JP2004215104A - Transmission assigning control device, and transmission assigning control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the deterioration of the accuracy of the determination of transmission parameters, without using a high-performance processing device. <P>SOLUTION: A TPC (Transmit Power Control) summation part 301 sums TPC commands for DL (Down Link) other than CQI (Channel Quality of Indicator) generating zone in a communication terminal device. A CQI correction part 302 corrects CQI signals, sent from the communication terminal device, based on a summation value of the TPC command. A transmission end deciding part 303 selects a communication terminal device which becomes a candidate for sending a packet by the control signal for packet transmission, and decides on the transmission end device, based on a corrected CQI, which is a CQI signal sent from the selected communication terminal device. A MCS (Modulation and Coding Scheme) deciding part 304 carries out MCS selection of the transmission end device, based on the corrected CQI, which is the CQI sent next of the CQI used in the transmission end deciding part 303 out of the transmitted CQI signals from the transmission end device decided by the transmission end deciding part 303. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to transmission allocation control when performing packet data communication using a common physical channel in a wireless communication system, and is suitably applied to, for example, a base station apparatus.
[0002]
[Prior art]
In the field of wireless communication, a downlink high-speed packet transmission scheme has been developed in which a plurality of communication terminal devices share a high-speed, large-capacity downlink channel and packet data is transmitted from the base station device to the communication terminal devices. In this downlink high-speed packet transmission scheme, a scheduling technique and an adaptive modulation technique are used to increase transmission efficiency.
[0003]
The scheduling technology is a technology in which a base station device sets a communication terminal device to which a downlink high-speed packet is transmitted for each time slot and allocates packet data to be transmitted to the communication terminal device. In addition, the adaptive modulation technique is to select MCS (Modulation and Coding Scheme) adaptively according to the state of a propagation path of a communication terminal device that transmits packet data, that is, to determine a modulation scheme, a coding rate, a code multiplex number, and the like. Is the technology to do.
[0004]
Hereinafter, the operation of the base station device and the communication terminal device of the wireless communication system that performs high-speed packet transmission will be outlined.
[0005]
The base station apparatus predicts a line state based on a report value (for example, CQI: Channel Quality of Indicator) of a downlink state reported (transmitted) from each communication terminal apparatus, and transmits from the predicted line state, QoS, or the like. The previous communication terminal device is selected, and packet data for the communication terminal device is allocated to each time slot. Further, the base station apparatus determines a modulation scheme, a coding rate, a code multiplex number, and the like when transmitting to the determined destination communication terminal apparatus, and performs error correction coding and modulation on the packet data based on the determined modulation scheme, coding rate, code multiplexing number, and the like. The data is transmitted to the destination communication terminal device.
[0006]
Each communication terminal apparatus performs demodulation in a time slot to which a packet addressed to the own station is allocated based on the received information indicating the scheduling result, performs CRC detection, and the like, and when the packet data is correctly demodulated, If the ACK signal indicating this cannot be demodulated correctly, the NACK signal indicating this is transmitted to the base station apparatus.
[0007]
The base station device transmits new packet data to the communication terminal device when receiving the ACK signal, and retransmits the same packet data when receiving the NACK signal.
[0008]
Here, a description will be given below using CQI as a report value of a downlink state for determining a modulation scheme, a coding rate, a code multiplexing number, and the like when transmitting to a communication terminal apparatus. In this specification, an operation from CIR measurement to CQI generation is referred to as CQI measurement. If the processing time required from the measurement of the CQI in the communication terminal apparatus to the selection of the destination apparatus in the base station apparatus and the determination of the transmission parameters such as the modulation scheme, the coding rate and the number of code multiplexes is long, the base station apparatus In the case of the packet transmission in the above, the line state at the time when the CQI is measured may have changed, and the optimal transmission parameter is not always selected. Specifically, if the state of the propagation path deteriorates between the time when the CQI is measured in the communication terminal apparatus and the time when the packet is transmitted in the base station apparatus, the communication terminal apparatus cannot receive the packet. Conversely, if the state of the propagation path is better, only a smaller amount of data than the amount of data that can be transmitted during packet transmission will be sent, which will result in a decrease in throughput. That is, if the processing time from the CQI measurement to the determination of the transmission parameters (the modulation scheme, the coding rate, the number of code multiplexes, etc.) is long, the determination accuracy of the transmission parameters deteriorates. Therefore, it is necessary to process in a short time from the measurement of the CQI in the communication terminal device to the selection of the communication terminal device of the transmission destination in the base station device and the determination of the modulation method, the coding rate, the number of code multiplexes, and the like.
