KR20050020549A - Method for scheduling assignment of uplink packet transmission - Google Patents

Abstract

PURPOSE: A scheduling assign method for uplink packet transmitting is provided to transmit a buffer state to a node B by a UE when an event is generated in a data buffer, while sending the buffer state by using a timer, thereby reducing the frequency of transmission of the buffer state and a delay time. CONSTITUTION: A UE observes a buffer state(1000), and decides whether packet data stored in an EUDCH(Enhanced Uplink Dedicated Channel) data buffer exceeds a threshold value(1002). If so, the UE transmits the buffer state and CSI(Channel State Information)(1006), and moves to a next scheduling transmission number(1008), then observes the EUDCH data buffer(1010). The UE decides whether to continuously transmit the buffer state and the CSI(1012). If so, the UE decides whether new data is created(1014). If so, the UE sends a buffer state(1016), and decides whether it is time for transmit CSI(1020). If so, the UE sends the CSI(1022), and moves to the step '1008'.

Description

Scheduling allocation method for uplink packet transmission {METHOD FOR SCHEDULING ASSIGNMENT OF UPLINK PACKET TRANSMISSION}

The present invention relates to an EUDCH mobile communication system, and more particularly, to a method for efficiently transmitting and receiving scheduling information and scheduling allocation information for transmitting packet data through an uplink.

The present invention describes a situation in which an enhanced uplink dedicated channel (hereinafter referred to as "EUDCH") is used in a wideband code division multiple access (WCDMA) communication system. The EUDCH is a channel proposed to improve the performance of packet transmission in reverse communication in an asynchronous code division multiple access communication system. Along with the Adaptive Modulation and Coding (AMC) and Hybrid Automatic Retransmission Request (HARQ) methods used in the " HSDPA " hereinafter, a smaller transmission time interval (hereinafter referred to as " TTI ") is used. New techniques can be used. The TTI may be defined as a unit in which one data block is transmitted in a physical channel. In addition, the scheduling of the uplink channel is also controlled by the Node B as the HSDPA is performed by the Node B rather than the Radio Network Controller (hereinafter referred to as "RNC"). Of course, Node B control scheduling for uplink has many differences from Node B control scheduling for downlink.

Since uplink signals transmitted by a plurality of user terminals (hereinafter, referred to as "UE") are not orthogonal to each other, the uplink signals serve as interference signals. As a result, as the uplink signal received by the Node B increases, the amount of interference signal for the uplink signal transmitted by a specific UE also increases. As the amount of the interference signal for the uplink signal transmitted by the specific UE increases, the reception performance of the Node B decreases. In order to overcome this disadvantage, the uplink transmission power may be increased, but the uplink signal having the increased transmission power serves as an interference signal with respect to other signals. Therefore, the Node B limits the amount of uplink signals that can be received while guaranteeing the reception performance. <Equation 1> represents the amount of uplink signals that can be received while ensuring the reception performance of the Node B.

remind Is the total received broadband power spectral density of the Node B, Denotes the thermal noise power spectral density of Node B. The ROT is a radio resource that the Node B can allocate for the EUDCH packet data service on the uplink.

1A and 1B show an amount of uplink radio resources that can be allocated by a Node B. FIG. As shown in FIGS. 1A and 1B, the uplink radio resource allocated by the Node B may be represented by the sum of inter-cell interference (ICI), voice traffic, and EUDCH packet traffic. FIG. 1A illustrates a change in the total ROT when the Node B scheduling is not used. Since the scheduling is not performed on the EUDCH packet traffic, when a plurality of UEs simultaneously transmit the packet data using a high data rate, the UE data may be transmitted at a higher ROT than a target ROT. In this case, the reception performance of the uplink signal is degraded.

Figure 1b shows the change in the total ROT when using the Node B scheduling. When the Node B scheduling is used, the plurality of UEs can be prevented from simultaneously transmitting the packet data using a high data rate. That is, the Node B scheduling can prevent the total ROT from increasing above the target ROT by allowing a low data rate to other UEs when allowing a high data rate to a specific UE. Therefore, the Node B scheduling can always be guaranteed a constant reception performance.

The Node B performs Node B scheduling to notify availability of EUDCH data transmission for each UE or adjust the EUDCH data rate by using request data rate or channel state information of UEs using the EUDCH. The Node B scheduling allocates the data rate to the UEs so that the measured ROT of the Node B does not exceed a target ROT in order to improve the performance of the mobile communication system. The Node B may allocate a low data rate for a far-away UE and a high data rate for a far-away UE.

2 illustrates a basic concept of a situation in which Node B scheduling is used in EUDCH. 200 in FIG. 2 shows a Node B supporting EUDCH, and UEs illustrated at 210 to 216 are UEs transmitting EUDCH. When the data rate of the UE increases, the reception power received by the Node B from the UE increases. Therefore, the ROT of the UE occupies a large part of the total ROT. On the other hand, when the data rate of the UE decreases, the reception power received by the Node B from the UE decreases. Therefore, the ROT of the UE occupies a small part of the total ROT. The Node B performs Node B scheduling for the EUDCH packet data in consideration of the relationship between the data rate and radio resources and the data rate requested by the UE.

FIG. 2 illustrates that the UEs transmit the packet data at transmit powers of different reverse channels according to distances from the Node Bs. The UE 210 farthest from the Node B transmits packet data at the transmit power 220 of the highest reverse channel, and the UE 214 nearest the Node B transmits the lowest power of the reverse channel. The packet data is sent to 224. The Node B can be scheduled to be inversely proportional to the strength of the transmit power of the reverse channel and the data rate in order to improve the performance of the mobile communication system while reducing the ICI for other cells while maintaining the total ROT. In other words, a small data rate is allocated to a UE having the highest transmit power of the reverse channel, and a high data rate is allocated to a UE having the lowest transmit power of the reverse channel.

3 illustrates a process in which a UE is allocated a data rate for EUDCH packet data transmission from a Node B and transmits the packet data using the assigned data rate. In step 310, EUDCH is set between the Node B 300 and the UE 302. Step 310 includes a process of transmitting and receiving messages through a dedicated transport channel. In step 312, the UE 302 transmits information about a required data rate and information indicating an uplink channel condition to the Node B 300 in step 312. The uplink channel state information includes uplink transmission power transmitted by the UE 302 and a transmission power margin of the UE 303.

The Node B 300 receiving the uplink transmission power may estimate a forward channel situation by comparing the uplink transmission power and the reception power. That is, if the difference between the uplink transmit power and the uplink receive power is small, the reverse channel situation is good. If the difference between the transmit power and the receive power is large, the reverse channel situation is poor. When the UE transmits a transmission power margin to estimate an uplink channel situation, the Node B 300 estimates the uplink transmission power by subtracting the transmission power margin from the maximum possible transmission power of a UE that is already known. can do. The Node B 300 determines the maximum possible data rate for the uplink packet channel of the UE by using the estimated channel condition of the UE and information about the data rate required by the UE 302.

The determined maximum possible data rate is notified to the UE 302 in step 314. The UE 302 determines the data rate of packet data to be transmitted within the range of the maximum possible data rate reported, and transmits the packet data to the Node B 300 at the determined data rate in step 316.

4 illustrates a structure of reverse physical channels supporting EUDCH service. The reverse physical channels include a dedicated physical data channel (DPDCH), a dedicated physical control channel (DPCCH), and a high speed dedicated physical control channel (HS-DPCCH) for HSDPA service. ), And a physical control channel (EU-DPCCH) for the EUDCH service. The EU-DPCCH is a physical control channel for EUDCH service information (uplink transmission power, uplink transmission power margin) necessary for the UE's buffer state and Node B to estimate the uplink channel condition (Channel State Information: CSI). Send it. The EU-DPCCH transmits a packet data transport format identifier (E-TFRI) for an EUDCH service transmitted on the EU-DPDCH. The EU-DPDCH is a dedicated physical data channel for the EUDCH service and transmits packet data using a data rate determined according to scheduling information notified from the Node B. The DPDCH supports only the BPSK modulation scheme, but the EU-DPDCH supports not only the BPSK but also QPSK and 8PSK in order to increase the data rate while maintaining the number of spreading codes transmitted simultaneously.

An EUDCH transmission controller 404 transmits the data buffer state, CSI, etc. of the UE necessary for the Node B control scheduling to the Node B through the EU-DPCCH. The EUDCH transmission controller 404 determines the E-TFRI, and transmits the determined E-TFRI to Node B through the EU-DPCCH. The packet data transmission format is determined using the maximum data rate allowed by the scheduling allocator 402.

The EUDCH packet transmitter 406 receives the packet data of the amount specified by the transmission format of the forwarded EUDCH packet data from the EUDCH data buffer 400. The received packet data performs channel coding and modulation using the EUDCH packet data transmission format, and then transmits EUDCH packet data performed by the modulation process to the Node B using an EU-DPDCH channel.

The data of the DPDCH is spread at chip rate using the OVSF code at multiplier 422 and multiplied by the channel gain at multiplier 424. Data of the DPDCH multiplied by the channel gain is input to a summer 426. Control information of the EU-DPCCH is spread at a chip rate using an OVSF code in a multiplier 408, and a channel in a multiplier 410. Multiplied by gain The control information of the EU-DPCCH multiplied by the channel gain is input to the summer 426. The summer 426 adds the input data of the DPDCH and the control information of the EU-DPCCH and configures an I channel.

The transmission symbol of the EU-DPDCH is assumed to be transmitted in a complex symbol. In other words, when the transmission symbol of the EU-DPDCH is modulated using BPSK, it has a real value. However, as described above, when the modulation is performed using QPSK and 8PSK, it has a complex value. The modulator 412 converts the packet data delivered from the EUDCH packet transmitter 406 into a complex symbol stream of I + jQ and then passes it to the multiplier 414. The multiplier 414 spreads the modulation symbols at chip rate by the OVSF code. The output of the multiplier 414 is multiplied by the channel gain in multiplier 418.

