KR20050018540A - Method for scheduling assignment of uplink packet transmission - Google Patents

Abstract

PURPOSE: A scheduling assign method for uplink packet transmitting is provided to transmit buffer status information necessary for base station control scheduling and CSI(Channel State Information) at different periods, if an amount of standby data in a terminal buffer is more than a threshold value, thereby reducing a signaling overhead. CONSTITUTION: A buffer status, CSI transmission start/end determiner(1202) determines buffer status and start/end times of CSI transmission. A buffer status, CSI transmission time determiner(1204) determines buffer status and CSI transmission times after the first transmission times of buffer status and CSI. When a buffer status transmission switch(1206) is on, the buffer status is attached with a CRC in a CRC attachment unit(1208), and is channel-coded in a channel coding unit(1210). The channel-coded buffer status is inputted to a multiplexer(1212). An EUDCH(Enhanced Uplink Dedicated CHannel) transport format determiner(1218) determines a transport format of packet data by using scheduling assign information.

Description

Scheduling Assignment 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 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. The reception performance of the Node B is degraded as the amount of the interference signal for the uplink signal transmitted by the specific UE increases. 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.

ROT = I_o / N_0

I_0 is the total received broadband power spectral density of the Node B, and N_0 represents the thermal noise power spectral density of the 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 EUDCHdpt Node B scheduling is used. 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. Information on the status of the uplink channel includes uplink transmission power and transmission power margin.

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 factor (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 a terminal buffer state, CSI, etc. 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 allocates the same to the 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 a chip rate using an OVSF code in a multiplier 432, and in a multiplier 434. Multiplied by the channel gain. The summer 436 adds the input control information of the DPCCH and the control information of the HS-DPCCH and allocates the same to the Q channel. The output of summer 436 is multiplied by imaginary number in multiplier 438 and then passed to summer 420.

The summer 420 transfers the output of the summer 426, the output of the multiplier 418, and the output of the multiplier 438 to the multiplier 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 shaper 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 transmitted to the UE through the antenna 528 via the RF 526.

  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 must transmit the buffer status information and the CSI at a predetermined time interval (scheduling interval length: T_ "sch_int") every time in order to receive scheduling allocation information from the Node B.

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 status information and the CSI transmitted from the UE, and includes the determined maximum data rate in scheduling allocation information to notify the UE at interval 610. . 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 status information and the CSI at a scheduling interval length interval as shown in the sections 602 to 606. After the interval 606, since the UE has transmitted all the packet data stored in the EUDCH data buffer, the transmission of the buffer status information and the CSI is stopped. In addition, the Node B does not transmit the scheduling allocation information when the ROT condition is not met even though the buffer status information and the CSI are received from the UE.

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 status information and the CSI to the Node B at every scheduling transmission interval interval. By transmitting the buffer status information and the CSI at each scheduling transmission interval interval, uplink signaling causes an overload, which causes the efficiency of uplink packet transmission to be impaired. Thus, an efficient scheduling scheme that can prevent overloading 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 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 the mobile communication system consisting of a user terminal for transmitting to the base station, the method for transmitting the buffer state and channel state information of the buffer in which the user terminal stores the packet data, the method comprising: different buffer state transmission period from the base station controller and Receiving the channel state information transmission cycle, 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 transmitting the buffer state and the channel state information. After starting, the received buffer status transmission period and The updated buffer status and channel status information are transmitted according to a null status information transmission period.

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 a mobile communication system comprising a user terminal for transmitting to the base station, the base station transmits scheduling allocation information using the received buffer status and channel status information, the buffer status receiving period and channel different from the base station controller Receiving a status information receiving period, generating scheduling allocation information using the buffer state and channel state information first received from the user terminal, transmitting the generated scheduling allocation information, and the buffer state and channel After receiving the status information, the delivery Is characterized by an constituted by any method comprising the steps of: receiving the updated buffer status and channel status information in accordance with the buffer status information transmission period and the channel state information transmission period.

