JP2003110486A - Method of scheduling radio channel, its device, and mobile communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio channel scheduling method which can correspond to a smart antenna base station capable of communicating with a plurality of mobile stations at the same time. SOLUTION: This radio channel scheduling method selects a plurality of mobile stations at the destination of down transmission of a radio base station being equipped with a smart antenna for forming a plurality of beams. At the same time, mobile stations capable of being selected as the object to direct a beam are selected in order of better communication quality, concerning the mobile stations positioned within the coverage of the radio base station.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio channel scheduling method and apparatus suitable for use in a smart antenna base station capable of simultaneously communicating with a plurality of mobile stations, and a mobile communication system using the radio channel scheduling method.

[0002]

2. Description of the Related Art In recent years, there has been a demand for high-speed data communication even in mobile communication due to the spread of the Internet. In order to meet this demand, wireless packet mobile communication systems capable of data transfer by high-speed packet communication are being put to practical use. As such a wireless packet mobile communication system, for example, a technical standard “C.S0024 cdma2000 H” by a standardization organization “3GPP2” is used.
igh Rate Packet Data Air Interface Specification
s "-compliant 1xEV-DO system is known.

In addition, the demand for mobile communications is increasing more and more, and there is an urgent need to improve the mobile station accommodation capacity per base station in a mobile communication system. In order to solve this problem, a mobile communication system to which a smart antenna is applied is known. The smart antenna directs a beam only to an arbitrary mobile station. The technology of this smart antenna is described, for example, in "Adaptive signal processing by array antenna" published by Science and Technology Publishing Company.

FIG. 5 is a diagram for explaining a mobile communication system including a base station equipped with a smart antenna and a mobile station. In the system of FIG. 5, a base station (smart antenna base station) 100 equipped with a smart antenna is used.
However, the beams A1 to A3 of the smart antenna are simultaneously formed individually for the three mobile stations 101 to 103. The smart antenna base station 100 uses these beam A
1 to A3 mobile stations 101 respectively located within the reachable range
It is possible to communicate at the same time as ˜103.

On the other hand, mobile communication systems to which sector antennas are applied are also known. In this mobile communication system, the antenna directivity of the base station is divided into two or more predetermined number of sectors in advance. This sector corresponds to a cell provided by a normal base station. Further, the base station is equipped with sector antenna base station facilities for the number of sectors.

FIG. 6 is a diagram for explaining a mobile communication system including a base station having a sector antenna and a mobile station. In the system of FIG. 6, a base station (three-sector base station) 200 provided with base station equipment for sector antennas for three sectors simultaneously forms beams B1 to B3 of the sector antenna. The three-sector base station 200 can simultaneously communicate with the mobile stations 101 to 103 located within the reach of these beams B1 to B3, respectively.

The smart antenna is superior in the points (1) and (2) between the case where the smart antenna is applied and the case where the sector antenna is applied. (1) The amount of interference between mobile stations accommodated in the same base station is smaller when the smart antenna is applied. The reason for this is that the smart antenna base station can set null (direction in which beam gain is small) for each beam. That is, it is possible to specify a direction in which radio waves are not desired to be transmitted for each beam. As a result, the smart antenna base station can reduce interference between mobile stations by directing null directions between beams formed simultaneously.

On the other hand, the sector base station cannot use the null direction. Therefore, the beams interfere with each other near the boundary between adjacent sectors, which results in CI
R (desired wave signal power to interference wave signal power ratio) deteriorates,
For example, the transmission speed decreases and the communication quality deteriorates. For this reason, when the area per sector is narrowed by dividing into a large number of sectors, the probability that the mobile station is located near the boundary between the sectors becomes high, and the range in which good communication quality can be maintained is small. turn into. This is an obstacle when dividing into a large number of sectors to improve the mobile station accommodation capacity.

(2) When a smart antenna is applied,
Handover within the base station does not occur. The reason is that the smart antenna base station can freely set the direction in which the beam is directed according to the position of the mobile station. Therefore, as long as the mobile station is located within the coverage (service area) of the smart antenna base station, handover within the base station does not occur.

