JP2003189354A - Subscriber wireless communication system and base station apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a point-multipoint subscriber wireless communication system and a base station apparatus that can reduce the scale of the base station apparatus so as to facilitate its installation and expansion of a modulation demodulation section according to the expansion of a subscriber station apparatus. <P>SOLUTION: A subordinate base station apparatus 3 comprising only indoor devices is connected through wireless channels to master base station apparatuses 2A, 2B each provided with modulation demodulation sections 22a to 22d and connected to a backbone network, uses in common indoor apparatus parts including the modulation and demodulation sections of the master base station apparatuses 2A, 2B, uses a point-point wireless channel to apply non-regenerative relaying to a carrier sent from the master base station apparatuses 2A, 2B and transmits the carrier to a sector whose direction is not overlapped with the wireless channel. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a subscriber wireless communication system and a base station device, and more particularly to facilitating the installation of the base station device and making a capital investment of the base station commensurate with the expansion of the subscriber station device. The present invention relates to a possible subscriber wireless communication system and a base station device.

[0002]

2. Description of the Related Art Generally, as shown in FIG. 12, a point-multipoint subscriber wireless communication system accommodates a plurality of subscriber station devices 1 (1a to 1m) and the plurality of subscriber station devices 1. The subscriber station apparatus 1 is composed of a base station apparatus 2 and a subscriber station apparatus 1.
E802.3, I.D. 431a, etc.)
Having an antenna that mediates wireless communication with the base station device 2, it performs conversion of an electric signal from the user terminal device into a radio signal and conversion of a radio signal from the base station device 2 into an electric signal, The base station device 2 has an antenna 21 that is connected to the backbone network and accommodates a plurality of subscriber station devices, and restores a radio signal received from the subscriber station device 1 to an electric signal and from the backbone network. To convert the electric signal of to the wireless signal.

In such a system, the base station apparatus 2 performs radio transmission with a plurality of subscriber apparatuses 1a to 1m, so that the antenna 2 is located at a position where the subscriber station apparatus 1 can be easily seen.
It is necessary to install a plurality of antennas 1. Therefore, the plurality of antennas 21 usually has a sector configuration.

FIG. 12 shows an example of a 4-sector configuration.
The base station device 2 has 90 degree sector antennas 21a to 21d,
The modulation / demodulation units 22a to 22d and the backbone interface unit 23 are included.

Usually, the antenna 21 and the modulation / demodulation unit 22 are physically separated from each other, so that the two units are connected by a signal cable 24.

Further, the adjacent sectors are arranged so that the radio frequencies for transmission and reception are different from each other so that radio wave interference does not occur.

For this reason, the modulation / demodulation unit 22 has the number of sector antennas, that is, four modulation / demodulation units 22 in a 4-sector configuration, for example, in order to support different radio frequencies.
Is required.

[0008]

From the viewpoint of installing a base station device, if there is a plan to accommodate an unspecified number of subscriber station devices 1 in a certain area (surface deployment), the It is necessary to install a plurality of base station devices 2.

Generally, the installation interval of the base station devices 2 is determined by the number of subscriber station devices 1 that can be accommodated per base station device 2. Therefore, since the base station device 2 is installed systematically from the beginning when the number of subscriber station devices 1 is small, it can be said that the burden of initial investment is large.

From the viewpoint of the configuration of the base station apparatus 2, when it is planned to accommodate a large number of subscriber station apparatuses 1 from the beginning of the installation of the base station apparatus 2, the antennas 21a ...
21d and the modulation / demodulation units 22a to 22d will be installed from the beginning, but at the beginning of installation, the number of subscriber station devices 1 is small,
It is not preferable from the standpoint of initial investment if the expansion is to be done sequentially.

In addition, in a special case where the subscriber station device 1 is unevenly distributed in a specific sector, a method of installing the antenna 21 and the modulation / demodulation unit 22 only in the corresponding sector is conceivable. However, since the subscriber station device 1 exists, the antenna 21 must be installed from the beginning of the installation of the base station device 2.
However, it can be said that it is preferable in terms of capital investment that the modem unit 22 is mounted with units corresponding to the number of installed subscriber station devices 1.

Further, the base station device 2 includes a sector antenna 2
1a to 21d, modulation / demodulation units 22a to 22d, a backbone interface unit 23, and a power supply device (not shown), etc., and a place where the device can be installed cannot always be found according to the plan depending on the scale of the device. , There are places where you have to forgo the service.

Further, in an area where the installation density of the subscriber station devices 1 is expected to be low, the installation interval of the base station devices 2 is widened to increase the coverage area per base station so as to meet the accommodation capacity. However, in this case, it is necessary to extend the transmittable distance of the sector antenna 21, and there are restrictions such as improving the antenna performance and limiting the radio frequency band that can be used for rain attenuation.

Therefore, according to the present invention, the scale of the base station apparatus is kept small to facilitate the installation, and the number of subscriber station apparatuses accommodated in the base station apparatus is small. An object of the present invention is to provide a point-multipoint subscriber wireless communication system and a base station device in which a modulation / demodulation unit can be added in accordance with the addition of a station device.

Further, according to the present invention, even in an area where the installation density of subscriber station devices is expected to be low, the coverage area can be expanded without taking measures such as improving antenna performance. An object is to provide a wireless communication system and a base station device.

Furthermore, the present invention provides a point-multipoint subscriber wireless communication system which enables a subscriber station device to be installed at a place where the base station device is installed and to provide services to the subscriber station device. It is an object to provide a base station device.

