KR20070023203A - Method of transmitting and receiving messages via uplink common channel in mocile communications system - Google Patents

Abstract

The present invention relates to a method for transmitting and receiving a message through an uplink common channel that allows a wireless terminal to transmit a long length or two or more messages with an appropriate transmission power through an uplink common channel in a wireless mobile communication system. One feature of the present invention is that the radio terminal transmits the preamble and the first message upward through the common channel, and the downlink response signal received from the network in order to enable the radio terminal to transmit a long length RACH message with an appropriate transmission power In this case, the second message is transmitted upward through the common channel or the first message is retransmitted.

Preamble, RACH, PRACH, ACK, NACK, AICH, MSG-ACK

Description

Method of transmitting and receiving messages via uplink common channel in mocile communications system}

1 illustrates a network structure of a UMTS mobile communication system.

2 is a diagram illustrating a structure of a radio interface protocol between a UE and a UTRAN based on a radio access network standard of 3GPP.

FIG. 3 illustrates a process of transmitting an Initial Direct Transfer (IDT) message for establishing a signal connection and transmission of messages exchanged between a UE and an RNC for an RRC connection.

4 is a view for explaining a transmission scheme of a physical channel PRACH according to the prior art.

5 illustrates the structure of a downlink physical channel AICH according to the prior art.

6 is a process flow diagram in accordance with one preferred embodiment of the present invention.

7 is a process flow diagram of another preferred embodiment according to the present invention.

8 is a diagram illustrating a RACH configuration method according to the present invention.

9 is a process flow diagram of another preferred embodiment according to the present invention.

10 is a process flow diagram of yet another preferred embodiment according to the present invention.

11 illustrates an example of transmitting an RRC connection request message and an IDT message of a terminal according to an embodiment of the present invention.

12 illustrates an example of an MSG-ACK channel used in preferred embodiments of the present invention.

13 is a view for explaining a physical channel PRACH transmission process according to an embodiment of the present invention.

The present invention relates to a wireless mobile communication system. More specifically, the present invention relates to a method for transmitting and receiving messages through an uplink common channel that allows a wireless terminal to transmit a long length or two or more messages with an appropriate transmission power through an uplink common channel in a wireless mobile communication system.

1 illustrates a network structure of a universal mobile telecommunications system (UMTS) mobile communication system. The UMTS system is largely composed of a user equipment (abbreviated as 'UE'), a UTMS radio access network (UMTS Terrestrial Radio Access Network (hereinafter abbreviated as 'UTRAN')) and a core network (hereinafter abbreviated as CN). . UTRAN is composed of one or more Radio Network Sub-systems (hereinafter, referred to as 'RNS'), and each RNS is referred to as one Radio Network Controller (hereinafter, referred to as 'RNC'). It consists of one or more base stations (hereinafter referred to as 'Node B') managed by the RNC. One or more cells exist in one Node B.

2 is a diagram illustrating a structure of a radio interface protocol between a terminal and a UTRAN based on a radio access network standard of 3GPP. The wireless interface protocol of FIG. 2 consists of a physical layer, a data link layer, and a network layer horizontally, and a user plane for transmitting data information vertically. And Control Plane for Signaling. The protocol layers of FIG. 2 are based on the lower three layers of the Open System Interconnection (OSI) reference model, which are well known in communication systems, and include L1 (first layer), L2 (second layer), and L3 (first layer). Three layers).

Each layer of FIG. 2 is described as follows. The physical layer, which is the first layer, provides an information transfer service to an upper layer by using a physical channel. The physical layer is connected to the upper medium access control layer through a transport channel, and data between the medium access control layer and the physical layer moves through the transport channel. Then, data is moved between different physical layers, that is, between physical layers of a transmitting side and a receiving side through physical channels.

The medium access control (hereinafter, abbreviated as 'MAC') of the second layer provides a service to a radio link control layer, which is a higher layer, through a logical channel. The radio link control layer (hereinafter, referred to as 'RLC') layer of the second layer supports reliable data transmission, and is an RLC service data unit (hereinafter referred to as 'SDU') from the upper layer. Segmentation and Concatenation can be performed.

The radio resource control layer (hereinafter abbreviated as 'RRC') layer located at the bottom of the third layer is defined only in the control plane, and the configuration of radio bearers (abbreviated as 'RB') is configured. It is responsible for the control of logical channels, transport channels, and physical channels in connection with reconfiguration and release. In this case, the RB refers to a service provided by the second layer for data transmission between the UE and the UTRAN. In general, the RB is configured to define characteristics of a protocol layer and a channel necessary to provide a specific service. The process of setting specific parameters and operation methods.

Hereinafter, the RRC connection and the signal connection will be described in detail. In order to start a call, the terminal must establish an RRC connection with the UTRAN and a signaling connection with the CN. Through the RRC connection and the signal connection, the terminal exchanges terminal-specific control information with UTRAN or CN. FIG. 3 illustrates a process of transmitting an Initial Direct Transfer (IDT) message for establishing a signal connection and transmission of messages exchanged between a UE and an RNC for an RRC connection.

In the process for RRC connection, the terminal transmits an RRC Connection Request message to the RNC [S11], in response to the RRC connection request message, the RNC recalls an RRC Connection Setup Message. The terminal transmits to the terminal [S12], and the terminal transmits an RRC Connection Setup Complete message to the RNC [S13]. If the process is successfully completed, the UE and the RNC establish an RRC connection. After the RRC connection is created, the terminal transmits an IDT message to start a process for establishing a signal connection [S14].

