JP2003009240A - Base station, mobile station and radio communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently perform ongoing data transmission by expanding the width of a mobile station to be an object that performs scheduling in each carrier by increasing a carrier that can be used by one mobile station to a plurality of carriers. SOLUTION: A base station 10 allocates two or more carriers to respective mobile stations 20a and 20b and receives a request transmission speed corresponding to at least one carrier among allocated carriers from the respective mobile stations. The base station 10 calculates an evaluation function of each mobile station in each carrier on the basis of the request transmission speeds received respectively from the mobile stations 20a and 20b and decides a mobile station that transmits data in each time division on the basis of the evaluation function in the respective carriers f1 to f3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a base station, a mobile station and a radio communication method used for cellular mobile communication and the like.

[0002]

2. Description of the Related Art Recently, as a next-generation high-speed wireless communication system
cdma2000 1x-EV DO method is being developed. Cdma200 above
0 1x-EV DO method is a standard method of HDR (High Data Rate) method, which is an extension method of cdma2000 1x by Qualcomm, and is standardized by Std.T-64 1S-2000 at ARIB.
CS0024 "cdma2000 High Rate Packet Data Air Inte
It is standardized by the "rface Specification" and is currently being serviced by KDDI in Japan. cdmaOne method (ARIB T-53 in Japan, EIA / TIA / IS-95 in North America, South Korea, etc.
Etc., and cdma compatible with the 3rd generation system (3G)
2000 It is a method aimed at improving the communication speed by further specializing the 1x method in data communication. In addition, cdma2000 l
In x-EV DO, EV means Evolution and DO means Data only.

[0003]

In the cdma2000 1x-EV DO system, by switching the modulation system of the data transmitted to the mobile station by the base station based on the information notifying the reception status received from the mobile station, When the reception status of the mobile station is good, it is possible to use a high communication speed with a low error resistance but a high communication speed when the reception status is bad, and a communication speed with a low error resistance but a high error resistance. In this system, the downlink data communication speed is not simply determined by the instantaneous value of the desired wave power to interference wave power ratio (CIR) indicating the reception state as in the conventional cdmaOne system, but is predicted or past. It changes due to correction by statistical data such as error rate of downlink data transmission. That is, CDM, which is a communication method that is currently widespread.
In A, unlike the cdma20001x-EV DO method, the change in the data communication speed depending on the location is not so remarkable, so the judgment of the reception status etc. is also determined from the Ec / Io (pilot signal strength The received signal strength to the total), CIR, and other instantaneous values.

On the other hand, in the cdma2000 1x-EV DO system, an extremely accurate data communication rate directly obtained in consideration of prediction and correction by statistical data such as error rate of past downlink data transmission is directly shown. Required transmission rate (DRC; Data
The mobile station side has a rate control bit) as a table, and based on this table, the requested transmission rate is notified from the mobile station to the base station. As a result, data communication at various communication speeds described above is performed.

Also, in the downlink direction (direction from the base station to the mobile station) of the cdma2000 1x-EV DO system, the time is in units of 1/600 seconds (hereinafter referred to as "divided time" or "slot").
Time division multiplex access (TDMA; time division multiplex access) in which communication is performed with only one mobile station within that time, and communication is performed with multiple mobile stations by switching the mobile station of the communication partner according to time. ) Is adopted. As a result, it is possible to always perform data transmission with the maximum power to each mobile station, and it is possible to perform data communication between mobile stations at the highest communication speed.

In this time division multiple access, the base station side evaluates the communication status of each mobile station based on the requested transmission rate notified from the mobile station side, and based on this evaluation result, which mobile station is next The slots are used to decide whether to send the data. The allocation of this slot is called scheduling. Conventionally, each mobile station has been configured to perform data communication using only one fixed carrier assigned to itself, so scheduling in each carrier is performed in the mobile station to which the carrier is assigned. Met.

As described above, since the scheduling in each carrier is conventionally performed between the limited mobile stations to which the carrier is assigned, for example,
When mobile stations with good communication conditions are concentrated on one carrier, while mobile stations with poor communication conditions are concentrated on other carriers, there is no effective measure and it is used by the own station. There has been a problem that it is difficult to effectively utilize the carrier to transmit downlink data.

The present invention has been made in view of the above circumstances. By increasing the number of carriers that can be used by one mobile station to a plurality of carriers, the range of mobile stations to be scheduled in each carrier is increased. An object of the present invention is to provide a base station, a mobile station, and a wireless communication method that can efficiently perform downlink data transmission.

