JPH0799666A - Method and device for dividing digital signal data into classes and method and device for adaptive y/c separation - Google Patents

Abstract

PURPOSE:To improve the performance of separation of a color signal from signal data where a luminance signal Y and the color signal C are multiplexed with respect to frequency. CONSTITUTION:A class dividing part 3 divides input digital signal data into blocks and divides respective blocks by classes, and signal data divided into classes and the signal having a prescribed numerical value obtained by converting the patern of this signal data divided into classes are supplied to a class-classified adaptive filter processing part 4. This part 4 reads out a filter coefficient adapted to the prescribed numerical value from a table of filter coefficients, which are preliminarily learnt and stored by a filter coefficient determining part 5, and uses this filter coefficient to perform the linear estimation processing, thereby separating the color signal C. This color signal C is used to output the luminance signal Y from an adder 7, and color difference signals (I and Q signals) are outputted from an I and Q signal separation processing circuit 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital signal data classifying device and adaptive Y / C separation for separating digital signal data in which a luminance signal and a chrominance signal are frequency-multiplexed to generate a digital component signal. Device, method for classifying digital signal data, and adaptive Y
/ C separation method.

[0002]

2. Description of the Related Art An NTSC system, a PAL system, or the like is adopted for a color television signal used in a general color television or the like.

The color television signals according to the NTSC system and the PAL system are both a luminance signal (Y signal) and two color difference signals I (wide band) and Q (narrow band) signal (P).
The AL system is a composite color television signal in which a color signal (C signal) composed of RY and BY signals is multiplexed by frequency interleaving. This composite color television signal is called a composite signal.

On the other hand, Y, I, Q signals (Y, R-
A color television signal separated into three signals (Y, BY signals) is called a component signal. To generate a component signal from the composite signal, a bandpass filter is used to separate the composite signal into a luminance signal (Y signal) and a color signal (C signal) (Y / C separation).
In addition, the color signal can be obtained by converting the color signal into an I signal and a Q signal.

As a method of separating the composite signal from Y / C, some band-limiting filters are used instead of the band-pass filter, and outputs from these band-limiting filters are adaptively selected. Alternatively, a method of mixing these outputs has also been proposed.

[0006]

By the way, the band of the luminance signal and the band of the chrominance signal of the composite color television signal according to the NTSC system are not constantly multiplexed depending on the position and time. Therefore, when the composite color television signal is separated into the luminance signal and the chrominance signal, it is impossible to completely separate the luminance signal and the chrominance signal by using the band limiting filter with the simple fixed coefficient.

Further, when a method of adaptively selecting and mixing the outputs from these band limiting filters by using some band limiting filters, the state of the signal to be extracted is Again, it is difficult to completely separate a composite color television signal because it is too large for the number of band limiting filters.

In view of the above-mentioned circumstances, the present invention has a digital signal data classifying device, an adaptive Y / C separating device, and a digital signal data device capable of easily and completely separating a composite color television signal. And the adaptive Y / C separation method.

[0009]

A classifying device for digital signal data according to the present invention includes a block processing unit for dividing digital signal data into blocks, and a block signal data from the block processing unit. A threshold value determination processing unit that determines a threshold value when performing the binarization process,
A binarization processing unit that binarizes the blocked signal data from the blocking processing unit using the threshold value from the threshold value determination processing unit, and a block from the binarization processing unit. The above-described problem is solved by including a conversion processing unit that converts each binarized signal data into a corresponding numerical value.

Further, the adaptive Y / C separation device according to the present invention divides the digital signal data in which the luminance signal Y and the color signal C are frequency-multiplexed into blocks, divides them into classes, and converts them into numerical values corresponding to the class divisions. And a filter processing unit that obtains a filter coefficient by a numerical value corresponding to the class division from the class dividing unit, separates the color signal from the signal data of each block using the filter coefficient, and the filter processing unit. And a color difference signal processing unit that converts the output from the color difference signal into a color difference signal.

Here, the class dividing section is a block processing section for dividing the digital signal data into blocks, and a threshold value for performing the binarization processing on the blocked signal data from the block processing section. And a binarization processing unit that binarizes the blocked signal data from the blocking processing unit using the threshold value from the threshold determination processing unit. And a conversion processing unit that converts the binarized signal data for each block from the binarization processing unit into a corresponding numerical value.

