JP2003008494A - Wireless base station - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wireless base station that conducts beam directivity control with other wireless base station so as to suppress occurrence of radio wave interference between cells and enhance a communication state of mobile stations. SOLUTION: The wireless base station does not direct its own direction beam to the azimuth of a mobile station or to the surrounding of its position for a period when the mobile station including the wireless base station as one of hand-off object wireless base stations receives a downlink signal from wireless base stations other than the wireless base station and generates null points to the mobile station so as to avoid deterioration in the speech quality due to radio wave interference.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a radio base station used for cellular mobile communication or the like.

[0002]

2. Description of the Related Art In a radio base station for cellular mobile communication, a method of individually controlling the directivity of a beam for one or more mobile stations in a radio zone has been considered. Further, there is null steering control in which a directional null point is directed in the direction in which an interference wave / interference wave exists. An antenna having these control functions is called an adaptive antenna, an adaptive antenna or a smart antenna, and for example,
A realization method is disclosed in Nobuyoshi Kikuma, "Adaptive Signal Processing by Array Antenna," published by 998 Science and Technology Publishing.

Beam directivity control includes a null steering system in a broad sense of controlling a beam. FIG. 5 shows a development view of the beam when the beam directivity control including the null steering control is performed. In FIG. 5, the radio base station 501 conducts null steering by directing a beam toward the mobile station 51 and directing a null (gain 0) that sets the electric field strength to zero in the direction in which the interfering wave exists.

Further, as shown in FIG. 6A, the radio base station 601 directs a null to the mobile station 62 while directing a beam to the mobile station 61, while FIG.
As shown in, when the beam is directed to the mobile station 62, the null is directed to the mobile station 61.

[0005]

[Problems to be Solved by the Invention] However, in the past,
The beam directivity control as described above in the cellular mobile communication is independently performed for each radio base station. Therefore,
When adjacent radio base stations direct beams simultaneously to mobile stations existing in the same area, these beams cause radio wave interference (inter-cell interference), which causes communication of mobile stations existing in the same area. There was a problem that the condition suddenly deteriorated. For example, as shown in FIG. 7, when the wireless base stations 701 and 702 are installed adjacent to each other and the mobile stations 71 and 72 are in the same direction as viewed from each wireless base station, the wireless base station 701 is the mobile station. If the timing of transmitting the downlink signal to 71 and the timing of transmitting the downlink signal to the mobile station 72 by the wireless base station 702 match,
There is a problem that radio waves are generated by the beams emitted from the respective radio base stations, and the communication quality of the mobile stations 71 and 72 deteriorates.

Further, as shown in FIG. 8, the radio base station 80
1 and the radio base station 802 are installed adjacent to each other, and the mobile station 81 is located at the boundary of both zones, the radio base station 801 directs a beam to the mobile station 81. When the radio base station 802 directs the beam to the mobile station 82 located in the zone of the own station, the radio base station 802 emits the beam to the mobile station 82, and the radio wave leaks to the mobile station 82. Is affected. Specifically, the leaked radio waves of the beam emitted from the base station 802 to the mobile station 82 and the radio base station 80
1 causes radio wave interference with the radio wave emitted to the mobile station 81, which deteriorates the communication quality of the mobile station 81.

The present invention has been made in view of the above circumstances. By performing beam directivity control between radio base stations, the occurrence of radio wave interference between cells is suppressed and the communication state of mobile stations is improved. It is intended to provide a wireless base station.

[0008]

In order to achieve the above object, the present invention provides a radio base station capable of controlling the beam directing direction, in which the overlapping state of the directing beams emitted from the respective radio base stations meets a predetermined condition. There is provided a radio base station characterized by forming a beam pattern so as to satisfy the requirement.

Further, in the radio base station according to claim 1, the predetermined condition is that radio wave interference caused by a directional beam emitted from each radio base station does not cause radio interference to the mobile station. It is characterized by being set.

