, a layer of media access control (then in this abbreviated document "MAC") plays a role in the correlation of different logical channels with different channels of transport. Also, the MAC layer also plays a role, such as logical channel multiplexing, in the correlation of several logical channels with a transport channel. MAC layer is connected to a radio link control (RLC) layer of a layer superior through a logical channel. Also, the logical channel can be classified primarily in a control channel to transfer information from a control plane and a traffic channel to transfer information from a user plane according to the type of The information transferred.

A radio link control (below in this abbreviated document RLC) of the second layer performs segmentation and concatenation of data received from a layer top to play a role in the size adjustment of the data to be appropriate for a lower layer to transfer the data to a radio section. Also, the RLC layer provides three kinds of RLC modes that include a transparent mode (a continued in this abbreviated document TM), a mode without acknowledgment of receipt (below in this abbreviated document UM) and a mode with acknowledgment (hereinafter abbreviated document AM) to guarantee various kinds of QoS demanded by each radio carrier (then in the present abbreviated document RB). In particular, the RLC AM performs a retransmission function through request and repetition Automatic (ARQ) for reliable data transfer.

A data convergence protocol layer by packets (PDCP) of the second layer performs a function of header compression to reduce the size of a header of IP packet containing relatively broad control information and unnecessary to effectively transmit an IP packet of this type, such as IPv4 and IPv6, in a radio section that has a width small band This allows a header part of the data carry only mandatory information that plays a role in increasing the transmission efficiency of the section of radio. In addition, in the LTE system, the PDCP layer also performs a safety function It consists of an encryption to prevent a interception of data by a third party and in the protection of integrity to prevent data manipulation by a third party

A radio resource control layer (a continued in this abbreviated document RRC) located in the upper part of a third layer is defined only in the control plane and is responsible for controlling a logical channel, a transport channel and physical channels in association with the configuration, reconfiguration and release of radio bearers (hereinafter abbreviated RB). In this case, RB means a logical path provided by the First and second layers of the radio protocol for the delivery of data between the user equipment and the UTRAN. Usually, setting up an RB means stipulating layer characteristics of radio protocol and channels required to provide a specific service and also means set parameters detailed and operational methods thereof. RB can be classified into a signaling RB (SRB) or a data RB (DRB) The SRB is used as a path to send an RRC message in a control plane (plane C) and the DRB is used as a path for transfer user data in a user plane (U plane).

As a downlink transport channel to transport data to a user equipment from a network, there is a broadcast channel (BCH) to transmit system information and a downlink shared channel (SCH) to transmit a User traffic or a control message. Can be transmitted downlink multicast traffic of a service broadcast or a control message on the downlink SCH or a separate downlink MCH (multicast channel). Meanwhile, as uplink transport channel for transmit data to a network from a user equipment, there is a random access channel (RACH) to transmit a message from initial control or a shared uplink channel (SCH) to transmit user traffic or a control message.

As a downlink physical channel for transmit information transferred on a transport channel of downlink to a radio section between a network and a computer of user, there is a physical broadcast channel to transfer BCH information, a physical multicast channel (PCMH) for transmit information from MCH, a shared link channel physical descendant to transmit information from PCH and SCH from downlink or a physical downlink control (or the called control channel DL L1 / L2) to transmit information from control provided by the first and second layers.

As a physical uplink channel for transmit information forwarded on a transport channel of uplink to a radio section between a network and a computer user, there is a physical uplink shared channel (PUSCH) to transmit uplink SCH information, a Physical random access channel (PRACH) to transmit information RACH or a physical uplink control channel (PUCCH) to transmit the control information provided by the layers first and second, such as HARQ ACK, HARQ NACK, request for planning (SR), channel quality indicator notification (CQI) and the like.

Based on the above description, the HARQ processing performed on the LTE system is explained schematically as follows.

Figure 4 is a diagram of the HARQ operation made in the LTE system.

Referring to Figure 4, a terminal (UE) is It has a transmission side and a base station (eNode B or eNB) is arranged on a reception side. A situation of uplink in which feedback information is received HARQ from the base station. This is also applicable so identical to a downlink situation.

First, in order to allow a terminal transmit data, a base station can transmit uplink planning information, that is, a uplink concession (UL) through the PDCCH (channel of physical downlink control) [S401]. In this case, the UL grant may include a terminal identifier (for example, C-RNTI, C-RNTI of semi-persistent planning), a location of a radio resource assigned (resource block assignments), a parameter of transmission such as a modulation / coding rate, a redundancy version and the like, a new data indicator (NDI), etc.