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 a mobile communication system consisting of a user terminal for transmitting to the base station, in the method for transmitting the scheduling assignment information from the base station using the buffer state and the channel state information of the buffer for storing the packet data transmitted from the user terminal Receiving, by the user terminal and the base station, different buffer state transmission periods and channel state information transmission periods from the base station controller; and when the data waiting in the buffer exceeds a threshold, the buffer state and the channel state to the base station. To initiate the transfer of information Transmitting the updated buffer state and channel state information according to the received buffer state transmission period and channel state information transmission period after starting transmission of the buffer state and channel state information; Generating scheduling allocation information by using the received buffer state and channel state information, transmitting the generated scheduling allocation information, and after receiving the buffer state and channel state information, transmitting the received buffer state And receiving the updated buffer status and channel status information according to the 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.

In the present invention, the buffer state transmitted from the UE to the Node B and the transmission period of the CSI is set differently, and the buffer state and the CSI are transmitted according to the set transmission period. The RNC sets the buffer state and the CSI transmission period differently in consideration of the quality of service required for the EUDCH service, the uplink ROT situation, and the handover of the UE. The reason for setting the buffer state and the CSI transmission period differently will be described with reference to FIG. 7.

FIG. 7 illustrates a process in which a UE located in a handover region transmits packet data using an EUDCH. In general, a UE located in the handover region transmits data to active Node Bs. The active Node Bs receive data transmitted from the UE and demodulate the received data. The active Node B demodulating the received data among the Active Node Bs without error may transmit the demodulated data to the RNC to obtain a macro selection diversity gain.

The UE receives three power control commands (TPCs) from the active Node Bs. The UE decreases the value of the transmission power when a command to lower the transmission power is transmitted to any one of the three TPCs. In addition, the UE increases the transmission power only when a command to increase transmission power of all three TPCs is transmitted. Equation 2 below is an equation for estimating the transmission power of the UE in the Node B.

Transmit "_power" "_ est" = CSI "_prev" + power "_control" "_ step_size" ㅧ (up "_count" -down "_coumt")

The Transmit "_power" "_est" is an estimate of the transmission power of the UE, the CSI "_prev" is the transmission power information of the UE previously received. The up " _count " represents the number of times commanding to increase the transmission power, and the down " _coumt " represents the number of times commanding to decrease the transmission power. The power " _control " " _step_size " represents an amount of transmission power that is decreased or increased by one command. As shown in Equation 2, the Node B uses a command regarding the transmit power of the previously received UE and the transmit power commanded by the Node B after the previously received UE transmit power. Estimate.

However, when the UE is in the handover region, the UE converts the power control command transmitted by the plurality of active Node Bs into one power control command and adjusts the transmission power according to the converted power control command. Since the specific active Node B cannot know the power control commands transmitted by the other active Node Bs, it is impossible to estimate the transmission power of the UE as shown in Equation 2 above. For the above reason, in order for the active Node B to accurately estimate the transmission power of the UE in the handover region, the UE should shorten the transmission period of the CSI. If the UE sets a long CSI transmission period, the active Node B cannot accurately estimate the transmission power of the UE. Equation 3 below is an equation for estimating a buffer state of the UE in an active Node B.

Buffer "_state" "_ est" = Buffer "_state" "_ prev &quot;-Data" _sent "

The Buffer "_state" "_ est" is a buffer state estimation value and the Buffer "_state" "_ prev" is a previously received buffer state value. The Data " _sent " means the amount of data received after the previous buffer status value. In the estimation of UE buffer status using E-TFRI, an error may occur, 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 this reason, the buffer state transmission period may be longer than the CSI transmission period. If a shorter transmission period is set for the buffer state transmission period and the CSI transmission period, it causes overhead in uplink signaling.

8 illustrates a process of setting the buffer state transmission period and the CSI transmission period in the RNC. Hereinafter, a process of setting the buffer state transmission period and the CSI transmission period according to the present invention will be described with reference to FIG. 8.

In step 800, the RNC determines a buffer status transmission period in consideration of ROT conditions and quality of service (QoS) required for EUCDH service. In step 802, the RNC determines whether the UE is located in the handover area. If the UE is located in the handover area as a result of the determination, go to step 804; and if the UE is not located in the handover area, go to step 806 if the UE is located in the handover area.

In step 804, the RNC sets the CSI transmission period to the scheduling interval length. In step 806, the RNC calculates a CSI transmission period T_CSI as shown in Equation 4 below.