[0009]

In order to achieve the above object, the present invention provides a base station for transmitting transmission data by time division multiplexing to a plurality of mobile stations using a plurality of carriers. A carrier allocating means for allocating two or more carriers to each mobile station, and a receiving means for receiving a required transmission rate (for example, DRC) corresponding to at least one of the allocated carriers from each mobile station. (For example, a requested transmission rate receiving unit 604 in an embodiment described later) and an evaluation function updating unit that obtains an evaluation function of each mobile station for each carrier based on the requested transmission rate received from each mobile station (for example, , An evaluation function updating unit 605 in an embodiment to be described later, and a mobile station that transmits data for each time division in each carrier. Based selecting means for determining (e.g., the mobile station selecting unit 606 in the embodiment described later) to provide a base station, characterized by comprising a.

The above-mentioned carrier allocating means may perform an operation of allocating two or more carriers to each mobile station in advance and transmitting the allocated carrier to the mobile station. Instead of assigning a fixed carrier to each mobile station, a process of transmitting the carrier used by the mobile station to all mobile stations may be performed. Specifically, for example, when the own station is transmitting downlink data using four carriers, even if the carrier to be used is determined in advance for one mobile station and only the determined carrier is transmitted. Alternatively, four carriers may be transmitted to all mobile stations. That is, in the present invention, the base station transmits two or more carriers (carriers) to one mobile station, and the requested transmission rate for two or more carriers transmitted by itself is received from the mobile station. It should have a configuration like this. In the embodiment described later, on the base station side, all carriers used by the own station are transmitted to all mobile stations,
The case where the mobile station selects a carrier for which the required transmission rate is to be measured from these carriers is described.

Also, in the base station according to claim 1,
Among the plurality of carriers used for data transmission, two or more carriers having a frequency difference of a predetermined value or more are selected for one mobile station.

Further, in the base station according to claim 1 or 2, the evaluation function is a value obtained by dividing the requested transmission rate notified from the mobile station by an average transmission rate of the mobile station. Is characterized by.

Also, in the base station according to claim 3,
The average transmission rate is a value independently obtained for each carrier.

Also, in the base station according to claim 3,
The average transmission rate is a common average transmission rate that is obtained by integrating the average transmission rates of all carriers.

Also, in the base station according to claim 3,
For the calculation of the evaluation function for the carriers used for data transmission, the average transmission rate obtained independently for each carrier is used, while for the calculation of the evaluation function for the carriers not used for data transmission. Is
A value smaller than the average transmission rate used for calculating the evaluation function in the carrier used for the data transmission is used.

In order to achieve the above object, the present invention provides a receiving means for receiving a plurality of carriers emitted from a base station, and a request for obtaining a required transmission rate for each carrier according to a receiving state of each carrier. There is provided a mobile station comprising: a transmission rate calculation means; and a transmission means for transmitting information specifying each carrier and the required transmission rate of the carrier in association with each other to the base station.

Further, in the mobile station according to claim 7,
Among the plurality of received carriers, two or more carriers having a frequency difference of a predetermined value or more are selected, and the required transmission rate is calculated only for the selected carriers. And

Further, in the mobile station according to claim 7 or 8, the notifying means sets the requested transmission rate having the highest requested transmission rate and the carrier identification information corresponding to the requested transmission rate. It is characterized by notifying to the base station.

In order to achieve the above object, the present invention is a radio communication method for transmitting transmission data by time division multiplexing to a plurality of mobile stations using a plurality of carriers. Assigning two or more carriers to a station; receiving a request transmission rate corresponding to at least one carrier of the assigned carriers from each mobile station; and a request transmission rate received from each of the mobile stations. Based on the evaluation function of each mobile station based on the evaluation function, and a step of determining a mobile station transmitting data for each time division in each carrier based on the evaluation function. A wireless communication method is provided.

As the mobile station of the present invention, the so-called CDMA (code division multiple access) system and PDC (Personal) are used.
Digital Cellular System) mobile phones and PHS
(Personal Handyphone System) (registered trademark),
It also includes portable terminals called PDA (Personal Digital Assistants). Here, in the case of the PDA, even if the communication means is built-in, or if the communication means is connected from the outside, the PDA performs the calling (call-in, communication) processing, which will be described later, which is a feature of the present invention.
Those performed by the main body are included in the present invention.

[0021]

DETAILED DESCRIPTION OF THE INVENTION An embodiment of the present invention will be described below with reference to the drawings. First, an outline of data communication performed between a base station and a mobile station according to an embodiment of the present invention will be described with reference to FIG.

In FIG. 1, reference numeral 10 is a base station,
Reference numerals 20a and 20b are mobile stations. The base station 10 has carriers f1 to f3 that are carriers of different frequencies.
Can be used to simultaneously transmit downlink data to a plurality of mobile stations. Here, carriers f1 and f2, which are data transmission media, are assigned to the mobile station 20a in advance, while carriers f1 and f2 are assigned to the mobile station 20b.
3 and 3 are assigned in advance. As a result, the mobile station 2
Downlink data can be transmitted to carrier 0a using carrier f1 and / or f2, and downlink data can be transmitted to carrier 20b using carriers f1 and / or f2. Here, the carriers assigned to each mobile station have a difference between frequencies of a predetermined value Δf or more. That is, | f1-f2 | ≧ Δf, | f1-f3 |
The relational expression of ≧ Δf holds.

