KR100256449B1 - Method for rejecting ntsc interference for using 3 step notch filter and a ntsc interference rejection filter circuit for reproming the same - Google Patents

Abstract

PURPOSE: A method for removing an NTSC interference using a three-stage notch filter and an NTSC interference removal filter circuit using the three-stage notch filter are provided to reduce the size of a system by efficiently removing an NTSC component including a visual career, a chrominance subcareer and an aural career of an analog signal in case of a ground wave digital television receipt. CONSTITUTION: An NTSC removal unit(100) is composed of a delay device(110), the first three-stage notch filter(120) and the second three-stage notch filter(130). The first energy generation unit(200) is composed of the first summing device(210), the first square root device(220) and the first integration device(230). The second energy generation unit(300) is composed of the second summing device(310), the second square root device(320) and the second integration device(330). An energy detector(400) receives the first energy(231) and the second energy(331), and provides a select signal(301) detected to an output unit(500). The output unit(500) is composed of a MUX(510).

Description

NTSC Interference Rejection Using Three Step Notch Filter and NTSC Interference Rejection Filter Circuit Using Three Step Notch Filter

The present invention relates to a method for removing NTSC interference using a three stage notch filter and an NTSC interference cancellation filter circuit using a three stage notch filter for performing the same.

One channel of the television uses the 6 MHz band, and there are three NTSC components in the 6 MHz band. subcar eer), which is located behind the 4.5MHz Aural career, and there are 7 null signals in the 6MHz channel band. The null signal has a periodic null every 57 * f _H , the NTSC video carrier is present on the second null, the NTSC luminance subcarrier is located on the sixth null, and the NTSC audio carrier is located on the seventh null.

1 is a circuit diagram showing an NTSC interference cancellation filter using a conventional comb filter.

In the conventional NTSC interference cancellation filter circuit using a comb filter, as shown in FIG. 1, the first NTSC removal filter unit 10, the second NTSC removal filter unit 20, and the first energy generation unit 30 are shown. ), A second energy generator 40, a minimum energy detector 50, and a mux 60.

The first NTSC rejection filter unit 10 includes a first retarder 11 and a first summer 13.

The first delay unit 11 receives the received I-channel data symbol 3, which is a real data portion of the A / D-converted VSB (Vest gaial Sideband) signal at the tuner, and delays by 12 symbols. The one delayed signal 12 is provided to the first summer 13.

The first summer 13 receives the received I-channel data symbol 3 and the first delayed signal 12 and adds the received I-channel jitter symbol 3 to the first delayed signal ( 12) is subtracted to remove the portion with null frequency to provide a VSB signal 14 from which analog NTSC components have been removed.

The second NTSC removal filter unit 20 includes a second delay unit 21 and a second summer 23.

The second delayer 21 mixes the PN511 and PN63 signals with general data at the transmitting end, so that the data field synchronization reference pattern 6, which is a signal generated by the PN511 and PN63 generators (not shown), is used to synchronize the signals. The signal is delayed by 12 symbols to provide the second delayed signal 22 to the second summer 23.

The second summer 23 receives the data field synchronization reference pattern 6 and the second delayed signal 22, adds the data field synchronization reference pattern 6, and subtracts the second delayed signal 22. The second summation removes the portion having the null frequency to provide the signal 24 from which the NTSC component has been removed.

The first energy generation unit 30 is composed of a third summer 31, a first multiplier 33 and the first integrator 35.

The third summer 31 receives the received one-channel data symbol 3 and the data field synchronization reference pattern 6, sums the received I-channel data symbol 3, and adds the data field synchronization reference pattern ( Subtract 6) to provide the summed signal 32 of the first energy generator 30 to the first multiplier 33.

The first multiplier 33 receives the sum signal 32 of the first energy generating unit and generates a first power 34 by squaring a first voltage having a magnitude and a phase to generate a first integrator 35. To provide.