T_CSI = (P_ {e, E-TFRI} / P_ {e, TPC}) ㅧ T_buffer

(A) is a maximum integer less than or equal to A. P_ {e, E-TFRI} is a reception error rate of E-TFRI, and P_ {e, TPC} is a reception error rate of a power control command transmitted to the UE. As shown in Equation 4, the CSI transmission period is set according to the reception error rate of the E-TFRI and the reception error rate of the power control command transmitted to the UE. The RNC transmits the determined buffer state transmission period (T_buffer) and the CSI transmission period to the UE using an RRC signaling message, and transmits to the Node B using NBAP signaling.

The method for setting the buffer state transmission period and the CSI transmission period described above has been described taking an example in which the buffer state transmission period is longer than the CSI transmission period. However, 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 has a long term fading such as shadowing due to the geographic influence. This may be achieved in consideration of a phenomenon, that is, a change in the average channel condition for a long time. In this case, the CSI information is transmitted in consideration of the average channel situation for a long time.

As described above, when the CSI information indicates an average channel condition for a long time, the buffer state transmission period and the CSI transmission period may set the CSI transmission period longer than the buffer state transmission period as another example of the present invention. Do.

9 is a diagram illustrating channel encoding of a buffer state and CSI transmitted from a UE. As shown in FIG. 9, the buffer state and the CSI are transmitted during one scheduling interval length. 9, the one scheduling interval length is set to 10 ms. In order to different the buffer state transmission period and the CSI transmission period, channel encoding is performed on the buffer state and the CSI in separate processes. 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 buffer status information has been transmitted through the CRC check. Since the CSI is transmitted at the rear end of the buffer state, the reception of the CSI can be determined by the reception of the buffer state.

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

1. The UE sends 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 buffer state and the CSI transmission according to a set transmission period (transmission period transmitted by the RNC to the UE). As described above, the buffer state and the transmission period of the CSI may vary according to the transmission period notified by the RNC.

3. The UE checks the EU-SCHCCH whether scheduling allocation information is transmitted from Node B after transmitting the buffer status and the CSI.

4. The UE stops the buffer state and 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 in the same scheduling transmission section is received.

2. When the Node B first receives the buffer state and the CSI, the Node B detects the buffer state and the CSI according to a set reception period (the reception period transmitted by the RNC to the Node B). As described above, the reception period of the buffer state and the CSI may vary according to the transmission period notified by the RNC. The scheduling allocation information is generated using the received buffer state and the CSI.

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 3, 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 the buffer state and CSI transmission retransmits the buffer state information because the packet data stored in the EUDCH data buffer exceeds a threshold for scheduling. CRC check is performed.

10 illustrates an example of signaling for transmitting and receiving scheduling allocation information between a UE and a Node B according to the present invention. At 1010 (CNT_ "sch_int" = 10), the UE transmits the buffer state and the CSI to the Node B because the amount of packet data stored in the EUDCH data buffer exceeds a threshold for scheduling. The UE periodically transmits the buffer state and the CSI to the Node B after the 1010. As shown in FIG. 10, the transmission period of the buffer state is different from the transmission period of the CSI. The transmission period of the buffer state is 8ms scheduling interval length (T_ "sch_int"), and the transmission period of the CSI is 4ms scheduling interval length.

When the Node B receives the buffer state and the CSI transmitted in 1010, the Node B receives the buffer state and the CSI transmitted by the UE according to the buffer state and the CSI reception period transmitted from the RNC. In addition, when the Node B receives the buffer state and the CSI transmitted in step 1010, the Node B transmits scheduling allocation information to the UE at 1000 in consideration of the ROT situation. The Node B transmits scheduling allocation information to the UE at 1002 using CSI transmitted by the UE at 1012, buffer state and CSI transmitted by the UE at 1014.

The Node B does not transmit scheduling assignment information to the UE if it is determined by Equation 3 that the UE has transmitted all the packet data stored in the EUDCH data buffer. In addition, when the Node B uses the unscheduling message, it notifies the UE that scheduling allocation information is no longer transmitted to the UE as in 1004. Upon receiving the unscheduling message, the UE stops buffering and transmitting CSI to the Node B. The Node B transmitting the unscheduling message performs a CRC check on the buffer status to determine whether a new buffer status is transmitted from the UE.

