KR101368565B1 - Method and apparatus for connecting channel for uplink service - Google Patents

Abstract

The present invention provides a method of accessing a channel in a mobile communication system, when uplink data is present, initializing the number of transmissions of the first preamble, attempting to access the E-DCH (Enhanced-Data Channel) and simultaneously. Increasing the number of transmissions of the first preamble by one; if the number of transmissions of the first preamble is less than or equal to the maximum number of transmissions of the preamble, retrying connection to the E-DCH; And if the number of transmissions exceeds the maximum number of preamble transmissions of the E-DCH, attempting to connect to the RACH (Random Access Channel).

WCDMA, CELL_FACH, E-DCH, Preamble, Maximum Retransmission Number

Description

Channel connection method and apparatus in a mobile communication system using a reverse service {METHOD AND APPARATUS FOR CONNECTING CHANNEL FOR UPLINK SERVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to UMTS (Universal Mobile Telecommunication Service) communication, a third generation mobile communication system using asynchronous wideband code division multiple access (WCDMA) technology, and in particular, a terminal in a CELL_FACH state. The present invention relates to a method and apparatus for transmitting uplink data using an E-DCH channel.

First, in the UMTS system, the state of the terminal is defined according to the connection state of the terminal. Among them, in the CELL_FACH state, a dedicated physical channel is not allocated to the terminal, and a higher signaling message or a small amount of data is transmitted and received. To this end, RACH / PRACH (Random Access Channel / Physical Random Access Channel) and FACH / S-CCPCH (Forward Access Channel / Secondary Common Control Channel) are allocated.

When the terminal reselects a cell, the RNC transmits a cell update message to the RNC, so that the Radio Nework Controller (RNC) knows the position of the terminal at the cell level. C-RNTI of a Media Access Control Packet Data Unit (MAC PDU) is used to distinguish terminals located in the same cell.

Next, a method of transmitting data using a PRACH by the UE will be described in more detail with reference to FIG.

Referring to FIG. 1, when a UE generates uplink data to be transmitted, it transmits a preamble 102 first. At this time, the terminal does not transmit the preamble immediately after the data is generated, and determines the transmission time. That is, 15 access slots 101 exist over two frames, and the UE randomly selects one of the access slots 101 that can be used in duplicate and transmits a preamble at that time.

After transmitting the preamble 102, the terminal receives a response to the preamble 102 through the Acquisition Indicator Channel (AICH) 104 after a time elapsed by t _pa . Thereafter, the UE determines whether the NodeB has successfully received the preamble 102 and has allowed the UE to transmit a PRACH message.

If the UE does not receive a response to the preamble transmitted through the AICH 104, the preamble 103 is retransmitted after t _pp 106. If the response is not received after the retransmission of the preamble 103, the UE retransmits the maximum number of preamble retransmissions and then reports NoACK (No Acknowledgent) to the MAC layer and terminates the RACH procedure. However, when the UE receives the acknowledgment (ACK) response through the AICH again, the UE transmits the preamble 103 and transmits the data through the PRACH channel 108 after t _pm 107. If the load in a cell is too high to allow a UE to attempt a new access or when multiple UEs attempt to access using the same preamble, the NACK is transmitted through the AICH. After receiving the NACK, the terminal reports to the upper MAC layer and terminates the PRACH procedure of the physical layer. If the MAC layer receives NoACK or NACK, it attempts PRACH procedure again. However, when the NoACK is reported and received, the PRACH procedure is attempted again in the next 10ms frame, and in the case of NACK, the PRACH procedure is retried after a specific time (backoff time). If the retry for this PRACH procedure exceeds the number of M _max , the connection failure is reported to a higher layer, and the access procedure is terminated at the MAC layer.

Next, the E-DCH service will be described.

