KR20060101644A - Channel equalizer in digital broadcasting receiver - Google Patents

Abstract

The present invention relates to an equalization apparatus for estimating the impulse response of a channel in a digital transmission / reception system to determine whether it is a dynamic channel or a static channel, and to control equalization parameters based on the equalization device. In particular, the present invention estimates the impulse response of the channel for each pilot synchronization signal periodically received, receives the previous impulse response and the current impulse response of the estimated channel, and measures the degree of change of the channel to estimate whether the estimated channel is a dynamic channel or a static channel. Determine if it is. In addition, the channel equalization performance may be improved by controlling a power normalization parameter of the frequency domain equalizer according to the determined characteristics of the channel and updating the filter coefficients of the frequency domain equalizer.

Dynamic Channels, Static Channels, Power Normalization Parameters, Frequency Domain Equalization

Description

Channel equalizer in digital broadcasting receiver

1 is a block diagram showing an embodiment of an equalization apparatus of a digital broadcast receiver according to the present invention;

2 is a data frame diagram of a typical TSC system

Explanation of symbols for main parts of the drawings

100: channel estimation unit 200: channel distortion compensation unit

221,222,233: First FFT Part 223: ROM

224 dynamic channel detector 230 frequency domain equalizer

231,234: complex multiplier 232: IFFT unit

235 multiplier 236 adder

237: coefficient bank 238: conjugate complex value generator

239: power normalization unit 300: noise canceling unit

400: error signal generator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital transmission and reception system, and more particularly, to an equalization apparatus for estimating an impulse response of a channel to determine whether the channel is a dynamic channel or a static channel, and to control the equalization parameter to perform channel equalization. .

In a digital communication system, a signal entered through a receiving end passes through a multipath transmission channel and is severely distorted due to interference between adjacent signals. Therefore, in order to recover the original signal from the distorted received signal, it is necessary to employ an equalizer for channel compensation.

In general, the most popular channel equalizer is a decision feedback equalizer (DFE) using a Least Mean Square (LMS) algorithm. The DFE regards the most energy-intensive path as the main path when the received signal enters through a multipath channel, and considers all remaining paths as neighboring signal interference (ISI) or ghost signals coming through the reflection path. After the phase and magnitude correction are extracted only for the signal coming through the main path, the signals coming through the remaining path are removed.

However, when the DFE is severely channel distortion, a decision error occurs frequently in a determination value coming into the input of the feedback filter, so that an error propagation is lost or the main path is blocked and a signal received only through the reflection path exists. Or, if the energy coming into each path is similar and it is unclear which signal to use as the main, there is a disadvantage in that it cannot be equalized properly.

The present invention is to solve the above problems, an object of the present invention is to estimate the impulse response of the channel to determine whether it is a dynamic channel or a static channel, based on this digital broadcast receiver to improve the equalization performance by controlling the equalization parameters It is to provide an equalization device.

In order to achieve the above object, the equalizer of the digital broadcast receiver according to the present invention estimates the impulse response of a channel for each pilot synchronization signal periodically received by the channel estimator, and estimates the previous impulse response and the current impulse response of the estimated channel. It is characterized by determining whether the estimated channel is a dynamic channel or a static channel by measuring the degree of change in the channel received from the input.

The present invention is characterized in that the filter coefficients of the frequency domain equalizer are updated by controlling a power normalization parameter of the frequency domain equalizer according to the characteristics of the determined channel.

If the hardware is configured as a feature, a channel estimator for estimating the impulse response of the channel from the received signal passing through the transmission channel and outputs; A dynamic channel detector for determining whether a channel is a dynamic channel or a static channel by using a difference value between an impulse response of a channel estimated in a current field and an impulse response of a channel estimated in a previous field output from the channel estimator. ; A frequency domain converter for converting the received signal and the estimated impulse response of the channel into a frequency domain signal, respectively, and outputting an inverse value of the estimated channel impulse response; And setting an inverse value of the channel impulse response of the frequency domain transform unit as an initial coefficient, selecting an equalization parameter corresponding to the channel characteristic detected by the dynamic channel detector in a data section thereafter, and continuously updating the coefficient using an error signal. And a frequency domain equalizer for compensating for distortion of the received signal in the frequency domain.