Hereinafter, a random access channel (RACH), which is one of transport channels of WCDMA, which is an asynchronous mobile communication system, will be described in detail. RACH is used to transmit short length data upwards, and some RRC messages such as RRC connection request message, cell update message, and URA update message are also RACH. Is sent through. The logical channels Common Control Channel (CCCH), Dedicated Control Channel (DCCH), and Dedicated Traffic Channel (DTCH) may be mapped to the transport channel RACH, which in turn is mapped to the physical channel Physical Random Access Channel (PRACH).

4 is a diagram for describing a transmission method of a physical channel PRACH according to the prior art. As shown in FIG. 4, the uplink physical channel PRACH is divided into a preamble part and a message part. The preamble part performs a power ramping function to adjust an appropriate transmission power used for message transmission and prevents collision between multiple terminals. The message part is a MAC PDU delivered from the MAC layer to a physical channel. It transmits (Packet Data Unit).

When the MAC layer of the terminal instructs the transmission of the PRACH to the physical layer of the terminal, the terminal physical layer first selects one access slot and one signature (signature) to transmit the PRACH preamble to the base station (Node B) do. The preamble is transmitted during an access slot duration of 1.33 ms length, and selects and transmits one signature among 16 signatures during the first predetermined length of the access slot. When the terminal transmits the preamble, the base station transmits a response signal through the downlink physical channel acquisition indicator channel (AICH). The AICH transmitted in response to the preamble transmits a signature selected by the preamble during the first predetermined length of an access slot corresponding to the access slot to which the preamble is transmitted. At this time, the base station transmits a positive response (ACK) or a negative response (NACK) to the terminal through the signature transmitted by the AICH. If the terminal receives the ACK, the terminal transmits a message part of 10 ms or 20 ms length using the OVSF code corresponding to the transmitted signature. When the terminal receives the NACK, the MAC layer of the terminal instructs the physical layer of the terminal to transmit PRACH again after a suitable time. Meanwhile, if the AICH corresponding to the preamble transmitted by the UE is not received, the UE transmits a new preamble with a power higher than the previous preamble after a predetermined access slot.

5 illustrates a structure of a downlink physical channel AICH according to the prior art. The downlink physical channel AICH transmits a 16 symbol signature _Si (i = 0 ... 15) during an access slot 5120 chips long. Here, the terminal selects a random signature S _i from signatures S ₀ to S ₁₅ and transmits the signature for the first 4096 chip length, and sets the transmission power 'OFF' period in which no symbol is transmitted for the remaining 1024 chip lengths. do. Meanwhile, similarly to FIG. 4, the preamble portion of the uplink physical channel PRACH also transmits a 16 symbol signature _Si (i = 0 ... 15) during the first 4096 chip length.

In the conventional RACH transmission scheme as described above, when a long length MAC PDU is to be transmitted through the RACH, the RACH transmission power must be increased. Therefore, there is a problem that the cell area is reduced. In addition, since there is a limitation in transmitting a long length of message, there is a problem in that the initial setting process using the RACH is long.

The present invention has been made to solve the problems of the prior art as described above, an object of the present invention is to provide a mobile terminal in a mobile communication system that enables the transmission of a long length of message with an appropriate transmission power using an uplink common channel. A method of transmitting and receiving a message through an uplink common channel is provided.

Another object of the present invention is to provide a message transmission and reception method through an uplink common channel, which allows a terminal to transmit two or more messages by quickly transmitting a response signal when a message is transmitted through an uplink common channel.

Accordingly, one feature of the present invention is that the wireless terminal transmits the preamble and the first message upward through a common channel and receives the network from the network so that the wireless terminal can transmit a long RACH message with an appropriate transmission power. In response to the response signal, the second message is transmitted upward or the first message is retransmitted through the common channel.

In one aspect of the present invention, a method for transmitting a message through an uplink common channel according to the present invention is directed to a method for transmitting a message from a terminal of a mobile communication system including a network and at least one terminal to the network through an uplink common channel. The method comprising: transmitting a first preamble through the uplink common channel; Receiving an acknowledgment signal (ACK) for the first preamble from the network; Transmitting a first message transmitted from an upper layer through the uplink common channel; And receiving an affirmative or negative acknowledgment signal (ACK / NACK) for the first message from the physical layer of the network.

In another aspect of the present invention, a method for receiving a message through an uplink common channel according to the present invention is a method for receiving a message transmitted through an uplink common channel from a terminal in a network of a mobile communication system including a network and at least one terminal. The method of claim 1, further comprising: receiving a first preamble from the terminal through the uplink common channel; Transmitting an acknowledgment signal (ACK) for the first preamble to the terminal; Receiving a first message from the terminal through the uplink common channel; And transmitting a positive or negative response signal (ACK / NACK) for the first message to the terminal.

In another aspect of the present invention, a method for transmitting a response signal according to the present invention includes a message transmitted through a random access channel (RACH) from a terminal in a network of a mobile communication system including a network and at least one terminal. A method for transmitting a response signal to a terminal, the method comprising: transmitting a response signal through an Acquisition Indicator Channel (AICH) for a preamble transmitted from the terminal through the RACH; And transmitting a response signal to the message transmitted from the terminal through the RACH in the physical layer of the network.

