JPWO2005032191A1 - Wireless base station equipment - Google Patents

Abstract

In the radio base station apparatus (1), detection means (23 for detecting a sector antenna (2-i) having a smaller communication load than others among a plurality of sector antennas (2-i: i = 1, 2, 3). ) And the sector antenna (2-i) of the sector antenna (2-i) so as to cover a predetermined area that can be a dead zone such as a peripheral area immediately below the antenna only by the sector antenna (2-i) detected by the detection means (23). And a control means (24) for performing transmission radio wave control. As a result, a predetermined area that can be a dead zone can be covered only by the sector antenna (2-i) having a small communication load, and a connection service equivalent to other areas is suppressed while suppressing frequent handoffs in the predetermined area. Can provide quality.

Description

  The present invention relates to a radio base station apparatus, and in particular, a service area is a peripheral area directly below an antenna that can be a dead zone of a sector antenna provided corresponding to each sector when a radio communication service area is divided into a plurality of sectors. The present invention relates to a radio base station apparatus suitable for use in covering.

FIG. 8 is a block diagram showing the configuration of an antenna system connected to a conventional radio base station apparatus. As shown in FIG. 8, the conventional antenna system is connected to a tower 140 or the like with a mobile station (not shown). Diversity sector antennas 110, 120, and 130 are provided for each of the sectors 100, 200, and 300 when the wireless communication service area is divided into a plurality (three in this case). Note that the shaded areas denoted by reference numerals 101, 201, and 301 indicate the cover areas of the sector antennas 110, 120, and 130, respectively.
In the conventional cell design, the mounting height, tilt angle, azimuth angle, etc. of each sector antenna 110, 120, 130 are adjusted in order to supply the optimum service area. For example, as shown in FIG. 9A In the area (area) 400 immediately below the antenna, there is an area (so-called dead zone) in which radio waves from which sector antennas 110, 120, and 130 do not reach or where the received power intensity required for the mobile station cannot be obtained.
In such a dead zone 400, for example, as shown in FIG. 9B, the prescribed transmission powers of the sector antennas 110, 120, and 130 are all set large to cover the areas 101, 201 of the sector antennas 110, 120, and 130. , 301 can be eliminated by expanding each, but in this case, in the peripheral area 400 immediately below the antenna, the cover areas 101, 201, 301 of the plurality of sector antennas 110, 120, 130 overlap, Since the received power intensity from each of the sector antennas 110, 120, and 130 is about the same, the mobile station is a multiple connection zone where a single mobile station is simultaneously connected to two or more sector antennas. In this case, since the distance difference between each sector antenna 110, 120, and 130 and the mobile station is small and the power intensity order easily changes, inter-sector handoff (handover) operations frequently occur. As a result, the processing load of the system is increased.
Therefore, in the past, cell design has been performed in order to reduce the quality of the call connection service by giving priority to the prevention of frequent handoff operations or to minimize the handoff area directly under the antenna as shown in FIG. 9A. A dead zone 400 is generated, leading to instability of the call connection service.
In order to suppress such instability of the call connection service while suppressing frequent handoff operations, for example, as shown in FIG. 10A and FIG. 10B, a sub antenna 150 is provided and the sub antenna coverage area 500 is insensitive. 11A and 11B, a reflector 160 that receives radio waves from the sector antenna 110 (or 120, 130) and reflects it to the dead zone 400 is installed. It is conceivable to cover the dead zone 400 with the cover area 600.
Alternatively, as shown in FIGS. 12A and 12B, a repeater 170 that relays radio waves from the sector antenna 110 (or 120, 130) is provided, and the dead zone 400 is covered by the cover area 700 of the repeater 170. As shown in FIG. 13A and FIG. 13B, it is conceivable that a complementary base station apparatus 180 is installed and the dead zone 400 is covered by the cover area 800 of the complementary base station apparatus 180.
However, in any case, a dedicated device is separately required to cover the area 400 immediately below the antenna, resulting in an increase in system scale and cost.
In addition, as conventional techniques related to the radio base station apparatus, other than that, Japanese Patent Laid-Open No. 2000-197107 (hereinafter referred to as Patent Document 1), Japanese Patent Laid-Open No. 10-164737 (hereinafter referred to as Patent Document 2), Japanese Patent No. 3290990. There are techniques proposed in Japanese Patent Publication (hereinafter referred to as Patent Document 3), Japanese Patent Application Laid-Open No. 2002-345013 (hereinafter referred to as Patent Document 4), and Japanese Patent Application Laid-Open No. 2003-18640 (hereinafter referred to as Patent Document 5).
