JP3337274B2 - Mobile communication system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used for a digital mobile communication system comprising a plurality of wireless communication areas. The present invention relates to a technique for reducing the number of frequency channels allocated to a plurality of base stations and effectively using radio waves. The present invention also relates to a technique for improving the efficiency of removing interference waves and improving communication quality.

[0002]

2. Description of the Related Art In a radio transmission system such as mobile communication, a plurality of base stations are installed at a distance, and a communication area is formed around the base stations. The communication area is conceptually an area such as a square, a hexagon, or a sector, and a mobile station in the area can connect to a base station in the communication area to perform communication. A carrier frequency is allocated to a radio channel for performing this communication. However, if the same frequency is used in an adjacent communication area, interference occurs and good communication cannot be performed. To this end, a plurality of carrier frequencies assigned to the system are divided into groups, a group is formed for each carrier frequency, and a frequency allocation method has been applied so that the same carrier frequency is not used in adjacent communication areas. The communication area in which the frequencies are arranged in this way is called a cell.

A conventional cell configuration will be described with reference to FIG. FIG. 9 is a diagram showing a conventional cell configuration. FIG. 9 shows the number N of carrier frequency groups in a hexagonal cell.
Shows the arrangement of the carrier frequency groups when is "4". N is also called the frequency repetition number. In FIG. 9, the carrier frequency is a carrier frequency group F1,
F2,..., F4. Even if the same frequencies are arranged at a distance from each other, the propagation characteristics change with the arrangement of the building and the movement of the mobile station, so that the interference power (PI) is larger than the desired signal power (PD). There is a moment. Therefore, the carrier-to-interference power ratio (CI) obtained from the interference power (PI) and the desired signal power (PD) based on the short section average level instead of the average power
R) are arranged so that the repetition of groups of the same carrier frequency is separated with a sufficient margin from the average carrier-to-interference power ratio so that the probability that R) becomes equal to or less than a certain value is sufficiently small.

[0004] A communication area obtained by dividing one cell by installing a plurality of directional antennas in one base station is called a sector. Since the directivity of the directional antenna is not ideal and the sectors cannot be completely separated, different carrier frequency groups are arranged in each sector. A conventional sector configuration will be described with reference to FIG.
FIG. 10 is a diagram showing a conventional sector configuration. In each sector, carrier frequency groups F1, F2, F3 are arranged. In practice, there are a plurality of similarly sectorized cells around a sectorized cell, so that the carrier frequency groups F1, F2, F
Carrier frequency groups other than 3 are arranged. Therefore, the number N of the entire carrier frequency groups is 3 or more.

[0005] While the method of allocating frequencies in a fixed manner has been described above, a dynamic channel assignment for dynamically allocating radio channels according to the traffic of each cell is known. In this method, the number of carrier frequencies allocated to the carrier frequency group dynamically changes according to the traffic of the cell, but the value of N does not change significantly. That is, N remains a large value of 3 or more.

[0006]

In these planar frequency allocation methods, in order to avoid the influence of interference, the number of repetitions N
Could not be less than a certain value. For example, in a hexagonal cell, N is a discrete integer value of 3, 4, 7,... And cannot be smaller than 2.

In other words, in order to form a service area which is a set of cells, it is necessary to use radio channel channels based on a number of frequency groups.

[0008] The object of the present invention has been made in view of such a background, and it is possible to reduce the number of repetitions N of the same frequency to 2 or less in one service area, and to use a mobile station capable of effectively using radio waves. It is to provide a wireless system.

It is another object of the present invention to provide a mobile communication system in which the efficiency of removing an interference wave is improved by using a training signal having a small cross-correlation and the communication quality is improved.

[0010]

SUMMARY OF THE INVENTION The present invention is a mobile communication system comprising a plurality of base stations, wherein a mobile station establishes a signal transmission path via a radio line with these base stations for communication.

Here, a feature of the present invention is that the base station or the mobile station includes means for transmitting a signal sequence including a training signal for each signal transmission path, and the mobile station or the base station receives the signal sequence. Means for removing an interference wave based on the training signal and extracting a desired wave.

It is to be noted that the base station or the mobile station is provided with a means for transmitting the training signals in the signal sequence with the same timing phase, whereby a more preferable system is configured.