[0009]
[Patent Document 1]
JP 2002-152228 A
[0010]
[Problems to be solved by the invention]
However, the processes from the measurement of the CQI in the communication terminal apparatus to the selection of the communication terminal apparatus of the transmission destination in the base station apparatus and the determination of the transmission parameters (such as the modulation scheme, the coding rate and the number of code multiplexes) must be performed in a short time. Therefore, there is a problem that a high-performance (high-speed processing) processing device must be used.
[0011]
The present invention has been made in view of the above, and an object of the present invention is to provide a transmission assignment control device and a transmission assignment control method that do not deteriorate the determination accuracy of a transmission parameter without using a high-performance processing device.
[0012]
[Means for Solving the Problems]
In order to solve this problem, the transmission assignment control device of the present invention determines a communication terminal device to which packet data is to be transmitted, based on a first report value indicating a downlink state transmitted from the communication terminal device. Transmission destination determining means for determining, based on a second report value, a transmission parameter to be assigned to the communication terminal device determined by the transmission destination determining means, wherein the first report value is The configuration reported before the second report value is adopted.
[0013]
According to this configuration, in determining the communication terminal device that is the transmission destination and determining the transmission parameters to be allocated to the determined communication terminal device, the transmission parameter is determined later, and these determinations are performed in a time-division manner. By taking advantage of what is done, these decisions are made by determining the destination using the first reported value reported before the second reported value indicating the downlink state used to determine the transmission parameters. By expanding the time required for these determinations as compared with the case of performing based on the same report value, the processing amount per unit time can be reduced. Further, since the second report value reported after the first report value used for determining the transmission destination is used for determining the transmission parameter, the transmission parameter corresponding to the propagation path state at the time of transmitting the packet is used. Can be sent.
[0014]
In the transmission allocation control device of the present invention, in the above-described configuration, the transmission destination determining unit determines the transmission power of a signal to be transmitted to the communication terminal device at the same time as determining the communication terminal device of the transmission destination, and determines the transmission parameter. The means adopts a configuration for determining the modulation scheme, the coding rate, and the number of code multiplexes.
[0015]
According to this configuration, since the transmission destination device and the transmission power are determined at the same time, a plurality of transmission destination devices can be selected if there is sufficient power resources.
[0016]
In the above configuration, the transmission assignment control device of the present invention may be arranged such that the transmission destination determining means tentatively determines the transmission power of a signal to be transmitted to the communication terminal device at the same time as the determination of the communication terminal device of the transmission destination. The determining means is configured to finally determine the transmission power tentatively determined by the transmission destination determining means and determine the modulation scheme, the coding rate, and the number of code multiplexes.
[0017]
According to this configuration, since the transmission destination device and the temporary determination of the transmission power are performed simultaneously, if there is enough power resources, a plurality of transmission destination devices can be selected, and the provisionally determined transmission power is reduced. By determining the modulation scheme, the coding rate, and the number of code multiplexes together with the final determination, it is possible to select a more optimal combination of transmission power and transmission parameters.
[0018]
The transmission assignment control device of the present invention employs a configuration in the above configuration, which further includes a report value correction unit that corrects the report value based on transmission power control information transmitted from time to time from a communication terminal device.
[0019]
According to this configuration, if there is a pause in the report period of the report value generated in the communication terminal device, the state of the propagation path fluctuates during the pause, and thus the destination is determined using the transmitted report value. And the determination of the MCS may not accurately indicate the downlink state, but may also be transmitted from the communication terminal apparatus at any time during the idle period and use the transmission power control information that reflects the downlink state to update the report value. By performing the correction, it is possible to obtain a report value that indicates the downlink state more accurately.
