JP2008187449A - Scheduling method and radio base station apparatus using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a scheduling method for optimizing the number of times of the calculation of an index value according to the radio characteristics of each user, and for reducing a calculation processing load, and a radio base station apparatus using it. <P>SOLUTION: This scheduling method of a radio communication system for calculating the index value for selecting a mobile station on the basis of line quality between a plurality of mobile stations and a radio base station apparatus, and for transmitting data from the radio base station apparatus by selecting the mobile station on the basis of the index value includes: estimating the maximum fading frequency for each mobile station on the basis of reception signals from the plurality of mobile stations by the radio base station apparatus, and determining index value calculation intervals for each mobile station according to the estimated maximum fading frequency for each mobile station. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a scheduling method and a radio base station apparatus using the same, and calculates an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and the radio base station apparatus. The present invention relates to a scheduling method for a radio communication system that selects a mobile station based on the data and transmits data from the radio base station apparatus, and a radio base station apparatus using the same.

  For example, in high-speed packet communication such as HSDPA (High Speed Downlink Packet Access), a scheduling method for adaptively selecting a mobile station to be transmitted is defined according to channel quality, allocation frequency, and the like.

  In the conventional scheduling method, since the channel quality, the allocation frequency, and the like may vary in units of TTI (Transmission Time Interval: 2 msec in HSDPA technology), an index value as a scheduling coefficient is calculated for each TTI period, A mobile station with a high index value is selected.

  There are several wireless communication systems in which a line is shared by a plurality of users. The mobile communication system will be described by taking IMT-2000 as an example.

  FIG. 1 shows a configuration diagram of an example of a mobile communication system. In the figure, the mobile communication system includes a core network 1, a radio network controller (RNC) 2, 3, demultiplexers 4, 5, radio base stations (Node B) 6a to 6e, and mobile stations. (UE: User equipment) 7.

  The core network 1 is a network for performing routing in the mobile communication system, and includes, for example, an ATM switching network, a packet switching network, a router network, and the like. The core network 1 is also connected to other public networks (PSTN) or the like so that the mobile station 7 can communicate with a fixed telephone or the like.

  The radio base station control devices 2 and 3 are positioned as higher-level devices of the radio base station devices 6a to 6e, and have a control function for managing radio resources used by these radio base station devices 6a to 6e. In addition, a handover control function is also provided that receives signals from one mobile station 7 from a plurality of subordinate radio base station apparatuses during handover and selects the data with better quality and sends it to the core network 1 side. Yes.

  The demultiplexers 4 and 5 are provided between the radio base station controllers 2 and 3 and the radio base station apparatuses 6a to 6e, and receive the radio base station apparatuses 6a to 6e received from the radio base station controllers 2 and 3, respectively. The addressed signals are separated and output to each radio base station apparatus, and the signals from the radio base station apparatuses 6a to 6e are multiplexed and delivered to the radio base station control apparatuses 2 and 3 side.

  The radio base station devices 6 a to 6 c perform radio communication with the mobile station 7 while the radio base station control device 3 manages radio resources and the radio base station devices 6 d and 6 e manage radio resources.

  The mobile station 7 establishes a radio line with the radio base station devices 6a to 6e by being in the radio area of each of the radio base station devices 6a to 6e, and performs other communication via the core network 1. Communicate with the device.

  The interface between the core network 1 and the radio base station controllers 2 and 3 is the Iu interface, the interface between the radio base station controllers 2 and 3 is the Iur interface, and the radio base station controllers 2 and 3 and each radio base station The interface between the station apparatuses 6a to 6e is called an Iub interface, and the interface between the radio base station apparatuses 6a to 6e and the mobile station 7 is called a Uu interface. The network is specifically referred to as a radio access network (RAN).

  The line between the core network 1 and the radio base station control devices 2 and 3 is shared for Iu and Iur interfaces (a plurality of Iur interfaces with a plurality of radio base station control devices). The lines between the station control devices 2 and 3 and the demultiplexing devices 4 and 5 are shared for Iub interfaces for a plurality of radio base station devices.

  Furthermore, the HSDPA method is adopted as a technique that enables high-speed downlink data transmission. Here, HSDPA adopts an adaptive coded modulation and coding (AMC), and, for example, a QPSK modulation scheme (QPSK modulation scheme) and a 16-value QAM scheme (16 QAM scheme) are used as a radio base. Adaptive switching is performed according to the radio environment between the station apparatus and the mobile station.

  HSDPA adopts an H-ARQ (Hybrid Automatic Repeat reQuest) method. In H-ARQ, when a mobile station detects an error in received data from a radio base station apparatus, the mobile station makes a retransmission request (transmission of a NACK signal) to the radio base station apparatus.

  Since the radio base station apparatus that has received the retransmission request performs data retransmission, the mobile station performs error correction decoding using both the already received data and the retransmitted received data. In this way, in H-ARQ, even if there is an error, the already received data is effectively used, so that the gain of error correction decoding is increased, and as a result, the number of retransmissions is reduced. When an ACK signal is received from a mobile station, data transmission is successful, so retransmission is unnecessary, and the next data transmission is performed.

  The main radio channels used for HSDPA are HS-SCCH (High Speed-Shared Control Channel), HS-PDSCH (High Speed-Physical Down Channel-Heided Channel), and HS-DPCCH (High-Ded Channel).

  Both HS-SCCH and HS-PDSCH are shared channels in the downlink direction (that is, a downlink that is a direction from the radio base station apparatus to the mobile station), and HS-SCCH is connected to HS-PDSCH. This is a control channel for transmitting various parameters related to data to be transmitted. In other words, it is a channel for notifying (notifying) that data transmission is performed via the HS-PDSCH.

  The various parameters include, for example, modulation scheme information indicating which modulation scheme is used to transmit data using HS-PDSCH, the number of assigned spreading codes (number of codes), and the rate for transmission data Information such as a pattern of matching is included.

  On the other hand, HS-DPCCH is an individual control channel (dedicated control channel) in the uplink direction (that is, the uplink from the mobile station to the radio base station apparatus), and the data received via HS-PDSCH This is used when the mobile station transmits a reception result (ACK signal, NACK signal) to the radio base station apparatus depending on whether there is an error or not. That is, it is a channel used for transmitting a reception result of data received via the HS-PDSCH. When the mobile station fails to receive data (when the received data is a CRC error, etc.), the NACK signal is transmitted from the mobile station, so that the radio base station apparatus executes retransmission control.