[0013] Further, two or less carrier frequency groups are repeatedly assigned to a communication area in which a signal transmission path is set, thereby forming a more preferable system.

Further, it is preferable to use a training signal having a small cross-correlation as a training signal used in a signal transmission path which causes mutual interference.

[0015] The communication area may be composed of a plurality of sectors centered on a base station.

Further, the base station can be provided with a transmission diversity antenna forming a plurality of signal transmission paths for the mobile station.

Furthermore, it is preferable to use transmission power control means for making the average reception power from the mobile station received by the base station substantially constant.

[0018]

In the communication area formed by the base station, two or less carrier frequency groups are repeatedly assigned. In this case, a carrier frequency group can be repeatedly assigned to each cell of a communication area formed by one base station, and the communication area has a sector configuration such as a sector centered on the base station. Can be repeatedly assigned.

In the case of a sector configuration, the same carrier frequency is used in one cell, so that interference occurs. As a method for canceling the interference wave, the base station or the mobile station is provided with an adaptive interference canceller for distinguishing the desired wave from the interference wave. The adaptive interference canceller receives a signal sequence including a training signal transmitted from a base station or a mobile station, and reduces an interference wave based on the training signal. This training signal is different for each sector. The training signal is a signal whose phase as a signal sequence is synchronized, and a signal sequence having a small cross-correlation is used. Extract the waves.

If the communication area is not divided into sectors,
Interference wave cancellation can be performed by repeatedly assigning two or less carrier frequency groups to cells serving as communication areas formed by the base station and using different training signals for each communication area.

Further, a transmission diversity antenna is provided in the base station, and different signal sequences at the same frequency are transmitted from the transmission diversity antenna to the mobile station through different signal transmission paths. The mobile station can extract a signal received on one signal transmission line as a desired wave by using an adaptive interference canceller with respect to a signal received on the same frequency but on a different signal transmission line.

In the conventional mobile communication system of frequency allocation, the use of the training signal for each cell or each communication area such as a sector improves the interference wave removal efficiency, so that the communication quality can be improved. it can.

Further, the average received power of the signal from the mobile station at the base station can be made substantially constant by the transmission power control, so that the adaptive interference canceller can be operated effectively.

[0024]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The construction of a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a diagram showing a cell configuration according to the first embodiment of the present invention. FIG. 2 is a block diagram of the adaptive interference canceller according to the first embodiment of the present invention.

In this embodiment, each of the base stations B1 to B5
Constitute a cell as a communication area, and the mobile stations C1 and C2 are connected to the base stations B1 to B5 by radio channels of the carrier frequency groups F1 and F2 assigned to the respective base stations B1 to B5.
This is a mobile communication system that performs communication by being connected to B5.

Here, the features of this embodiment are as follows.
The cells formed by the base stations B1 to B5 are repeatedly assigned two or less carrier frequency groups F1 and F2, and the base stations B1 to B5 or the mobile stations C1 and C2 generate a signal sequence including a training signal different for each cell. And an adaptive interference canceller shown in FIG. 2 as means for removing an interference wave and extracting a desired wave based on a training signal transmitted from a base station or a mobile station.

In order to set a different training signal for each cell in each signal transmission line, a means for knowing which signal transmission line the base station has set which training signal is required. In order to avoid this, there is a method in which a training signal is determined in advance for each cell.

Base stations B1 to B5 or mobile stations C1, C2
Has means for inserting a training signal into a transmission signal. Also, the base stations B1 to B5 or the mobile stations C1, C2
Has means for transmitting the training signals in the signal sequence with the same timing phase between different base stations B1 to B5. Further, a signal having a small cross-correlation between training signals different for each cell is used.

FIG. 1A shows a carrier frequency group F
1 is used repeatedly in hexagonal cells. FIG.
(B) shows two carrier frequency groups F1 and F
2 is used repeatedly in a square cell. In such an arrangement method, as described above, the probability that the level of the interference wave becomes higher than the desired wave increases, so that communication becomes impossible on the conventional transmission path. In the present invention, the adaptive interference canceller is installed in the base stations B1 to B5 and the mobile stations C1 and C2 together with such an arrangement method. Hereinafter, for ease of explanation, downlink signals from the base stations B1 to B5 to the mobile stations C1 and C2 will be described. The same applies to uplink signals from the mobile stations C1 and C2 to the base stations B1 to B5.