Here, in the technology described in Patent Document 1, in a CDMA (Code Division Multiple Access) cellular radio base station of a base station antenna diversity system, at least one antenna of at least two antennas covering the same sector is used. The transmission power of communication from the base station to the mobile station is controlled in a time-varying manner according to the traffic situation of the sector covered by the antenna.
More specifically, when there is a margin of traffic in each sector, the transmission power from the antenna is increased to increase the signal power to interference power ratio of the mobile station and improve the communication quality. When the traffic increases, the transmission power from one antenna is reduced and the diversity effect is partially reduced, but the necessary communication path is secured and the number of mobile stations that can be accommodated in one sector is reduced. Can be avoided.
In addition, according to the technique of Patent Document 1, the number of mobile stations in the handover state in the same sector is monitored, and the transmission power distribution between the antennas covering the same sector is changed to the movement in the handover state in the same sector. By controlling the number of stations to be within the upper and lower limits, the transmission power distribution between the two antennas can be changed to approach the optimum power distribution, and transmission with unnecessary large transmission power can be performed. It can also be avoided.
The technique described in Patent Document 2 divides a service area of one cell base station into a plurality of sectors, and a plurality of transmission antennas, for example, about 2 to 4 transmission / reception antennas based on a positional relationship in movement of a mobile terminal. By switching control to select the system, the number of wires connecting between the transmitting / receiving antennas having directivity and the modulator / demodulator for each sector is reduced, thereby simplifying the system construction.
Furthermore, the technique described in Patent Document 3 recognizes the sector that has received the weakest signal among the signals from the mobile units received via the first and second sectors, and uses the recognized sectors to recognize the mobile unit. By reducing the signal strength of the signal to the SNR, the S / I ratio (Signal to Interference ratio) in a communication system comprising a plurality of base stations, at least one of which is divided into a plurality of sectors, is improved. That's it.
The technique described in Patent Document 4 relates to a radio base station apparatus in a cellular system. The base station apparatus is arranged in a first area composed of a predetermined number of sectors and inside the first area. By performing wireless communication with the mobile station apparatus in a cell configured with a second area composed of a smaller number of sectors than the predetermined number, a plurality of mobile station apparatuses are located in an area (second area) close to the base station apparatus. By reducing the frequency of crossing the sector, the amount of processing related to handover control in the base station apparatus is reduced.
Furthermore, the technique described in Patent Document 5 relates to a CDMA mobile communication system, and is placed in an environment (sector dense area) where mobile terminals can receive transmission signals from an excessive number of base stations / sectors. In this case, the base station controller detects this from the pilot strength report transmitted by the terminal, and performs a hard handover to another carrier frequency having a different sector configuration or base station configuration, thereby enabling stable communication of the terminal. Is realized.
JP 2000-197107 A Japanese Patent Laid-Open No. 10-164637 Japanese Patent No. 3290990 JP 2002-345013 A JP 2003-18640 A

However, none of the techniques described in Patent Documents 1 to 5 described above is intended to eliminate the dead zone generated in the peripheral area immediately below the sector antenna, and suppresses frequent occurrence of inter-sector handoff operations. However, as in the area directly under the antenna, the call connection is equivalent to other areas even in areas where the coverage is overlapped by increasing the transmission power of each sector antenna and expanding each different cover area. It is impossible to provide quality of service.
For example, since the technique described in Patent Document 1 described above relates to transmission power control of a diversity antenna that covers the same sector, it is not planned to cover the peripheral area immediately below the antenna, and the dead zone is eliminated. Can't hope.
The present invention has been devised in view of the above-described problems.In an area that can be a dead zone such as a peripheral area directly under an antenna, an inter-sector sector can be provided without separately preparing a dedicated device for covering the area. An object of the present invention is to provide a call connection service quality equivalent to that of other areas while suppressing frequent handoff operations.

In order to achieve the above object, a radio base station apparatus of the present invention is connected to a plurality of sector antennas respectively covering different sectors when a service area of radio communication with a mobile station is divided into a plurality of sectors, A predetermined area can be overlapped by expanding any of the cover areas by transmitting radio wave control for the plurality of sector antennas, and is characterized by having the following means.