The control information of the DPCCH is spread at the chip rate using the OVSF code in the multiplier 428 and multiplied by the channel gain in the multiplier 430. The control information of the DPDCH multiplied by the channel gain is input to a summer 436. The control information of the HS-DPCCH is spread at the chip rate using the OVSF code in the multiplier 432 and multiplied by the channel gain in the multiplier 434. The summer 436 adds the control information of the inputted DPCCH and the control information of the HS-DPCCH to form a Q channel. The output of summer 436 is multiplied by imaginary number in multiplier 438 and then passed to summer 420.

The summer 420 constructs a complex symbol string obtained by adding the output of the summer 426, the output of the multiplier 418, and the output of the multiplier 438, and multiply the complex symbol string. Forward to 442. The multiplier 442 scrambles the transmitted complex symbol string using a scrambling code. The scrambled complex symbol string is converted into pulse form in the pulse generator 444 and then transmitted to the Node B through the antenna 448 via the RF 446.

5 illustrates a structure of a scheduling control channel and a scheduling control channel for transmitting EUDCH scheduling information. The scheduling control channel transmits a scheduling grant message and a maximum allowed data rate to a plurality of UEs using one OVSF code. The scheduling permission message includes information on whether to allow transmission of the EUDCH packet data. In addition, by transmitting a UE ID (UE ID) at the same time, the UE can distinguish the scheduling control information delivered to it.

The EU-SCHCCH data is converted into two symbol streams I and Q by the serial / parallel converter 510 and then transmitted to the modulator 512. The modulator 512 converts the input symbol stream into I and Q streams and then transmits the same to the multipliers 514 and 516. The multipliers 514 and 516 spread the received I, Q streams at chip rate by OVSF code. The Q stream delivered from multiplier 516 is multiplied by imaginary j in multiplier 518 and then passed to summer 520. The summer 520 transfers the output of the multiplier 514 and the output of the multiplier 518 to the multiplier 522. The multiplier 522 scrambles the transmitted complex symbol string using a scrambling code. The scrambled complex symbol string is converted into pulse form in the pulse shaper 524 and then passed through the RF 526 to the UE through the antenna 528.

6 illustrates a process of transmitting buffer status information and CSI from a UE to a Node B, and transmitting the scheduling allocation information to the UE. The UE receives a predetermined time (scheduling interval length: CSI) from the buffer state and the CSI in order to receive scheduling allocation information from the Node B. Must be sent every time.

In section 600, packet data to be transmitted to the Node B is stored (waited) in the EUDCH data buffer of the UE. The UE transmits the buffer status information and the CSI to receive the scheduling allocation information to the Node B in section 602. The Node B determines the maximum data rate to allocate to the UE by using the buffer state and the CSI transmitted from the UE, and includes the determined maximum data rate in scheduling allocation information to notify the UE at interval 612. If the packet data stored in the EUDCH data buffer cannot be transmitted to the Node B in one transmission, the UE continues to request the scheduling allocation information for the Node B. To this end, the UE continuously transmits the buffer state and the CSI at a scheduling interval length interval in the interval 602 and the interval after the interval 602.

In step 614, the Node B does not transmit scheduling allocation information for the UE because the condition of the ROT is not met. That is, the Node B does not transmit the scheduling allocation information every time a buffer state or CSI is received from the UE, and determines whether to transmit the scheduling allocation information in consideration of the ROT condition. An interval 604 or 606 means that new data to be transmitted to the Node B has occurred in the EUDCH data buffer. The UE transmits the buffer state and the CSI to the Node B until step 608, and since the UE transmits all the packet data stored in the EUDCH data buffer from the block 610, the UE stops transmitting the buffer state information and the CSI.

As shown in FIG. 6, in order to transmit all packet data stored in the EUCDH data buffer to the Node B, scheduling allocation information must be received from the Node B in a predetermined cycle unit. To this end, the UE continuously transmits the buffer state and the CSI to the Node B in a scheduling interval length interval. By continuously transmitting the buffer status information and the CSI at the scheduling interval length intervals, overloading of uplink signaling is caused, which causes the efficiency of uplink packet transmission to be impaired. Therefore, an efficient scheduling scheme that can prevent the overload of the uplink signaling is discussed.

Accordingly, an object of the present invention to solve the above-mentioned problems of the prior art is to propose a method for reducing signaling overhead for uplink packet transmission.

Another object of the present invention is to propose a method of controlling a buffer state transmitted on the uplink and a transmission period of a CSI in order to reduce signaling overhead.

Another object of the present invention is to propose a method for efficiently transmitting an uplink packet by adjusting a buffer state and a CSI transmission period.

Another object of the present invention is to propose a method of efficiently using radio resources by adjusting the buffer state and the transmission period of the CSI.

In order to achieve the above object of the present invention, a base station controller, a base station for generating scheduling assignment information using the received buffer state and channel state information, and the uplink packet data using the scheduling assignment information transmitted from the base station. In the mobile communication system consisting of a user terminal for transmitting to the base station, in the method for transmitting the buffer state and channel state information of the buffer in which the user terminal stores the packet data, the channel state information transmission period from the base station controller Receiving the buffer, starting the transmission of the buffer state and the channel state information to the base station when the data waiting in the buffer exceeds a threshold; and after the transmission of the buffer state and the channel state information, the received channel The updated channel state information according to the state information transmission period Transmission, when a new packet data to be transmitted to the base station is transmitted to the buffer constituted by any process characterized by transmitting the buffer status.

In order to achieve the objects of the present invention, the base station controller, a base station for generating scheduling assignment information using the received buffer state and channel state information, and the uplink packet data using the scheduling assignment information transmitted from the base station. In a mobile communication system consisting of a user terminal for transmitting to a base station, the method of transmitting the buffer state and channel state information of the buffer in which the user terminal stores the packet data, the buffer state by the information transmitted from the base station controller Setting a transmission time point and a transmission time point of channel state information; if data waiting in the buffer exceeds a threshold, starting the buffer state and channel state information transmission at the set buffer state transmission point; After the transmission of the status and channel status information, the setting Transmitting the updated channel state information according to the transmission time of the channel state information, and transmitting the buffer state at the transmission time of the set buffer state when new packet data to be transmitted to the base station is transferred to the buffer. .

In order to achieve the above object of the present invention, a base station controller, a base station for generating scheduling assignment information using the received buffer state and channel state information, and the uplink packet data using the scheduling assignment information transmitted from the base station. In the mobile communication system consisting of a user terminal for transmitting to the base station, in the method for transmitting the buffer state and channel state information of the buffer in which the user terminal stores the packet data, the channel state information transmission period from the base station controller Receiving the buffer, starting the transmission of the buffer status and the channel status information to the base station if the data waiting in the buffer exceeds a threshold; and after the transmission of the buffer status and the channel status information, the scheduling allocation information. Increases the buffer state to the base station and Checking whether or not to transmit null state information, and when the buffer state and channel state information are transmitted, increasing the scheduling allocation information to transmit the updated channel state information according to the set channel state information transmission time point, When the new packet data to be transmitted to the base station is delivered to the buffer, it is characterized in that the process of transmitting the buffer state at the time of the set buffer state transmission.

In order to achieve the above object of the present invention, a base station controller, a base station for generating scheduling assignment information using the received buffer state and channel state information, and the uplink packet data using the scheduling assignment information transmitted from the base station. In the mobile communication system consisting of a user terminal for transmitting to the base station, in the method for transmitting the buffer state and channel state information of the buffer in which the user terminal stores the packet data, the channel state information transmission period from the base station controller Receiving the buffer, starting the transmission of the buffer state and the channel state information to the base station when the data waiting in the buffer exceeds a threshold, and setting the timer after the transmission of the buffer state and the channel state information. The buffer status determined by the process and the set timer. And transmitting the buffer status according to the transmission time point, and transmitting the updated channel status information according to the received channel status information transmission period.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

The Node B can estimate the amount of packet data stored in the EUDCH data buffer of the UE by using the previously received buffer state and the amount of data received from the E-TFRI. Equation 2 below is an equation for estimating the amount of packet data stored in the EUDCH data buffer of the UE.

remind Is an estimated buffer state, and Is the buffer state previously received. remind Above It means the amount of data received later. The estimation of the UE buffer status using E-TFRI may cause an error, but the E-TFRI has a reception error rate lower than that of the power control command in order to increase the reception performance of packet data. For the above reason, the buffer state transmission period may be longer than the CSI transmission period. Further, when new packet data is generated in the data buffer of the UE, the Node B cannot recognize that new packet data has been generated by Equation (2).

7 is a diagram illustrating channel encoding of a buffer state and CSI transmitted by a UE according to the present invention. As shown in FIG. 7, the buffer state and the CSI are transmitted in one scheduling interval length. In FIG. 7, the one scheduling interval length is set to 10 ms. However, the CSI is transmitted on a periodic basis, but the buffer state is transmitted to the Node B only when new data is generated in the EUDCH data buffer of the UE. The buffer status is transmitted only when a new event occurs in the data buffer, not in units of a predetermined period. For this reason, the buffer state and the CSI are channel-coded separately. That is, the buffer state performs a channel encoding process after adding a CRC, and the CSI performs a channel encoding process without adding a CRC. The Node B recognizes that a buffer state is transmitted through the CRC check as the CSI performs a channel encoding process without adding a CRC. In addition, the reception of the CSI is transmitted at the rear end of the buffer state, so it can be known whether the reception of the buffer state. In addition, the CRC may be commonly used for the buffer state and the CSI.

Hereinafter, the operation of the UE according to the present invention will be described.

1. The UE transmits a buffer status and CSI to the Node B when the packet data of the EUCDH data buffer exceeds a threshold for scheduling.

2. After the UE transmits the buffer state and the CSI, the UE repeatedly performs the CSI transmission according to a set transmission period (transmission period transmitted by the RNC to the UE). However, the buffer state is transmitted to the Node B only when a new event occurs in the data buffer.

3. The UE checks the EU-SCHCCH to see if scheduling allocation information has been received from the Node B after transmitting the buffer status and CSI.

4. The UE stops the buffer state and the CSI transmission when the packet data of the EUDCH data buffer is reduced below the threshold. In addition, the buffer status and the CSI transmission are stopped even when the scheduling release message is transmitted from the Node B.

The operation of Node B is as follows.

