KR100343164B1 - Method and apparatus for controlling intermodulation signal in communication system - Google Patents

Abstract

The present invention relates to a method and apparatus for controlling an intermodulation signal in a communication system. In the communication system according to the present invention, a method of controlling an intermodulation signal for removing an intermodulation signal included in a received signal includes the steps of: outputting the received signal as a discrete-converted sample; Calculating a sample Xp having a maximum size in the output sample; Calculating an average value Xave for the remaining samples except for a predetermined number of samples located in the periphery of the sample Xp; Determining whether an intermodulation signal is generated by comparing the value Xave + alpha plus the predetermined value alpha with the average value Xave and the value of the sample Xp; Calculating a digital filter coefficient for filtering the intermodulated signal when the intermodulated signal is detected; And filtering the intermodulated signal using the calculated digital filter coefficients.

According to the present invention, by accurately determining the mutual interference signal generated by the receiver of the mobile communication terminal of the wireless transmission and reception system and filtering and removing the mutual interference signal, to improve the call quality and prevent unnecessary current consumption, battery life and talk time To extend.

Description

Method and apparatus for controlling intermodulation signal in communication system

The present invention relates to a method and apparatus for controlling an intermodulation signal, and more particularly, to a method and apparatus for detecting an intermodulation signal in a mobile communication system.

In general, when receiving a signal transmitted from the transmission equipment of the communication system, due to the non-linearity of the device in the receiving equipment, the intermodulation signal may occur in the signal band to receive. In this case, the intermodulation signal acts as an interference signal, and the intermodulation signal should be suppressed as much as possible in order to accurately recover information transmitted from the received signal. To this end, if it is determined that the intermodulation signal is generated, there is a method of reducing the intermodulation signal or reducing the level of the reception signal by improving the linearity of the device by flowing a large current through a device such as an amplifier or a mixer of the receiver.

Conventional communication systems use a method of determining that an intermodulation signal has occurred when a level of a received signal rises based on a specific level. However, in a wireless communication environment, the level of a received signal is severe due to fading. The detection method used was very likely to misinterpret the generation of intermodulation signals. Especially, in the case of a mobile communication system, such intermodulation signals were generated very irregularly, making it very difficult to determine the intermodulation signals.

Therefore, if the intermodulation signal is not generated and the receiver is controlled by determining that the intermodulation signal is generated, the demodulation performance of the receiver is degraded, and an unnecessary current is excessively flowed to improve the linearity of the receiver device. It could shorten the life. In addition, in the case of controlling the intermodulation signal in a manner of attenuating the reception signal level, there is a problem in that an unnecessary attenuation of the reception signal is caused to decrease the call connection rate and disconnection during a call.

The present invention has been made to solve the above-mentioned problems, and a method of accurately determining whether an intermodulated signal acting as an interference to a signal to be received by a receiver of a communication system and a method of removing the generated intermodulated signal An object of the present invention is to provide a modulated signal control method and apparatus.

1 is a block diagram of a receiver for explaining an intermodulation signal control apparatus according to the present invention.

FIG. 2 is a flowchart for describing an operation of the apparatus shown in FIG. 1.

3 is a graph for explaining information calculation of intermodulated signals in a discrete free-transformed sample according to the present invention.

According to the present invention for achieving the above object, an intermodulation signal control apparatus for removing the intermodulation signal included in the baseband transformed received signal in a communication system, by sampling the baseband-converted analog signal A / D conversion means for converting to a digital baseband signal; A discrete free transform unit for inputting the digital baseband signal and outputting a sample converted into a discrete free signal; A digital filter unit for filtering and removing the intermodulated signal from the digital baseband signal using the digital filter coefficient introduced according to a control signal, or transmitting the filtered signal to the modulator without filtering; The discrete free-transformed sample is introduced to calculate an average value Xave of the remaining samples excluding the sample Xp having the maximum value and a predetermined number of samples located around the sample Xp, and the average value Xave. The digital filter is controlled by comparing the value (Xave + alpha) plus a predetermined value (alpha) with the value of the sample (Xp) to determine whether an intermodulation signal is generated, and controlling the digital filter (Xp) and its surroundings. And a controller configured to generate the digital filter coefficients using a maximum value P of the intermodulated signal calculated by interpolating a predetermined number of samples located at and a frequency and bandwidth at the maximum value P.

In addition, the predetermined value alpha is a value set as an experimental value to compensate for the average value Xave lowered by extremely low sample values in the reception channel band so as to become a reference level of the intermodulation signal.

