KR0157897B1 - Digital notch filter - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital notch filter. In the related art, since the position of the color carrier is different for each transmission method, there is a problem in that the color signal is removed by implementing the respective filter. In order to improve this point, the present invention has a floating trap characteristic according to each method for NTSC, PAL, and SECAM methods having different color subcarriers, and there is no color signal for S-VHS signal, so only gain is obtained. Invented to adjust, the present invention can remove the color signal by adjusting the trap position by adjusting the position adjustment variable (α) value for the video signal method of NTSC, PAL, SECAM having a color subcarrier at different frequencies, respectively. In addition, it is possible to adjust the basic gain in processing the luminance signal according to the adjustment of the gain adjustment variable β.

Description

Digital Notch Filter

1 is a frequency characteristic curve according to the conventional color signal removal.

2 is a frequency characteristic curve of a digital notch filter of the present invention.

3 is a characteristic curve of trap frequency according to frequency position adjustment.

4 is a block diagram of a digital notch filter of the present invention.

* Explanation of symbols for main parts of the drawings

101,104,108: Amplifiers 102,103,105,106: Delays

107, 109: multiplexer 110, 111: adder

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to color signal removal technology, and more particularly, to a digital notch filter that can remove color code arc components by having a flexible trap characteristic for different broadcasting schemes in a TV.

In general, a color signal component is not included in a black and white television signal or an S-VHS signal, but a color signal component is included in a color system.

In addition, there are NTSC, PAL, and SECAM methods for transmitting the color difference signals according to the color scheme.

The NTSC system transmits an I, Q full color signal by amplitude modulating a 3.579545 MHz color carrier with orthogonal and π / 2 phase modulation.

In the PAL scheme, color polarity signals R-Y and B-Y are inverted in polarity of color carriers for each scan line with respect to R-Y, and amplitude-modulated 4.433618 MHz color carriers are transmitted by orthogonal and π / 2 phase modulation.

The SECAM method modulates the color difference signals RY (D _R ) and BY (D _B ) into two different color subcarriers (f _OR = 4.40625MHz and f _OB = 4.25MHz) and transmits them in a linear sequential manner. .

Accordingly, the color TV extracts the color difference signal from the video signal transmitted by the corresponding transmission method and reproduces the color signal.

In this case, when the color carrier is loaded on the luminance signal, a change in luminance of a point occurs and appears as noise in the reproduced image.

In order to reduce this noise, each transmission system needs to remove the color signal component contained in the color carrier, and attenuates 15 to 16dB or more for the low range.

That is, the NTSC method uses a notch filter that forms a color signal trap frequency characteristic at a frequency of 3.579545 MHz as shown in FIG. 1 (1), and 4.4361 MHz as shown in FIG. 1 (2) in the PAL method. A Notch filter is used to form the color signal trap frequency characteristic at the frequency of.

In addition, in the SECAM method, an accurate trap is not formed due to a fixed frequency characteristic, and two different color subcarriers f _OR and f _OB exist as shown in FIG. 3 (3.286 MHz). Use a bell-shaped filter with the center in place.

Therefore, conventionally, the inconvenience of having to remove the color signal by implementing each filter for each transmission scheme.

The present invention has a dynamic trap characteristic according to each method for NTSC, PAL and SECAM with different color subcarriers, and no gain for S-VHS signal because there is no color signal. The purpose is to provide a digital Notch filter that can be created to control only the bay.

As shown in FIG. 4, the digital notch filter of the present invention includes an amplifier 101 (104) (amplifying a video input signal with a predetermined gain (β / 2) (α) (β / 2), respectively. 108, delayers 102 and 103 for sequentially delaying the output of the amplifier 101, delayers 105 and 106 for sequentially delaying the output of the amplifier 104, and a control signal. A multiplexer 107 for selecting the output of the delayer 105 when trapping by S ₀ and an output of the delayer 103 when not trapping, and a control signal S ₁ . A multiplexer 109 for selecting the output of the amplifier 108 when trapping by and a selector for the output of the delayer 106 when not trapping, and an output of the multiplexer 109 and the delayer ( An adder 110 for summing the outputs of 103, the output of the adder 110 and the output of the multiplexer 107 to add color; It constitutes the signal is removed to the adder 111 for outputting.

