JP2009188456A - Interference removing method and device of radio repeater for mobile communication - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an interference removing method and a device which is applied to a radio repeater. <P>SOLUTION: After a reception-side signal and an output-side signal are detected in real time, a weighting factor, based on correlation between the reception-side signal and output-side signal is computed in real time, an interference removal signal by the computed weighting factor is generated, thereby there is not a block where interference position is detected and all the interferences within a fixed section can be eliminated. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

The present invention relates to an interference removal method and apparatus in a radio repeater for mobile communication.

In general, a repeater is provided in an area where radio wave shadow areas are covered or the installation cost of a base station is borne, so that the service quality of mobile communication in the area is satisfied.

The repeater can be roughly classified into a wired repeater connected on one side to the base station by wire such as an optical cable, and a wireless repeater connected to the base station wirelessly. The wired repeater is capable of maintaining good call quality because wired communication is performed between the repeater and the base station, but it is more expensive than the wireless repeater, and moreover, the wired repeater and the wired repeater are installed. The cost of renting is considerably high. On the other hand, since the wireless repeater performs wireless communication between the repeater and the base station, the call quality is inferior to that of the wired repeater, but there is an advantage that installation and operation costs are low.

The wireless repeater as described above is even more preferable than an expensive wired repeater when the area that the repeater is responsible for is narrow due to the influence of electromagnetic wave shielding by the structure, such as underground in the building. Applicable. However, when a radio repeater is provided in an open area rather than inside the building, the transmission signal via the transmission antenna of the radio repeater is fed back to the reception antenna and mixed with the original reception signal. Not only can the service not be provided due to signal interference and oscillation phenomenon, but in the worst case, it may cause a base station failure. Due to such problems, the wireless repeater has been used only in a limited place such as the underground inside the building.

However, the merit of the wireless repeater that the installation and operation costs are lower than that of the wired repeater is still attractive, and the technology that can eliminate the interference of the feedback signal has appeared. Note that a radio repeater to which a technique capable of removing interference of such feedback signals is applied is an ICS (Interference).
Cancellation System) It is called a repeater.

Conventional interference cancellation techniques include a technique using an analog method (see, for example, Patent Document 1 below), a technique using a digital method (see, for example, Patent Document 2 below), an analog method, and a digital method. The present invention relates to an interference cancellation technique using a digital method.

Hereinafter, an example of an interference removal technique using a normal digital method will be described with reference to FIG.

A reception signal [R, R = S (original signal) + I (interference signal)] transmitted from the weighting factor calculation unit 22 via the reception antenna 11 is detected at the front end of the subtractor 21, and is transmitted via the transmission antenna 12. The output signal ^ S transmitted in this manner is detected at the front end of the transmission antenna 12. Further, an interference position is derived using the correlation between the received signal R and the output signal ^ S, and a weighting factor W for removing the interference is calculated using an ICS algorithm. Subsequently, the weighting factor calculation unit 22 applies the calculated weighting factor W to the adaptive filter 23. The adaptive filter 23 generates the interference cancellation signal ^ I and then generates the generated interference cancellation signal ^ I is input to the subtractor 21. In the subtracter 21, the reception signal R input from the reception antenna 11 side and the interference cancellation signal ^ I input from the adaptive filter 23 are mixed.

Among the above-described ordinary digital interference removal methods, according to the conventional technique, as shown in FIG. 2, positions A, B, and C where the interference is large in the entire time domain constant section (T: time) to be processed. After detecting the block and estimating the detected portion, the interference signal is removed only in the blocks A, B, and C where the interference is large. However, in this case, it takes time to detect and estimate the positions A, B, and C blocks with large interference, and as a result, the reaction speed of interference removal is slow.

In addition, the response to random fading generated by high-speed moving bodies (automobiles, etc.) is slow, and the relay quality of calls and transmission data deteriorates. This results in local restrictions.
Republic of Korea Published Patent No. 2003-0017171 Republic of Korea Published Patent No. 2003-0060186

The present invention has been made in view of the above circumstances, and an object thereof is to provide a technique capable of removing an interference signal from a received signal in real time.

In order to achieve the above object, the interference canceling method in the mobile communication radio repeater according to the present invention is a reception side signal in which the original signal S and the interference signal I are mixed (a signal transmitted from the reception antenna side). And a signal detection step for detecting an output side signal (a signal directed to the transmitting antenna side) in real time, and a weighting factor W using a correlation between the reception side signal and the output side signal detected in the signal detection step. A weighting factor calculating step for calculating the interference canceling signal ^ I based on the weighting factor calculated in the weighting factor calculating step in real time, and the interference canceling signal generating step from the receiving side signal. After subtracting the interference cancellation signal ^ I generated in step 1 in real time And a post-interference removal signal generation step for generating the signal Err.

More specifically, the weighting factor in the weighting factor calculation step is calculated by an ICS algorithm.

