KR100527281B1 - Real Time Error Signal Detection and Cancellation System - Google Patents

Abstract

According to the present invention, when a transmission output signal is fed back to a receiving antenna in various wireless communication systems, the returned receiving signal is introduced through the receiving antenna of the receiver (generally, the signal fed back to the receiving end is also called an error signal). Since the error signal acts as an interference noise in the receiver, the error signal detection and removal device for accurately detecting the error signal and preventing the error signal fed back to the receiver using the detected error signal in order not to flow into the receiver will be. In particular, the real-time adaptability to accurately detect and remove the error signal returned to the receiver in consideration of the delay time necessary to generate the corresponding signal having the same amplitude, reverse phase and the same time delay with respect to the error signal returned to the receiver An error signal detection and eliminator

The present invention not only accurately detects and removes an error signal fed back to a receiving end in a wireless communication system in real time, but also can be applied to various communication systems, and a signal splitter for detecting and removing error signals accurately in real time. And a first cancellation signal detector, a second cancellation signal detector, an error signal detector, and a time delay.

Description

Real time error signal detection and cancellation system

In general, in a wireless communication system, a transmission signal is a signal having a much stronger magnitude than a reception signal, and a transmission signal very strong relative to the reception signal is fed back to the reception antenna and mixed with the reception signal and input to the receiver. This feedback input signal degrades the performance of the receiver and is the primary cause of oscillation, so the feedback signal should be removed so that it is not input to the receiver. However, it is difficult to detect an error signal because the feedback signal (error signal) from which the transmission signal is fed back to the receiving end is a signal that continuously changes with time with amplitude, phase, and delay time.

This phenomenon can be seen in wireless relay devices installed and operated for the purpose of providing a better mobile communication service by installing a weak signal output from a base station and amplifying the weak signal and outputting it to a mobile station. have. The receiver degrades due to an error signal fed back from the wireless relay to the receiving end and oscillates, thus preventing the system from operating smoothly. Therefore, optical repeaters and microwave repeaters are used as a way to prevent such performance degradation and oscillation. However, they have various problems due to high system cost, optical line embedding, and optical line lease cost. That is, the relay device performs the function of receiving and amplifying the weak radio wave and transmitting the amplified signal again. For this purpose, the relay apparatus includes a separate receiving antenna and a separate transmitting antenna. When relaying at the same frequency through the repeater, a strong transmission signal is fed back to the receiving antenna and received along with the receiving signal to be relayed through the receiving antenna. This feedback signal causes a weakening of the repeater function. Therefore, the technique of accurately detecting and removing the feedback signal (error signal) fed back to the receiver by the strong transmission signal from the received signal is a very important technique in the relay apparatus.

The present invention is to accurately detect the feedback signal (error signal) of the wireless communication system in real time and to remove the error signal in order to prevent the oscillation caused by the wireless transmission signal output from the transmitting antenna to the receiving antenna. The present invention relates to a real-time adaptive error signal detection and removal device.

The present invention relates to a real-time adaptive error signal detection and removal device for detecting and removing the error signal flowing through the receiving antenna of the receiver in various wireless communication systems. In particular, the present invention relates to a method and apparatus for detecting and removing an error signal from which a wireless transmission signal output from a transmission antenna is fed back to a reception antenna. The present invention relates to a real-time adaptive error signal detection and removal device capable of real-time adaptation to changes in amplitude, phase, and delay time of an error signal that is changed in real time by a change in an external wireless communication environment condition.

In particular, the present invention is the technical task of the implementation of a device for detecting and removing error signals by real-time adaptation to changes in the external environment as described above, and also to detect and remove error signals in various general communication devices as well as wireless communication. In order to solve the problem, a real-time adaptive error signal detection and removal device can be implemented.

Accordingly, the present invention provides a method and apparatus for real-time adaptive error signal detection and removal having a function of detecting and removing error signals generated in a wireless communication system and a general communication system.

In order to achieve the above object, the present invention provides a real-time adaptive correction of an unwanted error signal before inputting an unwanted feedback signal (error signal) component except for a desired signal from a received signal received through a wireless path in a wireless communication system. The present invention provides a real-time adaptive error signal detection and removal device using the detection and removal technique.

Therefore, the present invention distributes the signal splitter 100 and the signal splitter 100 that can distribute the input signal at a constant ratio by using a desired signal and an unwanted error signal combined in an external receiving antenna system as input signals. A first canceling signal detector 102, a signal distributed by the signal divider 100, which removes an error signal by combining corresponding signals having corresponding amplitudes, inverse phases, and the same time delay with respect to the received signals And an error signal detector 104 for detecting an unwanted error signal by combining the output signal of the first cancellation signal detector 102 and a time delay device for giving a predetermined time delay to the signal distributed by the signal splitter 100. (106), a second cancellation that combines the signal delayed by a constant time in the time delay unit (106) with the corresponding signal to remove the unwanted error signal and output only the desired signal. And a signal detector 108.