[0017]

In order to achieve the above object, the invention according to claim 1 has a plurality of base station devices and a plurality of subscriber station devices respectively accommodated in the base station devices. However, the plurality of base station devices are respectively arranged in a cover area composed of a plurality of sectors, and each base station device is assigned a transmission / reception frequency so that the cover areas do not come into contact with sectors having the same frequency. In a person wireless communication system, a main base station apparatus having a plurality of first antennas and second antennas, which is connected to a backbone network with a modulation / demodulation means and is arranged for each sector of its own station, and a sector of its own station A fourth antenna that is installed to face each of the plurality of third antennas and the second antenna of the adjacent main base station device and that performs wireless transmission with the main base station device. Characterized by comprising a slave base station device with a container.

The invention according to claim 2 is characterized in that, in the invention according to claim 1, the main base station apparatus and the subordinate base station apparatus alternately allocate different frequencies to adjacent sectors.

The invention according to claim 3 is the invention according to claim 2, wherein the main base station device modulates a signal transmitted and received to and from the backbone network into two different frequencies, and the two frequencies are adjacent to each other. And the same frequency as that of the first antenna whose horizontal pointing direction is substantially the same as that of the second antenna is assigned to the second antenna, and the dependent base station device sets the fourth antenna to the fourth antenna. It is characterized in that the frequency of the signal transmitted / received via the antenna is assigned to the third antenna whose horizontal pointing direction is orthogonal to that of the second antenna.

The invention according to claim 4 is the invention according to claim 2, wherein the main base station device modulates a signal transmitted and received to and from the backbone network into two different frequencies, and the two frequencies are adjacent to each other. And the same frequency as that of the first antenna whose horizontal pointing direction is orthogonal to that of the second antenna is assigned to the second antenna.
And the subordinate base station apparatus assigns the frequency of the signal transmitted / received via the fourth antenna to the fourth antenna.
It is assigned to the third antenna having the same horizontal orientation as that of the third antenna.

[0021] According to a fifth aspect of the present invention, in the second aspect of the present invention, the main base station apparatus includes two second antennas for one adjacent subordinate base station apparatus.
And modulating signals transmitted and received to and from the backbone network into two different frequencies, and the two frequencies are
The subordinate base station apparatus has two fourth antennas for one adjacent main base station apparatus, and the subordinate base station apparatus assigns the two second antennas alternately to adjacent sectors. The two fourth antennas are arranged so as to face the two second antennas of the adjacent main base station device, respectively, and the two frequencies which are transmitted and received via the two fourth antennas are adjacent sectors. It is characterized in that they are alternately assigned to.

The invention according to claim 6 is the invention according to claim 1, wherein the dependent base station device receives a radio signal transmitted and received by the third antenna and a radio signal transmitted and received by the fourth antenna. The intermediate frequency signal for non-regenerative repeating is directly distributed to the subscriber station device by wire.

Further, the invention according to claim 7 is a subscriber which is arranged in a cover area composed of a plurality of sectors and which performs point-to-multipoint wireless communication with a plurality of subscriber station devices in the cover area. A primary base station device in a wireless communication system, which mediates wireless transmission between a plurality of first antennas arranged one for each 0 adjacent sectors and a dependent base station device arranged adjacently 2 antennas and connecting means for connecting to the backbone network,
Modulation and demodulation means for modulating a signal received from the backbone network so that at least frequencies of adjacent sectors are different, and demodulating a radio signal received by the first antenna and the second antenna. Characterize.

Further, the invention according to claim 8 is a subscriber which is arranged in a cover area composed of a plurality of sectors and which performs point-to-multipoint wireless communication with a plurality of subscriber station devices in the cover area. A subordinate base station device in a wireless communication system, which is arranged adjacent to a plurality of first antennas arranged one for each adjacent sector,
A second antenna that has a modulation / demodulation means and mediates wireless transmission with a main base station apparatus connected to the backbone network; and a radio signal transmitted and received by the first antenna so that at least frequencies between adjacent sectors are different, and Second
And a relay means for non-regeneratively relaying a radio signal transmitted and received by the antenna as an intermediate frequency signal.

The invention according to claim 9 is characterized in that, in the invention according to claim 8, the relay means directly distributes the intermediate frequency signal to a predetermined subscriber station device.

[0026]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a subscriber wireless communication system and a base station apparatus according to the present invention will be described below in detail with reference to the accompanying drawings.

FIG. 1 is a diagram showing a cell arrangement example of a base station of a subscriber wireless communication system according to the present invention.

In FIG. 1, in the base station, odd-numbered columns (base stations 2A to 2D, and 2H to 2K) and even-numbered columns (base stations 2E to 2G) are vertically displaced from each other by 1/2 cell radius. ing.

In the downlink cell arrangement, carrier signals (frequency F _T1 , F _T2 ) output from the sector antenna are used.
2 occupy the same frequency region every two waves. The carrier wave transmitted from each sector antenna has a frequency F
_T1 is assigned to sectors 1 and 3, frequency F _{T 2} is assigned to sectors 2 and 4, and frequency F _T1 is assigned to sectors 2 and 4 in the even columns.
The frequency F _T2 is assigned to the sectors 1 and 3, and the sectors adjacent to each other in the upper, lower, left, and right have transmission cell arrangements having different radio frequencies.

In the cell arrangement in the upstream direction, each sector antenna is
Carrier signal (frequency F_R1, F_R2)
Shows the same frequency range for every two waves, and the frequency F for odd columns.
_R1Are sectors 1 and 3, frequency F_R2Divided into sectors 2 and 4
Is assigned and the frequency F in even columns _R1Are sectors 2 and 4,
Frequency F_R2Are assigned to sectors 1 and 3
Sectors adjacent to the
Has become.

With such an arrangement, signal interference between sectors can be prevented.