More specifically, the output-side signal in the weighting factor calculation step is a reference signal Ref for interference cancellation that compensates for the delay generated in the circuit itself at the rear end of the detection location.

In order to achieve the above object, an interference canceling apparatus in a mobile communication radio repeater according to the present invention receives a reception side signal in which an original signal S and an interference signal I are mixed (sent from a reception antenna side). Signal) and output side signal (signal toward the transmitting antenna side) are detected in real time, and the weighting factor W is calculated in real time using the correlation between the reception side signal and the output side signal. An interference cancellation signal generation unit that generates an interference cancellation signal ^ I in real time by applying the weighting factor calculated in real time in the weighting factor calculation unit, and the interference cancellation signal generation unit from the reception side signal A subtractor that subtracts the interference cancellation signal ^ I generated in step 1 in real time to generate a signal Err after subtraction removal. And features.

The interference cancellation apparatus further includes a delay correction unit that compensates for the delay generated in the circuit itself at the rear end of the detection location for the detected output-side signal ^ S, and then applies the delay correction unit to the weighting factor calculation unit.

More specifically, the interference cancellation signal generation unit is an adaptive filter.

Furthermore, the present invention includes a radio communication repeater for mobile communication to which the above-described interference cancellation method or interference cancellation apparatus is applied.

The present invention has the following effects.
First of all, by removing all the interferences in the defined section T in real time without the process of detecting the position where the interference is large, it is excellent in the reaction speed of interference removal and is randomized by a high-speed moving body. Excellent performance in fading.
Second, since it can be applied to a city center where there are many high-speed moving bodies, there is no restriction on the installation location.
Finally, by removing all interference within a defined section, the processing ability of multipath interference (primary interference, secondary interference, etc.) is excellent.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a block diagram of a main part of a radio repeater for mobile communication to which the interference canceller 300 according to the embodiment of the present invention is applied.

As shown in FIG. 3, the interference cancellation apparatus 300 according to the embodiment of the present invention includes a subtraction unit 31, a weighting factor calculation unit 32, an interference cancellation signal generation unit 33, a delay correction unit 34, and the like.

The subtractor 31 receives an interference cancellation signal input from the interference cancellation signal generator 33 from a reception signal (R, R = S + I) in which the original signal S and the interference signal I received via the reception antenna 11 are mixed. I is subtracted to generate a signal Err after interference cancellation.

The weighting factor calculation unit 32 detects the interference-removed signal Err generated and output from the subtraction unit 31 and the output signal ^ S output via the transmission antenna 12 in real time, and then based on the ICS algorithm, and The weighting factor W is calculated in real time using the correlation between the subtracted signal Err and the output signal ^ S. Here, the output signal ^ S detected by the weighting factor calculation unit 32 is a reference signal Ref for interference removal whose delay is corrected by the delay correction unit 34, as will be described later.

The interference cancellation signal generation unit 33 is provided as an adaptive filter, applies the weighting factor W calculated by the weighting factor calculation unit 32, generates an interference cancellation signal ^ I in real time, and gives it to the subtraction unit 31.

The delay correction unit 34 corrects the delay of the output signal ^ S detected on the transmission path. That is, the output signal ^ S has the same delay as the interference signal I fed back by compensating for the delay generated in the circuit itself at the rear end of the detected portion. The delay correction unit 34 provides the interference cancellation signal generation unit 33 and the weighting factor calculation unit 32 with the reference signal Ref for interference cancellation whose delay is corrected in the output signal ^ S.

For reference, the filter denoted by reference numeral 20 functions as a correlation element for increasing the correlation between the post-interference signal Err detected in real time by the weighting factor calculation unit 32 and the output signal ^ S.

Hereinafter, for convenience, an interference removal method performed in the interference removal apparatus 300 having the above-described configuration will be described based on the flowchart of FIG.

1. Signal detection <S401>
The interference-removed signal Err and the output signal ^ S are detected in real time at the rear end of the subtractor 31 and the front end of the transmission antenna 12, respectively.

2. Delay correction <S402>
The delay correcting unit 34 compensates for the delay of the output signal ^ S detected at the front end of the transmitting antenna 12 and generates a reference signal Ref for interference removal. The generated interference cancellation reference signal Ref is given to the weighting factor calculation unit 32 and the interference cancellation signal generation unit 33.

3. Calculation of weighting factor <S403>
In the weighting factor calculation unit 32, the post-interference signal Err detected at the rear end of the subtractor 31 using the ICS algorithm, and the delay correction unit 34 after correcting the signal after detection at the front end of the transmission antenna 12. The weighting factor W is calculated in real time using the correlation with the reference signal Ref for interference removal.

4). Generation of interference cancellation signal <S404>
The interference cancellation signal generation unit 33 applies the weighting factor W calculated by the weighting factor calculation unit 32 to the interference cancellation reference signal Ref input from the delay correction unit 34 side to generate an interference cancellation signal. The interference cancellation signal ^ I generated in this way by the interference cancellation signal generation unit 33 is input to the subtractor 31.