(A) Detection means for detecting a sector antenna having a smaller communication load than the others among the plurality of sector antennas. (B) The sector antenna so as to cover the predetermined area only by the sector antenna detected by the detection means. Further, the radio base station apparatus of the present invention is connected to a plurality of sector antennas respectively covering different sectors when a service area for radio communication with a mobile station is divided into a plurality of sectors. The predetermined area can be overlapped by expanding any of the respective cover areas by transmitting radio wave control for the plurality of sector antennas, and is characterized by comprising the following means.
(A) Detection means for detecting a sector antenna having a smaller communication load than others among the plurality of sector antennas (b) For sector antennas other than the sector antenna detected by the detection means, do not cover the predetermined area For the sector antenna detected by the detection means, the control means for controlling the transmission radio wave so as to cover the predetermined area. Here, the control means transmits from the sector antenna detected by the detection means. It may be configured as transmission power control means for increasing the transmission power of the control signal for the mobile station, or radio wave emission of the control signal for the mobile station transmitted from the sector antenna detected by the detection means It may be configured as radio wave emission angle control means for controlling the angle.
The detecting means is configured as call connection monitoring means for detecting a sector antenna having a smaller number of call connections than others by monitoring the number of call connections of each sector antenna as a sector antenna having a smaller communication load. Is preferred.
Furthermore, the control means includes a multi-connection number monitoring unit that monitors the number of multi-connections that represents the number of calls that are simultaneously connected to two or more sector antennas, and a multi-connection number sector antenna that is monitored by the multi-connection number monitoring unit. If the difference between them exceeds a predetermined threshold, handoff from a sector antenna with a large number of multiple connections to another sector antenna is allowed, and handoff from another sector antenna to the sector antenna with a large number of multiple connections is allowed. You may provide the hand-off control part to refuse.
The control means is monitored by a simultaneous connection number monitoring unit that monitors the number of simultaneous connections indicating the number of paths simultaneously connected to calls connected to two or more sector antennas, and the simultaneous connection number monitoring unit. If the difference between the sector antennas with the number of simultaneous connections exceeds a predetermined threshold, the coverage area of the sector antennas with a small number of simultaneous connections is enlarged and the coverage area of the sector antennas with a large number of simultaneous connections is reduced. Furthermore, a simultaneous connection control unit that performs transmission radio wave control of each sector antenna may be provided.
The predetermined area is preferably an area immediately below the plurality of sector antennas.
Furthermore, the radio base station apparatus of the present invention is a radio base station apparatus connected to n sector antennas respectively provided corresponding to n (n is a natural number of 3 or more) sectors, The predetermined area immediately below the sector antenna can cover the predetermined area by increasing the transmission power for any of the n sector antennas, and includes the following means: Yes.
(A) Detection means for detecting a sector antenna with the least communication load among the n sector antennas (b) Transmission from the sector antenna to the extent that the predetermined area can be covered by the sector antenna detected by the detection means Control means for increasing transmission power of control signal for mobile station or controlling radio wave radiation angle The radio base station apparatus of the present invention is provided corresponding to n sectors (n is a natural number of 3 or more), respectively. A radio base station apparatus connected to the n sector antennas, and by increasing the transmission power for any of the n sector antennas for a predetermined area immediately below the n sector antennas, What can cover the predetermined area is characterized by comprising the following means.
(A) Detection means for detecting a sector antenna with the least communication load among the n sector antennas (b) For a sector antenna other than the sector antenna detected by the detection means, the predetermined area cannot be covered. The transmission power or radio wave radiation angle is controlled so that a control signal for the mobile station is transmitted to the mobile station, and the sector antenna detected by the detecting means is controlled to the extent that the predetermined area can be covered. Control means for controlling transmission power or radio wave emission angle so as to transmit a signal Note that the control signal is preferably a signal used for cell search in the mobile station or a signal used for synchronization detection in the mobile station.

FIG. 1 is a block diagram showing a configuration focusing on a radio base station system of a mobile communication system according to an embodiment of the present invention.
FIG. 2 is a flowchart for explaining the operation (power control) of the radio base station system shown in FIG.
3A and 3B are schematic diagrams for explaining changes in the coverage area of the sector antenna by the power control shown in FIG.
FIG. 4 is a flowchart for explaining the operation (handoff control) of the radio base station system shown in FIG.
5A and 5B are schematic diagrams for explaining changes in the coverage area of the sector antenna by the handoff control shown in FIG.
FIG. 6 is a flowchart for explaining the operation (simultaneous connection control) of the radio base station system shown in FIG.
7A and 7B are schematic diagrams for explaining changes in the coverage area of the sector antenna by the simultaneous connection control shown in FIG.
FIG. 8 is a block diagram showing a configuration of an antenna system connected to a conventional radio base station apparatus.