[0020]
The base station apparatus of the present invention employs a configuration including the transmission allocation control device having the above configuration. According to this configuration, it is possible to reduce the processing amount per unit time by expanding the time required for determining the transmission destination and the transmission parameter, and to cope with the propagation path state at the time of transmitting the packet. It can be transmitted with transmission parameters.
[0021]
The transmission allocation control method of the present invention, when determining the communication terminal device to which the packet data is transmitted, before the report value indicating the downlink state used to determine the transmission parameters to be allocated to the communication terminal device of the transmission destination Use the reported values reported.
[0022]
According to this method, in determining the communication terminal device that is the transmission destination and determining the transmission parameters to be allocated to the determined communication terminal device, the transmission parameter is determined later, and these determinations are performed in a time-division manner. Making use of what is done, by determining the destination using the report value reported before the report value of the downlink state used to determine the transmission parameters, these decisions are made based on the same report value Compared with the case, the time required for these determinations can be extended, and the processing amount per unit time can be reduced. In addition, since a report value reported later than the report value used for destination determination is used to determine a transmission parameter, it is possible to transmit a packet with a transmission parameter corresponding to a propagation path state at the time of transmitting a packet. .
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
The gist of the present invention is that, when determining a communication terminal apparatus to which packet data is to be transmitted, a report value reported before a report value indicating a downlink state used for determination of a transmission parameter is used for transmission. An object of the present invention is to increase the processing time from the previous determination of the communication terminal device to the determination of the transmission parameter, and to reduce the processing amount per unit time.
[0024]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0025]
(One embodiment)
FIG. 1 is a block diagram showing a configuration of the base station apparatus according to the embodiment of the present invention. Hereinafter, the receiving system of base station apparatus 100 shown in FIG. 1 will be described.
[0026]
Shared device (D _UP ) 102 outputs the signal received by antenna 101 to reception RF section 103. Further, duplexer 102 wirelessly transmits the signal output from transmission RF section 167 from antenna 101.
[0027]
The reception RF unit 103 converts the radio frequency reception signal output from the duplexer 102 into a baseband digital signal, and outputs the baseband digital signal to the demodulation unit 104.
[0028]
Demodulation section 104 is prepared for a predetermined number of communication terminal apparatuses, performs demodulation processing such as despreading and RAKE combining on the received baseband signal, and outputs the result to demultiplexing section 105.
[0029]
Separation section 105 separates the output signal of demodulation section 104 into a data signal and a control signal. The control signal separated by the separation unit 105 includes a DL (Downlink) TPC command, a CQI signal, an ACK / NACK signal, and the like. The separated control signal is output to decoding section 106, and the separated data signal is output to decoding section 107.
[0030]
Decoding section 106 performs processing such as error correction decoding on the control signal separated by separation section 105, outputs a TPC command for DL, a CQI signal, and an ACK / NACK signal to scheduler section 151, and outputs a TPC command for DL. Is also output to the transmission power control unit 158.
[0031]
Decoding section 107 performs processing such as error correction decoding on the data signal separated by separation section 105 to obtain received data.
[0032]
Next, of the transmission systems of the base station apparatus 100, a transmission system of packet data will be described. The scheduler unit 151, which is a feature of the present invention, is a communication terminal device (hereinafter, referred to as a “destination device”) that transmits a packet based on a packet transmission control signal, a CQI signal from each communication terminal device, and a TPC command for DL. ) Is determined, and information indicating the destination device and the packet data to be transmitted is output to the buffer (Queue) 152.
[0033]
Further, the scheduler 151 determines a modulation scheme, a coding rate, the number of code multiplexes, and the like based on the CQI signal and the pilot signal of the transmission destination apparatus, and instructs the modulator 153. Further, scheduler section 151 determines the transmission power of the packet data based on the CQI signal from the destination apparatus, and outputs a signal indicating the transmission power to transmission power control section 154.