5. Generation of signal after interference removal <S405>
The subtractor 31 subtracts the interference cancellation signal ^ I input from the interference cancellation signal generation unit 33 from the reception signal R received via the reception antenna 11 in real time, so that the signal after interference cancellation is received from the reception signal R. Err is generated.

Further, the post-interference signal Err generated in step S405 is output to the transmitting antenna 12 side, and the post-interference signal Err is detected in real time as described in step S401. That is, as described above, the interference cancellation signal generation unit 32 has a signal component having a correlation with the interference cancellation reference signal Ref used in the ICS algorithm among the reception signal R components received via the reception antenna 11. However, since the interference signal I has a correlation with the reference signal Ref for interference removal, the interference signal I is removed from the reception signal R.

On the other hand, since the original signal S has no correlation with the interference removal reference signal Err, it passes through the subtracter 31 without being removed, and is sent to the transmitting antenna 12 side through the filter 30 and the like.

That is, according to the above-described embodiment of the present invention, the interference is detected in real time within the constant time zone to be processed without deriving the position of the large interference within the constant time zone T to be processed. It can be removed.

While the present invention has been illustrated and described in connection with preferred embodiments for illustrating the principles of the present invention, the present invention is not limited to such construction and operation as illustrated and described. Rather, it will be apparent to those skilled in the art that numerous modifications and variations can be made to the present invention without departing from the spirit and scope of the appended claims. Accordingly, all such suitable changes and modifications and equivalents should also be considered within the scope of the present invention.

It is a block diagram of the radio repeater by a prior art. It is a reference diagram for demonstrating the interference removal system in the radio repeater of FIG. It is a block diagram of the principal part of the radio repeater to which the interference cancellation apparatus by embodiment of this invention was applied. It is a flowchart of the interference removal method performed in the interference removal apparatus of FIG.

Explanation of symbols

300: interference cancellation device 31: subtraction unit 32: weighting factor calculation unit 33: interference cancellation signal generation unit 34: delay correction unit S: original signal I: interference signal R: reception signal
^ S: Output signal
^ I: Interference cancellation signal Err: Interference cancellation signal Ref: Interference cancellation reference signal W: Weighting factor Fs: Sampling frequency T: All time domain constant interval to be processed

Claims (8)

Signal detection step for detecting in real time a reception side signal (a signal transmitted from the reception antenna side) and an output side signal (a signal directed to the transmission antenna side) in which the original signal (S) and the interference signal (I) are mixed When,
A weighting factor calculation step of calculating a weighting factor (W) using the correlation between the reception side signal and the output side signal detected in the signal detection step;
An interference cancellation signal generating step for generating an interference cancellation signal (^ I) based on the weighting factor calculated in the weighting factor calculation step in real time;
A signal generation step after interference removal that subtracts the interference cancellation signal (^ I) generated in the interference cancellation signal generation step from the reception side signal in real time to generate the signal after interference cancellation (Err);
The interference removal method in the radio | wireless repeater for mobile communications which removes all the interference in a fixed area in real time characterized by including these. The weighting factor in the weighting factor calculation step is:
The interference cancellation method in the radio repeater for mobile communication according to claim 1, wherein the interference cancellation method is calculated by an ICS algorithm. The output side signal in the weighting factor calculation step is:
2. The interference canceling method for a radio repeater for mobile communication according to claim 1, wherein the interference canceling reference signal (Ref) compensates for the delay generated in the circuit at the rear end of the detection point. A reception side signal (a signal sent from the reception antenna side) and an output side signal (a signal going to the transmission antenna side) mixed with the original signal (S) and the interference signal (I) are detected in real time, and the reception A weighting factor calculation unit that calculates the weighting factor (W) in real time using the correlation between the side signal and the output side signal;
An interference cancellation signal generation unit that generates an interference cancellation signal (^ I) in real time by applying the weighting factor calculated in real time in the weighting factor calculation unit;
A subtractor that subtracts the interference cancellation signal (^ I) generated in the interference cancellation signal generation unit from the reception side signal in real time to generate a signal after subtraction removal (Err);
An interference canceling apparatus in a radio repeater for mobile communication, comprising: 5. A delay correction unit for giving to the weighting factor calculation unit after compensating for the delay generated in the circuit at the rear end of the detection point with respect to the detected output side signal (^ S). The interference removal apparatus in the radio | wireless repeater for mobile communications as described in any one of. The interference cancellation signal generator is
5. The interference canceling apparatus for a radio repeater for mobile communication according to claim 4, wherein the interference canceling apparatus is an adaptive filter. A radio repeater for mobile communication, to which the interference cancellation method according to claim 1 is applied. A radio repeater for mobile communication to which the interference canceller according to any one of claims 4 to 6 is applied.