9A and 9B are schematic diagrams for explaining the cover area of the conventional antenna system.
FIG. 10A is a schematic diagram showing a system configuration example in the case where a sub-antenna is used as means for complementing a peripheral area (dead zone) immediately below an antenna of a conventional antenna system.
FIG. 10B is a schematic diagram showing a cover area of the antenna system shown in FIG. 10A.
FIG. 11A is a schematic diagram showing a system configuration example in the case where a reflector is used as a means for complementing a peripheral area (dead zone) immediately below an antenna of a conventional antenna system.
FIG. 11B is a schematic diagram showing a cover area of the antenna system shown in FIG. 11A.
FIG. 12A is a schematic diagram illustrating a system configuration example in the case where a repeater is used as a means for complementing a peripheral area (dead zone) immediately below an antenna of a conventional antenna system.
12B is a schematic diagram showing a cover area of the antenna system shown in FIG. 12A.
FIG. 13A is a schematic diagram illustrating a system configuration example in the case where a complementary base station apparatus is used as means for complementing a peripheral area (dead zone) immediately below an antenna of a conventional antenna system.
FIG. 13B is a schematic diagram showing a cover area of the antenna system shown in FIG. 13A.

FIG. 1 is a block diagram showing a configuration focusing on a radio base station system of a mobile communication system according to an embodiment of the present invention. As shown in FIG. 1 (which may be simply referred to as “base station system”) 1 is a wireless communication service area with a mobile station (not shown) n (n is usually a natural number of 3 or more, where n = 3). One or more base station apparatuses (BTS: Base Transceiver System) connected to n sector antennas 2-1, 2-2, 2-3 provided corresponding to each sector when divided into sectors (cells) ) 2 and a base station control device (RNC: Radio Network Control Equipment) 3 connected to the base station device 2. Note that the base station control device 3 is normally connected to a plurality of base station devices 2 to centrally control and manage call processing and the like of each base station device 2.
As shown in FIG. 1, the base station apparatus 2 includes transceivers 21-1, 21-2 and 21-3 provided for each sector antenna 2-i, a call processing unit 22, and call connection monitoring. The base station control apparatus 3 includes a transmission unit 31, a call connection monitoring control unit 32, and a call processing control unit 33.
Here, in the base station apparatus 2, each of the sector antennas 2-i (i = 1, 2, 3) is configured as a diversity antenna including two transmitting / receiving antennas 2 having directivity. Wireless signals are transmitted and received between the two. The radio signal includes a control channel (CCH) signal (control signal) for transmitting / receiving control information to / from a mobile station and a traffic channel (TCH: Traffic Channel) for transmitting / receiving user data. As a signal of the downlink common control channel to the mobile station, a signal used for cell search (identification of the base station apparatus 2) in the mobile station or a signal used for synchronization detection in the mobile station (for example, a common pilot channel) In other words, each cover area (radio zone) is formed for each sector antenna 2-i. Each sector antenna 2-i is controlled (transmitted radio wave control) by controlling the transmission power (downlink transmission power) of a control signal (common pilot channel signal) transmitted from the sector antenna 2-i by a power control unit 24 described later. The cover area of 2-i can be controlled (enlarged or reduced).
Each of the transceivers 21-i is connected to the corresponding sector antenna 2-i, and transmits and receives radio signals (control channel signals and communication channel signals) to and from the mobile station. The call processing unit 22 performs call processing for wireless communication with the mobile station via each transceiver 21-i, and the call connection monitoring unit 23 By monitoring the call processing in the call processing unit 22, the number of calls connected in each sector and the number of multi-connections between sectors (the number of calls connected to two or more sector antennas 2-i at the same time) are monitored. Based on the monitoring result, a control instruction is given to the power control unit 24 for transmission power control of each sector antenna 2-i.
Specifically, in the present embodiment, the sector antenna 2-i having the smallest number of call connections is detected, and the transmission power of the sector antenna 2-i (common pilot channel signal transmission power) is directly below the antenna at a constant pace. The power control unit 24 increases so that the surrounding area can be covered, and conversely, the transmission power of the sector antenna 2-i having a large number of call connections is reduced at a constant pace so as not to cover the surrounding area immediately below the antenna. By giving a control instruction, it functions to reduce the gap between the sectors in the number of call connections. At this time, the inter-sector handoff also functions to allow and reject so that there is no difference in the number of multiple connections for each sector.