According to the above configuration, when there is a mobile station receiving a downlink signal from another station, the directional beam is not directed to the mobile stations existing around the mobile station. Therefore, it is possible to reliably prevent the directional beam emitted by the own station from becoming an interference wave of the mobile station. The directional beam is a beam directed to a mobile station that transmits downlink data.

Further, in order to achieve the above object, the present invention provides
Do not direct the directional beam of the own station to the azimuth or position of the mobile station within the period in which the mobile station including the own station as a handoff candidate radio base station is receiving a downlink signal from a radio base station other than the own station There is provided a radio base station characterized by forming a beam pattern.

According to such a configuration, when a mobile station including its own station as a handoff candidate radio base station is receiving a downlink signal from another station, the pointing beam should not be directed to the mobile station. As a result, it is possible to reliably prevent the mobile station from being affected by the radio wave of the directional beam emitted from the mobile station. The directional beam is a beam directed to a mobile station that transmits downlink data.

Further, in the radio base station according to claim 3, the mobile station including its own station as a handoff candidate radio base station receives the downlink signal from a radio base station other than its own station during the movement. It is characterized in that the beam pattern is formed so that the directional beam is not directed to the vicinity of the position where the station exists.

According to this structure, when the own station is set as the handoff candidate radio base station and there is a mobile station receiving a downlink signal from another station, the mobile station receives a beam. The beam is not directed to other mobile stations existing near the mobile station.
Since the directed beam is emitted with a certain width,
Even if you avoid directing a directional beam to a mobile station that is receiving a downlink signal from another station, if your station emits a beam to a mobile station in the immediate vicinity of that mobile station, both Mobile stations are affected by the directional beams emitted from the respective radio base stations, which deteriorates the communication quality. Therefore, when there is a mobile station that is receiving a downlink signal from another station, by not directing the directional beam to the mobile stations existing in the vicinity of that mobile station, It is possible to prevent the beam from becoming an interference wave of the mobile station.

Further, in the radio base station according to claim 3 or 4, within a period during which a mobile station including its own station as a handoff candidate radio base station is receiving a downlink signal from a radio base station other than its own station. In the above, a beam pattern for directing null to the azimuth or position of the mobile station is formed.

According to this structure, the null is directed to the mobile station communicating with the other station without directing the beam. By this means, it is possible to avoid generating an interfering wave that interferes with communication to a mobile station that is communicating with another station, so that it is possible to improve the communication quality of the mobile station.

Further, in the radio base station according to any one of claims 3 to 5, a downlink signal is received from a radio base station other than itself based on the information of the handoff candidate radio base station. It is characterized in that the mobile station that is present is identified.

The information of the handoff candidate radio base station is information in which the information of the radio base station with which the mobile station may receive the downlink signal is registered for each mobile station. More preferably, it is information in which information of several wireless base stations that have a higher possibility of receiving a downlink signal among the wireless base stations that may receive a downlink signal is registered. This information is like a table in which information of wireless base stations that may receive a downlink signal next is registered so that the handoff can be smoothly performed. CDMA mobile phone system standard ARIB STD-53 1.1
An example is the active set disclosed in “Edition”.

Further, in the radio base station according to any one of claims 3 to 6, the position or azimuth of the mobile station is detected based on an upstream signal received from each mobile station. And

In the radio base station according to any one of claims 3 to 7, each mobile station obtains the position information received from the global positioning system,
It is characterized in that the own station detects the position or azimuth of the mobile station receiving the upstream signal.

Further, in the radio base station according to any one of claims 3 to 8, when the number of mobile station candidates to which the null is directed exceeds a null formation limit number of the own station, It is characterized in that a mobile station having a low reception capability is prioritized over a mobile station having a high downlink signal reception capability and a null is directed.

In the radio base station according to any one of claims 3 to 9, when the number of mobile station candidates to which the null is directed exceeds the null formation limit number of the own station, It is characterized in that a mobile station having no adaptive antenna is prioritized over a mobile station having an adaptive antenna to direct the null.