Each mobile station 20a, 20b obtains the reception quality (for example, desired wave power to interference wave power ratio CIR, error rate, etc.) of the common channel notified by the carrier assigned to each mobile station, and further The required transmission rate is calculated based on the reception quality, and the required transmission rate is calculated by the base station 1
Send to 0. That is, the mobile station 20a calculates the required transmission rates for the carriers f1 and f2, and transmits the calculated required transmission rates to the base station 10 in association with the respective carrier identifiers. Similarly, the mobile station 20b calculates the required transmission rates for the carriers f1 and f3, respectively, and transmits the calculated required transmission rates and the carrier identifiers to the base station 10 in association with each other. The method of obtaining the reception quality and the required transmission rate will be described later.

When the base station 10 receives the required transmission rates for the assigned carriers from the mobile stations 20a and 20b, these are divided for each carrier and the evaluation function of each mobile station is obtained for each carrier. Specifically, since the carrier f1 is assigned to the mobile stations 20a and 20b, the requested transmission rate is received from each mobile station, and the evaluation function in each mobile station is obtained based on these requested transmission rates. . Similarly, for the carrier f2, an evaluation function is obtained based on the requested transmission rate received from the mobile station 20a, and for the carrier f3, the mobile station 20b.
The evaluation function is obtained based on the requested transmission rate received from the. Then, scheduling is performed so that downlink data is transmitted using the carrier to the mobile station that has the highest value among the evaluation functions obtained for each carrier.

For example, in the carrier f1, the mobile station 2
If the evaluation function of 0a is higher than the evaluation function of the mobile station 20b, the base station 10 determines to use the carrier f1 to transmit downlink data to the mobile station 20a. Since the requested transmission rate is transmitted only from the mobile station 20a for the carrier f2, it is determined to use the carrier f2 to transmit downlink data to the mobile station 20a.

Here, when the scheduling is performed as described above, the carrier f1 for the mobile station 20a is
And downlink data transmission using f2 will be performed simultaneously. In this case, for example, if the mobile station 20a has a function of receiving downlink data from two carriers at the same time, the downlink data is transmitted to the mobile station 20a using the carriers f1 and f2. On the other hand, when the mobile station 20a does not have a function of simultaneously receiving downlink data from a plurality of carriers, the base station has the highest evaluation function of the mobile station 20a, for example, the mobile station 20a in the carrier f1. An evaluation function,
The evaluation function of the mobile station 20a in the carrier f2 is compared, and the carrier having the higher evaluation function is used to determine the mobile station 2
The downlink data is transmitted to 0a.

On the other hand, for the mobile station 20b, if the carrier f1 is used for data transmission to the mobile station 20a, scheduling is performed so that downlink data is transmitted using the carrier f3. On the other hand, if downlink data transmission to the mobile station 20a is not performed using the carrier f1, the evaluation functions of the mobile station 20b in the carriers f1 and f3 are compared, and the carrier having the higher evaluation function is used to move. Downlink data is transmitted to the station 20b. When the mobile station 20b has a function of simultaneously receiving downlink data transmitted by a plurality of carriers,
Downlink data is transmitted to the mobile station 20 by the carriers f1 and f3.
sent to b.

As described above, instead of assigning each carrier to each mobile station on the base station side, the carrier may be arbitrarily selected on the mobile station side. In this case, the base station side sends out the carriers f1 to f3 to the respective mobile stations, the mobile station side selects some of them, and requests the required transmission rate etc. only for the selected carriers. Ask. At the mobile station,
The required transmission rate may be calculated for all carriers transmitted from the base station.

Next, the configurations and operations of the base station and mobile station according to the present invention will be described in detail with reference to FIGS.

<< Mobile Station >> First, the mobile station according to the first embodiment of the present invention will be described with reference to FIG. Figure 2
FIG. 4 is a block diagram showing an internal configuration of a mobile station in consideration of a case where a carrier to be measured, a number of carriers reporting a required transmission rate, and a number of carriers waiting to receive a downlink dedicated carrier have the same value. . Note that the mobile station sets the number of carriers that can obtain the required transmission rate DRC before performing the following series of processes as the number of carriers that can simultaneously receive the individual channels as “multi-carrier correspondence information”, and sets the uplink individual channel transmission unit 309. Notify the base station via. In addition, in the present embodiment, a case will be described in which the base station side does not allocate two or more specific carriers to the mobile station, but the mobile station selects a carrier for which the requested transmission rate is to be measured.

First, a plurality of carriers emitted from the base station side are received via the antenna 301, and distributed via the frequency demultiplexer / combiner 308 to the carrier-by-carrier processing unit 310 for each carrier.