If the Node B does not use the scheduling assignment message, the UE stops transmitting the buffer state and the CSI to the Node B when the packet data stored in the EUDCH data buffer falls below the threshold.

The buffer state and the CSI are transmitted. The buffer state and the CSI are not determined based on the first transmitted buffer state, and the transmission period of the CSI is not determined. Determine the transmission period of CSI. Equation 5 below is a formula for determining the transmission time of the buffer state, and Equation 6 below is a formula for determining the transmission time of the CSI.

(CNT_ "sch_int" -offset_buffer) mod (T_buffer / T_ "sch_int") = 0

(CNT_ "sch_int" -offset_CSI) mod (T_CSI / T_ "sch_int") = 0

The CNT_ "sch_int" represents a number of scheduling transmission intervals. The offset_buffer is an integer and sets a different value for each UE in order to prevent an increase in the ROT at a specific time by transmitting a buffer state from each UE at the same time. Accordingly, the UE transmits the buffer status to the Node B at a time set for the UE (a scheduling transmission interval number). The offset_CSI is an integer and sets a different value for each UE in order to prevent the CSI from being transmitted from each UE 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 interval number) set for the UE.

11 illustrates a method of determining a buffer state and a transmission time for transmitting CSI according to the present invention. In FIG. 11, offset_buffer and offset_CSI are set to zero. The transmission period of the buffer state is 8 ms scheduling interval length, and the transmission period of the CSI is 4 ms scheduling interval length. In Equation 5, the transmission time of the buffer state is 16, 24, and Equation 6 indicates that the CSI is 12, 16, 20, 24, 28. The UE transmits the CSI at 1105, 1106, 1107, 1108, and 1109 after transmitting the buffer state and the CSI at 1104. In addition, the UE transmits the buffer status information at 1106 and 1108.

12 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. 12.

The buffer status, CSI transmission start and end determiner 1202 determines the start time and end time of the buffer status and CSI transmission. The buffer state and the CSI transmission time point are determined by comparing the input buffer state with a threshold value. When the input buffer state (amount of packet data stored in the EUDCH data buffer) exceeds the threshold value, 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. Further, even when the input buffer state is less than or equal to the threshold value, the buffer state and the end point of the CSI become the end point.

The buffer state, the CSI transmission time determiner 1204 determines the buffer state, the buffer state determined by the CSI transmission start and end determiner 1202, and the buffer state and the CSI transmission time after the initial transmission time of the CSI. The buffer status and the CSI transmission time point are described with reference to FIGS. 10 and 11. As described above, the buffer status and the CSI transmission time point are transmitted from the RNC. The buffer state, CSI transfer time determiner 1204 turns on the buffer state transfer switch 1206 at the determined buffer state transfer time. The buffer state, the CSI transmission time determiner 1204 turns on the CSI transmission switch 1214 when the determined CSI transmission time.

When the buffer state transfer switch 1206 is turned on, the buffer state is channel coded by the channel coding unit 1210 after the CRC is added by the CRC adding unit 1208. The channel coded buffer state is input to a multiplexer 1212. When the CSI transmission switch 1214 is turned on, the CSI is channel coded by the channel coding unit 1216 and then input to the multiplexer 1212. The EUDCH transmission format determiner 1218 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 factor (E-TFRI) determined by the EUDCH transmission format determiner 1218 is channel coded by the channel coding unit 1222 after the CRC is added by the CRC adding unit 1220. The channel coded transmission format factor is input to the multiplexer 1212. The multiplexer 1212 transmits the input buffer status, the CSI, and the transmission format factors to the EUDPCCH. The EUDCH packet transmitter 1224 transmits the packet data stored in the EUDCH data buffer using the transmission format determined by the EUDCH transmission format determiner 1218.

13 illustrates an operation at the UE transmitting end according to the present invention. In step 1300, the UE observes the buffer status. The buffer state observation observes the amount of packet data stored in the EUDCH data buffer. In step 1302, 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 1306; and if it is determined that the amount of packet data stored in the EUDCH data buffer does not exceed the threshold, it is 1304. Go to step. At 1304, the UE moves to the next scheduling transmission interval number and observes the EUDCH data buffer.

