JP2003209879A - Multiple access communication system, multiple access communication method, wireless base station apparatus, and wireless mobile station apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To increase the capacity by eliminating interference inside and outside of cells. <P>SOLUTION: Base stations BS-X, BS-Y of cells X, Y adjacent to each other or placed nearly use the same frequency f<SB>1</SB>to access a mobile station at the same time. A mobile station MS-A belonging to the cell X receives a sum of a desired signal from the base station BS-X to which the mobile station belongs and an interference signal sent from the base station BS-Y at the outside of the cell to other mobile station MS-B, and cancels the interference when the number of users is regarded as two. For example, the SIC (Successive Interference Cancellation) detecting multi-users is applied on the basis of the strength of the received signal. <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 multiple access communication system and a multiple access communication method for a plurality of mobile terminals to simultaneously communicate with one base station, and more particularly, to eliminate interference inside and outside a cell. The present invention relates to a multi-cell multiple access communication system and a multi-cell multiple access communication method with expanded capacity (communication capacity).

More particularly, the present invention relates to a multi-cell multiple-access communication system and a multi-cell multiple-access communication method for operating at a frequency repetition as short as possible to increase capacity, and in particular, one frequency repetition is realized by a non-spreading method. The present invention relates to a multi-cell multiple access communication system and a multi-cell multiple access communication method for increasing capacity.

[0003]

2. Description of the Related Art Mobile communication originates from the discovery of electromagnetic waves in the first place, and since then, research and development has been advanced due to the necessity of communication with ships, aircraft and trains. Furthermore, the targets of communication have expanded to automobiles and people. It has become possible to transmit not only telegraphs and telephones but also computer data and multimedia contents such as images.

Recently, due to improvements in manufacturing technology, downsizing and price reduction of mobile terminals are rapidly progressing. In addition, mobile terminals, such as mobile phones, are becoming more and more personalized due to the expansion of information and communication services. Furthermore, due to liberalization of communications and reduction of communications charges,
The user base is expanding more and more.

Mobile communication is basically based on the fact that a mobile station such as an on-vehicle phone or a mobile phone finds a nearest base station and exchanges radio waves between the mobile station and the base station. The range within which the radio waves from one base station can reach is defined as "cell (Ce
ll) ". A cell is usually a circle with a predetermined radius centered on the base station antenna. Then, the communication service area is configured by arranging the cells without gaps.

FIG. 6 schematically illustrates a cell configuration in a mobile radio communication system in which a service area is surface-deployed by a plurality of base stations represented by a cellular system. By installing base stations (not shown) at certain fixed intervals and laying a plurality of cells provided by each base station without interruption, as shown in the figure,
A wide area service area is built.

In this way, the mobile communication system uses the cell by making the radio wave of the base station reach only in the cell so that the same frequency is repeatedly used in other cells. , The effective use of limited frequency resources and the division into cells reduce the radio wave output for communication, and the size and power saving of mobile units that are usually implemented as battery-powered portable devices are reduced. This is because there are merits such as Recently, due to an increase in the number of mobile phone users, the size of cells has been further reduced.

By the way, there are a plurality of mobile terminals in one cell, and these communicate with one base station at the same time. That is, from the perspective of the base station, it is necessary to multiplex access (multiple access), that is, to multiplex radio signals to detect which signal belongs to which user (multi-user detection).

Conventionally, as a multiple access technique in wireless communication, time division multiplexing (TDMA) is used.
le Access) and second generation PDC (Personal Digital
Cellular) frequency division multiplexing (F)
DMA: Frequency Division Multiple Access (CDM) used in the third generation.
A: Code Division Multiple Access) and the like are known.

[0010] TDMA is a communication system in which a communication channel is divided in advance into time slots on a time axis and different time slots are assigned to each mobile terminal that communicates at the same time, and a digital system is a prerequisite. The digital form telephone system in Japan uses time division multiplexing of 3 or 6 channels.

Further, the FDMA is a system for performing communication by allocating different frequencies between mobile terminals that communicate at the same time (that is, for each communication channel). That is, a large number of channels used for communication are arranged on the frequency axis, and vacant channels are appropriately allocated and used.
FDMA can support both analog and digital communication systems. In Japan, FDMA is used for analog car phones and mobile phones.

CDMA is a system in which a wide frequency is shared by a plurality of mobile terminals by using spread spectrum.
A mobile terminal is assigned with a spreading sequence for spread spectrum every time communication is performed, and spreads a communication signal using this spreading sequence and transmits the spread signal. Since the mobile terminal uses a common frequency, the communication signals of other stations are all interference to the own station, and the performance of extracting the received signal from the interference greatly affects the reception level.

In a wireless communication environment in which mobile communication spreads rapidly and widely and a large number of mobile stations exist in the same cell, how to expand the communication capacity (capacity) with few resources. Is the biggest issue.