Next, the operation of the adaptive interference canceller according to the first embodiment of the present invention will be described with reference to FIG. The adaptive interference canceller of FIG. 2 is a linear interference canceller. Hereinafter, a description will be given using a complex display in which the in-phase amplitude component of the wireless signal is a real part and the quadrature amplitude component is an imaginary part.

In the linear interference canceller, the first antenna A
The signal received by the NT1 is amplified and detected by the receiving unit REC1, and a complex envelope is extracted. Receivers REC1 and RE
C2 includes an amplifier, a synthesizer, a filter, a mixer,
A detector and the like are included. The weighting of the first complex coefficient to the complex envelope is performed by the multiplication circuit MUL1.

Similarly, the signal received by the second antenna ANT2 is multiplied by the second complex coefficient by the multiplication circuit MUL2. After the two multiplication outputs are synthesized by the complex synthesis circuit ADD1, the complex judgment circuit DEC judges the synthesized signal. The judgment output is the output of this canceller.

The difference between the input and output signals of the complex decision circuit DEC is taken by an adder ADD2 to extract the error. Control circuit CO
The NT uses the inputs of the multiplication circuits MUL1 and MUL2 and the extracted error to calculate two complex coefficients by an algorithm that minimizes the error. Here, control is performed by the least square method, and when there is noise, the complex coefficient is determined so as to maximize the signal-to-noise power ratio CNR. When the interference wave is larger than noise, control is performed so that the signal-to-interference power ratio CIR becomes maximum. At this time, the complex coefficients are determined so that the interference cancels each other in the complex combining circuit ADD1.

The linear interference canceller according to the first embodiment of the present invention has the same configuration when there are three or more receiving antennas, and cancels the number of interference waves obtained by subtracting 1 from the number of antennas.

Next, a second adaptive interference canceller according to the first embodiment of the present invention will be described with reference to FIG. FIG. 3 is a block diagram of a second adaptive interference canceller according to the first embodiment of the present invention. The adaptive interference canceller of FIG. 3 is a non-linear interference canceller. In the nonlinear interference canceller, a replica of the desired wave and the interference wave included in the received wave is generated, and each replica is subtracted from the received wave by the complex difference circuits SUB1 and SUB2. The error, which is the output of the complex difference circuits SUB1 and SUB2, is simply a noise component of the received wave when a correct replica is subtracted.
Using this error as a metric, maximum likelihood sequence estimation processing is performed by a maximum likelihood sequence estimation circuit MLSE. Maximum likelihood sequence estimation circuit ML
The SE outputs a complex decision value of the signal as a canceller output. From the maximum likelihood sequence estimation circuit MLSE,
Transmission sequence candidates of the desired wave and the interference wave are output, and replicas of the desired wave and the interference wave are generated by the respective signal regeneration circuits REG-S and REG-I. These reproductions require estimated values of the amplitude and phase of the carrier components of the received desired wave and interference wave, that is, complex amplitude coefficients, and these coefficients are generated by the respective control circuits CONT-S and CONT-I. Is done. In these control circuits, the complex amplitude coefficient is estimated based on the transmission sequence candidate and the error such that the error is minimized.

In the maximum likelihood sequence estimation processing as described above, since the interference wave component is canceled from the error, a good detection characteristic can be obtained. When the number of interference waves is one or more, the function is extended so that the maximum likelihood sequence estimation circuit MLSE can output transmission sequence candidates for the increase of interference waves in order to generate a replica for the increase, and the signal reproduction circuit REG- I, a complex difference circuit SUB and a control circuit CONT-I are added.

The same configuration can be adopted when there are two or more receiving antennas ANT in the nonlinear interference canceller. That is, the same maximum likelihood sequence estimation circuit MLSE is used, and the other complex difference circuits SUB1 and SU
B2, the signal reproducing circuits REG-S and REG-I, and the control circuits CONT-S and CONT-I are added in a manner similar to the second antenna and the like added thereto. The added signal reproducing circuits REG-S and REG-I include:
Signal regeneration circuits REG-S and R of the first antenna ANT
EG-I signal sequence candidates are input. The error component obtained by subtracting the corresponding replica from each antenna reception wave is added to the square of each absolute value, and the maximum likelihood sequence estimation circuit MLS
E is input. In the nonlinear interference canceller, although the number of interference waves that can be canceled does not increase even if the number of antennas is increased, the interference canceling effect operates stably because the received power increases.