Preferably, the network transmits a response signal for the preamble and a response signal for the message through the same channel code, and the response signal for the preamble and the response signal for the message are transmitted during different time intervals of one slot. . Preferably, the response signal for the preamble is transmitted during the first time period of the slot, and the response signal for the message is transmitted for the remaining time period.

Preferably, the network includes a base station Node B and a base station controller RNC, and the response signal is transmitted by the base station in response to the first message.

Preferably, the process includes generating a first message and a second message by the terminal. The process of generating the first message and the second message is performed in any one of the RRC layer, PDCP layer, RLC layer and MAC layer of the terminal. Preferably, one of the layers may generate the message by separating one data unit into a first message and a second message, and distinguishing the first and second messages from the first message and the second message. You can include a delimiter.

Preferably, the first message and the second message constitute one RRC connection request message.

Preferably, the first message includes an RRC connection request message and the second message includes an IDT message.

Preferably, the specific code included in the preamble is mapped to the specific code included in the response signal for the message. The specific code included in the preamble is a specific signature. Preferably, one signature that may be included in the preamble is mapped to one of codes that may be included in the response signal to the message.

The construction, operation and other features of the present invention will be readily understood by the preferred embodiments of the present invention described below with reference to the accompanying drawings.

6 is a process flow diagram according to one preferred embodiment of the present invention. The embodiment of FIG. 6 assumes that the UE divides one RRC message into two RACHs and transmits the two RACH messages or two RRC PDUs corresponding to the two RRC messages in two RACH messages. . In addition, it is assumed that both RACH messages are successfully transmitted in the initial transmission.

The RRC layer of the UE delivers the first RRC PDU to be included in the first RACH message to be transmitted to the RLC layer through the RLC-DATA-REQ primitive. The RLC layer generates an RLC PDU from the first RRC PDU through a MAC-DATA-REQ primitive and delivers it to the MAC layer [S101].

The MAC layer starts the RACH process. In this process, the MAC layer performs one or more continuity tests for determining whether to transmit according to a probability set by the RRC layer, and PRACHs to the physical layer through a PHY-ACCESS-REQ primitive after a predetermined time. Instructs to start the transmission process [S102].

The physical layer of the terminal starts a PRACH transmission process. First, the physical layer transmits a PRACH preamble to a base station Node B [S103]. If there is no response from the base station to the preamble for a certain time, the physical layer increases the transmission power of the preamble by a predetermined amount and transmits the preamble again.

When the base station receives the preamble, the physical layer of the base station transmits a response signal for the preamble through the AICH [S104]. When the terminal receives the ACK response of the preamble through the AICH, the physical layer of the terminal informs the terminal MAC layer of the ACK of the preamble through the PHY-ACCESS-CNF primitive [S105].

The MAC layer of the terminal delivers the MAC PDU including the first RRC PDU to the terminal physical layer through a PHY-DATA_REQ primitive [S106]. The terminal transmits the MAC PDU including the first RRC PDU to the Node B through a PRACH message part [S107].

The Node B determines whether or not the MAC PDU including the first RRC PDU is correctly received by checking a cyclic redundancy check (CRC) of the received PRACH message. When the MAC PDU including the first RRC PDU is correctly received, the Node B transmits an ACK to the UE indicating that the PRACH message part is correctly received through the MSG-ACK channel [S108]. If the Node B does not correctly receive the MAC PDU including the first RRC PDU, the Node B transmits NACK through the MSG-ACK channel or does not transmit any information to the corresponding access slot.

When correctly receiving the MAC PDU including the first RRC PDU, the Node B delivers the MAC PDU including the first RRC PDU successfully received to the RNC via a RACH FP (Frame Protocol), and the MAC The first RRC PDU included in the PDU is delivered to the RRC layer of the RNC [S109].

The physical layer of the terminal informs the MAC layer of the terminal that the MAC PDU including the first RRC PDU has been successfully transmitted through the PHY-DATA-CNF primitive [S110]. The MAC layer of the UE informs the RRC layer of the UE that the first RRC PDU has been successfully transmitted through the CMAC-STATUS-IND primitive [S111].

The RRC layer of the terminal delivers a second RRC PDU to be included in the second RACH message to be transmitted through the RLC-DATA-REQ primitive to the RLC layer of the terminal [S112]. The RLC layer of the terminal generates an RLC PDU from the second RRC PDU through a MAC-DATA-REQ primitive and delivers it to the MAC layer of the terminal [S112].

The MAC layer of the terminal starts a RACH process. In this process, the terminal MAC performs one or more continuity tests (Persistency Test) to determine whether to transmit according to the probability set in the RRC layer, and after a predetermined time has passed to the physical layer through a PHY-ACCESS-REQ primitive Instructs to start the PRACH transmission process [S113]. Or, for the RRC PDU transmission of the second RACH process and the subsequent process, the UE MAC layer PRACH to the physical layer through the PHY-ACCESS-REQ primitive immediately or after a certain back-off time without continuity test It may indicate to start the transfer process.

The physical layer of the terminal starts a PRACH transmission process. First, the terminal physical layer transmits a PRACH preamble [S114]. If there is no response to the preamble for a predetermined time, the physical layer of the terminal increases the transmission power of the preamble by a predetermined amount and transmits the preamble again. When the Node B receives the preamble, the physical layer of the Node B transmits a response signal for the preamble through the AICH [S115].