Here, the problems of multi-user detection and capacity (communication capacity) of each of the above-described multiple access methods will be considered.

FDMA has no problem because of frequency division. However, the number of users that can be accommodated in one cell is small because the upper limit is the number of channels created by dividing the usable frequency band. Further, it is impossible to repeat the same frequency between adjacent cells, and the capacity of the entire communication service is small.

Further, in CDMA, code division is performed using a spreading sequence composed of orthogonal and pseudo-orthogonal codes. Since users in a cell share the same frequency, signals of other users all become interference waves. . Since the base station side can know the spreading sequence to be used for each mobile terminal, the base station can detect the signal of each user, but on the contrary, the mobile terminal side uses it for other mobile terminals. Since the spreading sequence cannot be known, user detection is not realized. Further, it is sufficient if all spreading sequences are orthogonal, but non-orthogonal components become interference components, and therefore the number of users that can be accommodated is small with respect to the number of channels created by the pseudo orthogonal code. Also, C
Since DMA uses a wide frequency band due to spreading, even if one frequency repetition can be realized, the capacity is small.

On the other hand, as shown in FIG. 6, in a service area in which small cells are arranged without gaps, the base station to be connected is changed as the mobile station moves between cells. I have to do it. Such switching of the connection base station of the mobile station is called "handover" or "handoff".

FIG. 7 schematically illustrates how the mobile station hands off. In the upper part of the figure, the base station BS-
A is in communication with mobile station MS-X and base station BS-B is in communication with mobile station MS-Y.

Here, the mobile station MS-Y is the base station BS-A.
As the mobile station MS-Y approaches the side cell,
-It becomes possible to receive the transmission signal from A as well. Normally, the handoff procedure is started at this point and the base station B
S-A starts preparation for accommodating mobile station MS-Y in the cell (middle stage of FIG. 7).

After that, the mobile station MS-Y is completely BS-A.
Mobile station MS
-Y changes the connected base station to BS-A, and finally the mobile station MS-Y is accommodated in the base station BS-A (lower part of FIG. 7).

As a conventional non-spreading type cellular system, a system for performing multiple access by TDMA is widely known. In a communication system in which multiple access is performed by TDMA or FDMA, different frequency resources are arranged in adjacent or neighboring base stations. Therefore, when the connected base station is changed by handoff, the channel is provided by changing the frequency resource to be used. Here, frequency resource assignment between adjacent base stations will be described with reference to FIG.

In FIG. 8, the shaded portion is the frequency resource assigned to the base station BS-A, and the non-shaded portion is the base station BS-B.
It is assumed that the frequency resource is assigned to. Here, for simplification of description, it is assumed that four frequency channels are allocated to these two base stations in the 3TDMA structure. In this case, each base station can accommodate up to 6 channels.

Each base station uses an unused frequency resource among the frequency resources assigned to the base station when a mobile station informs that it wants to communicate. Figure 7
In the example shown in FIG. 1, the base station BS-A is the mobile station MS-X.
It is assumed that the frequency resource CH (0,0) is used for communication with the mobile station MS and the base station BS-B uses the frequency resource CH (1,0) for communication with the mobile station MS-Y. .

At this time, when the mobile station MS-Y hands off, the base station BS-A uses unused channels, that is, CH (0,1), CH (0,2), and CH (0,0). ,
Either CH (1,1) or CH (1,2) is selected. Then, when the mobile station MS-Y starts communication with the base station BS-A, the mobile station MS-Y changes the frequency channels and the time slots to those designated by the base station BS-A.

As described above, in the non-spreading type mobile radio communication system, it is necessary to change the frequency resource used for communication at the time of handoff. If this cannot be done immediately, a line disconnection or the like occurs. There is a risk.

Further, since the same frequency resource is used between adjacent base stations, there is interference, so it is necessary to divide and assign the frequency resource assigned to the communication system. Therefore, there is a problem that the frequency resources that can be used by each base station are limited, and the capacity of the entire communication system is limited.

[0027]

SUMMARY OF THE INVENTION It is an object of the present invention to provide an excellent multi-cell multiple-access communication system and multi-cell multiple-access communication method capable of increasing interference by eliminating interference inside and outside a cell. It is in.

A further object of the present invention is to provide an excellent multi-cell multiple-access communication system and multi-cell multiple-access communication method that can be operated with as short a frequency repetition as possible to increase the capacity.

A further object of the present invention is to provide an excellent multi-cell multiple access communication system and multi-cell multiple access communication method capable of realizing one frequency repetition by a non-spreading method and increasing the capacity.

A further object of the present invention is to provide an excellent non-spreading multi-cell multiple-access communication system and multi-cell multiple-access communication method in which the risk of line disconnection does not occur during handoff.

