JPH09148981A - Spectrum effective use method and communication system using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To effectively use a frequency by controlling the radiation directivity of a radio wave between a base station and moving stations. SOLUTION: The base station B concentratedly monitors and controls a call with the moving stations M1-4 in a single radio zone. The base station allocates the same carrier frequency F1 to the respective moving stations M1, M3 and M4 in detached places and radiates the radio wave of sharp directivity in a target direction with transmission power sufficient for arrival. Thus, an inconvenience does not occur in communication since the communication radio waves of the respective moving stations do not interfere one another. Since the moving station M2 is near the moving station 1, a frequency F2 is allocated to the moving station M1 and mutual interference is avoided. Thus, the plural moving stations in the zone can simultaneously make communication with one frequency and the number of channels which can be allocated to the zone can be increased. Thus, a spectrum can effectively be used by re-using the frequency in the zone.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technique for effectively utilizing spectrum, that is, frequency. The present invention also relates to a communication system to which such a method is applied, and particularly to a mobile communication system that communicates via a base station.

[0002]

2. Description of the Related Art In wireless communication, since one space is shared by radio waves, radio waves of the same frequency cannot be used at the same place at the same time for the same purpose (propagation direction). That is, once the radio wave is emitted, the use of others must be restricted, and this use must be done in an orderly manner under certain rules.

In view of such a point, a single zone configuration (a large zone configuration) in which one service area is covered by one base station and a multiple zone configuration (a small zone configuration in which one service area is covered by a plurality of base stations) There is a communication system that adopts a zone configuration) to make effective use of frequencies. here,
A zone refers to a physical range in which a base station can communicate, and is also called a wireless zone or a cell, to which a predetermined frequency assigned to the zone is allocated. In addition to the omni-zone configuration in which the base station radiates radio waves in a non-directional manner in a horizontal plane, the small zone configuration includes a sector-shaped sector that emits radio waves in a horizontal plane with directivity such as 90 degrees and 120 degrees. ) There is a zone structure. As such a system in which the service area is divided into small zones, that is, micro-cellization or sectorization, specifically, there are a cellular system and an MCA system.

However, with the rapid increase in demand for wireless communication today, further effective use of frequencies is desired.

[0005]

SUMMARY OF THE INVENTION In view of the above-mentioned problems, it is an object of the present invention to provide a method and a communication system capable of further effectively utilizing frequencies.

[0006]

A spectrum effective utilization method according to the present invention is a spectrum effective utilization method for allocating a predetermined frequency to at least one radio zone,
In one of the wireless zones, the radiation directivity of the radio wave of the base station to the mobile station is controlled toward the position of the mobile station, and the radio wave radiation of the radio wave of the mobile station to the base station is directed toward the position of the base station. It is characterized by controlling directivity.

A communication system according to the present invention is a communication system having a base station and a mobile station that transmit and receive radio waves at a frequency assigned in at least one radio zone, and in one of the radio zones, the base station Controls the radiation directivity of radio waves to the mobile station toward the position of the mobile station, the mobile station controls the radiation directivity of radio waves to the base station toward the position of the base station. It has a feature.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS As a more detailed mode of the above-mentioned effective use of spectrum, in one of the wireless zones, a base station radiates radio waves of a designated downlink frequency toward the position of the first mobile station to the first mobile station. The directivity is controlled, and the radiation directivity of the radio wave of the designated uplink frequency to the base station of the first mobile station is controlled toward the position of the base station, and at the same time, the first directivity of the base station toward the position of the second mobile station is controlled. The radiation directivity of the radio wave of the same downlink designated frequency to the two mobile stations is controlled, and the radiation directivity of the radio wave of the same uplink designated frequency to the base station of the second mobile station is controlled toward the position of the base station ( 1-
1). Further, in this aspect, the first mobile station-base station channel and the second mobile station-base station channel are in a state where substantially no mutual interference occurs (1-2).

Further, in the above communication system, the base station controls the radiation directivity toward the position of a new mobile station to be connected at the same frequency as the frequency used for the channel in communication, and transmits the radio wave. Only when it is determined that the radiation does not substantially interfere with the channel being communicated, the same frequency is assigned to the new mobile station for transmission and reception of radio waves to the new mobile station and directed to the position of the new mobile station. The mobile station controls the radiation directivity, generates an assigned frequency signal indicating the same frequency and a control signal for controlling the radiation directivity of the radio wave to the base station of the new mobile station, and transmits the control signal to the mobile station. However, it is possible to adopt a mode in which the assigned frequency signal and the control signal are received, the radiation directivity is controlled accordingly, and the radio wave is transmitted / received to / from the base station (2-1). Here, the base station is still in communication even if it radiates radio waves while controlling the radiation directivity toward the position of the new mobile station to be connected at the same frequency as that used for the channel in communication. If it cannot be determined that it does not substantially interfere with, the different frequency that is not used in the channel being communicated in the local station is assigned to the transmission and reception of radio waves to the new mobile station and the new mobile station position is set. In addition to controlling the radiation directivity toward the mobile station, it is preferable to generate an allocation frequency signal indicating a different frequency and a control signal for controlling the radiation directivity of the radio wave to the base station of the new mobile station, and transmit this to the mobile station. (2-2).