The UMTS system uses the enhanced uplink dedicated channel, E-DCH, to further improve the performance of uplink packet transmission. The E-DCH is an improvement from a typical dedicated channel (DCH) to support more stable high-speed data transmission, and is characterized by an Adaptive Modulation and Coding (AMC) and Hybrid Automatic Retransmission Request (HARQ). ) And a transport channel supporting techniques such as NodeB control scheduling.
2 is a diagram illustrating transmission of data through an E-DCH.

Referring to FIG. 2, the E-DCH service system includes a NodeB 201 supporting the E-DCH, and the terminals 203, 204, and 207 transmit data through the E-DCHs 206, 205, and 207. The NodeB 201 determines the channel status of the terminals 203, 204, and 207 using the E-DCHs 206, 205, and 207 to schedule data transmission of the terminals 203, 204, and 207. The scheduling is a low data rate for the terminal 204 located far from the NodeB 201 while the Rise Over Thermal (RoT) value of the NodeB 201 does not exceed the target value in order to increase the performance of the entire system The data throughput of the entire cell can be increased by assigning a high data rate to an adjacent terminal 203 or 207.
3 is a message flow diagram illustrating a transmission and reception procedure through an E-DCH.

Referring to FIG. 3, in step 303, the NodeB 301 and the terminal 302 configure an E-DCH. The setting process of step 303 includes sending and receiving messages through a dedicated transport channel. When the E-DCH is set up, the UE 302 informs the Node B 301 of status information (Schedulling information) in operation 304. The status information may include terminal transmission power information indicating uplink channel information, extra power information that the terminal can transmit, amount of data to be transmitted accumulated in the buffer of the terminal, and the like.

The NodeB 301 that receives the state information in step 311 monitors the state information of the terminal 302. In step 311, the Node B 301 determines to allow uplink packet transmission to the UE 302, and transmits scheduling grant information to the UE 302 in step 305. The scheduling assignment information includes an allowed data rate and an allowable timing. In step 312, the terminal 302 determines the E-DCH transport format combincation (E-TFC) of the E-DCH to be transmitted on the uplink using the scheduling assignment information. In step 306 and 307, the E-DCH is determined. It transmits uplink (UL) data through. In this case, an enhanced dedicated physical data channel (hereinafter referred to as E-DPDCH) is used as the physical channel used. At the same time, in step 307, the E-TFC information and the HARQ are transmitted to the Node B 301 through an Enhanced Dedicated Physical Control Channel (E-DPCCH).

In step 313, the NodeB 301 determines whether there is an error in the TFRI and the data. In step 308, the Node B 301 transmits the response information according to the determination result of step 313 to the UE 302. If there is an error, the Node B 301 performs NACK (Non-Acknowledge) Acknowledge) on the ACK / NACK channel. When the ACK information is transmitted, the transmission of the data is completed and the UE 302 transmits the new user data through the E-DCH. However, if the NACK information is transmitted, the UE 302 transmits the same data through the E-DCH Retransmit again.

The E-DCH channel described above is a channel used in the CELL_DCH state in which the channel of the UE is exclusively connected. However, in order to improve the uplink packet transmission performance of the UE currently in the CELL_FACH state, there is an attempt to transmit the UE of the CELL_FACH using the E-DCH instead of the RACH channel. 4 is a diagram illustrating a method of transmitting an E-DCH by a UE having CELL_FACH.

Referring to FIG. 4, the terminal first selects an access slot and a signature and transmits a preamble 401 in the same manner as the conventional RACH transmission procedure. When the NodeB detects the preamble, the signature is transmitted through the AICH 403. When the UE receives the response through the AICH, the UE transmits packet data through the E-DPDCH 404, which is a physical channel of the E-DCH channel. In order to demodulate the packet data transmitted through the E-DPDCH 404, necessary control information is simultaneously transmitted through the E-DPCCH channel 405. In addition, since the UE needs power control for E-DCH transmission, the UE transmits information on the DPCCH 406 and receives a TPC command from the NodeB through the F-DPCH 403. In order to set the stable E-DPDCH 404 / E-DPCCH 405 power, the power control is performed through the F-DPCH 403 and the DPCCH 405 in advance, and then the E-DPDCH 404 / E- The power setting information may be transmitted through the DPCCH 405. It is not shown in the figure, but it is possible to receive it via E-RGCH or E-AGCH in order to receive scheduling thereafter.