[0034]
Further, scheduler section 151 outputs a signal to be transmitted to the destination apparatus by HS-SCCH (Shared Control Channel for HS-PDSCH) (hereinafter, referred to as "HS-SCCH signal") to modulation section 160. The HS-SCCH signal includes information (TFRI) indicating the timing of transmitting packet data, the coding rate of the packet data, the modulation scheme, and the like. The internal configuration of the scheduler 151 will be described later.
[0035]
The buffer 152 outputs the packet data for the communication terminal device of the transmission destination instructed by the scheduler 151 to the modulator 153 as packet data to be transmitted by HS-PDSCH (High Speed Physical Downlink Shared Channel).
[0036]
Modulation section 153 performs error correction coding, modulation, and spreading on the packet data according to the instruction of scheduler section 151, and outputs the result to amplification section 155.
[0037]
The transmission power control unit 154 controls the transmission power of the output signal of the modulation unit 153 to be a value determined by the scheduler unit 151 by controlling the amplification amount of the amplification unit 155. The output signal of the amplifier 155 is a signal transmitted on the HS-PDSCH, and is output to the multiplexer (MUX) 166.
[0038]
Modulation section 160 performs error correction coding, modulation, and spreading on the HS-SCCH signal output by scheduler section 151, and outputs the result to amplification section 162.
[0039]
The transmission power control section 161 controls the amplification amount of the amplification section 162 with a value obtained by adding an offset to the transmission power value of the transmission power control section 158, so that the transmission power of the HS-SCCH signal output from the scheduler section 151 is output. Control. The signal amplified by amplifying section 162 is a signal transmitted on the HS-SCCH and is output to multiplexing section 166. Note that the transmission power control unit 161 may correct the offset value according to a retransmission state or the like.
[0040]
Next, among the transmission systems of the base station device 100, a transmission system for individual control information and data will be described. The transmission system described here is provided for a predetermined number of communication terminal devices, and operates for each communication terminal device. Here, a portion corresponding to one specific communication terminal device will be described.
[0041]
The multiplexing unit (MUX) 156 multiplexes the pilot signal and the UL (Uplink) TPC command with the individual data (including the control signal) to be transmitted to each communication terminal device, and outputs the multiplexed signal to the modulation unit 157.
[0042]
Modulating section 157 performs error correction coding, modulation and spreading on the output signal of multiplexing section 156 and outputs the result to amplifying section 159.
[0043]
Transmission power control section 158 controls the transmission power of the output signal of modulation section 157 by controlling the amount of amplification of amplification section 159 according to the TPC command for DL. The signal amplified by the amplification section 159 is a signal transmitted on a DPCH (including a dedicated physical channel: associated DPCH), and is output to a multiplexing section (MUX) 166.
[0044]
Finally, the transmission system of the common control data among the transmission systems of the base station device 100 will be described. Modulating section 163 performs error correction coding, modulation and spreading on the common control data, and outputs the result to amplifying section 165. The transmission power control section 164 controls the transmission power of the output signal of the modulation section 163 by controlling the amplification amount of the amplification section 165. The output signal of the amplifying unit 165 is a signal transmitted by CPICH (Common Pilot Channel) or the like, and is output to the multiplexing unit 166.
[0045]
The multiplexing unit 166 multiplexes each output signal of the amplifying unit 155, the amplifying unit 159, the amplifying unit 162, and the amplifying unit 165, and outputs the multiplexed signal to the transmission RF unit 167.
[0046]
The transmission RF unit 167 converts the baseband digital signal output from the multiplexing unit 166 into a radio frequency signal and outputs the signal to the duplexer 102.
[0047]
FIG. 2 is a block diagram showing a configuration of a communication terminal device that performs wireless communication with the base station device shown in FIG. Communication terminal apparatus 200 in FIG. 2 receives individual data, common control data, packet data, and HS-SCCH signals from base station apparatus 100. Hereinafter, the operation of each component in communication terminal apparatus 200 of FIG. 2 will be described.
[0048]
Shared device (D _UP ) 202 outputs the signal received by antenna 201 to reception RF section 203. Further, duplexer 202 wirelessly transmits the signal output from transmission RF section 258 from antenna 201.