The measurement downlink common channel setting section 307 selects two or more carriers whose transmission quality is to be measured from the plurality of carriers received from the base station. At this time, the measurement downlink common channel receiving unit 307 selects two or more carriers whose frequency difference is equal to or more than a preset predetermined value. As a selection procedure, for example, the first carrier may be arbitrarily selected, and the carriers after the second carrier may be selected such that the frequency is equal to the frequency of the preceding carrier + Δf. It should be noted that Δf may be selected in consideration of frequency-selective fading so that the correlation of fluctuations between received signals is small. Specifically, the desired wave power to the interference wave power ratio CI
A carrier having a small correlation between instantaneous values such as R and error rate is selected.

Then, the measurement downlink common channel setting unit 30
When a carrier to be measured is selected, the control unit 7 transmits control information (mobile station identifier, mobile station code, etc.) A required for transmission / reception of the selected carrier to a frequency demultiplexer / combiner 308, a downlink dedicated channel receiving unit 302, and a downlink common channel. The channel reception unit 303, the requested transmission rate transmission unit 306, and the uplink dedicated channel transmission unit 309 are notified and the transmission and reception are set.

The carrier to be measured received from the base station side is received by the downlink common channel receiving unit 303 in the carrier-by-carrier processing unit 310 for each carrier, and the quality evaluation unit 3
04, quality evaluation of the desired wave power to interference wave power ratio CIR, error rate, etc. is performed, and the evaluation result is notified to the required transmission rate calculation unit 305. Specifically, the quality evaluation unit 30
4 calculates a desired wave power to interference wave power ratio CIR by the following equation (1) based on Ec / Io (pilot signal strength vs. total received signal strength). CIR = (Ec / lo) / (1-Ec / lo) (1) Further, based on the CIR obtained based on the above equation, the next reception slot timing (here, one slot is 1.66 ms)
CIR (hereinafter, referred to as a predicted CIR value) value at = 1/600 second) is predicted. The prediction method here is not particularly limited, but a method such as linear prediction may be used as an example. Here, information indicating how many slots after which CIR should be predicted is included in various control signals transmitted from the base station when the mobile station is powered on. Then, the quality evaluation unit calculates the predicted CIR by the method described above, and outputs the predicted CIR to the required transmission rate calculation unit 305 as a quality result.

The required transmission rate calculation unit 305 determines the required transmission rate DRC from the evaluation result output from the quality evaluation unit 304.
To calculate. Specifically, the required transmission rate calculation unit 305
Has a table in which the predicted CIR and the required transmission rate DRC are directly associated with each other, and C is the evaluation result notified from the quality evaluation unit 304 with reference to this table.
The required transmission rate DRC corresponding to IR is obtained. The required transmission rate DRC (Data Rate Control Bit) directly indicates an extremely accurate data transmission rate obtained in consideration of prediction and correction by statistical data such as an error rate of past downlink data transmission. It is a thing.

The required transmission speed D calculated in this way
The RC is notified to the wireless base station from each carrier that has performed the measurement via the requested transmission rate transmission unit 306. Note that the transmission of the required transmission rate DRC for a plurality of carriers may be performed by one of the measurement target carriers.
That is, the mobile station 20a shown in FIG. 1 will be described as an example. The carrier f1 transmits the required transmission rate DRC of the carrier f1 and the carrier f2 transmits the required transmission rate DRC of the carrier f2. Alternatively, the required transmission rates DRC of the carriers f1 and f2 may be collectively transmitted by any carrier, for example, the carrier f1.

Then, the mobile station puts the downlink dedicated channel receiving section 302 into a reception standby state for each carrier to be measured, and when receiving the downlink dedicated channel, the downlink signal combining section 31 is received.
Output to 1. The downlink signal combination unit 311 combines the downlink dedicated channels received by a plurality of carriers into one signal.

Next, a mobile station according to the second embodiment of the present invention will be described with reference to FIG. FIG. 3 is a block diagram showing an internal configuration of a mobile station according to the second embodiment of the present invention.

The mobile station according to the present embodiment differs from the mobile station according to the first embodiment shown in FIG. 2 in that the number of carriers to be measured, the number of carriers reporting the required transmission rate, and the downlink dedicated carrier are set. The number of carriers waiting for reception is different. Therefore, the mobile station in this embodiment, as shown in FIG. 3, has a downlink common channel 403, a downlink dedicated channel reception unit 406, and a requested transmission rate transmission unit 408.
Each has a configuration in which it is suppressed to a required number of minutes. Also,
Before performing the following processing, the mobile station sets the number of carriers for which the mobile station can simultaneously obtain the required transmission rate as the number of carriers that can simultaneously receive the individual channels as "multi-carrier correspondence information", and the uplink individual channel transmission unit 309. To the base station via.

Hereinafter, each part constituting the mobile station in this embodiment will be described in detail. The same components as those of the mobile station according to the first embodiment described above are designated by the same reference numerals, and detailed description thereof will be omitted.