The power control unit 24 controls (increases / decreases) the transmission power of a signal transmitted from the sector antenna 2-i in accordance with a control instruction from the call connection monitoring unit 23.
That is, the call connection monitoring unit 23 of the present embodiment functions as a detection unit that detects the sector antenna 2-i having the smallest number of call connections (the least communication load) among the sector antennas 2-i, The power control unit 24 functions as a multi-connection number monitoring unit that monitors the number of multi-connections, and the power control unit 24 covers the peripheral area immediately below the antenna only with the sector antenna 2-i detected by the call connection monitoring unit 23 as the detection means. In addition, the sector antenna 2-i functions as a control means for performing transmission radio wave control (transmission power control of a common pilot channel signal as a control signal).
On the other hand, in the base station control device 3, the transmission unit 31 is an interface that is connected to the call processing unit 22 of the base station device 2 and performs transmission and reception of calls and call control signals to and from the base station device 2. The call connection monitoring control unit 32 monitors the number of simultaneous connections of each call (the number of paths in which multi-connected calls are simultaneously connected to the same base station apparatus 2 or a plurality of different base station apparatuses 2). In order to perform transmission power control of each sector based on the monitoring result, control is performed to the power control unit 24 of the base station device 2 via the call processing control unit 33, the transmission unit 31, and the call connection monitoring unit 23 of the base station device 2. In this embodiment, the transmission power of the sector antenna 2-i with a small number of calls with a simultaneous connection number of 3 (3-Way) or more is increased at a constant pace. A section with a large number of connections for a call with 3 connections. The transmission power of the antenna 2-i is decreased at a constant pace, serves to reduce the gap between each sector of concurrent connections.
That is, the call connection monitoring control unit 32 functions as the simultaneous connection number monitoring unit 321 that monitors the number of simultaneous connections, and between the sector antennas 2-i having the number of simultaneous connections monitored by the simultaneous connection number monitoring unit 321. If the difference between the sector antennas exceeds the predetermined threshold, the transmission area of each sector antenna 2-i is expanded so that the coverage area of the sector antenna with a small number of simultaneous connections is enlarged and the coverage area of the sector antenna with a large number of simultaneous connections is reduced. It also has a function as a simultaneous connection control unit 322 that performs radio wave control (control power transmission control).
The call processing control unit 33 controls the call processing by the call processing unit 22 of the base station device 2 via the transmission unit 31 and transmits a control instruction from the call connection monitoring control unit 3 via the transmission unit 31 to the base station device. 2 to the power control unit 24.
Hereinafter, the operation of the base station system 1 of the present embodiment configured as described above will be described in detail.
(1) Power control First, the base station apparatus 2 uses the call connection monitoring unit 23 to, for example, as shown in FIG. 2, sectors X, Y covered by the sector antennas 2-1, 2-2, 2-3, respectively. , Z (see FIGS. 3A and 3B), the number of call connections (Nx, Ny, Nz) is monitored (step A1), and the sector with the smallest number of call connections (for example, X) and the sector with the largest number (for example, Y) And a difference (connection difference) Q1 between the two is extracted (step A2).
Then, the call connection monitoring unit 23 determines whether or not the obtained connection difference Q1 exceeds a preset setting value (threshold value) D1 (step A3), and if not, each sector X, Y, Monitoring of the number of Z call connections is continued (N route in step A3), and if it exceeds, an instruction is given to the power control unit 24 to reduce the transmission power of the sector antenna 2-1 of sector X having a small number of call connections by one step. The transmission power of the sector antenna 2-2 of the sector Y with a large number of call connections is decreased by one step (step A5).
By repeating the above processing, as shown in FIGS. 3A and 3B, the transmission power of the sector antenna 2-1 in the sector X increases at a constant pace, and the cover area 41 is expanded. While the peripheral area 400 immediately below the antenna is covered, the transmission power of the sector antenna 2-2 in the sector Y decreases at a constant pace, and the cover area 42 is reduced (the cover area of the sector antenna 2-3 for the sector Z). No change in 43).
That is, for the sector antennas 2-2 and 2-3 other than the sector antenna 2-1 detected as the sector antenna having the smallest communication load (number of call connections) by the call connection monitoring unit 23, the peripheral area 400 directly below the antenna is covered. Thus, the transmission power is controlled so that the sector antenna 2-1 detected by the call connection monitoring unit 23 is covered so as to cover the peripheral area 400 immediately below the antenna.
As a result, the mobile station 4 located in the peripheral area 400 immediately below the antenna is located in the cover area 41 of the sector antenna 2-1 of the sector X, and the received power from the sector antenna 21 becomes larger than the others. It will be connected only to 2-1.