There is a limit to the number of nulls that the radio base station can form. Therefore, when there are more mobile station candidates to which the null is directed than the null formation limit number of the own station, priorities are determined according to a predetermined condition, and nulls are formed in descending order of priority. In the present invention, a mobile station that is easily affected by surrounding interference waves, that is, a mobile station with low reception capability is a mobile station that does not have an adaptive antenna, and an antenna that does not have this adaptive antenna is prioritized to form a null. As a result, the influence of the interference of the radio wave generated by the own station is avoided. This makes it possible to stabilize the communication quality of the mobile station.

[0024]

DETAILED DESCRIPTION OF THE INVENTION An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing a configuration of a radio base station according to an embodiment of the present invention. In the figure, reference numerals 901 to 903 all denote antenna elements. The arrangement of the antenna elements 901 to 903 can be set arbitrarily. Reference numeral 904 is a steering vector calculation unit, which includes antenna elements 901 and 90.
The steering vector is calculated based on the uplink signal received from the mobile station via the mobile stations 2, 903. This steering vector is a vector indicating the direction of the mobile station.

Reference numeral 905 denotes a transmission weighting coefficient calculation unit,
Using the steering vector calculated by the steering vector calculation unit 904 and the handoff candidate base station information acquired from another cellular radio base station or a higher-level station that collectively manages the radio base station, the mobile station that directs the beam is determined. Then, the transmission weight coefficient is determined based on this.

Here, the handoff candidate base station information is
For each mobile station, the information of the wireless base station that may establish communication (the information of the wireless base station that may receive the downlink signal) and the information of the wireless base station that is currently communicating It is a registered table. The station that manages the handoff candidate base station information may be set to be managed by any wireless base station included in the handoff candidate base station information, or by all the wireless base stations, in addition to the above-mentioned upper station. It is possible. In the present invention, the station that manages the handoff candidate base station information may be any station and is not particularly limited. Also, this handoff candidate base station information is registered based on the uplink signal received from the mobile station, and when the information is updated, between the radio base stations or between the radio base station and the upper station. It is assumed that the update information is notified between them and the latest information is always held in each radio base station.

Reference numeral 906 is a transmission unit, which indicates a mobile station in a transmission waiting state in which transmission data has occurred in a transmission weighting coefficient calculation unit 9
05 is notified and the transmission data is output. Reference numeral 907 is a transmission beam pattern forming circuit, and based on the transmission weight coefficient acquired from the transmission weight coefficient calculation unit 905,
The transmission data output from the transmission unit 906 is branched for each antenna element, and the amplitude and phase of each signal are manipulated. Then, the transmission pattern is transmitted to the mobile station via the circulators 111 to 113 and the antenna elements 901 to 903 by the beam pattern formed by the transmission beam pattern forming circuit 907. Here, the weighting coefficient is information containing the amount of change in amplitude and phase operated for each of the antenna elements 901 to 903, and is represented by a complex vector having elements of the number N of antenna elements.

Next, the operation of the radio base station having the above configuration will be described. << First Embodiment >>

First, the radio base station receives an upstream signal from a mobile station existing near its own station (inside its own station zone and near its own zone). These upstream signals are output to the steering vector calculation unit 904 via the antenna elements 901 to 903 of the wireless base station. The upstream signal contains various information such as identification information of the mobile station and radio wave information. The zone is the range within which the radio waves emitted by the radio base station reach.

The steering vector calculation unit 904 obtains the azimuth of the mobile station by performing a predetermined calculation process based on the uplink signal of the mobile station received via the antenna elements 901 to 903. Then, the obtained azimuth information is output to the transmission weighting coefficient calculation unit 905 together with various information of the mobile station.

The transmission weighting factor calculation unit 905 holds the latest azimuth information of the mobile station obtained by the steering vector calculation unit 904 and the latest handoff candidate base station information transmitted from the upper station. . On the other hand, when the transmission unit 906 receives the transmission data, the information of the mobile station is notified as the transmission waiting wireless base station information.