The first integrator 35 provides a first energy signal 36 without the NTSC cancellation filter by inputting the first power 34 to integrate the power.

The second energy generator 40 includes a fourth summer 41, a second squarer 43, and a second integrator 45.

The fourth summer 41 receives the first summed signal 14 from which the NTSC component is removed and the second summed signal 24 from which the NTSC component is removed, and the second summated to remove the NTSC component. The sum signal 24 of the second energy generator 40 to the second multiplier 43 by subtracting the received signal 24 and summing the first summed signal 14 from which the NTSC component is removed. do.

The second multiplier 43 receives the sum signal 42 of the second energy generating unit 40 to generate a second power 44 by squaring a second voltage having a magnitude and a phase to generate a second power 44. Provided by integrator 45.

The second integrator 45 receives the second power 44 and integrates the second power to provide the second energy signal 46 from which the NTSC component has been removed.

The minimum energy detector 50 includes an energy signal 36 without the NTSC removal filter provided by the first energy generator 30 and an energy signal 46 from which the NTSC component provided by the second energy generator 40 has been removed. ), The minimum energy is detected, and the energy detected selection signal 51 is provided to the mux 60.

The mux 60 receives the energy detection selection signal 51 and receives the second energy signal 46 from which the NTSC component is removed is greater than the first energy signal 36 without passing through the NTSC removal filter. The output I channel data symbol 3 as it is, and when the second energy signal 46 from which the NTSC component is removed is smaller than the first energy signal 36 without passing through the NTSC removal filter, the analog NTSC component is removed. The VSB signal 63 is selectively output.

VSB (Vestigial Sideband) is a residual sideband, which does not completely remove one sideband like SSB (Single Side Band), but represents a signal that has left part of one sideband. An odd symmetrical signal.

However, the conventional comb filter may receive the received I channel data symbol 3 and the data field synchronization reference pattern 6 to obtain a waveform from which the analog NTSC components V, C, and A carriers are removed. There is a problem that even the digital components of the 1st, 3rd, 4th, 5th null parts of the frequency signal, that is, the round dotted lines, are removed.

2A to 2D are waveform diagrams showing the frequency spectrum of the NTSC interference cancellation filter using the comb filter.

FIG. 2A shows the positions of V, C, and A carriers, NTSC components, present in a bandwidth of 6 MHz per television channel, and a video carrier (V carrier) at a local band edge of 1.25 MHz, and a luminance subcarrier (C) at 3.5 MHz, respectively. Carrier), a voice carrier (A carrier) present at 4.5 MHz is located.

2B shows the frequency characteristics of a comb filter for filtering a frequency signal with a periodic null portion every 57 fH. When the NTSC horizontal line rate is fH, the null signal is a periodic null signal every 57 * f _H , where 7 null signals are located at a bandwidth of 6 MHz per television channel, and the NTSC components V, C, and A carriers are respectively It can be seen that the V carrier, which is an image carrier located in the second null portion, the C carrier, which is a luminance subcarrier present in the sixth null, and the A carrier, which is an audio carrier present in the seventh null portion, are positioned. However, NTSC elimination filtering using a comb filter removes V, C, A carriers, which are analog NTSC meals, and digital signals of the 1st, 3rd, 4th, and 5th null parts.

2C shows frequency characteristics with a bandwidth of 6 MHz of the digital broadcast signal.

2D is an enlarged waveform of frequency characteristics of the digital broadcasting shown in FIG. 2C. 2C and D of FIG. 2D indicate a desired signal, and an error occurs when the leading and trailing edges are large, and P, a synchronization signal for error recovery, corrects an error using a pilot carrier.

Therefore, in the NTSC interference cancellation filter circuit using the conventional comb filter, the size of the trellis decoder is very large in the trellis decoder at the rear of the whole system when using the D = 12 Symbols delay of the delay unit. In addition, due to the frequency characteristics of the comb filter, not only the analog NTSC component but also the digital signal component is removed.