[0049]
The reception RF unit 203 converts the radio frequency reception signal output from the duplexer 202 into a baseband digital signal, and converts this digital signal into a buffer 204, a demodulation / decoding unit 205, a demodulation unit 208, and a CIR (Carrier to Interference). (Ratio) output to the measurement unit 212.
[0050]
The buffer 204 temporarily stores the baseband digital signal and outputs the signal to the demodulation / decoding unit 206.
[0051]
The demodulation / decoding unit 205 demodulates the HS-SCCH signal by performing despreading, RAKE combining, and the like on the baseband digital signal, performs decoding processing such as error correction decoding, and performs packet processing of the packet data addressed to the own station. Information necessary for demodulation / decoding of the packet data, such as the arrival timing, the modulation scheme of the packet data, the coding rate, and the number of code multiplexes, is obtained and output to the demodulation / decoding section 206.
[0052]
The demodulation / decoding unit 206 performs despreading, RAKE combining, and the like on the baseband digital signal stored in the buffer 204 based on the information obtained by the demodulation / decoding unit 205, thereby forming an HS-PDSCH signal. And performs decoding processing such as error correction decoding, and outputs the packet data obtained by the demodulation / decoding processing to the error detection unit 207.
[0053]
The error detection unit 207 performs error detection on the packet data output from the demodulation / decoding unit 206, and codes an ACK signal when no error is detected, and codes a NACK signal when an error is detected. Output to the multiplexing / multiplexing unit (MUX) 251.
[0054]
Demodulation section 208 demodulates the DPCH signal by performing despreading, RAKE combining, and the like on the baseband digital signal, and outputs the demodulated DPCH signal to demultiplexing section 209.
[0055]
Separating section 209 separates the output signal of demodulating section 208 into data and control signals. The control signal separated by the separation unit 209 includes a UL TPC command and the like. The UL TPC command is output to transmission power control section 257.
[0056]
SIR measurement section 210 measures the downlink reception SIR based on the desired wave level and interference wave level measured in the demodulation process, and outputs the measured reception SIR to TPC generation section 211.
[0057]
TPC generation section 211 generates a TPC command for DL based on the magnitude relationship between the received SIR output from SIR measurement section 210 and the target SIR, and outputs it to multiplexing section (MUX) 254.
[0058]
CIR measuring section 212 measures the CIR by demodulating (or correlating) the common control channel (CPICH) signal transmitted from the base station apparatus, and outputs the measurement result to CQI generating section 213. CQI generation section 213 generates a CQI signal based on the CIR of the CPICH signal transmitted from the base station apparatus, and outputs the generated CQI signal to coding / multiplexing section 251.
[0059]
The coding / multiplexing section 251 performs error correction coding on the CQI signal and the ACK / NACK signal, respectively, and then multiplexes and outputs the multiplexed signal to the modulation section 252. Modulating section 252 spreads and modulates the output signal of multiplexing section 251 and outputs the result to multiplexing section (MUX) 256.
[0060]
Coding / modulation section 253 performs error correction coding, spreading, and modulation on data transmitted from communication terminal apparatus 200 to base station apparatus 100, and outputs the result to multiplexing section 256.
[0061]
The multiplexing unit 254 multiplexes the DL TPC command and the pilot signal and outputs the multiplexed data to the encoding / modulation unit 255. Encoding / modulating section 255 encodes, spreads, and modulates the output signal of multiplexing section 254 and outputs the result to multiplexing section 256.
[0062]
The multiplexing unit 256 multiplexes each output signal of the modulation unit 252, the encoding / modulation unit 253, and the encoding / modulation unit 255, and outputs the multiplexed signal to the transmission RF unit 258.
[0063]
Transmission power control section 257 controls the transmission power of the output signal of multiplexing section 256 by controlling the amount of amplification of transmission RF section 258 according to the UL TPC command. Note that when connected to a plurality of base station apparatuses, the transmission power control unit 257 performs control to increase the transmission power only when all UL TPC commands instruct the transmission power to increase.