In addition, in the communication system according to the present invention for achieving another object, a method of detecting a cross-modulated signal in a baseband-converted received signal to determine whether an intermodulated signal is generated, outputting the received signal as a discrete-converted sample. ; Calculating a sample Xp having a maximum size in the output sample; Calculating an average value Xave for the remaining samples except for a predetermined number of samples located in the periphery of the sample Xp; And determining that the intermodulation signal is generated when the value of the sample Xp is larger than the value Xave + alpha added to the average value Xave by the predetermined value alpha.

In accordance with another aspect of the present invention, there is provided a method for controlling an intermodulation signal included in a baseband transformed reception signal, the method including: outputting a received signal as a discrete-converted sample; Calculating a sample Xp having a maximum size in the output sample; Calculating an average value Xave for the remaining samples except for a predetermined number of samples located in the periphery of the sample Xp; Determining whether an intermodulation signal is generated by comparing the value Xave + alpha plus the predetermined value alpha with the average value Xave and the value of the sample Xp; Calculating a digital filter coefficient for filtering the intermodulated signal when the intermodulated signal is detected; And filtering the intermodulated signal using the calculated digital filter coefficients.

The calculating of the coefficients of the digital filter may include interpolating the sample Xp having the maximum value and its surrounding samples to obtain a more accurate maximum value P of the frequency component of the intermodulation signal, and obtaining the maximum value P. Calculating a frequency at; Calculating an intermodulation signal bandwidth by taking samples adjacent to the sample (Xp) having a value larger than the value (Xave + alpha) by adding a predetermined value (alpha) to the average value (Xave); And calculating the digital filter coefficient using the frequency Fp of the maximum value P of the frequency components of the intermodulated signal and the intermodulated signal bandwidth B _IMD .

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

1 is a block diagram of a mobile communication terminal for explaining an intermodulation signal control apparatus according to the present invention.

In FIG. 1, the signal received from the antenna 101 is amplified in the low noise amplifier 103 having a good signal-to-noise ratio via the duplexer 102. The low noise amplifier 103 filters and amplifies only a reception band signal of a desired channel. The signal amplified by the low noise amplifier 103 is output to the mixer 104. The mixer 104 mixes the output of the low noise amplifier 103 and the signal oscillated by the first local oscillator 123 to down-convert the signal received from the antenna 101 to an intermediate frequency and then an intermediate frequency (IF) filter ( 105), a reception band signal of a desired channel is obtained.

In addition, the audio signal modulated by the modulation / demodulation unit 121 is output to the antenna 101 through the transmitting RF unit 122 and the duplexer 102.

The intermediate frequency filter 105 removes the image signal from the introduced intermediate frequency signal. At this stage, if the signals of the unwanted channel are quite large, the non-linear characteristics of the devices such as the low noise amplifier 103 and the mixer 104 may cause an inter-signal to occur in the desired channel. If it passes 105, it is not filtered.

The intermediate frequency signal is transmitted to the I (inphase) component through the baseband converter 100 including the second local oscillator 108, the 90-degree phase shifter 109, and the second and third mixers 106 and 107. It is converted into a baseband signal of a Q (quadrature) component, and then input to the first and second A / D converters 110 and 111, respectively, and is sampled as a digital signal.

The digitally converted miracle band signals I and Q are simultaneously input to a discrete fourier transform (DFT) 112 and a digital filter 118. The discrete Fourier transform unit 112 performs Fourier transform on the digitally converted baseband signal and outputs it to the control unit 116. The control unit 116 injects discrete Fourier transformed data to calculate whether the intermodulated signal is generated, the generated center frequency, the signal strength, and the occupied bandwidth as shown in the flowchart of FIG. B _IMD ) and the digital filter coefficient 119 calculated using the center frequency is transmitted to the digital filter 118, and if the control unit 116 determines that the intermodulation signal is generated, the control line 117 of the digital filter 118 Output control signal to) to operate in operation mode. At this time, the digital filter 118 removes the intermodulation signal included in the corresponding reception channel according to the digital filter coefficients and outputs it to the demodulation demodulator 121 so that the received signal is correctly demodulated.

In addition, if it is determined that the intermodulation signal is not generated, the controller 116 controls the digital filter 118 to output the introduced baseband signal to the modulator 121 without filtering.

FIG. 2 is a flowchart for describing an operation of the apparatus shown in FIG. 1.