  In addition, the HS-DPCCH is also used for the mobile station that has measured the reception quality (for example, SIR) of the received signal from the radio base station apparatus to transmit the result to the radio base station apparatus as CQI information (Channel Quality Indicator). Used. Based on the received CQI information, the radio base station apparatus determines whether the downlink radio environment is good or not. If the radio base station apparatus is good, the radio base station apparatus switches to a modulation method capable of transmitting data at a higher speed. Adaptive modulation is performed to switch to a modulation scheme for transmitting data.

  Next, a channel configuration in HSDPA will be described. FIG. 2 is a diagram for illustrating a channel configuration in HSDPA. Since W-CDMA employs a code division multiplexing system, each channel is separated by a code.

  First, the channels not described will be briefly described. CPICH (Common Pilot Channel) and SCH (Synchronization Channel) are downlink common channels, respectively.

  The CPICH is a channel used for channel estimation, cell search, and a timing reference for other downlink physical channels in the same cell in a mobile station, and is a channel for transmitting a so-called pilot signal. Strictly speaking, the SCH includes a P-SCH (Primary SCH) and an S-SCH (Secondary SCH), and is a channel transmitted in bursts at the first 256 chips of each slot. The SCH is received by a mobile station that performs a three-stage cell search, and is used to establish slot synchronization and frame synchronization.

  Next, the timing relationship of channels will be described with reference to FIG. Each channel constitutes one frame (10 ms) by 15 slots (each slot corresponds to a length of 2560 chips). As described above, since CPICH is used as a reference for other channels, the heads of P-CCPCH and HS-SCCH frames coincide with the heads of CPICH frames. Here, the head of the HS-PDSCH frame is delayed by 2 slots with respect to the HS-SCCH or the like, but after the mobile station receives the modulation scheme information via the HS-SCCH, the received modulation scheme is changed to the received modulation scheme. This is because HS-PDSCH can be demodulated by a corresponding demodulation method. HS-SCCH and HS-PDSCH constitute one subframe with three slots.

  The HS-DPCCH is an uplink channel, and the first slot thereof receives an ACK / NACK signal indicating the HS-PDSCH reception result from the mobile station after about 7.5 slots have elapsed from the reception of the HS-PDSCH. Used to transmit to station equipment. The second and third slots are used for periodically transmitting CQI information for adaptive modulation control to the radio base station apparatus. Here, the CQI information to be transmitted is calculated based on a reception environment (for example, SIR measurement result of CPICH) measured in a period from 4 slots before 1 slot before CQI transmission.

  The scheduler of the radio base station apparatus determines a transmission target (mobile station) and a transmission speed, a modulation method, and the like based on an index value calculated based on the channel quality and the transmission data rate. The scheduler is used in various communication systems. Here, a scheduler applied to a mobile communication system adopting the HSDPA scheme will be described as an example. In HSDPA, since the physical downlink data channel HS-PDSCH described above is shared by a plurality of mobile stations, it is necessary to select a mobile station to be transmitted, and the scheduler is involved in mobile station selection control.

  As a mobile station selection algorithm executed by the scheduler, the Maximum CIR method and the Proportional Fairness method have been proposed (see Non-Patent Document 1). The Maximum CIR method is a method for selecting a user with good line quality, but it is not assigned to a user with poor line quality, and there is no fairness.

On the other hand, Proportional Fairness method is based on equation (1):
Cn (PF) = Rn (1-α) / Ave_Rn (1-β) (1)
In this method, the index value Cn (PF) is calculated, and the one having a high index value Cn (PF) is selected, so that the throughput is improved while maintaining fairness.

  In Equation (1), Rn is instantaneous line quality, Ave_Rn is average line quality, and 1-α and 1-β are weighting coefficients. Also, Rn, Ave_Rn may be replaced with the amount of data that can be transmitted according to the channel quality, not the channel quality.

  Conventionally, in the above scheduler calculation, coefficients are calculated for all users every TTI period regardless of the fluctuation of the line quality, and the processing load is large.

Patent Document 1 describes that HSDPA, HUDPA, and the like provide a wireless communication method that supports data transmission / reception via the downlink and / or uplink.
JP 2004-312739 A JP 2001-358621 A IEICE Technique RCS2001-291, pp. 51-58, Mar. 2002. "Characteristic comparison of scheduling methods focusing on user throughput in high-speed downlink packets" 3G TS 25.212 (3rd Generation Partnership Project: Technical Specifications / Physical channels and mapping of transport channels on physics)

In a wireless communication system in which a line is shared by a plurality of users, a transmission target is selected from a plurality of users based on a scheduling method, and adaptive modulation control according to downlink quality is performed. In a wireless communication system that accommodates users, there is a problem that an increase in calculation processing load is a concern.
(1) It is necessary to calculate index values for all transmission candidate users at every transmission opportunity (every 2 ms in HSDPA).
(2) In order to improve the user throughput, the index formula is often complicated by considering various parameters.

  The above problem is caused by the fact that the number of index value calculations per unit time is made uniform for all users regardless of the fluctuation state of parameters used for index value calculation. For example, in the HSDPA system, the channel quality is used for calculating the index value, but the user whose channel quality does not fluctuate very much, that is, the user whose index value does not fluctuate within a unit time, Since the index value is calculated at the same interval, the number of calculations is more than necessary.

  The present invention has been made in view of the above points, and provides a scheduling method capable of reducing the calculation processing load by optimizing the number of index value calculations according to the radio characteristics of each user, and a radio base station apparatus using the same The purpose is to do.

A scheduling method according to an embodiment of the present invention calculates an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and a radio base station apparatus, and selects the mobile station based on the index value In the scheduling method of the radio communication system for transmitting data from the radio base station apparatus,
Estimating the maximum fading frequency for each mobile station based on the received signals from the plurality of mobile stations in the radio base station device,
By determining the index value calculation interval for each mobile station according to the estimated maximum fading frequency for each mobile station, it is possible to optimize the number of index value calculations according to the radio characteristics of each user and reduce the calculation processing load.

In the scheduling method,
The channel quality information included in the received signals from the plurality of mobile stations in the radio base station apparatus is extracted for each mobile station,
Calculate the dispersion value of the line quality from the extracted line quality information for each mobile station,
A mobile station in which the variance value of the channel quality exceeds a predetermined threshold may be set as an index value calculation target.

A radio base station apparatus according to an embodiment of the present invention calculates an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and the radio base station apparatus, and the mobile station based on the index value In a radio base station apparatus of a radio communication system that selects and transmits data from the radio base station apparatus,
Fading frequency estimation means for estimating a maximum fading frequency for each mobile station based on received signals from the plurality of mobile stations in the radio base station device;
By having an index value calculation interval determination means for determining an index value calculation interval for each mobile station according to the estimated maximum fading frequency for each mobile station, the calculation processing is performed by optimizing the number of index value calculations according to the radio characteristics of each user. The load can be reduced.