On the other hand, the beam of the sector antenna formed by the sector base station covers a fixed area and does not move. Therefore, every time the mobile station moves and crosses between sectors, an inter-sector handover within the base station occurs. This inter-sector handover is more likely to occur as the number of sectors increases, which causes an increase in the amount of control signal transfer for handover and an increase in the communication delay amount due to sector switching. Further, the consumption of base station resources (CPU processing capacity, memory capacity, etc.) for handover processing increases. This is also an obstacle when dividing into a large number of sectors to improve the mobile station accommodation capacity.

As described above, when the sector antenna is applied, problems such as deterioration of communication quality and an increase in load on the base station occur as the number of sector divisions increases. You can't improve your abilities as you want. Actually, it is said that the upper limit is about 6 sectors per base station.

On the other hand, when the smart antenna is applied, for example, if the width of one beam from the base station is 30 degrees, it is possible to simultaneously form up to 12 beams. It has twice as much mobile station accommodation capacity as the above. Furthermore, since the amount of interference between mobile stations can be reduced by forming a null, it is possible to maintain a good state in terms of communication quality. For these reasons, it is effective to apply a smart antenna in a mobile communication system in order to improve the mobile station accommodation capacity per base station.

[0013]

By the way, in order to apply the smart antenna to the wireless packet mobile communication system, a scheduler function corresponding to the smart antenna is required. The scheduler function is a function of assigning a wireless channel to a mobile station in a wireless packet mobile communication system. Specifically, when a large number of mobile stations are located within the coverage of the base station and the number of mobile stations that can simultaneously communicate with the base station is less than the number of mobile stations within the coverage, communication with the base station is performed. Select the best mobile station to use.

As a scheduling method in the conventional scheduler function, for example, a PF (Proportional Fairness) scheduler method of the 1xEV-DO system is known. For this PF scheduler method, refer to, for example, “IEEE International Conference, VTC 2000 Spring presentation manuscript”
A. Japali, R. Padovani, R. Pankaj, “Data throughputo
f CDMA-HDR a High Efficieney-High Data Rate Person
al Communication Wireless System ””.

However, in this PF scheduler method, one base station can target only one mobile station for downlink transmission, and is compatible with a smart antenna base station capable of simultaneously communicating with a plurality of mobile stations. Not not. Therefore, there is a demand for a scheduling method suitable for smart antenna base stations.

The present invention has been made in consideration of such circumstances, and an object thereof is a radio channel scheduling method and an apparatus thereof capable of supporting a smart antenna base station capable of simultaneously communicating with a plurality of mobile stations. To provide.

Another object of the present invention is to provide a mobile communication system using the radio channel scheduling method.

[0018]

In order to solve the above problems, a wireless channel scheduling method according to a first aspect of the present invention is directed to a downlink transmission destination in a wireless base station equipped with a smart antenna that simultaneously forms a plurality of beams. A radio channel scheduling method for selecting a plurality of mobile stations, the mobile station being located within the coverage of the radio base station, wherein the mobile stations selectable as targets to which the beam is directed are selected in order of good communication quality. It is characterized by including a station selection process.

In the radio channel scheduling method according to the present invention, the mobile station selecting step includes a process of selecting the mobile station on condition that the azimuth difference between the mobile stations is equal to or larger than a predetermined angle. The predetermined angle is determined as a value such that interference between adjacent beams does not affect communication quality.

A radio channel scheduling method according to a third aspect of the present invention is characterized in that the mobile station selecting process includes a process of sequentially selecting from mobile stations having a large evaluation function value which is an index of communication quality.

According to a fourth aspect of the present invention, in the radio channel scheduling method, the mobile station selecting step is a process for suppressing the number of mobile stations having a predetermined low transmission rate, which are simultaneously selected as mobile stations of a downlink transmission destination, to a predetermined upper limit value or less. It is characterized by including.

The radio channel scheduling method according to claim 5 further comprises the step of confirming whether the communication quality of the selected mobile station satisfies the required transmission rate notified from the mobile station. Is characterized by.

The radio channel scheduling method according to claim 6 is characterized in that the communication quality for all the selected mobile stations satisfies the required transmission rate notified from the mobile stations. The method further includes the step of determining the selected mobile stations as transmission destinations for downlink transmission at the same time.

In the radio channel scheduling method according to the seventh aspect, when there is even one mobile station that does not satisfy the required transmission rate, more interference is given to beams for other mobile stations. Deleting the mobile station which is the forming direction of the existing beam from the selected mobile stations,
Alternatively, the method further includes the step of deleting, from the selected mobile stations, the mobile station having the smallest evaluation function value serving as an index of communication quality.