1. Node B continuously performs a CRC check to determine whether buffer status information is transmitted from the UE. When the buffer status information is detected by the CRC check, the CSI transmitted from the same scheduling transmission number is received.

2. When the Node B receives the buffer state and the CSI for the first time, the Node B detects the CSI according to a set reception period (a reception period transmitted by the RNC to the Node B). The scheduling allocation information is generated using the received buffer state and the CSI. However, the CRC check is continuously performed to determine whether the buffer state is received.

3. When the Node B determines that the packet data stored in the EUDCH data buffer of the UE is less than or equal to the threshold value according to Equation 2, the Node B stops receiving the buffer state and the CSI.

4. In case of using the unscheduling message, the Node B transmits the unscheduling message to the UE when the buffer state and the CSI transmission are stopped. The unscheduling message means that the Node B no longer performs a scheduling process.

5. The Node B determines whether the UE, which has stopped transmitting the buffer state and the CSI, retransmits the buffer state information because the packet data stored in the EUDCH data buffer exceeds a threshold for scheduling. Perform CRC check.

<First Embodiment>

8 illustrates signaling between a Node B and a UE according to the first embodiment of the present invention. Hereinafter, the terms shown in FIG. 8 will be described first. remind Denotes the scheduling interval length. As shown in FIG. 7, it means a transmission length for transmitting one buffer state and CSI. Denotes a scheduling transmission number. The scheduling transmission number divides an interval for transmitting a buffer state or CSI by a scheduling interval length unit, and sequentially assigns numbers to the divided scheduling interval lengths. In FIG. 8, the scheduling transmission number 10 to the scheduling transmission number 30 are shown. Denotes the transmission period of the CSI.

In the scheduling transmission number 10 (800), the amount of packet data to be transmitted to the Node B by the UE exceeds a threshold. Accordingly, the UE transmits a buffer state and CSI to the Node B. The Node B transmits scheduling allocation information to the UE using the buffer state and CSI received in step 800. Of course, the Node B does not transmit the scheduling allocation information in units of a scheduling interval length, but determines whether to transmit the scheduling allocation information in consideration of the ROT.

In scheduling transmission number 14, the UE transmits only the CSI to the Node B. The transmission period of the CSI is received from the RNC. Accordingly, the UE transmits the CSI to the Node B according to the CSI transmission period received from the RNC. In FIG. 8, in the transmission transmission numbers 10, 14, 18, 22, and 26, the UE transmits the CSI to the Node B. The buffer state is not transmitted since the UE can estimate the buffer state of the UE using the buffer state received in the scheduling transmission number 10 and the amount of packet data transmitted in a predetermined interval after the scheduling transmission information 10. This is as described in Equation 2 above.

In scheduling transmission number 15, packet data to be transmitted to the Node B is generated in the EUDCH data buffer of the UE. It is impossible for the Node B to estimate the packet data generated in the scheduling transmission number 15 by Equation (2). Accordingly, the UE transmits a buffer state, which is information about data generated in the scheduling transmission number 15, to the Node B.

The UE, which has transmitted the buffer state in the scheduling transmission number 15, determines the transmission format of the packet data using the scheduling allocation information transmitted from the Node B. However, the UE cannot know whether the Node B has received the buffer state transmitted by the scheduling transmission number 15 without error. That is, when the UE does not receive the scheduling assignment information from the Node B for a predetermined time elapses, the UE cannot know why the Node B does not transmit the scheduling assignment information. The reason why the Node B does not transmit the scheduling allocation information may be due to ROT and may not receive a new buffer state. Accordingly, if the scheduling allocation information is not received such that the predetermined time elapses, the UE transmits the measured buffer state to the Node B after the set time elapses. FIG. 8 shows that the buffer status is retransmitted to the Node B in the scheduling transmission number 24. In addition, although FIG. 8 sets the buffer state retransmission time to 9 ms scheduling interval length, the buffer state retransmission time may be set by the radio network controller (RNC) and transmitted to the UE. In addition, Node B also transmits scheduling allocation information to the UE within the buffer state retransmission time after receiving the buffer state. By implementing the Node B operation as described above, the UE cannot receive the scheduling allocation information within the buffer state retransmission time after the transmission of the buffer state only when the Node B does not receive the buffer state. If the scheduling allocation information is not received so that the buffer state retransmission time elapses when the buffer state is transmitted for the first time, the UE does not receive the original buffer state and the CSI. Send status and CSI.

The Node B determines that the amount of packet data to be transmitted by the UE is less than or equal to a threshold at 818, and transmits a unscheduling message to the UE. Upon receiving the unscheduling message, the UE stops transmitting the buffer state and the CSI to the Node B. In addition, the UE stops the buffer state and CSI transmission to the Node B when the amount of packet data waiting in the EUDCH data buffer is less than a threshold.

9 illustrates a structure of an EUDCH transmission controller of a UE according to the present invention. Hereinafter, the structure of the EUDCH transmission controller of the UE according to the present invention will be described in detail with reference to FIG. 9. The buffer status, CSI transmission start and end determiner 902 determines the buffer status and the CSI transmission start time and end time. The buffer status and the start time of the CSI transmission are determined by comparing a threshold value with the input buffer status. When the input buffer state (amount of packet data stored in the EUDCH data buffer) exceeds the threshold, the buffer state and the transmission start time of the CSI become. The buffer state and the end point of the CSI transmission are the time points at which the scheduling release message is received from the Node B. In addition, when the unscheduling message is not used, the buffer state and the end of the CSI transmission become the point even when the input buffer state is less than or equal to the threshold.

The buffer state, the CSI transmission time determiner 904 determines the buffer state, the buffer state determined by the CSI transmission start and end determiner 902, and the buffer state and the CSI transmission time after the CSI transmission start time. The buffer status and the CSI transmission time point are as described with reference to FIG. 8. The buffer state, the CSI transmission time determiner 904 turns on the buffer state transfer switch 906 and the CSI transfer switch 912 at the buffer state and the transmission start time of the CSI. The buffer state, the CSI transmission time determiner 904 after transmitting the CSI at the start of the CSI transmission Wow The CSI transmission switch 912 is turned on to periodically transmit the CSI at the scheduling transmission number determined by. The buffer state, CSI transmission time determiner 904 turns on the buffer state transfer switch 906 when a new data arrival indication indicates that new data has occurred in the data buffer of the UE. The buffer state, CSI transmission time determiner 904 is the scheduling assignment information receiving indicator and the buffer state retransmission period ( ) To control the buffer status transfer switch 906 and the CSI transfer switch 912. That is, the buffer status transfer switch 906 is turned on if it is not indicated that the scheduling allocation information has been received from the scheduling allocation information receiving indicator during the buffer state retransmission period. In addition, if the scheduling assignment information is not received during the set buffer state retransmission period after the buffer state is first transmitted to the Node B, the CSI transfer switch 912 is also turned on at the same time.

When the buffer state transfer switch 906 is turned on, the buffer state is channel coded by the channel coding unit 910 after the CRC is added by the CRC adding unit 908. The channel coded buffer state is input to a multiplexer 922. When the CSI transmission switch 912 is turned on, the CSI is channel coded by the channel coding unit 914 and then input to the multiplexer 922. The EUDCH transmission format determiner 916 determines the transmission format of the packet data stored in the EUDCH data buffer by using the scheduling assignment information transmitted from the Node B. The transmission format identifier (E-TFRI) determined by the EUDCH transmission format determiner 916 is channel coded by the channel coding unit 920 after the CRC is added by the CRC adding unit 918. The channel coded transmission format identifier is input to the multiplexer 922. The multiplexer 922 transmits the input buffer status, the CSI, and the transmission format identifier to the EUDPCCH. The EUDCH packet transmitter 924 transmits the packet data stored in the EUDCH data buffer by using the transmission format determined by the EUDCH transmission format determiner 916.

10 illustrates operation at the UE transmitting end according to the present invention. Together, in step 1000, the UE observes the buffer status. The buffer state observation observes the amount of packet data stored in the EUDCH data buffer. In step 1002, the UE determines whether the packet data stored in the EUDCH data buffer exceeds a threshold. If the amount of packet data stored in the EUDCH data buffer exceeds the threshold, the determination proceeds to step 1006. If the amount of packet data stored in the EUDCH data buffer does not exceed the threshold, the determination proceeds to step 1004. Move. In step 1004, the UE moves to the next scheduling transmission number and observes the EUDCH data buffer.

In step 1006, the UE transmits a buffer state and CSI, and moves to step 1008. After the UE moves to the next scheduling transmission number in step 1008, the UE observes the EUDCH data buffer in step 1010. In step 1012, the UE determines whether to continue transmitting buffer status and CSI. The determination is made by comparing the threshold with the packet data stored in the EUDCH data buffer as described above. If it is determined that the buffer state and the CSI are continuously transmitted, the process moves to step 1014. If it is determined that the buffer state and the CSI transmission are stopped, the process moves to step 1024. In step 1024, the UE determines whether to continue the reverse packet transmission service. If it is determined that the reverse packet forwarding service continues, the process moves to step 1026 and then observes the next scheduling forwarding number. If the reverse packet transfer service does not continue, the procedure ends.

In step 1014, the UE determines whether new data is generated in the EUDCH data buffer. If new data has been generated in the EUDCH data buffer as a result of the determination, the process proceeds to step 1016. If new data has not been generated in the EUDCH data buffer, the process proceeds to step 1018. In step 1018, it is determined whether scheduling allocation information has been transmitted from the Node B within the buffer state retransmission period after the previous buffer state transmission. If the scheduling allocation information is received within the buffer state retransmission period as a result of the determination, step 1020 is performed. If the scheduling allocation information is not received within the buffer state retransmission period as a result of the determination, step 1016 is performed. In step 1016, the UE transmits a buffer state. Although not illustrated in step 1016, if the scheduling allocation information is not received within the buffer state retransmission period after transmitting the buffer state for the first time in step 1018, the CSI is transmitted simultaneously with the buffer state. In step 1020, the UE determines whether it is time to transmit CSI. The CSI transmission time point is transmitted from the RNC. If it is determined that the CSI is transmitted, the procedure proceeds to step 1022, after transmitting the CSI, to step 1008. If it is determined that the CSI transmission point is not reached, step 1008 is reached.