Further, in the adaptive Y / C separation apparatus according to the present invention, the signal data before frequency-multiplexing the luminance signal Y and the color signal C and the signal data after frequency-multiplexing are respectively divided into blocks, The filter coefficient used when separating the color signal data from the signal data after frequency-multiplexing is obtained by learning using these block-shaped signal data, and the filter coefficient for each block and the class division are supported. The numerical value to be stored is stored in a table in advance.

Further, the method of classifying digital signal data according to the present invention comprises a block processing step of dividing the digital signal data into blocks, and a binarization processing of the block signal data from the block processing step. By using the threshold value determining processing step for determining the threshold value when applying and the threshold value from the threshold value determining processing step, the blocked signal data from the blocking processing step is binarized. And a conversion processing step of converting the binarized signal data for each block from the binarization processing step into a corresponding numerical value.

Further, in the adaptive Y / C separation method according to the present invention, the digital signal data in which the luminance signal Y and the chrominance signal C are frequency-multiplexed is divided into classes and divided into classes, and converted into numerical values corresponding to the classes. Class division process to
A filter coefficient is obtained by a numerical value corresponding to the class division from this class division step, and a filter processing step for separating a color signal from signal data for each block using this filter coefficient, and an output from the filter processing step is a color difference signal. And a color difference signal processing step of

Here, the class dividing step includes a blocking processing step for dividing the digital signal data into blocks.
Using a threshold value determining process step for determining a threshold value when binarizing the blocked signal data from the blocking process step, and the threshold value from the threshold value determining process step. And a binarization processing step of binarizing the blocked signal data from the block processing step,
And a conversion processing step of converting the binarized signal data for each block from the binarization processing step into a corresponding numerical value.

In the adaptive Y / C separation method according to the present invention, the signal data before frequency-multiplexing the luminance signal Y and the color signal C and the signal data after frequency-multiplexing are respectively divided into blocks, The filter coefficient used when separating the color signal data from the signal data after frequency-multiplexing is obtained by learning using these block-shaped signal data, and the filter coefficient for each block and the class division are supported. The numerical value to be stored is stored in a table in advance.

[0017]

According to the present invention, when the color signal is separated from the digital signal data in which the color signal and the luminance signal are frequency-multiplexed, the signal data in which the frequency-multiplexed signal data is divided into blocks and divided into classes. The filter coefficient corresponding to a predetermined numerical value obtained by converting the pattern is read, and the color signal is separated from the frequency-multiplexed signal data using this filter coefficient.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 shows a schematic structure of an adaptive Y / C separation device according to the present invention. In this embodiment, it is assumed that frequency-multiplexed NTSC digital composite signal data is input from the input terminal 1 of FIG.

The digital signal data input from the input terminal 1 is input to the class dividing section 3 in the color signal separation processing section 2. The class dividing unit 3 divides the input digital signal data into blocks, and divides the blocked signal data into classes for each block. Further, the pattern of this class-divided signal data is converted into a predetermined numerical value (class code). The class-divided signal data B and the signal P having a predetermined numerical value are supplied to the class-specific adaptive filter processing unit 4.

Here, the filter coefficient determining section 5 will be described. In the filter coefficient determining unit 5, after the frequency signal is actually frequency-multiplexed, the signal data in a separated state before the luminance signal Y and the color signal C are frequency-multiplexed. The learning is performed using the signal data of 1 to obtain the filter coefficient of the Y / C separation filter used when separating the color signal C from the frequency-multiplexed signal data, for example, a linear estimation coefficient. This linear estimation coefficient is determined by a prediction coefficient estimation device, such as a least squares estimation device. The learning is performed on the signal data obtained by dividing the frequency-multiplexed signal data into blocks, and the filter coefficient corresponding to each of the blocked signal data is obtained. The filter coefficient (linear estimation coefficient) determined in this way is a predetermined numerical value when the pattern of the signal data obtained by classifying the blocked signal data corresponding to this filter coefficient is converted, that is, a so-called class code ( Class information) as an address and RO
It is previously stored as a table in M (read-only memory).

Therefore, the adaptive filter processing unit for each class 4 reads out the linear estimation coefficient adapted to the signal data B divided into blocks for each block from the filter coefficient determination unit 5 by using the numerical value of the input signal P. . further,
The color signal C is separated by performing linear estimation processing for each block on the block-shaped signal data using the read linear estimation coefficient. This color signal C is I, Q
It is output to the signal separation processing unit 6 and the adder 7.

