KR0164780B1 - Digital non-linear pre-emphasis/de-emphasis apparatus - Google Patents

Abstract

TECHNICAL FIELD The present invention relates to a video signal processing system, and more particularly, to a digital nonlinear pre-emphasis / de-emphasis device that removes noise components from video signals to provide a high quality video signal.

To this end, the digital nonlinear pre-emphasis / de-emphasis device includes a high pass filter for passing only a high frequency component signal u _n or U _n of a predetermined frequency band of an input signal x _n applied from an input terminal; Determine a first frequency band control coefficient for multiplying the high frequency component signal u _n by a frequency band control coefficient Emb such that the gain for the highest frequency of the high frequency component signal u _n is 1, and then returning the signal Embu _n to the high pass filter And a slope from the high frequency component signal U _n , a frequency band control coefficient Dema is determined from the determined slope, and the mixed frequency band control coefficient Dema is mixed with the high frequency component signal U _n . A second frequency band control coefficient determination unit for returning a signal DemaU _n to the high pass filtering means; A first switch which selects one of signals output from the first frequency band control coefficient determiner and the second frequency band control coefficient determiner and feeds it back to the high pass filter; A first gain control coefficient determination unit which multiplies the high frequency component signal u _n by a predetermined gain control coefficient Emb; A second gain control coefficient determination unit for determining a slope from the high frequency component signal U _n , determining a gain control coefficient Demb from the determined slope, and mixing the determined gain control coefficient Demb with the high frequency component signal Un; ; A second switch for selecting one of signals output from the first and second gain control coefficient determination units; And an adder for adding and outputting the input signal x _n and an output signal selected by the second switch. In addition, the frequency band control coefficient Dema determined by the second frequency band control coefficient determiner is

ego to be. In addition, the gain control coefficient Demb determined by the second gain control coefficient determination unit is ego, to be.

In this way, the frequency band and the gain control coefficient can be obtained using the slope which hardly changes according to the value of the high frequency component signal. Therefore, it is possible to implement a more economical digital nonlinear pre-emphasis / de-emphasis device that can be implemented with only one ROM and can reduce the occupied area of the ROM when designing an integrated device.

Description

Digital nonlinear pre-emphasis / de-emphasis device

1 is a block diagram of a conventional digital nonlinear pre-emphasis / de-emphasis device.

2 is a block diagram of a digital nonlinear pre-emphasis device according to the present invention.

FIG. 3 is a diagram showing the relationship between the high frequency component signal U _n and the gain control coefficient Emb according to an example of the specification of the digital nonlinear pre-emphasis device as shown in FIG. 2.

4 is a block diagram of a digital nonlinear de-emphasis device according to the present invention.

FIG. 5 is a diagram showing a relationship between a high frequency component signal U _n , a frequency band control coefficient Dema, and a gain control coefficient Demb in the configuration of FIG. 4.

6 is a block diagram of a digital nonlinear pre-emphasis / de-emphasis device according to the present invention.

* Explanation of symbols for main parts of the drawings

1: input stage 9: thrust stage

2,5 delay unit 3: subtractor

4,8,20,40,52: Adder 12,14: Switch

30: ROM gain control coefficient (Emb) 32,44,54: Mixer

42: frequency band control coefficient (Dema) slope determination unit

50: gain control coefficient (Dema) slope determination unit

The present invention relates to a video signal processing system, and more particularly, to a digital nonlinear pre-emphasis / de-emphasis device that removes noise components from video signals to provide a high quality video signal.

In general, non-linear pre-emphasis / de-emphasis devices are used in video tape recorders and camcorders to process high quality video signals. The nonlinear pre-emphasis / de-emphasis device emphasizes the high frequency components of the video signal in the recording mode of the video signal, and decreases the highlighted high frequency components in the reproduction mode of the video signal. By using the nonlinear pre-emphasis / de-emphasis device as described above, it is possible to suppress the video signal of the noise component having the small amplitude and to effectively suppress the distortion of the waveform with respect to the signal component having the large amplitude. .