The configuration information of the channels necessary for data transmission through the conventional E-DCH needs to receive higher signaling before the channel is configured as shown in step 303 of FIG. 3. There is a time delay during this process and thus the advantage of using the E-DCH in the CELL FACH state is lost.
Therefore, in order to reduce the above-mentioned disadvantages, the configuration information of a plurality of E-DCH sets currently available through the system information of the cell is received in advance, and which E-DCH set is used in response to the preamble through the AICH. That is, it uses the method of informing the E-DCH set index.

Even when the E-DCH is supported to the CELL_FACH terminal as described above, since the base station must also set the existing RACH connection for the previous version terminal, when the number of uplink preambles is limited, some of the entire preamble preamble for the RACH connection The rest shall be allocated as a preamble for E-DCH access. In addition, all of the related configuration information will be transmitted through system information.

Even when the E-DCH is used in the CELL_FACH state as described above, when all of the E-DCH set resources owned by the cell are occupied or when a plurality of UEs attempt to access the same preamble, the NodeB responds to the corresponding preamble. NACK will be sent. Therefore, the probability of transmitting a NACK is increased in the case of a cell having many terminals attempting to access. In addition, when the NodeB does not properly receive the preamble, the UE may not receive ACK / NACK. In this case, a specific solution for the retry method of the terminal has not been proposed.

Accordingly, an object of the present invention is to provide a method for retrying a terminal when the CELL_FACH state terminal does not receive an ACK response for the preamble when using the E-DCH. This is to avoid interruption of uplink data transmission.

In order to achieve the above object, there is provided a method of accessing a channel of a terminal in a mobile communication system, when uplink data is present, initializing the number of transmissions of the first preamble, and enhanced-data channel (E-DCH). Attempting to connect at the same time and increasing the number of transmissions of the first preamble by one, and if the number of transmissions of the first preamble is less than or equal to the maximum number of transmissions of the preamble of the E-DCH, retry connection to the E-DCH. And attempting to access a random access channel (RACH) when the number of transmissions of the first preamble exceeds the maximum number of transmissions of the E-DCH.
An apparatus for achieving the above object is a terminal for performing a channel access in a mobile communication system, when uplink data is present, initializes the number of transmission of the first preamble, E-DCH (Enhanced-Data Channel) Attempts to connect to the controller and increases the number of transmissions of the first preamble by one, and if the number of transmissions of the first preamble is less than or equal to the maximum number of transmissions of the preamble of the E-DCH, attempts to connect to the E-DCH. If the number of transmissions of the first preamble exceeds the maximum number of transmissions of the preamble of the E-DCH, the terminal performs a channel access including a transceiver for attempting to connect to a random access channel (RACH).

In the present invention, when the UE attempting to access the E-DCH continuously attempts to receive an ACK response or if the UE attempts an existing RACH connection when a specific number of retries is exceeded, the UE attempts to connect to the E-DCH. Uplink data transmission can be performed even when resources are scarce.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

In the present invention, when the UE in the CELL_FACH state transmits uplink data using the E-DCH, the UE transmits the access preamble to the Node B through the E-DCH, but due to a high cell load or collision, AICH If the NACK is received by the Node B, or if no response is continuously received from the Node B, and the E-DCH access procedure is terminated at the physical layer and the NACK or NoACK is reported to the MAC layer, the UE reconnects to the MAC layer. The preamble is retransmitted for the attempt. In this case, a new method of accessing a terminal channel is proposed.

