KR20040097683A - Interference cancellation system by using DSP and repeating apparatus thereof - Google Patents

Abstract

PURPOSE: An interference cancellation system by digital signal processing and a relay system using the same are provided to improve the quality of communication and transmit signals of good quality by removing an interference signal through a DSP(Digital Signal Processor) after converting an RF(Radio Frequency) signal, received from a base station, into a digital signal. CONSTITUTION: A relay system using an interference cancellation system by digital signal processing comprises four processing units. The first processing unit converts an RF signal, received from a base station, into an IF(Intermediate Frequency) analog signal. The second processing unit converts the analog signal into a digital signal, downconverts the digital signal into a baseband digital signal, passes it through the interference cancellation system, and removes an interference signal by DSP processing. The third processing unit upconverts the DSP-processed baseband digital signal and converts it into an analog signal again. The fourth processing unit converts the analog-converted IF into an RF signal.

Description

Interference cancellation system by digital signal processing and relay device using same

The present invention relates to an interference cancellation system and a relay device, and by converting an RF signal received from a base station into a digital signal and then removing the interference signal by a DSP to improve the communication quality by a digital signal processing that can transmit a good signal An interference cancellation system and a relay apparatus using the same.

In general, the RF repeater is installed and operated in a shaded area in the service area of the base station as shown in FIG. 1A. As shown in FIG. 1B, an oscillation phenomenon is caused by mixing an interference signal by the path environment path, which causes the system performance to be degraded. In order to prevent such oscillation, conventionally, a method of separating a horizontal distance between an antenna and an antenna, a method of installing using the structure of a building to the maximum, a method of improving separation by vertically separating an antenna, and a repeater of a frequency conversion method are used. Various methods such as a method of connecting a base station and a repeater with an optical cable have been used.

However, the above methods are not easy to secure the space enough to separate the antenna, each requires a large-scale construction such as steel pipe to have a sufficient vertical separation degree, inefficient use of frequency resources, cost of optical line rental, etc. The disadvantage is that fixed costs are excessively spent.

1C is a block diagram of an interference cancellation system according to the prior art, in which the RF signal received by the reception antenna 101 is amplified by the amplifier 103 and transmitted through the transmission antenna 102. The output signal of the amplifier 103 is diverted by the distribution device 104 to detect the amplitude and phase of the RF signal, and then is output by the phase shifter 105, the attenuator 106 and the delay line 107. By generating a signal of the same amplitude, anti-phase, and fed back to the synthesizer 108 to synthesize the signal was used to eliminate the interference signal.

However, the above-described method is difficult to obtain accurate dynamic amplitude and anti-phase signal due to the complicated system configuration, and the interference efficiency of the interference signal is not only decreased, and because the band characteristic is narrow band, the signal having a wide bandwidth cannot be processed. There is this.

The present invention is to solve the above problems, by converting the RF signal received from the base station to digital and by eliminating the interference signal by the DSP to improve the communication quality by digital signal processing that can transmit a good signal It is an object of the present invention to provide an interference cancellation system and a relay apparatus using the same.

1A is a view showing installation of a general relay device.

1B is a view showing the path environment of the relay device.

1C is a block diagram of an interference cancellation system according to the prior art.

2 is a block diagram illustrating the use of an interference cancellation system by digital signal processing in accordance with the present invention.

3 is a block diagram illustrating the interference cancellation algorithm of FIG.

Figure 4a is a view showing a narrowband recognition signal of the interference cancellation system by digital signal processing according to the present invention.

Figure 4b is a view showing a wideband recognition signal of the interference cancellation system by digital signal processing according to the present invention.

Figure 5 is a block diagram of a digital signal processing unit of the interference cancellation system by digital signal processing according to the present invention.

Figure 6a is a diagram showing a four-channel WCDMA signal input to the interference cancellation system by digital signal processing according to the present invention.

Figure 6b is a view showing a four-channel WCDMA signal output from the interference cancellation system by digital signal processing according to the present invention.

7 is a block diagram of a relay apparatus using an interference cancellation system by digital signal processing according to the present invention.