(First Embodiment) FIG. 2 shows the main base station device 2E in the base station cell arrangement of FIG.
FIG. 3 is a block diagram showing an example of a system configuration of a subscriber wireless communication system when it is arranged as a subordinate base station device 3 of A and 2B.

In FIG. 2, the subscriber radio communication system comprises a main base station apparatus 2 (2A and 2B), a dependent base station apparatus 3, subscriber station apparatuses 1a to 1m and 4a to 4m ', 4
n.

The subordinate base station apparatus 3 has an antenna 31 and a signal mixing / mixing unit 35a via radio transmission with the subscriber station apparatus 4.
And 35b and antennas 36a and 36b, and the antenna 31 is a 90-degree sector antenna 31a-3.
It has a 4-sector structure consisting of 1d.

The antenna 31 is the conventional antenna 2
It is functionally the same as 1.

As for the subscriber station device 4n, the subscriber station indoor device 4n-1 is directly accommodated in the signal mix mixer 35a of the subordinate base station device 3 (hereinafter, this state is referred to as direct collection). The base station device 2 includes the sector antennas 21a to 21a.
21d, modulation / demodulation units 22a to 22d, backbone interface unit 23, signal component mixing flow unit 25d, antenna 26.
It consists of

In this subscriber wireless communication system, the four modulation / demodulation units that should originally be included in the subordinate base station device 3 are shared with the modulation / demodulation units 22a to 22d in the main base station device 2, but instead of this. The subordinate base station device 3 uses the signal component blending flow unit 35a to provide two sector antennas 31a,
31c, and is connected to the two sector antennas 31b and 31d using the signal-mixing / flowing device 35b.

In the main base station device 2A, the modulation / demodulation unit 2
2a to 22d are assigned to the sector antennas 21a to 21d in the main base station device 2A, respectively, and
The modulation / demodulation unit 22d is used for modulation / demodulation of the sector antenna 21d, and the sector antenna 31 of the dependent base station device 3 is used.
It is used for modulation and demodulation of a and 31c. Further, the signal component mixing / flowing unit 25d distributes the modulation / demodulation signal from the modulation / demodulation unit 22d to the main base station device 2A and the subordinate base station device 3, and modulates the main base station device 2A and the subordinate base station device 3 from each other. The signals are merged and sent to the modem unit 22d.

In the main base station device 2B, the modulation / demodulation unit 22a has the sector antenna 31 of the subordinate base station device 3.
It is used for modulation and demodulation of b and 31d. Therefore, although the sectors to be handled are different, the functional operation is exactly the same as that of the main base station device 2A.

FIG. 3 is a block diagram showing the detailed construction of the signal mix flow section 25d of the main base station apparatus 2A and the signal mix flow section 35a of the slave base station apparatus 3 shown in FIG.

In FIG. 3, the signal component mixing flow portions 25d, 3
Signal distributors 25d1 and 35a1, which are components of 5a,
The signal combiners 25d2 and 35a2 are functionally the same.

In the main base station device 2A, the modulation / demodulation unit 22d
Modulation signal (frequency f _T2) Is the signal distribution
25d1. Modulation signal (frequency f_T2)
Is divided into two routes here, and the sector antenna 21
d, sent to the antenna 26a. Sector antenna 21
d, at the antenna 26a, the modulated signal (frequency f_T2)
Carrier signal (frequency F_T2) To frequency conversion
Antenna 36a of the subscriber station device 1 and the dependent base station device 3
Send to.

In the subordinate base station device 3, the main base station device 2A
Carrier wave signal sent from (frequency F_T2) Is Ann
The IF signal (frequency f_T2) To frequency conversion
And is sent to the signal distributor 35a1. IF signal
Wave number f_T2) Is divided into three routes here, sector
Antennas 31a and 31c, indoor unit 4n for directly collecting subscriber stations
Sent to -1. With the sector antennas 31a and 31c
Is the IF signal (frequency f _T2) Is a carrier signal (frequency F
_T2) To the subscriber station apparatus 4 and frequency-converted to).

In the subordinate base station device 3, is the subscriber station device 4
Carrier wave signal (frequency F_R2) Is the sector
IF signals (frequency f_R2)
To the signal combiner 35a2.
These two IF signals and the direct collection subscriber station indoor unit 4n-
The signals sent from 1 are collected here in one way.
And sent to the antenna 36a. With antenna 36a
Is the IF signal (frequency f _R2) Is a carrier signal (frequency F
_R2) To the main base station device 2A
It

In the main base station device 2A, the carrier signal (frequency F _R2 ) sent from the subscriber station device 4 is frequency-converted into a modulated signal (frequency f _R2 ) by the sector antenna 21d, and the subordinate base station device is operated. The carrier wave signal (frequency F _R2 ) sent from the frequency converter 3 is frequency-converted into a modulated signal (frequency f _R2 ) by the antenna 26a, and the signal combiner 2
Sent to 5d2. The two modulated signals are collected here in one path and sent to the modulator / demodulator 22d.

Similarly, the combination of the signal component blending flow device 25a of the main base station device 2B and the signal component blending flow device 35b of the dependent base station device 3 is the sector antenna 31 of the dependent base station device 3.
It is used for communication of b and 31d. Although the sector to handle is different,
The functional operation is the same as that of the main base station device 2A.

In the above description, the case where the number of directly-received subscriber station devices is one has been described, but when the number of directly-received subscriber station devices is increased, the signal distributor 3 is used for the downlink direction.
Regarding the number of signal distributions in 5a1 and the upstream direction, the number of signal mergings of the signal merging unit 35a2 may be increased. Further, of course, even when there is no subscriber station device directly collected, the number of signal distributions in the signal distributor 35a1 and the signal combiner 3
The signal merging number of 5a2 can be adjusted to deal with this.