Conventionally, a method of using these interference cancellers as an alternative to an equalizer has been considered in order to cancel a delayed wave generated by multipath propagation of a desired wave. Also, it has been used as a means for canceling an interference wave as an adaptive array antenna in a radar or the like. However, in the present invention, two or less carrier frequency groups F1 and F2 are arranged repeatedly so that the interference wave whose level has increased is canceled on the receiving side. In the repetition of two or less carrier frequency groups F1 and F2,
Since high-level interference of two or more waves occurs randomly,
The nature of the interference wave in the present invention is completely different from that of the delayed wave due to multipath or interference from a distant cell.

Next, the signal configuration used in the first embodiment of the present invention will be described with reference to FIG. FIG. 4 is a diagram showing a signal configuration used in the first embodiment of the present invention. The control circuit CONT in the interference canceller needs to quickly optimize the value of the complex coefficient. For this purpose, a training signal is inserted into a signal sequence to be transmitted. Since the training signal is known on the receiving side, it is not necessary to make a determination in a training section. If an error is directly calculated using a known training signal, erroneous convergence due to a determination error can be eliminated. When the erroneous convergence is eliminated, an accurate coefficient that converges at a high speed is required, so that the interference cancellation characteristic is improved.

If the timing phase of the training signal in the signal sequence is not synchronized between the desired wave and the interference wave, the interference wave may become a data sequence when training the desired wave. In the random modulation, the data of the interference wave may accidentally become a signal close to the training signal of the desired wave in the training section of the desired wave. At this time, since the canceller cannot distinguish between the desired wave and the interference wave, the cancellation characteristic is deteriorated. Such deterioration can be avoided by synchronizing the training signals as shown in FIG. 4 and making the training signals different. As a guide for different training signals, it is conceivable to reduce the cross-correlation of the training signals. At this time, if the complex coefficients are obtained by the least squares method, the least squares method will correlate with the training signal within the time of taking the mean square, so that an interference wave without cross-correlation is regarded as noise, and the error due to noise is considered. Is controlled so that is minimized. Timing synchronization of the training signal requires special equipment for synchronization when the cell is far away. The accuracy may be such that the cross-correlation can be regarded as small. For example, for a training signal of 10 symbols, about ± 2 symbols can be considered as a guide. In order to synchronize the timing phases of the training signals transmitted from the base stations, for example, the timing phases of the training signals transmitted from a plurality of base stations can be synchronized under the control of the control station. Further, the present embodiment is a digital communication system for transmitting and receiving a signal having a burst configuration. Since the transmission timing of the mobile station is controlled based on the timing signal from the base station, the timing phase of the training signal is synchronized. Can be sent.

Next, a second embodiment of the present invention will be described with reference to FIG. FIG. 5 is a diagram showing a sector configuration according to the second embodiment of the present invention. In FIG. 5A, the same frequency is allocated to all sectors in which three frequency groups are conventionally allocated. 5 (b) and 5 (c), two carrier frequency groups F1 and F2 are alternately arranged. In the case of FIG. 5B, the same carrier frequency groups F1 and F2 have directivities opposite to each other, and the load on the interference canceller is reduced. Also, in the case of FIG. 5C, the same frequency is alternated, despite the fact that the sectors are installed in multiple stages to improve the frequency utilization rate by locational repetition. The burden on the interference canceller is reduced as compared with the method of ()).

When the present invention is applied to a sector, since the signal processing is performed in the same base station B, the synchronization of the training signal shown in the first embodiment of the present invention becomes easy. That is,
Since the signals of each sector are processed and transmitted in the same base station B, unlike the case of the cell, no specially complicated device is required for synchronizing the training signals. It should be noted that the training signal may be any signal as long as it has a different cross-correlation between sectors in which the same frequency is arranged, which differs for each sector.