* Explanation of symbols for the main parts of the drawings

101. Receive antenna 102. Transmit antenna

103. Amplifiers 104. Distribution Devices

105. Phaser 106. Attenuator

107. Delayed lines 108. Synthesis equipment

201. First Antenna 202. First Bandpass Filter

203. Low Noise Amplifier 204. First Mixer

205. SAW filter 206. First amplifier

207. First Attenuator 208. Oscillator

209. Second amplifier 210. Low pass filter

211.Second Attenuator 212.Second Mixer

213. Power amplifier 214. Second bandpass filter

215. Second antenna 300, 600. Interference cancellation system

301. A / D converter 302. Digital signal processing unit

303. D / A Converter 401. Channel Filter

402.Interfere Searcher 403.Digital Up Converter

404. Complementary Signal Generator

406. Recognition signal generator 501. NCO

502. FIR channel filter 503. Automatic gain control circuit

504. Complex Modulator 505. Digital Mixer

601. First duplexer 602. First low noise amplifier

603. First power amplifier 604. Second duplexer

605. Second low noise amplifier 606. Second power amplifier

In order to achieve the above object, the present invention provides a relay apparatus for processing a signal received from a base station and retransmitting it to a shadow area, comprising: first processing means for converting a received RF signal into an intermediate frequency; Second processing means for converting the intermediate frequency, which is an analog signal, into a digital signal, down converting the digital signal into a baseband digital signal, and passing the interference cancellation system to remove the interference signal by DSP processing; Third processing means for up-converting the DSP-processed baseband digital signal and converting it back to an analog signal; And fourth processing means for converting the intermediate frequency converted into analog into an RF signal.

The first processing means includes: an apparatus for low noise amplifying an RF signal received from a base station; and an apparatus for bandpass filtering to remove signals other than a required band; and an apparatus for downconverting the RF signal to an intermediate frequency by a mixer. SAW filtering to remove noise components included in the intermediate frequency; and amplifying or attenuating the intermediate frequency signal to obtain a required gain.

The second processing means includes: an apparatus for converting the intermediate frequency signal into a digital signal by an A / D converter; and an apparatus for downconverting the digital signal into a baseband digital signal; and extracting an interference signal from the baseband digital signal. And DSP processing by generating a complementary signal.

The third processing means includes an apparatus for up-converting the DSP-processed baseband digital signal into a digital signal, and an apparatus for converting the digital signal into an intermediate frequency which is an analog signal by a D / A converter.

The fourth processing means includes: an apparatus for amplifying or attenuating the intermediate frequency signal to obtain a required gain; and an apparatus for low pass filtering to remove unwanted signals included in the intermediate frequency signal; and the intermediate apparatus by a mixer. An apparatus for upconverting a frequency signal to an RF frequency; and an apparatus for amplifying the RF signal to obtain a required gain; and an apparatus for bandpass filtering to remove a signal other than the required band.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram illustrating the use of an interference cancellation system by digital signal processing according to the present invention. As shown, the RF signal input through the first antenna 201 is filtered by only the required frequency band by the first bandpass filter 202 and amplified in a state where noise is suppressed as much as possible by the low noise amplifier 203. The local oscillation signal is received from the oscillator 208 and down-converted to an intermediate frequency through the first mixer 204. In addition, the intermediate frequency signal is filtered by the SAW filter 205 and the strength of the signal is properly adjusted by the first amplifier 206 and the first attenuator 207.

The intermediate frequency signal is converted into a digital signal by the A / D converter 301, and the A / D converted signal is again converted by the D / A converter 303 after the interference signal is removed from the digital processing unit 302. It is converted into an analog signal.

The signal converted to analog through the digital signal processing is amplified by the second amplifier 209 and passed through the low band filter 210, and then the level is adjusted by the second attenuator 211. The mixer 212 is upconverted to an RF signal. The upconverted RF signal is amplified by the power amplifier 213, band-pass filtered by the second bandpass filter 214, and then transmitted through the second antenna 215.