The dynamic channel detector obtains a difference between the estimated channel impulse response of the current field and the channel impulse response of the previous field, calculates the amount of change of the channel by taking an absolute value or a square of the difference value, and then calculates the calculated amount of change of the channel. If it is larger than the threshold, the channel characteristic is determined as a dynamic channel, and if it is not larger, the channel is determined as a static channel.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described. At this time, the configuration and operation of the present invention shown in the drawings and described by it will be described as at least one embodiment, by which the technical spirit of the present invention and its core configuration and operation is not limited.

1 is a block diagram showing an embodiment of an equalization apparatus of a digital broadcasting receiver according to the present invention. The channel estimator 100 estimates a path (impulse response) of a transmission channel from a received signal y (n). The channel estimator 100 determines whether the channel characteristic is a dynamic channel or a static channel using the estimated channel impulse response, and controls the equalization parameter in the frequency domain according to the determination result to compensate for the channel distortion of the received signal. Enhanced noise included in the time domain signal output from the channel distortion compensator 200 by predicting the amplified noise during equalization from the output of the distortion compensator 200 and the channel distortion compensator 200. And an error signal using a noise canceller 300 for removing residual symbol interference components, an output signal from the channel distortion compensator 200, and an output signal from the noise canceller 300. It consists of error signal generator 400 and outputting to the group channel distortion compensation unit 200.

The channel distortion compensator 200 is a first fast Fourier transform (FFT) unit 221 for transforming the received signal from the time domain to the frequency domain, the time impulse response of the channel estimated by the channel estimator 100 The second FFT unit 222 converts the frequency domain corresponding to the reverse channel of the transmission channel of the frequency domain into a table in advance and stores the frequency response corresponding to the reverse channel of the transmission channel converted into the frequency domain. A ROM 223 for outputting a frequency response, a dynamic channel detector 224 for detecting whether the estimated channel is a dynamic channel by determining an amount of change in the channel based on an impulse response of the estimated channel, and the first FFT 221. The frequency response output from the ROM 223 is used as an initial coefficient when the frequency domain equalization is performed on the input signal outputted from the signal and corresponds to the channel characteristic detected by the dynamic channel detector 224. Selects a power normalization parameter to update the coefficients and comprises a frequency domain equalizer 230 for compensating for the channel while adaptively equalizing the distorted transmission channel during the data period by using the initial coefficient or the updated coefficient. do. The frequency domain equalizer 230 is an LMS algorithm.

The frequency domain equalizer 230 uses the frequency response output from the ROM 223 as an initial coefficient, and in the coefficient bank 237 and the first FFT unit 221 storing coefficients necessary for channel equalization. A complex multiplier 231 and a complex multiplier configured to multiply the output frequency domain signal by a coefficient output from the coefficient bank 237 to compensate for channel distortion included in the frequency domain signal output from the first FFT unit 221. IFFT unit 232 for inverting the distortion-corrected frequency domain signal output from the 231 back to the time domain, the difference between the output of the IFFT unit 232 and the signal from which the noise is removed in the noise canceling unit 300 A third FFT unit 233 for receiving an error signal and converting it into a frequency domain; a conjugate complex value generator 238 for outputting a conjugate conjugate value of the frequency domain signal output from the first FFT unit 221; Detected by the dynamic channel detector 224 A power normalization unit 239 for normalizing the output signal of the conjugate complex value generator 238 by selecting a power normalization parameter corresponding to the channel characteristic, and an output of the power normalization unit 239 and the third power normalization parameter 239. A complex multiplier 234 for multiplying the output of the FFT unit 233, a multiplier 235 for multiplying the output of the complex multiplier 234 by a step size α, and an output of the multiplier 235 and the coefficient bank ( And an adder 236 for storing coefficients in the coefficient bank 237 after performing the coefficient update by adding the output of the 237.

The noise remover 300 extracts only colored noise from the output of the channel distortion compensator 200 and predicts the amplified noise at the time of equalization, from the output of the channel distortion compensator 200. The noise predictor 311 subtracts the noise predicted by the subtractor 312.

In the present invention configured as described above, when the transmission signal is called x (n), the impulse response of the discrete equivalent channel is called h (n), and the white noise is called w (n), the input signal y (n) input to the receiver is It may be expressed as Equation 1 below.