11 shows a reception device of a Node B according to the present invention. Hereinafter, a reception device of a Node B according to the present invention will be described with reference to FIG. 11. The antenna 1100 receives the signal transmitted by the UE and transmits the signal to the RF unit 1102. The RF unit 1102 converts the received signal into a baseband signal and transmits the signal to a pulse generator 1104. The pulse former 1104 transmits the transmitted baseband signal to the scrambler 1106. The scrambler 1106 descrambles the scrambling code. The descrambled signal is passed to the demultiplexer 1112 after passing through the despreader 1108 and the channel compensator 1110. The demultiplexer 1112 separates the transmitted signal into a buffer state, CSI, and E-TFRI.

The buffer state separated from the demultiplexer 1112 is transferred to the buffer state channel decoding unit 1122 for channel decoding. The channel decoded buffer state checks CRC at CRC detector 1124. The CRC detector 1124 transmits the CRC detection result value to the CSI reception point controller 1132. The CSI reception time controller 1132 determines whether a buffer status is transmitted from the UE by using the transferred CRC result value. When it is determined that the buffer status is transmitted from the UE, the CSI receiving time controller 1124 turns on the CSI receiving switch 1118. In addition, when the buffer state is first received, the CSI reception point controller 1132 Wow After that, the reception time of the CSI is determined using the threshold. At the determined CSI reception time, the CSI receiving switch 1118 is turned on. The CSI channel decoder 1120 channel-decodes the CSI transmitted from the demultiplexer 1112. The E-TFRI channel decoding unit 1114 channel-decodes the E-TFRI transmitted from the demultiplexer 1112, and then transfers the E-TFRI to the E-TFRI CRC detection unit 1116.

The EUDCH data decoding unit 1126 decodes EUDCH data received from the UE using the E-TFRI. The EUDCH scheduler 1128 generates scheduler allocation information to be transmitted to the UE by using the CSI transmitted from the CSI channel decoding unit 1120 and the buffer state transferred from the buffer state CRC detector 1124. The UE buffer state estimator 1130 estimates the buffer state of the UE by using the E-TFRI output from the E-TFRI CRC detector 1116 and the buffer state transferred from the buffer state CRC detector 1124. The buffer state estimate of the UE is passed to the CSI reception point controller 1132. The CSI reception time controller 1132 transmits a unscheduling message to the UE when the buffer state estimate is smaller than a threshold. The UE receiving the unscheduling message stops the buffer state and CSI transmission.

12 illustrates operation in Node B in accordance with the present invention. In step 1200, the Node B channel-decodes the buffer state transmitted by the UE. In step 1202, the Node B performs a CRC check on the channel decoded buffer state and moves to step 1204. In step 1204, the Node B determines whether the UE transmits a buffer state by using a result of performing a CRC check on the buffer state. If the UE transmits the buffer state as a result of the determination, the process proceeds to step 1206. If the UE does not transmit the buffer state, the process moves to step 1208. In step 1208, the Node B moves to the next scheduler transmission number.

In step 1206, the Node B performs CSI channel decoding, and then moves to the next scheduling transmission number in step 1210. In step 1212, the Node B channel-decodes the buffer state transmitted by the UE. In step 1214, the Node B performs a CRC check on the channel decoded buffer state and moves to step 1216. In step 1216, the Node B estimates the buffer status of the UE by using the previously received buffer status and the amount of received data known from the E-TFRI. That is, the difference in the received data amount known from the E-TFRI in the previously received buffer state becomes the buffer state of the UE. In step 1218, the Node B determines whether the buffer state estimate of the UE estimated in step 1216 has a value greater than or equal to the threshold. If the buffer state estimate of the UE has a value greater than or equal to the threshold, the determination proceeds to step 1220. If the buffer state estimate of the UE has a value less than or equal to the threshold, the operation proceeds to step 1224 and a release scheduling message is sent to the UE. Send it. In step 1226, the Node B transmitting the scheduling release message determines whether to continue the uplink packet transmission service. As a result of the determination, if the uplink packet transmission service continues, the flow moves on to step 1228 and moves to the next scheduling transmission number. If it is determined that the uplink packet transmission service is stopped, the procedure ends.

In step 1220, the Node B determines whether the CSI is received. The CSI reception point is delivered from the RNC. If it is determined that the CSI is received, the method proceeds to step 1222 and performs a channel decoding process on the received CSI, and then moves to step 1210. If the result of the determination, the procedure moves to step 1210.

<Second Embodiment>

13 illustrates signaling between a Node B and a UE according to a second embodiment of the present invention. Hereinafter, the terms shown in FIG. 13 will be described first. remind Denotes the scheduling interval length. Denotes a scheduling transmission number. Means transmission period of CSI, Means the transmission period of buffer status.

In the scheduling transmission number 10 1300, the amount of packet data to be transmitted to the Node B by the UE exceeds a threshold. Accordingly, the UE transmits a buffer state and CSI to the Node B. The Node B transmits scheduling allocation information to the UE using the buffer state and the CSI received at 1300. Of course, the Node B does not transmit the scheduling allocation information in units of a scheduling interval length, but determines whether to transmit the scheduling allocation information in consideration of the ROT.

In scheduling transmission number 14, the UE transmits only the CSI to the Node B. The transmission period of the CSI is received from the RNC. Accordingly, the UE transmits the CSI to the Node B according to the CSI transmission period received from the RNC. In FIG. 8, in the transmission transmission numbers 10, 14, 18, 22, and 26, the UE transmits the CSI to the Node B. The buffer state is not transmitted since the UE can estimate the buffer state of the UE using the buffer state received in the scheduling transmission number 10 and the amount of packet data transmitted in the interval after the scheduling transmission information 10. This is as described in Equation 2 above.

However, in scheduling transmission numbers 13 and 16, packet data to be transmitted to the Node B is newly generated in the EUDCH data buffer of the UE. It is impossible for the Node B to estimate the packet data generated in the scheduling transmission number 15 by Equation (2). Accordingly, the UE transmits a buffer state, which is information about data generated in the scheduling transmission numbers 13 and 16, to the Node B. However, unlike the first embodiment, when a new packet data to be transmitted to the Node B occurs, the packet data is transmitted according to the set buffer state transmission period. That is, the UE transmits the buffer state only when new data to be transmitted to the Node B corresponding to the buffer state transmission period occurs. Therefore, even when it is time to transmit the buffer state, if there is no newly generated packet data in the EUDCH data buffer, the buffer state is not transmitted. 13 shows that the buffer status is transmitted in the scheduling transmission number 18.

The UE that has transmitted the buffer state in the scheduling transmission number 18 determines the transmission format of the packet data using the scheduling allocation information transmitted from the Node B. However, the UE cannot know whether the Node B has received the buffer state transmitted in the scheduling transmission number 18 without error. Accordingly, the UE retransmits the buffer state to the Node B if the scheduling allocation information is not received such that a buffer state transmission period elapses after the buffer state is transmitted. However, Node B should transmit the scheduling assignment information to the UE within the buffer state transmission period after receiving the buffer state. Therefore, only when the Node B does not receive the transmitted buffer state, the UE does not receive the scheduling assignment information. FIG. 13 shows that the buffer status is retransmitted to the Node B in the scheduling transmission number 26. However, when the buffer status retransmission time elapses when the buffer state is first transmitted, the UE transmits CSI information along with retransmission of the buffer state.

In step 1318, the Node B determines that the amount of packet data to be transmitted by the UE is less than or equal to a threshold and transmits a unscheduling message to the UE. Upon receiving the unscheduling message, the UE stops transmitting the buffer state and the CSI to the Node B. In addition, the UE stops the buffer state and CSI transmission to the Node B when the amount of packet data waiting in the EUDCH data buffer is less than a threshold.

14 illustrates a structure of an EUDCH transmission controller of a UE according to the second embodiment of the present invention. Only the buffer state and the CSI transmission time determiner which are different in function from those shown in FIG. 9 among the elements shown in FIG. 14 will be described.

The buffer state, the CSI transmission time determiner 1404 determines the buffer state, the buffer state determined by the CSI transmission start and end determiner 1402, and the buffer state and the CSI transmission time after the CSI transmission start time. The buffer status and CSI transmission time point are as described with reference to FIG. 13. The buffer state, CSI transfer time determiner 1404 turns on the buffer state transfer switch 1406 and the CSI transfer switch 1412 at the buffer state and the transfer start time of the CSI. The buffer state, the CSI transmission time determiner 1404 transmits the CSI at the start time of the CSI transmission Wow The CSI transmission switch 1412 is turned on to periodically transmit the CSI at the scheduling transmission number determined by. The buffer state, the CSI transmission time determiner 904, when a new data arrival indication indicates that new data has occurred in the data buffer of the UE, taking into account the buffer state transmission period, the buffer state transfer switch ( 1406). That is, the buffer state transfer switch 1406 is turned on to transmit the buffer state in the buffer state transfer period that appears first after the data generation indicator indicates that new data has been generated in the data buffer of the UE.

After transmitting the buffer state for the newly generated packet data, the buffer state transfer switch 1406 is turned on if the scheduling allocation information has not been received from the scheduling assignment information receiving indicator during the buffer state transmission period. In addition, if the scheduling allocation information is not received during the buffer state transmission period after the buffer state is first transmitted to the Node B, the CSI transfer switch 1412 is also turned on at the same time.

15 illustrates an operation at the UE transmitting end according to the second embodiment of the present invention. In step 1500, the UE observes the buffer status. The buffer state observation observes the amount of packet data stored in the EUDCH data buffer. In step 1502, the UE determines whether packet data stored in the EUDCH data buffer exceeds a threshold. If the amount of packet data stored in the EUDCH data buffer exceeds the threshold, the determination proceeds to step 1006. If the amount of packet data stored in the EUDCH data buffer does not exceed the threshold, the procedure proceeds to step 1504. Move. In step 1504, the UE moves to the next scheduling transmission number and observes the EUDCH data buffer.