First, it is checked whether an intermodulation distortion (IMD) test period is performed in a reception standby mode or a transmission / reception mode (step 202). In step 202, the algorithm is terminated when the intermodulation signal checking period is not performed, and if the intermodulation signal checking period is performed, the discrete Fourier transform unit 112 receives the baseband signal reception samples of the I component 113 and the Q component 114 of FIG. Inflow, the discrete Fourier transform is output to the control unit 116 (step 203). The control unit 116 searches for the sample Xp having the maximum size among the N Fourier transformed samples (step 204), and then selects a predetermined number of samples Xp and the sample Xp having the maximum size. The average value Xave of the remaining samples except for the samples is calculated (step 205). For example, in the Fourier transformed N samples (X [n], n = 0, 1, .., P, .., N-1), the P th sample is the maximum value and the M th order in the P th sample. The average value Xave of the samples excluding the samples up to the frequency sample and the samples from the P th sample to the M th lower frequency sample is calculated as in Equation 1 below.

The controller 116 compares the average value Xave with Xp + alpha. If the average value Xave is greater than Xp + alpha, the controller 116 determines that an intermodulation signal is occurring, and proceeds to step 207, and the value of the sample Xp If less than Xave + alpha, it is determined that no intermodulation signal is generated (step 206), and the digital filter 118 transmits that the intermodulation signal is not generated through the control line 117 to the digital filter 118. The introduced baseband signals 113 and 114 are transmitted to the modulation and demodulation unit 121 (step 211). Here, the value is set as an experimental value to compensate for the average value Xave lowered by extremely low sample values in the reception channel band so as to become a reference level of the alpha intermodulation signal.

If it is determined that an intermodulation signal is generated, interpolation is performed by taking only the maximum value sample (Xp) and a few samples around the maximum value sample, and then using the more accurate sample maximum value (P) and the frequency when the magnitude Fp) is calculated (step 207). By comparing the magnitudes of the samples of the upper and lower frequencies with respect to the sample Xp with the average value Xave or the average value Xave + alpha, the bandwidth of the intermodulation signal B _IMD is determined. Is calculated (step 208). Finally, the control unit 116 outputs the generation signal of the intermodulation signal to the digital filter 118 through the control line 117, and obtains the maximum value P, the frequency Fp at this time, and the bandwidth of the intermodulation signal ( B _IMD ) is output to an internal register (not shown) and the digital filter coefficient is calculated using the same (step 209). The intermodulated signal is filtered and removed using the calculated digital filter coefficients (step 210). On the other hand, if the intermodulation signal is not detected in step 206, a signal informing that the intermodulation signal is not generated is output to the digital filter 118.

In the embodiment shown in Figure 1 is a device for controlling the intermodulation signal by filtering the intermodulation signal using the digital filter 118, the control unit 116 is based on the information obtained by the algorithm of FIG. The coefficient of the filter 118 is calculated and output to the digital filter 118. Since necessary information may vary according to the control method used, calculation of the maximum value P, the frequency Fp of P, and the bandwidth B _IMD may be partially omitted in the flowchart of FIG. 2.

3 is a graph illustrating information calculation of intermodulated signals in a discrete Fourier transformed sample according to the present invention. The vertical axis represents the magnitude or intensity of the frequency component and is often expressed in dBm, and the horizontal axis represents the frequency. Reference numeral 302 is, for example, a simple 16-point discrete Fourier transformed sample, 303 is a sample (Xp) having a maximum value, 304 is a magnitude of a sample (Xp) having a maximum value, and 305 is Xave + alpha to determine the intermodulation signal. It is the level to judge the occurrence. That is, if each sample is taken one by one around the maximum sample 303 in the graph and approximated by interpolation, the maximum value P of the intermodulation signal 309 is calculated and the frequency Fp 307 is obtained. ) Can be calculated. Also, there are three samples in the graph that are larger than the reference level 305 around the maximum sample Xp, including the maximum sample 303 in the graph, and these samples have a constant frequency interval so that the bandwidth of the 308 intermodulation signal is 308. (B _IMD ) can be approximated.

Meanwhile, the above-described embodiment of the present invention can be written as a program that can be executed in a control unit including a central processing unit (MPU) in a communication system. And it may be implemented in a control unit for operating the program from a medium used in a central processing unit (MPU). The media includes storage media such as magnetic storage media (e.g., ROM, floppy disk, hard disk, etc.), optical reading media (e.g., CD-ROM, DVD, etc.) and carrier waves (e.g., transmitted over the Internet). .

The recording medium is a method of controlling the intermodulation signal to remove the intermodulation signal included in the baseband converted reception signal in a communication system comprising the steps of: outputting the received signal as a discrete Fourier transformed sample; Calculating a sample Xp having a maximum size in the output sample; Calculating an average value Xave for the remaining samples except for a predetermined number of samples located in the periphery of the sample Xp; Determining whether an intermodulation signal is generated by comparing the value Xave + alpha plus the predetermined value alpha with the average value Xave and the value of the sample Xp; Calculating a digital filter coefficient for filtering the intermodulated signal when the intermodulated signal is detected; And storing a program code for executing the filtering of the intermodulated signal using the calculated digital filter coefficients in the controller.