In step 1306, the UE transmits the buffer state and the CSI, and moves to step 1308. In step 1308, the UE moves to the next scheduling transmission interval number. In step 1310, the UE observes the EUDCH data buffer. In step 1312, the UE determines whether to continue transmitting the buffer state and the CSI. The determination is made by comparing the threshold value 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 proceeds to step 1314. In step 1322, 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 1324 and then observes the next scheduling transmission interval number. If the reverse packet transfer service does not continue, the procedure ends.

In step 1314, the UE determines whether it is time to transmit a buffer state. The buffer status transfer time is transmitted from the RNC. Therefore, it is determined whether the buffer status transmission time transmitted from the RNC coincides with the scheduling transmission interval. If the buffer state transmission time and the scheduling transmission section are identical as a result of the determination, the process moves to step 1316, and if the buffer state transmission time and the scheduling transmission section do not match, the process moves to 1318. In step 1316, the UE transmits the buffer status and moves to step 1318. In step 1318, the UE determines whether it is time to transmit CSI. The CSI transmission time point is transmitted from the RNC. Therefore, it is determined whether the CSI transmission time point transmitted from the RNC coincides with the scheduling transmission interval. If the CSI transmission time point and the scheduling transmission section coincide with the determination result, the process moves to step 1320, and if the CSI transmission time point and the scheduling transmission section do not match, the process moves to step 1308. In step 1320, the UE transmits the CSI, and moves to step 1308.

14 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. 14. The antenna 1400 receives the signal transmitted by the UE and transmits the signal to the RF unit 1402. The RF unit 1402 converts the received signal into a baseband signal and transfers the signal to a pulse generator 1404. The pulse former 1404 transfers the transmitted baseband signal to the scrambler 1406. The scrambler 1406 descrambles the scrambling code. The descrambled signal is transmitted to the demultiplexer 1412 after passing through the despreader 1408 and the channel compensator 1410. The demultiplexer 1412 separates the transmitted signal into a buffer state, CSI, and E-TFRI.

The buffer state separated from the demultiplexer is transferred to a buffer state channel decoding unit 1422 for channel decoding. The channel decoded buffer state checks CRC at CRC detector 1426. The CRC detector 1426 transmits the CRC detection result value to the buffer state and the CSI reception point controller 1434. The buffer status and the CSI reception time controller 1434 determine whether the buffer status has been transmitted from the UE by using the transferred CRC result value. When it is determined that the buffer state is transmitted from the UE, the buffer state and the reception time of the CSI are determined using CNT_ "sch_int", T_buffer, T_SCI, and threshold values. The buffer state receiving switch 1416 and the CSI receiving switch 1414 are turned on at the determined buffer state and the CSI receiving point. The CSI channel decoder 1420 channel decodes the CSI transmitted from the demultiplexer 1412. The E-TFRI channel decoder 1418 channel-decodes the E-TFRI transmitted from the demultiplexer 1412 and then transfers the E-TFRI CRC detector 1424.

The EUDCH data decoding unit 1428 decodes EUDCH data received from the UE using the E-TFRI. The EUDCH scheduler 1430 generates scheduler allocation information to be transmitted to the UE by using the CSI transmitted from the CSI channel decoding unit 1420 and the buffer state transferred from the buffer state CRC detector 1426. The UE buffer state estimator 1432 estimates the buffer state of the UE by using the CSI transmitted from the CSI channel decoding unit 1420 and the buffer state transferred from the buffer state CRC detector 1426. The buffer state estimate of the UE is passed to the buffer state and the CSI reception point controller 1434. The buffer state and CSI reception point controller 1434 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.

15 illustrates operation in Node B according to the present invention. In step 1500, the Node B channel-decodes the buffer state transmitted by the UE. In step 1502, the Node B performs a CRC check on the channel decoded buffer state and moves to step 1504. In step 1504, 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 1506. If the UE does not transmit the buffer state, the process moves to step 1508. In step 1508, the Node B moves to the next scheduler transmission interval number.

