KR100379380B1 - Method for removing interference signal in communication system - Google Patents

Abstract

The present invention is to provide a method for removing interference signals in a communication system that can improve the overall communication quality by using different interference signal cancellation methods for voice calls and data calls received through a radio link. In such a communication system, an interference signal canceling method includes a first step of searching for a second user signal having a greater signal-to-noise ratio than a first user signal to be detected, and having a signal-to-noise ratio greater than the first user signal. A second step of determining whether the second user signal is a voice call when there is a second user signal, a third step of decoding the second user signal if the second user signal is a voice call, and the decoded second user A fourth step of estimating a magnitude of a signal, a fifth step of reproducing a voice signal of the estimated second user signal, and a sixth step of removing the second user signal from the received signal with the reproduced second user voice signal Is made of.

Description

Method for removing interference signal in communication system

The present invention relates to a method for canceling an interference signal in a communication system, and in particular, to provide an interference signal method in a communication system suitable for improving overall communication quality by using a method for canceling an interference signal different from each other according to a voice call and a data call. will be.

In general, as a method of canceling interference signals according to voice and data calls in a direct sequence communication system, there is a successive interference cancellation (SIC) method.

Here, the voice call and the data call have different characteristics, and the voice call requires fast output without delay of signal processing rather than accuracy, and the data call requires accurate output of data rather than delay of signal processing.

That is, the data call should have a lower bit error rate (BIR) than the voice call. The reason for this is that although the voice is generally inaccurate, it is possible to communicate by inferring the context relations between the front and the back. This is because a data call that sends and receives various information using the Internet or PC communication places more importance on accuracy than fast data reception.

This continuous interference cancellation (SIC) method removes the interference signal in the received signal using the same continuous interference cancellation method regardless of whether the received call is a voice call or a data call.

Hereinafter, with reference to the accompanying drawings will be described a continuous interference cancellation apparatus and interference signal cancellation method according to the voice call and data call in the conventional direct sequence communication system.

1 is a block diagram illustrating a continuous interference cancellation apparatus for removing an interference signal among signals received through a reverse link in a conventional base station.

As shown in FIG. 1, a continuous interference canceling device for canceling an interference signal in a signal received through a reverse link in a conventional base station includes an antenna, a high frequency end (RF), an intermediate frequency end (IF), and a baseband end (Baseband). The user signal to be demodulated by the demodulation stage 8 of the base station and a plurality of user signals (non-user signals) to be removed are received in all the received signals received from the mobile station through the reverse link.

Here, for the non-user signal including the user signal received by the demodulator 8, the demodulator is not a problem if the signal input at the strength of the strongest signal is a user signal, but an unnecessary non-user signal is stronger than the user signal. If the signal is input at the strength of the signal-to-noise ratio signal, the non-user's signal should be regarded as an interference signal and eliminated.

The conventional demodulation stage 8 for removing such an interference signal includes a matched filter unit 1 for performing matched filtering on a received signal, and a value of the matched filtered received signal +. Decision unit 2 for determining the digital value (+1 or -1) of and-and deinterleaving for removing the interleaved signal from the mobile station from the received received signal. Deinterleaver 3 to perform, a convolution decoder 4 for detecting an error due to noise generated on a channel, and removing a non-user signal when a non-user signal (interference signal) is detected A convolutional encoder 5 for encoding a convolutionally decoded signal, an interleaver portion 6 for interleaving a frequency interleaved with a received signal to a convolutionally encoded interference signal, and modulating the interleaved signal. It is configured modulator (7), and a summing part for removing from the total received signal by summing the non-user signal and said modulated signal. At this time, the convolutional encoder 5, the interleaver 6, and the modulator 7 are the modulation stage 9.

At this time, when the received interference signal is a data call, the deinterleaver unit 3, the convolutional decoder and encoder units 4 and 5, and the interleaver unit 6 as well as the matched filter unit 1 and the decision unit 2 When roughened and then modulated by the modulator 7 and summed by the adder, excellent bit error rate characteristics can be obtained.

FIG. 2 is a flowchart for explaining a method of canceling an interference signal using the apparatus for continuously removing interference as shown in FIG. 1.