Upon receiving the above notification, the transmission weighting factor calculation unit 905 first refers to the above-mentioned handoff candidate base station information, and the own station is registered as a handoff candidate radio base station, and is currently the own station. Mobile station receiving a downlink signal from a radio base station other than the above (hereinafter, this mobile station is referred to as mobile station X
Called)). Then, the mobile stations located around the mobile station X are extracted from the mobile stations in the transmission standby state notified earlier, and beam weighting processing is performed so as not to direct the directional beam to the extracted mobile stations. That is,
The mobile stations existing around the mobile station X are extracted by comparing the azimuth information of the mobile station X with the azimuth information of the mobile station in the transmission standby state obtained by the steering vector calculation unit 904. Is performed by extracting mobile stations existing within a predetermined angle range set in advance and in a transmission standby state.

By performing the above-mentioned processing, the transmission weighting factor calculation unit 905 determines the beam pattern so that the beam is not directed to the mobile stations located in the periphery of the mobile station X among the mobile stations in the transmission standby state. Weighting,
The result of this weighting is transmitted beam pattern forming circuit 907.
Output to. The transmission beam pattern forming circuit 907 forms and outputs a transmission beam pattern by allocating transmission data to each of the antennas 901 to 903 based on the transmission weight coefficient acquired from the transmission weight coefficient calculation unit 905.
As a result, the transmission data is transmitted to the mobile station via the circulators 111 to 113 and the antenna elements 901 to 903 by the beam pattern formed by the transmission beam pattern forming circuit 907.

Next, the operation of the radio base station according to the above-described first embodiment will be described with a specific example. now,
As shown in FIG. 2, wireless base stations 301 and 302 are installed, and the zone of the wireless base station 301 and the wireless base station 3 are installed.
The mobile stations 31 and 32 exist in the same area near the boundary with the zone 02. Then, the mobile station 31 is currently establishing communication with the radio base station 301. A process performed by the radio base station 302 when the radio base station 302 receives a plurality of transmission data including the transmission data addressed to the mobile station 32 in the above-described state will be described.

The handoff candidate base station information in the above-mentioned state has the registration contents as shown in FIG. That is, in the mobile station 31, the wireless base station 301 is registered as a wireless base station with which communication is established, and the wireless base station 302 is registered as a handoff candidate wireless base station. Further, in the mobile station 32, 301 and 302 are registered as handoff candidate radio base stations.

First, when the transmission weight coefficient calculation unit 905 of the radio base station 302 receives a notification from the transmission unit 906 that a plurality of transmission data including the transmission data addressed to the mobile station 32 has been received, it is shown in FIG. From the handoff candidate base station information, the mobile station 31 is extracted as a mobile station whose own station is registered as a handoff candidate radio base station and which is currently establishing communication with another station. Then, the mobile stations located around the mobile station 31 are extracted from the plurality of mobile stations including the mobile station 32 in the transmission standby state. This process
This is performed based on the azimuth information of the mobile station 31 and the mobile station in the transmission standby state obtained by the steering vector calculation unit 904.

As a result, when the mobile station 32 is extracted as a mobile station in the transmission standby state existing around the mobile station 31, the transmission weighting coefficient calculation unit 905 directs the directional beam to the mobile stations other than the mobile station 32. To determine the transmission weighting factor. In this way, the mobile station in the transmission standby state to which the directional beam is directed becomes a mobile station in which there is no mobile station communicating with a base station other than the local station around the mobile station. Then, when the transmission weight coefficient calculation unit 905 determines the transmission weight coefficient, it outputs the result to the transmission beam pattern forming circuit 907.

In the above-described embodiment, the mobile station (mobile station X) is registered as a handoff candidate radio base station and has established communication with a radio base station other than the own station.
The extraction determination of the mobile stations located in the vicinity of the mobile station was performed based on the direction of the mobile station X. Instead of the determination method based on the direction information, a method of determining based on the amount of radio wave interference. But it's okay. Hereinafter, this method will be briefly described.