In step 1506, the Node B performs CSI channel decoding, and then, in step 1510, the Node B moves to the next scheduling transmission interval number. In step 1512, 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 1514, the Node B determines whether the buffer state estimate of the UE estimated in step 1512 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 process moves to step 1516. If the buffer state estimate of the UE has a value less than the threshold, the process proceeds to step 1526 and is scheduled to the UE. Send a release message. In step 1528, 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 process moves to step 1530 and moves to the next scheduling transmission interval number. If it is determined that the uplink packet transmission service is stopped, the procedure ends.

In step 1516, the Node B determines whether or not a buffer state is received. The buffer status reception point is transmitted from the RNC. If it is determined that the buffer state is received at step 1518, the process proceeds to step 1518. After performing the decoding process on the received buffer state in step 1518, it performs a CRC check in step 1520. In step 1522, 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 procedure proceeds to step 1524 and performs a channel decoding process on the received CSI, and then proceeds to step 1510. If the CSI is received, the procedure proceeds to step 1510.

16 illustrates a structure of a UE receiver that receives scheduling allocation information transmitted from a Node B according to the present invention. The antenna 1600 receives the scheduling allocation information transmitted by the Node B and transmits the scheduling allocation information 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 baseband signal is passed to the EU-SCHCCH channel decoder 1614 after passing through the switch 1608 and passing through the despreader 1610 and the channel compensator 1612. The switch 1608 will be described later. The EU-SCHCCH channel decoder 1614 performs a channel decoding process for the EU-SCHCCH, and then transfers it to the EU-SCCCH CRC detector 1616. The EU-SCCCH CRC detector 1616 determines whether scheduling allocation information has been received from the Node B by performing a CRC check on the received EU-SCCCH. The received scheduling assignment information is forwarded to the EUDCH transmission controller 1618. If it is determined that the scheduling release message is transmitted from the Node B by the CRC check of the EU-SCCCH CRC detection unit 1616, the received scheduling release message is transmitted to the scheduling assignment reception controller 1620. Hereinafter, an operation of the scheduling assignment reception controller 1620 will be described.

The scheduling allocation controller 1620 receives a buffer state, a threshold value, and a buffer state report flag. The buffer status report means that a buffer status is initially transmitted from a transmitting side of a UE to the Node B. In response to the received buffer status report, the scheduling allocation reception controller 1620 turns on the switch to receive scheduling allocation information transmitted from the Node B. The scheduling allocation reception controller 1620 controls the switch 1608 by using the transferred buffer state and a threshold value. If the transmitted buffer state is larger than the threshold value, the switch is turned on to receive scheduling allocation information transmitted from the Node B. When the delivered buffer state is smaller than the threshold value, the switch 1608 is turned off. The scheduling assignment reception controller 1620 may perform the above operation by receiving the buffer state and the threshold value from the transmitter of the UE. The scheduling assignment reception controller 1620 turns off the switch 1608 when the scheduling release message is received from the EU-SCHCCH CRC detector 1616.

17 illustrates the operation of a UE receiver in accordance with the present invention. In step 1700, the UE determines whether a reception start condition of scheduling allocation information is satisfied. The scheduling assignment information reception start condition is a time point at which a buffer status report transmitted from the UE transmitter is received. If the scheduling assignment information reception start condition is satisfied, the process proceeds to step 1702. If the scheduling assignment information reception start condition is not satisfied, the process proceeds to step 1704 and then moves to the next scheduling transmission section.

In step 1702, the UE performs a scheduling assignment channel decoding process, and then, in step 1706, the UE performs a CRC check on the decoded scheduling assignment information. If it is determined by the CRC check that the scheduling allocation information has been received from the Node B, the flow proceeds to step 1710. If the scheduling allocation information is not received, the flow moves to step 1712. In step 1710, the UE delivers the received scheduling allocation information to the EUDCH transmission controller. In step 1712, the UE moves to the next scheduling transmission interval, and moves to step 1714. In step 1714, the buffer state is observed. The buffer state observation compares a threshold and an amount of packet data stored in the EUDCH data buffer. In step 1716, the UE determines whether to continue receiving scheduling assignment information. If the amount of packet data stored in the EUDCH data buffer is greater than a threshold value, the flow proceeds to step 1702 to continue receiving the scheduling allocation information. If the amount of packet data stored in the EUDCH data buffer is smaller than the threshold value, the flow proceeds to step 1718. In step 1718, the UE 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 to step 1720 to move to the next scheduling transmission interval. If it is determined that the uplink packet transmission service is stopped, the procedure ends. Although not shown in FIG. 17, when the scheduling release message is received from the Node B, the scheduling allocation information is stopped.