As one mode of the above communication system, a GPS can be provided in a mobile station to obtain position information of the mobile station, and a position signal corresponding to the position information can be transmitted to a base station (2-3). ). The radiation directivity control can target radio waves having a frequency assigned to the communication channel (2-4). In addition to directivity control, the base station is based on the position of the new mobile station and the received electric field strength of the radio wave from the new mobile station or the received electric field strength of the radio wave from the base station at the new mobile station. , Determines the degree of line-of-sight in the propagation of radio waves to the mobile station, controls the width of the radiation beam at the local station according to the degree of line-of-sight, and generates a determination line-of-sight signal indicating the degree of line-of-sight To the mobile station, and the mobile station can further control the width of the radiation beam at the mobile station in response to the decision line-of-sight signal (2-5). In addition to the width of this radiation beam, the base station further controls the transmission power of radio waves to the new mobile station in its own station according to the degree of line-of-sight or the width of the radiation beam, and the mobile station judges whether it has received it. It is also possible to further control the transmission power at the local station according to the line-of-sight signal (2-6). The control of the radiation characteristic including the directivity can be realized by array antennas used in the base station and the mobile station (2-
7). When the wireless zone includes a plurality of small zones, the communication system can perform the above-described control of radiation directivity for each of the small zones (2-8).

[0011]

The present invention will be described in detail below with reference to the drawings. First, a basic spectrum effective utilization method will be described. FIG. 1 shows an example of communication in a service area in a single wireless zone, that is, a large zone configuration. In this case, the base station B centrally monitors and controls the call status with the mobile stations M1 to M4 in the zone. The channel or carrier frequency assigned to this zone is FDMA (Frequency Division Multiplexed).
Access: frequency division multiplex connection) and the like, one is generally allocated to one mobile station by the base station and communication with each mobile station is performed, but in the present invention, a predetermined number of required transceivers are provided in the base station. It is possible to allocate one carrier frequency to two or more mobile stations and to communicate with each mobile station. The method is based on the base station B and the mobile stations M1 to M1.
That is, the transmission focus of the radio wave of M4 is appropriately controlled according to the positions of the mobile stations M1 to M4.

That is, the mobile stations M1, M3 and M4 are
As shown in the drawing, the base stations B are located at distant positions, and in such a state, the same carrier frequency F1 is assigned to these mobile stations. Then, the base station B narrows the focus toward the mobile station M1 and radiates a radio wave when communicating with the mobile station M1, and the mobile station M3 when communicating with the mobile station M3.
When the communication with the mobile station M4 is performed, the focus is narrowed toward the mobile station M4 and the radio wave is emitted toward the mobile station M4. The mobile stations M1, M3 and M4 are
At the time of communication with the base station, radio waves are radiated by narrowing the focus toward the base station B. Specifically, narrowing down the focus includes radiating a radio wave with a sharp directivity in a target direction, and radiating a radio wave with a transmission power sufficient to reach the target position. The alternate long and short dash line in FIG. 1 schematically shows the narrowing down of the base stations to the mobile stations. The mobile stations M1, M3, and M4 have a positional relationship such that the communication radio waves of the mobile stations do not cause mutual interference due to focus narrowing control. It is possible to carry out the communication without any trouble.

On the other hand, the mobile station M2 is located near the mobile station M1, and in such a state, the base station B allocates the carrier frequency F2 different from that of the mobile station M1 to the mobile station M2.
This is because if the carrier frequency F1 is assigned to the mobile station M2, the communication waves of the mobile stations M1 and M2 will interfere with each other even if the base station B and the mobile stations M1 and M2 perform focus narrowing control. It is done to avoid that.
Therefore, as described above, the same carrier frequency is assigned only to mobile stations that are in a positional relationship or state in which each communication radio wave does not cause mutual interference due to focus narrowing control, and different carrier frequencies are assigned to other mobile stations. Of.

With such a method, a plurality of mobile stations in a large zone can simultaneously communicate with one carrier frequency, and the number of channels that can be assigned to the zone can be increased. Further, this corresponds to the fact that the frequency is reused within the zone, so that the intended further use of the spectrum can be achieved.