[0031]

The present invention has been made in consideration of the above problems, and the first aspect thereof is that each base station has adjacent cells capable of communicating with one or more mobile stations. Or a multiple access communication system or multiple access communication method of a multi-cell multi-user configuration that exists in close proximity,
Adjacent or neighboring cells share a channel with the same spatial, temporal and frequency, and the receiving station receives incoming signals from each transmitting station inside and outside the cell as the desired signal. To detect multiple users,
A multiple-access communication system or a multiple-access communication method.

However, the term "system" as used herein refers to a logical assembly of a plurality of devices (or functional modules that realize a specific function), and each device or functional module is a single casing. It does not matter whether it is in the body or not.

According to the multiple access communication system or the multiple access communication method according to the first aspect of the present invention, the receiving station is
Since the incoming signal from each station on the transmitting side inside and outside the cell is regarded as a desired signal and detected, adjacent or neighboring cells can share the same spatial, temporal and frequency channels. .

Therefore, it is possible to realize a multi-cell structure by repeating one frequency, the efficiency of frequency utilization is increased, and the capacity (communication capacity) is expanded at the same utilization efficiency.

Here, the station on the transmission side may transmit the transmission signal by the non-spreading method. Since wireless communication is performed by the non-spreading method, the frequency band used by one channel can be small, and the frequency utilization efficiency is improved. As a result, the capacity is expanded as compared with a communication system such as CDMA.

Further, the receiving station is, for example, SIC (Succ
An interference cancellation technique such as essive Interference Cancellaer) may be applied to perform detection of each signal, that is, multi-user detection. The SIC demodulates a received signal transmitted from each station on the transmission side inside and outside the cell and propagated through each propagation characteristic and the sum of the noise and the received signal in descending order of received power, and All the received signals can be detected by repeating the process of canceling the signal.

The term “in cell” means the cell range of the base station to which the user (mobile station) belongs (or is registered). Multi-user detection is performed not only at the boundary of the cell but also at the center of the cell although interference from other stations is small. You can also think of it as "a signal addressed to you" or "a signal other than that." When the mobile station is located at the periphery of the cell and is about to hand off, both the signals addressed to itself from the two base stations and the other signals are received as desired signals. (In rare cases, it is possible to receive signals from two or more base stations.)

A second aspect of the present invention is a multi-cell / multi-user multiple access communication system or multiple access communication method in which cells capable of communicating with each base station are adjacent or close to each other. Or neighboring cells share the same spatial, temporal, and frequency channels, and the base station and mobile station each desire incoming signals from each transmitting station inside and outside the cell. A plurality of users are detected as signals, and the base station detects the plurality of users without allocating new frequency resources for mobile stations handing off from the cells of other base stations. A multi-access communication system or a multi-access communication method, characterized in that it continues to receive signals from.

According to the multiple-access communication system or the multiple-access communication method according to the second aspect of the present invention, it is assumed that multi-user detection is performed on the receiving side of wireless communication. Even if there is, it is not necessary to divide the frequency resource assigned to the base station, and as a result, the problem that the capacity of the entire communication system is limited can be solved.

Further, according to the multiple access communication system or multiple access communication method of the second aspect of the present invention, it is not necessary to switch communication channels due to handoff by realizing one frequency repetition. As a result, the number of processing steps required for handoff can be reduced, and handoff can be smoothly performed with a high success rate.

Further, the mobile station, when deterioration of the quality of the received signal obtained by the detection of the above-mentioned plurality of users is expected, of the frequency resource allocated to the mobile station with respect to the base station in communication. A change may be requested.
That is, by switching the communication channel when the reception status in the mobile station is not good, it becomes possible to provide the service with suitable communication quality even in the mobile station located at the cell boundary or the like.

A third aspect of the present invention is a radio base station apparatus which operates in a multiple access multi-cell communication environment in which cells capable of communicating with each base station are adjacent or close to each other. In addition, the incoming signals from each mobile station inside and outside the own cell are considered as desired signals to detect multiple users, and a new mobile station handing off from the cell of another base station is added. The radio base station apparatus is characterized by continuing to receive a signal from the mobile station by detecting the plurality of users without allocating frequency resources.

The radio base station apparatus according to the third aspect of the present invention can operate in the multiple access radio communication environment according to the second aspect of the present invention. This radio base station apparatus realizes one frequency repetition by considering incoming signals from each mobile station inside and outside the own cell as desired signals and detecting a plurality of users. Further, without allocating a new frequency resource for the mobile station handing off from the cell of another base station, by continuing the reception of the signal from the mobile station by the detection of the plurality of users, the handoff is performed. It is not necessary to switch the communication channel caused by it. As a result, the number of processing steps required for handoff can be reduced, and handoff can be smoothly performed with a high success rate.