The terminal can check if there is information UL concession sent to itself by monitoring the PDCCH each TTI (transmission time interval). In case of discover the UL grant information sent to itself, the terminal can transmit data (data 1 in figure 4) on the PUSCH (physical uplink shared channel) according to the UL grant information received [S402]. In this case, the transmitted data can be transmitted by the PDU (data unit protocol) MAC (media access control).

As mentioned in the previous description, after the terminal has performed the link transmission ascending on the PUSCH, it is in standby mode for reception of HARQ feedback information on the PHICH (channel of physical hybrid ARQ indicator) from the base station. Yes since the base station is transmitted HARQ NACK for data 1 [S403], the terminal retransmits data 1 in a relay TTI of the data 1 [S404]. On the contrary, if from the base station [no shown in the drawing] HARQ ACK is received, the terminal stops the HARQ retransmission of data 1.

Every time the terminal makes a transmission of data using the HARQ scheme, the terminal keeps track of the number of transmissions (NB_TX_ACTUAL). If the transmission number reaches a maximum transmission number (NB_TX_ACTUAL), the terminal discard the MAC PDU stored in the HARQ buffer.

If HARQ ACK is received for data 1 retransmitted in step (S404) from terminal [S405] and if receives a UL grant on the PDCCH [S406], the terminal is informed if data to be transmitted this time is a PDU MAC initially transmitted and if a MAC PDU should be retransmitted Previously using a new data indicator (NDI) field received About the PDCCH. In this case, the NDI field is a 1 bit field. He NDI field is changed alternately as 0 \ rightarrow1 \ rightarrow0 \ rightarrow1 \ rightarrow ... every time that a new MAC PDU is transmitted. For the relay, the field NDI is set to a value equal to that of the previous transmission. In In particular, the terminal is informed if it should retransmit the MAC PDU comparing if the NDI field is set to a value previously transmitted.

In the case of figure 4, since a value from "NDI = 0" in step (S401) is changed to "NDI = 1" in the stage (S406), the terminal recognizes that the transmission corresponding is a new transmission. The terminal can then transmit data 2 on the PUSCH [S407].

Meanwhile, in the LTE system, a station base can establish a measurement operation for a terminal that You need intermediation for mobility support. Therefore in a measurement pause during which the terminal performs the intermediation, as a rule a communication is interrupted between the base station and the terminal. In this case, the "intermediation" includes intra-frequency measurement, a interfrequency measurement, mobility measurement inter-RAT, etc. "Intermediation" can be called "measurement pause operation" if this does not cause confusion.

The measurement pause interval can determined according to an establishment of the base station. As the measurement pause operation every interval is performed determined, the terminal stops transmission to the base station on the uplink for 6 \ f7 and stops reception on the downlink for 6 ms.

However, if the measurement pause matches With the HARQ feedback reception time, it is impossible for The terminal receives HARQ feedback from the base station. The 3GPP LTE standard (see 3GPP TS 36.321 V8.0.0), before presenting The present invention specifies a normal "HARQ operation". However, 3GPP TS 36.321 V8.0.0 says nothing as to how HARQ operation can be continued when the time of receipt Feedback HARQ matches the measurement pause.

Object of the invention

Accordingly, the present invention is refers to a HARQ operation processing method considering a measurement pause that substantially avoids one or more problems due to limitations and disadvantages of the related technique.

An object of the present invention is provide an effective HARQ processing method, intended to a case in which a measurement pause to interrupt the uplink transmission / downlink overlaps with the time of receipt of HARQ feedback information in a mobile communication system

Advantages, objects and additional features of the invention will be set forth in part in the description that follows and in part they will be apparent to those skilled in the art by examine the following or can be learned by implementing the invention. The objectives and other advantages of the invention can be carried out and achieved through the structure particularly indicated in the written description and in the claims of the present document as well as in the attached drawings.

To reach these objects and other advantages and according to the purpose of the invention, as performed and described extensively in this document, a method for an operation HARQ (hybrid automatic repeat request) processed by a terminal in a mobile communication system, according to the present invention, includes the steps of receiving a grant signal from uplink from a base station, transmit a signal from uplink to the base station based on the signal from uplink grant, determining if there is a pause of measurement at the time of receiving feedback information for the uplink signal transmission from the station base, in which the terminal performs a measurement operation during the measurement pause, and adjust the information of feedback on acknowledgment of receipt or non-acknowledgment of receipt when determines that the measurement pause is set at the time of receive feedback information in such a way that the terminal cannot receive feedback information.