When receiving the ACK response of the preamble through the AICH, the physical layer of the terminal informs the MAC layer of the terminal through the PHY-ACCESS-CNF primitive [S116]. The MAC layer of the terminal delivers the MAC PDU including the second RRC PDU to the physical layer of the terminal through a PHY-DATA_REQ primitive [S117]. The terminal transmits the MAC PDU including the second RRC PDU to the Node B through a PRACH message part [S118].

The Node B determines whether the MAC PDU including the second RRC PDU is correctly received by a method such as checking a CRC of the received PRACH message. When the MAC PDU including the second RRC PDU is correctly received, the Node B transmits an ACK to the UE indicating that the PRACH message part is correctly received through the MSG-ACK channel [S119]. If the Node B does not correctly receive the MAC PDU including the second RRC PDU, the Node B may transmit a NACK through the MSG-ACK channel or may not transmit any information to the corresponding access slot.

When correctly receiving the MAC PDU including the second RRC PDU, the Node B delivers the MAC PDU including the second RRC PDU successfully received to the RNC via a RACH Frame Protocol (FP), and the MAC The second RRC PDU included in the PDU is delivered to the RRC layer of the RNC [S120]. The RRC layer of the RNC obtains an RRC message transmitted by the UE RRC layer from the received first RRC PDU and second RRC PDU.

The physical layer of the terminal informs the MAC layer of the terminal that the MAC PDU including the second RRC PDU has been successfully transmitted through the PHY-DATA-CNF primitive [S121]. The MAC layer of the UE informs the UE RRC layer that the second RRC PDU has been successfully transmitted through the CMAC-STATUS-IND primitive [S122].

7 is a process flow diagram of another preferred embodiment according to the present invention. In the embodiment of FIG. 7, the RLC layer of the UE divides one higher layer PDU into two RACH messages and transmits the two RACH messages, or two RLC PDUs corresponding to the two upper layer PDUs into two RACH messages. It is then assumed to transmit. In addition, it is assumed that both RACH messages are successfully transmitted in the initial transmission.

The RLC layer of the UE generates the first RLC PDU and delivers it to the MAC layer through the MAC-DATA-REQ primitive [S131].

The MAC layer starts the RACH process. In this process, the MAC layer performs one or more continuity tests for determining whether to transmit according to a probability set by the RRC layer, and PRACHs to the physical layer through a PHY-ACCESS-REQ primitive after a predetermined time. Instructs to start the transmission process [S132].

The physical layer of the terminal starts a PRACH transmission process. First, the physical layer transmits a PRACH preamble to a base station Node B [S133]. If there is no response from the base station to the preamble for a certain time, the physical layer increases the transmission power of the preamble by a predetermined amount and transmits the preamble again.

When the base station receives the preamble, the physical layer of the base station transmits a response signal for the preamble through the AICH [S134]. When the terminal receives the ACK response of the preamble through the AICH, the physical layer of the terminal informs the terminal MAC layer of the ACK of the preamble through the PHY-ACCESS-CNF primitive [S135].

The MAC layer of the terminal delivers the MAC PDU including the first RLC PDU to the terminal physical layer through a PHY-DATA_REQ primitive [S136]. The terminal transmits the MAC PDU including the first RLC PDU to the Node B through a PRACH message part [S137].

The Node B determines whether or not the MAC PDU including the first RLC PDU is correctly received by checking a cyclic redunduncy check (CRC) of the received PRACH message. When the MAC PDU including the first RLC PDU is correctly received, the Node B transmits an ACK to the UE indicating that the PRACH message part is correctly received through the MSG-ACK channel [S138]. If the Node B does not correctly receive the MAC PDU including the first RLC PDU, the Node B transmits NACK through the MSG-ACK channel or does not transmit any information to the corresponding access slot.

When correctly receiving the MAC PDU including the first RLC PDU, the Node B delivers the MAC PDU containing the first RLC PDU successfully received to the RNC through a RACH Frame Protocol (FP), and the MAC The first RLC PDU included in the PDU is delivered to the RLC layer of the RNC [S139].

The physical layer of the terminal informs the MAC layer of the terminal that the MAC PDU including the first RLC PDU has been successfully transmitted through the PHY-DATA-CNF primitive [S140]. The MAC layer of the UE informs the RLC layer of the UE that the first RLC PDU has been successfully transmitted through the CMAC-STATUS-IND primitive [S141].

The RLC layer of the terminal delivers the second RLC PDU to the MAC layer of the terminal through a MAC-DATA-REQ primitive [S142].

The MAC layer of the terminal starts a RACH process. In this process, the terminal MAC performs one or more continuity tests (Persistency Test) to determine whether to transmit according to the probability set in the RRC layer, and after a predetermined time has passed to the physical layer through a PHY-ACCESS-REQ primitive Instructs to start the PRACH transmission process [S143]. Alternatively, for the RLC PDU transmission of the second RACH process and the subsequent process, the UE MAC layer PRACHs to the physical layer through PHY-ACCESS-REQ primitive immediately or after a certain back-off time without continuity test. It may indicate to start the transfer process.

The physical layer of the terminal starts a PRACH transmission process. First, the terminal physical layer transmits a PRACH preamble [S144]. If there is no response to the preamble for a predetermined time, the physical layer of the terminal increases the transmission power of the preamble by a predetermined amount and transmits the preamble again. When the Node B receives the preamble, the physical layer of the Node B transmits a response signal for the preamble through the AICH [S145].