The calculating of the digital filter may be performed by interpolating a sample Xp having the maximum value and its surrounding samples to obtain a more accurate maximum value P of frequency components of the intermodulation signal, Calculating a frequency; Calculating an intermodulation signal bandwidth by taking samples adjacent to the sample (Xp) having a value larger than the value (Xave + alpha) by adding a predetermined value (alpha) to the average value (Xave); And calculating the digital filter coefficient using the frequency Fp of the maximum value P of the frequency components of the intermodulated signal and the intermodulated signal bandwidth B _IMD .

And functional program code and code segments for implementing the present invention can be easily inferred by programmers in the art to which the present invention belongs.

According to the present invention, by accurately determining the mutual interference signal generated by the receiver of the mobile communication terminal of the wireless transmission and reception system and filtering and removing the mutual interference signal, to improve the call quality and prevent unnecessary current consumption, battery life and talk time To extend.

Claims (7)

An intermodulation signal control apparatus for removing an intermodulation signal included in a baseband converted reception signal in a communication system, A / D conversion means for sampling each baseband converted analog signal and converting the analog signal into a digital baseband signal; A discrete Fourier transform unit for inputting the digital baseband signal and outputting a discrete Fourier transform sample; A digital filter unit for filtering and removing the intermodulated signal from the digital baseband signal using the digital filter coefficient introduced according to a control signal, or transmitting the filtered signal to the modulator without filtering; The discrete Fourier transformed sample is introduced to calculate an average value Xave of the remaining samples excluding the sample Xp having the maximum value and a predetermined number of samples located around the sample Xp, and the average value Xave. The digital filter is controlled by comparing the value (Xave + alpha) plus a predetermined value (alpha) with the value of the sample (Xp) to determine whether an intermodulation signal is generated, and controlling the digital filter (Xp) and its surroundings. And a control unit for generating the digital filter coefficients using a maximum value P and a frequency and bandwidth at the maximum value P of the intermodulated signal calculated by interpolating a predetermined number of samples located at. Intermodulation Signal Control System The method of claim 1, wherein the predetermined value alpha is a value set as an experimental value to compensate for an average value Xave lowered by extremely low sample values in a reception channel band so as to be a reference level of an intermodulation signal. Intermodulation signal control device in a communication system. In the intermodulation signal detection method for determining whether the intermodulation signal is generated in the baseband transformed reception signal in the communication system, Outputting the received signal as a discrete Fourier transformed sample; Calculating a sample Xp having a maximum size in the output sample; Calculating an average value Xave for the remaining samples except for a predetermined number of samples located in the periphery of the sample Xp; And determining that the intermodulation signal is generated when the value of the sample Xp is larger than the value Xave + alpha plus the predetermined value alpha added to the average value Xave. Intermodulation signal detection method of the. 4. The method of claim 3, wherein the predetermined value alpha is a value set as an experimental value to compensate for an average value Xave lowered by extremely low sample values in a reception channel band so as to be a reference level of an intermodulation signal. A method for detecting intermodulation signals in a communication system. A method of controlling an intermodulation signal included in a baseband transformed reception signal in a communication system includes outputting a received signal as a discrete Fourier transformed sample; Calculating a sample Xp having a maximum size in the output sample; Calculating an average value Xave for the remaining samples except for a predetermined number of samples located in the periphery of the sample Xp; Determining whether an intermodulation signal is generated by comparing the value Xave + alpha plus the predetermined value alpha with the average value Xave and the value of the sample Xp; Calculating a digital filter coefficient for filtering the intermodulated signal when the intermodulated signal is detected; And And filtering the intermodulated signal using the calculated digital filter coefficients. The method of claim 5, wherein the calculating of the digital filter Interpolating the sample Xp having the maximum value and its surrounding samples to obtain a more accurate maximum value P of frequency components of the intermodulation signal and calculating a frequency at the maximum value P; Calculating an intermodulation signal bandwidth by taking samples adjacent to the sample (Xp) having a value larger than the value (Xave + alpha) by adding a predetermined value (alpha) to the average value (Xave); And And calculating the digital filter coefficients using the frequency Fp of the maximum value P of the frequency components of the intermodulated signal and the intermodulated signal bandwidth B _IMD . Signal control method. 7. The method of claim 6, wherein the predetermined value alpha is a value set as an experimental value to compensate for an average value Xave lowered by extremely low sample values in a reception channel band so as to be a reference level of an intermodulation signal. A method of controlling intermodulation signals in a communication system.