Further, the radio base station apparatus according to the third aspect of the present invention allocates a new frequency resource in response to receiving a request to change the used frequency resource from the mobile station in communication. Good. That is, by switching the communication channel when the reception status in the mobile station is not good, it becomes possible to provide the service with suitable communication quality even in the mobile station located at the cell boundary or the like.

A fourth aspect of the present invention is a radio mobile station apparatus operating in a multiple access communication environment of a multi-cell / multi-user configuration in which cells capable of communicating with each base station are adjacent or close to each other. Then, the wireless mobile station device is characterized in that both incoming signals from mobile stations inside and outside the cell are regarded as desired signals and a plurality of users are detected.

The radio mobile station apparatus according to the fourth aspect of the present invention can operate in the multiple access radio communication environment according to the second aspect of the present invention. This wireless mobile station device, by considering the incoming signal from each base station in the cell and outside the cell as a desired signal, by detecting a plurality of users,
Realize 1 frequency repetition.

In the multiple-access wireless communication environment according to the second aspect of the present invention, the base station continues to receive signals from the mobile station upon detection of a plurality of users, so that the communication channel caused by the handoff occurs. It does not switch. On the other hand, the mobile station requests the base station in communication to change the frequency resource assigned to the mobile station when deterioration of the quality of the received signal obtained by the detection of multiple users is expected. You may do it. That is, by switching the communication channel when the reception status in the mobile station is not good, it becomes possible to provide the service with suitable communication quality even in the mobile station located at the cell boundary or the like.

Still other objects, features and advantages of the present invention are as follows.
It will be apparent from the embodiments of the present invention described later and the more detailed description based on the accompanying drawings.

[0049]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below in detail with reference to the drawings.

A. Multi-user in multiple access system
The Detection FIG. 1 schematically shows the configuration of a multi-cell multiple access communication system according to this embodiment.

In the example shown in FIG. 1, only one mobile terminal is drawn in one cell in order to simplify the description and avoid complication of the drawing. It may exist inside. Further, it should be understood that a large number of adjacent cells are arranged around the cell X and the cell Y to form a wider communication service area.

On the illustrated multi-cell multiple access communication system, one mobile terminal MS-A exists in the cell X, which is the communicable range of the base station BS-X, and the base station B
One mobile terminal M in cell Y provided by S-Y
SB is present. Here, it is assumed that the cell X and the cell Y are arranged adjacent to each other.

In the illustrated multi-cell multiple access communication system, a spreading sequence is not used for multiple access (that is, C
The non-spreading method (which does not perform DMA) is adopted. When mobile communication is operated with a small number of frequency repetitions such as one frequency repetition, co-channel interference occurs. First, the communication operation in the entire multi-cell multiple access communication system will be described.

However, BS-X and BS-Y, which are base stations of cells X and Y arranged adjacent to or close to each other, can connect to a mobile station at the same time using the same frequency f _1. To do.

At the times shown in the figure, the mobile station MS-A belongs to the base station BS-X, and the mobile station MS-B belongs to the base station BS-Y.
Belongs to. The same frequency is used between any of the base stations and the mobile stations, and they are in the connected state at the same time.

The signal received by the mobile station MS-A on the downlink is the signal (desired wave) that is transmitted to the MS-A from the base station BS-X to which it belongs and reaches with the propagation characteristic H _XA , and the signal outside the cell. It is the sum of the signal (interference wave) transmitted from the base station BS-Y to another mobile station MS-B and reaching the MS-A with the propagation characteristic _HYA .

Similarly, the signal received by the mobile station MS-B is the signal (desired wave) transmitted from the base station BS-Y to the mobile station MS-B and reaching the mobile station MS-B with the propagation characteristic _HYB . The sum of the signals (interference waves) transmitted from the base station BS-X outside the cell to the other mobile station MS-A and reaching the MS-B with the propagation characteristic H _XB .

The signal received by the base station BS-X on the uplink is transmitted from the mobile station MS-A in the cell to the base station BS-X.
A signal (desired wave) transmitted to a base station BS-X with a propagation characteristic H _AX and a base station with a propagation characteristic H _BX transmitted from a mobile station MS-B outside the cell to another base station BS-Y. BS-X
Is the sum of the signals (interference waves) that reach

Similarly, the signal received by the base station BS-Y is transmitted from the mobile station MS-B in the cell to the base station BS-Y and reaches the base station BS-Y with the propagation characteristic H _BY (desired signal). Wave) from the mobile station MS-A outside the cell to another base station BS
The sum of the signals (interference waves) transmitted to -X and reaching the base station BS-Y with the propagation characteristic H _AY .

In the multi-cell multiple access communication system according to this embodiment, since the same frequency is used in adjacent cells without using spreading sequences, which base station
In both the downlink and the uplink between the mobile stations, adjacent base stations / mobile stations interfere with each other and interfere with the reception of the desired signal.