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

1 is a basic configuration of a real-time adaptive error signal detection and removal apparatus applied to the present invention.

FIG. 2 is a detailed configuration diagram of the first cancellation signal detector of FIG. 1. FIG.

3 is a detailed configuration diagram of the error signal detector of FIG.

4 is a detailed block diagram of the second canceling signal detector of FIG.

As shown in FIG. 1, the basic components for the real-time adaptive error signal detection and removal apparatus are the signal divider 100, the first cancellation signal detector 102, the error signal detector 104, and the time delay 106. ), And a second cancellation signal detector 108.

The signal splitter 100 performs a function of regularly dividing and distributing a received input signal to detect and remove an unwanted error signal component from a received input signal including a desired signal and an unwanted error signal. The first cancellation signal detector 102 includes a desired signal and an undesired error signal component distributed in the signal divider 100 to remove unwanted error signal components from the desired signal and the unwanted error signal distributed from the signal splitter 100. Combining the corresponding signals, the error signal detector 104 removes the desired and undesired signals from the signal divider 100 to remove only the desired signal components from the desired and undesired error signals distributed by the signal splitter 100. The error signal component and the output signal of the first cancellation signal detector 102 are combined, and the time delay 106 is By using the error signal detected by the difference signal detector 104, the signal is divided into a constant time and a corresponding signal necessary to generate a corresponding signal having the same amplitude, inverse phase, and the same time delay, and is input to the second cancellation signal detector 108. By giving a delay time equal to the delay time determined in consideration of the predetermined time delay to be a time delay to deliver the signal distributed in the signal distributor 100 to the second offset signal detector 108, the second offset signal detector 108 combines the distribution signal and the corresponding signal of the signal divider 100 regularly time-delayed by the time delay unit 106 to remove unwanted error signal components from the received input signal and output only the desired signal components. In this case, the corresponding signal is a reference signal sampled at a constant ratio of the signal output through the transmission antenna. A signal generated to detect and remove an unwanted feedback signal (error signal) component fed back through a receiving antenna. The signal has the same amplitude, reverse phase, and the same delay time as the feedback signal (error signal). The feedback signal (error signal) radiated into the radio space through the transmitting antenna and returned to the receiving antenna and the reference signal sampled by the transmitting antenna are regarded as the same signal component, and have only a difference in amplitude magnitude and delay time. Therefore, when the feedback signal fed back through the radio antenna to the receiving antenna via the radio space reaches the first cancellation signal detector 102, the feedback signal (error signal) in the first cancellation signal detector 102 ) To be combined with the signal corresponding to the feedback signal (error signal) (corresponding signal with dynamic amplitude, reverse phase and the same delay time). As a result, the reference signal sampled by the transmitting antenna is a signal having the same phase compared to the feedback signal (error signal) fed back to the receiving antenna, but has a difference in amplitude and delay time. A corresponding signal having the same delay time is generated.

FIG. 2 is a detailed block diagram of the first cancellation signal detector 102 of FIG. 1 and includes a band pass filter 1, 200, a band pass filter 2, 202, and a signal combiner 1, 204. .

The band pass filter (1) (200) passes only signals of a certain band among the signals distributed at a constant ratio by the signal splitter (100), performs a function of removing signal components out of band, and the band pass filter (2). ) 202 removes out-of-band signals from the corresponding signal components and passes only signals of a certain band. The filter characteristics of the band pass filter (1) 200 and the band pass filter (2) 202 should have the same frequency characteristics, and the frequency characteristics of the signal distributed by the signal splitter 100 and the frequency characteristics of the corresponding signal are excellent. If there is no need to use. The signal combiner (1) 204 combines the distribution signal of the signal divider 100 via the band pass filter (1) (200) and the corresponding signal received through the band pass filter (2) (202). Only the unwanted error signal component is removed from the signal and the unwanted error signal, and only the desired signal component is output and transmitted to the error signal detector 104. Input to the receiving antenna at the signal coupling point of the signal combiner (1) 204. When the input signal (desired signal + error signal) and the corresponding signal are combined, the feedback signal (error signal) and the corresponding signal are signals having inverse phase, dynamic amplitude, and the same delay time, so that there is no feedback signal component. When the feedback signal is normally removed by the corresponding signal, only the desired signal is output, and the output desired signal becomes the input of the error signal detector 104.

FIG. 3 is a detailed configuration diagram of the error signal detector 104 of FIG. 1, and includes a band pass filter 3, 300, a band pass filter 4, 302, a phase inverter 304, and a signal combiner 2 ( 306).