FIG. 2 shows an example in which communication of a service area is performed in a plurality of wireless zones, that is, small zone configurations. In this case, a regular hexagonal zone is adopted as the small zone, and the service area is covered or spread with many small zones (cells). The base stations B1 to B7 perform state monitoring and control of calls with mobile stations within the service area in a distributed manner for each small zone. The channel or carrier frequency is assigned to each small zone. Also in this case, basically, one for one mobile station in one small zone.
Although one carrier frequency is allocated by the base station to perform communication with each mobile station, in the present invention, one carrier frequency is assigned to two or more mobile stations in one small zone to communicate with each mobile station. It can be carried out. The method is to perform narrowing-down control of base stations and mobile stations in the large zone of FIG. 1 in the small zone as well.

Therefore, similar to the above, a plurality of mobile stations in a small zone can simultaneously communicate with one carrier frequency, and the number of channels that can be assigned to the zone can be increased, so that in each small zone. The frequency will be reused and the intended purpose will be achieved. 1 and 2 have been described on the assumption that they have an omni-zone configuration, the method described above can of course be applied even if the zone configuration has a sector zone configuration.

To implement this method more specifically, the following modes can be adopted. 1. Narrow down control is performed on the communication (call) channel,
Not done on the control channel. 2. Mobile stations use GPS (Global Positioning System)
), Etc., and transmits its current position to the base station via a control channel.

3. The base station controls the radiation directivity toward the target mobile station and sends out the carrier wave of the communication channel. 4. The mobile station controls the radiation directivity toward the base station,
The carrier of the communication channel is transmitted. 5. The base station uses the position information of the mobile station and the received electric field strength of the radio wave from the mobile station to determine the visibility of the radio wave propagation (such as the building or terrain that is an obstacle to the radio wave propagation between the base station and the mobile station. There is a certain degree, or how much the propagating radio wave diffracts to reach the partner station). When it is determined that the visibility is good, the base station and the mobile station increase the degree of sharpness of the radiation directivity in accordance with the degree, and otherwise decrease the degree of sharpness.

6. The base station and the mobile station radiate radio waves with transmission power that is inversely or substantially inversely proportional to the degree of sharpness of radiation directivity. As a result, power consumption of each station can be saved and interference with other stations can be reduced. 7. The base station stores required data of the position of each mobile station in communication and the degree of focus reduction (direction of radiation beam in radiation directivity and degree of sharpness and transmission power (or degree of line-of-sight)). . When a mobile station to communicate with newly appears, the base station allocates a channel to the new mobile station based on the stored data, the position information of the new mobile station, and the degree of visibility. More specifically, if it is determined that interference will not occur if narrowing control is performed even if the carrier frequency of the communication channel currently in use is assigned to the new mobile station, the communication channel currently in use for the new mobile station The carrier frequency is assigned, and the communication with a new mobile station is started together with the narrowing control. vice versa,
If it is determined that interference will occur even if narrowing control is performed if the carrier frequency of the communication channel currently in use is assigned to the new mobile station, the carrier frequency of the communication channel currently in use for the new mobile station Allocates another carrier frequency and starts communication with a new mobile station with narrowing control.

8. The radiation directivity of each station is controlled by using an antenna whose focus can be narrowed down, such as an array antenna, for both the mobile station and the base station. Next, an application example of the above-described spectrum effective utilization method will be described. FIG. 3 shows a TDM according to the present invention in such an application example.
1 shows the configuration of an A (Time Division Multiple Access) communication device.

In FIG. 3, a phased array having variable directional characteristics including a radiation direction of a radio wave and a radiation beam shape.
Antenna 1 is an antenna for both transmission and reception, and has a TDD
(Time Division Duplex) method is adopted. The signal terminal of the antenna 1 is connected to the receiving unit 3 via the antenna switch 2.
And the transmission unit 4, and the control terminal of the antenna 1 is connected to the CPU 19 described later. In this example, the antenna switch 2 makes the selection of connection with the receiving unit 3 a steady state.

In the receiving section 3, the high frequency signal which is the signal received by the antenna 1 and passed through the antenna switch 2 is band-limited by the band limiting filter (BPF) 5 and then supplied to the high frequency amplifier 6. The signal amplified by the high frequency amplifier 6 is supplied to the down converter 8 via the band limiting filter 7. The down converter 8 performs frequency conversion to mix the supplied high frequency signal with the local oscillation signal from the VCO 9 to generate an intermediate frequency signal. The intermediate frequency signal is digitized by the A / D converter 10 and then supplied to a DSP (digital signal processor) 11.

The DSP 11 detects the supplied digitized intermediate frequency signal. That is, in order to detect a baseband signal such as a voice signal and a control signal included in the received signal, for example, a 16QA
M demodulation processing is performed to obtain demodulated data, which is supplied to the channel coding logic circuit 12. In addition to the demodulation process, the DSP 11 also verifies, for each bit (or each sample), whether or not a preamble pattern has arrived in the received signal, and establishes frame synchronization. The channel coding logic circuit 12 decomposes the demodulated data from the DSP 11 into each frame for each time slot designated by the CPU 19, and converts the communication data in the demodulated data into a voice code.
The control data in the demodulated data is transferred to the C (codec) 21 or the data input / output interface 22 to the CPU 19. This time slot decomposition in the channel coding logic circuit 12 involves operation as a decoder for decoding the demodulated data. The data transferred to the voice CODEC 21 is converted into an analog signal there, and is acoustically output from the speaker 26 through the speaker amplifier 24.
If the communication data is voice data, voice CODEC
If it is other than audio data, it is supplied to the data input / output interface 22.