[0064]
RF transmitting section 258 amplifies the baseband digital signal output from multiplexing section 256, converts the signal into a radio frequency signal, and outputs the signal to duplexer 202.
[0065]
Next, the internal configuration of scheduler section 151 of base station apparatus 100 will be described using FIG. The TPC integrating section 301 and the CQI correcting section 302 are prepared for a predetermined number of communication terminal apparatuses, and operate for each communication terminal apparatus. Here, a portion corresponding to one specific communication terminal device will be described.
[0066]
TPC integrating section 301 integrates DL TPC commands in a communication terminal apparatus other than the CQI measurement section, and outputs the integrated result to CQI correcting section 302. Here, the reason why the TPC command for DL is used is that the TPC command as the transmission power control information reflects the propagation path state. That is, if the SIR at the time of reception is less than the predetermined value, the communication terminal apparatus recognizes that the propagation path condition is bad, and generates a TPC command (+1) requesting the base station apparatus to increase the transmission power. , SIR is equal to or more than a predetermined value, the channel state is recognized as being good, and a TPC command (−1) for requesting the base station apparatus to reduce the transmission power is generated. Further, the generation period of the TPC command is shorter than the CQI measurement period, and the TPC command is generated as needed even while the CQI measurement is paused with a predetermined interval provided. This is used for correction.
[0067]
CQI correction section 302 corrects the CQI signal transmitted from the communication terminal apparatus based on the integrated value of the TPC command output from TPC command integration section 301. The corrected CQI is output to transmission destination determining section 303 and MCS determining section 304.
[0068]
The destination determining unit 303 determines a destination communication terminal device (transmission destination device) based on the packet transmission control signal corresponding to each communication terminal device and the CQI corrected by the CQI correction unit 302. The destination determining unit 303 outputs information indicating the destination device to the buffer 152, the MCS determining unit 304, and the HS-SCCH signal generating unit 305.
[0069]
An MCS determining unit 304 as a transmission parameter determining unit performs MCS selection (determination of a modulation scheme, a coding rate, a code multiplexing number, and the like) of a destination device based on the CQI corrected by the CQI correcting unit 302, and Is output to the HS-SCCH signal generation section 305 and the modulation section 153 is notified. Also, the MCS determination unit 304 determines the transmission power of the packet data based on the CQI simultaneously with the selection of the MCS, and outputs the transmission power to the transmission power control unit 154 (an output line is not shown). In the present embodiment, transmission parameters are transmission power, modulation scheme, coding rate, and number of code multiplexes.
[0070]
The CQI output from CQI correction section 302, the operation timing of transmission destination determination section 303, and the operation timing of MCS determination section 304 will be described later.
[0071]
HS-SCCH signal generation section 305 generates an HS-SCCH signal for the destination apparatus based on the MCS or the like output from MCS determination section 304 and outputs the signal to amplification section 162.
[0072]
Here, the transmission power of the packet data is determined by the MCS determination unit 304. However, the transmission power of the packet data is determined by the destination determination unit 303 at the same time as the determination of the communication terminal device (transmission destination device) of the transmission destination. You can also. In this case, since the transmission destination device and the determination of the transmission power are performed simultaneously, a plurality of transmission destination devices can be selected if there is enough power resources.
[0073]
Furthermore, the transmission destination of the packet data can be provisionally determined at the same time as the transmission destination device is determined by the transmission destination determination unit 303. After the provisional determination, the MCS determination unit 304 selects the MCS and transmits the final packet data. The power can also be determined. In this case, if there is enough power resources, it is possible to select a plurality of destination devices and to select a more optimal combination of transmission power and transmission parameters based on the provisionally determined transmission power.
[0074]
Next, operations of the transmission destination determining unit 303 and the MCS determining unit 304 will be described with reference to FIG. FIG. 4A is a conceptual diagram illustrating the operation of a conventional transmission destination determining unit and MCS determining unit along a time axis. In this figure, the upper part shows the CQI transmission timing in the transmission destination device (communication terminal device), and the lower part shows the time axis. Is a positive number. T = t ₀ Starts transmission of CQI (1), and T = t ₁ Then, the transmission of the CQI (1) ends. T = t ₁ From T = t ₂ Until (T = t _1.5 ), The CQI (1) is subjected to reception processing (demodulation / decoding) in the base station apparatus, and determination of a transmission destination is started using the CQI (1).