A radio channel scheduling apparatus according to claim 8 is a radio channel for performing mobile station selection processing for selecting a plurality of downlink transmission destination mobile stations in a radio base station equipped with a smart antenna that simultaneously forms a plurality of beams. A scheduling device, wherein the scheduling device comprises:
According to the wireless channel scheduling method described in any one of 1) to 3) above, processing means for executing the mobile station selection processing is provided.

A mobile communication system according to claim 9 comprises a radio base station equipped with a smart antenna for simultaneously forming a plurality of beams, and a plurality of mobile stations located within the coverage of the radio base station. The radio base station selects a plurality of mobile stations as downlink transmission destinations by the radio channel scheduling method according to any one of claims 1 to 7.

[0027]

DETAILED DESCRIPTION OF THE INVENTION An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the configuration of a mobile communication system according to an embodiment of the present invention, to which the radio channel scheduling method of the present invention is applied. In the mobile communication system in FIG. 1, a plurality (m) of mobile stations 2-1 to 2-1 are located within the coverage (service area) of a base station (smart antenna base station) 1 equipped with a smart antenna. The smart antenna base station 1 can simultaneously form the beams of a plurality of smart antennas. In FIG. 1, beams 3-1 and 4 and m-1 of the smart antenna are simultaneously formed individually for the mobile stations 2-1 and 4 and m-1. The smart antenna base station 1 uses these beams 3
It is possible to communicate simultaneously with the mobile stations 2-1, 4 and m-1 respectively located within the reach of -1, 4 and m-1.

The number m of mobile stations is larger than the number n of mobile stations that the smart antenna base station 1 can simultaneously perform downlink transmission. The value of n matches the number of beams that the smart antenna base station 1 can simultaneously form. In the wireless channel scheduling method according to the present embodiment, the smart antenna base station 1 selects a plurality of mobile stations that simultaneously allocate wireless channels and perform downlink transmission from the m mobile stations 2-1 to 2-1. It is a thing. 2 to 4 below
This radio channel scheduling method will be described in detail with reference to.

FIG. 2 is a flow chart showing the flow of processing of the radio channel scheduling method of this embodiment. As shown in the flowchart of FIG. 2, first, a candidate list of mobile stations is created in step S1. In the process of creating this candidate list, m mobile stations 2-1 located within the coverage of the smart antenna base station 1
˜m are arranged in order from the largest evaluation function value.
In the candidate list, the azimuth angles of the mobile stations 2-1 to m (0 indicating the azimuth of the mobile station as seen from the smart antenna base station 1 are shown.
(Any angle of 360 degrees) should be included.

The evaluation function value is a value that is an index of communication quality, and the better the value, the better the communication quality. As this evaluation function value, 1xEV
-The evaluation function "DRC / used in the DO system
The value calculated by "R" is used. “DRC” is the predicted downlink data communication speed notified from the mobile station to the smart antenna base station 1. “R” is the average value of the data communication rates transmitted from the smart antenna base station 1 to the mobile station in the past.

FIG. 3 shows an example of the structure of the candidate list 10. The candidate list 10 of FIG. 3 is an example when the number of mobile stations in the coverage is 14 (m = 14), and the mobile station 2-1
To 14 are arranged in ascending order of the evaluation function values, and mobile stations NO1 to 14 are assigned in order from the largest evaluation function value. In addition, the azimuth angle of each mobile station is also described in association with the mobile stations NO1 to 14.

Next, in step S2, the destination list is initialized. The transmission destination list is a table in which the mobile stations of the transmission destinations to which the smart antenna base station 1 simultaneously performs downlink transmission are described. In the initialization process, the destination list is made empty.

Then, the highest mobile station in the candidate list 10 is moved to the lowest in the destination list and deleted from the candidate list 10 (step S3). In the example of FIG. 3, the mobile station NO1 having the largest evaluation function value corresponds to the highest mobile station. Next, for the mobile station added to the destination list, the azimuth difference between all the upper mobile stations (all the mobile stations already listed in the destination list) is the predetermined angle α or more. It is confirmed (step S4).