When transmitting the preamble in the same manner as in the conventional RACH procedure, the UE may retry the preamble transmission and may terminate the E-DCH connection when the number of retries exceeds a predetermined number (Mmax). However, since a cell allocates resources for RACH connection as well as E-DCH access for uplink access, according to the present invention, the UE receives a NACK response for the preamble for E-DCH access and retries. If is greater than Mmax to propose a method for the UE to attempt the RACH access. In other words, it proposes a method for the UE to select the RAH, not E-DCH.

First, the parameters necessary for the preferred implementation of the present invention will be described. The UE receives the configuration information required for the existing RACH connection and the configuration information required for the newly introduced E-DCH connection through cell system information. In the present invention, the following Table 1 is used for E-DCH connection. As in>, it is proposed to transmit two maximum preamble retrans Max values as configuration information.

Preamble Retrans Max for E-DCH (M _{max _e} ) Integer value Preamble Retrans Max for RACH (M _{max _r} ) Integer value

In Table 1, the Mmax_r value may use the same value as the Mmax value given for the RACH connection.

5 is a flowchart illustrating an operation of a terminal according to an exemplary embodiment of the present invention.

Referring to FIG. 5, in step 502, the UE receives system information including RACH connection and E-DCH connection related configuration information from the RRC. In step 503, the terminal receiving the system information monitors whether uplink data exists.

As a result of the monitoring, if there is no uplink data, the terminal continuously performs a monitoring step 503.

However, if the uplink data is present as a result of monitoring in step 503, the terminal proceeds to step 504, and first initializes M, the connection attempt count counter, to zero. In step 505, the UE attempts to access the E-DCH and increases M by one. Next, in step 506, the UE checks whether M is less than or equal to Mmax_e.

If M is less than or equal to Mmax_e, as a result of the check in step 506, the UE may continue to attempt the E-DCH connection, so the UE moves to step 507 and instructs the physical layer to use the E-DCH connection preamble. Then, in step 508, the terminal checks the status information reported from the physical layer. If the ACK is transmitted as a result of the state information check in step 508, the UE transmits uplink data using the allocated E-DCH set in step 509.

However, if the NACK or NoACK is reported as a result of the state information check in step 508, the terminal returns to step 505 again to retry the preamble transmission.

If a NACK occurs, it is not transmitted at the next transmission time, but is transmitted after waiting for a specific time. In the case of NoACK, it is transmitted in the next frame. M presented in steps 504 to 506 indicates the number of preamble transmissions to the E-DCH as the number of first preamble transmissions. Thereafter, M presented in steps 510 to 514 indicates the number of preamble transmissions in the RACH as the number of second preamble transmissions.

On the other hand, since the value of M is increased at every retry, a case in which M exceeds the value of Mmax_e may occur in the case of continuous retry. That is, when the check result of step 505 indicates that M exceeds the Mmax_e value, the terminal proceeds to step 510 to initialize the counter and M again, and attempts RACH access. To this end, the UE first proceeds to step 511 and increments the counter by one again. Next, the UE does not compare the Mmax_e value, which is the maximum number of preamble transmissions for the E-DCH connection, and compares the maximum preamble transmission number Mmax_r value of the RACH. do. If M is less than or equal to the value of Mmax_r, the physical layer is instructed to use a preamble for RACH connection. In step 514, the terminal checks the status information reported from the physical layer. If the ACK is received, the process proceeds to step 515 to transmit data to the RACH. In case of NACK or NoACK, the process proceeds to step 511 again to retry the RACH connection. If the Mmax_r value is larger than the Mmax_r value, the process proceeds to step 516 and reports that the M value exceeds the maximum number of preamble transmissions, and terminates the connection attempt.

For reference, although the present invention has been described based on the number of transmissions of the preamble, the existing RACH connection may be performed when the Tmax is exceeded after attempting the E-DCH access using a time interval (Tmax) instead of the number of transmissions. will be.

1 is a diagram illustrating a conventional physical layer RACH transmission procedure;

2 is a diagram illustrating transmission of data through an E-DCH.