FIG. 4 shows the main base station apparatus 2A shown in FIG.
2B is a diagram showing a cell arrangement example of subordinate base station apparatuses 3. FIG. In particular, FIG. 4A is a cell arrangement example showing the relationship between the main base station device 2A and the dependent base station device 3, and FIG.
3 is an example of cell arrangement showing the relationship between the main base station device 2B and the dependent base station device 3. FIG.

In FIG. 4A, the sector 4 of the main base station device 2A performs wireless transmission with the subscriber station devices 1a to 1m using the sector antenna 21d, and the antenna 26a.
Is used for point-to-point wireless transmission with the subordinate base station device 3.

Here, the sector antenna 21d and the antenna
26a has the same frequency (F_T2, F _R2) Carrier signal
The sector antenna 21d has a tilt angle.
The radio waves are radiated downward from the horizontal.
The tenor 26a is a directional wireless transmission in a substantially horizontal direction.
Therefore, the direction where signal interference does not occur between both antennas
Have a relationship.

The subordinate base station apparatus 3 performs point-to-point radio transmission with the main base station apparatus 2A through the antenna 36a, and the subscriber station apparatus 4 through the sector antennas 31a and 31c.
a-4 m'are wirelessly transmitted. In downlink communication, a carrier signal is received from the main base station device 2A located in the direction of sector 2, the signal is divided into two routes, and the signals are sent in the directions of sectors 1 and 3. Although the carrier signals of the same frequency ( _FT2 ) are used, the antenna 36a and the sector antennas 31a and 31c have different antenna main axis directions,
There is a directional relationship in which signal interference does not occur between these antennas. Further, even in the uplink communication, since the antennas have the same antenna directional relationship, even if carrier signals of the same frequency ( _FR2 ) are used, signal interference does not occur between these antennas.

Similarly, in FIG. 4B, the combination of the antenna 26b of the main base station apparatus 2B and the sector antennas 31b and 31d of the subordinate base station apparatus 3 is used for the communication of the sectors 2 and 4 of the subordinate base station apparatus 3. Be served. Although the sector to be handled is different, the functional operation is the same as that of the main base station device 2A.

In such a system, the signal flow in the downlink direction from the main base station device 2 to the subscriber station devices 1a to 1m is the same signal in each sector unit, and the subscriber station device 1a is the same. It is only necessary to extract the portion addressed to the own station at 1 m to 1 m, but the signal flow in the upstream direction from the subscriber station devices 1a to 1m to the main base station device 2 is not limited to the plurality of subscriber station devices 1a to 1m.
It is necessary to control so that the transmission timing does not overlap every m.

Similarly, there is a method of fixedly allocating the subordinate base station apparatus 3 and the subscriber station apparatuses 4a to 4m 'so that the time slots do not overlap.

FIG. 5 is a diagram showing an example of a frame structure of radio time slots in the sector 4 of the main base station apparatus 2A and the sectors 1 and 3 of the subordinate base station apparatus 3 in the subscriber radio communication system.

In FIG. 5, the radio time slot is composed of a plurality of time slots, and u timeslots form one frame in the downstream direction from the main base station apparatus 2A and the subordinate base station apparatus 3. In the upstream direction from the subscriber station devices 1a to 1m and 4a to 4m ', v time slots form one frame.

Here, there are the following types of time slots.

F: Frame start slot (downstream direction) P: Response slot (upstream direction) A: Reserved slot (upstream direction) R: Random access slot (downstream direction) G: Guard slot (upstream direction) Frame start slot F is , The start position of the downlink frame is shown. Based on this F, the start position of the uplink frame (usually,
The response slot P is placed here). Further, the frame start slot F is paired with the response slot P of the upstream frame, and the main base station apparatus 2A collects status information of the subscriber station apparatuses 1a to 1m and 4a to 4m '.
The control is performed, and this also includes the type determination control of each time slot.

The reserved slot A is assigned to the main base station device 2A and is the subscriber station devices 1a to 1m and 4a to.
It is a time slot for every 4 m ', and the subscriber station device 1
The time slot position of the reserved slot A is determined for each of a to 1 m and 4a to 4m '.

The random access slot R is a time slot to which destination information is appropriately added by the main base station apparatus 2A and which is sent to each of the subscriber station apparatuses 1a to 1m and 4a to 4m '.

The guard slot G is a buffer slot and is used to prevent signal collision with the reserved slot A following the response slot P.

As for the v time slots in the upstream direction, in the example shown in FIG. 5, v-3 slots excluding the 3 time slots used for the response slot P and the guard slot G are equally distributed in 3 sectors to reserve slots. We use for A.

The subscriber station devices 1a and 1b are accommodated in the sector 4 of the main base station device 2A, and the subscriber station device 4a
Is in the sector 1 of the dependent base station device 3 and is in the subscriber station device 4b.
Are accommodated in the sector 3 of the dependent base station device 3. Upstream signals are sent to the corresponding sector antenna 21.
Although the signals are received at d, 31a, 31c, the respective subscriber station devices 1a-1m and 4a-4m 'raise signals only in the assigned time slots, so that the sector antennas 21d, 31a, 31c are used. But the signal junction 2
The signals do not overlap even with 5d2 and 35a2.

The allocation of the time slots is entrusted to the main base station device 2A, and management is performed so that the sum of the communication speeds of the respective subscriber station devices 1a to 1m and 4a to 4m 'does not exceed the radio transmission band. Has been done.