In the interference signal canceling method using the interference canceling apparatus according to the related art, when the non-user signal having the strongest signal strength is found among the user signals not removed by the interference canceling apparatus of the base station (S1), Decode the user signal (S2). That is, it generates a signal to be removed before removing it.

Then, deinterleaving the decoded signal (S3).

Subsequently, the deinterleaved non-user signal is convolutionally decoded (S4).

Then, the convolutionally decoded non-user signal is convolutionally encoded (S5).

Subsequently, the convolutionally encoded non-user signal is interleaved (S6).

The size of the interleaved non-user signal (decoded signal) is then estimated using the output size from the matched filter (S7).

The non-user signal having the strongest signal is reproduced using the estimated signal size and chip sequence (S8).

The strongest signal is removed from the entire received signal (S9).

Finally, all of the non-user's signals (however, the process of S1 to S9 is repeated until the decoded value of the user signal is limited or if the number of signals to be removed is limited.

In this case, if the signal-to-noise ratio of the non-user is smaller than the signal-to-noise ratio of the user, it is not necessary to repeat the interference signal removing process as described above.

In such an interference cancellation method using a conventional continuous interference cancellation device, it does not consider the characteristics of the received signal, resulting in performance defects according to the characteristics of the call. That is, when finding and decoding a non-user having the strongest signal strength, the signal after the matched filter can be divided into a voice call and a data call. The voice call is uncomfortable when the removal of the interference signal is delayed. The data call does not take into account the characteristics that the user feels inconvenient when it is incorrect, so if a non-user signal is received regardless of whether the received call is a voice call or a data call, the voice call goes through the convolutional decoder to delay the voice call. There was a problem in that the overall communication quality is lowered.

An object of the present invention has been made in view of the above-mentioned problems of the prior art, it is possible to prevent the processing delay for the user's voice call by quickly removing the interference signal for the voice call among the signals received on the reverse link The present invention provides a method for canceling an interference signal in a communication system.

According to an aspect of the present invention for achieving the above object, a first step of searching whether there is a second user signal having a signal-to-noise ratio greater than the first user signal to be detected among the received signal, than the first user signal A second step of determining whether the second user signal is a voice call when there is a second user signal having a larger signal-to-noise ratio, a third step of decoding the second user signal if the second user signal is a voice call, A fourth step of estimating the magnitude of the decoded second user signal, a fifth step of reproducing the speech signal of the estimated second user signal, and the second user signal of the received signal as the reproduced second user voice signal The sixth step is to remove.

According to the present invention as described above, it is possible to quickly remove the interference signal having a greater signal strength than the voice call to be received from the interference signal received by the interference canceller has the advantage of improving the overall communication quality.

1 is a block diagram illustrating a continuous interference cancellation apparatus for removing interference signals in a signal received through a reverse link in a conventional base station

FIG. 2 is a flowchart for explaining a method of canceling an interference signal using a continuous interference canceller as shown in FIG. 1.

3 is a block diagram illustrating a continuous interference cancellation apparatus for canceling an interference signal in a signal received through a reverse link in a base station according to the present invention.

FIG. 4 is a flowchart for explaining a method of canceling an interference signal using a continuous interference canceller as shown in FIG. 3.

* Description of the symbols for the main parts of the drawings *

11: matched filter unit 12: decision unit

13 deinterleaver 14 Convolutional decoder

15: convolutional encoder 16: interleaver

17 modulation unit 18 switching unit

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

FIG. 3 is a block diagram illustrating a continuous interference cancellation (SIC) device for canceling an interference signal in a signal received through a reverse link in a base station according to the present invention.

As shown in FIG. 3, a continuous interference cancellation (SIC) device for canceling an interference signal among signals received through a reverse link in a base station according to the present invention includes an antenna, a high frequency end (RF), and an intermediate frequency end (IF). And a user signal to be demodulated by the demodulation stage 19 of the base station and a plurality of non-user signals to be removed from the received signals received from the mobile station through the base link through the baseband. .

Here, for the non-user signal including the user signal received by the demodulator 19, the demodulator is not a problem if the signal input with the strongest signal strength is the user signal, but the signal of the unnecessary non-user signal is the strongest (signal band). If the noise ratio is strong, input non-user's signal should be regarded as interference signal and removed.