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the prior art in view of the above, and a first object of the present invention includes a video carrier, a luminance subcarrier, and an audio carrier of an analog signal received together in terrestrial digital television reception. The present invention provides a method for removing NTSC interference using a three-stage notch filter for efficiently removing NTSC components.

A second object of the present invention is to provide an NTSC interference cancellation filter circuit using a three stage notch filter which is particularly suitable for carrying out the above method.

1 is a circuit diagram showing an NTSC interference cancellation filter using a conventional comb filter.

2A to 2D are waveform diagrams showing the frequency spectrum of the NTSC interference cancellation filter using the comb filter.

3 is a circuit diagram illustrating an NTSC interference cancellation filter using a three-stage notch filter according to an embodiment of the present invention.

4 is a waveform showing the frequency characteristic of a three-stage notch filter.

5 is an operation flowchart of an NTSC interference cancellation filter circuit using a three-stage notch filter according to the embodiment of FIG. 3.

* Explanation of symbols for main parts of the drawings

V: Visual career A: Aural Career

C: Chromaminance subcareer

D: 12 symbol delay

In order to realize the first object of the present invention described above, the present invention provides a signal delayed by 12 symbols by receiving a received I channel data symbol and a data field synchronization reference pattern signal, and a first three-stage notch filtered NTSC component. Providing the removed signal and a second three notch filtered signal to remove the NTSC component; (b) receiving the received I channel data symbol and the data field synchronization reference pattern signal to generate energy to provide a first energy; (C) receiving a signal from which the NTSC component is removed by the first three-stage notch filtering and the signal from which the NTSC component is removed by the second three-notch filtering and providing a second energy; (d) detecting the energy by receiving the first energy and the second energy and providing an energy detected selection signal; And (e) receiving an NTSC component including an image carrier, a luminance subcarrier, and an audio carrier by receiving the signal delayed by 12 symbols, the first 3-notch-filtered signal from which the NTSC component is removed, and the energy-detected selection signal. A method of eliminating NTSC interference using a three-stage notch filter, characterized in that the step of selectively outputting the VSB signal.

In order to achieve the second object of the present invention, the present invention is a signal delayed by 12 symbols by receiving the I channel data symbol and the data field synchronization reference pattern signal received from the input terminal, the first three-stage notch filtered NTSC An NTSC removal unit for providing a signal from which components have been removed and a second three-step notch filtered signal to remove NTSC components; A first energy generator configured to receive the received I channel data symbols and the data field synchronization reference pattern signal to generate energy to provide first energy; A second energy generation unit configured to generate energy by receiving a signal from which the first three-stage notch filtered NTSC component is removed and a signal from the second three-stage notched filtered NTSC component and provide second energy; An energy detector configured to detect the energy by receiving the first energy and the second energy and provide an energy detected selection signal; And receiving the 12-symbol delayed signal, the first 3-notch-filtered signal from which the NTSC component is removed, and the energy-detected selection signal, and removing the VSB signal from which the NTSC component including the video carrier, the luminance subcarrier, and the voice carrier are removed. It provides an NTSC interference cancellation filter circuit using a three-stage notch filter, characterized in that the step of selectively outputting.

According to the present invention, the structure of the trellis decoder is simplified by using an NTSC interference cancellation filter circuit using a three-stage notch filter, and the comb filter significantly prevents the removal of not only the NTSC component but also the digital broadcasting signal of the TV. It is possible to receive digital broadcast of much improved quality.

Therefore, in the terrestrial digital TV reception, the analog NTSC characteristics including the video carrier, the luminance subcarrier, and the audio carrier of the signals received together can be efficiently removed using a three-stage notch filter.

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

3 is a circuit diagram illustrating an NTSC interference cancellation filter using a three-stage notch filter according to an embodiment of the present invention.

The NTSC interference elimination filter circuit using the three-stage notch filter includes an NTSC removal unit 100, a first energy generation unit 200, a second energy generation unit 300, an energy detector 400, and an output unit 500. It is composed.