First, a plurality of carriers emitted from the base station are received by the antenna 301. The measurement downlink common channel setting unit 307 selects a plurality of carriers to be measured by the mobile station, and outputs control information (mobile station identifier, mobile station code, etc.) necessary for transmission / reception of the measurement target carrier to the frequency demultiplexer / combiner 308 and downlink. The common channel reception unit 303, the downlink dedicated channel reception unit 302, the requested transmission rate transmission unit 306, and the uplink dedicated channel transmission unit 309 are notified and the settings necessary for transmission and reception are performed.

The carrier to be measured received from the base station side is received by the downlink common channel receiving unit 303 which is different for each carrier, and the quality evaluation unit 304 evaluates the quality of desired wave power to interference wave power ratio CIR and error rate. The requested transmission rate calculation unit 405 is notified of the evaluation result. The requested transmission rate calculation unit 405 calculates the requested transmission rate DRC for each carrier based on the evaluation result received from each quality evaluation unit 304, and the requested transmission rate DRC is calculated.
Select the preset number from highest to lowest,
The selected requested transmission rate DRC and its carrier identification code are associated (information B in the figure) and transmitted to the downlink dedicated channel receiving section 302 and the requested transmission rate transmitting section 306.

The required transmission rate transmission unit 306 transmits the carrier identification code and the required transmission rate DRC selected by the required transmission rate calculation unit 405 to the base station via the carrier having the highest required transmission rate DRC. Note that the required transmission rates DRC for a plurality of carriers may be simultaneously transmitted in parallel using the required transmission rate 306 for each carrier to be measured. The downlink dedicated channel reception unit 302 enters the reception standby state based on the instructed carrier and the requested transmission rate DRC, and when receiving the downlink dedicated channel, outputs the downlink dedicated channel to the downlink signal synthesis unit 311. The downlink signal synthesis unit 311
Downlink signals received by a plurality of carriers are combined into one signal.

Next, a mobile station according to the third embodiment of the present invention will be described with reference to FIG. In the mobile station according to the present embodiment, in the second embodiment described above, the number of downlink dedicated channel receiving sections 302 is set to one, and the downlink signal combining section 311 is removed from the constituent elements. That is, in the mobile station according to the present embodiment, the carrier to be measured received by the downlink common channel reception unit 303 is quality-evaluated by the quality evaluation unit 304 such as the desired wave power to interference wave power ratio CIR and the error rate. , Is output to the requested transmission rate calculation unit 505. The required transmission rate calculation unit 505 outputs, to the required transmission rate transmission unit 306, the carrier identifier and the required transmission rate for one carrier having the best required transmission rate among the plurality of input required transmission rates. The request transmission rate transmitting unit 306 associates the received request transmission rate and the received carrier identifier with each other and transmits them to the base station. On the other hand, the required transmission rate calculation unit 40
5 indicates the carrier identifier and the information B of the required transmission rate,
The signal is output to each downlink dedicated channel receiving unit 302. Upon receiving this information, the downlink dedicated channel receiving unit 506
Enters standby for reception. In this way, the carrier identifier having the highest required transmission rate DRC and the required transmission rate DRC may be transmitted to the base station. By doing so, the number of requested transmission rates received by the base station is reduced, so that the scheduling process performed on the base station side can be reduced. Further, from the mobile station side, the number of constituent elements can be reduced as compared with the mobile stations according to the above-described first and second embodiments, so that cost reduction and size reduction can be achieved.

<< Base Station >> Next, a base station according to an embodiment of the present invention will be described with reference to FIG. FIG. 5 is a block diagram showing an internal configuration of a base station according to an embodiment of the present invention. In FIG. 5, the required transmission rate DRC from each mobile station received via the antenna 601 is demultiplexed for each carrier by the frequency demultiplexer / combiner 602 and output to each required transmission rate receiving unit 604 for each carrier. To be done.
Upon acquiring the requested transmission rate DRC associated with the identification information of each mobile station, the requested transmission rate receiving unit 604 notifies the evaluation function updating unit 605 of this information. As a result,
Required transmission rate D for each carrier received from the mobile station
RC is input to the evaluation function update unit 605 of the corresponding carrier.

When the evaluation function update unit 605 provided for each carrier acquires the mobile station identifier and the requested transmission rate DRC, it updates the evaluation function management table managed by itself based on these pieces of information. . As shown in FIG. 5, the evaluation function management table is a table in which the required transmission rate and the evaluation function are associated with each mobile station. The details of the calculation method of the evaluation function will be described later.
If the requested transmission rate DRC cannot be received from the mobile station at the time of updating the evaluation function management table, the requested transmission rate is updated to a preset fixed value α (for example, α = 0). The determination that the requested transmission rate cannot be received from the mobile station is determined because the mobile station carrier correspondence control unit 609 monitors the communication between the base station and the mobile station.