Hereinafter, a general nonlinear pre-emphasis / de-emphasis device will be described.

1 is a schematic block diagram of a conventional digital nonlinear pre-emphasis / de-emphasis device.

The digital non-linear pre-emphasis / de-emphasis device has a structure applied to both digital pre-emphasis and de-emsurface device. Such a digital non-linear pre-emphasis / de-emphasis device is described in US Pat. VIDEO SIGNALS IN A VIDEO SIGNAL PROCESSING SYSTEM.

First, the case where the device is a digital nonlinear pre-emphasis device will be described. The digital nonlinear pre-emphasis device includes a high pass filter 100 which receives a predetermined coded quantized n th input signal x _n applied from the input terminal 1 and passes only the high frequency signal component u _n of the input signal x _n . In order to change the pass frequency band of the high pass filter 100, the first high-frequency signal component u _n is multiplied by the frequency band control coefficient Ema to apply the feedback signal Emau _n to the high pass filter 100. 6), a second ROM 7 and the second ROM (signal Embu _n and an input terminal (1) outputted from 7) for multiplying a gain control coefficient Emb the high frequency component signal u _n of the output signal Embu _n And an adder 8 that adds an input signal x _n directly applied from the output signal and outputs the signal y _n to the output terminal 9.

The frequency band control coefficient Ema and the gain control coefficient Emb, which are coefficients of the first ROM 6 and the ROM 7, are functions of the high frequency component signal u _n of the video input signal x _n .

In addition, the high pass filter 100 includes a delay unit 2 for delaying an input signal x _n for a predetermined sampling period k and outputting the delayed input signal x _nk , and a signal x _nk outputted from the delay unit 2. A subtractor 3 for subtracting the input signal x _n , a delay unit 5 for delaying the signal Emau _n output from the first form 6 for a predetermined sampling period k and outputting the delayed feedback signal Emau _nk ; And an adder 4 which adds a signal x _n -x _nk subtracted by the subtractor 3 and a signal Emau _nk delayed and fed back from the delay unit 5.

According to the configuration as described above, the output signal of the digital nonlinear pre-emphasis device output to the final output stage 9 is as shown in Equation (1) below.

In the above configuration, when the delay elements of the delay units 2 and 5 are the primary delay elements, assuming that the transfer function of the digital nonlinear pre-emphasis device is Hem (Z), the transfer function Hem (Z) is It is as following Formula (2).

Next, a case where the device having the above configuration is a digital nonlinear de-emphasis device will be described. The digital nonlinear de-emphasis device again reduces the signal of the high frequency band highlighted from the digital nonlinear pre-emphasis device. Therefore, the transfer function of the digital nonlinear de-emphasis device is called Hdem (Z), and the frequency band control coefficient and the gain control coefficient which are coefficients of the first ROM 6 and the second ROM 7 in the de-emphasis device are described. When Dema and Demb, the transfer function Hdem (Z) is as shown in Equation (3) below, and when Equation (3) is developed as shown in Equation (4) below.

It can be seen from the above Equation (4) that the frequency band control coefficient Dema and the gain control coefficient Demb in the digital nonlinear de-emphasis apparatus are determined as in the following formulas (5a) and (5b). In addition, since the signals in the digital nonlinear de-emphasis device correspond to the inverses of the signals in the digital nonlinear pre-emphasis device, the signal input to the input terminal 1 is referred to as y _n , and the final signal output to the output terminal 9 is referred to as y _n . Let x be x _n and the high frequency component signal of the input signal y _{n be} u _n . The final signal x _n to be output is similar to the following Equation (6).

In Equations (5a) and (5b), it can be seen that the frequency band control coefficient Dema and the gain control coefficient Demb of the digital nonlinear de-emphasis device are functions of the coefficients Ema and Emb of the digital nonlinear pre-emphasis device. Therefore, the frequency band control coefficient Dema and the gain control coefficient Demb of the digital nonlinear de-emphasis device can be obtained from the coefficients of the digital nonlinear pre-emphasis device. The frequency band control coefficients and control gain coefficients of the digital nonlinear pre-emphasis device and the de-emphasis device are determined by the ROM. Each of the first ROM 6 and the second ROM 7 is generated as a specific output value after multiplying an input signal by specific nonlinear constants determined by the amplitude of the input signal. Each of the first ROM 6 and the second ROM 7 uses input signal data as address data, and stores output values specified by the address data in the address.