Preferably, when it is determined that the measurement pause is set at the time of receiving information feedback and the terminal cannot receive information from feedback, feedback information conforms to acknowledgment Of receipt.

More preferably, even when the terminal adjust the feedback information to acknowledgment, the terminal retains the uplink signal in a memory HARQ intermediate.

In this case, the method may also include the stages of receiving an uplink grant signal additional for uplink signal from base station and retransmit the uplink signal that has been retained in HARQ buffer from the terminal.

Preferably, the terminal performs at least one of an intrafrequency measurement, a measurement of interfrequency and mobility measurement inter-RAT as the measurement operation during the measurement pause

Preferably, the HARQ process is assumed It is a synchronous HARQ process.

In another aspect of the present invention, a terminal, which performs a HARQ operation (repeat request automatic hybrid) in a mobile communication system, includes a receiving module that receives a link grant signal ascending from a base station, a transmission module that transmits an uplink signal to the base station based on the uplink grant signal, a module of measurement that performs a measurement operation and does not perform minus one of uplink and link transmissions descending during a prescribed measurement pause, and at least one HARQ process module configured to manage the HARQ operation of the terminal, in which the at least one HARQ process module is set to determine if there is a measurement pause in the time to receive feedback information for a transmission of the specific uplink signal from the base station and to adjust the feedback information to acknowledgment of receipt or not acknowledgment of receipt when it is determined that the measurement pause is set at the time of receiving the feedback information such that the terminal cannot Receive feedback information.

Preferably, when it is determined that the measurement pause is set at the time of receiving the feedback information and if it is impossible to receive the feedback information through the reception module, the at least one HARQ process module is configured to adjust the feedback information upon acknowledgment.

More preferably, each of the at least one HARQ process module is associated with a buffer HARQ. When a specific HARQ process module enters the al minus a HARQ module process adjusts the information of feedback upon receipt, the HARQ process module specific is configured to preserve the link signal specific ascending in a specific HARQ buffer associated with the specific HARQ process module.

In this case, when the receiving module receives an additional uplink grant signal for the transmission of the uplink signal from the base station, the specific HARQ process module is configured to retransmit the uplink signal that has been retained in the specific HARQ buffer through the module transmission.

Preferably, the transmission module and the Receive module are included in a physical layer module, the at least one HARQ process module is included in a MAC layer (media access control), and the measurement module comprises the minus one of a module in an RRC layer module (resource control radio) and a module in the physical layer module.

Accordingly, the present invention provides the following effects and / or advantages.

First, after a terminal has transmitted data to a base station using the HARQ scheme, if the HARQ feedback reception time for transmission of data overlaps with a measurement pause, the terminal cannot receive HARQ feedback. If so, the terminal establishes HARQ feedback information for the corresponding HARQ feedback by itself. Therefore, the terminal can perform a normal HARQ operation normally.

Second, the method of the present invention can increase the efficiency of resources more than the method of adjusting HARQ feedback reception time and a measurement pause so that they do not overlap each other.

Third, even if a terminal works so that determines HARQ feedback information, which does not a base station is received by the terminal, like ACK by itself provides means to allow the terminal to initiate a Relay for that specific transmission. Therefore you can operate a system flexibly.

It should be understood that both the description previous general as the following detailed description of the The present invention are exemplary and explanatory and are intended to provide an additional explanation of the invention as claimed.

Description of the figures

The attached drawings, which are included for provide a better understanding of the invention and are incorporated and constitute a part of this application, illustrate (one) embodiment (s) of the invention and together with the Description serve to explain the principle of the invention. In the drawings:

Figure 1 is a schematic diagram of a E-UMTS network structure as an example of a mobile communication system;

Figure 2 and Figure 3 are diagrams of structures of a radio interface protocol between a team of user and a UTRAN based on the network specifications of 3GPP radio access;

Figure 4 is a diagram of the HARQ operation performed in the LTE system;

Figure 5 is a diagram to explain a problem that occurs in case of a measurement pause and the HARQ feedback information reception time is overlap each other;

Figure 6 is a diagram to explain a scheme for a terminal to work so as to determine a HARQ feedback not received as HARQ NACK according to one embodiment of the present invention;

Figure 7 is a diagram to explain a scheme for a terminal to function so that it determines a HARQ feedback not received as ACK according to another embodiment of the present invention;

Figure 8 is a diagram of a method of performing a HARQ operation on a terminal according to a preferred embodiment of the present invention; Y

Figure 9 is a schematic diagram of a configuration of a terminal to perform a HARQ operation according to An embodiment of the present invention.