The present embodiment is characterized in that the base station and the mobile station perform not only the desired signal from within the cell but also the interference signal from outside the cell as a desired signal and perform multi-user detection. is there. Hereinafter, a case where the mobile station MS-A performs a reception process on the downlink will be described as an example.

FIG. 2 schematically shows the channel structure received by the mobile station MS-A. As already described with reference to FIG. 1, in the downlink, the mobile station MS-A receives a desired signal from the base station BS-X to which the mobile station MS-A belongs and from the base station BS-Y outside the cell to another mobile station. Receive an interfering signal transmitted to station MS-B.

The base station BS-X sends the transmission information I _XA (00
When transmitting 1), the transmitter (Transmitter)
X) 11 performs signal processing such as modulation and up-conversion to convert into a transmission signal T _XA (002) and sends it out.

On the other hand, the base station BS-Y transmits the transmission information I
When transmitting _YB (011), the transmitter (Transmit
signal processing such as modulation and up-conversion by the ter Y) 21 to convert the signal into a transmission signal T _YB (012) and send it.

The transmission signal T _XA (002) is propagated to the mobile station BS-X via the propagation characteristic H _XA , and the transmission signal T _YB (01
2) is propagated to the mobile station BS-X via the propagation characteristic H _YA ,
Further, thermal noise noise is added in the middle of them. As a result, the received signal R _A received at the mobile station MS- _A
(020) is as follows.

[0066]

[Equation 1]

Since the receiving side (the mobile station MS-A in this case) receiving this received signal R _A detects both the information of the two information sources, the base stations BS-X and BS-Y, the number of users is increased. When 2 is regarded as 2, the interference cancellation is performed.

FIG. 3 schematically shows a functional configuration on the receiver side that receives a reception signal R _A composed of the sum of two transmission signals R _XA and R _YA and noise.

On the receiver side, a multi-user detector (MUD: Mult) for detecting a user from the received signal R _A (020).
i-User Detection Entity) 31 and the two signals extracted from the received signal are subjected to hard decision to transmit information I _XA and I _YB
And hard decision units 32 and 33 for estimating

The multi-user detector 31 has two users.
If it is considered that the interference is canceled. It is generally estimated that users with strong received signals are more reliable.
In the present embodiment, multi-user
As one of the detection methods, SIC (Su
ccessive Interference Cancellation) is applied. S
The IC is a technique that makes it possible to detect all the received signals by demodulating the received power in descending order and repeating the process of canceling its own signal.

FIG. 4 shows in detail the internal structure of the multi-user detector 31 formed by applying the SIC.

As shown, the multi-user detector 31 is
A filter (Demod A) 4 that corrects the received signal R _A based on the propagation characteristic H _XA , demodulates and performs soft decision (or hard decision) to estimate the transmitted signal T _XA from the base station BS-X 4
1 and an interference canceller (IC) 42 that subtracts the reception signal from the base station BS-X from all reception signals based on the estimation result of the transmission signal T _XA.
And a filter (De) for estimating the transmission signal T _YB from the base station BS-Y by correcting the interference cancellation result based on the propagation characteristic H _YA and performing demodulation and soft decision (or hard decision).
The mod B) 43 and an interference canceller (IC) 44 that subtracts the received signal from the base station BS-Y based on the estimation result of the transmitted signal T _YB are configured as basic units of the interference canceling process. Then, the number of repetitions of this basic unit is determined in consideration of the accuracy of signal processing and the processing cost.

The operating characteristics of the multi-user detector 31 will be described below.

When R _A is received via each propagation path (step S1), the filter 41-1 uses the estimated value of the propagation characteristic H _XA to transmit from the base station BS-X to the mobile station MS-A. A replica (021) of the signal T _XA is output (step S2).

The replica (021) of the transmission signal T _XA from the base station BS-X to the mobile station MS-A is a multiplier 45-
1 is multiplied by the estimated value of the propagation characteristic H _XA to generate a replica (022) of the transmission path output from the base station BS-X to the mobile station MS-A (step S3).

The replica (022) of the transmission path output from the base station BS-X to the mobile station MS-A is an interference component for the mobile station MS-B. The interference canceller 42-1 converts the received signal RA (020) into a replica (0
22) is subtracted, and the subtraction result (023) is input to the filter 43-1 (step S4).

The filter 43-1 outputs the replica (024) of the transmission signal T _YB from the base station BS-Y to the mobile station MS-B by using the estimated value of the propagation characteristic H _YB (step S5). .

The replica (024) of the transmission signal T _YB from the base station BS-Y to the mobile station MS-B is the multiplier 46-
1 is multiplied by the estimated value of the propagation characteristic H _YB to generate a replica (025) of the transmission path output from the base station BS-Y to the mobile station MS-B (step S6).