However, a total of four ROMs are required to implement a digital nonlinear pre-emphasis / de-emphasis device using a ROM as described above. The area occupied by the four ROMs in the integrated design of the digital nonlinear pre-emphasis / de-emphasis device is considerable. Accordingly, when the digital nonlinear pre-emphasis / de-emphasis device is integrated design, there is a problem that the cost increases, and the integration design is not easy. In addition, the frequency band control coefficient and the gain control coefficient, which are the coefficients of the ROM, can be obtained through a number of repetitive attempts. In some cases, it is more efficient to obtain the coefficients using RAM because the coefficients obtained are not constant.

It is therefore an object of the present invention to provide a digital nonlinear pre-emphasis / de-emphasis device having a small footprint.

It is another object of the present invention to provide a digital nonlinear pre-emphasis / de-emphasis device in which frequency band control coefficients and gain control coefficients can be easily obtained.

It is still another object of the present invention to provide a method for easily optimizing frequency control coefficients and gain control coefficients using a signal slope in a digital nonlinear pre-emphasis / de-emphasis device.

According to the above objects, the digital non-linear pre-emphasis / de-emphasis device of the present invention, the digital non-linear pre-emphasis / de-emphasis device is a high pass filtering to pass only the signal of the high frequency component from the input signal Means for determining a frequency band control coefficient by multiplying a signal of a high frequency component by a frequency band control coefficient and applying it to the high pass filtering means; and a means for determining a frequency band control coefficient on a signal of a high frequency component passed through the high pass filtering means. Gain control coefficient determination means for multiplying a gain control coefficient corresponding to the frequency band determined by the < RTI ID = 0.0 > and < / RTI >

And the frequency band control coefficient determining means of the digital nonlinear pre-emphasis device comprises: gain dividing means for dividing the gain of the signal applied from the low pass filtering means so that the gain of the highest frequency is 1, and the predetermined amount The gain of is composed of a divided signal and an adding means for adding a signal applied directly from the low pass filtering means. In addition, the gain control coefficient determining means of the digital nonlinear pre-emphasis device is a ROM for multiplying a signal applied from a low pass filtering means by a predetermined gain control coefficient, a signal multiplied by a predetermined gain control coefficient in the ROM and the low pass. It consists of mixing means for mixing the signal applied directly from the filtering means. In the above, the ROM may store the gain value corresponding to the value of the frequency band control coefficient in advance according to a given specification of the video processing system.

The frequency band control coefficient determining means of the digital nonlinear de-emphasis apparatus includes frequency band control coefficient determining means for determining a slope of a signal applied from a low pass filtering means, and a predetermined frequency band control coefficient slope and a predetermined frequency band control coefficient slope. Adding means for adding a maximum value of the frequency band control coefficient and outputting the frequency band control coefficient; and mixing means for mixing the frequency band control coefficient outputted from the adding means with a high frequency component signal applied from the low pass filtering means. It is composed. In addition, the gain control coefficient determining means includes a gain control coefficient slope determination means for determining the slope of the input signal by inputting a signal having an increased bandwidth output from the low pass filtering means, and the determined gain control coefficient slope and a predetermined value And adding means for adding the maximum value of the gain control coefficient to the gain control coefficient and mixing means for mixing the gain control coefficient outputted from the adding means with the high frequency component signal.

Hereinafter, a digital nonlinear pre-emphasis / de-emphasis device according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description, the high pass filtering means, the input stage, the output stage, and the adder have the same configuration as the high pass filtering means, the input stage, the output stage, and the adder in the conventional digital nonlinear pre-emphasis / de-emphasis apparatus. Use the same. And the same configuration and operation will be briefly described to clarify the present invention.