In the radio base station apparatus,
The fading frequency estimation means despreads received signals from the plurality of mobile stations, estimates amplitude / phase fluctuation amounts for each mobile station, and based on the amplitude / phase fluctuation amounts of a plurality of slots, the mobile station The maximum fading frequency may be estimated every time.

In the radio base station apparatus,
The fading frequency estimation means may be configured to extract movement speed information included in received signals from the plurality of mobile stations and estimate a maximum fading frequency for each mobile station based on the extracted movement speed information.

A radio base station apparatus according to another embodiment of the present invention calculates an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and the radio base station apparatus, and based on the index value In a radio base station apparatus of a radio communication system that selects a mobile station and transmits data from the radio base station apparatus,
Channel quality information extraction means for extracting channel quality information included in received signals from the plurality of mobile stations for each mobile station in the radio base station device;
Dispersion value calculating means for calculating a dispersion value of line quality for each mobile station from the extracted line quality information;
An index value calculation target determination unit that sets a mobile station whose channel quality variance value exceeds a predetermined threshold as an index value calculation target, thereby optimizing the number of index value calculations according to the radio characteristics of each user Can be reduced.

A radio base station apparatus according to another embodiment of the present invention calculates an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and the radio base station apparatus, and based on the index value In a radio base station apparatus of a radio communication system that selects a mobile station and transmits data from the radio base station apparatus,
Fading frequency estimation means for estimating a maximum fading frequency for each mobile station based on received signals from the plurality of mobile stations in the radio base station device;
Index value calculation interval determining means for determining an index value calculation interval for each mobile station according to the estimated maximum fading frequency for each mobile station;
Channel quality information extraction means for extracting channel quality information included in received signals from the plurality of mobile stations for each mobile station in the radio base station device;
Dispersion value calculating means for calculating a dispersion value of line quality for each mobile station from the extracted line quality information;
An index value calculation target determination unit that sets a mobile station whose variance value of channel quality of the mobile station that has reached the index value calculation timing after the index value calculation interval has passed a predetermined threshold as a target for index value calculation Thus, the number of index value calculations can be optimized according to the radio characteristics of each user, and the calculation processing load can be reduced.

  According to the present invention, it is possible to reduce the calculation processing load by optimizing the number of index value calculations according to the radio characteristics of each user.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<HSDPA system>
FIG. 3 shows a configuration diagram of an embodiment of an HSDPA system to which the present invention is applied. In the figure, two radio base station apparatuses 6a and 6b are connected to one radio base station control apparatus, and the radio base station apparatus 6a communicates with subordinate mobile stations 7 _{1 to} 7 _m, and wireless the base station apparatus 6b is communicating with the mobile station _{7 m} + 1 _{~7 n} under.

The scheduler unit 21 of each of the radio base station devices 6a and 6b selects a mobile station that transmits data based on channel quality information (CQI, H-ARQ information (ACK / NACK information)) received from the mobile station. (Mobile station selection control), the transmission data amount, modulation scheme, power, etc. are determined based on the CQI information received from the mobile stations 7 _{1 to} 7 _n and instructed to the channel coding unit 22.

Further, the scheduler unit 21 requests data addressed to each of the mobile stations 7 _{1 to} 7 _{n from} the radio base station controller 2 based on the scheduling result (flow control). The radio base station controller 2 holds data addressed to each of the mobile stations 7 _{1 to} 7 _n received via the core network, and sends out the data addressed to the requested mobile station in response to a request from the scheduler unit 21. .

  The buffer units 23 of the radio base station devices 6a to 6b store the data addressed to each mobile station sent from the RNC buffer unit 26 of the radio base station control device 2, and are addressed to the mobile station designated by the instruction from the scheduler unit 21. Data is input to the channel coding unit 22 in the requested block size. Further, the Iub control unit 24 of the radio base station apparatuses 6a to 6b performs flow control of data transfer from the radio base station control apparatus 2 to each of the radio base station apparatuses 6a to 6b.

  The channel coding unit 22 adds a CRC code for each block to the input data addressed to the mobile station, encodes it for each predetermined number of blocks, modulates the data using a modulation method designated by the scheduler, and transmits the data to each mobile station. To do.

<Principle of the invention>
In the present invention, the processing load is reduced by adaptively determining the calculation interval in accordance with the fluctuation state of the parameter used in the index formula such as the line quality. In the HSDPA system, the fluctuation of the channel quality is determined by the moving speed of the mobile body and the maximum fading frequency. Therefore, by determining the index value calculation interval based on these parameters, the processing can be performed more than the conventional method. The load can be reduced.

<First method>
In the first method, the maximum fading frequency is estimated by a radio base station apparatus using a known maximum fading frequency estimation method, and the index value calculation interval is determined according to the result.

  Assuming average power bo and maximum fading frequency fd, it is generally known that the number Nrs of crossing the upper or lower reference level Rs per unit time can be expressed by equation (2).

Nrs = (2 × π) ^1/2 × fd × Rs / (2 × bo) ^1/2 × exp (−Rs ^{2 / (2 × bo)} )
... (2)
However, bo is the power corresponding to the CQI reported at that time, and the lower reference level Rs is an amplitude corresponding to power 1 dB lower than the reported CQI, that is, Rs = bo / 10 ^1/20. Nrs≈1.06a × fd. The upper reference level Rs is an amplitude corresponding to power 1 dB higher than the reported CQI, that is, when Rs = bo × 10 ^1/20 , Nrs≈1.059 × fd at that time.

  Thus, defining the upper and lower reference levels Rs, crossing Rs is equivalent to varying from the power corresponding to the reported CQI and varying to another level division (CQI). You can think of it.

  Nrs is the number of fluctuations per unit time, and it can be considered that there is a possibility that the CQI fluctuates only once in 1 / (1.06a × fd) [sec] (the vertical fluctuation from the average power is Since it does not occur at the same time, a shorter index value calculation interval is selected), and it is considered that the error is small even if the index value is not calculated during 1 / (1.06a × fd) [sec].

  FIG. 5 shows a section that may change once from CQI = 15 to CQI = 14 or CQI = 16 when bo is equivalent to CQI = 15. Here, in order to secure an accuracy margin in the index value calculation, the index value calculation interval is set to 1 / (2 × fd) [sec].