3 is a message flow diagram illustrating a transmission and reception procedure through an E-DCH;

4 is a diagram illustrating E-DCH transmission in CELL_FACH,

5 is a flowchart illustrating a terminal operation according to an embodiment of the present invention.

Claims (14)

In a channel access method of a terminal in a mobile communication system, Initializing the number of transmissions of the first preamble when uplink data exists; Attempting to connect to an Enhanced-Data Channel (E-DCH) and simultaneously increasing the number of transmissions of the first preamble by one; Retrying connection to the E-DCH when the number of transmissions of the first preamble is equal to or less than the maximum number of transmissions of the E-DCH; And if the number of transmissions of the first preamble exceeds the maximum number of transmissions of the E-DCH, attempting to connect to a random access channel (RACH). The method of claim 1, Instructing a physical layer to use the first preamble when the number of transmissions of the first preamble is equal to or less than the maximum number of transmissions of the preamble of the E-DCH; Checking status information reported from the physical layer; And receiving an acknowledgment (ACK) as a result of the checking, further comprising accessing the E-DCH and transmitting data. The method according to claim 1, Attempting to connect to the RACH and increasing the number of second preamble transmissions initialized at the same time; Retrying connection with the RACH when the number of times of the second preamble transmission is less than or equal to the maximum number of preamble transmissions of the RACH; Instructing a physical layer to use the second preamble; Checking status information reported from the physical layer; And receiving the ACK as a result of the checking, further comprising connecting to the RACH to transmit data. The method of claim 3, If the number of second preamble transmissions exceeds the maximum number of preamble transmissions of the RACH, reporting the second preamble transmission number to a higher layer to reach the maximum number of transmissions of the RACH. . The method of claim 3, If the acknowledgment results in receiving a negative acknowledgment (NACK) or a no acknowledgment (NO acknowledgment), the method further comprises retrying the connection to the RACH. The method of claim 5, If the NACK is received, the channel access method characterized in that the data is transmitted after waiting a specific time. The method of claim 5, If the NO ACK is received, the channel access method characterized in that the data is transmitted in the next frame. A terminal for performing channel access in a mobile communication system, A controller for initializing the number of transmissions of the first preamble, attempting to access the Enhanced-Data Channel (E-DCH) and increasing the number of transmissions of the first preamble by one when uplink data exists; If the number of transmissions of the first preamble is equal to or less than the maximum number of preamble transmissions of the E-DCH, retry connection to the E-DCH, and the number of transmissions of the first preamble exceeds the maximum number of transmissions of the preamble. If the channel access terminal including a transceiver for attempting to access a random access channel (RACH). 9. The method of claim 8, The transmission and reception unit instructs the physical layer to use the first preamble when the number of transmissions of the first preamble is equal to or less than the maximum number of transmissions of the E-DCH, and confirms state information reported from the physical layer. And receiving an acknowledgment (ACK), and accessing the E-DCH to transmit data. 9. The method of claim 8, The transmitter / receiver attempts to connect to the RACH and increases the number of second preamble transmissions initialized at the same time. When the number of second preamble transmissions is less than or equal to the maximum number of preamble transmissions of RAH, the transceiver attempts to connect to the RACH. Instructing the use of the second preamble to the layer, confirming the status information reported from the physical layer, and when receiving the acknowledgment as the result of the check, indicating that the RACH is connected to transmit data Access terminal. The method of claim 10, The transceiver, if the number of transmissions of the second preamble exceeds the maximum number of transmissions of the RACH, reports that the number of transmissions of the second preamble reaches the maximum number of transmissions of the RACH to an upper layer. Access terminal. The method of claim 10, And the transmission / reception unit retries the connection with the RACH when receiving the NACK (Negative Acknowledgement) or the NO ACK (No Acknowledgement) as a result of the confirmation. The method of claim 12, When the transceiver receives the NACK, the channel access terminal, characterized in that for transmitting a data after waiting a specific time. The method of claim 12, The transmitter / receiver transmits data in the next frame when the NO ACK is received.

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