The received signal y (n) as shown in Equation 1 is input to the channel estimator 100 and the first FFT unit 221 of the channel distortion compensator 200.

을 채널 왜곡 보상부(200)의 제 2 FFT부(222)와 동적 채널 검출기(224)로 출력한다. The channel estimator 100 receives y (n) as an input and estimates an impulse response h (n) of a discrete equivalent channel that the original signal x (n) has passed through, thereby estimating a finite impulse response of the channel.

Is output to the second FFT unit 222 and the dynamic channel detector 224 of the channel distortion compensator 200.

In this case, the channel estimator 100 may use the Simple Correlation Method (SCM) or the Least Square Method (LSM) estimation method to estimate the impulse response of the transmission channel. It is the choice of the system designer to decide whether to use SCM or LSM in the present invention.

That is, the SCM method assumes that the training signal periodically added to the transmission signal is a white signal, and obtains a cross correlation value between the training signal passed through the channel and the training signal already known at the receiver. It is a method to estimate the impulse response.

의 행렬 연산을 하여 전송 채널의 임펄스 응답을 추정하는 방법이다.Meanwhile, the least square method (LSM) estimation method obtains a cross correlation value p between a training signal passed through a channel during a training time and a training signal known to a receiver, and calculates an autocorrelation matrix R of the training signal. Obtain Then, remove the autocorrelation part existing in p, which is the cross correlation value between the received signal and the original training signal.

It is a method of estimating the impulse response of a transmission channel by performing a matrix operation of.

The first FFT unit 221 of the channel distortion compensator 200 converts the received signal y (n) into a frequency domain to perform a complex multiplier 231 and a conjugate complex value generator 238 in the frequency domain equalizer 230. Will output

The complex multiplier 231 is a component of a frequency component converted into N frequency bins through a first FFT unit 221 and a frequency component of the same size (N) stored in the coefficient bank 237. The multiplication is performed and output to the IFFT unit 232. Here, the component product means a product of the same frequency bins. The result of the product of the complex multiplier 231 is equalized in the frequency domain, and the frequency component with the equalization is inversely converted back into the time domain in the IFFT unit 232 to remove the noise remover 300 and the error signal generator. Is output to 400.

The conjugate complex value generator 238 generates a conjugate complex value of the received signal in the frequency domain and outputs it to the power normalization unit 239. For example, if the received signal in the frequency domain output from the first FFT unit 221 is a complex number in the form of a + jb, the conjugate complex value of the received signal in the frequency domain output from the conjugate complex value generator 238 is a it becomes -jb. That is, the complex number whose real part a is the same and whose only sign of the imaginary part jb is opposite is called a conjugate conjugate value.

Meanwhile, the second FFT unit 222 of the channel distortion compensator 200 converts the output signal of the channel estimator 100 into a frequency domain and outputs the output signal to the ROM 223.

The inverse values of the input values are pre-tabled and stored in the ROM 223, and an inverse value of the impulse response of the channel converted into the frequency domain is selected in the ROM 223 so that the coefficient bank of the frequency domain equalizer 230 is selected. The output is 237.

In this case, even though a frequency bin having a value of 0 exists in the frequency response of the estimated channel, since the inverse value is obtained through the ROM 223, it is always limited to a finite value, You can avoid the danger.

That is, the frequency response of the inverse channel obtained through the ROM 223 is downloaded to the coefficient bank 237 having the storage of the size of the FFT block, and used as an initial coefficient for frequency domain equalization of a new incoming data block. In this case, the coefficient download time may be performed for each training signal, or may be a method of performing adaptive equalization only once and at the initial time. In addition, the two methods described above may be selected or combined, which will vary depending on the designer implementing the same.

The filter coefficients of the coefficient bank 237 are input to the multiplier 231 to equalize the frequency domain.

The noise predictor 311 of the noise remover 300 predicts the colored noise amplified at the time of equalization from the output signal of the frequency domain equalizer 230 and outputs it to the subtractor 312. The subtractor 312 removes the predicted noise of the noise predictor 311 from the output signal of the frequency domain equalizer 230 to remove colored noise that has been amplified during equalization.

The final output from which the amplification noise is removed from the noise removing unit 300 is input to the determining unit 411 of the error signal generating unit 400 to generate an error signal for updating a new equalization coefficient.