The mobile station selecting unit 606 prepared for each carrier searches the evaluation function management table managed by the evaluation function updating unit 605, selects the mobile station having the maximum evaluation function, and selects this mobile station. And the requested transmission rate DRC are associated with each other and output to the mobile station carrier correspondence control unit 609.

When the mobile station carrier correspondence control unit 609 acquires the mobile station identifier for which the evaluation function showed the highest value and the required transmission rate DRC from the mobile station selection unit 606 provided for each carrier, this The information is output to the downlink transmission buffer section 610 and the downlink dedicated channel transmission section 607. The downlink transmission buffer unit 610 distributes the transmission waiting data of the selected mobile station to the downlink dedicated channel transmission unit 607 provided corresponding to the selected carrier.
Here, the amount of data to be distributed is the amount corresponding to the requested transmission rate DRC acquired in association with the mobile station that is the distribution destination.

Downlink dedicated channel transmitter 60 for each carrier
When the delivery data is acquired from the downlink transmission buffer unit 610, the mobile station 7 generates a downlink dedicated channel transmission signal for the destination mobile station of the acquired downlink data, and this downlink dedicated channel transmission signal is the frequency demultiplexer / combiner 602. Are combined and transmitted from the antenna 601. As a result, downlink data is transmitted to the mobile station with the highest communication quality in each carrier.

2 to 5, the information A is information on the mobile station to be received (identifier, mobile station code, etc.), and information B.
Is information about multi-carrier correspondence, information C is information about a measurement target carrier selected by the mobile station, and information D is the mobile station selection unit 60.
The information in which the mobile station selected by 6, the carrier identifier, and the requested transmission rate DRC are associated, and the information E and F indicate the information in which the mobile station identifier and the received requested transmission rate DRC are associated.

Next, the evaluation function calculated by the evaluation function updating unit 605 provided for each carrier will be described. First, the evaluation function in the carrier fi (i = 1, 2, 3 ...) Can be obtained by the following equation (2). Evaluation function = DRCi / Ri (2) In the above equation, DRCi is the required transmission rate DRC of the carrier fi, and Ri is the average transmission rate of the carrier fi. Further, the average transmission rate of the carrier fi in the slot t is given by the following equation (3). Ri (t) ＝ Ri (t-1) × {1- (1 / tc)} ＋ f (ri (t), A) × 1 / tc (3)

In the above equation (3), Ri (t) is the average transmission rate at time t, Ri (t-1) is the average transmission rate at time t-1, and 1- (1 / tc) is the past average transmission rate. The rate of forgetting the speed (forgetting rate), and 1 / tc is the rate of remembering the newly received downlink (memory rate). Also, f (ri (t), A) is ri (t)
And A, where A is the number of carriers simultaneously monitored by the mobile station and ri (t) is the time t at carrier fi.
Shows the transmission rate for downlink transmission. Below this
The method of setting the term of f (ri (t), A) is explained.

First, the term f (ri (t), A) in the above equation for calculating the average transmission rate is (1) the average transmission rate independently obtained for each carrier (2) the average transmission rate for all carriers The two cases in which the common average transmission rate is obtained by comprehensively determining the rates will be roughly described.

(1) When the average transmission rate is calculated independently for each carrier << Method 1-1 >> As a term of f (ri (t), A), downlink transmission is performed at time t on carriers f1 and f2, respectively. Transmission speed r1
By using (t) and r2 (t), the evaluation function is obtained using the average transmission rate obtained independently for each carrier. For example, taking the mobile station 20a shown in FIG. 1 as an example, the mobile stations 20 in the carriers f1 and f2 will be described.
The evaluation function of a is as follows. R1 (t) = R1 (t-1) × {1- (1 / tc)} + r1 (t) × 1 / tc R2 (t) = R2 (t-1) × {1- (1 / tc)} + R2 (t) × 1 / tc Thus, by setting the average transmission rate to an independent value for each carrier, the required transmission rate D for each carrier is
At the timing when RC becomes maximum, the evaluation function becomes maximum and the downlink signal can be received.

(2) When a common average transmission rate obtained by collectively calculating the average transmission rates of all carriers << Method 2-1 >> Common average transmission obtained by comprehensively obtaining the average transmission rates of all carriers Use speed. For example, as the term of f (ri (t), A), the "carrier average transmission rate" obtained by dividing the total transmission rate of downlink transmission by the number A of monitored carriers is used as shown in the following equation (4). . f (ri (t), A) = {Σri (t)} / A (4) In the above equation, Σri (t) is the total transmission rate of downlink transmission at time t, and A is measured by the mobile station. This is the number of targeted carriers. For example, the mobile station 2 shown in FIG.
0a is taken as an example, the number of carriers measured by the mobile station 20a is 2, the current downlink transmission transmission speed of the carrier f1 is 1.2 Mbps, and the downlink transmission transmission speed of the carrier f2 is 1.2 Mbps. If so, f (ri (t), A) = (1.2Mbps + 1.2Mbps) /2=1.2Mbps (5). Then, by substituting the value of 1.2 Mbps obtained in (5) above into the term of f (ri (t), A) in equation (3), R1
(t) and R2 (t) are obtained respectively, and the evaluation function for each carrier is calculated using the obtained average transmission rates.