The NTSC remover 100 includes a delay unit 110, a first three stage notch filter 120, and a second three stage notch filter 130.

The delay unit 110 receives the I-channel data symbol 103 received from the input terminal 101, delays the signal, and provides the output unit 500 with a signal 111 delayed by 12 symbols.

The first third notch filter 120 receives the received I channel data symbol 1030 to remove the V, C, and A carriers, and removes the signal 121 from which the NTSC component is removed. Provided to the two energy unit 300 and the output unit 500.

The second third notch filter 130 receives the data field synchronization reference pattern signal 104 from the input terminal 102 to filter the second third notch to remove V, C, and A carriers, and to remove NTSC components. The signal 131 is provided to the second energy unit 300.

The first energy generator 200 includes a first summer 210, a first square root 220, and a first integrator 230.

The first summer 210 receives the received I channel data symbol 103 and the data field synchronization reference pattern signal 104, and adds the received I channel data symbol 103 to the data field synchronization reference. The pattern signal 104 is subtracted to provide the first summed and subtracted voltage signal 211 to the first square root 220.

The first square root 220 receives the first summed and subtracted voltage signal 211 and squares a voltage having a magnitude and a phase to convert the first square rooted power signal 221 to the first integrator 230. to provide.

The first integrator 230 receives the first square rooted power signal 221 and integrates power to provide a first energy 231 to the energy detector 400.

The second energy generator 300 includes a second summer 310, a second square root 320, and a second integrator 330.

The second summer 310 receives a signal 121 in which the NTSC component is removed by the first three-stage notch filtering and a signal 131 in which the NTSC component is removed by the second three-stage notch filtering. However, the second notch-filtered NTSC component is removed by summing the signals 121 and the second three-notch filtered NTSC component is removed by subtracting the second summed and subtracted voltage signal 311 to the second. Provided by the square root (320).

The second square root 320 receives the second summed and subtracted voltage signal 311 and squares a voltage having a magnitude and a phase to convert the second square root power signal 321 to the second integrator 320. to provide.

The second integrator 330 receives the second squared power signal 321 and integrates power to provide the second energy 331 to the energy detector 400.

The energy detector 400 receives the first energy 231 and the second energy 331, detects energy, and provides an energy detected selection signal 301 to the output unit 500.

The output unit 500 is composed of only the mux 510.

The mux 510 receives the 12-symbol delayed signal 111, the first 3-stage notch-filtered signal 121 having the NTSC component removed, and the energy-detected selection signal 301. If the first energy signal 231 is smaller than the first three-stage notch filtered second energy signal 331, the received I-channel data symbols delayed by the 12 symbols are output as it is, and the three-stage notch filter is applied. When the rough first energy signal 231 is greater than the first three notch filtered second energy signal 331, the first third notch filtered signal 121 may be selectively provided to remove the NTSC component, thereby providing V, The VSB signal 513 from which the NTSC components of the C and A carriers have been removed is output.

4 is a waveform showing the frequency characteristics of a three-stage notch filter, wherein three NTSC components exist in a 6 MHz television channel band, and the NTSC components are video carriers (V carriers) at a low band edge of 1.25 MHz, and the 1.25 MHz In the three-stage notch filter, three NTSC components, which are the luminance subcarriers (C carriers) located after 3.58 MHz at the frequency and the voice carriers (A carriers) located at 4.5 MHz at the 1, 25 MHz frequencies, are positioned. It can be seen that it is removed by the NTSC interference cancellation filter circuit used.

FIG. 5 is a flowchart illustrating an operating principle of an NTSC interference cancellation filter circuit using the three-stage notch filter shown in FIG. 3.

The I channel data symbol 103 received from the input terminal 101 is provided to the delay unit 110, the thirteenth stage notch filter 120, and the first summer 210, and the data field is synchronized from the input terminal 9102. The reference pattern signal 104 is received and provided to the second third notch filter 130 and the first summer 210. The received I channel data symbol 103 is inputted from the delay unit 110 to delay the signal to provide the signal 111 delayed by 12 symbols to the mux 510 (step S1).