In this way, by controlling the allocation of the time slots between the main base station device 2A and the subscriber station devices 1a to 1m and 4a to 4m ', one main base station device 2A can control a plurality of times. Subscriber station devices 1a-1m and 4a-
It can accommodate 4m '. The main base station device 2
In the other sectors of A (sectors 1 to 3), the main base station device 2A uses the entire frame to accommodate the subscriber station device 1.

In the above embodiment, the total number of sectors in the radio transmission section of the main base station device 2A and the subordinate base station device 3 covered by one modulator / demodulator 22d is set to 3, and the number of slots is evenly distributed in each sector. Although the case is given as an example, even if the number of sectors is different from this and the number of slots is not evenly distributed, it is possible to share a plurality of sectors by sharing the modulation / demodulation unit using a similar method. .

For example, when the number of subscriber station apparatuses accommodated by the sector 4 of the main base station apparatus 2A is larger than the number of subscriber station apparatuses accommodated by the sectors 1 and 3 of the subordinate base station apparatus 3, respectively. Of v-3 slots excluding the three time slots used for the response slot P and the guard slot G, half of the slots are allocated for the sector 4, and the remaining half are equally distributed to the other two sectors. In some cases, it may be convenient to distribute the number of slots unevenly. this is,
Of course, the same can be applied to a method of allocating slots to subscriber station devices in the same sector.

(Second Embodiment) FIG. 6 shows the main base station device 2E in the base station cell arrangement of FIG.
It is a block diagram which shows another example of a system configuration of a subscriber radio | wireless communications system when arrange | positioning as the subordinate base station apparatus 3 of A and 2B.

It is to be noted that, in FIG. 6, description of portions having the same configuration as the subscriber radio system shown in FIG. 2 will be omitted. Further, although the direct-acquisition subscriber station device 4n is not particularly shown and the description thereof is omitted, the direct-receipt subscriber station device 4n can also be directly-acquired similarly to the subscriber radio system of FIG.

The subscriber wireless communication system shown in FIG. 6 differs from the subscriber wireless communication system shown in FIG.
The modulation / demodulation unit 22a of the main base station device 2A is used for modulation / demodulation of the sector antennas 31b, 31d of the dependent base station device 3, and the modulation / demodulation unit 22d of the main base station device 2B for modulation / demodulation of the sector antennas 31a, 31c of the dependent base station device 3. Is to be served.

FIG. 7 is a diagram showing a detailed configuration of the signal component blending flow unit 25a of the main base station device 2A and the signal component blending flow unit 35b of the dependent base station device 3 shown in FIG.

In FIG. 7, the signal mix flow sections 25a, 3
Signal distributors 25a1 and 35b1, which are components of 5b,
The signal combiners 25a2 and 35b2 are functionally the same.

In the main base station device 2A, is the modulation / demodulation unit 22a?
Modulation signal (frequency f _T1) Is the signal distribution
To the container 25a1. Modulation signal (frequency f_T1)
Is divided into two routes here, and the sector antenna 21
a, sent to the antenna 26a. Sector antenna 21
a and the antenna 26a, the modulated signal (frequency f_T1)
Carrier signal (frequency F_T1) To frequency conversion
Antenna 36b of the subscriber station device 1 and the dependent base station device 3
Send to.

In the subordinate base station device 3, the main base station device 2A
The carrier wave signal (frequency F _T1 ) sent from the antenna is frequency-converted into an IF signal (frequency f _T1 ) by the antenna 36b and sent to the signal distributor 35b1. The IF signal (frequency f _T1 ) is divided into two routes here and sent to the sector antennas 31b and 31d. The sector antennas 31b and 31d frequency-convert the IF signal (frequency f _T1 ) into a carrier signal (frequency F _T1 ) and transmit it to the subscriber station device 4.

In the dependent base station device 3, the carrier signal (frequency F _R1 ) sent from the subscriber station device 4 is IF signal (frequency f _R1 ) at the sector antennas 31b and 31d.
To the signal combiner 35b2.
These two IF signals are now collected in one path and sent to the antenna 36b. The antenna 36b converts the IF signal (frequency f _R1 ) into a carrier signal (frequency F
_R1 ) is frequency-converted and transmitted to the main base station device 2A.

In the main base station device 2A, the carrier signal (frequency F _R1 ) sent from the subscriber station device 4 is frequency-converted into a modulated signal (frequency f _R1 ) by the sector antenna 21a, and the subordinate base station device is operated. The carrier wave signal (frequency F _R1 ) sent from the frequency converter 3 is frequency-converted into a modulated signal (frequency f _R1 ) by the antenna 26a, and the signal combiner 2
5a2. The two modulated signals are collected here in one path and sent to the modulator / demodulator 22a.

Similarly, the combination of the signal component blending flow device 25d of the main base station device 2B and the signal component blending flow device 35a of the subordinate base station device 3 is the sector antenna 31 of the subordinate base station device 3.
a, 31c is used for communication. Although the sector to handle is different,
The functional operation is the same as that of the main base station device 2A.

FIG. 8 shows the main base station device 2A shown in FIG.
2B is a diagram showing a cell arrangement example of subordinate base station apparatuses 3. FIG. In particular, FIG. 8A is a cell arrangement example showing the relationship between the main base station device 2A and the dependent base station device 3, and FIG.
3 is an example of cell arrangement showing the relationship between the main base station device 2B and the dependent base station device 3. FIG.

In FIG. 8A, the sector 4 of the main base station device 2A performs wireless transmission with the subscriber station devices 1a to 1m by using the sector antenna 21d, and the antenna 26a.
Is used for point-to-point wireless transmission with the subordinate base station device 3. The sector antenna 21d uses carrier wave signals of frequencies ( _FT2 , _FR2 ) and the antenna 26
Since a uses carrier signals of frequencies (F _T1 , F _R1 ), signal interference does not occur between both antennas.