Also, since signals from mobile stations C1 and C2 in each sector to base station B are received by the same base station B, the interference wave in the same cell may be an interference in a certain sector but may be different. In this sector, it is a wanted wave. Therefore, the configuration of the nonlinear interference canceller shown in FIG. 3 of the first embodiment of the present invention can be simplified. When this non-linear canceller is applied to a cell, the interference wave is a signal of another cell, so it is only required as a signal for cancellation. However, if applied to a sector, the interference wave is a signal of the own cell, so that the transmission characteristics can be improved by operating cooperatively with an adaptive interference canceller in another sector of the own cell as follows.

An adaptive interference canceller used in the second embodiment of the present invention will be described with reference to FIG. FIG. 6 is a block diagram of an adaptive interference canceller according to the second embodiment of the present invention. Desired signal S1 to be received in sector # 1
And the desired signal S2 to be received by the sector # 2 at the same time. In sector # 1 and sector # 2, the roles of the desired wave and the interference wave are reversed. Sector # 1
For each of # 2 and # 2, replicas of the desired signals S1 and S2 and the interference signals I1 and I2 are generated. The maximum likelihood sequence estimation circuit MLSE performs a maximum likelihood sequence estimation process and generates an optimal replica.

Next, another adaptive interference canceller used in the second embodiment of the present invention will be described with reference to FIG. FIG. 7 is a block diagram of another adaptive interference canceller used in the second embodiment of the present invention. When the level of the desired signal S1 of the sector # 1 is sufficiently higher than the level of the interference wave I2, the complex determination circuit MLSE1 detects the desired signal S1 independently.
The level of the desired signal S2 in the sector # 2 is equal to the interference wave I1.
If it is not too high, it is considered that the influence of the interference wave is large, and the processing result of the maximum likelihood sequence estimation circuit MLSE1 is used to generate a replica of the interference wave of the sector # 2. This eliminates the need for the maximum likelihood sequence estimation circuit MLSE2 to generate interference wave candidates, thereby reducing processing. Also, the interference wave I
Since the detection signal S1 which is considered to have a low error detection probability is used when generating one replica, the canceling effect is enhanced and the error rate of the desired signal S2 is also reduced.

Next, a third embodiment of the present invention will be described with reference to FIG. FIG. 8 is a diagram showing a base station and a cell according to the third embodiment of the present invention. In the third embodiment of the present invention, an antenna for transmission diversity is set in the base station B. From transmission antennas # 10 and # 20, signals S10 and S2 of the same carrier frequency group belonging to frequency F1
0 is transmitted. As a transmission method, antenna # 10
, A signal S10 from the antenna # 20, a signal S1 + S2 from the antenna # 10,
20, a signal S1-S2 is transmitted. In either method, the signals S10 and S20 are independent and at the same level. In addition, antennas # 10 and # 20 are sufficiently separated from each other so that the paths of the transmission paths are different. At this time, the signals from the antennas at the receiving point are independent of each other. Hereinafter, the above-described method will be described.

Since the antennas are fully separated, signals passing through different paths are received, and the interference canceller at the mobile station can separate and detect the received signal S1 or S2 or both using the training signal. it can. That is, in the first and second embodiments of the present invention, only one signal can be transmitted using one carrier frequency. However, in the third embodiment of the present invention, one carrier frequency can be transmitted in one cell. Two signals can be shared. That is, it can be used twice. If the L transmitting antennas are installed sufficiently far around the base station and different signals are transmitted from each transmitting antenna, the signal is received by the mobile station via L paths in principle. Therefore, if a signal is received by a linear canceller having L or more antennas, one of the signals can be received as a desired signal. Also, a desired signal can be received similarly by using a nonlinear interference canceller capable of generating (L-1) interference wave replicas.

When the number L of antennas is large, L / 2 signals may be transmitted from two transmitting antennas per signal with L being an even number without assigning them to separate signals. By doing so, the number of interference waves decreases and the number of diversity per signal increases, so that transmission characteristics are improved and the scale of the canceller can be reduced.