The decision unit 411 outputs a decision value closest to the output of the equalizer to the selector 412. The selector 413 is a kind of mux. The selector 413 selects a training string of the training signal generator 412 in the training signal section and selects a determination value of the determination unit 411 in the data section and outputs the result to the subtractor 414.

The subtractor 414 obtains a difference between the output signal z (n) of the frequency domain equalizer 230 and the output signal d (n) of the mux 413 to obtain a third FFT unit 234 of the frequency domain equalizer 230. ) Is output as an error signal.

Meanwhile, the dynamic channel detector 224 of the channel distortion compensator 200 detects whether a channel estimated from the output signal of the channel estimator 100 is a dynamic channel or a static channel and displays the result in the frequency domain equalizer 230. Is output to the power normalization unit 239.

In this case, in order to see an example of dynamic channel detection using the impulse response of the channel in the dynamic channel detector 224, the frame structure of the ATSC system, which is the North American digital TV transmission standard shown in FIG.

Referring to FIG. 2, one data frame includes an odd data field and an even data field, and each data field is further divided into 313 data segments. The 313 data segment includes one field sync segment and a general data segment of 312 including a training sequence signal. Each data segment consists of four segment sync symbols and 828 data symbols.

The field sync segment has a length of 1 data segment, and there is a data segment sync pattern in the first 4 symbols, and then 511 PN 511, which is a pseudo random sequence, 63 PN 63 and 63 each, respectively. 63, PN 63 is present and the next 24 symbols are VSB mode-related information. Here, the polarity of the second PN 63 of the three PN 63 section is changed each time. That is, '1' is changed to '0' and '0' is changed to '1'. Therefore, one frame may be divided into an even / odd field according to the polarity of the second PN 63.

The remaining 104 symbols after the 24 symbols in which the VSB mode-related information is present are not used, and the last 12 symbols of the unused area are copied with the last 12 symbols of the previous segment (pre-code symbol).

At this time, since one data field has a period of about 24.2 ms, it can be seen that about 41.3 field sync segments are transmitted per second.

Accordingly, the channel estimator 100 of the present invention uses a simple correlation method (SCM) or LS estimation method (LSM) using the training sequence of PN511, PN63, etc. each time the field sync segment is received. Estimate the impulse response of.

In addition, the dynamic channel detector 224 compares the difference between the impulse response of the channel estimated in the current field and the impulse response of the channel estimated in the previous field with a preset threshold to determine whether the characteristic of the channel is a dynamic channel or not. Determine if it is. The determined channel characteristic is then output to the power normalization unit 239 of the frequency domain equalizer 230.

,

이라고 하고, 이전 필드에서 추정한 채널의 임펄스 응답을

이라고 하자. 여기서 N은 추정한 채널 임펄스 응답의 길이이다.That is, the difference between the impulse response of the channel estimated in the current field and the impulse response of the channel estimated in the previous field indicates the degree of change of the channel between one field. The impulse response of the channel

,

The impulse response of the channel estimated from the previous field

Let's say. Where N is the estimated channel impulse response length.

The difference between the impulse response of the channel estimated in the current field and the impulse response of the channel estimated in the previous field, D (t, t-1), is a numerical value representing the channel change and the difference between the two channel impulse responses as shown in Equation 2 below. It can be calculated as the absolute value of or the square of the difference.

At this time, if the channel is a static channel, i.e., there is almost no change, since the channel impulse response in the current field and the channel impulse response in the previous field are almost the same, the amount of change of the channel is almost zero, as shown in Equation 3 below. .

Accordingly, the dynamic channel detector 224 determines that the amount of change D (t, t-1) of the channel is smaller than the threshold by comparing the preset variation D (t, t-1) to the static channel as shown in Equation 4 below. If it is larger than the threshold, it is determined as a dynamic channel.

if D (t, t-1) ≤ threshold, then static channel

else dynamic channel

In addition to the above-described method, there is a method of determining whether the channel is a dynamic channel by averaging the change amount of the channel over several fields.

Next, a process of controlling the power normalization parameter of the frequency domain equalizer 230 using the detection result of the dynamic channel detector 224 will be described.