<< Method 2-2 >> As the term of f (ri (t), A), the highest transmission rate of the measurement target carriers is used as shown in the following equation (6). f (ri (t), A) = max (ri (t)) (6) For example, taking the mobile station 20a shown in FIG. 1 as an example, the downlink transmission transmission speed of the carrier f1 is 150 kbp.
If the downlink transmission transmission rate of the carrier f2 is 1.5 Mbps, f (ri (t), A) = max (ri (t)) = 1.5 Mbps (7). Then, using the above 1.5 Mbps, f (ri (t), A) in equation (3)
By substituting into the term of
Ri (t) is obtained, and an evaluation function for each carrier is calculated using the obtained average transmission rates.

<< Method 2-3 >> As the term of f (ri (t), A), the sum of downlink transmission transmission rates is used as shown in the following equation (8). f (ri (t), A) = Σri (t) (8) For example, taking the mobile station 20a shown in FIG. 1 as an example, the number of carriers measured by the mobile station 20a is two. Yes, the current downlink transmission transmission rate of carrier f1 is 150 kbps, and the current downlink transmission transmission rate of carrier f2 is
If it is 1.5Mbps, then f (ri (t), A) = 150kbps + 1.5Mbps = 1.65kbps (9). Then, by substituting the value of 1.65 kbps obtained by the equation (9) into the term f (ri (t), A) of the equation (3),
R1 (t) and R2 (t) are obtained respectively, and an evaluation function for each carrier is calculated using the obtained average transmission rates.

The method 2-2 and the method 2-3 described above are used.
Then, ri should be set so that the average transmission rate Ri becomes as high as possible.
(t) is selected. As a result, slots are evenly allocated to each mobile station, but the inherent advantage of multicarrier, which actively transmits downlink data to mobile stations with the best communication conditions, is not utilized.
On the other hand, according to the method 2-1, since the average value per carrier is used, the value of the average transmission rate Ri becomes an average value for each carrier, and while utilizing the advantage of such multicarrier, It is possible to perform downlink data transmission fairly to each mobile station.

<< Other Techniques >> Different carriers (carriers used for data transmission) that have succeeded in downlink reception and carriers that have not succeeded in downlink reception (carriers not used for data transmission) differ in f (ri ( t) and A) are used. For example, for a carrier that succeeds in downlink reception, the transmission transmission rate ri (t) that is uniquely obtained by the carrier used in method 1-1 described above is used as f (ri (t), A), while downlink reception is performed. For the failed carrier, f (ri (t), A) is used with a value smaller than the value of ri (t) used for the carrier that has been successfully received in downlink. As a method of obtaining a value smaller than the value of ri (t) used in the carrier that has succeeded in downlink reception, the minimum value of ri (t) of the carrier that has succeeded in downlink reception is f ( It may be used as ri (t), A), or a value obtained by multiplying this value by a preset numerical value smaller than 1 may be used.

Further, for example, the values to be set for ri (t) are prepared discretely in advance, and among these values, the predetermined step rate set in advance from ri (t) of the carrier that has succeeded in downlink reception. The down value may be used as the common f (ri (t), A) term of the carrier that has failed downlink reception. Specifically, the discretely prepared values are 38.4kbps, 76.8kbps,
157.6kbps, 2.4Mbps, if the ri (t) of the carrier that succeeded in downlink reception is 157.6kbps and it was set to use a value that was downgraded in two steps, common carriers that failed in downlink reception 38.4 kbps is used as the f (ri (t), A) term.

In this way, by setting the set value of the average transmission rate R to be different between the carrier that has succeeded in downlink reception and the carrier that has failed, the average transmission rate in the carrier that has not succeeded in downlink reception can be obtained. It is possible to prevent it from increasing too much, and to prevent the value of the evaluation function in the carrier for which downlink reception has failed from decreasing too much. Therefore, it is possible to increase the possibility of successful downlink reception in a carrier in which downlink reception has failed.

Although the embodiment of the present invention has been described in detail above with reference to the drawings, the specific structure is not limited to this embodiment, and includes a design etc. within the scope not departing from the gist of the present invention. Be done.

[0063]

As described above, according to the base station of the present invention, the carrier allocation for allocating two or more carriers to each mobile station and the required transmission rate corresponding to at least one of the allocated carriers are performed. Received from each mobile station, based on the requested transmission rate received from each mobile station, obtain an evaluation function of each mobile station for each carrier, in each carrier, a mobile station that transmits data for each time division Since it is determined based on the evaluation function, the number of carriers that can be used by one mobile station is increased to a plurality of carriers, and the selection range of mobile stations that perform data transmission using one carrier can be widened. By this means, downlink data transmission can be efficiently performed.