When the ACK response of the preamble is received through the AICH, the physical layer of the UE informs the MAC layer of the UE through the PHY-ACCESS-CNF primitive [S146]. The MAC layer of the terminal delivers the MAC PDU including the second RLC PDU to the physical layer of the terminal through a PHY-DATA_REQ primitive [S147]. The terminal transmits the MAC PDU including the second RLC PDU to the Node B through a PRACH message part [S148].

The Node B determines whether the MAC PDU including the second RLC PDU is correctly received by a method such as checking a CRC of the received PRACH message. When the MAC PDU including the second RLC PDU is correctly received, the Node B transmits an ACK indicating to the UE that the PRACH message part is correctly received through the MSG-ACK channel [S149]. If the Node B does not correctly receive the MAC PDU including the second RLC PDU, the Node B may transmit a NACK through the MSG-ACK channel or may not transmit any information to the corresponding access slot.

When correctly receiving the MAC PDU including the second RLC PDU, the Node B delivers the MAC PDU including the second RLC PDU successfully received to the RNC through a RACH Frame Protocol (FP), and the MAC The second RLC PDU included in the PDU is delivered to the RLC layer of the RNC [S150]. The RLC layer of the RNC obtains a PDU of an upper layer of the terminal from the received first RLC PDU and second RLC PDU.

The physical layer of the terminal informs the MAC layer of the terminal that the MAC PDU including the second RLC PDU has been successfully transmitted through the PHY-DATA-CNF primitive [S151]. The MAC layer of the UE informs the UE RLC layer that the second RLC PDU has been successfully transmitted through the CMAC-STATUS-IND primitive [S152].

Meanwhile, the RNC may designate a specific access slot, a specific code (preferably a signature), or a specific MAC header coding value (preferably a specific TCTF coded value) for RACH use using ACK. In this case, the Node B may restrict the ACK or the NACK to be transmitted through the MSG-ACK channel only when the Node B receives the specific access slot, code, or MAC header code value during the process of the preferred embodiment of the present invention. . Specifically, when the ACK of the message is required, the terminal transmits the PRACH using a specific access slot, a specific code, or a specific MAC header coding value. At this time, the Node B transmits ACK or NACK through the MSG-ACK channel only when receiving a PRACH message transmitted using the specific access slot, specific code or specific MAC header coding value. If a PRACH message transmitted using an access slot or code or MAC header code value other than the specific access slot, specific code or specific MAC header coding value is received, the Node B transmits through the MSG-ACK channel. Do not send ACK or NACK.

8 illustrates a RACH configuration scheme according to the present invention. Here, the RACH configuration information (RACH configuration) includes all information for configuring the RACH using the ACK, information for setting the AICH channel, information for setting the MSG-ACK channel. In addition, the RACH configuration information includes transmission power information of the channel and transmission timing information of the channel.

The RNC sets the RACH using the ACK through the 'COMMON TRANSPORT CHANNEL SETUP REQUEST' message [S161]. In this process, the RNC may restrict the Node B to transmit ACK or NACK only through the MSG-ACK channel when the Node B receives a specific access slot, a specific code, or a specific MAC header code value. After receiving according to the RACH configuration information, the Node B transmits a 'COMMON TRANSPORT CHANNEL SETUP RESPONSE' message to the RNC [S162].

The RRC layer of the RNC broadcasts the RACH configuration information to a UE through BCCH in a system information block (hereinafter, abbreviated as 'SIB') [S163]. The terminal receives the SIB transmitted on the BCCH to obtain the RACH configuration information. Preferably SIB Type 5 or Type 6 is used for transmitting the RACH configuration information.

The RRC layer of the UE configures physical channel PRACH transmission according to the RACH configuration information through a CPHY-RL-Setup-REQ primitive [S164]. The RRC layer of the UE configures transport channel RACH transmission according to the RACH configuration information through a CPHY-TrCH-Config-REQ primitive [S165]. The RRC layer of the UE configures transport channel RACH transmission according to the RACH configuration information through a CMAC-Config-REQ primitive [S166].

9 is a process flow diagram of yet another preferred embodiment according to the present invention. 9 shows an example of retransmitting a first PRACH message.

The RRC layer of the UE delivers the first RRC PDU to be included in the first RACH message to be transmitted to the RLC layer through the RLC-DATA-REQ primitive. The RLC layer generates an RLC PDU from the first RRC PDU through a MAC-DATA-REQ primitive and delivers it to the MAC layer [S171].

The MAC layer starts the RACH process. In this process, the MAC layer performs one or more continuity tests for determining whether to transmit according to a probability set by the RRC layer, and PRACHs to the physical layer through a PHY-ACCESS-REQ primitive after a predetermined time. Instructs to start the transmission process [S172].

The physical layer of the terminal starts a PRACH transmission process. First, the physical layer transmits a PRACH preamble to a base station Node B [S173]. If there is no response from the base station to the preamble for a certain time, the physical layer increases the transmission power of the preamble by a predetermined amount and transmits the preamble again.

When the base station receives the preamble, the physical layer of the base station transmits a response signal for the preamble through the AICH [S174]. When the terminal receives the ACK response of the preamble through the AICH, the physical layer of the terminal informs the terminal MAC layer of the ACK of the preamble through a PHY- ACCESS-CNF primitive [S175].

The MAC layer of the terminal delivers the MAC PDU including the first RRC PDU to the terminal physical layer through a PHY-DATA_REQ primitive [S176]. The terminal transmits the MAC PDU including the first RRC PDU to the Node B through a PRACH message part [S177].