The subordinate base station apparatus 3 performs point-to-point radio communication with the main base station apparatus 2A through the antenna 36a, and performs radio transmission with the subscriber station apparatuses 4a to 4m 'through the sector antennas 31b and 31d. For downlink communication, the main base station device 2A located in the sector 2 direction
The carrier signal is received from, and the signal is divided into two routes and sent in the directions of sectors 2 and 4. Here, the dependent base station device 3
Sector 2 has an antenna 36a and a sector antenna 31b.
_Uses a carrier signal of the same frequency (F _T1 ),
The sector antenna 31b irradiates radio waves downward from the horizontal by providing a tilt angle, and the antenna 36a is a radio transmission in a substantially horizontal direction having directivity, so that signal interference does not occur between both antennas. It has a directional relationship. Further, even in the communication in the upstream direction, since the antenna direction relationship is similar, signal interference does not occur between these antennas even if carrier signals of the same frequency (F _R1 ) are used.

Similarly, in FIG. 8B, the combination of the antenna 26b of the main base station device 2B and the sector antennas 31a and 31c of the subordinate base station device 3 is used for the communication of the sectors 1 and 3 of the subordinate base station device 3. Be served. Although the sector to be handled is different, the functional operation is the same as that of the main base station device 2A.

FIG. 9 is a diagram showing an example of a frame structure of radio time slots in the sector 1 of the main base station apparatus 2A and the sectors 2 and 4 of the subordinate base station apparatus 3 in the subscriber radio communication system.

In FIG. 9, the radio time slot is composed of a plurality of time slots, and u time slots form one frame in the downstream direction from the main base station apparatus 2A and the subordinate base station apparatus 3. In the upstream direction from the subscriber station devices 1a to 1m and 4a to 4m ', v time slots form one frame.

In the example shown in FIG. 9, the v time slots in the upstream direction are reserved slots by equally distributing the v-3 slots except the 3 time slots used for the response slot P and the guard slot G in 3 sectors. We use for A.

The subscriber station apparatuses 1a and 1b are housed in the sector 1 of the main base station apparatus 2A, and the subscriber station apparatus 4a
Is in the sector 2 of the dependent base station device 3 and is in the subscriber station device 4b.
Are accommodated in the sector 4 of the dependent base station device 3. Upstream signals are sent to the corresponding sector antenna 21.
Although the signals are received by a, 31b, and 31d, the respective subscriber station devices 1a to 1m and 4a to 4m 'raise signals only in the assigned time slots, so that the respective sector antennas 21a, 31b, and 31d. But the signal junction 2
The signals do not overlap even with 5a2 and 35a2.

The allocation of the time slots is entrusted to the main base station apparatus 2A, and management is performed so that the sum of the communication speeds of the respective subscriber station apparatuses 1a to 1m and 4a to 4m 'does not exceed the radio transmission band. Has been done.

In this way, by performing the time slot allocation control between the main base station device 2A and the subscriber station devices 1a to 1m and 4a to 4m ', one main base station device 2A can control a plurality of times. Subscriber station devices 1a-1m and 4a-
It can accommodate 4m '. The main base station device 2
In the other sectors of A (sectors 2 to 4), the main base station device 2A uses the entire frame to accommodate the subscriber station device 1.

(Third Embodiment) FIG. 10 shows the main base station device 2E in the base station cell arrangement of FIG.
FIG. 6 is a block diagram showing another example of the system configuration of the subscriber wireless communication system when it is arranged as the dependent base station device 3 of A.

It is to be noted that, in FIG. 10, description of portions having the same configuration as the subscriber radio system shown in FIG. 2 will be omitted. Further, although the direct collection subscriber station device 4n is not shown in the figure and the description thereof is omitted, it is of course possible to directly collect the subscriber station device 4n like the subscriber radio system of FIG.

The subscriber wireless communication system shown in FIG. 10 differs from the subscriber wireless communication system shown in FIG.
The dependent base station device 3 is dependent only on the main base station device 2A, and is used for modulation / demodulation of the sector antennas 31b and 31d.
The modulation / demodulation unit 22a of A is provided, and the sector antenna 31a,
That is, the modulation / demodulation unit 22d of the main base station device 2A is used for the modulation / demodulation of 31c.

In the main base station device 2A, the modulation / demodulation unit 22
a to 22d are sector antennas 2 in the main base station device 2A.
1a to 21d, and the modulation / demodulation unit 22d is used for modulation / demodulation of the sector antenna 21d and the sector antenna 31 of the dependent base station device 3 is provided.
The modulation / demodulation unit 22a is used for modulation / demodulation of the sector antenna 21a, and is also used for modulation / demodulation of the sector antennas 31b, 31c of the slave base station device 3. The signal mixing / mixing unit 25d distributes the modulation / demodulation signal from the modulation / demodulation unit 22d to the main base station device 2A and the subordinate base station device 3, and also modulates the main base station device 2A and the subordinate base station device 3 to each other. Modulation and demodulation unit 2
2d, and the signal component flow section 25a is connected to the modulation / demodulation section 22a.
The modulated signal from the main base station device 2A and the dependent base station device 3 are distributed, and the modulated signals from the main base station device 2A and the dependent base station device 3 are merged and sent to the modulator / demodulator 22a.

The combination of the signal mix flow section 25d of the main base station device 2A and the signal mix flow section 35a of the subordinate base station device 3 in FIG. 10 is used for communication of the sector antennas 31a and 31c of the subordinate base station device 3. The detailed configuration thereof is the same as that described in FIG. 3, and the signal component blending flow device 25a and the signal component blending flow device 35d of the dependent base station device 3 are used.
Is the sector antenna 3 of the dependent base station device 3.
It is used for communication of 1a and 31c, and its detailed configuration is the same as that described in FIG.