  For example, when the maximum fading frequency is 50 Hz (corresponding to a moving speed of 27 km), as shown in FIG. 4, the index value calculation frequency is reduced to about 1/5 as compared with the conventional case. In FIG. 4, the index value is calculated during the period indicated by hatching. The maximum fading frequency fd is calculated using a known fading frequency estimation method.

  By determining the index value calculation timing according to the maximum fading frequency, it is possible to calculate the index value according to the channel quality fluctuation, so that the processing load can be reduced while minimizing the scheduling selection error. . For example, when fd = 55.6 Hz (moving speed = 30 km / h, carrier frequency = 2 GHz), the index value calculation interval is 10 ms, which is five times the current calculation interval (= 2 ms).

<Second method>
In the second method, the moving speed is reported from the mobile station to the base station at a certain interval, and the index value calculation interval is determined based on the maximum fading frequency calculated from the moving speed. In the first method, the maximum fading frequency is estimated by a known technique. However, in the second method, the moving speed is reported from the mobile station, and the maximum fading frequency is calculated based on the report. The mobile station has a GPS (Global Positioning System) system, for example, and obtains a moving speed using position information obtained by the GPS system.

  Since the method after calculating the maximum fading frequency is the same as the first method, only the method for calculating the maximum fading frequency will be described. A relational expression between the maximum fading frequency fd and the moving speed V is shown in Expression (3).

fd = fc × V / C (C is a high speed, fc is a carrier frequency) (3)
By determining the index value calculation timing according to the maximum fading frequency, it is possible to calculate the index value according to the channel quality fluctuation, so that the processing load can be reduced while minimizing the scheduling selection error. . For example, when fd = 55.6 Hz (moving speed = 30 km / h, carrier frequency = 2 GHz), the index value calculation interval is 10 ms, which is five times the current calculation interval (= 2 ms).

<Third method>
In the third method, a variance value of past channel quality is calculated, and only mobile stations whose variance value exceeds a certain threshold value are subject to index value calculation. The dispersion value of the line quality in the past fixed period indicates the amount of fluctuation in the past, and since it follows the moving speed of the mobile station, assuming that the moving speed does not change rapidly, the dispersion value of the line quality in the past fixed period is Considering this as an indication of future line fluctuations, only mobile stations that exceed a certain threshold are subject to index value calculation, thereby making it possible to reduce the processing load while minimizing index value calculation errors.

  In the first and second methods, the period in which there is no fluctuation in channel quality is calculated from the maximum fading frequency, whereas in the third method, scheduling is performed based on the actual fluctuation value of the past channel quality calculated. Therefore, although the processing load is increased by the variance value calculation as compared with the first and second methods, the index value calculation interval becomes longer and the processing load is reduced as a whole.

  Specifically, since the variance calculation is about 1/15 of the calculation amount of the index value calculation, even if the calculation amount increases by about 1/15, the processing load of the index value calculation is half (moving speed V = 100 km / Even if h, the index value calculation interval can be reduced to about half), it is effective.

<Fourth method>
In the fourth method, the index value calculation target is determined by the third method at the index value calculation timing calculated by the first method.

  In the first method, since the index value calculation interval is determined based on the case where the number of reference level crossings is maximized and the accuracy margin is taken into consideration, the index value calculation timing has been reached from the previous time. It is possible that the line quality has not changed much. For this reason, at the index value calculation timing calculated by the first method, the third method is used to determine the index value calculation target mobile station based on the past fluctuation amount of the channel quality, thereby further increasing the processing load. Can be reduced.

  In the first and second methods, when the index value calculation timing is set by the maximum fading frequency, the index value must be calculated even if the channel quality does not fluctuate. By doing this, even when the index value calculation timing is small, when the actual fluctuation amount of the channel quality is small, the index value calculation process is not performed by not performing the index value calculation.

<Fifth method>
In the fifth method, the index value calculation target is determined by the third method at the index value calculation timing calculated by the second method.

  The difference between the first method and the second method is only the difference in the calculation method of the maximum fading frequency, and the index value calculation timing calculation method is the same as the first method. Therefore, the second method and the third method It is possible to adopt the same method as the fourth method by combining the above. That is, at the index value calculation timing calculated by the second method, the third method is used to determine the index value calculation target mobile station based on the past fluctuation amount of the channel quality. Can be reduced.

  In the first and second methods, when the index value calculation timing is set by the maximum fading frequency, the index value must be calculated even if the channel quality does not fluctuate. Thus, even at the index value calculation timing, when the actual fluctuation amount of the channel quality is small, the load of the index value calculation process is reduced by not performing the calculation.

<Embodiment of First Method>
In this embodiment, the radio base station apparatus estimates the maximum fading frequency using a known fading frequency estimation method, and the index value calculation interval is determined according to the result.

  FIG. 6 is a configuration diagram of the first embodiment of the scheduler unit 21 for realizing the first method. For the CCH despreading / detector 31 to fd estimator 33, a known technique described in Patent Document 2 or the like is used.

  In the figure, a CCH despreading / detecting device 31 despreads and detects a DPCCH reception signal transmitted from a mobile station and supplies it to a CH estimator 32. The CCH despreading / detector 31 extracts CQI information from each mobile station and supplies it to the scheduler 35.

  The CH estimator 32 estimates the amount of amplitude / phase fluctuation in the radio wave propagation environment for each mobile station based on the supplied despread signal and supplies it to the fd estimator 33.

  The fd estimator 33 estimates the maximum fading frequency (hereinafter referred to as “fd”) for each mobile station based on the amplitude / phase fluctuation amount of the plurality of slots.

  The SCD calculation cycle calculator (SCD: schedule) 34 checks whether the calculation cycle update timing Tup_cal, i, k is in accordance with the calculation cycle update count k and the maximum fading frequency (fd, i) of the i-th mobile station. If it is the update timing, the next update timing Tup_cal, i, k + 1 is calculated according to the equation (4).

  Here, Ct_up, i is an update timing correction coefficient in the i-th mobile station, and Ct_up, i is increased when importance is placed on reducing the update frequency, and Ct_up, i is decreased when importance is placed on improving the channel quality calculation accuracy. Set. In the present invention, Ct_up, i is premised on a fixed value (for example, about 0.8), and the calculation method is not mentioned.

Tup_cal, i, k + 1 =
Tup_cal, i, k + 1 / fd, i × Ct_up, i (4)
Next, the SCD calculation cycle calculator 34 calculates the calculation cycle Tscd, i that is the basis of the index value calculation timing from the maximum fading frequency (fd, i) in the i-th mobile station based on the equation (5). The scheduler 35 is notified. Here, Ct_scd, i is a calculation period correction coefficient in the i-th mobile station, and Ct_scd, i is set to be large when the calculation frequency is important, and Ct_scd, i is set to be small when the line quality calculation accuracy is important. . Ct_scd, i is premised on a fixed value (for example, about 0.5), and the calculation method is not mentioned.