On the other hand, the analog voice signal from the microphone 25 is transmitted to the voice CO through the microphone amplifier 23.
It is supplied to the DEC 21. The voice CODEC 21 digitizes the supplied audio signal in a predetermined format to generate a digital audio signal, and supplies it as communication data to the channel coding logic circuit 12. The channel coding logic circuit 12 is further supplied from the data input / output interface 22 with a digital signal of a predetermined format as communication data. The channel coding logic circuit 12 sends the communication data from the voice CODEC 21 or the data input / output interface 22 to the CP.
It is inserted in the time slot designated by U19. The insertion into this time slot is accompanied by an operation as a coder that performs a predetermined code conversion. The output data of the channel coding logic circuit 12 thus obtained is the DSP 1
Transferred to 1. The DSP 11 inserts the preamble pattern into a predetermined time slot in the frame according to the designation from the CPU 19, forms a series of transmission data together with the transfer data from the channel coding logic circuit 12, and, for example, the above-mentioned 16QA for the transmission data.
Modulation processing based on M is performed. The data obtained by the modulation processing is supplied to the transmission unit 4.

The transmitting section 4 converts the data received from the DSP 11 into an analog signal in the D / A converter 13 and supplies it to the up converter 14 as an analog signal. The up-converter 14 mixes the supplied signal with the oscillation signal from the VCO 15 to perform frequency conversion into a frequency to be transmitted. The frequency-converted signal is amplified by the pre-stage amplifier 16, further power-amplified by the power amplifier 17, and supplied to the antenna 1 through the antenna switch 2 to be radiated.

The CPU (central processing unit) 19 also controls various processing including modulation and demodulation processing of the DSP 11, and antenna control and channel allocation control described later. The switching operation of the antenna switch 2, the oscillation frequency of the VCOs 9 and 15 and the amplification operation of the power amplifier 17 are performed by the DSP 1
Controlled by the operating state of 1. The CPU 19 controls the DSP 11 according to the operation from the keyboard 20, and also controls the channel coding logic circuit 12 and the voice C.
It also controls each operation mode of the ODEC 21.

From the down converter 8, RSSI (Received Signal Strength Indicato) indicating the received electric field strength is displayed.
r) A signal is emitted and supplied to the CPU 19 via an interface (not shown). Such a configuration is adopted in both the base station (or master station) and the mobile station (slave station), but the configuration adopted in the mobile station is further
PS30 is provided. The GPS 30 receives the received signal from the antenna switch 2 and obtains the position information of the mobile station from this received signal. This position information is sent to the CPU 19 and used for antenna control and channel allocation control described later. Further, the base station is provided with a predetermined number of transceivers having the configuration of FIG. 3 (excluding GPS).

The basic communication mode between the base station and the mobile station in TDMA is as follows. FIG. 4 shows a communication form of the 3-multiplex TDMA method. In FIG.
(A) shows the transmission / reception mode of one mobile station (first communication station). The transmission period from the mobile station to the base station (second communication station) and the transmission period from the base station to the mobile station. The transmission period and the downlink period are time-divisionally and alternately repeated. Then, the mobile station has a predetermined time zone (also called a time slot) allocated at the beginning of the uplink period, for example.
And the receiving operation is performed in the same predetermined time zone assigned to the beginning of the downlink period. On the other hand, the base station performs reception in the up period and transmission in the down period almost in synchronization with the transmission / reception operation of the mobile station.

An example of the transmission operation period of the mobile station, that is, an example of the format of transmission data corresponding to one frame is shown in FIGS. 4B and 4C. In the control channel, this transmission data is a transient response ramp time (R), a preamplifier (PR), a synchronization word (unique word: UW), a channel type (CI), and a call code of the partner station in order from the beginning. Identification code (DA), calling identification code (OA) which is the calling code of the local station, control data for link channel allocation, and additional information for error detection (CRC:
Cyclic Redundancy Check). The transmission data in the communication channel includes a transient response ramp time (R), a preamble (PR), a synchronization word (unique word: UW), a channel type (CI), communication data, and additional information for error detection (from the beginning). CRC). Note that a guard time of a predetermined number of bits is usually placed between adjacent transmission / reception communication time zones, and a pilot signal is appropriately inserted in the transmission data, but this is omitted here.