[0075]
In the base station device, the communication terminal device is T = t. ₂ From T = t ₃ T = t while transmitting CQI (2) during _2.5 Determines the destination. Further, the MCS is determined using the CQI (1). The MCS is determined at the end of transmission of CQI (2) (T = t ₃ ) And CQI (3) transmission start (T = t ₄ ) (T = t _3.5 ), And transmission of the packet is started with the determined MCS.
[0076]
On the other hand, FIG. 4B is a conceptual diagram illustrating operations of the transmission destination determining unit 303 and the MCS determining unit 304 according to an embodiment of the present invention along a time axis. The upper and lower parts in this figure are the same as those in FIG. T = t ₀ Starts transmission of CQI (1), and T = t ₁ Then, the transmission of the CQI (1) ends. T = t ₁ From T = t ₂ Until (T = t _1.5 ), The base station apparatus performs reception processing (demodulation / decoding) on the CQI (1), and the transmission destination determination unit 303 starts to determine the transmission destination using the CQI (1).
[0077]
At the end of transmission of CQI (2) (T = t ₃ ) And CQI (3) transmission start (T = t ₄ ) (T = t _3.5 Then, the base station device (destination determining unit 303) ends the determination of the destination. Also, the CQI (2) is transmitted to the base station apparatus while the destination determining process is being performed, and the MCS determining unit 304 determines the MCS using the CQI (2). MCS is determined at the end of transmission of CQI (3) (T = t ₅ ) And CQI (4) transmission start (T = t ₆ ) (T = t _5.5 ), And transmission of the packet is started with the determined MCS.
[0078]
As described above, in the present embodiment, by determining the destination device using the CQI transmitted before the CQI used for determining the MCS, it is possible to determine the destination communication terminal device to determine the MCS as compared with the related art. The processing time can be extended, and the processing does not need to be performed in a short time. Therefore, a high-performance (high-speed processing) processing device may not be used.
[0079]
4 (A) and FIG. 4 (B), when looking at CQI used for MCS determination, conventionally, CQI (1) is used for MCS determination and transmission of CQI (1) is started (T = T ₀ ) To determine MCS (T = t _3.5 T) _3.5 -T ₀ Only takes time. On the other hand, in the present embodiment, CQI (2) used for MCS determination starts transmission (T = t ₂ ), And the MCS is determined (T = t _5.5 T) _5.5 -T ₂ Only takes time. Since the transmission timing of CQI is the same in the conventional and the present embodiment, the time required from transmission of CQI used for MCS determination to MCS determination, t _3.5 -T ₀ And t _5.5 -T ₂ Is substantially the same with reference to the packet transmission start time, and there is no difference in the degree of change in the propagation path state. For this reason, it is possible to set the modulation method, coding rate, code multiplexing number, and the like corresponding to the propagation path state at the time of packet transmission. That is, even if the time required from the determination of the communication terminal device of the transmission destination to the determination of the MCS is increased, it is possible to avoid deterioration of the MCS determination accuracy.
[0080]
Next, the operation of scheduler section 151 according to the embodiment of the present invention will be described using FIG. In this figure, in step (hereinafter abbreviated as "ST") 501, DL TPC commands are integrated, and the process proceeds to ST502.
[0081]
In ST502, transmission destination determining section 303 acquires the CQI corrected by CQI correcting section 302 based on the TPC integrated value calculated in ST501.
[0082]
In ST503, the destination is determined based on the corrected CQI acquired by destination determining section 303, and the process proceeds to ST504.
[0083]
In ST504, after integrating the TPC commands for DL in ST501, the TPC commands received from the communication terminal device are integrated, and the process proceeds to ST505.