In step 1506, the UE transmits the buffer state and the CSI, and moves to step 1508. In step 1508, the UE moves to the next scheduling transmission number, and in step 1510, the UE observes the EUDCH data buffer. In step 1512, the UE determines whether to continue transmitting the buffer state and the CSI. The determination is made by comparing the threshold with the packet data stored in the EUDCH data buffer as described above. If it is determined that the buffer state and the CSI are continuously transmitted, the process proceeds to step 1514. If it is determined that the buffer state and the CSI transmission are stopped, the process proceeds to step 1528. In step 1528, the UE determines whether to continue the reverse packet transmission service. If it is determined that the reverse packet transmission service continues, the process moves to step 1530 and then observes the next scheduling transmission number. If the reverse packet transfer service does not continue, the procedure ends.

In step 1514, the UE determines whether it is time to transmit a buffer state. If the determination result transfers to the buffer state, the process moves to step 1516, and if the determination result transfers to the step 1524. In step 1516, the UE determines whether new data is generated in the EUDCH data buffer. If new data has been generated in the EUDCH data buffer as a result of the determination, the process proceeds to step 1518. If new data has not occurred in the EUDCH data buffer, the process proceeds to step 1520. In step 1520, the UE determines whether the buffer state is transmitted at the time of transmitting the previous buffer state. If it is determined that the buffer state is transmitted at the time of the previous buffer state transmission, the determination proceeds to step 1522. If the buffer state is not transmitted at the time of the previous buffer state transmission, the process proceeds to step 1524. In step 1522, the UE determines whether the scheduling allocation information has been received. If it is determined that the scheduling allocation information has been received, the procedure proceeds to step 1524. If the scheduling result has not been received, the procedure proceeds to step 1518.

 In step 1518, the UE transmits a buffer state. Although not shown in step 1518, if the scheduling allocation information is not received within the buffer state transmission period after the first buffer state is transmitted, the CSI is transmitted simultaneously with the buffer state. In step 1524, the UE determines whether it is time to transmit CSI. The CSI transmission time point is transmitted from the RNC. If it is determined that the CSI is transmitted, the procedure proceeds to step 1526, after transmitting the CSI, to step 1508. If it is determined that the CSI is not transmitted, the process moves to step 1508.

16 shows a reception device of a Node B according to the present invention. Hereinafter, a reception device of a Node B according to the present invention will be described with reference to FIG. 16. The antenna 1600 receives a signal transmitted by the UE and transmits the signal to the RF unit 1602. The RF unit 1602 converts the received signal into a baseband signal and transfers the signal to a pulse generator 1604. The pulse former 1604 delivers the transmitted baseband signal to the scrambler 1606. The scrambler 1606 descrambles the scrambling code. The descrambled signal is passed to the demultiplexer 1612 after passing through the despreader 1608 and the channel compensator 1610. The demultiplexer 1612 separates the transmitted signal into a buffer state, CSI, and E-TFRI.

The buffer state separated from the demultiplexer 1612 is transferred to the buffer state channel decoding unit 1622 for channel decoding. The channel decoded buffer state checks CRC at CRC detector 1624. The CRC detector 1624 transfers the CRC detection result value to the buffer state and the CSI reception point controller 1632. The buffer status and the CSI reception time controller 1632 determines whether the buffer status is transmitted from the UE by using the transferred CRC result value. If it is determined that the buffer status is transmitted from the UE, the buffer status and the CSI receiving time controller 1632 turns on the CSI receiving switch 1618. In addition, when the buffer state is first received, the buffer state and the CSI reception point controller 1632 Wow Determine the reception time of CSI using. At the determined CSI reception time, the CSI reception switch 1618 is turned on. The buffer state and the CSI reception point controller 1632 Wow Determines when to receive the buffer state using. At the time of receiving the determined buffer state, the buffer state receiving switch 1634 is turned on. However, as described above, the buffer status is not always received at the time of receiving the determined buffer status, but the buffer status is received only when a new event occurs in the EUDCH data buffer of the UE. In addition, when the UE, which has transmitted the buffer state because the new event occurs, does not receive the scheduling allocation information, transmits the buffer state in the subsequent buffer state transmission period. Accordingly, the Node B may receive a buffer state at this point. The CSI channel decoder 1620 channel-decodes the CSI transmitted from the demultiplexer 1612. The E-TFRI channel decoder 1614 channel-decodes the E-TFRI transmitted from the demultiplexer 1612 and then transfers the E-TFRI to the E-TFRI CRC detector 1616.

The EUDCH data decoding unit 1626 decodes EUDCH data received from the UE using the E-TFRI. The EUDCH scheduler 1628 generates scheduler allocation information to be transmitted to the UE by using the CSI transmitted from the CSI channel decoding unit 1620 and the buffer state transferred from the buffer state CRC detector 1624. The UE buffer state estimator 1630 estimates the buffer state of the UE by using the E-TFRI output from the E-TFRI CRC detector 1616 and the buffer state transferred from the buffer state CRC detector 1624. The buffer state estimate of the UE is passed to the buffer state and the CSI reception point controller 1632. The buffer state and CSI reception point controller 1632 transmits a unscheduling message to the UE when the buffer state estimate is less than a threshold. The UE receiving the unscheduling message stops the buffer state and CSI transmission.

17 shows operation in Node B according to the second embodiment of the present invention. In step 1700, the Node B channel decodes the buffer state transmitted by the UE. In step 1702, the Node B performs a CRC check on the channel decoded buffer state and moves to step 1704. In step 1704, the Node B determines whether the UE transmits a buffer state by using a result of performing a CRC check on the buffer state. If the UE transmits the buffer state as a result of the determination, the process moves to step 1706. If the UE does not transmit the buffer state, the process moves to step 1708. In step 1708, the Node B moves to the next scheduler transmission number.

In step 1706, the Node B performs CSI channel decoding and then moves to the next scheduling transmission number in step 1710. In step 1712, the Node B estimates the buffer status of the UE by using the previously received buffer status and the amount of received data known from the E-TFRI. That is, the difference in the received data amount known from the E-TFRI in the previously received buffer state becomes the buffer state of the UE. In step 1714, the Node B determines whether the buffer state estimate of the UE estimated in step 1712 has a value greater than or equal to the threshold. If the result of the determination indicates that the buffer state estimate of the UE has a value greater than or equal to the threshold, the operation proceeds to step 1716. If the determination result of the determination indicates that the buffer state estimate of the UE has a value less than or equal to the threshold value, the operation proceeds to step 1718 and the release scheduling message to the UE. Send it. In operation 1720, the Node B transmitting the scheduling release message determines whether to continue the uplink packet transmission service. As a result of the determination, if the uplink packet transmission service is continued, the process moves to step 1722 and moves to the next scheduling transmission number. If it is determined that the uplink packet transmission service is stopped, the procedure ends.

In step 1716, the Node B determines whether it is time to receive a buffer state. If it is determined that the buffer state is received at operation point, the process proceeds to step 1724, and if it is determined that the buffer state is received at operation time, the process moves to step 1728. In step 1724, the Node B performs a channel decoding process on the buffer state and moves to step 1726. In step 1726, the Node B checks a CRC for a buffer state in which a channel decoding process is performed. By checking the CRC for the buffer state, it is possible to recognize whether or not the actual buffer state has been received. In step 1728, the Node B determines whether the CSI is received. The CSI reception point is delivered from the RNC. If it is determined that the CSI is received, the controller proceeds to step 1730 and performs a channel decoding process on the received CSI, and then moves to step 1710. If the determination result, the controller moves to step 1710.

<Third Embodiment>

In the third embodiment, in order to prevent the amount of uplink interference due to the uplink signaling, the RNC controls the buffer state transmitted by each UE and the transmission time of the CSI. To this end, the RNC controls the UE to transmit the buffer status and the CSI at different transmission time points (scheduled transmission numbers) for each UE. Equation 3 below shows a buffer state transmission time of the UE, and Equation 4 below shows CSI transmission time of the UE.

remind Is an identification code indicating a scheduling transmission section by number. remind Is an integer, and different values are set for each UE in order to prevent the buffer state from being transmitted from each UE at the same time and increasing the ROT at a specific time. Accordingly, the UE transmits the buffer state to the Node B at a time (scheduled transmission number) set for the UE. remind Is an integer and sets a different value for each UE in order to prevent CSI from each UE being transmitted at the same time and increasing the ROT at a specific time. Accordingly, the UE transmits the CSI to the Node B at a time (scheduled transmission number) set for the UE.

In the third embodiment, even if packet data waiting in the EUDCH data buffer exceeds a threshold, the buffer status is transmitted in the transmission section determined by Equation (3). In addition, the Node B can efficiently use Node B's limited hardware equipment by sharing it with multiple UEs by checking whether the buffer status is received only at the time of receiving the buffer status.

18 illustrates signaling between a Node B and a UE according to a third embodiment of the present invention. In FIG. 18, the buffer state transmission period is 6 ms scheduling interval length, and the scheduling transmission numbers are 12, 18, and 24. The CSI transmission period is a 4 ms scheduling interval length, and the scheduling transmission numbers are 14, 18, 22, and 26.

In the scheduling transmission number 10 (1800), the amount of packet data to be transmitted to the Node B by the UE exceeds a threshold. However, since the scheduling transmission number 10 is not the buffer status transmission section, the UE waits without transmitting the buffer status. In the scheduling transmission number 12, the UE transmits a buffer state. At the same time the UE transmits CSI. Although the scheduling transmission number 12 is not the CSI transmission interval, the CSI is also transmitted with respect to the buffer state transmitted first. Thereafter, the UE transmits the CSI when the CSI transmission period is reached.

In scheduling transmission number 16, packet data is newly generated in the EUDCH data buffer. However, since the transmission number 16 is not a buffer state transmission point as described above, the transmission number 16 waits, and then transmits the buffer state in the scheduling transmission number 18.

The Node B generates scheduling assignment information using the buffer state and CSI transmitted by the UE, and transmits the generated scheduling assignment information to the UE. However, the UE cannot know that the Node B has received the buffer state transmitted by the scheduling transmission number 18 without error. Accordingly, the UE retransmits the buffer state to the Node B if the scheduling allocation information is not received such that a buffer state transmission period elapses after the buffer state is transmitted. In addition, Node B also transmits the scheduling assignment information to the UE within the buffer status transmission period after receiving the buffer status. FIG. 18 shows that the buffer status is retransmitted to the Node B in the scheduling transmission number 24. However, when the buffer status retransmission time elapses when the buffer state is first transmitted, the UE transmits CSI along with the buffer state retransmission when the scheduling assignment information is not received.