The band pass filter (3) (300) passes only signals of a certain band among the signals distributed at a constant ratio by the signal splitter (100), performs a function of removing signal components out of band, and the band pass filter (4). ) 302 removes out-of-band signals from the output signal components generated by the first cancellation signal detector 102 and passes only signals of a predetermined band. The filter characteristics of the band pass filter (3) 300 and the band pass filter (4) 302 should have the same frequency characteristics, and the frequency characteristics of the signal distributed by the signal splitter 100 and the first cancellation signal detector 102. There is no need to use it when the output signal frequency characteristic of the C) is excellent. The phase inverter 304 performs a function of inverting the phase by 180 degrees after the signal distributed in the signal distributor 100 passes through the band pass filter 3 and 300. The signal combiner (2) 306 transmits the signal distributed from the signal divider 100 through the band pass filter (3) 300 and the phase inverter 304 and the first cancellation signal detector (102). By combining the signal output from the signal output through the band pass filter (4) 302 to remove only the desired signal component from the signal components distributed in the signal splitter 100 and detects only the error signal that is an unwanted signal component Outputs the input signal (desired signal + error signal) input to the receiving antenna at the signal coupling point of the signal combiner (2) (306) and the output signal of the first cancellation signal detector (102). In this case, the desired signal input through the receiving antenna and the signal output from the first cancellation signal detector 102 and input to the error signal detector 104 are canceled because they are mutually out of phase and have the same magnitude. signal Only output

4 is a detailed block diagram of the second cancellation signal detector 108 of FIG. 1 and includes a band pass filter 5, 400, a band pass filter 6, 402, and a signal combiner 3, 404. .

The band pass filter (5) (400) passes only signals of a certain band among the signals time-delayed by the time delay unit (106), the signals distributed by the signal divider (100) at a constant rate, and out-of-band signal components. The band pass filter (6) 402 removes out-of-band signals from the corresponding signal components and passes only signals of a predetermined band. The filter characteristics of the band pass filter (5) 400 and the band pass filter (6) 402 should have the same frequency characteristics, and the frequency characteristics of the signal distributed by the signal splitter 100 and the frequency characteristics of the corresponding signal are excellent. If there is no need to use. The signal combiner (3) (404) is a band pass that performs the function of passing only the signal of a certain band among the signals delayed by the time delay unit (106) by the signal divider 100 at a constant rate Combining the signal input via the filter (5) 400 and the corresponding signal via the bandpass filter (6) 402 removes only the unwanted error signal components from the received and unwanted error signals received. Only the desired signal component is output. When combining the input signal (desired signal + error signal) inputted to the receiving antenna and the corresponding signal at the signal coupling point of the signal combiner (3) 404, the feedback signal (error signal) and Since the corresponding signals are signals having inverse phase, dynamic amplitude, and the same delay time, when combined, the feedback signal component disappears, and the feedback signal is normally removed by the corresponding signal. In this case, only the desired signal is output, and only the output desired signal component is output.

The wireless communication system configured as described above can accurately detect an error signal fed back to the receiver in real time, and generate a corresponding signal corresponding to the error signal using the detected error signal, and generate a constant signal to generate the corresponding signal. Compensation for the delayed error signal in consideration of the delay time, combined with the corresponding signal, eliminates the error signal component that is returned and only the desired signal component can be input to the receiver, thus preventing oscillation caused by the feedback error signal. It can also improve the power amplifier output and increase system efficiency.

That is, the wireless communication system according to the present invention is proposed as a method for solving various problems that may be generated in the wireless communication system by the error signal fed back to the receiving end as a real-time adaptive error signal detection and removal device that can be designed and commercialized. It is possible to remove the influence of the feedback signal commonly generated in the wireless communication system, that is, the transmission signal transmitted through the transmission antenna is fed back to the reception antenna and inputted. In particular, the present invention is not only applicable to a base station system, but also to a wireless communication system for a mobile communication and a general communication system.

The present invention relates to a real-time adaptive error signal detection and removal apparatus for detecting and eliminating error signals transmitted from a transmission output signal to a reception antenna of a receiver in various wireless communication systems, which is generated by feedback to a reception antenna of a transmission signal. The error signal can be detected, and the error signal to be fed back can be removed using the detected error signal. Therefore, oscillation of the receiver caused by the error signal can be prevented.

In addition, since it is possible to prevent the feedback signal (error signal) commonly generated in the wireless repeater system, the output of the wireless repeater system can be increased by improving the separation of input / output signals of the wireless repeater system. The service area and coverage of the system can be widened, and the service quality can be improved, the stability of the system and the performance of the system can be increased, and the subscriber capacity can be increased.

As described above, the present invention which detects and removes an error signal fed back to a receiver in real time is generally applied to a cellular, PCS system, an IMT-2000 system, and a wireless communication system employing CDMA technology, which is currently commercialized by a simple change of technical content. This invention is a versatile invention that can be used to detect and eliminate error signals, which are unwanted signal components occurring in other general communication systems.