Tscd, i = (1 / fd, i) / 2 × Ct_scd, i (5)
The scheduler 35 calculates an index value for each mobile station for each calculation cycle Tscd, i, performs mobile station selection control for determining whether to transmit data based on the index value, and transmits the mobile station to the radio base station controller. The flow control for requesting the data addressed to the mobile station is determined, and the transmission data amount, modulation scheme, power, etc. for the mobile station are determined based on the CQI information received from the mobile station.

  Based on this, FIG. 7 shows a waveform diagram showing the calculation cycle update timing and calculation cycle when Ct_scd, i = 1. In this figure, for facilitating understanding, the maximum fading frequency component (the incoming wave from the traveling direction of the mobile station) is extracted, and actually, by various diffracted waves, reflected waves, scattered waves, etc. The received wave is a complex waveform. In the figure, the symbol x represents the calculation period obtained by the scheduler 35, and the arrow represents the update timing of the calculation period obtained by the SCD calculation period calculator 34.

<Embodiment of Second Method>
In this embodiment, the moving speed of the mobile station is reported to the base station at a certain interval, and the index value calculation interval is determined based on the maximum fading frequency calculated from the moving speed.

  FIG. 8 shows a block diagram of a second embodiment of the scheduler unit 21 for realizing the second method. A known technique is used for the CCH despreading / detecting device 41.

  In the figure, a CCH despreading / detector 41 despreads and detects the DPCCH reception signal transmitted from the mobile station for each mobile station, and supplies it to the moving speed detector 42. The CCH despreading / detector 41 extracts CQI information from each mobile station and supplies it to the scheduler 45.

  The moving speed detector 42 extracts the moving speed Vi of the i-th mobile station from the DPCCH according to the moving speed detection cycle (slot number) Nslot, i of the i-th mobile station.

  Here, one symbol / slot in the DPCCH frame is assigned as the moving speed bit. FIG. 9 shows an example of mapping of moving speed bits to the DPCCH (see Non-Patent Document 2 for details of bits in the slot). The slot of the DPCCH includes a pilot that is a bit for channel estimation and frame synchronization establishment, an TFCI that is an index bit indicating a transport stream, and an FBI that is a bit used for transmission diversity (not used when transmission diversity is not performed). The TPC is a bit used for power control. The FBI area is used as a moving speed bit, and the moving speed is expressed by a plurality of slots.

  As a specific movement speed extraction method, when the movement speed detection period expires, extraction of movement speed bits is started. After collecting movement speed extraction bits for the number of recognizable bits (≦ Nslot, i), the movement speed is extracted. To detect. For example, if the moving speed detection cycle is 120 slots and the moving speed recognition bit number is 15, 15 moving speed bits (15 bits) are extracted for each 120 slots, and the table shown in FIG. 10 is referred to. Detect the moving speed.

  In FIG. 10, when the movement speed extraction bit is “00000 00000 00000”, the movement speed is 0.01 [km / h] or less, and when the movement speed extraction bit is “00000 00000 00001”, the movement speed is 0.02 [km / h]. h], and when the movement speed extraction bit is “11111 11111 11111”, the movement speed is 327.68 [km / h] or more.

The fd calculator 43 calculates the maximum fading frequency (i.e., the maximum fading frequency (i) of the i-th mobile station according to the equation (6) based on the light speed C (= 3 × 10 ⁻⁵ km / h), the carrier frequency fc, and the moving speed detected by the moving speed detector. fd, i) is calculated.

fd, i = fc × Vi / C (6)
The SCD calculation cycle calculator 44 checks whether or not the calculation cycle update timing Tup_cal, i, k is in accordance with the calculation cycle update count k of the i-th mobile station and the maximum fading frequency (fd, i). Then, the next update timing Tup_cal, i, k + 1 is calculated according to the equation (7). Here, Ct_up, i is an update timing correction coefficient in the i-th mobile station, and Ct_up, i is increased when importance is placed on reducing the update frequency, and Ct_up, i is decreased when importance is placed on improving the channel quality calculation accuracy. Set.

Tup_cal, i, k + 1 = Tup_cal, i, k
+ 1 / fd, i × Ct_up, i (7)
Next, the SCD calculation cycle calculator 44 calculates a calculation cycle Tscd, i that is a basis for the index value calculation timing from the maximum fading frequency (fd, i) in the i-th mobile station based on the equation (8). Here, Ct_scd, i is a calculation period correction coefficient in the i-th mobile station, and Ct_scd, i is set to be large when the calculation frequency is important, and Ct_scd, i is set to be small when the line quality calculation accuracy is important. .

Tscd, i = (1 / fd, i) / 2 × Ct_scd, i (8)
The scheduler 45 performs index value calculation for each mobile station for each computation cycle Tscd, i, performs mobile station selection control for determining whether to transmit data based on the index value, and transmits the result to the radio base station controller. The flow control for requesting the data addressed to the mobile station is determined, and the transmission data amount, modulation scheme, power, etc. for the mobile station are determined based on the CQI information received from the mobile station.

<Third method embodiment>
In this embodiment, a variance value of past line quality is calculated, and only mobile stations whose variance value exceeds a certain threshold value are subject to index value calculation.

  FIG. 11 is a configuration diagram of the third embodiment of the scheduler unit 21 for realizing the third method. In the figure, the same parts as those in FIG.

  In FIG. 11, the CCH despreading / detecting device 31 despreads and detects the DPCCH reception signal transmitted from the mobile station for each mobile station, and supplies it to the CH estimator 32. Further, the CCH despreading / detecting device 31 extracts CQI information from each mobile station and supplies it to the forgetting factor calculator 51.

  The CH estimator 32 estimates the amount of amplitude / phase fluctuation in the radio wave propagation environment for each mobile station based on the supplied despread signal and supplies it to the fd estimator 33.

  The fd estimator 33 estimates the maximum fading frequency fd for each mobile station based on the amplitude / phase fluctuation amounts of a plurality of slots and supplies the estimated value to the forgetting factor calculator 51.

  In place of the CCH despreading / detector 31, CH estimator 32, and fd estimator 33, the CCH despreading / detector 41, the moving speed detector 42, and the fd calculator 43 are used to estimate the fading frequency fd. Also good.