FIG. 11 shows the main base station apparatus 2A shown in FIG.
3 is a cell arrangement example showing the relationship between the subordinate base station device 3 and the subordinate base station device 3.

In FIG. 11, the sector 4 of the main base station device 2A uses the sector antenna 21d to make the subscriber station device 1
a to 1 m and wireless transmission is performed, and the dependent base station device 3 is respectively used by using the antenna 26a and the antenna 26b.
And point-to-point wireless transmission.

[0095] Here, although the sector antenna 21d and the antenna 26a is used a carrier signal of the same frequency _{(F T2, F R 2)} , the sector antenna 21d is a radio wave irradiated downward from the horizontal to provide a tilt angle In addition, since the antenna 26a is a radio transmission having a directivity and in a substantially horizontal direction, the antenna 26a has a directional relationship such that signal interference does not occur between both antennas. Further, since the antenna 26b handles frequencies different from those of the sector antenna 21d and the antenna 26a, signal interference does not occur between these three antennas.

The subordinate base station apparatus 3 performs point-to-point radio communication with the main base station apparatus 2A through the antenna 36a and the antenna 36b, respectively, and radio transmission with the subscriber station apparatuses 4a through 4m 'through the sector antennas 31a through 31d. It is carried out. For downlink communication, the antenna 36
a receives a carrier signal of frequency (F _T2 ) from the main base station device 2A located in the direction of sector 2, divides this signal into two routes and sends it to the directions of sectors 1 and 3, and also the antenna 36b receives the carrier signal of the frequency ( _FT1 ) from the main base station apparatus 2A located in the direction of sector 2, divides the received signal into two routes, and sends them in the directions of sectors 2 and 4.

Here, the sector 2 of the dependent base station device 3 is
The antenna 36b and the sector antenna 31b use a carrier signal of the same frequency ( _FT1 ), but the sector antenna 31b is provided with a tilt angle and radiates radio waves downward from the horizontal, and the antenna 36a is directional. Since the wireless transmission is performed in a substantially horizontal direction, the directional relationship is such that signal interference does not occur between both antennas. Further, even in the communication in the upstream direction, since the antenna direction relationship is similar, signal interference does not occur between these antennas even if carrier signals of the same frequency (F _R1 ) are used.

The radio time slots in the sector 4 of the main base station apparatus 2A and the sectors 1 and 3 of the subordinate base station apparatus 3 and the sector 1 of the main base station apparatus 2A of the subscriber radio communication system shown in FIG. Also, the frame configurations of the radio time slots in the sectors 2 and 4 of the dependent base station device 3 are the same as those shown in FIGS.

A method of subordinating the subordinate base station device 3 with the four main base station devices 2A, 2B, 2H, and 2I is also possible. In this case, the sector 1 of the main base station device 2B and the subordinate base station device 3 are subordinate to each other. Of the main base station device 2I and the sector 3 of the subordinate base station device 3 share the modulator / demodulator 22a.
, And the sector 3 of the main base station device 2H and the sector 4 of the subordinate base station device 3 share the modulator / demodulator 22c, and the sector 4 of the main base station device 2A and the subordinate base station device 3 are shared.
In this case, one modulation / demodulation unit covers two sectors, for example, the sector 1 of FIG.

The modulation / demodulation units 22a to 22d are not limited to be shared by the main base station apparatus 2 and the dependent base station apparatus 3, and for example, a method is provided in which the modulation / demodulation section dedicated to the dependent base station apparatus 3 is provided. Is also possible. In this case, the corresponding sectors of the main base station apparatus 2 and the dependent base station apparatus 3 can use full slots.

Further, the dependent base station device 3 does not need to fully support four sectors, but it is also possible to support only the sectors which are expected to accommodate the subscriber station device 4. Similarly, the main base station device 2 is not limited to the 4-sector configuration.

[0102]

As described above, according to the present invention, the main base station apparatus is provided with the modulation / demodulation section and the backbone interface section, which have a large circuit scale and are difficult to install outdoors, for a plurality of base stations. Installation where the size of the dependent base station device is kept small to facilitate installation, and the number of subscriber station devices that can be accommodated in the main base station device is small. It is possible to increase the number of departments, which brings about the effect that the capital investment of the base station corresponding to the number of subscriber station devices becomes possible.

Further, by centrally installing a constituent unit having a large circuit scale and a severe MTBF value, such as a modulator / demodulator, it is possible to perform centralized control of equipment and improve maintainability.

Further, according to the present invention, the main base station device and the dependent base station device are cascade-connected to improve the antenna performance even in an area where the installation density of subscriber station devices is expected to be low. It is possible to expand the cover area without taking measures such as the above.

Further, when the installation density of subscriber station devices increases in the future, the location where the subordinate base station device is installed is additionally provided with a modulation / demodulation unit, backbone interface unit, power supply unit, etc. It is also possible to upgrade to a device.

Further, originally, since the modulation / demodulation unit is not provided at the place where the dependent base station device is installed,
The subscriber station device cannot be installed, and the provision of service has to be postponed to such a subscriber station. However, according to the present invention, such a subscriber station device is given priority. By directly accommodating the subordinate base station device, it is possible to provide a service to the subscriber station installed in the place where the subordinate base station device is installed.

[Brief description of drawings]

FIG. 1 is a diagram showing a cell arrangement example of a base station according to the present invention.

FIG. 2 is a diagram showing an example of a system configuration of a subscriber wireless communication system according to the present invention.

FIG. 3 is a block diagram illustrating a detailed configuration of frequency conversion units of the main base station device and the dependent base station device shown in FIG.