Although FIG. 4 mainly shows the transmission mode of the mobile station, even in the transmission mode of the base station (that is, the reception mode of the mobile station), transmission in the same format as (b) and (c) is performed. Data is sent to the mobile station. FIG. 5 shows operations from the start to the end of communication, and includes processing operations including antenna control and channel allocation control of the base station and mobile station according to the present invention.

In FIG. 5, first, an incoming call or an outgoing call is made from the base station to the mobile station on the control channel (S).
1). In response to this, the mobile station radiates a transmission wave including the control data of the link channel establishment request based on the operation of the keyboard 20 from the antenna 1 (S2). The base station
Upon receiving a link channel establishment request from the mobile station to the base station on the control channel, a transmission wave including control data requesting information indicating the location of the mobile station is radiated from the antenna 1 (S3). When the mobile station receives this position information request, the position information of its own station obtained from the GPS 30 is C
The signal corresponding to the received position information is taken into the PU 19, and the CPU 19 causes the DSP 11 to perform predetermined formatting or modulation and includes the signal in the transmitted wave to radiate it from the antenna 1 to respond to the base station with the position information. (S
4). When the base station obtains the position information of the mobile station in this way, it performs a channel allocation process to be used for communication with the mobile station as described above (S5).

That is, the channel allocation process is
Note 7. Obey. Before the channel allocation process,
For example, as shown in FIG. 6, the base station B has already communicated (communication
Position of each mobile station M1 to M3 (x)₁ , Y₁ ),
(X_Two , Y_Two ), (X_Three , Y_Three ) And its focus aperture
(Direction of radiation beam and transmission power in radiation directivity
(Or degree of visibility) = Vector Dd₁ , Dd_Two ,
Dd_Three , And the sharpness of the radiation beam = beam D0₁,
D0_Two, D0_ThreeRequired data of (shape) is written in advance in the CPU 19.
I remember. In the example of FIG. 6, the communication of the mobile stations M1 to M3 is
The same carrier frequency F1 is in the process of
It is assumed that no mobile station is communicating. Line of Figure 5
The new mobile station targeted for the incoming call in step S1 is mobile station M4.
And its position is (x_Four , Y_Four ) Of the base station
The CPU 19 uses the mobile station M1 in the channel allocation process.
~ Stored data about M3 and location of new mobile station M4
Information (x _Four , Y_Four ) To the mobile station M4 based on
When communication is performed at wave frequency F1 and narrowing control is performed
A predetermined algorithm to determine if there is interference
Set.

The algorithm executed by the CPU 19 includes, for example, the base station obtained by RSSI in the step S4.
It is preferable to include a process of determining the received electric field strength of the radio wave from the new mobile station received in (3) and determining the line of sight between the base station and the mobile station. That is, the mobile station emits a radio wave with a certain transmission power and directivity in the control channel, and the CPU 19 grasps the attenuation amount of the radio wave from the mobile station to the base station based on the measured received electric field strength. When the amount of attenuation is small relative to the distance from the mobile station to the base station, the CPU 19 determines that the visibility is good according to the degree, and when it is large, the visibility is poor according to the degree. It is determined that Then, the CPU 19 determines the shape of the beam to be emitted and the transmission power according to the degree of the line of sight. Therefore C
The PU 19 estimates not only the radiation direction toward the new mobile station but also the radiation beam with the determined shape and transmission power when performing communication with the new mobile station, so that the PU 19 can communicate with other mobile stations. It is determined whether or not interference will occur.
Note that the line-of-sight determination can be performed by the mobile station, but considering the configuration and operation simplification of the communication equipment on the mobile station side, it is more advantageous to perform the line-of-sight determination by the base station as in this example. Is.

In the case of FIG. 6, the mobile station M4 uses the beam D0.
_Since it is located at a position apart from ₁ , D0 ₂ and D0 ₃ and has a relatively good visibility to the base station, the beam D0 _{4 as} shown in the figure is formed by performing the narrowing control and communication is performed at the carrier frequency F1. It is assumed that no interference will occur. When this is determined by the above algorithm, the already used carrier frequency F1 is assigned to the new mobile station M4.

In contrast to this, when the new mobile station that is the target of the incoming call in the step S1 of FIG. 5 is the mobile station M5 and its position is (x ₅ , y ₅ ), the CPU 19 of the base station ,
In the channel allocation process, the storage data regarding the mobile stations M1 to M3 and the position information (x ₅ , y) of the new mobile station M5 are stored.
Based on ₅ ), it is also determined by a predetermined algorithm whether interference will occur when the mobile station M5 communicates with the carrier frequency F1 and the narrowing control is performed.
In this case, mobile station M5 is located near beam D0 ₁ ,
Even if the narrowing control is performed, the beam D0 ₅ formed spatially overlaps the beam D0 ₁ , so that it is assumed that interference will occur when communication is performed at the carrier frequency F1. When this is determined by the above algorithm, the carrier frequency F1 is not allocated to the new mobile station M5, but another carrier frequency F2 is allocated.