  The forgetting factor calculator 51 determines forgetting factors αave ′ and αvar ′ used when calculating the CQI average value and the variance value. The CQI average forgetting factor αave ′ is calculated by the formula (9) based on the CQI average count k and the forgetting factor preset value αave. Further, the forgetting factor αvar ′ of the variance value is calculated by the equation (10) based on the CQI average frequency k and the forgetting factor preset value αvar. Note that MIN (a, b) indicates that the smaller of a and b is selected.

  At this time, when the estimated maximum fading frequency fd, i is equal to or higher than a threshold value fd_thr (for example, about 30 Hz) so that the CQI average value can be immediately followed when the channel quality largely fluctuates, k is initialized (k = 1). To do.

αave ′ = MIN (1-1 / k, αave) k = 1, 2,... (9)
αvar ′ = MIN (1-1 / k, αvar) k = 1, 2,... (10)
The CQI average calculator 52 calculates the CQI average value (CQIave, i, k) using the equation (11) using αave ′ and αvar ′. Since the CQI is expressed in a logarithm, it is calculated after being converted to a true number (CQItrue, i) and supplied to the line quality distribution calculator 53.

CQIave, i, k = CQItrue, i × (1-αave ′)
+ CQIave, i, k−1 × αave ′ (11)
The channel quality variance calculator 53 calculates the channel quality variance value CQIvar, i, k using the CQI average value CQIave, i, k, and supplies it to the threshold judgment unit 54. The variance value (CQIvar, i, k−1) is the variance value up to the previous time. Since CQI is expressed in a logarithm, it is calculated after being converted to a true number (CQItrue, i).

CQIvar, i, k = (CQItrue, i-CQIave, i, k) ²
× (1-αvar ′) + CQIvar, i, k−1 × αvar ′
(12)
The threshold value determination unit 54 compares the variance value CQIvar, i, k with a threshold value CQIvar_thr (for example, about 68 as a true value) and notifies the scheduler 55 of a mobile station having a variance value CQIvar, i, k larger than the threshold value as a scheduling target. To do.

  The scheduler 55 performs index value calculation for the scheduling target mobile station, performs mobile station selection control for determining whether or not to transmit data based on the index value, and determines the transmission to the radio base station controller. Flow control for requesting addressed data is performed, and further, a transmission data amount, a modulation scheme, power, and the like for the mobile station are determined based on CQI information received from the mobile station.

<Embodiment of Fourth Method>
In the fourth method, the index value calculation target is determined by the third method at the index value calculation timing calculated by the first method.

  FIG. 12 shows a block diagram of a fourth embodiment of the scheduler unit 21 for realizing the fourth method. In the figure, the same parts as those in FIG.

  In FIG. 12, the CCH despreading / detecting device 31 despreads and detects the DPCCH reception signal transmitted from the mobile station for each mobile station and supplies it to the CH estimator 32. Further, the CCH despreading / detecting device 31 extracts CQI information from each mobile station and supplies it to the forgetting factor calculator 51.

  The CH estimator 32 estimates the amount of amplitude / phase fluctuation in the radio wave propagation environment for each mobile station based on the supplied despread signal and supplies it to the fd estimator 33.

  The fd estimator 33 estimates the maximum fading frequency fd for each mobile station based on the amplitude / phase fluctuation amounts of a plurality of slots and supplies the estimated value to the forgetting factor calculator 51.

  The SCD calculation cycle calculator 34 checks whether the calculation cycle update timing Tup_cal, i, k is in accordance with the calculation cycle update count k and the maximum fading frequency (fd, i) of the i-th mobile station. For example, the next update timing Tup_cal, i, k + 1 is calculated according to the equation (4). Further, the calculation cycle Tscd, i that is the basis of the index value calculation timing is calculated from the maximum maximum fading frequency (fd, i) in the i-th mobile station based on the equation (5). Further, the SCD calculation cycle calculator 34 gives an operation instruction to the forgetting factor calculator 51 and the CQI average calculator 52 every time the calculation cycle elapses.

  The forgetting factor calculator 51 determines the forgetting factors αave ′ and αvar ′ used when calculating the CQI average value and the variance value only when the operation instruction is given. The forgetting factor αave ′ is calculated by equation (9) based on the CQI average count k and the forgetting factor preset value αave. Further, the forgetting factor αvar ′ is calculated by the equation (10) based on the CQI average number k and the forgetting factor preset value αvar. At this time, when the estimated maximum fading frequency fd, i is equal to or higher than a threshold value fd_thr (for example, about 30 Hz) so that the CQI average value can be immediately followed when the channel quality greatly changes, k is initialized (k = 1). To do.

  The CQI average calculator 52 calculates the CQI average value (CQIave, i, k) by the equation (11) using αave ′ and αvar ′ only when the operation instruction is given. Since the CQI is expressed in a logarithm, it is calculated after being converted to a true number (CQItrue, i) and supplied to the line quality distribution calculator 53.

  The channel quality variance calculator 53 calculates the channel quality variance value CQIvar, i, k using the CQI average value CQIave, i, k, and supplies it to the threshold judgment unit 54. The variance value (CQIvar, i, k−1) is the variance value up to the previous time. Since CQI is expressed in a logarithm, it is calculated after being converted to a true number (CQItrue, i).

  The threshold value determination unit 54 compares the variance value CQIvar, i, k with a threshold value CQIvar_thr (for example, about 68 as a true value) and notifies the scheduler 55 of a mobile station having a variance value CQIvar, i, k larger than the threshold value as a scheduling target. To do.

  The scheduler 55 performs index value calculation for the scheduling target mobile station, performs mobile station selection control for determining whether or not to transmit data based on the index value, and determines the transmission to the radio base station controller. Flow control for requesting addressed data is performed, and further, a transmission data amount, a modulation scheme, power, and the like for the mobile station are determined based on CQI information received from the mobile station.

  In other words, the index value calculation is not performed except for the index value calculation timing, and the index value calculation is not performed if the scheduling method mobile station is not selected by the third method even at the index value calculation timing. The index value is calculated less frequently.

  An example of the time transition of the index value calculation of the mobile station in FIG. 13 is shown. In the figure, the hatched portion in the upper part shows a period where the variance value CQIvar, i, k ≧ threshold value CQIvar_thr, and the hatched part in the middle portion shows the index value calculation timing. The lower part shows the index value Cn (PF) calculated by the equation (1), but the index value Cn (PF) is calculated only at the timing indicated by the arrow where the upper part and the hatched portion of interruption overlap.

<Embodiment of Fifth Method>
In the fifth method, the index value calculation target is determined by the third method at the index value calculation timing calculated by the second method.

  FIG. 14 is a configuration diagram of the fifth embodiment of the scheduler unit 21 for realizing the fifth method. In the figure, the same parts as those in FIG.