[0084]
In ST505, MCS determining section 304 obtains a CQI corrected by CQI correcting section 302 based on the TPC integrated value calculated in ST504 (a CQI temporally different from the corrected CQI obtained by destination determining section 303). .
[0085]
In ST506, MCS determination section 304 determines the MCS based on the corrected CQI acquired, and ends the operation of scheduler section 151.
[0086]
As described above, according to the present embodiment, when the base station apparatus determines the communication terminal apparatus of the transmission destination and determines the MCS, the CQI reported at different timings in the communication terminal apparatus is used, so that the transmission Since the processing time from the determination of the transmission terminal device to the determination of the transmission parameter, that is, the start of packet transmission, can be extended and the processing amount per unit time can be reduced, high-performance (high-speed processing) processing is possible. It is possible to eliminate the necessity of using a device, and it is possible to avoid deterioration of MCS determination accuracy by making the CQI used for MCS determination the latest CQI for the base station device.
[0087]
In the present embodiment, the TPC is integrated and the CQI is corrected using the integrated value of the TPC. However, the present invention is not limited to this, and the CQI may be corrected by other factors. Further, the correction need not be performed.
[0088]
【The invention's effect】
As described above, according to the present invention, the base station uses the report values indicating the downlink state reported at different timings in the communication terminal to determine the communication terminal of the transmission destination, the modulation scheme, and the code. By determining the transmission parameters such as the conversion rate and the number of code multiplexes, it is possible to increase the processing time until the determination of the communication terminal device of the transmission destination and the determination of the transmission parameters, and to reduce the processing amount per unit time. This eliminates the need for using a processing device capable of high-speed processing. Further, by making the report value used for determining the transmission parameter the latest report value in the base station apparatus, it is possible to avoid deterioration in the accuracy of determining the transmission parameter.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a base station apparatus according to an embodiment of the present invention.
FIG. 2 is a block diagram showing a configuration of a communication terminal apparatus that performs wireless communication with a base station apparatus according to the embodiment of the present invention.
FIG. 3 is a block diagram showing an internal configuration of a scheduler unit in the base station apparatus according to the embodiment of the present invention.
FIG. 4 is a conceptual diagram for explaining operations of a transmission destination determining unit and an MCS determining unit according to the embodiment of the present invention.
FIG. 5 is a flowchart showing an operation of a scheduler unit in the base station apparatus according to the embodiment of the present invention.
[Explanation of symbols]
151 scheduler section
152 buffer
153 Modulation unit
213 CQI generator
301 TPC integration unit
302 CQI correction unit
303 Transmission destination determination unit
304 MCS determination unit
305 HS-SCCH signal generator

Claims (6)

Destination determining means for determining a communication terminal to which packet data is to be transmitted, based on a first report value indicating a downlink state transmitted from the communication terminal;
Transmission parameter determining means for determining a transmission parameter to be assigned to the communication terminal device determined by the transmission destination determining means based on a second report value;
With
The transmission assignment control device according to claim 1, wherein the first report value is reported before the second report value. The transmission destination determination unit determines the transmission power of a signal to be transmitted to the communication terminal device at the same time as the determination of the communication terminal device of the transmission destination. The transmission assignment control device according to claim 1, wherein the number of multiplexes is determined. The transmission destination determination unit is tentatively determining the transmission power of a signal to be transmitted to the communication terminal device simultaneously with the determination of the communication terminal device of the transmission destination, and the transmission parameter determination unit is provisionally determined by the transmission destination determination unit. The transmission assignment control device according to claim 1, wherein the transmission power is finally determined, and the modulation scheme, the coding rate, and the number of code multiplexes are determined. The transmission allocation control according to any one of claims 1 to 3, further comprising: a report value correction unit configured to correct the report value based on transmission power control information transmitted from a communication terminal device as needed. apparatus. A base station apparatus comprising the transmission assignment control device according to any one of claims 1 to 4. When determining a communication terminal device to which packet data is to be transmitted, it is necessary to use a report value that is reported before a report value indicating a downlink state used for determining a transmission parameter to be assigned to the communication terminal device of the transmission destination. Characteristic transmission allocation control method.

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