Detailed description of the invention

Reference will be made in detail below to preferred embodiments of the present invention, examples of which are illustrated in the attached drawings. When ever it is possible, the same reference numbers will be used in all drawings to refer to the same or similar parts. In The following detailed description of the invention are included details to help a complete understanding of this invention. However, it is evident to those skilled in the art that the present invention can be implemented without those details. By example, although the following detailed description is made in detail assuming that a mobile communication system is the 3GPP LTE system, is applicable to other communication systems prescribed mobile excluding exclusive elements of 3GPP LTE.

Occasionally, structures are omitted and devices known to the public to avoid inaccuracies conceptual of the present invention or can be illustrated as block diagrams focusing on their main functions.

Also, in the following description, it is assumed that a terminal is a generic term of an end device fixed or mobile user such as a user equipment (UE), a mobile station (MS) and the like. In addition, a station is supposed to base is a generic name of a random node of one end of network, which communicates with a terminal, such as a Node B, an eNode B and the like

The problem caused when the measurement pause and the timing of receipt of HARQ feedback information is overlap each other is explained in detail as follows.

Figure 5 is a diagram to explain a problem that occurs in case of a measurement and timing pause of receiving feedback information HARQ overlap between yes.

Referring to figure 5, if a terminal receives a UL grant from a base station, the terminal generates a corresponding MAC PDU for the UL concession received, for example, a MAC A PDU in the example shown in Figure 5, and You can then make an initial transmission [S501]. Subsequently, the terminal can receive information from HARQ feedback corresponding to the transmission of the MAC A PDU at the given time [S502]. Since the HARQ operation is performs synchronously in the LTE system in general, the information of HARQ feedback on the corresponding UL grant is Receive at the specific time. If the terminal receives HARQ NACK from the base station in step (S502), the terminal can transmit the corresponding MAC A PDU in a following period [S503]. In this case, it is assumed that the HARQ operation is performed in non adaptive way. For example, the retransmission of the MAC A PDU in step (S503) is performed using the same scheme of the stage (S501) and through the same resources of the stage (S501) if there is no separate UL grant.

Meanwhile, if a system needs a intermediation, the base station can pause measurement of a prescribed period for the terminal. The terminal can perform an operation such that an interfrequency measurement, a intra-frequency measurement, a system mobility measurement inter-radio (inter-RAT) or similar in The measurement pause set.

In this case, the "measurement of interfrequency "means a measurement operation at a frequency different from a link carrier frequency descending from a service cell while the "measurement intrafrequency "means a measurement operation at the downlink carrier frequency of the service cell. In addition, the "system mobility measurement inter-radio "includes a system measurement inter-radio to UTRA frequency (radio access universal terrestrial), a system measurement inter-radio to the GERAN frequency (access network of GSM / EDGE radio), an inter-radio system measurement at CDMA2000 HRPD frequency (packet data at high speed CDMA2000) or at CDMA2000 frequency 1xRTT (1x technology CDMA2000 radio transmission) and the like.

The base station can set the pause of measurement explained above in the terminal through a RRC layer signal (radio resource control). Also, the Measurement operation mentioned above can be managed through an RRC layer module of the terminal. In figure 5, the terminal performs the measurement operation mentioned above in a measurement pause 1 (MG1) of a period interval default and a measurement pause 2 (MG2) of a range of predetermined period Therefore, the terminal stops the uplink / downlink receptions in pauses 1 and 2 measurement.

If the time to receive information from HARQ feedback for the MAC A PDU retransmitted on the stage (S503) overlaps with measurement pause 2 in which it is not possible uplink / downlink reception of the terminal [S504], since the terminal cannot receive an instruction from the base station, the terminal cannot perform a following HARQ operation. Generally, the HARQ operation of a terminal in the LTE system determines whether a retransmission should be performed according to the HARQ feedback reception from a base station. If the feedback information from the base station does not provide the determination of ACK or NACK, there is the problem that a connection with a next operation HARQ is disconnected.