As described above, according to the present invention, when the amount of data waiting in the terminal buffer is greater than or equal to a threshold value, the terminal transmits a signaling state for uplink packet data transmission by transmitting buffer state and CSI information, which are information necessary for base station control scheduling at different periods. Can be reduced. Accordingly, it is possible to efficiently use radio resources used in the EUDCH mobile communication system.

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 a process of receiving a transmission format command from active base stations by a user terminal located in a handover region.

8 is a view showing that the transmission cycle of the channel state information varies depending on the location of the user terminal.

9 is a channel coded representation of buffer status and channel status information.

FIG. 10 is a diagram illustrating a transmission period of buffer status and channel state information according to a first embodiment of the present invention. FIG.

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

12 illustrates a transmitter of a user terminal for transmitting an uplink packet.

FIG. 13 illustrates an operation performed by a transmitter of a user terminal for transmitting an uplink packet. FIG.

14 shows a receiving section of a base station for transmitting uplink packets.

FIG. 15 illustrates an operation performed at a receiving unit of a base station transmitting an uplink packet. FIG.

16 is a diagram illustrating a receiver of a user terminal for transmitting an uplink packet.

17 illustrates an operation performed at a receiving unit of a user terminal transmitting an uplink packet.

Claims (15)

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 different buffer state transmission period and 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; And transmitting the updated buffer state and channel state information according to the received buffer state transmission period and channel state information transmission period after starting transmission of the buffer state and channel state information. The method as claimed in claim 1, wherein the buffer state transmission period is set longer than the channel state information transmission period. The method as claimed in claim 1, wherein the channel state information transmission period is set longer than the buffer 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 the base station controller determines a transmission period of the buffer state and a transmission period of channel state information according to a quality of service of uplink packet data and whether the user terminal is handovered. 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 the mobile communication system, the base station transmits the scheduling assignment information using the received buffer status and channel status information, Receiving a different buffer state receiving period and channel state information receiving period from the base station controller; Generating scheduling allocation information by using the buffer state and channel state information first received from the user terminal, and transmitting the generated scheduling allocation information; And after receiving the buffer state and the channel state information, receiving the updated buffer state and the channel state information according to the received buffer state transmission period and the channel state information transmission period. 9. The method as claimed in claim 8, wherein the buffer state of the user terminal is estimated using a difference between a previously received buffer state and a packet data received after the previously received buffer state. 10. The method as claimed in claim 9, wherein if the estimated buffer state is smaller than a threshold value, the transmission of the buffer state and channel state information is requested to the user terminal. The method as claimed in claim 8, wherein the buffer state transmission period is set longer than the channel state information transmission period. The method as claimed in claim 8, wherein the channel state information transmission period is set longer than the buffer state transmission period. 9. The method of claim 8, wherein the buffer state is first received by checking a cyclic redundancy bit. The method as claimed in claim 8, wherein the base station controller determines a transmission period of the buffer state and a transmission period of channel state information according to a quality of service of uplink packet data and whether the user terminal is handovered. 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 the mobile communication system, a method for transmitting scheduling assignment information from the base station using the buffer status and channel state information of the buffer that stores the packet data transmitted from the user terminal, Receiving, by the user terminal and the base station, different buffer state transmission periods and channel state information transmission periods 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; Transmitting the updated buffer state and channel state information according to the received buffer state transmission period and channel state information transmission period after starting transmission of the buffer state and channel state information; Generating scheduling allocation information by using the buffer state and channel state information first received from the user terminal, and transmitting the generated scheduling allocation information; And after receiving the buffer state and the channel state information, receiving the updated buffer state and the channel state information according to the received buffer state transmission period and the channel state information transmission period.