As described above, in the frequency allocation method in which a plurality of transmission antennas are set, different signals can be transmitted at the same carrier frequency in the same radio area, so that a plurality of mobile stations can use the same carrier frequency at the same time. Also,
By using this property, information up to L times can be transmitted to the same mobile station. For example, after doubling the information into two halves of an algorithm and transmitting them with different transmitting antennas, separating the two by an interference canceller at the mobile station and detecting them, when these are divided on the transmitting side, the opposite is true. Synthesize by algorithm. In the linear interference canceller, hardware may be configured to extract each signal separately. Further, in the nonlinear interference canceller, the configuration described in the second embodiment with reference to FIG. 6 or FIG. 7 may be used, and the input may be a diversity receiving antenna of a mobile station instead of a sector antenna. Conventionally, in order to perform double transmission, it was necessary to double the band or to multi-value the band. However, in the former, the number of channels is reduced, and in the latter, the power efficiency of the transmission power amplifier is reduced. There were drawbacks. According to the present invention, the transmission band does not increase, and each antenna output may use a conventional amplifier independently.

In the third embodiment in which a plurality of transmitting antennas are set in the base station, a training signal for each signal transmission path formed by the transmitting antenna is added to the signal sequence transmitted from the transmitting antenna. This is the same as in the first and second embodiments.

Next, a fourth embodiment will be described. In the above-described first and second embodiments, the repetition of the carrier frequency group assigned to the communication area is set to 2 or less to achieve effective use of radio waves. By using the mobile communication system for each area, it is possible to provide a mobile communication system in which interference is reduced and communication quality is improved.

In the fourth embodiment, it is assumed that the arrangement of the carrier frequency groups assigned to the base stations is the same as that of the conventional example, for example, as shown in FIG. At this time, the training signal defined for each base station has a small cross-correlation with the base station to which the same carrier frequency group that may cause interference is allocated, and the desired signal interferes with the desired signal at the same carrier frequency. It shall be able to distinguish between waves.

The adaptive interference canceller shown in FIG. 2 or the adaptive interference canceller used in FIGS. 3, 6 and 7 eliminates interference waves at the same carrier frequency based on a training signal having a small cross-correlation. Is improved. For example, even when interfering radio waves from cells in which the same carrier frequency group is arranged at a distance due to the relationship between radio wave conditions and terrain, etc., even if interfering radio waves are mixed based on the training signal of the desired wave and the interfering wave with a small cross-correlation If interference wave removal is performed, interference cancellation characteristics are improved. In particular, since the training signal used in a cell in which interference may occur has a small cross-correlation, even if the carrier frequency group is arranged in the conventional manner, the training signal can be arranged as described above. By doing so, a mobile radio system with improved communication quality can be realized.

Next, a fifth embodiment of the present invention will be described. In transmission from a mobile station to a base station, if the transmission power is kept constant, the received power changes significantly due to fluctuations in the propagation path length and propagation path. Since the adaptive interference canceller does not ideally cancel the interference wave, if the interference wave level of the desired signal exceeds the canceling ability, the cancellation becomes impossible and the operation becomes unstable.
Therefore, means for controlling the transmission power of the mobile station so that the reception power at the base station becomes substantially constant is installed in the mobile station.

As such a transmission power control method, an increase / decrease signal is transmitted from the base station to each mobile station in accordance with the base station average received power from each mobile station, and the mobile station responds to this increase / decrease signal. There is a method of controlling transmission power. Further, the transmission power from the base station is kept constant, the propagation loss is estimated based on the average received power of the signal from the base station received by the mobile station, and the transmission from the mobile station is performed according to the estimated loss. There is a way to control power.

As described above, if the transmission power of the mobile station is controlled, the average received power from any mobile station becomes substantially constant, so that the adaptive interference canceller can operate well.

[0057]

As described above, according to the present invention,
The same frequency repetition number N in one service area
Can be reduced to 2 or less, so that the frequency use efficiency can be improved and the radio waves can be effectively used.

In addition, since two diversity antennas for reception are also installed in the current base station, a modem in the station can be simply used without making any major changes in antenna equipment and the like.
The present invention can be implemented by changing the amplifier equipment.

Further, in the present invention, the efficiency of removing interference waves is improved by using a training signal having a small cross-correlation for each cell or each sector while maintaining the current frequency arrangement with respect to the cell, thereby improving the communication quality. A mobile radio system can be provided.

[Brief description of the drawings]

FIG. 1 is a diagram showing a cell configuration according to a first embodiment of the present invention.

FIG. 2 is a block diagram of an adaptive interference canceller according to the first embodiment of the present invention.

FIG. 3 is a block diagram of another adaptive interference canceller according to the first embodiment of the present invention.