Still another case is possible. When the new mobile station that is the target of the incoming call in the step S1 of FIG. 5 is the mobile station M6 and its position is (x ₆ , y ₆ ), the base station C
The PU 19 uses the mobile stations M1 to M1 in the channel allocation process.
Based on the stored data about M3 and the position information (x ₆ , y ₆ ) of the new mobile station M6, whether or not interference occurs when the mobile station M6 communicates with the carrier frequency F1 and the narrowing control is performed. Determined by a predetermined algorithm. In this case, the mobile station M6 uses the beams D0 ₁ , D
Although 0 ₂ is relatively distant, outlook is poor, in order to form a reliable radio waves reach the mobile station M6 is must be made larger relatively broad and transmit power width of the radiation beam. Therefore, the beam D0 ₆ formed by controlling the focusing
Is spatially overlapped with the beam D0 ₁ or D0 ₂ , it is assumed that interference will occur when communication is performed at the carrier frequency F1. When this is determined by the above algorithm, the carrier frequency F1 is not allocated to the new mobile station M6, but another carrier frequency F2 is allocated. If the position of the mobile station M6 was clear, a narrow beam D0 ₆ ′ could be formed by the focusing control, and the carrier frequency F1 being used could be assigned.

In FIG. 6, the channel allocation in the case where one carrier frequency is already used when a new mobile station is called is explained, but there are a plurality of carrier frequencies already used. Also in the case, channel allocation is performed for the same purpose. That is, the carrier frequency is selected so as not to interfere with the communication of other mobile stations even when the communication with the new mobile station is performed together with the narrowing control.

As an example, when a new mobile station is called in FIG. 7, two carrier frequencies F1 and F2 have already been transmitted to the mobile station M1.
A case in which it is used for ~ M4 is shown. Whether or not the channel allocation to the new mobile station M5 gives interference to the channels CH1 and CH2 when the carrier frequency F1 is adopted for the communication of the mobile station M5 and the narrowing control is performed (or whether the channel CH5 causes interference) Is determined. When it is determined that the channel CH1 is to be interfered as in this case, the allocation of the carrier frequency F1 is abandoned, then the carrier frequency F2 is adopted for the communication of the mobile station M5, and the channel CH3 is selected when the narrowing control is performed. , CH4 is interfered with (or channel CH5 is interfered with). Then, when it is determined that no interference occurs on any of the channels CH3 and CH4 as in this case, the carrier frequency F2 is adopted for the communication of the mobile station M5 for the first time.

Similarly, for channel allocation to a new mobile station M6, whether or not the carrier frequencies F1 and F2 can be used for communication with the mobile station M6 by controlling the narrowing down without causing interference. It is judged sequentially. Here, the mobile station M6 has no choice but to have a shape over a wide area such as the beam D0 ₆ even if the narrowing control is performed and the carrier frequencies F1 and F are used.
Whichever of the two is adopted, interference is given to either of the channels CH2 and CH4. Therefore, in this case, the mobile station M6
The carrier frequency F3 different from F1 and F2 is adopted for the communication.

The base station performs the carrier frequency allocation calculation adapted to each case in the CPU 19 as described above. The base station not only allocates the carrier frequency, but also transmits the transmission wave of the mobile station to be controlled by the mobile station. The radiation characteristics (direction of radiation beam, width (shape) of beam, transmission power) are also estimated.
Of course, the radiation characteristic to be controlled by the base station itself is also held based on the execution result of the above algorithm.

Thus, in the step S5, the antenna 1 transmits the transmission wave having the control data including the assigned frequency signal indicating the carrier frequency determined by the base station and the control data including the decision line-of-sight signal and indicating the radiation characteristic of the mobile station. Then, the mobile station receives it and identifies the radio wave radiation characteristics from the link channel to be shifted and the antenna 1 to be controlled from the contents of the control data.

Next, the base station and the mobile station respectively shift to the determined link channel (communication channel), and perform narrowing control so that the held radiation characteristic and the identified radiation characteristic are obtained (S6B, S6M). To switch to the link channel, the VCO 9 changes the reception frequency to V
It is performed by controlling the transmission frequency by the CO 15 so as to correspond to the determined carrier frequency. In the narrow-down control (antenna control), the CPU 19 supplies an antenna control signal for controlling the direction and beam shape of the radiation beam to the array antenna 1 so that the held or identified radiation characteristic is obtained, and the power amplifier via the DSP 11. 17
Supply a power control signal.

When shifting to the communication channel, first, the mobile station supplies the synchronization burst to the base station (S10), and then the synchronization burst is supplied from the base station to the mobile station (S11). Then, the communication mode setting request is supplied from the mobile station to the base station (S12), and the base station responds to the communication mode setting (S13). Further, when an incoming call response is supplied from the mobile station to the base station (S14) and a call setup is supplied from the base station to the mobile station (S15), the mobile station responds to the call setup (S16). ), It will be a call.