Therefore, without providing a dedicated device for covering the peripheral area 400 directly below the antenna as in the prior art, the frequent use of the inter-sector handoff operation in the peripheral area 400 directly below the antenna is suppressed, and also in the peripheral area 400 directly below the antenna. It is possible to provide a stable call connection service quality equivalent to other areas.
In the above example, the transmission power of the sector antenna 2-2 with the largest number of call connections is controlled to decrease with the increase in the transmission power of the sector antenna 2-1 with the smallest number of call connections. Even if only the transmission power of the sector antenna 2-1 with the smallest number of connections is increased to such an extent that the peripheral area 400 directly under the antenna can be covered (the transmission power of the sector antenna 2-2 with the largest number of call connections should be maintained). Even so, stable call connection service quality in the peripheral area 400 immediately below the antenna can be provided.
(2) Handoff Control Now, when the transmission power control of the sector antenna 2-i is performed as described above to change the cover areas 41, 42, 43 of the sector antenna 2-i, the sector antenna 2- An inter-sector handoff operation may occur for the mobile station 4 located in a region where the received power from i is substantially the same (multi-connection zone: see, for example, reference numerals 44, 45, 46, and 47 in FIG. 5A) (FIG. 3B). reference).
In such a case, if handoff for the sector antenna 2-i that originally has a large number of call connections (multi-connection number) and a high communication load is permitted, waste of communication resources such as radio channels and a load of call processing increase, and the base station The number of mobile stations accommodated by the device 2 will decrease.
Therefore, the base station apparatus 1 according to the present embodiment performs handoff control according to the procedure shown in FIG. 4 in order to prevent waste of communication resources and increase in call processing load due to such handoff. That is, the base station apparatus 2 monitors the number of multi-connections (Mx, My, Mz) of each sector X, Y, Z (sector antennas 2-1, 2-2, 2-3) by the call connection monitoring unit 23. Then (step B1), the sector having the largest number of multiple connections (for example, X) and the sector having the smallest number of connections (for example, Y) and the difference (connection difference) Q2 between them are obtained (step B2).
Then, the call connection monitoring unit 23 determines whether or not the obtained connection difference Q2 exceeds a preset setting value (threshold value) D2 (step B3). Since there is a difference in the number of connections, as shown in FIGS. 5A and 5B, the mobile station 4 located in the multi-connection zone 44 allows handoff from the sector X with a large number of multi-connections to the sector Y with a small number of multi-connections. (From Y route of step B3 to step B4) If not exceeding (if the disparity is not large), handoff from sector X to sector Y is rejected (from N route of step B3 to step B5).
5A and 5B, when handoff control is performed for mobile stations 4 located in other multi-connection zones 45, 46, and 47, there is a difference in the number of multi-connections in each sector as described above. In addition, handoff to a sector with a small number of multi-connections is allowed, but handoff to a sector with a large number of multi-connections or a sector with no difference in the number of multi-connections is rejected. At that time, the mobile station 4 rejected for handoff communicates while maintaining the connection with the sector antenna 2-i before movement even when moving between sectors.
By performing the handoff control as described above together with the transmission power control described above, even when an inter-sector handoff occurs due to a change in the cover areas 41, 42, 43 of each sector antenna 2-i, The sector antenna 2-i with the least number of call connections can cover the peripheral area 400 immediately below the antenna while suppressing the call connection due to the handoff from being concentrated on the sector antenna 2-i. Therefore, it is possible to efficiently provide stable call connection service quality in the peripheral area 400 immediately below the antenna while suppressing waste of communication resources and an increase in call processing load.
(3) Simultaneous Connection Control Next, simultaneous connection control in the radio base station system will be described in detail with reference to FIGS. 6, 7A and 7B.
7A, reference numeral 48 represents a zone in which three mobile stations 4 are simultaneously multi-connected to sector antennas 2-i of three different base station apparatuses 1, and reference numeral 49 represents one mobile station. The zone 4 is a zone in which multiple connections are made simultaneously to three different sector antennas 2-1, 2-2, 2-3, but such simultaneous connection reduces the communication resources of the base station apparatus 2. It will be wasted.