In the following description, the delay unit will be assumed to be a first order delay element, and the equation developed accordingly will also be developed to correspond to the first order delay element. However, it is obvious to those skilled in the art that the delay unit may be composed of a plurality of delay elements.

A digital nonlinear pre-emphasis device according to the invention is disclosed in FIG.

The signal x _n input from the input terminal 1 is applied to the adder 8 and the high pass filter 100. The high pass filter 100 outputs only a high frequency component of the applied input signal xn as a signal u _n . The high frequency component signal u _n is applied to the frequency bandwidth control coefficient determiner 200. Bandwidth control factor determination unit 200 and the gain of the high frequency component signal u _n 1/2 ⁿ times the signal gain of the divider 22, which, the high frequency component signal u _n and the high gain of the divided fold the 1/2 ⁿ It consists of an adder 20 which adds the signal u _n applied directly from the keg filter 100. As described above, the high frequency component signal u _n having a gain divided by 1/2 ⁿ times with the high frequency component signal un is added by the adder 20 and then input to the high pass filter 100. At this time, the input / output relationship between the high frequency component signal u _n of the input signal x _n and the input signal x _n is the same as in the above formula (1). In the above equation (1), assuming that the delay element k is the primary delay element, and the equation is developed for Ema, the following equation (7) is given.

In the case of Z ^-1 = 1, that is, ω = 0 in the formula (7), the formula (7) is as shown in the following formula (8a), and in the formula (7) when Z ^-1 = -1, that is, ω = π The above formula (7) is as shown in the following formula (8b).

From the equations (8a) and (8b), the characteristics of the high pass filter can be seen, and as Ema has a value close to 1, the bandwidth increases. Accordingly, the frequency band control coefficient determiner 200 may increase the frequency bandwidth by determining the frequency band control coefficient Ema such that the gain of the highest frequency of the signal u _n output from the adder 4 is 1. In the present invention, in order to determine the frequency band control coefficient Ema so that the gain of the highest frequency is 1, the frequency band control coefficient determination unit 200 divides the gain of the high frequency component signal un by 1/2 ⁿ times, and divides the gain. A high frequency component signal having _n and a high frequency component signal u _n applied directly from the low pass filter 100 are added.

The signal u _n having the increased bandwidth by the frequency band control coefficient determiner 200 is applied to the gain control coefficient determiner 300. On the other hand, to determine the gain control coefficient Emb, it is necessary to determine that the gain of the highest frequency meets the specification of 1. An example of the relationship between the gain control coefficient Emb according to the specification that the gain of the highest frequency is 1 and the high frequency component signal u _n of the input signal is shown in FIG. 3.

Since the gain of the highest frequency is determined to be 1 by the frequency band control coefficient determiner 200, the gain control coefficient determiner 300 does not need to emphasize the gain again for the highest frequency. However, for a signal having a gain of 1 or less, it is necessary to multiply the gain control coefficient Emb as shown in FIG. In the above specification, the relationship between the gain control coefficient Emb and the high frequency component signal u _n of the input signal is nonlinearly determined as shown in FIG. 3, and thus, it is necessary to implement the ROM Emb 30. That is, since it is necessary to multiply a predetermined gain control coefficient according to the gain of the applied signal when the high frequency component signal un is applied, the gain control coefficient corresponding to the high frequency component signal u _n is stored in the ROM Emb 30 in advance. There is a need. Given the same specification as in FIG. 3, the gain control coefficient Emb for a signal between 0.4 and 0.9 is It can be optimized by the slope of.

The gain control coefficient determination unit 300 as described above is composed of a ROM Emb (30) and a mixer (32). Accordingly, the signal u _n having the increased bandwidth applied to the gain control coefficient determiner 300 is multiplied by the gain control coefficient according to the specification given by the ROM Emb 30, and then output to the mixer 32. Therefore, the signal u _n having the increased bandwidth applied to the gain control coefficient determiner 300 is directly applied to the mixer 32. Therefore, the signal output from the gain control coefficient determiner 300 is output as a signal Embu _n having an increased bandwidth and an enhanced gain. And outputs to the output terminal (9) and then adding the input signal xn is applied directly from the signal Embu _n adder 8 is the signal having increased bandwidth and gain highlighted Embu _n and an input terminal (1) receiving the application.