The received I channel data symbol 103 and the data field synchronization reference pattern signal 104 are inputted from the first summer 210, and the received I channel data symbol 103 is summed and the data field synchronization reference pattern is summed. The signal 104 is subtracted to provide the first summed and subtracted voltage signal 211 to the first square root 220. The first summed and subtracted voltage signal 211 is input to provide a first square rooted power signal 221 to the first integrator 230 by square rooting a voltage having a magnitude and a phase (step S2).

The first square rooted power signal 221 is received and integrated in the first integrator 230 to provide the first energy 231 to the energy detector 400 (step S3).

A second summer 310 and a mux signal are received by receiving the received I channel data symbol 103 from the first three stage notch filter 120 and removing the NTSC component by removing the first three stage notch filter. 510). A second summer adder receives the data field synchronization reference pattern signal 104 from the input terminal 102 by the second three-stage notch filter 130 and performs a second three-notch filtering to remove the NTSC component. In step 310, it is provided (310).

The first three-stage notch-filtered signal 121 from which the NTSC component has been removed and the second three-stage notch-filtered signal 131 from which the NTSC component has been removed are received from the second summer 310. A second square root of the second summed and subtracted voltage signal 311 may be subtracted by subtracting the signal 121 notch filtered to remove the NTSC component and subtracting the second three stage notch filtered signal to remove the NTSC component. It is provided as a group (320). The second summed and subtracted voltage signal 311 is inputted from the second square root 320 to square root a voltage having a magnitude and a phase, thereby converting the second square rooted power signal 321 to the second integrator 320. to provide. The second square rooted power signal 321 is input from the second integrator 330 to integrate the power to provide the second energy 331 to the energy detector 400 (step S5).

The second square rooted power signal 321 is input from the second integrator 330 and integrated to provide a second energy 331 to the energy detector 400 (step S6).

The first energy 231 and the second energy 331 are input and the energy detector 400 detects energy to provide the energy detected selection signal 301 to the output unit 500 (step S7).

The signal 111 delayed by 12 symbols, the first three stage notch filtered signal 121 having the NTSC component removed, and the energy detected selection signal 301 are input from the mux 510, and the three stage notch filter is input. When the first non-energetic energy signal 231 is smaller than the first third notch filtered second energy signal 331, the received 12-channel delayed received I-channel data symbols are output as they are, and the third-level notch filter is passed through. When the first energy signal 231 is greater than the first three notch-filtered second energy signal 331, the first third notch-filtered signal 121 with the NTSC component removed is selectively output (step S8). ).

Accordingly, the VSB signal 513 from which the NTSC components of the V, C, and A carriers are removed from the mux 510 is outputted to the output terminal 530 (step S9).

As a result, the received I channel data symbol and data field synchronous interference pattern are measured at the input of the three stage notch filter, as shown in FIG. 3, and compared with each other to produce two error signals. Then, the two error signals of the voltage component provide power through the square root and convert them into energy through an integrator and input them to the energy detector to detect the minimum interference energy of the two signals and provide the energy detected selection signal to the mux 500. Therefore, since the MUX 500 may or may not have an NTSC component, the 12-signal delayed signal 111 and the first third notch-filtered carrier include V, C, and A carriers. The first energy signal 231 without the three-stage notch filter is input by receiving the signal 121 from which the NTSC component is removed and the energy detection selection signal 301, and the second energy signal with the first three notch filtering. If less than 331, the received first I-channel data symbols delayed by 12 symbols are output as it is, and the first energy signal 231 without the three-stage notch filter is the first three-stage notch filtered second energy signal 331. If larger, the first three-stage notch-filtered signal 121 selectively removes the NTSC component to output the VSB signal 513 from which the NTSC component of the V, C, and A carriers is removed.