The Node B determines whether the MAC PDU including the first RRC PDU is correctly received by a method such as checking a CRC of the received PRACH message. When the Node B does not correctly receive the MAC PDU including the first RRC PDU, the Node B does not transmit NACK through the MSG-ACK channel or transmit any information to the corresponding access slot [S178].

If the NACK is received through the MSG-ACK channel or the ACK or NACK is not received through the MSG-ACK channel in the corresponding access slot, the physical layer of the UE through the PHY-DATA-CNF primitive, the first RRC PDU Informs the MAC layer of the terminal that the MAC PDU including the was not successfully transmitted [S179].

The UE may operate differently by distinguishing between a case in which a NACK is received through an MSG-ACK channel and a case in which no response is received through an MSG-ACK channel. That is, when the terminal receives the NACK, the physical layer of the terminal informs that the MAC layer has received the NACK, the MAC layer of the terminal delays transmission for a backoff time corresponding to the NACK After that, execute the process from S182. On the other hand, if the terminal does not receive any response, the physical layer of the terminal delays the transmission during the backoff (Backoff) for the case there is no response and then executes the process after S183. Or, if the terminal does not receive any response, the physical layer of the terminal informs that the MAC layer did not receive a response, the MAC layer of the terminal corresponds to the backoff (Backoff) time when there is no response After the transmission is delayed, the process from S182 is executed.

The MAC layer of the UE informs the UE RRC layer that the first RRC PDU has not been successfully transmitted through the CMAC-STATUS-IND primitive and requests retransmission [S180]. The RRC layer of the terminal retransmits the first RRC PDU to the terminal RLC layer through an RLC-DATA-REQ primitive [S181].

The RLC layer of the terminal generates an RLC PDU from the second RRC PDU through a MAC-DATA-REQ primitive and delivers it to the MAC layer of the terminal [S182]. If the UE RLC layer or the UE MAC layer stores the first RRC PDU previously transmitted, the UE may not perform steps S181 and S182.

The terminal MAC starts the RACH process. In this process, the UE MAC layer performs one or more continuity tests to determine whether to transmit according to the probability set in the RRC layer, and the PHY-ACCESS-REQ primitive to the physical layer of the UE for a predetermined time. After the elapse of time, it is indicated to start the PRACH transmission process [S183]. Alternatively, for the second RACH and subsequent RACH transmission, the UE MAC layer transmits PRACH to the physical layer through PHY-ACCESS-REQ primitive immediately or after a certain back-off time without continuity test. Instruct them to begin the process.

The physical layer of the terminal starts a PRACH transmission process. First, the terminal physical layer transmits a PRACH preamble [S184]. If there is no response to the preamble for a predetermined time, the UE physical layer increases the transmit power of the preamble by a predetermined amount and transmits the preamble again.

When the Node B receives the preamble, the physical layer of the Node B transmits a response signal for the preamble through the AICH [S185]. When receiving the ACK response of the preamble through the AICH, the physical layer of the UE informs the MAC layer of the UE through the PHY-ACCESS-CNF [S186].

The MAC layer of the terminal delivers the MAC PDU including the first RRC PDU to the physical layer of the terminal through a PHY-DATA_REQ primitive [S187]. The terminal transmits the MAC PDU including the first RRC PDU to the Node B through a PRACH message part [S188].

The Node B determines whether the MAC PDU including the first RRC PDU is correctly received by a method such as checking a CRC of the received PRACH message. When the MAC PDU including the first RRC PDU is correctly received, the Node B transmits an ACK to the UE indicating that the PRACH message part is correctly received through the MSG-ACK channel [S189]. If the Node B does not correctly receive the MAC PDU including the first RRC PDU, it does not transmit NACK or transmit any information to the corresponding access slot through the MSG-ACK channel.

When correctly receiving the MAC PDU including the first RRC PDU, the Node B delivers the MAC PDU containing the first RRC PDU successfully received to the RNC via the RACH FP (Frame Protocol) [S190] The first RRC PDU included in the MAC PDU is delivered to the RRC layer of the RNC.

The physical layer of the terminal informs the MAC layer of the terminal that the MAC PDU including the first RRC PDU has been successfully transmitted through the PHY-DATA-CNF primitive [S191]. The MAC layer of the UE informs the RRC layer of the UE that the first RRC PDU has been successfully transmitted through the CMAC-STATUS-IND primitive [S192].

10 is a process flow diagram of yet another preferred embodiment according to the present invention. 10 is an embodiment of retransmitting a first PRACH message, and may be similarly applied to subsequent retransmissions.

The RLC layer of the terminal generates an RLC PDU and delivers it to the MAC layer of the terminal through a MAC-DATA-REQ primitive [S201].

The MAC layer starts the RACH process. In this process, the MAC layer performs one or more continuity tests for determining whether to transmit according to a probability set by the RRC layer, and PRACHs to the physical layer through a PHY-ACCESS-REQ primitive after a predetermined time. Instructs to start the transmission process [S202].

The physical layer of the terminal starts a PRACH transmission process. First, the physical layer transmits a PRACH preamble to a base station Node B [S173]. If there is no response to the preamble from the base station for a predetermined time, the physical layer increases the transmit power of the preamble by a predetermined amount and transmits the preamble again.

When the base station receives the preamble, the physical layer of the base station transmits a response signal for the preamble through the AICH [S204]. When the terminal receives the ACK response of the preamble through the AICH, the physical layer of the terminal informs the terminal MAC layer of the ACK of the preamble through the PHY-ACCESS-CNF primitive [S205].