Therefore, in the present embodiment, in order to reduce such a zone having a large number of simultaneous connections as much as possible, the simultaneous connection control is performed according to a procedure as shown in FIG. 6, for example. That is, the radio base station system 1 monitors the number of simultaneous connections (Wn) of multiple connections of each call by the call connection monitoring control unit 32 of the base station controller 3 (step C1), and the number of simultaneous connections is 3 or more. The sector with the least number of call connections (for example, sector X in FIG. 7A) and the most sector (for example, sector Y in FIG. 7A) and the difference (connection difference) Q3 between them are obtained (step C2).
Then, the call connection monitoring control unit 32 determines whether or not the connection difference Q3 exceeds a preset setting value (threshold value) D3 (step C3). The transmission power of sector Y (sector antenna 2-2) is decreased by one step (from the Y route of step C3 to step C4), and the transmission power of sector X (sector antenna 2-1) is increased by one step (step C5). ). When the connection difference Q3 does not exceed the set value D3, the call connection monitoring control unit 32 repeats the processing from Step C1 (N route of Step C3).
By such simultaneous connection control, as shown in FIGS. 7A and 7B, the cover area 41 of the sector antenna 2-1 having a small number of call connections is expanded, and the peripheral area 400 immediately below the antenna is covered by the cover area 41. At the same time, the cover area 42 of the sector antenna 2-2 is reduced, and the number of zones 48 and 49 in which the number of simultaneous connections is 3 (3-Way) or more can be reduced.
Accordingly, in this case as well, it is possible to efficiently provide stable call connection service quality in the peripheral area 400 immediately below the antenna while suppressing waste of communication resources of the base station apparatus 2 and an increase in the load of call processing. .
As described above, according to the present embodiment, in the mobile communication system having the sectored antenna system, the number of call connections under each sector is monitored, and the mobile station 4 located in the peripheral area 400 immediately below the antenna is connected to the call. The transmission power of the control signal (common pilot channel signal) is controlled for each sector so as to be connected to only one arbitrary sector antenna 2-i having a small number, and the other sector antennas 2 in the peripheral area 400 immediately below the antenna are controlled. Since the sector antenna 2-i that always has little call connection covers the peripheral area 400 immediately below the antenna by providing a power difference from the control signal transmitted from -i, the area 400 can be covered as in the past. Call connection in the peripheral area 400 directly below the antenna while preventing frequent handoffs between sectors without preparing a dedicated device. The quality of service it is possible to stabilize.
In this embodiment, the handoff control described above with reference to FIG. 4 and the simultaneous connection control described with reference to FIG. 6 are used in combination with the transmission power control, thereby suppressing frequent handoff between sectors and an increase in the number of simultaneous connections. Therefore, waste of communication resources and call processing load can be suppressed.
Needless to say, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.
For example, in the above-described embodiment, the sector antenna 2-i that covers the peripheral area 400 directly below the antenna is detected (selected) as the communication load of the sector antenna 2-i based on the number of call connections. For example, the number of mobile stations in communication, total transmission power, total reception power, and the like can be used as the communication load of the sector antenna 2-i.
Furthermore, in the above-described embodiment, the area 400 immediately below the antenna is covered with the sector antenna 2-i having a low communication load, but each sector antenna is located at a location apart from the sector antenna 2-i other than the area directly below the antenna. It is also possible to target an area that can be a dead zone that is covered by overlapping each of the cover areas by transmitting radio wave (power) control for 2-i.
In the above-described embodiment, it is assumed that the handoff control and the simultaneous connection control are used together with the transmission power control of the sector antenna 2-i having the smallest communication load. Can be achieved, and only one of handoff control and simultaneous connection control can be used in combination.
Furthermore, in the embodiment described above, the cover area of the sector antenna 2-i is enlarged / reduced by transmission power control (increase / decrease) of the sector antenna 2-i. Physically control the tilt angle, azimuth angle, etc., or electrically control the polarization state of the transmitted radio wave of the sector antenna 2-i by electrical tilt control, or perform both physical and electrical control thereof. Thus, it is possible to modify the cover area of the sector antenna 2-i (how to spread the transmission radio wave beam) by controlling the radio wave radiation angle of the sector antenna 2-i, which is the same as in the above-described embodiment. An effect can be obtained. In this case, the power control unit 24 (see FIG. 1) controls the radiation of the control signal transmitted from the antenna detected by the call connection monitoring unit 23 as the sector antenna 2-i having a small communication load. What is necessary is just to comprise as an angle control means.

  As described above in detail, according to the present invention, since only the sector antenna with a low communication load covers an area that can be a dead zone like the area immediately below the antenna, while suppressing frequent handoffs in the area, Since connection service quality equivalent to other areas can be provided, it is considered extremely useful in the field of mobile communication technology.