First, the transmission weight coefficient calculation unit 905 obtains the transmission weight coefficient for each mobile station other than the mobile station X that is receiving the upstream signal, and determines the transmission beam pattern of each mobile station. calculate. Then, a mobile station that gives radio wave interference in which the obtained transmission beam pattern is equal to or greater than a predetermined numerical value set in the direction of the mobile station X is extracted. Then, the weighting coefficient of the transmission beam pattern is determined so as not to direct the directional beam to the extracted mobile station, and the weighting coefficient is output to the transmission beam pattern forming circuit.

As described above, according to the present embodiment, even if a mobile station is in a transmission standby state, there is a mobile station that is communicating with a radio base station other than the mobile station in the vicinity of the mobile station. If so, the directional beam is not directed to the mobile station. That is, the transmission data is not transmitted to such a mobile station. Then, when the mobile station existing near the mobile station disconnects communication with another wireless base station and the mobile station communicating with the mobile station disappears, the mobile station Transmission data is transmitted by directing a directional beam to the beam. As a result, it is possible to avoid the influence of radio wave interference due to an interference wave or the like on other mobile stations, and improve the communication quality of the mobile station.

<Second Embodiment> In the present embodiment, in order to further reduce the influence of radio interference caused by an interference wave or the like given to a mobile station, it is determined that the beam is not directed in the first embodiment. Form a null for the mobile station. The specific operation will be described below.

For example, as shown in FIG. 4, the radio base stations 401 and 402 are now installed, and the mobile station 41 is located near the boundary between the zones. In such a situation, when the mobile station 41 and the radio base station 401 have established communication, the radio base station 402 determines that the mobile station 4
Point null to 1. The determination of the mobile station 41 is the same as in the above-described first embodiment. Normally, when the beam is directed, leakage occurs in directions other than the direction in which the beam is directed. That is, there is a possibility that leakage radio waves may affect the direction in which the beam is not directed. In the present embodiment, the beam is not directed and the null is directed to the mobile station whose own station is registered in the handoff candidate radio base station and which has established communication with another radio base station. As a result, even if the leaked radio waves are not emitted to the mobile station, the radio interference of the mobile station can be significantly reduced.

By controlling the pointing directions of the beam and the null in this way, it is possible to prevent the mobile station communicating with a radio base station other than the own station from emitting an interfering radio wave, and It is possible to further improve the communication quality of.

There is a limit to the number of nulls that can be formed by the radio base station (hereinafter, this limit number is referred to as a null formation limit number). Therefore, when the number of mobile stations determined to form a null exceeds the null formation limit number, the nulls are formed by giving priority to those that meet a predetermined condition. The priority order of forming the null will be described below.

For example, when there are a plurality of mobile stations (hereinafter referred to as transmitting mobile stations) that are transmitting downlink signals within the zone of the own station, first, the communicating mobile station is first. Form nulls with priority. That is, when the beam is directed to one mobile station, a null is formed to another transmitting mobile station. Then, as a result of directing the null to the mobile station that is transmitting, as described above, if the number of null formation limit is not reached yet, handoff transmission has been received from a radio base station other than the own station, and, A null is formed by giving priority to a mobile station with low reception capability. This is because a mobile station with low reception capability is affected by the communication quality even if the radio interference is such that the mobile station with high communication does not affect the communication quality.

In this way, by giving priority to the mobile station which is easily affected by the radio wave emitted from itself, and directing the null,
It is possible to improve the communication quality of the mobile station and provide a stable communication environment. Examples of the mobile station having low reception capability include a mobile station having no adaptive antenna.

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 includes a design etc. within the scope not departing from the gist of the present invention. Be done. In the above-described embodiment, for example, the case where the mobile station exists near the zone boundary between the two wireless base stations is described. However, instead of this, the mobile station exists near the cell boundary obtained by further dividing the zone. In the case where there exists, the same effect can be obtained by performing the same beam pointing control.

[0048]

As described above, according to the radio base station of the present invention, the handoff candidate base station information is used to link the cellular radio base stations with the mobile station that directs the beam for each transmission beam. By selecting the mobile station that directs the null, it becomes difficult to direct the beam to the mobile stations where the adjacent cellular radio base station is approaching at the same time, and the adjacent cellular radio base station is directed in the direction in which the cellular radio base station directs the beam. By directing nulls, downlink inter-cell interference is reduced. By this means, it is possible to obtain the effect of improving the communication quality of mobile stations located in the cell boundary area where handoff is performed.