The I / Q signal separation processing unit 6 synchronously detects the input color signals and converts them into I and Q signals which are color difference signals. The converted I signal is output from the output terminal 8 and the Q signal is output from the output terminal 9.

Further, the input terminal 1 is connected to the adder 7.
The digital signal data from is supplied. Therefore, in the adder 7, the luminance signal Y is output by subtracting the color signal C from the class-based adaptive filter processing unit 4 from the digital signal data. The brightness signal Y is output from the output terminal 10.

Next, referring to FIG.
Will be explained. Digital signal data input from the input terminal 11 is input to the blocking processing unit 12 in the class dividing unit 3. In the blocking processing unit 12,
Two-dimensional block formation is performed on the NTSC one-dimensional digital signal data that has been frequency-multiplexed and scan-converted. At this time, the digital signal data is converted so that the blocks in the vicinity of the block composed of the two-dimensional digital image signal become a one-dimensional signal string. The blocked signal data is output as signal data B from the output terminal 17 to the class-specific adaptive filter processing unit 4 of FIG. 1, and is also supplied to the binarization processing unit 13 and the threshold value determination processing unit 15.

In the threshold value determination processing unit 15, the threshold value used when the binarization processing unit 13 performs the binarization process on the blocked signal data is determined for each block. For example, the average value within the block is used as the threshold value.

In the binarization processing unit 13, the threshold value from the threshold value determination processing unit 15 is manipulated for each block, and using this threshold value, the blocking from the blocking processing unit 12 is performed. The signal data is binarized for each block. The binarized signal data is output to the packing processing unit 14.

In this packing processing unit 14, binarization processing is performed.
Of the binarized signal data of each block from the processing unit 13.
The pattern is a predetermined numerical value, so-called class code (class
Information). For example, a signal in which 1 word is m bits
Blocked with n words of data as one block
When the signal data is directly divided into classes, 2 ^mn
Generated class code, but it was blocked above
By applying binarization processing to the signal data, the class
The number of codes is 2ⁿReduced to individual pieces. The above predetermined value (
(Las code) is output from output terminal 16 as signal P
It

Next, the class-specific adaptive filter processing section 4 will be described with reference to FIG. The converted predetermined value signal P from the class dividing unit 3 is input to the ROM table reading unit 20 from the input terminal 19. This RO
In the M table reading unit 20, the filter coefficient determination unit 5 reads the linear estimation coefficient in the ROM stored in advance by using the predetermined numerical value (class code). The read linear estimation coefficient is sent to the linear estimation processing unit 21 as the signal A.

The linear estimation processing unit 21 has an input terminal 1
8, the signal data blocked by the blocking processing unit 11 in FIG. 2 is input as the signal data B. By performing the sum-of-products calculation of the blocked signal data and the linear estimation coefficient, The color signal C is separated from the multiplexed signal data, and the color signal C is output from the output terminal 22.

In this embodiment, the signal data input to the adaptive Y / C separator is NTSC digital signal data, but the PAL digital signal data is used instead of the NTSC digital signal data. It is also possible to enter.

Further, the class dividing section 3 generates a predetermined numerical value (class code) by performing binarization processing on the blocked signal data, but instead of this binarization processing, , ADRC (adaptive dynamic range encoding) processing may be used as the class code.

Further, although the class-based adaptive filter processing unit 4 performs the processing using the linear estimation coefficient, a nonlinear quadratic estimation coefficient may be used instead of the linear estimation coefficient.

[0034]

As is apparent from the above description, the classifying device for digital signal data according to the present invention has a blocking processing unit for blocking the digital signal data into blocks, and the blocking processing unit from the blocking processing unit. A threshold value determination processing unit that determines a threshold value when performing binarization processing on the generated signal data and a threshold value from the threshold value determination processing unit are used, A binarization processing unit that binarizes the signal data that has been blocked,
By including a conversion processing unit that converts the binarized signal data for each block from the binarization processing unit into a corresponding numerical value, the number of signal states that can be handled can be increased. It is possible to improve the separation performance of the color signal from the signal data in which the Y and the color signal C are frequency-multiplexed.