Regarding the establishment of the pause of measurement mentioned above, the measurement pause is set for a terminal through an RRC layer signal of a station base. Also, the HARQ transmission and retransmission moments They are also managed by the base station. Therefore it is possible consider a scheme to adjust the time of receipt of HARQ feedback so that it does not overlap with the measurement pause in advance by the base station. However, the moment of HARQ feedback reception may vary depending on how many times Relay via HARQ. In case they are assigned resources considering all the possibilities that the pause of Measurement and timing of feedback feedback HARQ overlap, there is a problem that the effectiveness of Resources may get worse.

According to an embodiment of the present invention, instead of allowing a base station to change the scheme of resource allocation considering the problem mentioned previously, if a terminal cannot receive a feedback HARQ from the base station due to the interruption of the uplink transmission / reception / downlink, such as the measurement operation mentioned above, the terminal determines HARQ feedback information from the base station, that is not received from the base station, by itself and then Performs following HARQ operations.

According to this embodiment, if the time of HARQ feedback reception overlaps the measurement pause mentioned above, it is proposed that a terminal works determining HARQ feedback not received as HARQ NACK.

Figure 6 is a diagram to explain a scheme for a terminal to function so that it determines a HARQ feedback not received as HARQ NACK according to one embodiment of the present invention.

Referring to figure 6, a terminal generates the MAC A PDU according to the UL grant received from a station base and then can transmit the MAC A PDU generated on the PUSCH [S601]. In addition, the base station can set a pause of measurement such as a measurement pause 1 (MG1), a pause 2 of measurement (MG2) and a measurement pause 3 (MG3), shown in the Figure 6, for the terminal through an RRC layer signal. For the therefore, an RRC layer module of the terminal stops communications uplink / downlink in measurement pause corresponding and then you can pause intermediation described above using a physical layer module.

After the terminal has transmitted the MAC A PDU, the terminal waits for HARQ feedback from the base station at the given time. If the terminal receives HARQ NACK from the base station [S602], the terminal may attempt a Relay of the MAC A PDU at the time of retransmission next, for example, a next TTI [S603].

Meanwhile, if the time of a reception of HARQ feedback information for the MAC PDU A retransmitted on stage (S603) overlaps with pause 2 of measurement [S604], the terminal according to this embodiment considers the HARQ feedback information that is not received from the base station as NACK and then proceed with the HARQ operation next. In particular, the terminal may retransmit the MAC A PDU on a next transmission TTI [S605].

Figure 6 shows the example in which The base station actually transmits HARQ NACK on stage (S604). However, even if the base station actually transmits HARQ ACK in step (S604), the terminal does not receive the HARQ ACK correspondent. According to this embodiment, the terminal determines this. like HARQ NACK and then do the retransmission. Thus, although the base station receives the MAC A PDU again after a satisfactory reception of the MAC A PDU, the base station can ignore the MAC A PDU transmitted repeatedly thanks to the ID of HARQ process or similar.

Meanwhile, according to another embodiment of the present invention, since the measurement pause coincides with the HARQ feedback information reception time, as mentioned in the description above, if a reception is not possible of HARQ feedback information, a terminal determines the HARQ feedback information not received as ACK and then Perform the following HARQ operation.

Figure 7 is a diagram to explain a scheme for a terminal to function so that it determines a HARQ feedback not received as ACK according to another embodiment of The present invention.

Referring to figure 7, a terminal generates a MAC A PDU according to a UL grant received and then can transmit the generated MAC A PDU [S701]. Like realization shown in figure 6, it is assumed that a pause of measurement such as a measurement pause 1 (MG1), a pause 2 of measurement (MG2) and a measurement pause 3 (MG3), with a period prescribed through an RRC layer signal from a base station. Therefore, an RRC layer module of the terminal performs a intermediation operation in the corresponding measurement pause and then you can stop the transmission and reception of link up / down link during measurement pause correspondent.

The terminal may receive feedback information corresponding to the MAC A PDU transmitted in step (S701) from the base station at a predetermined time [S702]. If the terminal receives HARQ NACK from the base station, the terminal may retransmit the MAC A PDU at a subsequent transmission time
[S703].

As the moment of receiving information from HARQ feedback on the MAC A PDU retransmitted at the stage (S703) overlaps with measurement pause 2, if the terminal cannot receive HARQ feedback information from the station base, the terminal of the present embodiment considers the HARQ feedback information not received as ACK and then you can perform a following HARQ operation [S704]. In particular, since the measurement pause and the moment of reception of HARQ feedback information overlap each other, if not possible to receive HARQ feedback information from the base station, the terminal of the present embodiment stops the Relay

Meanwhile, when a relay of a terminal in the LTE system, even if a base station really fails to receive data transmitted from the terminal, you can stop the retransmission of the terminal by transmitting HARQ ACK since the retransmission of a terminal is not possible. This concept can be called "suspension." Retransmission of the terminal canceled due to the suspension can be initiated from again if the base station reassigns a UL grant to through the signaling of the PDCCH.