At the end of the call, the mobile station radiates from the antenna 1 a transmission wave containing control data informing that the call to the base station based on the operation of the keyboard 20 will be disconnected (S20). The base station receives this and releases the communication channel that has been used (S21). When the mobile station further requests disconnection of wireless channels including the control channel (S2
2), the base station disconnects the wireless channel to the mobile station and disconnects the communication (S23).

By controlling the radiation characteristics of the base station and the mobile station as described above, both stations can form a communication form as shown in FIG. FIG. 8 shows a three-multiplex multiple-wave TDMA communication mode, which shows one frame configuration on the base station side, and follows the example of FIG. Before the new mobile station M4 appears, the base station communicates with the mobile stations M1 to M3 on the dedicated channel of the same carrier frequency F1 by distributing the antenna radiation characteristics. That is, as shown in (a), (b), and (c) of FIG. 8, the base station receives radio waves from the mobile stations M1, M2, and M3 in the same reception time band in the uplink period, and In the meantime, the mobile station from which the radio wave is emitted is identified in the emission direction of each radio wave. Further, even in the downlink period, the mobile stations M1, M2, M3 are used in the same transmission time zone.
Each radio wave is transmitted to, and in the meantime, the control of the radiation characteristics towards each corresponding mobile station. In this way, the base station is capable of communicating with a plurality of mobile stations at the same carrier frequency and time zone due to different radiation characteristics of transmitted and received radio waves. This is basically because the base station itself has a plurality of transceivers as shown in FIG. 3, of which the first to third transceivers are in charge of (a), (b), and (c) frame sequences, and the same. This is achieved by communicating with the radiation characteristics specified for each of the transmission and reception time zones of. New mobile station M
Even when 4 appears, the same carrier frequency F1 as that of the mobile stations M1 to M3 is assigned to the communication, and can be written as shown in (d) of FIG. In this case, the fourth transceiver in the base station is in charge of the frame sequence of (d), and communication is performed with the first to third transceivers in the same transmission / reception time period with the radiation characteristics defined for each. . When a new mobile station M5 or M6 appears, another carrier frequency F2 is assigned to the communication, so that a frame sequence with a different carrier frequency F2 is formed by the fifth transceiver as shown in (e) of FIG. To be done.

In each of the series of (a) to (e) of FIG. 8, it is illustrated that there is a free communication time zone, that is, a free channel in the up period and the down period. This empty channel can of course be used in the TDMA system. In short, in the conventional TDMA method, only three channels are allocated in one frame sequence for communication using one carrier frequency, but according to this embodiment, the frame sequence of the carrier frequency F1 is , (A), (b), (c), and (d) can be formed, and since three channels can be provided for each frame sequence, a total of 12 channels can be used as one carrier frequency. Can be carried by. Even if the narrowing control is performed, it is possible to use the vacant channels of the sequentially available frame sequence after the new frame sequence cannot be formed, or to use a certain frame sequence ( For example, the operation of performing narrowing-down control and forming another frame sequence (for example, (b) in FIG. 8) only after using all the channels in (a) in FIG. 8 may be repeated.

In the above communication system, 16QAM is adopted as the modulation method and TQ is used as the communication method.
Although DMA is adopted, it goes without saying that it is not particularly limited to these. Further, although the GPS provided in the mobile station is mentioned as a means for detecting the position information of the mobile station, various other well-known methods can be adopted as the method for detecting the position of the mobile station. . However, when GPS is adopted, it may be advantageous in terms of its detection accuracy or cost performance. Thus, the present invention is generally applicable to a system that provides wireless communication in a predetermined service area at a predetermined frequency, and it goes without saying that the design of each component can be modified.

[0048]

As described above in detail, according to the method of effectively using frequency of the present invention and the communication system using the same, the frequency utilization rate can be dramatically improved.

[Brief description of the drawings]

FIG. 1 is a schematic diagram when the method of the present invention is applied to a large zone configuration.

FIG. 2 is a schematic diagram when the method of the present invention is applied to a small zone configuration.

FIG. 3 is a block diagram showing the configuration of a TDMA communication device according to an embodiment of the present invention.

4 is a triple TDMA as an operation example of the communication device of FIG.
The figure which shows the communication form of a system.

5 is a process chart showing a mode from start to end of communication between a base station and a mobile station as an operation example of the communication device of FIG. 3;

6 is a schematic diagram showing an example of a more detailed aspect of channel allocation and antenna control in FIG.

FIG. 7 is a schematic diagram showing another example of a more detailed aspect of channel allocation and antenna control in FIG.

FIG. 8 is a time chart showing a communication form enabled by the communication system according to the present invention.