In step 1820, the Node B determines that the amount of packet data to be transmitted by the UE is less than or equal to a threshold and transmits a unscheduling message to the UE. Upon receiving the unscheduling message, the UE stops transmitting the buffer state and the CSI to the Node B. In addition, the UE stops the buffer state and CSI transmission to the Node B when the amount of packet data waiting in the EUDCH data buffer is less than a threshold.

19 shows a transmission structure of a UE according to a third embodiment of the present invention. Hereinafter, the buffer state, the CSI transmission start and end determiner 1902, the buffer state, and the CSI transmission time determiner 1904 of FIG. 19 will be described. Operations performed in other configurations than the above configuration are the same as operations performed in the configurations of FIG. 9.

The buffer state, CSI transmission start and end determiner 902 determines the start time and end time of the buffer state and CSI transmission. The transmission start point of the buffer state may include an input buffer state and a buffer state transmission period, Is determined in consideration of the threshold. The buffer state transfer time after the input buffer state exceeds the threshold becomes the buffer state transfer start point. The CSI transmission start time point is the same as the buffer state transmission start time point. The buffer state and the end point of the CSI transmission are the time points at which the scheduling release message is received from the Node B. In addition, even when the input buffer state is less than or equal to the threshold, the buffer state and the transfer end point of the CSI are provided.

The buffer state, the CSI transmission time determiner 1904 determines the buffer state, the buffer state determined by the CSI transmission start and end determiner 1902, and the buffer state and the CSI transmission time after the CSI transmission start time. The buffer state and CSI transmission time point are as described with reference to FIG. 18. The buffer state, CSI transfer time determiner 1904 turns on the buffer state transfer switch 1906 and the CSI transfer switch 1912 at the buffer state and the transfer start time of the CSI. The buffer state, the CSI transmission time determiner 1904 after transmitting the CSI at the start time of the CSI transmission Wow , The CSI transmission switch 1912 is turned on to periodically transmit the CSI at the scheduling transmission number determined by. The buffer state, the CSI transmission time determiner 1904 transmits the buffer state in the buffer state transmission period after a new data arrival indication indicates that new data has occurred in the data buffer. The state transfer switch 1906 is turned on. The buffer state transmission period is Wow , Determined by The buffer state, CSI transmission time determiner 1904 controls the buffer state transfer switch 1906 and the CSI transfer switch 1912 using the scheduling assignment information reception indicator and the buffer state transfer period. After transmitting the buffer state for the newly generated packet data, the buffer state transfer switch 1906 is turned on if the scheduling allocation information is not indicated from the scheduling allocation information receiving indicator during the buffer state transmission period. In addition, if the scheduling allocation information is not received during the buffer state transmission period after the buffer state is first transmitted to the Node B, the CSI transfer switch 1912 is also simultaneously turned on.

20 shows an operation of the UE transmitting end according to the third embodiment of the present invention. In step 2000, the UE determines whether it is time to transmit a buffer state. If it is determined that the buffer state is transmitted, the process moves to step 2002. If it is determined that the buffer state is transmitted, the process moves to step 2004. In step 2002, the UE observes a buffer state. The buffer state observation observes the amount of packet data stored in the EUDCH data buffer. In step 2006, the UE determines whether the packet data stored in the EUDCH data buffer exceeds a threshold. If the amount of packet data stored in the EUDCH data buffer exceeds the threshold, the determination proceeds to step 2008. If the amount of packet data stored in the EUDCH data buffer does not exceed the threshold, the determination proceeds to step 2004. Move. In step 2004, the UE moves to the next scheduling transmission number and observes the EUDCH data buffer.

In step 2008, the UE transmits a buffer state and CSI, and moves to step 2010. In step 2010, the UE moves to the next scheduling transmission number, and in step 2012, the UE observes the EUDCH data buffer. In step 2014, the UE determines whether to continue transmitting the buffer state and the CSI. The determination is made by comparing the threshold with the packet data stored in the EUDCH data buffer as described above. If it is determined that the buffer state and the CSI continue to be transmitted, the process moves to step 2016. If it is determined that the buffer state and the CSI transmission are stopped, the process moves to step 2018. In step 2018, the UE determines whether to continue the reverse packet transmission service. If it is determined that the reverse packet transmission service continues, the process moves to step 2020 and observes the next scheduling transmission number. If the reverse packet transfer service does not continue, the procedure ends.

In step 2016, the UE determines whether it is time to transmit a buffer state. If it is determined that the buffer state is transmitted, the procedure goes to step 2022. If the result of determination determines that the buffer state is transmitted, the procedure goes to step 2030. In step 2022, the UE determines whether new data is generated in the EUDCH data buffer. If new data has been generated in the EUDCH data buffer as a result of the determination, the procedure proceeds to step 2028. If new data has not occurred in the EUDCH data buffer, the procedure proceeds to step 2024. In step 2024, the UE determines whether the buffer status is transmitted at the time of transmitting the previous buffer status. If it is determined that the buffer state has been transmitted at the time of the previous buffer state transmission, the process moves to step 2026. If the buffer state has not been transmitted at the time of the previous buffer state transmission, the process moves to step 2030. In step 2026, the UE determines whether the scheduling allocation information has been received. If it is determined that the scheduling assignment information has been received, the procedure proceeds to step 2030. If the scheduling result has not been received, the procedure proceeds to step 2028.

 In step 2028, the UE transmits a buffer state. Although not shown in step 1518, if the scheduling allocation information is not received within the buffer state transmission period after the first buffer state is transmitted, the CSI is transmitted simultaneously with the buffer state. In step 2030, the UE determines whether it is time to transmit CSI. The CSI transmission time point is transmitted from the RNC. If it is determined that the CSI is transmitted, the procedure proceeds to step 2032 after transmitting CSI to step 2010. If it is determined that the CSI is not transmitted, the process moves to step 2010.

21 shows a reception device of a Node B according to the present invention. Hereinafter, a reception device of a Node B according to the present invention will be described with reference to FIG. 21. The antenna 2100 receives a signal transmitted by the UE and transmits the signal to the RF unit 2102. The RF unit 2102 converts the received signal into a baseband signal and transfers the signal to a pulse generator 2104. The pulse former 2104 delivers the transmitted baseband signal to the scrambler 2106. The scrambler 2106 descrambles the scrambling code. The descrambled signal is transmitted to the demultiplexer 2112 after passing through the despreader 2108 and the channel compensator 2110. The demultiplexer 2112 separates the transmitted signal into a buffer state, CSI, and E-TFRI.

The buffer state separated from the demultiplexer 2112 is transferred to the buffer state channel decoding unit 2122 for channel decoding. The channel decoded buffer state checks CRC at CRC detector 2124. The CRC detector 2124 transmits the CRC detection result value to the buffer state and the CSI reception time controller 2132. The buffer status and the CSI reception time controller 2132 determines whether the buffer status is transmitted from the UE by using the transferred CRC result value. If it is determined that the buffer status is transmitted from the UE, the buffer status and the CSI receiving time controller 2132 turn on the CSI receiving switch 2118. In addition, when the buffer state is first received, the buffer state and the CSI reception point controller 2132 Wow , Determine the reception time of CSI using. At the determined CSI reception time, the CSI reception switch 2118 is turned on. The buffer state and the CSI reception time controller 2132 Wow , Determines when to receive the buffer state using. At the time of receiving the determined buffer state, the buffer state receiving switch 2134 is turned on. However, as described above, the buffer status is not always received at the time of receiving the determined buffer status, but the buffer status is received only when a new event occurs in the EUDCH data buffer of the UE. In addition, when the UE, which has transmitted the buffer state because the new event occurs, does not receive the scheduling allocation information, transmits the buffer state in the subsequent buffer state transmission period. Accordingly, the Node B may receive a buffer state at this point. The CSI channel decoder 2120 channel decodes the CSI transmitted from the demultiplexer 2112. The E-TFRI channel decoder 2114 channel-decodes the E-TFRI transmitted from the demultiplexer 2112 and then transfers the E-TFRI CRC detector 2116.

The EUDCH data decoding unit 2126 decodes EUDCH data received from the UE using the E-TFRI. The EUDCH scheduler 2128 generates scheduler allocation information to be transmitted to the UE using the CSI transmitted from the CSI channel decoding unit 2120 and the buffer state transferred from the buffer state CRC detection unit 2124. The UE buffer state estimator 2130 estimates the buffer state of the UE by using the E-TFRI output from the E-TFRI CRC detector 2116 and the buffer state transferred from the buffer state CRC detector 2124. The buffer state estimate of the UE is passed to the buffer state and the CSI reception point controller 2132. The buffer state and CSI reception point controller 1632 transmits a unscheduling message to the UE when the buffer state estimate is less than a threshold. The UE receiving the unscheduling message stops the buffer state and CSI transmission.

22 illustrates operations in a Node B according to a third embodiment of the present invention. In step 2200, the Node B determines whether it is time to receive a buffer state. If it is determined that the buffer status is received, the procedure goes to step 2202; In step 2202, the Node B channel decodes the buffer state transmitted by the UE. In step 2206, the Node B performs a CRC check on the channel decoded buffer state and moves to step 2208. In step 2208, the Node B determines whether the UE transmits a buffer state by using a result of performing a CRC check on the buffer state. If the UE transmits the buffer state as a result of the determination, the process moves to step 2210. If the UE does not transmit the buffer state, the process moves to step 2204. In step 2204, the Node B moves to the next scheduler transmission number.

In step 2210, the Node B performs CSI channel decoding, and then moves to the next scheduling transmission number in step 2212. In step 2214, the Node B estimates the buffer status of the UE by using the previously received buffer status and the amount of received data known from the E-TFRI. That is, the difference in the received data amount known from the E-TFRI in the previously received buffer state becomes the buffer state of the UE. In step 2216, the Node B determines whether the buffer state estimate of the UE estimated in step 2214 has a value greater than or equal to the threshold. If the determination result of the buffer state of the UE has a value greater than or equal to the threshold, go to step 2218; if the determination of the buffer state of the UE has a value less than the threshold, go to step 2220; Send it. In step 2222, the Node B transmitting the scheduling release message determines whether to continue the uplink packet transmission service. As a result of the determination, if the uplink packet transmission service is continued, the process moves to step 2224 and moves to the next scheduling transmission number. If it is determined that the uplink packet transmission service is stopped, the procedure ends.