The above-mentioned azimuth angle difference is the angle difference between the azimuths of the mobile stations 2-1 to m viewed from the smart antenna base station 1. In FIG. 1, for example, the azimuth difference between the mobile station 2-1 and the mobile station 2-2 is θ ₁ , and the azimuth difference between the mobile station 2-2 and the mobile station 2-3 is θ _2. Is. The azimuth difference between the mobile station 2-1 and the mobile station 2-3 is (θ ₁ + θ ₂ ).
Becomes

The azimuth difference between the mobile stations being equal to or greater than the predetermined angle α is a condition for the combination of mobile stations capable of forming beams at the same time. Further, the predetermined angle α is set to a value such that interference between beams formed adjacently does not affect communication quality. For example, the predetermined angle α is determined so that the mobile station can guarantee the transmission rate requested by the base station (requested transmission rate).

Next, as a result of the confirmation in step S4, if the angle is equal to or greater than the predetermined angle α, the process proceeds to step S5, in which the communication quality of all mobile stations included in the destination list is calculated from each mobile station to the smart antenna base station. It is confirmed whether the requested transmission rate (DRC) notified to 1 is satisfied.

In step S4, the azimuth angle difference between the mobile stations is set to a predetermined angle α or more so as not to cause extreme interference between adjacent beams simultaneously formed by the smart antenna base station 1. However, since the actual propagation environment is complicated, the process of step S5 is performed in order to ensure the communication quality of all mobile stations included in the destination group more reliably.

Next, as a result of the confirmation in step S5, the communication quality of all mobile stations satisfies the required transmission rate, and the number of mobile stations in the destination list reaches the number n of mobile stations that can simultaneously perform downlink transmission. If (the determination result of step S6 is "YES")
In this case), the mobile stations included in the transmission destination list are determined as the transmission destinations for downlink transmission at the same time.

On the other hand, if the result of the confirmation in step S4 is less than the predetermined angle α (if the result of the determination in step S4 is "NO"), or if the result of the confirmation in step S5 is one of the required transmission rates. If there is a mobile station that does not satisfy the condition (if the determination result in step S5 is "NO"), the process proceeds to step S7. In this step S7, the mobile station that has moved to the destination list in this loop (the loop from step S3 to S8) (that is, the mobile station that has moved to the destination list in the process of immediately preceding step S3) is transmitted. Delete from the list.

Next, if there are still mobile stations in the candidate list 10, the process returns to step S3, and if there are no mobile stations in the candidate list 10, the process ends (step S8). In step S6,
Even when the number of mobile stations in the destination list has not reached the number n of mobile stations that can be simultaneously downlink transmitted and the determination result is “NO”, the process of step S8 is performed.

FIG. 4 shows the candidate list 10 shown in FIG. 3 obtained by repeatedly performing the above-mentioned steps S3 to S8 until the number of mobile stations in the destination list reaches the number n of mobile stations. It is a figure which shows the structural example of the transmission destination list | wrist 20, It is an example in case the number of mobile stations which can carry out downlink transmission is 5 (n = 5), and the predetermined angle (alpha) is 15 degrees. This Figure 4
In the destination list 20 of, the mobile station NO, its evaluation function value, and azimuth are described.

As shown in FIG. 4, since the azimuth angle difference between the mobile stations No. 1 to No. 4 is 15 degrees or more, it is described in the destination list 20. However, mobile station NO5
The mobile station No. 7 has an azimuth angle difference of less than 15 degrees with the mobile stations Nos. 1 to 4 and is not listed in the destination list 20. As a result, the mobile station of the mobile station NO8 having an azimuth difference of 15 degrees or more with the mobile stations of the mobile stations NO1 to 4 will be described in the destination list 20, and the mobile stations NO1 to 4 and The five mobile stations of NO8 are determined as the destinations for simultaneous downlink transmission.

In the above-described embodiment, every time the mobile station is moved from the candidate list to the destination list, it is confirmed in step S5 whether the communication quality of all mobile stations satisfies the required transmission rate. However, after moving n mobile stations that satisfy the condition of the predetermined angle α to the destination list, it is necessary to check whether the communication quality of all mobile stations in the destination list satisfies the required transmission rate. May be.

In this case, if even one mobile station does not satisfy the required transmission rate, the mobile stations are deleted one by one according to the following criteria 1 or 2. Then, every time this deletion is performed, the communication quality of all mobile stations is confirmed again. This deletion process is performed until the number of mobile stations in the destination list becomes 1, unless the communication quality of all mobile stations in the destination list satisfies the required transmission rate.