The demodulation stage 19 according to the present invention for removing such an interference signal has a matched filter section 11 for performing matched filtering on a received signal, and a value of the matched filtered signal is + and-. Decision unit 12 that determines the digital value (+1 or -1), deinterleaver unit 13 for deinterleaving to remove interleaved data from the received received signal, and noise generated on the channel A convolutional decoder 14 for detecting an error by means, a convolutional encoder 15 encoding a convolutional decoded signal to remove the non-user signal when a non-user signal (interference signal) is detected, and a convolutional encoded interference An interleaver 16 for interleaving a frequency initially interleaved with a received signal to a signal, a modulator 17 for modulating the interleaved signal, a non-user signal and the modulated signal among all received signals When an arc is the matched-filtered signal and the summing portion for removing by summing speech receives it consists of a switching unit 18 for transmission to the modulator (17). In this case, the convolutional encoder 15, the interleaver 16, and the modulator 17 are the modulation stages 20.

In the case where the received interference signal is a data call, the matched filter unit 11, the decision unit 12, the deinterleaver unit 13, the convolutional decoder 14, the convolutional encoder 15, and the interleaver 16 After the modulation in the modulator 17, it is possible to obtain excellent reproduction characteristics having the same intensity as that of the signal when it is first received by the matched filter unit 11.

FIG. 4 is a flowchart for explaining a method of canceling an interference signal using the apparatus for continuously removing interference as shown in FIG. 3.

In the interference signal removing method using the interference canceling apparatus according to the present invention, as shown in FIG. 4, if a non-user signal having the strongest interference signal strength is found among users not removed from the interference canceling apparatus of the base station (S11), the non-user Decode the signal (S12). That is, it generates an interference signal to be removed before removing it.

Subsequently, it is determined whether a non-user signal to be removed is a voice call (S13).

Judgment result (S13) In the case of the voice call, the size of the voice call is estimated using the size at the output from the matched filter unit (S18).

Subsequently, the signal of the non-user having the strongest signal is reproduced using the estimated signal magnitude and the chip sequence (S19), and the strongest signal is removed from the entire received signal (S20). The process of S11 to S21 is repeated until the non-user's signal having a greater intensity than the user's signal is decoded or if the number of signals to be removed is limited.

However, if the determination result (S13) is not a voice call, that is, a data call, the decoded signal is deinterleaved (S14).

Subsequently, the deinterleaved non-user signal is convolutionally decoded (S15).

Then, the convolutionally decoded non-user signal is convolutionally encoded (S16).

Subsequently, the convolutionally encoded non-user signal is interleaved (S17).

The size of the interleaved non-user signal (decoded signal) is then estimated using the output from the matched filter unit (S18).

The non-user signal having the strongest signal is reproduced using the estimated signal magnitude and the chip sequence (S19).

The strongest signal is removed from the entire received signal (S20).

Then, the processes of S11 to S21 are repeated until a limited number of signals of all non-users having a greater intensity than that of the user are decoded or if the number of signals to be removed is limited.

In the communication system of the present invention as described above, the continuous interference signal cancellation method according to the voice call and the data call has the following effects.

First, by applying the continuous interference cancellation method according to the characteristics of voice call and data call among received signals, it is possible to quickly remove the interference signal for voice call that requires quick processing, so the overall call quality is excellent, thereby improving user satisfaction. Can be.

Second, when the voice call and the data call are not configured with the same channel element but implemented in different channel elements, there is an effect of reducing the configuration of additional hardware required to reproduce a signal to be removed.

Claims (2)

A first step of searching whether there is a second user signal having a greater signal-to-noise ratio than the first user signal to be detected among the received signals; A second step of determining whether the second user signal is a voice call when there is a second user signal having a greater signal-to-noise ratio than the first user signal; A third step of decoding the second user signal if the second user signal is a voice call; Estimating a magnitude of the decoded second user signal; Reproducing a voice signal of the estimated second user signal; And a sixth step of removing the second user signal from the received signal with the reproduced second user voice signal. 2. The method of claim 1, wherein in said second step, if said second user signal is not a voice call, deinterleaving, convolutional decoding, and convolutional encoding on said second user signal between said second step and said third step. And interleaving further comprising a method for canceling an interference signal in a communication system.