4 shows a digital nonlinear de-emphasis device according to the present invention.

The signal y _n input from the hysteresis stage 1 is applied to the adder 8 and the high pass filter 100. The high pass filter 100 outputs only the high frequency component of the applied input signal y _{n as} a signal u _n .

In the digital non-linear de-emphasis device including the above configuration, the frequency band control coefficient Dema and the gain control coefficient Demb are as shown in Equations 5 (a) and 5 (b). The high frequency component signal U _n of the input signal y _n is represented by the following Equation (9).

FIG. 5A is a diagram showing the relationship between the high frequency component signal U _n of the input signal and the frequency band control coefficient Dema in the digital nonlinear de-emphasis apparatus. As shown in FIG. 5 (a), the frequency band control coefficient Dema has a linear functional relationship with the high frequency component signal U _n of the input signal. Accordingly, it can be seen that the minimum and maximum values of the frequency band control coefficient Dema of the digital nonlinear de-emphasis device are represented by equations (10a) and (10b) of Figs. 5 (a) and (5a). Can be.

Therefore, in the digital nonlinear de-emphasis device, the frequency band control coefficient Dema can be obtained from the following equation (11).

On the other hand, in the digital nonlinear de-emphasis apparatus, a diagram showing the relationship between the high frequency component signal U _n of the input signal and the gain control coefficient Demb is shown in FIG. 5 (b). As shown in FIG. 5 (b), the gain control coefficient Demb has a linear functional relationship with respect to the high frequency component signal U _n of the input signal. Accordingly, it is understood that the minimum and maximum values of the gain control coefficient Demb of the digital nonlinear de-emphasis device are represented by the following equations (12a) and (12b) from FIG. 5 (b) and equation (5b). Can be.

Therefore, in the digital nonlinear de-emphasis device, the gain control coefficient Demb can be obtained from the following equation (13).

In equation (13), the gain control coefficient Demb has a substantially negative sign. However, it is not a big problem for the gain control coefficient Demb having a negative sign by subtracting it from the original input signal at the last stage of the digital nonlinear de-emphasis device.

Hereinafter, a frequency band control coefficient determiner and a gain control coefficient determiner for obtaining frequency band control coefficients and gain control coefficients of the digital nonlinear de-emphasis apparatus represented by Equations (11) and (13) will be described. Since the frequency band control coefficient and the gain control coefficient of the digital nonlinear de-emphasis device as described above hardly change according to the value of the high frequency component signal, the value can be obtained by obtaining a slope. However, since the gain control coefficient of the digital nonlinear pre-emphasis device is very sensitive to the value of the high frequency component signal, the gain control coefficient determination part of the digital nonlinear pre-emphasis device is composed of ROM.

The frequency band control coefficient determination unit 400 includes a Dema slope determination unit 42 that determines a slope of the high frequency component signal U _n , and a maximum of a slope determined by the Dema slope determination unit 42 and a preset frequency bandwidth control coefficient. An adder 40 for adding the value Dema _max and outputting the frequency band control coefficient to the high pass filter 100 by mixing the frequency band control coefficient output from the adder 40 with the high frequency component signal U _n . It consists of a mixer 44.

The high pass filter 100 receives a signal y _n from the input terminal 1 and passes only signal components of a predetermined frequency or more among the signals y _n . Accordingly, the high frequency component signal U _n of the input signal y _n output from the high pass filter 100 is applied to the Dema slope determination unit 42 of the frequency band control coefficient determiner 400. Dema inclination determination section 42 determines the inclination corresponding to the input signal U _n . The slope at this time is as described in equation (11) above. to be. As described above, the slope is applied to the adder 40. At this time, the adder 40 receives the maximum value Dema _max of the frequency band control coefficient at the same time in the preset digital nonlinear de-emphasis device. Accordingly, the adder 40 determines the frequency band control coefficient from the input signal U _n . The frequency band control coefficient determined as in Equation (11) above is mixed with the high frequency component signal U _n in the mixer 44 and fed back to the high pass filter 100. Accordingly, the signal U _n is multiplied by the predetermined frequency band control coefficient in the frequency band control coefficient determination unit 400 and applied to the gain control coefficient egg field 500. At this time, the signal U _n applied to the gain control coefficient determiner 500 has an increased bandwidth.