FIG. 4 is a diagram showing a signal configuration used in the first embodiment of the present invention.

FIG. 5 is a diagram showing a sector configuration according to a second embodiment of the present invention.

FIG. 6 is a block diagram of an adaptive interference canceller according to a second embodiment of the present invention.

FIG. 7 is a block diagram of another adaptive interference canceller according to the second embodiment of the present invention.

FIG. 8 is a diagram showing a base station and a cell according to a third embodiment of the present invention.

FIG. 9 is a diagram showing a cell configuration of a conventional example.

FIG. 10 is a diagram showing a conventional sector configuration.

[Explanation of symbols]

 REC1, REC2 Receiver ADD1 Complex synthesis circuit ADD2 Addition circuit B1 to B5 Base station C1, C2 Mobile station ANT Antenna ANT1 First antenna ANT2 Second antenna CONT, CONT-S, CONT-I Control circuit MLSE Maximum likelihood sequence estimation circuit MUL1 , MUL2 Multiplication circuit SUB1, SUB2 Complex difference circuit REG-S, REG-I Signal reproduction circuit DEC Complex decision circuit F1 to F4 Carrier frequency group

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) H04B ^7/ 24-7/26 102 H04Q ^7/ 00-7/38

Claims (7)

(57) [Claims] 1. A mobile communication system comprising a plurality of base stations, in which a mobile station establishes a signal transmission path via a radio channel and communicates with these base stations, wherein the base station or the mobile station comprises: Means for transmitting a signal sequence including a training signal for each transmission path, wherein the mobile station or the base station creates a replica of an interference wave and a desired wave based on the received training signal and interferes A mobile communication system comprising means for removing a wave and extracting a desired wave. (2)Mobile stations have multiple base stations,
Set up a signal transmission path with a wireless line to communicate with the base station.
In the mobile communication system to be performed, The base station or mobile station performs training for each signal transmission path.
Means for transmitting a signal sequence including a signaling signal, The mobile station or base station receives the training
A means to remove interference waves and extract desired waves based on signals
Prepared, The transmitting means includes: Training signal in signal sequence
Means to transmit signals with the same timing phaseIncluding thing
Characterized byMobile communication method. (3)Mobile stations have multiple base stations,
Set up a signal transmission path with a wireless line to communicate with the base station.
In the mobile communication system to be performed, The base station or mobile station performs training for each signal transmission path.
Means for transmitting a signal sequence including a signaling signal, The mobile station or base station receives the training
A means to remove interference waves and extract desired waves based on signals
Prepared,  The communication area where the signal transmission path is set
A Frequency group is repeatedly assignedFeatures
To beMobile communication method. (4)Mobile stations have multiple base stations,
Set up a signal transmission path with a wireless line to communicate with the base station.
In the mobile communication system to be performed, The base station or mobile station performs training for each signal transmission path.
Signal system including signaling signal A means for transmitting a column, The mobile station or base station receives the training
A means to remove interference waves and extract desired waves based on signals
Prepared,  Training used in signal transmission lines that cause interference with each other
Use a signal with low cross-correlationFeatures
To beMobile communication method. 5. A communication area in which a signal transmission path is set ,
5. The mobile communication system according to claim 1, comprising a plurality of sectors centered on a base station. 6.Mobile stations have multiple base stations,
Set up a signal transmission path with a wireless line to communicate with the base station.
In the mobile communication system to be performed, The base station or mobile station performs training for each signal transmission path.
Means for transmitting a signal sequence including a signaling signal, The mobile station or base station receives the training
A means to remove interference waves and extract desired waves based on signals
Prepared,  Form multiple signal transmission paths for mobile stations in base station
Equipped with transmit diversity antennaCharacterized byTransfer
Mobile communication system. 7.Mobile stations have multiple base stations,
Set up a signal transmission path with a wireless line to communicate with the base station.
In the mobile communication system to be performed, The base station or mobile station performs training for each signal transmission path.
Means for transmitting a signal sequence including a signaling signal, The mobile station or base station receives the training
A means to remove interference waves and extract desired waves based on signals
Prepared,  Base station average received power in transmission from mobile station to base station
Transmission power control means for making the power substantially constantFeatures
To beMobile communication method.