Therefore, according to the embodiment of the present invention, as shown in figure 7, when a terminal considers HARQ feedback information, which is not received by the terminal because the moment of receiving information from HARQ feedback overlaps with a measurement pause, such as ACK and the terminal stops a retransmission, if a base station wishes make a request for a retransmission of a MAC PDU correspondingly, the base station transmits a new concession of UL. If so, the terminal sets the corresponding MAC PDU for its Relay

Figure 8 is a diagram of a method of performing a HARQ operation on a terminal according to a preferred embodiment of the present invention.

Referring to Figure 8, in a step S801, a terminal determines that there is PDSCH information transmitted to itself on the PDCCH from a base station using a cell identifier (for example, C-RNTI, etc.) and then can obtain UL grant information from the PDSCH information transmitted to itself. Upon receipt of the UL grant, the terminal generates a corresponding uplink transmission signal, for example, MAC A PDU, and then stores it in a buffer
HARQ.

In particular, the terminal is provided with a plurality of HARQ processes that work synchronously. Specifically, each of the HARQ processes is assigned so synchronous to each TTI. For example, in the LTE system, it is assumed that A terminal is equipped with eight HARQ processes. Also, the HARQ processes are assigned as follows. First, the HARQ # 1 process is assigned to the 1st TTI, the HARQ # 2 process is assigned to the 2nd TTI, the HARQ # 8 process is assigned to the 8th TTI, the process HARQ # 1 is assigned again to the 9th TTI, and the HARQ # 2 process is assigned again at the 10th TTI and so on.

Since HARQ processes are assigned from synchronously, the HARQ process corresponding to the TTI, in which the PDCCH is received for an initial data transmission specific, it is used for the transmission of data. For example, it is assumed that a terminal receives the PDCCH including information from UL planning in a nth TTI and the nth TTI is supposed to corresponds to the HARQ #K process. When the terminal transmits data In the TTI (N + 4), you can use the HARQ #K process in the TTI (N + 4) to Data transmission

Meanwhile, each of the HARQ processes It has a HARQ buffer. Therefore, according to the granting of UL received in step (S801), a HARQ process specific to the terminal generates a MAC A PDU corresponding to the UL grant received and then stores it in its HARQ buffer. You can also use the stored MAC A PDU for transmission Initial and retransmission.

Subsequently, in one stage (S802), the terminal can initially transmit the MAC A PDU stored in memory HARQ intermediate. In particular, it can repeatedly retransmit the MAC A PDU through a prescribed count [not shown in the drawing], as described in the examples shown in figure 6 and the Figure 7. As mentioned in the previous description, the HARQ retransmission of a terminal in the LTE system is operational basically through a non-adaptive scheme. In particular, a Initial transmission of specific data is possible only if receives a PDCCH that carries UL concession information. Do not However, HARQ retransmission of the data is possible without PDCCH reception using the same UL grant for initial transmission in the TTI which has a following HARQ process assigned to it.

The transmission parameters used for the initial transmission or retransmission are transported over the PDCCH and the corresponding information is variable according to a state of channel. For example, if a channel status is better than that of a initial transmission, you can transmit the information at a rate of high bit rate changing modulation or load size Useful. On the contrary, if the channel status is poor, the transmission can be performed at a bit rate lower than the of the initial transmission.

Subsequently, in one stage (S803), although the base station transmit HARQ NACK to the terminal in response to the PDU MAC A transmitted in step (S802), the terminal cannot receive the HARQ NACK due to a measurement pause operation preset [S803]. In this case, according to the present invention, assumes that the terminal performs a HARQ operation following considering HARQ feedback information not received as HARQ ACK. Meanwhile, in the LTE system, even if a terminal transmits a specific MAC PDU to a base station and then receives HARQ ACK for the specific MAC PDU, it is assumed that the terminal retains the specific MAC PDU in a buffer HARQ unless the transmission count of the MAC PDU reaches a maximum retransmission number

Therefore, in the example shown in the figure 8, if the base station transmits a new UL grant to the terminal to make a request for a retransmission of the MAC PDU A [S804], the terminal can restart the retransmission of the MAC A PDU stored in the corresponding HARQ buffer [S805].