In step 2218, the Node B determines whether it is time to receive a buffer state. If it is determined that the buffer state is received at step 2226, the process proceeds to step 2226. In step 2226, the Node B performs a channel decoding process on the buffer state and moves to step 2228. In step 2228, the Node B checks a CRC for a buffer state in which a channel decoding process is performed. By checking the CRC for the buffer state, it is possible to recognize whether or not the actual buffer state has been received. In step 2230, the Node B determines whether it is a CSI reception time. The CSI reception point is delivered from the RNC. If it is determined that the CSI is received, the process proceeds to step 2232 and performs a channel decoding process on the received CSI, and then moves to step 2212. If the CSI is received, the process proceeds to step 2212.

<Fourth Embodiment>

FIG. 23 is a diagram illustrating a transmission period of buffer status and channel state information according to the fourth embodiment of the present invention. That is, the CSI information is transmitted at a predetermined CSI transmission point at regular intervals, and the buffer state is transmitted at a predetermined buffer state transmission point periodically as well as when new data is generated in a buffer of the UE. Accordingly, the signaling process for reducing the delay time for the base station to estimate the UE buffer state is shown.

Referring to FIG. 23, when data above a threshold is generated in a buffer of a UE at 2300, the UE first transmits a buffer state and CSI. At this time, since the buffer state transmission period and the CSI transmission period are set to T _buffer = 8 × T _{sch_int} and T _CSI = 4 × _{sch_int} , respectively, the UE Sends the buffer status at 2308 and 2312 that satisfy the period of The CSI information is transmitted at 2304, 2308, 2310, and 2312 that satisfy the period of. On the other hand, since the buffer state is first transmitted in the 2300 as described above The delay time for estimating the UE buffer state can be reduced by transmitting the UE buffer state not only at the time point determined by the period of time but also at 2302 and 2306 which are the time points when new data is generated in the UE buffer. The base station transmits scheduling assignment information at 2314 and 2316 based on the buffer state and the CSI information received from the UE, and at 2318 determines that there is no data to be transmitted to the buffer of the UE, at this time, a scheduling release message (scheduling release) message) may be sent to the UE.

The UE apparatus for transmitting a buffer state according to the fourth embodiment is the same as that of FIG. 14, and the buffer state, the CSI transmission time determiner 1404 periodically transmits the CSI information at a predetermined time point, and the buffer state is periodically It transmits at a time point or at a time point when new packet data is generated.

In this regard, FIG. 24 illustrates a process of transmitting a buffer state by a UE according to the fourth embodiment and transmitting the buffer state when new data is generated in the buffer of the UE.

Referring to FIG. 24, in step 2400, the UE checks a buffer state. That is, the UE checks the amount of packet data stored in the EUDCH data buffer. In step 2402, it is determined whether the packet data stored in the EUDCH data buffer exceeds a threshold. If it is determined that the amount of packet data stored in the EUDCH data buffer exceeds the threshold, go to step 2406; and if it is determined that the amount of packet data stored in the EUDCH data buffer does not exceed the threshold, proceed to step 2404. Move. In step 2404, the UE moves to the next scheduling transmission number and checks the EUDCH data buffer.

On the other hand, if the amount of packet data stored in the EUDCH data buffer in step 2406 exceeds the threshold, the UE transmits the buffer status and the CSI to the base station, and moves to step 2408. In step 2408, the UE moves to the next scheduling transmission number, and in step 2410, the UE checks the EUDCH data buffer. In step 2412, the UE checks whether to continue transmitting the buffer state and the CSI. This is determined by comparing the threshold with the amount of packet data stored in the EUDCH data buffer as described above. If it is determined that the buffer state and the CSI continue to be transmitted, the process proceeds to step 2414. If it is determined that the buffer state and the CSI transmission are stopped, the process proceeds to step 2424. In step 2424, the UE determines whether to continue the reverse packet transmission service. If it is determined that the reverse packet transmission service continues, the process moves to step 2426 and then observes the next scheduling transmission number. If the reverse packet transfer service does not continue, the procedure ends.

On the other hand, in step 2414, the UE determines whether new data is generated in the EUDCH data buffer. If new data has been generated in the EUDCH data buffer as a result of the determination, the method proceeds to step 2416 if new data has not occurred in the EUDCH data buffer. In step 2418, it is determined whether the current time point is a buffer state transmission time point. If it is determined in the step 2418 that the buffer state transmission time is determined, go to step 2416, and if it is determined that it is not the buffer state transmission time, go to step 2420. In step 2416, the UE transmits a buffer state. In step 2420, the UE determines whether it is time to transmit CSI. The CSI transmission time point is transmitted from the RNC. If it is determined that the CSI is transmitted, the method proceeds to step 2422, and transmits CSI to step 2408. If it is determined that the CSI is not transmitted, the process moves to step 2408. Although not shown in FIG. 24, if the scheduling allocation information is not received from the base station within the buffer state retransmission period after transmitting the buffer state for the first time in step 2406, the UE may transmit the buffer state and the CSI together again.

FIG. 25 is a diagram illustrating a signaling process of determining a buffer state transmission time with a timer according to a fifth embodiment of the present invention. In other words, the UE determines a buffer state transmission time by the provided timer, and transmits the buffer state to reduce the delay time required for the base station to estimate the UE buffer state, and according to the transmission of the buffer state. The signaling process to reduce the amount of additional reverse link interference is shown. Meanwhile, in the case of CSI information, the UE periodically transmits CSI information and minimizes an increase in the amount of uplink interference due to CSI transmission by allowing CSI transmission to be performed at different times for each UE.

Referring to FIG. 25, since the data amount of the UE buffer exceeds a threshold in 2500, the UE transmits the buffer state and the CSI information for the first time. It is decided as. Thereafter, as the scheduling interval progresses, the UE decreases the value of the timer by 1 and transmits the buffer state when the timer becomes 0 or when new data is generated. For CSI information, The CSI information is transmitted at 2504, 2506, 2510, and 2512, which are periodically determined according to the period of. On the other hand, after 2500, when the buffer is first transmitted, A new data is generated at 2502, which is before 2506, the next buffer state transmission time determined according to the UE, and the UE transmits the buffer state at 2502 and sets the timer. Set to. After the UE transmits the buffer state at 2502 The buffer status is transmitted at 2508, which is the time when the timer is determined to be 0. Timer = Set to. Since no new data is generated until the next buffer status 2514, the buffer status is transmitted at 2514, when Timer = 0, and Timer = Set to.

The UE device for transmitting a buffer state according to the fifth embodiment is the same as the device shown in FIG. 14, and the buffer state, the CSI transmission time determiner 1404 periodically transmits CSI information at a predetermined time point, and a timer. The transmission time of the buffer state is controlled according to the operation.

<Fifth Embodiment>

26 illustrates a UE procedure according to the fifth embodiment of the present invention.

In step 2600, the UE checks the buffer status. In this case, the buffer status check means that the UE checks the amount of packet data stored in the EUDCH data buffer. In step 2602, the UE determines whether the packet data stored in the EUDCH data buffer exceeds a threshold. If it is determined that the amount of packet data stored in the EUDCH data buffer exceeds the threshold, go to step 2606; and if it is determined that the amount of packet data stored in the EUDCH data buffer does not exceed the threshold, proceed to step 2604. Move. In step 2604, the UE moves to the next scheduling transmission number and observes the EUDCH data buffer.

In step 2606, the UE transmits the buffer state and the CSI, and moves to step 2608. In step 2608, the UE has a timer = Set to. In step 2610, the UE moves to the next scheduling transmission number, and in step 2612, the UE checks the EUDCH data buffer. In step 2614, the UE determines whether to continue transmitting the buffer state and the CSI. The determination is made by comparing the threshold with the packet data stored in the EUDCH data buffer as described above. If it is determined that the buffer state and the CSI continue to be transmitted, the process moves to step 2616. If it is determined that the buffer state and the CSI transmission are stopped, the process moves to step 2630. In step 2630, the UE determines whether to continue the reverse packet transmission service. If it is determined that the reverse packet transmission service continues, the process moves to step 2632 and then observes the next scheduling transmission number. If the reverse packet transfer service does not continue, the procedure ends.

In step 2616, the UE sets Timer = Timer-1, that is, decreases the Timer value by 1, and then moves to step 2618. In step 2618, the UE determines whether new data is generated in the EUDCH data buffer. If new data is generated in the EUDCH data buffer as a result of the determination, the process proceeds to step 2622. If new data does not occur in the EUDCH data buffer, the process proceeds to step 2620. In step 2620, it is determined whether Timer = 0. If it is determined in step 2620 that Timer = 0, the control proceeds to step 2622, and if it is determined that Timer = 0 is not determined, it proceeds to step 2626. After transmitting the buffer state in step 2622, the UE moves to step 2624. In step 2624, the UE indicates Timer = After that, go to step 2626. In step 2626, the UE determines whether it is time to transmit CSI. The CSI transmission time point is transmitted from the RNC. If it is determined that the CSI is transmitted, the procedure proceeds to step 2628, after transmitting the CSI, to step 2610. If it is determined that the CSI is not transmitted, the process moves to step 2610. Although not shown in FIG. 26, if the scheduling assignment information is not received from the base station within the buffer state retransmission period after transmitting the buffer state for the first time in step 2606, the UE may transmit the buffer state and the CSI together again. In addition, the base station apparatus according to the fifth embodiment is the same as FIG.

The above-described embodiments describe a process of transmitting CSI information at regular intervals regardless of the transmission time of the buffer state. In this case, considering that the temporary channel change due to fading phenomenon is overcome by the power control in the CDMA system, the base station control scheduling may be long-time fading such as shadowing due to a geographical effect. term fading, that is, in the above case, the CSI should represent the average channel condition for a long time.