The MAC layer of the terminal delivers the MAC PDU including the first RLC PDU to the terminal physical layer through a PHY-DATA_REQ primitive [S206]. The terminal transmits the MAC PDU including the first RLC PDU to the Node B through a PRACH message part [S207].

The Node B determines whether the MAC PDU including the first RLC PDU is correctly received by a method such as checking a CRC of the received PRACH message. If the Node B does not correctly receive the MAC PDU including the first RLC PDU, it does not transmit a NACK through the MSG-ACK channel or transmit any information to the corresponding access slot [S208].

If the NACK is received through the MSG-ACK channel or the ACK or NACK is not received through the MSG-ACK channel in the corresponding access slot, the physical layer of the UE through the PHY-DATA-CNF primitive, the first RLC PDU It informs the MAC layer of the terminal that the MAC PDU containing a was not successfully transmitted [S209].

Meanwhile, the terminal may operate differently by distinguishing between a case where a NACK is received through an MSG-ACK channel and a case where no response is received through the MSG-ACK channel. That is, when the terminal receives the NACK, the physical layer of the terminal informs that the MAC layer has received the NACK, the MAC layer of the terminal delays transmission for a backoff time corresponding to the NACK After that, execute the process from S212. On the other hand, if the terminal does not receive any response, the physical layer of the terminal delays the transmission during the backoff (Backoff) for the case there is no response and then executes the process after S213. Or, if the terminal does not receive any response, the physical layer of the terminal informs that the MAC layer did not receive a response, the MAC layer of the terminal corresponds to the backoff (Backoff) time when there is no response After delaying the transmission, the process from S212 is executed.

The MAC layer of the UE informs the UE RLC layer that the first RLC PDU has not been successfully transmitted through the MAC-STATUS-IND primitive and requests retransmission [S210]. The RLC layer of the terminal delivers the first RLC PDU to the MAC layer of the terminal through a MAC-DATA-REQ primitive [S211]. If the UE's MAC layer stores the first RLC PDU previously transmitted, the UE does not perform the processes S210 and S211.

The terminal MAC layer starts the RACH process. In this process, the terminal MAC layer performs one or more continuity tests (Persistency Test) to determine whether to transmit according to the probability set in the RRC layer, and the PHY-ACCESS-REQ primitive to a certain physical layer of the terminal After the time elapses, it is indicated to start the PRACH transmission process [S212]. Alternatively, for the RACH transmission of the second and subsequent RACH processes, the UE MAC layer transmits PRACH to the physical layer through PHY-ACCESS-REQ primitive immediately or after a certain back-off time without continuity test. Instruct them to begin the process.

The physical layer of the terminal starts a PRACH transmission process. First, the terminal physical layer transmits a PRACH preamble [S213]. If there is no response to the preamble for a predetermined time, the UE physical layer increases the transmit power of the preamble by a predetermined amount and transmits the preamble again.

When the Node B receives the preamble, the physical layer of the Node B transmits a response signal for the preamble through the AICH [S214]. When the ACK response of the preamble is received through the AICH, the physical layer of the UE informs the MAC layer of the UE through the PHY-ACCESS-CNF [S215].

The MAC layer of the terminal delivers the MAC PDU including the first RLC PDU to the physical layer of the terminal through a PHY-DATA_REQ primitive [S216]. The terminal transmits the MAC PDU including the first RLC PDU to the Node B through a PRACH message part [S217].

The Node B determines whether the MAC PDU including the first RLC PDU is correctly received by a method such as checking a CRC of the received PRACH message. When the MAC PDU including the first RLC PDU is correctly received, the Node B transmits an ACK to the UE indicating that the PRACH message part is correctly received through the MSG-ACK channel [S218]. If the Node B does not correctly receive the MAC PDU including the first RLC PDU, it does not transmit NACK or transmit any information to the corresponding access slot through the MSG-ACK channel.

When correctly receiving the MAC PDU including the first RLC PDU, the Node B delivers the MAC PDU containing the first RLC PDU successfully received to the RNC via a RACH FP (Frame Protocol) [S219] The first RLC PDU included in the MAC PDU is delivered to the RLC layer of the RNC.

The physical layer of the terminal informs the MAC layer of the terminal that the MAC PDU including the first RLC PDU has been successfully transmitted through the PHY-DATA-CNF primitive [S220]. The MAC layer of the UE informs the RLC layer of the UE that the first RLC PDU has been successfully transmitted through the MAC-STATUS-IND primitive [S221].

11 illustrates an example of transmitting an RRC connection request message and an IDT message of a terminal according to an embodiment of the present invention. That is, by using the RACH transmission according to the present invention, the UE may transmit an RRC connection request message for requesting an RRC connection and an IDT message for requesting a signal connection.

The terminal transmits the RRC connection request message and the IDT message together to the UTRAN using the RACH process as described above [S231]. For example, the RRC connection request message corresponds to the first RRC message in the embodiment of FIG. 6, and the IDT message corresponds to the second RRC message of FIG. 6. Upon receiving the IDT message, the UTRAN delivers the INITIAL UE message to the CN using the received IDT message.

The UTRAN transmits an RRC connection establishment message to the terminal in response to the RRC connection request message using the FACH [S232]. The terminal sets the DCH and transmits an RRC connection setup complete message to the UTRAN using the DCH [S233].