Accordingly, by using the NTSC interference cancellation filter circuit using the three-stage notch filter, an analog including a video carrier, a luminance subcarrier, and an audio carrier received together in the terrestrial digital TV reception has a disadvantage in the frequency spectrum of the conventional comb filter. It not only eliminates NTSC component but also digital broadcasting signal of TV, and can receive digital broadcasting of much improved quality. Also, by simplifying the structure of trellis decoder behind equalizer, The cost can be reduced.

As described above, by using the NTSC interference cancellation filter circuit using the three-stage notch filter according to the present invention, the structure of the trellis decoder is simplified to reduce the amount of hardware of the entire system, and also has a disadvantage in the frequency spectrum of the comb filter. In other words, the digital broadcast signal of the TV as well as the NTSC component is significantly prevented, and thus, the digital broadcast of much improved quality can be received.

Although this invention was demonstrated concretely by the said Example, this invention is not restrict | limited by this, A deformation | transformation and improvement are possible within the normal knowledge of a person skilled in the art.

Claims (11)

(a) A signal delayed by 12 symbols after receiving the I channel data symbol and the data field synchronization reference pattern signal received from the input terminal, the first third notch filtered signal having the NTSC component removed, and the second third notched filtered NTSC Providing a signal from which components have been removed; (b) receiving the received I channel data symbol and the data field synchronization reference pattern signal to generate energy to provide a first energy; (c) receiving energy from the first third notch filtered signal to remove the NTSC component and the second third notched filtered signal from which the NTSC component is removed to generate energy to provide a second energy; (d) receiving the first energy and the second energy and detecting energy of each store to provide an energy detected selection signal; And (e) receiving a signal delayed by 12 symbols, a first 3-stage notch-filtered signal from which an NTSC component is removed, and an energy-detected selection signal, and a VSB from which an NTSC component including an image carrier, a luminance subcarrier, and an audio carrier are removed. And a method of selectively outputting a residual sideband signal. The method of claim 1, wherein the step (a) comprises: (a-1) receiving the received I channel data symbol and delaying by 12 symbols to provide a signal delayed by 12 symbols; (a-2) receiving the received I channel data symbol and providing a signal from which a first three stage notch filtering is performed to remove an NTSC component; And (a-3) receiving the data field synchronization reference pattern signal and providing a second third notch filtered signal to remove an NTSC component, thereby removing NTSC interference using a three-stage notch filter. Way. The method of claim 1, wherein the step (b) comprises: (b-1) receiving the received I channel data symbol and the data field synchronization reference pattern signal, summing the received I channel data symbols and adding the data field synchronization reference; Subtracting the pattern signal to provide a first summed and subtracted voltage signal; (b-2) receiving the first summed and subtracted voltage signals to provide a first square rooted power signal by square rooting the voltage; And (b-3) receiving the first square rooted power signal and integrating power to provide a first energy. 3. The method of claim 1, wherein the step (c) comprises: (c-1) receiving a signal from which the NTSC component is removed by the first three-stage notch filtering and a signal from which the NTSC component has been removed by the second three-notch filtering; Summing a first three notch filtered signal that has not yet been NTSC component removed and subtracting the second three notched filtered NTSC component to provide a second summed and subtracted voltage signal; (c-2) receiving the second summed and subtracted voltage signal to provide a second square rooted power signal by square rooting the voltage; And (c-3) receiving the second squared power signal to integrate power to provide a second energy, wherein the third step notch filter removes NTSC interference. The method of claim 1, wherein the step (e) comprises: (e-1) receiving a signal delayed by the 12 symbols, the first three-level notch-filtered signal from which the NTSC component is removed, and an energy-detected selection signal; Outputting the received I-channel data symbols as they are if the first energy signal that has not passed the notch filter is smaller than the three-stage notch filtered second energy signal; And (e-2) receiving the signal delayed by 12 symbols, the first 3-stage notch-filtered signal from which the NTSC component has been removed, and the energy-detected selection signal. However, the method of removing NTSC interference using a three-stage notch filter, characterized in that the step of selectively outputting the VSB signal from which the NTSC component has been removed when it is larger than the notch filtered second energy signal. 