The replica (025) of the transmission path output from the base station BS-Y to the mobile station MS-B is an interference component for the mobile station MS-A. The interference canceller 44-1 subtracts the replica (025) which is an interference component from the subtraction result (023) of the interference canceller 42-1 (step S7).

Then, the base station BS-X to the mobile station MS-
The replica (022) of the transmission path output to A and the subtraction result (026) of the interference canceller 44-1 are added by the adder 47-2, and input to the interference cancellation processing unit 40-2 at the next stage (027). Then, the same interference removal processing is repeatedly executed (step S8).

When the number of repetitions of the interference removal processing reaches the predetermined number N, the output (028) of the filter 41-N of the mobile station MS-A is output to the decoder / demodulator (Decoder A).
Input to 51, and output the replica (029) of the transmission information _IXA to the mobile station MS-A (step S9).

Similarly, the output (030) of the filter 43-N of the base station MS-B is output to the decoder / demodulator (Dec).
ode B) 52 and outputs the replica (031) of the transmission information I _YB to the mobile station MS-B (step S10).

When the multi-user detection (MUD) processing in steps S1 to S10 described above is completed, the replicas (040) and (042) of the information signals from the base stations BS-X and BS-Y are hardened. Judgment processing is performed to set them as (041) and (043) (step S
11).

The mobile station MS-A has (041) and (04
Of 3), the determination value (041) of I _XA is used (step S12). Similarly, on the mobile station MS-B side, (04
Of 1) and (043), the judgment value (043) of I _YB is used.

Therefore, each base station BS-X and BS-
Y uses the same frequency f ₁ but can connect to each mobile station MS-A and MS-B at the same time. That is, since one frequency repetition can be realized, the capacity is greatly increased. Further, since the non-spreading method that does not use the spreading sequence is used, the frequency band to be used can be small, so that the increase in capacity can be expected.

The mobile station MS-A transmits not only the received signal from the base station BS-X of the cell to which it belongs but also the received signal from the base station BS-Y of the adjacent cell as desired signals. Is taken out, so when the mobile station moves between cells, handoff (switch of base station)
Can be handled accurately.

In the above description of the multi-user detection, the downlink from the base station to the mobile station is taken as an example. However, even in the case of the uplink from the mobile station to the base station, Multi-user detection can be realized by the station similarly implementing an interference cancellation method such as SIC.

In this embodiment, the inside of the cell is
It refers to the cell range of the base station to which (the mobile station) belongs (or is registered). Multi-user detection is performed not only at the boundary of the cell but also at the center of the cell although interference from other stations is small. You can also think of it as "a signal addressed to you" or "a signal other than that." When the mobile station is located at the periphery of the cell and is about to hand off, both the signals addressed to itself from the two base stations and the other signals are received as desired signals. (In rare cases, it is possible to receive signals from two or more base stations.)

B. Handoff Next, the handoff operation accompanying the inter-cell movement of the mobile station in the multiple access communication system according to this embodiment will be described.

As described above, the receivers of the base station and the mobile station are provided with means for individually demodulating a plurality of signals received on the same frequency resource, and multi-user detection is performed. ing. In addition, since multi-user detection receives and decodes a plurality of incoming radio channels using the same frequency resource,
It is possible for multiple users to share the same frequency resource.

The handoff operation by the base station will be described below while tracing the situation shown in FIG. For convenience of explanation, each of the base stations BS-A and BS-B is assumed to be able to use all of the frequency resources shown in FIG.

The base station BS-A is communicating with the mobile station MS-X using the frequency resource CH (0,0), and the base station BS-B is communicating with the mobile station MS-Y and the frequency resource CH (. 0,
0) is in communication (upper part of FIG. 7).

Here, the mobile station MS-Y moves to be able to receive the transmission signal from the base station BS-A (the middle part of FIG. 7). Then, in the mobile station MS-Y, in addition to the signal transmitted from the base station BS-B to the mobile station MS-Y, the signal transmitted from the base station BS-A to the mobile station MS-X is also included. It will be received in the added state.

At this time, in the receiver of the mobile station MS-Y, the signal addressed to the mobile station MS-Y is decoded from the base station BS-B by performing the multi-user detection (described above). A signal addressed to another mobile station MS-X from the station BS-A is similarly decoded, but no signal deterioration due to co-channel interference occurs.

After that, the mobile station MS-Y further adds to the base station B.
It moves to the vicinity of S-A and is finally accommodated in the cell of the base station BS-A. The base station BS-A uses the original CH (0, 0 as a communication channel with the mobile station MS-Y.
0) is continuously assigned. That is, the channel is not changed due to the change of the connected base station.