[Brief description of drawings]

FIG. 1 is a wireless network configuration diagram for schematically explaining data communication performed between a base station and a mobile station according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a schematic configuration of a mobile station according to the first embodiment of the present invention.

FIG. 3 is a block diagram showing a schematic configuration of a mobile station according to a second embodiment of the present invention.

FIG. 4 is a block diagram showing a schematic configuration of a mobile station according to a third embodiment of the present invention.

FIG. 5 is a block diagram showing a schematic configuration of a base station according to an embodiment of the present invention.

[Explanation of symbols]

10 ... Base station, 20a, 20b ... Mobile station, 301, 60
1 ... Antenna, 302 ... Downlink dedicated channel receiving unit, 30
3 ... Downlink common channel reception unit, 304, 504 ... Quality evaluation unit, 305, 405, 505 ... Required transmission rate calculation unit,
306 ... Requested transmission rate transmission unit, 307 ... Measurement downlink common channel setting unit, 308, 602 ... Frequency demultiplexer / combiner,
309 ... Uplink dedicated channel transmitting section, 310, 603 ... Carrier-by-carrier processing section, 311 ... Downlink signal combining section, 604 ... Required transmission rate receiving section, 605 ... Evaluation function updating section, 606 ...
Mobile station selection unit, 607 ... Downlink dedicated channel transmission unit, 60
8 ... Downlink common channel transmission unit, 609 ... Mobile station carrier correspondence control unit, 610 ... Downlink transmission buffer unit, 611 ... Mobile station carrier information reception unit

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Takashi Inoue             2-15-1 Ohara, Kamifukuoka City, Saitama Stock             Company CAD Research Institute (72) Inventor Yoshiaki Amano             2-15-1 Ohara, Kamifukuoka City, Saitama Stock             Company CAD Research Institute F-term (reference) 5K022 EE01 EE31                 5K028 AA11 BB04 DD01 DD02 PP04                       RR01 TT02                 5K067 AA01 AA13 BB01 BB21 CC10                       DD45 EE02 EE10 EE22 EE61                       EE71 GG01 GG11 JJ11 JJ21

Claims (10)

[Claims] 1. A base station that transmits transmission data by time division multiplexing to a plurality of mobile stations using a plurality of carriers, and carrier allocating means that allocates two or more carriers to each mobile station. Receiving means for receiving from each mobile station a required transmission rate corresponding to at least one of the assigned carriers, and each mobile station for each carrier based on the required transmission rate received from the mobile station. And a selecting means for determining a mobile station transmitting data for each time division in each carrier based on the evaluation function. 2. Among the plurality of carriers used for data transmission, for one mobile station, two or more carriers having a frequency difference of a predetermined value or more are selected. The base station according to claim 1. 3. The evaluation function is a value obtained by dividing the requested transmission rate notified from the mobile station by an average transmission rate of the mobile station. base station. 4. The base station according to claim 3, wherein the average transmission rate is a value independently obtained for each carrier. 5. The base station according to claim 3, wherein the average transmission rate is a common average transmission rate which is obtained by integrating the average transmission rates of all carriers. 6. The average transmission rate obtained independently for each carrier is used to calculate the evaluation function for the carrier used for data transmission, while the average transmission rate is calculated for the carrier not used for data transmission. The value smaller than the average transmission rate used for calculating the evaluation function in the carrier used for the data transmission is used for calculating the evaluation function.
The base station described in. 7. A receiving means for receiving a plurality of carriers emitted from a base station, a required transmission rate calculating means for obtaining a required transmission rate for each carrier according to a receiving state of each carrier, and each carrier is specified. The mobile station is characterized by further comprising: transmission means for transmitting the information to the base station in association with the required transmission rate of the carrier. 8. Among the plurality of received carriers, two or more carriers having a frequency difference of a predetermined value or more are selected, and the required transmission rate is calculated only for the selected carriers. The mobile station according to claim 7, wherein 9. The notification unit notifies the base station of the requested transmission rate having the highest requested transmission rate and the carrier identification information corresponding to the requested transmission rate. The mobile station according to claim 8. 10. A radio communication method for transmitting transmission data by time division multiplexing to a plurality of mobile stations using a plurality of carriers, the step of allocating two or more carriers to each mobile station, Of the assigned carriers, a step of receiving a request transmission rate corresponding to at least one carrier from each mobile station, and an evaluation of each mobile station for each carrier based on the request transmission rate received from each of the mobile stations A wireless communication method comprising: a step of obtaining a function; and a step of determining a mobile station transmitting data for each time division in each carrier based on the evaluation function.