The gain control coefficient determination unit 500 includes a demb slope determination unit 50 for determining a slope of the gain control coefficient in order to multiply the high frequency component signal U _n with a gain control coefficient, and a slope determined by the demb slope determination unit 50. And an adder 52 for adding the maximum value Dema _max of the preset gain control coefficient and outputting it as a gain control coefficient, and a mixer 54 for mixing the gain control coefficient output from the adder 52 with the high frequency component signal U _n . It is composed of

According to the above configuration, the high frequency component signal U _n having the bandwidth of the increased frequency is applied to the Demb slope determination unit 50 of the gain control coefficient determiner 500. Dema slope determination unit 50 determines the slope of the gain control coefficient corresponding to the input signal U _n . The slope at this time is as described in equation (13) above. to be.

The signal whose slope is determined as described above is applied to the adder 52. At this time, the adder 52 is simultaneously supplied with the maximum value Demb _max of the gain control coefficient in the digital nonlinear de-emphasis device set in advance, and outputs the gain control coefficient Demb. The gain control coefficient Demb output from the adder 52 is mixed with the high frequency component signal U _n in the mixer 54. Accordingly, the gain control coefficient determiner 500 multiplies the signal Un having the increased bandwidth by the gain control coefficient Demb and outputs the signal DembU _n to the adder 8.

In addition, an input signal y _n is directly applied to the adder 8 from the input terminal 1. Accordingly, the adder 8 adds the signal DembU _n having the increased bandwidth and the enhanced gain and the input signal y _n and outputs the signal x _n to the output terminal 9. Thus, the signal output to the output 9 has increased bandwidth and enhanced gain.

6 schematically shows a digital nonlinear pre-emphasis / de-emphasis device according to the present invention.

Digital nonlinear pre-emphasis and de-emphasis devices, as substantially shown in FIGS. 2 and 4, are used in recording / reproducing video signals such as video tape recorders. At this time, the selection of the digital nonlinear pre-emphasis and de-emphasis device is selected according to the recording and reproducing mode of the video signal.

Since the digital nonlinear pre-emphasis device is required in the recording mode of the video signal, the first frequency band control coefficient determiner 200 and the first gain control coefficient determiner 300 should be selected. In addition, since the digital nonlinear de-emphasis device is required in the reproduction mode of the video signal, the second frequency band control coefficient determiner 400 and the second gain control coefficient determiner 500 should be selected. The signal for selecting the recording and reproducing mode of the video signal as described above is the switching signal 10. If the switching signal 10 is a signal for selecting a recording mode of the video signal, the switching signal 10 switches 12 to select the first frequency band control coefficient determination unit 200 and the first gain control coefficient determination unit 300. , 14). On the other hand, if the switching signal 10 is a signal for selecting a reproduction mode of the video signal, the switching signal 10 switches 12 to select the second frequency band control coefficient determiner 400 and the second gain control coefficient determiner 500. , 14).

The first and second frequency band control coefficient determination units 200 and 400 and the first and second gain control coefficient determination units 300 and 500 briefly show respective determination units as shown in FIGS. 2 and 4. The details of each decision part are the same as those shown in Figs. 2 and 4, and the signal flows of the input and output are also the same.

Accordingly, a digital nonlinear pre-emphasis / de-emphasis device can be implemented in one video signal processing device.