[Brief description of drawings]

FIG. 1 is a block diagram showing an internal configuration of a radio base station according to an embodiment of the present invention.

FIG. 2 is a diagram for explaining beam directivity control according to the first embodiment of the present invention.

FIG. 3 is a diagram showing a data structure of handoff candidate base station information.

FIG. 4 is a diagram for explaining beam directivity control according to a second embodiment of the present invention.

FIG. 5 is a diagram for explaining conventional beam directivity control.

FIG. 6 is a diagram for explaining conventional beam directivity control.

FIG. 7 is a diagram for explaining conventional beam directivity control.

FIG. 8 is a diagram for explaining conventional beam pointing control.

[Explanation of symbols]

31, 32, 41, 42, 51, 61, 62, 71, 7
2, 81, 82 ... Mobile stations 301, 302, 401, 402, 501, 601, 7
01, 702, 801, 802 ... Radio base station 100 ... Upper stations 111 to 113 ... Circulators 901 to 903 ... Antenna element 904 ... Steering vector calculation unit 905 ... Transmission weight coefficient calculation unit 906 ... Transmission unit 907 ... Transmission beam pattern forming circuit

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Yoshiaki Amano             2-15-1 Ohara, Kamifukuoka City, Saitama Stock             Company CAD Research Institute (72) Inventor Yoshio Takeuchi             2-15-1 Ohara, Kamifukuoka City, Saitama Stock             Company CAD Research Institute F-term (reference) 5K059 CC02 CC04 DD10                 5K067 AA23 CC24 EE02 EE10 EE23                       EE41 FF03 GG01 GG11 JJ35                       JJ39 KK02 KK03

Claims (10)

[Claims] 1. A radio base station capable of controlling a beam directing direction, wherein a beam pattern is formed such that an overlapping state of the directed beams emitted from the respective radio base stations satisfies a predetermined condition. Station. 2. The predetermined condition is set so that radio interference caused by a directional beam emitted from each radio base station does not cause radio interference to the mobile station. The radio base station according to 1. 3. A radio base station capable of controlling a beam directing direction, wherein a mobile station including its own station as a handoff candidate radio base station receives a downlink signal from a radio base station other than its own station. A radio base station, characterized in that a beam pattern is formed so as not to direct the directional beam of the mobile station to the direction or position of the mobile station. 4. A directional beam for a mobile station including its own station as a handoff candidate radio base station during the period in which it receives a downlink signal from a radio base station other than its own station. The radio base station according to claim 3, wherein the beam pattern is formed so as not to direct the beam. 5. A null is directed to the azimuth or the position of the mobile station within a period in which a mobile station including its own station as a handoff candidate radio base station is receiving a downlink signal from a radio base station other than its own station. The radio base station according to claim 3 or 4, wherein a beam pattern is formed. 6. The mobile station which receives a downlink signal from a radio base station other than its own station is discriminated based on information of a handoff candidate radio base station. The radio base station according to any one of items. 7. The radio base station according to claim 3, wherein the position or azimuth of the mobile station is detected based on an uplink signal received from each mobile station. . 8. The mobile station acquires the position information received from the global positioning system to detect the position or azimuth of the mobile station receiving the upstream signal. The radio base station according to any one of claims 3 to 7. 9. When the number of mobile station candidates to which the null is directed exceeds the null formation limit number of the local station, the mobile station having a low reception capability is prioritized over the mobile station having a high downlink signal reception capability. And directing the null.
The radio base station according to claim 8. 10. When the number of mobile station candidates to which the null is directed exceeds the null formation limit number of the local station, the mobile station without the adaptive antenna is prioritized over the mobile station with the adaptive antenna. The radio base station according to any one of claims 3 to 9, wherein the radio base station causes the null to be directed.