Referring to the operation and effect of the present invention configured in this way in detail as follows.

In the present invention, the gain of the variable α and the low range for adjusting the trapped position according to each video signal system in order to obtain a frequency characteristic for forming an accurate trap at the color subcarrier position in the video signal system of NTSC, PAL, SECAM A variable (β) was set for controlling.

First, the amplitude characteristic of FIG. 1 can be represented by Equation (1), and the trap position other than the position adjustment variable (α) becomes as Equation (2) by setting Equation (1) to zero.

In this case, in accordance with the CCIR 601 recommendation, the sampling frequency is 13.5 MHz in each method, and the gain gain (β) is 2 to compensate the gain in the low range (ω) by about 6 dB. and the relationship of the frequency trapped in accordance with the position adjustment variable α is shown in FIG.

That is, FIG. 3 shows frequency characteristics at which color carriers are trapped in the PAL scheme, and FIG. 3 (d) shows frequency characteristics at which color carriers are trapped in the NPSC scheme.

3 (2) and (3) show trap frequency characteristics for color carriers of D _R (RY) and D _B (BY) transmitted in a serial sequence in the SECAM method, respectively.

Therefore, if the gain adjustment variable β is 2, the value of the position adjustment variable α when forming a trap in the color subcarriers of each signaling method is as follows.

PAL method: α = 0.946018 ..., f _trap = 4.43362MHz

SECAM scheme: D _R (RY); α = 0.923497 ..., f _trap = 4.40625 MHz

D _B (BY); α = 0.792159 ..., f _trap = 4.25 MHz

NTSC method: α = 0.90111 ..., f _trap = 3.57954MHz

In this case, the impulse response to the amplitude characteristics of Equation (1) is as shown in Equation (3) and the transfer function is as in Equation (4).

The impulse response to Equation (3) is obtained as shown in Table 5 below.

And, by moving by the predetermined time (T) on the time axis to the formula (4) in order to satisfy the causality of the filter that is, by multiplying the z ^-1 shown in Expression (5).

In addition, since the transfer function for the S-VHS signal does not include a color signal, only the delay is adjusted without amplifying the high range.

That is, only amplification is performed to a magnitude corresponding to the DC gain when operating as a trap filter to match the output range of the luminance signal during luminance signal processing.

However, the actual digital filter expresses a numerical value by finite field unlike a mathematically interpreted one due to the finiteness of the word length of a microprocessor, signal processor, arithmetic circuit, or memory applied to a system. Characteristic degradation due to truncation or rounding occurs, one of which is an error in the filter output due to quantization of the filter coefficients.

In other words, in performing digital signal processing, quantization error is inevitable, and when implementing a digital filter having a finite length field, coefficients must be quantized within an allowable range of the error.

Therefore, the magnitude of the error due to the coefficient quantization is obtained from the statistical method as obtained from the factor of the coefficient quantization bit number and the filter order as shown in Equation (7) (8), and the coefficient quantization bit required for the maximum allowable error. The number B can be obtained.

For example, if the gain control variable (β) is 2, the value of the PAL position adjustment variable (α) is (0.946018) 10 in decimal and only (0.1111 0010 0010 ...) ₂ in _binary . , The order of the filter is 3 in equation (5) (6).

Also, in Equation (7), if the magnitude of | E (ω) | is 0.001, that is, if the magnitude of the frequency response indicated by the coefficient quantization is allowed to be up to -60 dB, the coefficient quantization bit number B has a value of about 9.966. .

And, coefficient α (β) should be quantized to at least 10 bits.

Thus, in the case of decimal numbers, the value of (α) with (0.946018 ...) ₁₀ uses 10-bit binary value (0.1111001000) ₂ , and the error due to coefficient quantization at that time is less than 0.001 (or -60dB). do.

The values of the position control variable α and the gain control variable β expressed in binary from the coefficient quantization may be selected using a multiplexer or the like.

The present invention having the above characteristics is as shown in FIG. 4 when the transfer function of Equation (5) (6) is implemented as a circuit.