As described above, the final output signals of the digital nonlinear pre-emphasis and de-emphasis apparatus have increased bandwidth and enhanced gain, thereby suppressing a video signal of a noise component having a small amplitude, and having a large amplitude. The distortion of the waveform with respect to the signal component can be effectively suppressed. Since the digital nonlinear pre-emphasis and de-emphasis device can be implemented with only one ROM, the area occupied by the ROM in the design of an integrated device can be reduced, and economical benefits can be realized. There is an advantage that the frequency control coefficient and the gain control coefficient can be obtained more specifically by using the slope which hardly changes according to the value of the signal.

Claims (14)

A digital nonlinear pre-emphasis apparatus comprising: high pass filtering means for passing only a high frequency component signal of a predetermined frequency band or more from a predetermined input signal, and the high frequency component for changing a frequency band of a signal passing through the high pass filtering means; Determining a frequency band control coefficient by multiplying the high frequency component signal by a predetermined frequency band control coefficient such that the gain for the highest frequency of the signal is 1, and then feeding the high frequency component signal multiplied by the frequency band control coefficient to the high pass filtering means. Means; a gain control coefficient determining means for multiplying the high frequency component signal by a predetermined gain control coefficient; and digital means for adding and outputting the high frequency component signal multiplied by the gain control coefficient and the input signal. Pre-emphasis Device. 2. The apparatus of claim 1, wherein the frequency band control coefficient determining means comprises: gain dividing means for dividing a gain of the high frequency component signal applied from the high pass filtering means by a predetermined amount, a high frequency component signal having the divided gain, and the high frequency component; A digital nonlinear pre-emphasis circuit comprising: an adding means for adding component signals. 3. The apparatus of claim 2, wherein the gain control coefficient determining means comprises: storage means for generating a preset gain control coefficient corresponding to the high frequency component signal applied from the high pass filtering means; A digital non-linear pre-emphasis device, characterized by comprising arcing means for mixing with component signals. 4. The apparatus of claim 3, wherein the high pass filtering means comprises: first delay means for delaying the input signal for a predetermined sampling period, subtracting means for subtracting the input signal delayed by the first delay means from the input signal; Second delay means for delaying the signal returned from the frequency band control coefficient determining means for a predetermined sampling period, a signal output from the subtraction means and a feedback signal output from the second delay means are added to each other; A digital non-linear pre-emphasis device, characterized in that it comprises an addition means for outputting only signals of a predetermined frequency band or more. A digital nonlinear de-emphasis apparatus comprising: high pass filtering means for passing only a high frequency component signal of a predetermined frequency band or more from a predetermined input signal, a slope of the high frequency component signal, and a frequency band control coefficient from the determined slope And a frequency band control coefficient determination means for mixing the high frequency component signal with the determined frequency band control coefficient and outputting the frequency band control coefficient to the high pass filtering means, and determining the slope of the high frequency component signal. A gain control coefficient determination means for determining a gain control coefficient from the high frequency component signal, and adding means for adding and outputting a signal output from the gain control coefficient determination means and the input signal; Digital, characterized in that consisting of Nonlinear De-Emphasis Device. 6. The frequency band control coefficient determination means according to claim 5, wherein the frequency band control coefficient determination means includes: frequency band control coefficient slope determination means for determining a slope from the high frequency component signal, and a maximum of the determined frequency band control coefficient slope and a preset frequency band control coefficient; And digital means for adding a value, and mixing means for mixing the frequency band control coefficient outputted from said adding means into said high frequency component signal. The method of claim 6, wherein the gain control coefficient determination means comprises: a gain control coefficient slope determination means for determining a slope from the high frequency component signal, and a maximum value of the determined gain control coefficient slope and a preset gain control coefficient And an addition means for outputting a gain control coefficient and a mixing means for mixing the gain control coefficient outputted from the adding means with the high frequency component signal. 