1 is a basic configuration of a real-time error signal detection and removal apparatus applied to the present invention.

FIG. 2 is a detailed configuration diagram of the first cancellation signal detector of FIG. 1. FIG.

3 is a detailed configuration diagram of the error signal detector of FIG.

4 is a detailed block diagram of the second canceling signal detector of FIG.

5 is a detailed configuration diagram of the application embodiment of FIG.

<Description of Symbols for Main Parts of Drawings>

100: signal divider 102: first cancellation signal detector

104: error signal detector 106: time delay

108: second cancellation signal detector 200: band pass filter (1)

202: band pass filter (2) 204: signal combiner (1)

300: band pass filter (3) 302: band pass filter (4)

304: phase shifter 400: bandpass filter (5)

402: bandpass filter (6) 404: signal combiner (3)

Claims (8)

In the real-time adaptive error signal detection and removal device, Signal distribution means for distributing a signal received through an external reception antenna system according to a predetermined ratio; In order to remove an error signal which is an unwanted signal component input to the receiving terminal by receiving a distribution signal uniformly distributed by the signal distribution means, the error signal is removed by combining with a corresponding signal corresponding to the error signal and detecting only a desired signal component. First cancellation signal detection means; An unwanted error signal in combination with a desired signal component detected by the first canceling signal detection means to receive the distribution signal uniformly distributed by the signal distribution means and detect an error signal which is an unwanted signal component input to the receiving end Error signal detecting means for detecting only a component; Time delay means for compensating a constant time delay for a distribution signal distributed by said signal distribution means equal to a constant delay time required for generating a corresponding signal using the error signal detected by said error signal detection means; And Second offset signal detecting means for removing unwanted signal components and detecting only a desired signal by combining a signal delayed by the time delay means with a corresponding signal generated using the error signal detected by the error signal detecting means Apparatus for detecting and removing real-time adaptive error signal comprising a. 2. The apparatus of claim 1, wherein the signal distribution means, the first cancellation signal detection means, the error signal detection means, the time delay means, and the second cancellation signal detection means are unwanted errors except for a desired signal among the received signals received through the communication path. Real-time adaptability characterized by detecting unwanted error signals received before signal components are input to the receiver, generating corresponding signals using the detected error signals, and eliminating unwanted error signals by matching appropriate delay times Error signal detection and removal device. 2. The apparatus of claim 1, wherein the first cancellation signal detecting means corresponds to a band pass filter (1) (200) for passing only signals of a predetermined band and removing out-of-band signals among the signals distributed by the signal splitter (100). Bandpass filter (2) 202 that passes only signals of a certain band and removes out-of-band signals among the signals, and band-filtered signals are combined to remove only unwanted error signals from signals distributed in the signal distributor 100. Apparatus for detecting and removing real-time adaptive error signal, characterized in that it comprises a signal combiner (1) (204) for outputting only the desired signal. The band pass filter (3) (300) of claim 1, wherein the error signal detecting means includes a band pass filter (3) (300) for passing only signals of a predetermined band and removing out-of-band signals among the signals distributed by the signal splitter (100). (3) A phase inverter 304 for converting the phase of the filter signal passed through 300 degrees by 180 degrees and a signal having a predetermined band out of the desired signal components output from the first cancellation signal detector 102, and out of band signals. The bandpass filter (4) 302 for removing the bandpass filter and the passband filter the signal distributed in the signal splitter 100 and the phase-inverted signal and the output signal of the first cancellation signal detector 102 Real-time adaptive, characterized in that it comprises a signal combiner (2) (306) to remove only the desired signal from the signal divided by the signal splitter 100, and detects and outputs only the unwanted error signal Difference signal detection and removal unit. The signal detected by the error signal detector 104 according to claim 1, wherein the time delay means is located between the signal divider 100 and the second canceling signal detector 108 to distribute the signal distributed by the signal divider 100. Delay time is equal to the sum of the delay time required to generate the corresponding signal using the signal and the delay time required for the generated corresponding signal to reach the signal coupling point of the second cancellation signal detector 108. Apparatus for detecting and removing a real-time adaptive error signal, characterized in that to reach the signal coupling point of the second offset signal detector (108) after. The band of claim 1, wherein the second cancellation signal detection means is distributed by the signal divider 100 to pass only signals of a predetermined band among signals delayed by the time delay 106 and to remove out-of-band signals. In the signal splitter 100, a pass filter 5, 400, a band pass filter 6, 402 for passing only signals of a predetermined band from the corresponding signals and removing out-of-band signals, and a band-filtered signal are combined. And a signal combiner (3) (404) for removing only unwanted error signals from the distributed signals and outputting only desired signals. delete delete