  In FIG. 14, the CCH despreading / detecting device 41 despreads and detects the DPCCH reception signal transmitted from the mobile station for each mobile station and supplies it to the CH estimator 42. Also, the CCH despreading / detecting device 41 extracts CQI information from each mobile station and supplies it to the forgetting factor calculator 51.

  The moving speed detector 42 extracts the moving speed Vi of the i-th mobile station from the DPCCH according to the moving speed detection cycle (slot number) Nslot, i of the i-th mobile station.

The fd calculator 43 calculates the maximum fading frequency (i.e., the maximum fading frequency (i) of the i-th mobile station according to the equation (6) based on the light speed C (= 3 × 10 ⁻⁵ km / h), the carrier frequency fc, and the moving speed detected by the moving speed detector. fd, i) is calculated and supplied to the forgetting factor calculator 51.

  The SCD calculation cycle calculator 44 checks whether or not the calculation cycle update timing Tup_cal, i, k is in accordance with the calculation cycle update count k of the i-th mobile station and the maximum fading frequency (fd, i). Then, the next update timing Tup_cal, i, k + 1 is calculated according to the equation (7). Also, the calculation cycle Tscd, i that is the basis of the index value calculation timing is calculated from the maximum fading frequency (fd, i) in the i-th mobile station based on the equation (8). Further, the SCD calculation cycle calculator 44 gives an operation instruction to the forgetting coefficient calculator 51 and the CQI average calculator 52 every time the calculation cycle elapses.

  The forgetting factor calculator 51 determines the forgetting factors αave ′ and αvar ′ used when calculating the CQI average value and the variance value only when the operation instruction is given. The forgetting factor αave ′ is calculated by equation (9) based on the CQI average count k and the forgetting factor preset value αave. Further, the forgetting factor αvar ′ is calculated by the equation (10) based on the CQI average number k and the forgetting factor preset value αvar. At this time, when the estimated maximum fading frequency fd, i is equal to or higher than a threshold value fd_thr (for example, about 30 Hz) so that the CQI average value can be immediately followed when the channel quality largely fluctuates, k is initialized (k = 1). To do.

  The CQI average calculator 52 calculates the CQI average value (CQIave, i, k) by the equation (11) using αave ′ and αvar ′ only when the operation instruction is given. Since the CQI is expressed in a logarithm, it is calculated after being converted to a true number (CQItrue, i) and supplied to the line quality distribution calculator 53.

  The channel quality variance calculator 53 calculates the channel quality variance value CQIvar, i, k using the CQI average value CQIave, i, k, and supplies it to the threshold judgment unit 54. The variance value (CQIvar, i, k−1) is the variance value up to the previous time. Since CQI is expressed in logarithm, it is calculated after being converted to a true number (CQItrue, i).

  The threshold value determination unit 54 compares the variance value CQIvar, i, k with a threshold value CQIvar_thr (for example, about 68 as a true value), and notifies the scheduler 55 of a mobile station having a variance value CQIvar, i, k larger than the threshold value as a scheduling target. To do.

  The scheduler 55 performs index value calculation for the scheduling target mobile station, performs mobile station selection control for determining whether or not to transmit data based on the index value, and determines the transmission to the radio base station controller. Flow control for requesting the addressed data is performed, and further, the amount of transmission data, modulation scheme, power, etc. for the mobile station are determined based on the CQI information received from the mobile station.

  In other words, the index value calculation is not performed except for the index value calculation timing, and the index value calculation is not performed if the scheduling method mobile station is not selected by the third method even at the index value calculation timing. The index value is calculated less frequently.

The CCH despreading / detecting devices 31, 41, the moving speed detector 42, the fd estimator 33, and the fd calculator 43 correspond to the fading frequency estimating means described in the claims, and the schedulers 35, 45, 55 are index value calculation intervals. The SCD calculation period calculators 34 and 44 correspond to the channel quality information extraction unit, the forgetting factor calculator 51, the CQI average calculator 52, and the channel quality variance calculator 53 correspond to the variance value calculation unit, and the threshold determination unit 54 corresponds to an index value calculation target determination unit.
(Appendix 1)
Calculate an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and a radio base station apparatus, select a mobile station based on the index value, and transmit data from the radio base station apparatus In a scheduling method for a wireless communication system,
Estimating the maximum fading frequency for each mobile station based on the received signals from the plurality of mobile stations in the radio base station device,
A scheduling method characterized by determining an index value calculation interval for each mobile station according to the estimated maximum fading frequency for each mobile station.
(Appendix 2)
Calculate an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and a radio base station apparatus, select a mobile station based on the index value, and transmit data from the radio base station apparatus In a scheduling method for a wireless communication system,
The channel quality information included in the received signals from the plurality of mobile stations in the radio base station device is extracted for each mobile station,
Calculate the dispersion value of the line quality from the extracted line quality information for each mobile station,
A scheduling method characterized in that mobile stations whose channel quality variance value exceeds a predetermined threshold are targeted for index value calculation.
(Appendix 3)
Calculate an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and a radio base station apparatus, select a mobile station based on the index value, and transmit data from the radio base station apparatus In a radio base station apparatus of a radio communication system,
Fading frequency estimation means for estimating a maximum fading frequency for each mobile station based on received signals from the plurality of mobile stations in the radio base station device;
A radio base station apparatus comprising: index value calculation interval determining means for determining an index value calculation interval for each mobile station according to the estimated maximum fading frequency for each mobile station.
(Appendix 4)
In the radio base station apparatus of the radio communication system according to attachment 3,
The fading frequency estimation means despreads received signals from the plurality of mobile stations, estimates amplitude / phase fluctuation amounts for each mobile station, and based on the amplitude / phase fluctuation amounts of a plurality of slots, the mobile station A radio base station apparatus that estimates a maximum fading frequency every time.
(Appendix 5)
In the radio base station apparatus of the radio communication system according to attachment 3,
The fading frequency estimation means extracts movement speed information included in received signals from the plurality of mobile stations, and estimates a maximum fading frequency for each mobile station based on the extracted movement speed information. Base station device.
(Appendix 6)
Calculate an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and a radio base station apparatus, select a mobile station based on the index value, and transmit data from the radio base station apparatus In a radio base station apparatus of a radio communication system,
Channel quality information extraction means for extracting channel quality information included in received signals from the plurality of mobile stations for each mobile station in the radio base station device;
Dispersion value calculating means for calculating a dispersion value of line quality for each mobile station from the extracted line quality information;
A radio base station apparatus, comprising: an index value calculation target determination unit that sets a mobile station whose channel quality variance value exceeds a predetermined threshold as an index value calculation target.
(Appendix 7)
Calculate an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and a radio base station apparatus, select a mobile station based on the index value, and transmit data from the radio base station apparatus In a radio base station apparatus of a radio communication system,
Fading frequency estimation means for estimating a maximum fading frequency for each mobile station based on received signals from the plurality of mobile stations in the radio base station device;
Index value calculation interval determining means for determining an index value calculation interval for each mobile station according to the estimated maximum fading frequency for each mobile station;
Channel quality information extraction means for extracting channel quality information included in received signals from the plurality of mobile stations for each mobile station in the radio base station device;
Dispersion value calculating means for calculating a dispersion value of line quality for each mobile station from the extracted line quality information;
An index value calculation target determination unit that sets a mobile station whose variance value of channel quality of the mobile station that has reached the index value calculation timing after the index value calculation interval has passed a predetermined threshold as a target for index value calculation A radio base station apparatus characterized by the above.
(Appendix 8)
In the radio base station apparatus of the radio communication system according to appendix 7,
The fading frequency estimation means despreads received signals from the plurality of mobile stations, estimates amplitude / phase fluctuation amounts for each mobile station, and based on the amplitude / phase fluctuation amounts of a plurality of slots, the mobile station A radio base station apparatus that estimates a maximum fading frequency every time.
(Appendix 9)
In the radio base station apparatus of the radio communication system according to appendix 7,
The fading frequency estimation means extracts movement speed information included in received signals from the plurality of mobile stations, and estimates a maximum fading frequency for each mobile station based on the extracted movement speed information. Base station device.