<Sixth Embodiment>

FIG. 27 is a sixth embodiment of the present invention and shows channel encoding in order to transmit the buffer state and the channel state information at the time of transmission of the buffer state.

Referring to FIG. 27, when the CSI information indicates an average channel condition for a long time as described above, it is not necessary to periodically transmit CSI information. Accordingly, the buffer state and the CSI information may be transmitted together at the time of transmitting the buffer state. This is to transmit the CSI information together with the buffer status at the time when the buffer status and the CSI information are first transmitted, and then the buffer status is transmitted to the base station.

Accordingly, the base station can apply the CRC in common to detect whether the buffer status and the CSI information are transmitted.

That is, when the base station detects whether the buffer state and the CSI information are transmitted, the UE makes one CRC that is commonly applied to the buffer state and the CSI information, and channel-codes the same to transmit one channel. Accordingly, when the base station performs the channel decoding process, the base station recognizes that the buffer state and the CSI information are normally transmitted through a CRC check common to the buffer state and the CSI information.

As described above, when an event occurs in the data buffer after transmitting the buffer state and the CSI, the UE reduces the number of transmissions of the buffer state by transmitting a buffer state to the Node B. In addition, the UE transmits the buffer state to the Node B using a timer, thereby reducing the delay time required for the Node B to estimate the UE buffer state. In addition, when transmitting the buffer state and the CSI information together at the time of transmitting the buffer state, channel coding is applied to apply a common CRC. Accordingly, the signaling overhead for the transmission of the reverse link packet data can be reduced.

1A illustrates a change in a received signal of a base station when base station control scheduling is not used.

1B is a diagram illustrating a change in a received signal of a base station when base station control scheduling is used.

2 shows a user terminal and a base station performing uplink packet transmission.

3 is a diagram illustrating information transmitted and received between a user terminal and a base station to perform uplink packet transmission.

4 is a diagram illustrating a structure of a user terminal for transmitting an uplink packet.

5 is a diagram illustrating a structure of a scheduling control channel and a scheduling control channel of a base station for receiving an uplink packet.

6 is a diagram illustrating a transmission period of buffer status and channel state information for scheduling;

7 is a diagram illustrating channel encoding of a buffer state and CSI transmitted from a UE according to the present invention.

8 is a diagram illustrating a transmission period of buffer status and channel state information according to the first embodiment of the present invention.

9 is a diagram illustrating a transmitter of a user terminal for transmitting an uplink packet according to the first embodiment of the present invention.

10 is a diagram illustrating an operation performed by a transmitter of a user terminal transmitting an uplink packet according to the first embodiment of the present invention.

11 is a diagram illustrating a receiver of a base station for transmitting an uplink packet according to the first embodiment of the present invention.

12 illustrates an operation performed at a receiving unit of a base station transmitting an uplink packet according to a first embodiment of the present invention.

FIG. 13 is a diagram illustrating a transmission period of buffer status and channel state information according to a second embodiment of the present invention. FIG.

14 is a diagram illustrating a transmitter of a user terminal for transmitting an uplink packet according to a second embodiment of the present invention.

15 is a diagram illustrating an operation performed by a transmitting unit of a user terminal transmitting an uplink packet according to a second embodiment of the present invention.

16 is a diagram illustrating a receiving unit of a base station for transmitting an uplink packet according to a second embodiment of the present invention.

17 is a diagram illustrating an operation performed by a receiving unit of a base station transmitting an uplink packet according to a second embodiment of the present invention.

18 is a diagram illustrating a transmission period of buffer status and channel state information according to a third embodiment of the present invention.

19 is a diagram illustrating a transmitting unit of a user terminal for transmitting an uplink packet according to a third embodiment of the present invention.

20 illustrates an operation performed by a transmitter of a user terminal for transmitting an uplink packet according to a third embodiment of the present invention.

21 is a diagram illustrating a receiving unit of a base station for transmitting an uplink packet according to a third embodiment of the present invention.

22 is a diagram illustrating an operation performed by a receiving unit of a base station transmitting an uplink packet according to a third embodiment of the present invention.

FIG. 23 is a diagram illustrating determining a transmission period of buffer status and channel state information according to a fourth embodiment of the present invention. FIG.

24 is a diagram illustrating an operation performed by a transmitter of a user terminal transmitting an uplink packet according to a fourth embodiment of the present invention.

FIG. 25 is a diagram illustrating a timing of transmitting a buffer state with a timer according to a fifth embodiment of the present invention. FIG.

FIG. 26 illustrates an operation performed by a transmitter of a user terminal transmitting an uplink packet according to a fifth embodiment of the present invention. FIG.

FIG. 27 is a diagram of a channel for simultaneously transmitting a buffer state and channel state information according to a sixth embodiment of the present invention. FIG.

Claims (17)

A base station controller, a base station for generating scheduling assignment information using the received buffer state and channel state information, and a user terminal for transmitting the uplink packet data to the base station using the scheduling assignment information transmitted from the base station. In a mobile communication system, the user terminal transmits a buffer state and channel state information of a buffer that stores the packet data, Receiving a channel state information transmission period from the base station controller; Starting transmission of buffer status and channel status information to the base station when data waiting in the buffer exceeds a threshold; After transmitting the buffer state and the channel state information, the updated channel state information is transmitted according to the received channel state information transmission period, and when the new packet data to be transmitted to the base station is transmitted to the buffer, the buffer state is transmitted. The method, characterized in that consisting of a process. The method as claimed in claim 1, wherein after transmitting the buffer state, if the scheduling allocation information is not received during the buffer state retransmission period, the buffer state is retransmitted. 3. The method as claimed in claim 2, wherein the buffer state retransmission period is set longer than the channel state transmission period. 3. The method as claimed in claim 2, wherein the buffer state is transmitted by adding a cyclic redundancy bit for error detection. The method as claimed in claim 1, wherein the transmission of the buffer state and the channel state information is stopped when the packet data waiting in the buffer of the updated buffer is smaller than a threshold. The method as claimed in claim 1, wherein the transmission of the buffer state and the channel state information is stopped when the buffer state and the channel state information transmission are requested from the base station. The method as claimed in claim 1, wherein when the new packet data to be transmitted to the base station is transferred to the buffer, the buffer status is transmitted in a set buffer status transmission period. 8. The method as claimed in claim 7, wherein after transmitting the buffer state, if the scheduling allocation information is not received during the buffer state transmission period, the buffer state is retransmitted. The method as claimed in claim 8, wherein the buffer state transmission period is set longer than the channel state transmission period. A base station controller, a base station for generating scheduling assignment information using the received buffer state and channel state information, and a user terminal for transmitting the uplink packet data to the base station using the scheduling assignment information transmitted from the base station. In a mobile communication system, the user terminal transmits a buffer state and channel state information of a buffer that stores the packet data, Setting a buffer state transmission time and channel state information transmission time according to the information transmitted from the base station controller; Starting the transmission of the buffer state and the channel state information at the set buffer state transmission time point when the data waiting in the buffer exceeds a threshold; After transmitting the buffer state and channel state information, the updated channel state information is transmitted according to the set channel state information transmission time point, and when the new packet data to be transmitted to the base station is transferred to the buffer, the set buffer state transmission time point And transmitting the buffer state in the method. 12. The method as claimed in claim 10, wherein after transmitting the buffer status, the buffer status is retransmitted if the scheduling allocation information is not received until the next buffer status transmission time. A base station controller, a base station for generating scheduling assignment information using the received buffer state and channel state information, and a user terminal for transmitting the uplink packet data to the base station using the scheduling assignment information transmitted from the base station. In a mobile communication system, the user terminal transmits a buffer state and channel state information of a buffer that stores the packet data, Receiving a buffer state transmission period and a channel state information transmission period from the base station controller; Starting transmission of buffer status and channel status information to the base station when data waiting in the buffer exceeds a threshold; After transmitting the buffer state and channel state information, the updated channel state information is transmitted according to the received channel state information transmission period, and when new packet data to be transmitted to the base station is transferred to the buffer, the buffer state and the channel state information are transmitted. The method comprising the step of transmitting the channel status information at the same time. The method as claimed in claim 12, wherein, when new packet data to be transmitted to the base station is transferred to the buffer, error detection information for detecting whether the buffer state and the channel state information is transmitted is added and transmitted. 15. The method of claim 13, wherein when new packet data to be transmitted to the base station is transferred to the buffer, error detection information which is commonly applied to detect whether the buffer state and the channel state information are transmitted is added and transmitted. The method. 15. The apparatus of claim 14, wherein when the new packet data to be transmitted to the base station is transferred to the buffer, one error detection information is commonly applied to detect whether the buffer state and channel state information and the buffer state and channel state information are transmitted. The method as claimed in claim 1, wherein transmission is performed through one channel by adding. A base station controller, a base station for generating scheduling assignment information using the received buffer state and channel state information, and a user terminal for transmitting the uplink packet data to the base station using the scheduling assignment information transmitted from the base station. In a mobile communication system, the user terminal transmits a buffer state and channel state information of a buffer that stores the packet data, Receiving a channel state information transmission period from the base station controller; Starting transmission of buffer status and channel status information to the base station when data waiting in the buffer exceeds a threshold; After the transmission of the buffer state and channel state information, increasing the scheduling assignment information to determine whether to transmit the buffer state and channel state information to the base station; When transmitting the buffer state and the channel state information, the scheduling allocation information is increased to transmit the updated channel state information according to the set channel state information transmission time point, and new packet data to be transmitted to the base station is transmitted to the buffer. And transmitting the buffer state at the time of transmitting the set buffer state. A base station controller, a base station for generating scheduling assignment information using the received buffer state and channel state information, and a user terminal for transmitting the uplink packet data to the base station using the scheduling assignment information transmitted from the base station. In a mobile communication system, the user terminal transmits a buffer state and channel state information of a buffer that stores the packet data, Receiving a channel state information transmission period from the base station controller; Starting transmission of buffer status and channel status information to the base station when data waiting in the buffer exceeds a threshold; Setting a timer after transmitting the buffer state and channel state information; And transmitting the buffer status according to the buffer status transmission time determined by the set timer, and transmitting the updated channel status information according to the received channel status information transmission period.