Criterion 1: For beams for other mobile stations,
The mobile station that is in the beam forming direction giving more interference is deleted. Specifically, first, an index function f representing the amount of interference given to another beam is defined. And, the more interference with other beams for mobile stations with large evaluation function values,
Weighting is performed so that the value of the index function f becomes large. The mobile station having the maximum value of the index function f is deleted from the destination list. A definition example of the index function f will be shown.

F = Σ [interference amount i / rank of magnitude of evaluation function value of mobile station NO_i] where i is the mobile station NO in the destination list. The interference amount i is the amount of interference given to the beam for the mobile station of the mobile station NO_i. Σ [X (i)] is the sum of X (i) from i to 1 to the maximum mobile station NO in the destination list.

Criterion 2: The mobile station having the smallest evaluation function value is deleted from the destination list.

In addition, in the above-described embodiment, with respect to mobile stations that can use only a low transmission rate, the upper limit value p may be set for the number of mobile stations selected as downlink transmission destinations at the same time. This is performed in order to prevent the transmission throughput of the entire base station from being lowered by selecting only mobile stations having a low transmission rate. Therefore, the number of low transmission rate mobile stations (mobile stations whose requested transmission rate is smaller than a predetermined value) included in the destination list is counted, and when the number of p mobile stations is reached, the subsequent low transmission rate movement is performed. The station is deleted from the candidate list without moving to the destination list.

As a result, the p-th and subsequent mobile stations whose requested transmission rate is smaller than the predetermined value are not selected as mobile stations for downlink transmission at the same time. Therefore, only mobile stations with a low transmission rate are not selected and the base station is not selected. It is possible to prevent a decrease in transmission throughput of the entire station.

When implementing the radio channel scheduling method of the above-described embodiment, the smart antenna base station 1 is provided with a radio channel scheduling device for performing the processes of each step of the radio channel scheduling method. This radio channel scheduling device is a device for performing mobile station selection processing for selecting a plurality of mobile stations as downlink transmission destinations, and is provided with processing means for executing the mobile station selection processing by the radio channel scheduling method. Is.

Further, this processing means may be realized by dedicated hardware, and is also a program constituted by a memory, a CPU (central processing unit), etc., for realizing a radio channel scheduling function. May be realized by loading the program into a memory and executing the program.

Although the embodiment of the present invention has been described in detail above with reference to the drawings, the specific configuration is not limited to this embodiment, and design changes and the like within the scope not departing from the gist of the present invention. included.

[0053]

As described above, according to the present invention,
For mobile stations located within the coverage of the radio base station,
Since the mobile stations that can be selected as the target to which the beam is directed are selected in descending order of communication quality, it is possible to support a smart antenna base station that can simultaneously communicate with a plurality of mobile stations.

As a result, it is possible to apply the smart antenna to the mobile communication system and to achieve the improvement of the mobile station accommodation capacity per base station, which cannot be achieved by the sector antenna. Furthermore, when a smart antenna is applied, handover within the base station is not necessary and the amount of interference between mobile stations accommodated in the same base station can be reduced, so that the transmission throughput between the base station and the mobile station can be reduced. Effects such as improvement can also be obtained.

According to the second aspect of the invention, the mobile stations are selected on the condition that the azimuth difference between the mobile stations is equal to or larger than a predetermined angle, and the predetermined angles are formed adjacent to each other. Since the interference between the selected beams is determined as a value that does not affect the communication quality, the effect that the communication quality for the selected mobile station can be kept good is obtained.

According to the third aspect of the present invention, the mobile stations having a large evaluation function value, which is an index of communication quality, are sequentially selected. Therefore, the mobile stations are selected by quantitative judgment. It is possible to improve the reliability of the mobile station selection result.

Further, according to the invention of claim 4, with respect to mobile stations having a predetermined low transmission rate, the number of mobile stations simultaneously selected as downlink transmission destinations is controlled to be equal to or less than a predetermined upper limit value. It is possible to prevent a decrease in the transmission throughput of the entire base station without selecting only mobile stations having a rate.

Further, according to the invention of claim 5, it is confirmed that the communication quality of the selected mobile station satisfies the required transmission rate notified from the mobile station. Understanding the communication quality of all mobile stations included in the selected destination group even if it is uncertain whether the expected communication quality can be realized due to the complexity of the actual propagation environment Can be provided.