First, the filter coefficient W (k) of the frequency domain equalizer 230 is updated as in Equation 5 below. In other words, the product of the input of the filter tab and the product of the error is multiplied by the step-size α, and is updated to the next filter coefficient by adding the current filter coefficient.

는 수신된 데이터가 제1 FFT부(221), 공액 복소값 생성기(238), 전원 정규화부(239)를 순차적으로 거친 신호이다. here

The received data is a signal sequentially passed through the first FFT unit 221, the conjugate complex value generator 238, and the power normalization unit 239.

In Equation 5, d (n) is a reference signal, and a training column 412 is selected in a pilot section through a mux 413 of the error signal generator 400, and a decision device is selected in a data section. A decision signal of 411 is selected and used.

That is, the subtractor 414 in the error signal generator 400 obtains a difference between the reference signal d (n) output from the mux 413 and the output signal z (n) of the frequency domain equalizer 230. It outputs to the 3rd FFT part 233 of the equalizer 230 as an error signal e (n).

The third FFT unit 233 converts the input error signal e (n) into a frequency domain and outputs it to the multiplier 234 (E (k) = FFT (e (n)).

를 복소곱하여 곱셈기(235)로 출력한다. 이때, 상기 복소 곱셈기(235)의 연산은 시간 영역에서의 원형 상호 상관값 연산에 해당한다.The complex multiplier 234 is frequency domain data that is power normalized with error signal E (k) in the frequency domain.

The complex product is output to the multiplier 235. In this case, the operation of the complex multiplier 235 corresponds to a circular cross-correlation value calculation in the time domain.

The frequency domain signal of the circular cross-correlation value thus obtained is multiplied by the step size α in the multiplier 235 and then output to the adder 236.

The adder 236 adds the output of the multiplier 235 and the existing filter coefficients fed back from the coefficient bank 237 to perform coefficient update. That is, the output of the multiplier 235 is added to the existing coefficients stored in the coefficient bank 237 to be regenerated as filter coefficients for frequency equalization of the next block. Similarly, in the coefficient update operation of the adder 236, the same frequency bins must be added to the coefficient update.

Meanwhile, the power normalization unit 239 normalizes each frequency bin of the frequency domain input signal as shown in Equation 6 below.

Where N is the FFT point and P _i is the received signal power at each frequency bin. The received signal power P _i is calculated through the following equation (7).

는 시간 k에서의 i번째 탭 계수에 입력된 주파수 영역 데이터를 의미한다. 그리고

는 forgetting factor로서 각 주파수 빈의 수신 파워를 갱신하여 계산하는데 사용되는 유효한 메모리 영역을 조절하는 역할을 한다. 상기

는 0에서 1사이의 값으로서, 그 크기가 0에 가까울수록 동적 채널에서 등화기의 추적(tracking) 성능이 좋아지지만 AWGN TOV(threshold of visualability)가 높아지는 단점이 있고, 그 크기가 1에 가까울수록 등화기의 추적(tracking) 성능이 나빠지지만 AWGN TOV가 낮아지는 장점이 있다.In Equation 7

Denotes frequency domain data input to the i th tap coefficient at time k. And

Is a forgetting factor that controls the effective memory area used to update and calculate the received power of each frequency bin. remind

Is a value between 0 and 1, where the closer to 0, the better the tracking performance of the equalizer in dynamic channels, but the higher the AWGN threshold of visualability (TOV), the closer to 1 The tracking performance of the equalizer is worse but the AWGN TOV is lowered.

값을 낮추어 추적 성능을 높이고, 채널의 변화량이 작다면 즉, 정적 채널이라고 판단될 경우

값을 높이도록 제어함으로써, 주파수 영역 등화기의 성능을 개선할 수 있다.Therefore, when the dynamic channel detector 224 described above is determined to have a large amount of change in the channel, that is, the dynamic channel detector 224 is determined to be a dynamic channel.

Lower the value to increase tracking performance, and if the amount of change in the channel is small, i.e. it is determined to be a static channel

By controlling the value to be higher, the performance of the frequency domain equalizer can be improved.

That is, the power normalizer 239 updates a filter coefficient of the frequency domain equalizer 230 by selecting an appropriate power normalization parameter according to the determination result of the dynamic channel detector 224.