At this time, in the receiver of the base station BS-A,
Both the signal from the mobile station MS-X and the signal from the mobile station MS-Y are received, but since the multi-user detection (described above) is performed, the signal from the mobile station MS-X and the mobile station MS are received. It is possible to receive and decode both signals from -Y, which is not a problem.

Further, since the base station has less restrictions on downsizing and lower current consumption than a normal mobile station, it can perform multi-user detection processing with higher accuracy than a mobile station. There are almost no problems in handling.

Further, the subsequent processing will be described with reference to FIG.

In the upper part of FIG. 8, it is assumed that the mobile station MS-X and the mobile station MS-Y are communicating with the base station BS-A using the same frequency resource CH (0,0). After this, a new mobile station MS-Z is placed in the cell of the base station BS-A.
Consider the case where is housed. Here, it is assumed that it is determined that the mobile station MS-Z is assigned the frequency resource CH (0,0) that has already been assigned to the communication of the mobile station MS-X or the mobile station MS-Y.

When the base station BS-A starts communication with the mobile station MS-Z, the receiver of the base station BS-A receives each mobile station MS-X as a received signal on the frequency resource CH (0,0). , MS-Y, and MS-Z, the sum of the signals transmitted respectively arrives. Base station BS
-In A, high precision multi-user such as SIC
These received signals can be separated and decoded using the detection processing (described above).

On the other hand, the mobile stations MS-X, MS-Y, and MS-Z similarly transmit from the base station BS-A to the mobile stations MS-X, MS-Y, and MS-Z. Each signal is received, and similarly, separation and decoding are attempted for these signals by the multi-user detection processing.

Here, when the performance of the receiver of the mobile station MS-X is low, or when another mobile station is intensively using the same frequency in the destination cell, the mobile station MS-X
With -X, the decoding accuracy of the signal transmitted to its own mobile station becomes poor. The mobile station MS-X requests the base station BS-A to change the frequency resource assigned to its own communication, triggered by such deterioration of the received signal quality.

In response to the request, the base station BS-A searches for another frequency resource available in the base station BS-A and allocates a new frequency resource to be used with the mobile station MS-X.

By executing the procedure as described above, a mobile station equipped with a highly accurate multi-user detection device can perform handoff without changing the frequency resource used by the mobile station itself. , It will be possible to enjoy higher quality services.

[Supplement] The present invention has been described in detail with reference to the specific embodiments. However, it is obvious that those skilled in the art can modify or substitute the embodiments without departing from the scope of the present invention. That is, the present invention has been disclosed in the form of exemplification, and the contents of this specification should not be construed in a limited manner. In order to determine the gist of the present invention, the section of the claims described at the beginning should be taken into consideration.

[0106]

As described above in detail, according to the present invention,
It is possible to provide an excellent multi-cell multiple-access communication system and multi-cell multiple-access communication method capable of increasing interference by removing interference inside and outside a cell.

Also, according to the present invention, it is possible to provide an excellent multi-cell multiple-access communication system and multi-cell multiple-access communication method that can be operated with as short a frequency repetition as possible to increase the capacity.

Further, according to the present invention, an excellent multi-cell multiple access communication system can be realized which realizes one frequency repetition by the non-spreading method and can increase the capacity by removing the interference inside / outside the cell. Also, a multi-cell multiple access communication method can be provided.

According to the present invention, it is not necessary to divide the frequency resource to be assigned to the base station even in the non-spreading system by assuming that multi-user detection is performed on the receiving side of wireless communication. ,As a result,
It is possible to solve the problem that the capacity of the entire communication system is limited.

Further, according to the present invention, the communication channel switching due to the handoff is not performed by realizing the one frequency repetition. As a result, the number of processing steps required for handoff can be reduced, and handoff can be smoothly performed with a high success rate.

Furthermore, by switching the communication channel when the reception status in the mobile station is not good, it is possible to provide the service with suitable communication quality even in the mobile station located at the cell boundary or the like.

[Brief description of drawings]

FIG. 1 is a diagram schematically showing a configuration of a multi-cell multiple access communication system according to this embodiment.

FIG. 2 is a diagram schematically showing a channel configuration received by a mobile station MS-A.

FIG. 3 is a diagram schematically showing a functional configuration on a receiver side that receives a reception signal R _A composed of a sum of two transmission signals R _XA and R _YA and noise.

FIG. 4 is a diagram showing in detail an internal configuration of a multi-user detector 31 configured by applying SIC.

FIG. 5 is a diagram for explaining a channel management system according to the present embodiment.

FIG. 6 is a diagram schematically showing a cell configuration in a mobile radio communication system in which a service area is surface-deployed by a plurality of base stations.

FIG. 7 is a diagram schematically showing how a mobile station hands off.

FIG. 8 is a diagram for explaining frequency resource assignment in a communication system that performs multiple access by a non-spreading method.