8. The apparatus of claim 7, wherein the high pass filtering means comprises: first delay means for delaying the input signal for a predetermined sampling period, subtracting means for subtracting the input signal delayed by the first delay means from the input signal; And a second delay means for delaying the signal returned from the frequency band control coefficient determination means for a predetermined sampling period, a signal output from the subtraction means, and a feedback signal output from the second delay means. A digital non-linear pre-emphasis device comprising: an adding means for outputting only a signal of a frequency band or more. A digital nonlinear nonlinear pre-emphasis / de-emphasis device comprising: high-pass filtering means for passing only a high frequency component signal u _n or U _n of a predetermined frequency band of an input signal x _n applied from an input terminal, and the high frequency component; First frequency band control coefficient determining means for multiplying the high frequency component signal u _n by the frequency band control coefficient Ema such that the gain for the highest frequency of the signal u _n is 1 and then returning the signal Emau _n to the high pass filtering means; , to determine the slope from the the high frequency component signals U _n, and the one from the determined slope determines the frequency band control coefficient Dema, mixing a predetermined band control coefficient Dema wherein the high frequency component signal U _n after the signal DemaU second frequency band control coefficient determining means for returning _n to the high pass filtering means, and Group a first frequency band, the control factor determination means and the second frequency band control factor determination in the first switching means and the high frequency component signal u _n by selecting one of sinhojung output from the means for the high-band feedback to pass filtering means predetermined A first gain control coefficient determining means for multiplying a gain control coefficient Emb, a slope is determined from the high frequency component signal U _n , a gain control coefficient Dema is determined from the determined slope, and the high frequency component signal U _n Second gain control coefficient determination means for mixing the determined gain control coefficient Demb, second switching means for selecting one of signals output from the first and second gain control coefficient determination coefficients, and the input signal x _n and Digital non-linear pre-emphasis, characterized in that it comprises an adding means for adding an output signal selected by said second switching means. / De-emphasis apparatus. 10. The high frequency component signal according to claim 9, wherein the first frequency band control coefficient determining means comprises dividing means for dividing a gain of the high frequency nebula signal u _n applied from the high pass filtering means by a predetermined amount; Digital nonlinear pre-emphasis / de-emphasis device, characterized in that it comprises an adding means for adding the high frequency component signal u _n . 11. The apparatus of claim 10, wherein the first gain control coefficient determining means comprises: storage means for generating a preset gain control coefficient Emb corresponding to the gain of the high frequency component signal u _n applied from the high pass filtering means; And digital means for adding the generated gain control coefficient Emb to the component signal un. 12. The method of claim 11, wherein the second frequency band control coefficient determination means comprises: frequency band control coefficient slope determination means for discriminating a slope from the high frequency component signal U _n as shown in Equation (1) below; Mixing means for adding a coefficient slope and a maximum value Dema _max of a predetermined frequency bandwidth control coefficient, and mixing the frequency band control coefficient Dema such as the following equation (2) output from the adding means with the high frequency component signal U _n; Digital non-linear pre-emphasis / de-emphasis device, characterized in that consisting of means. 13. The method of claim 12, wherein the second gain control coefficient determination means comprises: gain control coefficient slope determination means for determining an inclination from the high frequency component signal U _n as shown in Equation (3), and the determined gain control coefficient slope and Mixing means for adding the maximum value Demb _max of the preset gain control coefficient and outputting the gain control coefficient as a gain control coefficient, and mixing means for mixing the gain control coefficient Demb outputted from the adding means with the high frequency component signal; Digital non-linear pre-emphasis / de-emphasis device, characterized in that consisting of. 10. The apparatus of claim 9, wherein the high pass filtering means comprises: first delay means for delaying an input signal x _n for a predetermined sampling period k, and an input signal x _nk delayed by the first delay means from the input signal x _n . A subtraction means for subtracting the signal, second delay means for delaying the signal Emau _n or DemaU _n fed back from the first or second frequency band control coefficient determining means for a predetermined sampling period for k, and from the subtraction means. The high frequency component signal u _n = x _n -x _nk + Emau _nk or U _n = x _n -x _nk + DemaU by adding the output signal x _nk and the feedback signal Emau _nk or DemaU _nk output from the second delay means. A digital non-linear pre-emphasis / de-emphasis device, characterized in that it comprises an addition means for outputting to _nk .