3 is a block diagram illustrating the interference cancellation algorithm of FIG. 2. The first embodiment of the interference cancellation algorithm by digital signal processing according to the present invention is a feedback signal analysis method using the original signal itself without a separate recognition signal, and its operation is as follows.

In the output of the channel filter 401, a signal currently delayed and a time delay signal (typically μsec) are input through various paths, as shown in Equation 1 below. In the Interfere Searcher unit 402, G _{1 is} provided for each path. Signals such as, G ₂ , G ₃ , t _d1 , t _d2 , t _d3 , θ ₁ , θ ₂ , and θ ₃ are estimated. At this time, the estimation principle is to determine the period (distance of the direct feedback signal and the reflection feedback signal) where the time delay is expected by using a time delay element (FIFO, Dual-Port Memory) for the signal transmitted through the Digital Up Converter 403 part. While sweeping, find the time delay with the largest amount of cross-correlation with the currently received r (t). Through this, the feedback signal amount and the phase signal can be found simultaneously.

Found above Is approximated to the signal fed back for each path among the signals currently received through the Complementary Signal Generator 404. In this case, the output signal of the Complementary Signal Generator 404 is expressed by Equation 2 below.

here to be.

Through Equations 1 and 2, the same result as in Equation 3 can be obtained.

Accordingly, since only i (t) + jq (t) currently received is output to the output of the summer 405 by Equation 3, the feedback signal can be effectively removed.

4A and 4B are diagrams illustrating a narrowband recognition signal and a wideband recognition signal of an interference cancellation system by digital signal processing according to the present invention. Such a recognition signal is an interference signal cancellation method using recognition signals representing the second and third embodiments of the interference cancellation algorithm by digital signal processing according to the present invention. Same as

In the above-described first embodiment, the feedback signal is analyzed using the original signal itself to measure the phase, delay, and signal amount of the feedback signal through the cross-correlation function. However, in the first embodiment, since the amount of power of the original signal itself continuously changes with time, an error may occur in estimating the phase change, the time delay, and the amount of power of the feedback signal by the interfere searcher 402.

In order to minimize this, in the second and third embodiments of the present invention, as shown in FIG. 3, the recognition signal generator 406 generates a recognition signal that can be easily demodulated by the user, thereby changing the phase change and time of the feedback signal. It is possible to reduce the delay and the estimation error of the amount of power. The output recognition signal m (t) is input through a receiving antenna like the feedback signal, and a signal as shown in Equation 4 below is input to an input terminal of the digital up converter 403.

In addition, a signal as shown in Equation 5 below is input to the output of the channel filter 401, and the Interfere Searcher unit 402 receives G ₁ , G ₂ , G ₃ , t _d1 , t _d2 , t _d3 , By estimating signals θ ₁ , θ ₂ , θ ₃ , and the like, the interference signal may be removed from the current signal to be relayed as in the first embodiment.

In the second embodiment of the present invention, as shown in FIG. 4A, a narrowband recognition signal having a bandwidth of 30 kHz is used. When the narrow band signal of 30 kHz is generated in the guard band between channels, it acts as an unnecessary wave for each channel, but since the recognition signal exists in the band of the service provider, it does not affect the band of other companies. Since the signal is generated in the band, it is eliminated by the channel filter at the terminal or the base station so that the call quality and the channel capacity are not affected.

In addition, in the third embodiment of the present invention, as shown in FIG. 4B, a wideband recognition signal having the same bandwidth as that of the service provider's band (for example, 20 MHz in the case of WCDMA) is used. In this case, the recognition signal is spread out over the entire band within 20MHz, but the signal is made small so that the WCDMA signal of 20MHz does not act as a noise.

In addition, the channel filter 401 of the interference cancellation system according to the present invention has a channel bandwidth (1.23 MHz in the case of CDMA) regardless of the forward link signal and the reverse link signal received through a receiving antenna independently of the interference signal cancellation method. In addition, channel filtering improves out-band signal suppression and improves signal purity and efficiency of high-power amplifiers.