6. A video carrier (V carrier) as a second null signal having three NTSC components out of seven null frequency components with a 6 MHz band per television channel, a luminance subcarrier (C carrier) as a sixth null signal, and a seventh null. A method for removing NTSC interference using a three-stage notch filter, characterized by removing a voice carrier (A carrier) which is a signal. Signal 111 received from the I-channel data symbol 103 received from the input terminal 101 and the data field synchronization reference pattern signal 104 from the input terminal 102 delayed by 12 symbols, and the first three-level notch filtering An NTSC removal unit 100 for providing a signal 121 from which the NTSC component has been removed and a second three-stage notch filtered signal to remove the NTSC component; A first energy generator (2 00) for generating energy by receiving the received I-channel data symbol (103) and the data field synchronization reference pattern signal (104) to provide a first energy (231); The first three-stage filtered signal 121 from which the NTSC component has been removed and the second three-stage notched filtered signal 131 from which the NTSC component has been removed are generated to generate energy to provide the second energy 331. A second energy generator 300 for; An energy detector (400) for receiving the first energy (231) and the second energy (331) to detect energy and provide an energy detected selection signal (301); And a video carrier, a luminance subcarrier, and an audio carrier receiving a signal 111 delayed by 12 symbols, a signal 121 in which the first three-level notch-filtered NTSC component is removed, and an energy-detected selection signal 301. And an output unit (500) for selectively outputting a VSB signal (513) from which an NTSC component has been removed. The method of claim 7, wherein the NTSC remover 100 receives the I channel data symbol 103 received from the input terminal 101 and delays by 13 symbols to provide a signal 111 delayed by 12 symbols. Retarder 110 for; A first three-stage notch filter 120 for receiving the I-channel data symbol 103 received from the input terminal 101 and performing three-stage notch filtering to remove the NTSC component; And a second three-stage notch filtering 130 for receiving the data field synchronization reference pattern signal 102 from the input terminal 102 to provide three-stage notch filtering to remove the NTSC component. NTSC interference elimination filter circuit using a three-stage notch filter. The method of claim 7, wherein the first energy generator 200 receives the received I channel data symbol 103 and the data field synchronization reference pattern signal 104 to receive the received I channel data symbol 103. A first summer (210) for summing and subtracting the data field synchronization reference pattern signal (104) to provide a first summed and subtracted voltage signal (211); A first square root unit 220 for receiving the first summed and subtracted voltage signal 211 to provide a first square rooted power signal 221 by square rooting the voltage; And a first integrator 230 for receiving the first square rooted power signal 221 to integrate power to provide a first energy 231. Circuit. The signal generator of claim 7, wherein the second energy generator 300 includes a signal 121 in which the first three stage notch-filtered NTSC component is removed and a signal in which the second three stage notch-filtered NTSC component is removed ( 131, the first three-stage notch-filtered signal 121 from which the NTSC component has been removed is added, and the second three-stage notch-filtered signal 131 from which the NTSC component has been removed is subtracted. A second summer 310 for providing a voltage signal 311; A second square root unit 320 for receiving a second summed and subtracted voltage signal 3110 to provide a second square rooted power signal 321 by square rooting the voltage; and the second squared power signal 321 NTSC interference cancellation filter circuit using a three-stage notch filter, characterized in that consisting of a second integrator (330) for providing a second energy 331 by integrating the power received. The method of claim 7, wherein the output unit 500 includes a signal 111 delayed by 12 symbols, a signal 121 in which the first three-stage notch-filtered NTSC component is removed, and an energy-detected selection signal 301. NTSC interference cancellation filter using a three-stage notch filter comprising a mux 510 for selectively outputting a VSB signal 513 from which NTSC components including an image carrier, a luminance subcarrier, and an audio carrier are removed. Circuit.

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