On the other hand, the terms used in the present invention (terminology) are terms defined in consideration of the functions in the present invention may vary according to the intention or practice of those skilled in the art, the definitions are the overall contents of the present invention It should be based on.

The present invention is not limited to the above-described embodiments, and as can be seen in the appended claims, modifications can be made by those skilled in the art to which the invention pertains, and such modifications are within the scope of the present invention.

As described above, according to the equalization apparatus of the digital broadcasting receiver according to the present invention, the impulse response of the channel is estimated for each pilot synchronization signal periodically received, and the change of the channel is performed by using the previous impulse response and the current impulse response of the estimated channel. It measures the degree and determines whether it is a dynamic channel or a static channel. The channel equalization performance can be improved by controlling the power normalization parameter of the channel equalizer to perform coefficient update according to the determined channel characteristics.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (7)

A channel estimator for estimating and outputting an impulse response of the channel from the received signal passing through the transmission channel; A dynamic channel detector for determining whether a channel is a dynamic channel or a static channel by using a difference value between an impulse response of a channel estimated in a current field and an impulse response of a channel estimated in a previous field output from the channel estimator. ; A frequency domain converter for converting the received signal and the estimated impulse response of the channel into a frequency domain signal, respectively, and outputting an inverse value of the estimated channel impulse response; And Set the inverse value of the channel impulse response of the frequency domain transform unit as an initial coefficient, and then select an equalization parameter corresponding to the channel characteristic detected by the dynamic channel detector in the data section, and continuously update the coefficient by using an error signal. And a frequency domain equalizer for compensating for distortion of the received signal in the domain. The method of claim 1, And a noise canceling unit for predicting the amplified colored noise during equalization from the output of the frequency domain equalizing unit and subtracting the equalized signal to whiten the noise. The method of claim 2, A determination unit connected to an output terminal of the noise removing unit and outputting a determination value closest to a signal in which the noise is whitened among a plurality of preset determination values; A selector configured to select a predetermined training string in a training section and to select a decision value output from the determining section as a reference signal; And a subtractor for outputting the difference between the reference signal output through the selector and the equalized signal to the frequency domain equalizer as an error signal. The method of claim 1, wherein the dynamic channel detector After calculating the difference between the estimated channel impulse response of the current field and the channel impulse response of the previous field, taking the absolute value or the square of the difference value and calculating the variation of the channel, if the calculated variation of the channel is greater than the preset threshold, An equalizer of a digital broadcast receiver, characterized in that the characteristic is determined as a dynamic channel and not a large channel. The frequency domain equalizer of claim 1, wherein the frequency domain equalizer A coefficient bank configured to receive an inverse value of the channel impulse response of the frequency domain converter as an initial coefficient, and to store and output coefficients that are continuously updated in a data section thereafter; A complex multiplier for correcting channel distortion included in the received signal by multiplying a received signal in the frequency domain by a coefficient output from the coefficient bank; An IFFT unit for inversely transforming a received signal in a frequency domain in which a distortion is corrected in the complex multiplier to a time domain; An FFT unit for receiving an error signal, which is a difference between a reference signal and an equalization signal, and converting the signal into a frequency domain; A conjugate complex value generator for outputting a conjugate complex value of the received signal of the frequency domain output from the frequency domain converter; A power normalizer for normalizing an output signal of the conjugate complex value generator by selecting a power normalization parameter corresponding to a channel characteristic of the dynamic channel detector; And a coefficient updater multiplying the output of the power normalization unit with the output of the FFT unit, multiplying the step size [alpha], and then adding a previous coefficient fed back from the coefficient bank to perform coefficient update and outputting the coefficient bank again to the coefficient bank. Equalizer of the digital broadcast receiver, characterized in that. The method of claim 5, wherein the power normalization unit Equalizer of the digital broadcasting receiver, characterized in that to normalize each frequency bin of the signal U (i) output from the conjugate complex value generator by applying the following equation.

Where N is the FFT point and P _i is the received signal power at each frequency bin. The method of claim 6, wherein the power normalization unit If the dynamic channel detector determines that the dynamic channel is the received signal power

Multiplied by

Selecting a small value and selecting a large value if the value is determined to be a static channel. here,

Is frequency domain data input to the i th tap coefficient at time k,

Is the forgetting factor K, a value between 0 and 1.

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