[Explanation of symbols]

11, 21 ... Transmitter 31 ... Multi-user detector 32, 33 ... Hard decision device 41, 43 ... Filter 42, 44 ... Interference canceller (IC) 45, 46 ... Multiplier 47 ... Adder 51, 52 ... Decoder / demodulator

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Kazuyuki Sakoda             6-735 Kita-Shinagawa, Shinagawa-ku, Tokyo Soni             -Inside the corporation F term (reference) 5K028 BB06 CC02 HH00 KK01 KK03                       SS04 SS14                 5K067 AA02 AA03 AA11 BB02 CC02                       CC04 CC10 EE02 EE10 EE41                       EE61 EE71 JJ11 JJ31 JJ71

Claims (14)

[Claims] 1. A multiple access communication system having a multi-cell / multi-user configuration, in which cells capable of communicating with each base station are adjacent to or close to each other, and spatial, temporal and frequency between adjacent or neighboring cells. Are shared by the same channel, and the receiving side station considers incoming signals from each transmitting side station inside and outside the cell as desired signals and detects multiple users. Multiple access communication system. 2. The multiple access system according to claim 1, wherein the station on the transmission side transmits the transmission signal by a non-spreading method. 3. The reception side station has a large reception power for a reception signal composed of the sum of an incoming signal and noise transmitted from each station on the transmission side inside and outside the cell and propagated through each propagation characteristic. The multiple access communication system according to claim 1, wherein all the received signals are detected by sequentially demodulating and canceling the own signal. 4. A multi-access multi-user communication method of a multi-cell multi-user configuration, in which cells capable of communicating with each base station exist adjacent to or close to each other, and spatial, temporal and frequency between adjacent or neighboring cells. Are shared by the same channel, and the receiving side station considers incoming signals from each transmitting side station inside and outside the cell as desired signals and detects multiple users. Multiple access communication method. 5. The multiple access method according to claim 4, wherein the station on the transmission side transmits the transmission signal by a non-spreading method. 6. The reception side station has a large reception power for a reception signal composed of the sum of an incoming signal and noise transmitted from each station on the transmission side inside and outside the cell and propagated through each propagation characteristic. 5. The multiple access communication method according to claim 4, wherein all the received signals are detected by sequentially demodulating and canceling the own signal. 7. A multiple-access multi-user communication system having a multi-cell multi-user configuration, in which cells capable of communicating with each base station are adjacent or close to each other, and spatial, temporal and frequency are established between adjacent or adjacent cells. , The same channel is shared, and the base station and mobile station consider the incoming signals from each station on the transmitting side inside and outside the cell as desired signals and detect multiple users. , Without allocating new frequency resources for mobile stations handing off from cells of other base stations,
A multiple access communication system, characterized in that reception of a signal from the mobile station is continued upon detection of the plurality of users. 8. The mobile station, when the deterioration of the quality of the received signal obtained by the detection of the plurality of users is expected, of the frequency resources allocated to the mobile station with respect to the base station in communication. 8. A change request is made.
A multiple access communication system according to. 9. A multi-cell / multi-user multiple access communication method in which cells capable of communicating with each base station exist adjacent to or close to each other, and spatial, temporal and frequency are established between adjacent or neighboring cells. The same channel is shared by the base station and the mobile station, and the base station and the mobile station detect multiple users by considering the incoming signals from each transmitting station inside and outside the cell as desired signals. , Without allocating new frequency resources for mobile stations handing off from cells of other base stations,
A multiple access communication method, characterized in that reception of a signal from the mobile station is continued upon detection of the plurality of users. 10. The mobile station, when deterioration of quality of a received signal obtained by the detection of the plurality of users is expected,
10. The multiple access communication method according to claim 9, wherein the base station in communication is requested to change the frequency resource allocated to the mobile station. 11. A wireless base station device operating in a multiple access communication environment of a multi-cell / multi-user configuration, in which cells capable of communicating with each base station are adjacent or close to each other. All the incoming signals from each mobile station are considered as desired signals to detect multiple users, and without assigning new frequency resources for mobile stations handing off from the cells of other base stations, A radio base station device, characterized in that reception of a signal from the mobile station is continued by detecting a plurality of users. 12. The radio base station apparatus according to claim 11, wherein a new frequency resource is allocated in response to the reception of a request to change the used frequency resource from the mobile station in communication. 13. A radio mobile station apparatus operating in a multiple access communication environment of a multi-cell / multi-user configuration, in which cells capable of communicating with each base station are adjacent or close to each other, wherein the mobile station is within and outside the cell. A radio mobile station apparatus, wherein all incoming signals from a station are regarded as desired signals and a plurality of users are detected. 14. A base station in communication is requested to change the frequency resource assigned to its own mobile station when deterioration of quality of a received signal obtained by detection of the plurality of users is expected. The wireless mobile station device according to claim 13, wherein