It is a block diagram of an example of a mobile communication system. It is a figure for demonstrating the timing relationship of a channel. It is a block diagram of one Embodiment of the HSDPA system to which this invention is applied. It is a figure which shows this invention and the conventional index value calculation timing. It is a figure which shows the area which may change once from CQI = 15 to CQI = 14 or CQI = 16. It is a block diagram of 1st Embodiment of the scheduler part for implement | achieving a 1st method. It is a wave form diagram showing a calculation cycle update timing and a calculation cycle. It is a block diagram of 2nd Embodiment of the scheduler part for implement | achieving a 2nd method. It is a figure which shows the example of mapping of the movement speed bit to DPCCH. It is a figure which shows the table of a moving speed extraction bit and a moving speed. It is a block diagram of 3rd Embodiment of the scheduler part for implement | achieving the 3rd method. It is a block diagram of 4th Embodiment of the scheduler part for implement | achieving the 4th method. It is a figure which shows an example of the time transition of index value calculation. It is a block diagram of 5th Embodiment of the scheduler part for implement | achieving the 5th method.

Explanation of symbols

1 a core network 2, 3 the radio base station controller 4, 5 demultiplexer 6a~6e radio base station apparatus 7 ₁ to _7-n mobile station 21 scheduler 22 channel coding section 23 buffer section 31 and 41 CCH despreading and detection device 32 CH estimator 33 fd estimator 34, 44 SCD calculation period calculator 35, 45, 55 Scheduler 42 Movement speed detector 43 fd calculator 51 Forgetting factor calculator 52 CQI average calculator 53 Channel quality dispersion calculator 54 Threshold judgment unit

Claims (7)

Calculate an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and a radio base station apparatus, select a mobile station based on the index value, and transmit data from the radio base station apparatus In a scheduling method for a wireless communication system,
Estimating the maximum fading frequency for each mobile station based on the received signals from the plurality of mobile stations in the radio base station device,
A scheduling method characterized by determining an index value calculation interval for each mobile station according to the estimated maximum fading frequency for each mobile station. Calculate an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and a radio base station apparatus, select a mobile station based on the index value, and transmit data from the radio base station apparatus In a scheduling method for a wireless communication system,
The channel quality information included in the received signals from the plurality of mobile stations in the radio base station device is extracted for each mobile station,
Calculate the dispersion value of the line quality from the extracted line quality information for each mobile station,
A scheduling method characterized in that mobile stations whose channel quality variance value exceeds a predetermined threshold are targeted for index value calculation. Calculate an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and a radio base station apparatus, select a mobile station based on the index value, and transmit data from the radio base station apparatus In a radio base station apparatus of a radio communication system,
Fading frequency estimation means for estimating a maximum fading frequency for each mobile station based on received signals from the plurality of mobile stations in the radio base station device;
A radio base station apparatus comprising: index value calculation interval determining means for determining an index value calculation interval for each mobile station according to the estimated maximum fading frequency for each mobile station. The radio base station apparatus of the radio communication system according to claim 3,
The fading frequency estimation means despreads received signals from the plurality of mobile stations, estimates amplitude / phase fluctuation amounts for each mobile station, and based on the amplitude / phase fluctuation amounts of a plurality of slots, the mobile station A radio base station apparatus that estimates a maximum fading frequency every time. The radio base station apparatus of the radio communication system according to claim 3,
The fading frequency estimation means extracts movement speed information included in received signals from the plurality of mobile stations, and estimates a maximum fading frequency for each mobile station based on the extracted movement speed information. Base station device. Calculate an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and a radio base station apparatus, select a mobile station based on the index value, and transmit data from the radio base station apparatus In a radio base station apparatus of a radio communication system,
Channel quality information extraction means for extracting channel quality information included in received signals from the plurality of mobile stations for each mobile station in the radio base station device;
Dispersion value calculating means for calculating a dispersion value of line quality for each mobile station from the extracted line quality information;
A radio base station apparatus, comprising: an index value calculation target determination unit that sets a mobile station whose channel quality variance value exceeds a predetermined threshold as an index value calculation target. Calculate an index value for selecting a mobile station based on channel quality between a plurality of mobile stations and a radio base station apparatus, select a mobile station based on the index value, and transmit data from the radio base station apparatus In a radio base station apparatus of a radio communication system,
Fading frequency estimation means for estimating a maximum fading frequency for each mobile station based on received signals from the plurality of mobile stations in the radio base station device;
Index value calculation interval determining means for determining an index value calculation interval for each mobile station according to the estimated maximum fading frequency for each mobile station;
Channel quality information extraction means for extracting channel quality information included in received signals from the plurality of mobile stations for each mobile station in the radio base station device;
Dispersion value calculating means for calculating a dispersion value of line quality for each mobile station from the extracted line quality information;
An index value calculation target determination unit that sets a mobile station whose variance value of channel quality of the mobile station that has reached the index value calculation timing after the index value calculation interval has passed a predetermined threshold as a target for index value calculation A radio base station apparatus characterized by the above.

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