When the composite video signal (CVBS) including the color signal or the S-VHS signal not including the color signal is input to the filter of the present invention, the amplifiers 101 and 108 are amplified by an arbitrary gain (β / 2) and the amplifier 104 is applied. Is amplified by an arbitrary gain α).

The gain adjustment variable β is used to adjust the gain in the low range required in the luminance signal processing, and the position adjustment variable α is a variable for adjusting the position of the trap frequency.

In this case, the output signal of the amplifier 101 is sequentially delayed through the delayers 102 and 103 and then output to the multiplexer 107 and the adder 110, and the output signal of the amplifier 104 is delayed 105. It is sequentially delayed at 106 and then output to the multiplexer 109.

The output signal of the delay unit 105 is output to the multiplexer 107 and the output signal of the amplifier 108 is output to the multiplexer 109.

Accordingly, each of the multiplexers 107 and 109 distinguishes whether an input signal is a composite video signal CVBS or an S-VHS signal according to each control signal S0 and S1, thereby trapping a color signal for trapping. Will be determined.

When the multiplexer 107 selects the output signal of the delay unit 105 by the control signal S0 and the multiplexer 109 selects the output signal of the amplifier 108 by the control signal S1, trap processing is performed. In this case, the adder 110 adds the output of the delayer 103 and the output of the multiplexer 109, and the adder 111 adds the output of the multiplexer 107 to the sum value.

The transfer function by this operation is shown in equation (5).

That is, the value of the gain control variable β has a fixed value according to the required gain in the low range, and the value of the position adjustment variable α has color subcarriers at different positions if it is adjusted according to the video signal method. The color signal removing operation is performed according to the video signal method.

Therefore, the output signal of the adder 111 outputs only the luminance signal component due to the sudden attenuation characteristic in the color carrier which is designated according to the value of the position adjustment variable α in each signal system.

When the multiplexer 107 selects the output of the delayer 103 by the control signal S0 and the multiplexer 109 selects the output of the delayer 106 by the control signal S1, the trap processing is performed. If not, the adder 110 sums the output of the delayer 103 and the output of the multiplexer 109 and adds the output of the multiplexer 107 to the DC gain by adding the output of the delayer 103. By performing only amplification with a corresponding magnitude, the output range of the luminance signal is matched.

The transfer function by this operation is shown in equation (6).

As a result, by setting the basic gain (β) at the low end and obtaining the variable (α) at the trap position from Equation (2), the frequency characteristic of forming a trap at an arbitrary frequency can be obtained. Therefore, NTSC, PAL, It is possible to adjust the position of the trap frequency and the basic gain in the low range for each SECAM video signal and S-VHS signal.

As described in detail above, the present invention can remove the color signal by adjusting the trap position by adjusting the position adjustment variable (α) for the video signal method of NTSC, PAL, and SECAM having color subcarriers at different frequencies. In addition, it is possible to adjust the basic gain in processing the luminance signal according to the adjustment of the gain adjustment variable β.

Therefore, the present invention can be applied to a circuit that separates a luminance signal by removing a color signal from a composite video signal in each signal method in a video device such as digital or computer.

Claims (4)

First to third amplifiers for amplifying the video input signal with an arbitrary gain, first and second delayers for sequentially delaying the output of the first amplifier, and third for sequentially delaying the output of the second amplifier. A fourth multiplexer for selecting one of the outputs of the second delayer and the third delayer according to the fourth delayer, the control signal S0, and the fourth delayer and the third amplifier according to the control signal S1. A second multiplexer for selecting one of the outputs, a first adder for summing up the output of the second multiplexer and the output of the second delayer, and a summing up output of the first adder and the output of the first multiplexer; Digital notch filter characterized by consisting of two adders. The digital notch filter according to claim 1, wherein the first and third amplifiers have the same gain (β / 2). 2. The digital notch filter as claimed in claim 1, wherein the second amplifier has a position adjustment variable [alpha] as a gain. The method of claim 1, wherein the first and second multiplexers are configured to select the outputs of the third delayer and the third amplifier separately in the case of trap processing, and to respectively select the outputs of the second and fourth delayers in the case of non-trap processing. Digital notch filter, characterized in that configured to have the transfer function as follows.