FIG. 4 is a diagram showing a cell arrangement example of the two main base station apparatuses and one dependent base station apparatus shown in FIG.

5 is a diagram showing an example of a frame structure of a radio time slot in the subscriber radio communication system shown in FIG.

FIG. 6 is a diagram showing another example of the system configuration of the subscriber wireless communication system according to the present invention.

7 is a block diagram illustrating a detailed configuration of a frequency conversion unit of each of the main base station apparatus and the dependent base station apparatus illustrated in FIG.

FIG. 8 is a diagram showing a cell arrangement example of the two main base station apparatuses and one dependent base station apparatus shown in FIG.

9 is a diagram showing an example of a frame configuration of radio time slots in the subscriber radio communication system shown in FIG.

FIG. 10 is a diagram showing another example of the system configuration of the subscriber wireless communication system according to the present invention.

11 is a diagram showing an example of cell arrangement of the main base station device and the subordinate base station device shown in FIG.

FIG. 12 is a system configuration diagram of a conventional subscriber wireless communication system.

[Explanation of symbols]

1a-m, 4a-m ', 4n Subscriber station equipment 2A to K Base station device 21a-d sector antenna 22a-d modulator / demodulator 23 Backbone interface section 24 signal cable 25a, 25d signal flow mixer 25a2, 25d2 signal junction 25a1, 25d1 signal distributor 26a, 26b antenna 3 Subordinate base station equipment 31a-d sector antenna 35a, 35b Signal flow mixer 35a1, 35b1 signal distributor 35a2, 35b2 signal combiner 36a, 36b antenna

Claims (9)

[Claims] 1. A plurality of base station devices and a plurality of subscriber station devices respectively accommodated in the base station devices, wherein the plurality of base station devices are each included in a cover area composed of a plurality of sectors. In a subscriber wireless communication system in which each base station device is assigned a transmission / reception frequency so that the coverage area does not contact between sectors of the same frequency, it is connected to the backbone network with modulation / demodulation means A main base station apparatus having a plurality of first antennas and a second antenna arranged for each sector of the above, and a plurality of third antennas arranged for each sector of the local station and an adjacent main base station apparatus A subordinate base station apparatus having a fourth antenna installed opposite to the second antenna and performing radio transmission with the main base station apparatus. Communication system. 2. The subscriber radio communication system according to claim 1, wherein the main base station apparatus and the subordinate base station apparatus alternately allocate different frequencies to adjacent sectors. 3. The main base station device modulates a signal transmitted / received to / from the backbone network into two different frequencies, alternately allocates the two frequencies to adjacent sectors, and horizontally directionally with the second antenna. The same frequency as that of the first antenna having substantially the same direction is assigned to the second antenna, and the dependent base station device sets the frequency of the signal transmitted and received via the fourth antenna to the second antenna. The subscriber wireless communication system according to claim 2, wherein the third wireless antenna is assigned to the third antennas whose horizontal pointing directions are orthogonal to each other. 4. The main base station device modulates a signal transmitted / received to / from the backbone network into two different frequencies, alternately allocates the two frequencies to adjacent sectors, and the second antenna and the horizontal direction The same frequency as that of the first antenna whose directions are orthogonal to each other is assigned to the second antenna, and the dependent base station device sets the frequency of a signal transmitted / received via the fourth antenna in a horizontal direction with the fourth antenna. The third in the same direction
3. The subscriber wireless communication system according to claim 2, wherein the subscriber wireless communication system is assigned to each antenna. 5. The main base station device has two second antennas for one adjacent base station device, and modulates a signal transmitted / received to / from the backbone network into two different frequencies. , The two frequencies are alternately allocated to adjacent sectors and are respectively allocated to the two second antennas, and the dependent base station device comprises: the fourth antenna for one adjacent main base station device; And the two fourth antennas are respectively arranged to face the two second antennas of the adjacent main base station device, and the two fourth antennas transmit and receive via the two fourth antennas. 3. The subscriber wireless communication system according to claim 2, wherein two frequencies are alternately allocated to adjacent sectors. 6. The IF for non-regeneratively relaying the radio signal transmitted and received by the third antenna and the radio signal transmitted and received by the fourth antenna, in the dependent base station device.
2. The subscriber wireless communication system according to claim 1, wherein the signal is directly distributed to the subscriber station device by wire. 7. A main base station device in a subscriber wireless communication system, which is arranged in a cover area composed of a plurality of sectors and performs point-to-multipoint wireless communication with a plurality of subscriber station devices in the cover area. And a plurality of first antennas, one for each adjacent sector, and a second antenna for mediating radio transmission with a dependent base station device, which is adjacently connected, and connected to the backbone network Connecting means for modulating the signal received from the backbone network so that at least frequencies between adjacent sectors are different, and modulating / demodulating means for demodulating a radio signal received by the first antenna and the second antenna. A main base station device comprising: 8. A subordinate base station apparatus in a subscriber wireless communication system, which is arranged in a cover area composed of a plurality of sectors and performs point-to-multipoint wireless communication with a plurality of subscriber station apparatuses in the cover area. In addition, a plurality of first antennas, one for each adjacent sector, and a main base station device, which is arranged adjacently and has a modulation / demodulation means and is connected to the backbone network, are used for mediating radio transmission. A relay for non-regeneratively relaying an intermediate frequency signal between a second antenna and a radio signal transmitted / received by the first antenna and a radio signal transmitted / received by the second antenna so that at least frequencies between adjacent sectors are different. And a dependent base station device. 9. The dependent base station apparatus according to claim 8, wherein the relay unit directly distributes the intermediate frequency signal to a predetermined subscriber station apparatus.