12 illustrates an example of an MSG-ACK channel used in preferred embodiments of the present invention. The MSG-ACK channel uses 1024 chips in addition to the 4096 chips required for AICH transmission in one access slot. Preferably, the AICH channel uses a scrambling code and a channel code such as the MSG-ACK channel. When transmitting an ACK that is a positive response to one PRACH message, the MSG-ACK is transmitted using a code and signature corresponding to a PRACH preamble for the PRACH message.

FIG. 13 illustrates a physical channel PRACH transmission process according to an embodiment of the present invention. FIG. After transmitting one PRACH message, the UE waits for an ACK or NACK transmitted through an MSG-ACK channel during an access slot corresponding to the PRACH transmission. If the ACK is transmitted on the MSG-ACK channel, the UE transmits a preamble for transmitting the next PRACH message. When receiving a positive response through the AICH, the UE transmits the next PRACH message transmission. In this case, when the next PRACH message is the last message and an ACK is received through the MSG-ACK channel during the access slot corresponding to the transmission of the next PRACH message, the physical layer of the terminal terminates the PRACH transmission to the MAC layer of the terminal. Informs the ACK received through the MSG-ACK channel. On the other hand, when the NACK is received through the MSG-ACK channel or nothing is received during the access slot corresponding to the next PRACH message transmission, the terminal transmits the preamble again to retransmit the next PRACH message.

The retransmission process of one PRACH message is continued until an ACK is received from the MSG-ACK channel, or the maximum number of message retransmissions transmitted from the RRC layer to the MAC layer or the physical layer is repeated. The maximum number of message retransmissions may be included in the RACH configuration information of FIG. 8.

It is apparent to those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit and essential features of the present invention. Accordingly, the above detailed description should not be construed as limiting in all aspects and should be considered as illustrative. The scope of the invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the invention are included in the scope of the invention.

According to the present invention, a wireless terminal transmits a preamble and a first message upward through a common channel, and transmits a second message upward through the common channel or transmits a first message according to a downlink response signal received from a network. By enabling retransmission, there is an effect that the wireless terminal can transmit a long length of message with an appropriate transmission power through a common uplink channel.

In addition, when the terminal transmits a message through an uplink common channel, the Node B can quickly respond to the message.

Claims (19)

In the method of transmitting a message to the network through an uplink common channel in a terminal of a mobile communication system comprising a network and at least one terminal, Transmitting a first preamble through the uplink common channel; Receiving an acknowledgment signal (ACK) for the first preamble from the network; Transmitting a first message transmitted from an upper layer through the uplink common channel; And Receiving a positive or negative response signal (ACK / NACK) for the first message from the physical layer of the network. The method of claim 1, Delivering a result of receiving a positive or negative response to the first message to the upper layer; Receiving a second message delivered from the upper layer; And transmitting the second message to the network. The method of claim 2, wherein the second message transmission step, Transmitting a second preamble through the uplink common channel; Receiving an acknowledgment signal (ACK) for the second preamble from the network; Transmitting the second message through the uplink common channel; And Receiving a positive or negative response signal (ACK / NACK) for the second message from the physical layer of the network. The method according to any one of claims 1 to 3, The response signal for the first or second preamble and the response signal for the first or second message are received through the same channel code. The method of claim 4, wherein The response signal for the first or second preamble and the response signal for the first or second message are received during different time intervals on one slot. . The method of claim 3, The first message and the second message is a message transmission method through the uplink common channel, characterized in that different types of messages generated in the upper layer. The method of claim 6, And the first message and the second message are an RRC connection request message and an IDT message, respectively. The method of claim 3, And the second message is a message retransmitted as the same message as the first message. In a network of a mobile communication system including a network and at least one terminal, a method for receiving a message transmitted through an uplink common channel, Receiving a first preamble through the uplink common channel from the terminal; Transmitting an acknowledgment signal (ACK) for the first preamble to the terminal; Receiving a first message from the terminal through the uplink common channel; And Transmitting a positive or negative response signal (ACK / NACK) for the first message to the terminal. The method of claim 9, The positive or negative response signal for the first message is transmitted in the physical layer of the network characterized in that the message receiving method through the uplink common channel. The method of claim 10, Receiving a second preamble from the terminal through the uplink common channel; Transmitting an acknowledgment signal (ACK) for the second preamble to the terminal; Receiving the second message from the terminal through the uplink common channel; And And transmitting a positive or negative response signal (ACK / NACK) for the second message to the terminal. The method of claim 11, The response signal for the first or second preamble and the response signal for the first or second message are transmitted through the same channel code. The method of claim 12, The response signal for the first or second preamble and the response signal for the first or second message are transmitted during different time intervals on one slot. . The method of claim 11, The first message and the second message is a message receiving method through the uplink common channel, characterized in that different types of messages generated in the upper layer of the terminal. The method of claim 14, And the first message and the second message are RRC connection request messages and IDT messages, respectively. The method of claim 11, And the second message is a message retransmitted as the same message as the first message. In a network of a mobile communication system including a network and at least one terminal, a method for transmitting a response signal to a message transmitted from a terminal through a random access channel (RACH), Transmitting a response signal through an Acquisition Indicator Channel (AICH) for the preamble transmitted from the terminal through the RACH; And Transmitting a response signal for a message transmitted through the RACH from the terminal in the physical layer of the network. The method of claim 17, And a response signal for the preamble and a response signal for the message are transmitted through the same channel code. The method of claim 18, The response signal for the preamble and the response signal for the message are transmitted over an uplink common channel, characterized in that transmitted over a different time interval in one slot (slot).

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