Further, according to the invention described in claim 6, on condition that the communication quality of all the selected mobile stations satisfies the requested transmission rate notified from the mobile stations, Since the selected mobile stations are determined as the transmission destinations for downlink transmission at the same time, the communication quality of all the mobile stations included in the selected transmission destination group can be more surely guaranteed.

According to the invention described in claim 7, 1
If any mobile station does not satisfy the required transmission rate, the selected mobile station is the mobile station in the beam forming direction that gives more interference to the beams for other mobile stations. Or the mobile station with the smallest evaluation function value, which is an index of communication quality, is deleted from the selected mobile stations, so that the communication quality of the entire base station is optimized. While maintaining the above, it is possible to obtain the effect that the communication quality of all the mobile stations included in the selected destination group can be more surely guaranteed.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a mobile communication system according to an embodiment of the present invention.

FIG. 2 is a flowchart showing a processing flow of a wireless channel scheduling method in the embodiment.

FIG. 3 is a diagram showing a configuration example of a candidate list in the same embodiment.

FIG. 4 is a diagram showing a configuration example of a destination list in the same embodiment.

FIG. 5 is a diagram for explaining a mobile communication system including a base station equipped with a smart antenna and a mobile station.

FIG. 6 is a diagram for explaining a mobile communication system including a base station having a sector antenna and a mobile station.

[Explanation of symbols]

1 smart antenna base station 2-1 to m mobile stations 3-1 to m Smart antenna beam

   ─────────────────────────────────────────────────── ─── 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) 5K067 AA13 BB21 CC08 DD45 EE02                       EE10 EE22 GG01 GG11 JJ17                       JJ66 KK02

Claims (9)

[Claims] 1. A radio channel scheduling method for selecting a plurality of mobile stations of a downlink transmission destination in a radio base station equipped with a smart antenna that simultaneously forms a plurality of beams, the method being located within the coverage of the radio base station. Regarding a mobile station, a radio channel scheduling method comprising a mobile station selection process of selecting a mobile station that can be selected as a target to which the beam is directed in order of good communication quality. 2. The mobile station selection process includes a process of selecting the mobile stations on condition that the azimuth difference between the mobile stations is equal to or more than a predetermined angle, and the predetermined angles are formed adjacent to each other. The radio channel scheduling method according to claim 1, wherein the interference between the beams is determined as a value that does not affect communication quality. 3. The mobile station selection process is performed from a mobile station having a large evaluation function value which is an index of communication quality,
The radio channel scheduling method according to claim 1, further comprising a process of sequentially selecting. 4. The mobile station selecting step includes a process of suppressing the number of mobile stations selected as downlink transmission destinations simultaneously with respect to mobile stations having a predetermined low transmission rate to a predetermined upper limit value or less. The radio channel scheduling method described in. 5. The method according to claim 1, further comprising the step of confirming whether the communication quality of the selected mobile station satisfies the required transmission rate notified from the mobile station. 5. The radio channel scheduling method according to any one of 4 above. 6. The selected mobile stations are simultaneously downlink-transmitted on condition that the communication quality of all the selected mobile stations satisfies the required transmission rate notified from the mobile stations. The radio channel scheduling method according to any one of claims 1 to 5, further comprising a step of determining a transmission destination. 7. When even one mobile station does not satisfy the required transmission rate, a mobile station which becomes a beam forming direction giving more interference to a beam for another mobile station is selected. The method further comprises the step of deleting from the selected mobile stations, or deleting from the selected mobile stations the mobile station having the smallest evaluation function value serving as an indicator of communication quality. The radio channel scheduling method according to claim 6. 8. A radio channel scheduling device for performing mobile station selection processing for selecting a plurality of downlink transmission destination mobile stations in a radio base station having a smart antenna that forms a plurality of beams at the same time. The radio channel scheduling method according to claim 7, further comprising a processing unit that executes the mobile station selection process. 9. A mobile communication system comprising: a radio base station having a smart antenna that simultaneously forms a plurality of beams; and a plurality of mobile stations located within the coverage of the radio base station, wherein the radio base station is A mobile communication system, comprising: selecting a plurality of mobile stations as downlink transmission destinations by the radio channel scheduling method according to any one of claims 1 to 7.