5 is a configuration diagram of a digital signal processing unit of an interference cancellation system by digital signal processing according to the present invention, and a cosine signal generated through an NCO (Numerically Controlled Oscillator) 501 and a signal input through an ADC; A sin signal is used to demodulate and convert the signal into a baseband digital signal (I / Q signal). The signal converted into the baseband digital signal is channel filtered for each channel by the FIR channel filter 502 with the bandwidth of each communication method such as CDMA2000, WCDMA, etc., and the channel filtered signal is automatically gained as required. After passing through the circuit 503 is reproduced as a multi-carrier baseband signal through the complex modulator 504, it is converted into a digital signal through the digital mixer 505 and output to the DAC. In this case, the process of converting the baseband digital signal into a digital signal is a counter action of the process of converting the above-described digital signal into a baseband digital signal.

6A and 6B are diagrams illustrating four channel WCDMA signals input to an interference cancellation system by digital signal processing according to the present invention, and a four channel WCDMA signal output from an interference cancellation system by digital signal processing according to the present invention. It is a figure which shows. 6A and 6B are examples of actual measurements of input / output characteristics. For convenience of experiment, the input signal inputs the WCDMA 4FA signal generated by the CDMA signal generator ESG4406 to the interference canceling device according to the present invention. It shows the waveform output through the filter. 6A and 6B, it can be seen that the interference signal mixed in the input signal waveform is removed from the output signal waveform. Therefore, it is obvious that the improvement effect is much greater in the actual environment than in the laboratory environment using the signal generator as described above.

7 is a block diagram of a repeater using an interference cancellation system by digital signal processing according to the present invention. The repeater according to the present invention includes a first duplexer 601 and a first low noise amplifier 602 and a first low noise amplifier 602 of a forward link. Since only the first power amplifier 603 and the second duplexer 604, the second low noise amplifier 605, and the second power amplifier 606 of the reverse link are applied, the interference cancellation system 600 by digital signal processing may be applied. System configuration is very simple. The following operations are the same as described above with reference to FIGS. 2, 3, and 5.

Therefore, the relay device according to the present invention can be easily operated by the operator considering the radio wave environment of the shadow area, and can be widely applied to various relay systems only by changing the software by digital signal processing, and using digital signal processing technology. As the interference is removed from the baseband, it is possible to widen the bandwidth and overcomes the limitation of the narrowband of the conventional analog interference cancellation system.

The interference canceling apparatus according to the present invention can be further improved by adding a narrowband or broadband recognition signal generator that does not affect the purity of a signal to be relayed, as well as an interference cancellation technique by digital signal processing technology. It is a technology that analyzes the signal by channel by processing the entire bandwidth by digital signal, so it can be widely applied to various mobile communication systems (IS95, GSM, CDMA2000, WCDMA, etc.) through software upgrade.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

As described above, the present invention provides a network for operators considering the propagation environment of the shadow area by adding a narrowband or wideband recognition signal generator that does not affect the purity of a signal to be relayed, as well as an interference cancellation technique by a digital signal processing technique. It is easy to operate and can be widely applied to various relay systems by only changing the software by digital signal processing, and wideband is possible because the interference is removed from the baseband using digital signal processing technology.

Claims (10)