Generally, if the time of receipt of HARQ feedback information and a measurement pause through RRC signaling overlap each other, a terminal cannot receive HARQ feedback information. But nevertheless, considering a random access procedure, if a terminal it works giving priority to the random access procedure in instead of the measurement operation, it is possible that the terminal can receive HARQ feedback information even though the timing of receipt of HARQ feedback information and a Measurement pause overlap each other.

For example, although the time of receipt of HARQ feedback information overlaps with a pause of measurement, if the corresponding HARQ feedback information refers to a third message transmission in a procedure random access of a terminal, the terminal receives the HARQ feedback information regardless of the pause of measurement. This case in which the terminal has no problem in the receipt of HARQ feedback information when not performing a actual measurement operation corresponds to the case in which no produces the above problem in association with figure 5. By therefore, in this document, it is assumed that this case does not corresponds to the "case in which the receipt of information from HARQ feedback from the terminal is not possible due to the coincidence between the measurement pause and the moment of reception of HARQ feedback ".

In the following description, a configuration of a terminal, which implements the method of HARQ processing described above, and more particularly, a operating method considering HARQ feedback information no received as HARQ ACK in the case where a terminal cannot receive HARQ feedback information due to the coincidence between a measurement pause and a reception moment of HARQ feedback information.

Figure 9 is a schematic diagram of a configuration of a terminal to perform a HARQ operation according to An embodiment of the present invention.

Referring to Figure 9, a terminal according to an embodiment of the present invention includes a physical layer module (901) having a transmission module (904) and a reception module (905), a layer module (902) MAC having at least one HARQ process module (906) that manages the HARQ operation of the terminal and a HARQ buffer (907) corresponding to at least one HARQ process module (906), and a layer module (903) RRC that has a measurement module (908) that performs a measurement operation instead of performing uplink / downlink transmission in a prescribed measurement pause. In Figure 9, the measurement module (908) is shown as an RRC layer module, the measurement module (908) may have another module (not shown) in the physical layer module (901) to perform the related operation With the measurement. However, the substantial management of the measurement operation is carried out by the RRC layer, so it will be assumed that the measurement module (908) is located in the RRC layer module (903), as shown in the figure
9.

Based on the previous configuration, the HARQ operation of a terminal according to an embodiment of the present invention is explained as follows.

First, the terminal can receive UL concession information through module (905) of Reception from a base station. UL grant information received is delivered to the MAC layer module to assign the module (906) corresponding HARQ process. In this case, the module (906) HARQ process generates a MAC PDU corresponding to the granting of UL received and then you can store it in the corresponding intermediate memory (907) HARQ. You can use the stored MAC PDU to an initial transmission or a retransmission. In particular, the PDU The generated MAC is delivered to the module transmission module (904) (901) physical layer and then transmitted to the base station About the PUSCH. Therefore, HARQ feedback information transmitted by the base station is received again by the module (905) of reception and then can be fed back to the corresponding HARQ process module (906).

Meanwhile, a measurement pause for an intermediation can be established at the terminal through RRC layer signaling from the base station. In particular, the measuring module (908) within the RRC layer module (903) can perform an intermediary operation according to an RRC signal from the base station. In this case, the measurement module (908) can deliver information about a measurement pause to interrupt the transmission and reception of uplink / downlink to the MAC layer module (902) and / or to the layer module (901)
physical.

Therefore, since the measurement pause for that the measuring module (908) perform the operation of intermediation overlaps with the moment of receiving information HARQ feedback for uplink transmission specific, if the terminal reception module (905) cannot receive the corresponding HARQ feedback information, the corresponding HARQ process module (906) considers the HARQ feedback information not received as HARQ ACK and Then perform a following HARQ operation. Even if the HARQ feedback information that is not received by the module (906) HARQ process is considered as HARQ ACK, the MAC PDU follows being stored in the memory (907) HARQ buffer. If received a new UL grant from the base station through the module (905) of reception and then delivered to the process module (906) HARQ, the HARQ process module (906) can relay the corresponding MAC PDU through the transmission module (904) according to the UL grant that has just been received.

       \ newpage
    

The HARQ process technology described above and the terminal configuration of it is explained mainly with reference to the example in application to the system 3GPP LTE. In addition, they are applicable to various communication systems mobile that have a similar HARQ operation process in the same way than to the 3GPP LTE system.