[Explanation of symbols]

B, B1 to B7 Base stations M, M1 to M6, M11, M12, M21, M22, M31, M3
2, M41, M42, M51, M52, M61, M62, M71, M72
Mobile station 1 Array antenna 2 Antenna switch 3 Receiver 4 Transmitter 5,7 BPF 6 High frequency amplifier 8 Down converter 9,15 VCO 10 A / D converter 11 DSP 12 Channel coding logic circuit 13 D / A converter 14 Up Converter 16 Preamplifier 17 Power amplifier 19 CPU 20 Keyboard 21 Voice CODEC 22 Data input / output interface 23 Microphone amplifier 24 Speaker amplifier 25 Microphone 26 Speaker 30 GPS

Claims (12)

[Claims] 1. A spectrum effective utilization method for allocating a predetermined frequency to at least one radio zone, wherein in one of the radio zones, a base station radiates a radio wave to the mobile station toward a position of the mobile station. And controlling the radiation directivity of the radio wave of the mobile station to the base station toward the position of the base station. 2. The position of the base station is controlled by controlling the radiation directivity of a radio wave of a specified downlink frequency of the base station with respect to the position of the first mobile station in one of the wireless zones. And controlling the radiation directivity of the radio wave of the uplink designated frequency of the first mobile station with respect to the base station, and the downlink designated frequency of the base station with respect to the second mobile station toward the position of the second mobile station. 2. The radiation directivity of the radio wave of the radio wave is controlled to control the radiation directivity of the radio wave of the uplink designated frequency with respect to the base station of the second mobile station toward the position of the base station. Spectrum effective usage. 3. The channel between the first mobile station and the base station and the channel between the second mobile station and the base station are in a sufficiently low interference state with each other. The effective use method of the spectrum according to claim 2. 4. A communication system having a base station and a mobile station that transmit and receive radio waves at a frequency assigned in at least one radio zone, wherein in one of the radio zones, the base station is the mobile station. To control the radiation directivity of radio waves to the mobile station, and the mobile station controls the radiation directivity of radio waves to the base station toward the position of the base station. . 5. The base station controls the radiation directivity toward the position of a new mobile station to be connected and radiates radio waves at the same frequency as the frequency used for the channel in communication. Only when it is determined that it does not substantially interfere with the channel in communication, the same frequency is assigned to the transmission and reception of radio waves to and from the new mobile station in the own station, and toward the position of the new mobile station. Controls the radiation directivity, generates an assigned frequency signal indicating the same frequency and a control signal for controlling the radiation directivity of radio waves to the base station of the new mobile station, and transmits the control signal to the mobile station. The mobile station receives the assigned frequency signal and the control signal, controls the radiation directivity accordingly, and transmits and receives radio waves to and from the base station. Placing communication system. 6. The base station controls the radiation directivity toward the position of a new mobile station to be connected and radiates radio waves at the same frequency as the frequency used for the channel in communication. When it is not possible to determine that it does not substantially interfere with the channel being communicated, the different frequency not used in the channel being communicated in the own station is allocated to transmission and reception of radio waves to the new mobile station, and Controlling radiation directivity toward the position of a new mobile station, and generating a control signal for controlling an allocation frequency signal indicating the different frequency and a radiation directivity of radio waves to the base station of the new mobile station. Then, the mobile station receives the assigned frequency signal and the control signal, controls the radiation directivity accordingly, and transmits and receives radio waves to and from the base station. Communication system according to claim 5, characterized in that. 7. The mobile station according to claim 5, wherein the mobile station has a GPS to obtain position information of the own station and transmits a position signal according to the position information to the base station. Communications system. 8. The communication system according to claim 5, wherein the control of the radiation directivity targets radio waves having a frequency assigned to a communication channel. 9. The base station determines a position of the new mobile station and a received electric field strength of a radio wave from the new mobile station or a received electric field strength of a radio wave from the base station in the new mobile station. Based on, to determine the degree of line-of-sight in the propagation of radio waves to the mobile station, while controlling the width of the radiation beam in its own station according to the degree of line-of-sight,
A decision line-of-sight signal indicating the degree of line-of-sight is generated and transmitted to the mobile station, and the mobile station receives the decision line-of-sight signal and further controls the width of the radiation beam in the own station in response to the decision line-of-sight signal. The communication system according to claim 5 or 6, characterized in that. 10. The base station further controls the transmission power of a radio wave to the new mobile station in the own station according to the degree of the line-of-sight or the width of the radiation beam, and the mobile station judges whether the received signal is received. The communication system according to claim 9, further comprising controlling the transmission power of the local station according to the line-of-sight signal. 11. The base station and the mobile station each have an array antenna, and the radiation directivity of each station is controlled by the array antenna.
11. The communication system according to any one of 1 to 10. 12. The wireless zone is a plurality of small zones, and for each of the small zones, the base station controls the radiation directivity of radio waves to the mobile station toward the position of the mobile station, 12. The communication system according to claim 4, wherein the station controls the radiation directivity of radio waves to the base station toward the position of the base station.