A relay apparatus for processing a signal received from a base station and retransmitting it to a shadow area, comprising: first processing means for converting a received RF signal into an intermediate frequency; Second processing means for converting the intermediate frequency, which is an analog signal, into a digital signal, down converting the digital signal into a baseband digital signal, and passing the interference cancellation system to remove the interference signal by DSP processing; Third processing means for up-converting the DSP-processed baseband digital signal and converting it back to an analog signal; And And a fourth processing means for converting the intermediate frequency converted into analog into an RF signal, and an interference cancellation system using the digital signal processing. The method of claim 1, wherein the first processing means, An apparatus for low noise amplifying the RF signal received from the base station; and An apparatus for bandpass filtering to remove signals other than required bands; and An apparatus for down converting the RF signal into an intermediate frequency by a mixer; and SAW filtering to remove the noise component included in the intermediate frequency; and a device for amplifying or attenuating the intermediate frequency signal to obtain the required gain; and the interference cancellation system by digital signal processing, and Repeater using this. The method of claim 1, wherein the second processing means, An apparatus for digitally converting the intermediate frequency signal by an A / D converter; and An apparatus for down converting the digital signal into a baseband digital signal; and And an apparatus for extracting an interference signal from the baseband digital signal and generating a complementary signal for DSP processing. The DSP processor of claim 1, wherein the DSP processing apparatus comprises: A device for demodulating a signal input through an A / D converter into a baseband digital signal (I / Q signal) by using a cosine signal and a sine signal generated through an NCO; and An apparatus for channel filtering the baseband digital signal for each channel by a FIR channel filter with a bandwidth of each communication scheme; and An apparatus for adjusting gain by the automatic gain control (AGC) circuit of the channel filtered signal; and A device for reproducing a multi-carrier baseband digital signal by a complex modulator; and A device for converting the multi-carrier baseband digital signal into a digital signal through a digital mixer and an NCO; and And an apparatus for converting the digital signal into an analog signal by means of a D / A converter. The method of claim 1, wherein the third processing means, A device for up-converting the DSP-processed baseband digital signal to a digital signal; and a device for converting the digital signal to an intermediate frequency, which is an analog signal, by a D / A converter. Interference cancellation system and repeater using the same. The method of claim 1, wherein the fourth processing means, An apparatus for amplifying or attenuating the intermediate frequency signal to obtain a required gain; and A low pass filtering device to remove unwanted signals included in the intermediate frequency signal; and An apparatus for up-converting the intermediate frequency signal to an RF frequency by a mixer; and An apparatus for amplifying the RF signal to obtain a required gain; and And an apparatus for bandpass filtering to remove signals other than required bands. After converting the RF signal received from the base station to the intermediate frequency, and converting the intermediate frequency into a digital signal, down-converting the digital signal into a baseband digital signal and removing the interference signal by the interference cancellation system, An interference cancellation system by digital signal processing for converting the baseband digital signal into a digital signal, converting the digital signal into an analog intermediate frequency, converting the intermediate frequency into an RF signal, and then retransmitting it to a shaded area and using the same Repeater. The method of claim 7, wherein the interference cancellation system, In order to remove the interference signal by the feedback signal analysis method using the original signal itself without a separate recognition signal, By branching the multipath signal passing through the channel filter, the interfere searcher unit measures the phase, delay and signal amount of the interference signal for each path through the cross-correlation function, And an interference canceling system using a digital signal processing and generating the reverse signal of the measured interference signal by a complementary signal generator. The method of claim 7 or 8, wherein the interference cancellation system, the recognition signal generator, In order to remove the interference signal by using the narrowband recognition signal generated by the recognition signal generator, Generating a recognition signal having a predetermined bandwidth in the guard band between the channels, detecting the recognition signal included in the feedback signal, Branching the multipath signal passing through the channel filter, and measuring the phase, delay and signal amount of the recognition signal through the cross-correlation function in the Interfere Searcher; Interference cancellation system by digital signal processing, characterized in that to remove the interference signal by the adder by generating a reverse signal of the interference signal by the Complementary Signal Generator using the measured phase, delay, the amount of the signal and the same Repeater used. The method of claim 7 or 8, wherein the interference cancellation system, the recognition signal generator, In order to remove the interference signal by using the broadband recognition signal generated by the recognition signal generator, Generating a wideband recognition signal having a bandwidth equal to a channel bandwidth of a service provider in all bands to detect the recognition signal included in the feedback signal, Branching the multipath signal passing through the channel filter, and measuring the phase, delay and signal amount of the recognition signal through the cross-correlation function in the Interfere Searcher; Interference cancellation system by digital signal processing, characterized in that to generate the inverse signal of the interference signal by the Complementary Signal Generator using the measured phase, delay, signal amount of the measured signal to remove the interference signal by the adder and this Repeater used.