Claims (11)

When the service area for wireless communication with a mobile station is divided into a plurality of sectors, it is connected to a plurality of sector antennas that respectively cover different sectors, and any of the respective coverage areas is controlled by transmission radio wave control for the plurality of sector antennas. Is a radio base station apparatus that can cover a predetermined area by expanding,
Detecting means for detecting a sector antenna having a smaller communication load than the other among the plurality of sector antennas;
A radio base station apparatus comprising: control means for performing transmission radio wave control of the sector antenna so that the predetermined area is covered only by the sector antenna detected by the detection means. When the service area for wireless communication with a mobile station is divided into a plurality of sectors, it is connected to a plurality of sector antennas that respectively cover different sectors, and any of the respective coverage areas is controlled by transmission radio wave control for the plurality of sector antennas. Is a radio base station apparatus that can cover a predetermined area by expanding,
Detecting means for detecting a sector antenna having a smaller communication load than the other among the plurality of sector antennas;
For sector antennas other than the sector antenna detected by the detection means, transmission radio wave control is performed so as not to cover the predetermined area, and for sector antennas detected by the detection means, transmission radio wave control is performed so as to cover the predetermined area. A radio base station apparatus comprising: The control means
The transmission power control means for increasing the transmission power of the control signal for the mobile station that is transmitted from the sector antenna detected by the detection means. The radio base station apparatus described in 1. The control means
3. The radio wave emission angle control means for controlling the radio wave emission angle of a control signal for the mobile station transmitted from the sector antenna detected by the detection means. The radio base station apparatus according to the item. The detection means
The call connection monitoring means is configured to detect a sector antenna having a smaller number of call connections than others by monitoring the number of call connections of each sector antenna as a sector antenna having a smaller communication load. The radio base station apparatus according to any one of claims 1 to 4. The control means
A multi-connection number monitoring unit for monitoring the number of multi-connections representing the number of calls connected to two or more sector antennas simultaneously;
When the difference between the number of multi-connection sector antennas monitored by the multi-connection number monitoring unit exceeds a predetermined threshold, handoff from a sector antenna with a large number of multi-connections to another sector antenna is permitted. 6. The radio base station apparatus according to claim 5, further comprising a handoff control unit that rejects handoff from the sector antenna to the sector antenna having a large number of multiple connections. The control means
A simultaneous connection number monitoring unit for monitoring the number of simultaneous connections indicating the number of paths simultaneously connected to calls connected to two or more sector antennas;
When the difference between the number of simultaneous connections monitored by the simultaneous connection number monitoring unit exceeds a predetermined threshold, the coverage area of the sector antenna with a small number of simultaneous connections is expanded, and the number of simultaneous connections is large. The radio base station according to claim 5 or 6, further comprising a simultaneous connection control unit that performs transmission radio wave control of each sector antenna so as to reduce a coverage area of the sector antenna. apparatus. The radio base station apparatus according to any one of claims 1 to 6, wherein the predetermined area is an area immediately below the plurality of sector antennas. A radio base station apparatus connected to n sector antennas respectively provided corresponding to n sectors (n is a natural number of 3 or more), and for a predetermined area immediately below the n sector antennas, In the radio base station apparatus capable of covering the predetermined area by increasing the transmission power for any of the n sector antennas,
Detecting means for detecting a sector antenna having the least communication load among the n sector antennas;
Control means for increasing the transmission power of the control signal for the mobile station transmitting from the sector antenna or controlling the radio wave radiation angle to the extent that the predetermined area can be covered by the sector antenna detected by the detection means A radio base station apparatus characterized by the above. A radio base station apparatus connected to n sector antennas respectively provided corresponding to n sectors (n is a natural number of 3 or more), and for a predetermined area immediately below the n sector antennas, In the radio base station apparatus capable of covering the predetermined area by increasing the transmission power for any of the n sector antennas,
Detecting means for detecting a sector antenna having the least communication load among the n sector antennas;
For sector antennas other than the sector antenna detected by the detection means, the transmission power or radio wave radiation angle is controlled so as to transmit a control signal for the mobile station to such an extent that the predetermined area cannot be covered, and the detection means The sector antenna detected in the step is provided with control means for controlling transmission power or radio wave radiation angle so as to transmit a control signal for the mobile station to such an extent that the predetermined area can be covered. Wireless base station equipment. The radio base station according to any one of claims 3 to 10, wherein the control signal is a signal used for cell search in the mobile station or a signal used for synchronization detection in the mobile station. apparatus.

Images