It will be evident to experts in the technique that various modifications and variations can be made in the present invention without departing from the scope of the invention. Therefore, it is intended that the present invention cover the modifications and variations of this invention provided they enter within the scope of the appended claims.

       \ vskip1.000000 \ baselineskip
    

References cited in memory

This list of references cited by the applicant is directed only to help the reader and not form part of the European patent document. Even if you have tried the greatest care in its conception, errors of omissions and the OBE declines all responsibility in this regard.

Patent documents mentioned in the report

US 61036455 B (0001)

KR 1020090018399 (0002)

US 61039095 B (0001)

Claims (13)

1. Method for a HARQ operation (request for automatic hybrid repeat) processed by a terminal in a mobile communication system, comprising the method:

receive a uplink grant signal from a base station (S801);

transmit a uplink signal to the base station based on the signal uplink concession (S802);

the method being characterized by comprising:

determine if there is a measurement pause at the time of receiving information from feedback for the uplink signal transmission, in which the terminal performs a measurement operation during the measurement pause; Y

adjust the feedback information upon acknowledgment or non-acknowledgment when it is determined that the measurement pause is set in the time to receive feedback information in such a way that the terminal cannot receive feedback information (S803).

2. Method according to claim 1, characterized in that when it is determined that the measurement pause is set at the time of receiving the feedback information and the terminal cannot receive the feedback information, the feedback information is set to acknowledgment. (S803). 3. Method according to claim 2, characterized in that the terminal retains the uplink signal in a HARQ buffer, even when the terminal sets the feedback information for the uplink signal to acknowledgment. 4. Method according to claim 3, characterized in that it further comprises:

receive a additional uplink grant signal for the signal uplink from the base station (S804); Y

relay the uplink signal that has been retained in memory HARQ intermediate from terminal (S805).

5. Method according to claim 1, characterized in that it further comprises:

perform at minus one of an intra-frequency measurement, a measurement of interfrequency and mobility measurement inter-RAT as the measurement operation during the measurement pause

Method according to claim 1, characterized in that the HARQ operation is a synchronous HARQ operation. 7. Terminal to perform a HARQ operation (hybrid automatic repeat request) in a system mobile communication, including the terminal:

a module (905) receiving receiving an uplink grant signal from a base station;

a module (904) transmission that transmits an uplink signal to the base station based on the link grant signal upward;

a module (908) of measurement that performs a measurement operation and that does not perform at least one of uplink and link communications descending during the measurement pause; Y

at least one HARQ process module (906) configured to manage the operation Terminal HARQ,

the terminal being characterized in that the at least one HARQ process module (906) is configured to determine if the measurement pause exists at the time of receiving feedback information for the transmission of the uplink signal from the base station and to adjust feedback information upon acknowledgment or non-acknowledgment when it is determined that the measurement pause is set at the time of receiving feedback information such that the terminal cannot receive the feedback information.

8. Terminal according to claim 7, characterized in that when it is determined that the measurement pause is set at the time of receiving the feedback information and the terminal cannot receive the feedback information through the receiving module, the at least one HARQ process module (906) is configured to adjust feedback information is set to acknowledgment. 9. Terminal according to claim 8, characterized in that each of the at least one HARQ process module (906) is associated with a HARQ buffer (907), and in which when a HARQ process module (906) specific from the at least one HARQ process module (906) adjust feedback information to acknowledgment, the module (906) of specific HARQ process is configured to preserve the uplink signal in a HARQ buffer memory (907) specific associated with the HARQ process module (906) specific. A terminal according to claim 9, characterized in that when the receiving module (905) receives an additional uplink grant signal for the uplink signal from the base station, the specific HARQ process module (906) is configured to retransmit the uplink signal that has been retained in the specific HARQ buffer (907) through the transmission module (904). 11. Terminal according to claim 7, characterized in that the measuring module (908) is configured to perform at least one of an intra-frequency measurement, an inter-frequency measurement and an inter-RAT mobility measurement as the measurement operation during pause measurement. 12. Terminal according to claim 7, characterized in that the transmission module (904) and the reception module (905) are included in a physical layer module (901), wherein the at least one process module (906) HARQ is included in a MAC layer module (902) (media access control), and wherein the measuring module (908) comprises at least one of a module in a module (903) of RRC layer (control of radio resources) and a module in the layer module (901) physical. 13. Terminal according to claim 7, characterized in that the HARQ operation is a synchronous HARQ operation.