Further, the adaptive Y / C separation device according to the present invention divides the digital signal data in which the luminance signal Y and the color signal C are frequency-multiplexed into blocks, divides them into classes, and converts them into numerical values corresponding to this class division. And a filter processing unit that obtains a filter coefficient by a numerical value corresponding to the class division from the class dividing unit, separates the color signal from the signal data of each block using the filter coefficient, and the filter processing unit. A color difference signal processing unit for converting the output from the color difference signal into a color difference signal, wherein the class dividing unit is a blocking processing unit for blocking the digital signal data, and a blocking processing unit from the blocking processing unit. By using a threshold value determination processing unit that determines a threshold value when the signal data is binarized and a threshold value from the threshold value determination processing unit, And binarization processing section for binarizing the blocked signal data from the serial block processing unit,
The adaptive Y / C separation apparatus according to the present invention further comprises a luminance signal Y. The conversion processing unit converts the binarized signal data for each block from the binarization processing unit into a corresponding numerical value. And the signal data before frequency-multiplexing the color signal C and the signal data after frequency-multiplexing are respectively divided into blocks, and the signal data after the frequency-multiplexing is performed using these blocked signal data. The filter coefficient used when separating the color signal data is obtained by learning, and the filter coefficient for each block and the numerical value corresponding to the class division are stored in the table in advance, so that the signal state that can be handled can be handled. Therefore, it is possible to improve the separation performance of the color signal from the signal data in which the luminance signal Y and the color signal C are frequency-multiplexed.

Furthermore, the method for classifying digital signal data according to the present invention comprises a block processing step of dividing the digital signal data into blocks, and a binarization processing of the block signal data from the block processing step. By using the threshold value determining processing step for determining the threshold value when applying and the threshold value from the threshold value determining processing step, the blocked signal data from the blocking processing step is binarized. And a conversion processing step of converting the binarized signal data for each block from the binarization processing step into a corresponding numerical value.
Since the number of signal states that can be handled can be increased,
It is possible to improve the separation performance of the color signal from the signal data in which the luminance signal Y and the color signal C are frequency-multiplexed.

Furthermore, the adaptive Y / C separation method according to the present invention divides the digital signal data in which the luminance signal Y and the chrominance signal C are frequency-multiplexed into blocks, divides them into classes, and converts them into numerical values corresponding to this class division. Class dividing step, and a filter processing step of obtaining a filter coefficient by a numerical value corresponding to the class division from this class dividing step, and separating the color signal from the signal data of each block by using this filter coefficient; A color difference signal processing step for converting the output from the color difference signal into a color difference signal, and the class dividing step comprises a blocking processing step for blocking the digital signal data and a block processing from the blocking processing step. A threshold value determining process step for determining a threshold value when the signal data is binarized, and the threshold value determining process step Using Rano threshold, 2 blocked signal data from the blocking process steps
It comprises a binarization processing step for binarizing and a conversion processing step for converting the binarized signal data for each block from the binarization processing step into a corresponding numerical value, and further, the adaptive Y according to the present invention. In the / C separation method, the luminance signal Y and the chrominance signal C are divided into signal data before frequency-multiplexing and signal data after frequency-multiplexing, and these blocked signal data are used. The filter coefficient used in separating the color signal data from the frequency-multiplexed signal data is obtained by learning, and the filter coefficient for each block and the numerical value corresponding to the class division are stored in advance in a table. Since it is possible to increase the number of signal states that can be handled, the separation performance of the color signal from the signal data in which the luminance signal Y and the color signal C are frequency multiplexed. It is possible to improve.

[Brief description of drawings]

FIG. 1 is a diagram showing a schematic configuration of an adaptive Y / C separation device according to the present invention.

FIG. 2 is a diagram showing a schematic configuration of a digital signal data classification device according to the present invention.

3 is a diagram showing a schematic configuration of a class-specific adaptive filter processing unit 4 of FIG.

[Explanation of symbols]

 2 ... Color signal separation processing circuit 3 ... Class division unit 4 ... Class-based adaptive filter processing unit 5 ... Filter coefficient determination unit 6 ... I, Q signal separation processing unit 12 ... Blocking processing unit 13 ... Binarization processing unit 14 ... Packing processing unit 15 ... Threshold value determination processing unit 20 ... ROM table Read-out unit 21 ... Linear estimation (sum of products) processing unit

Claims (8)

[Claims] 1. A blocking processing unit for blocking digital signal data into blocks, and a threshold value determination for determining a threshold value when binarizing the blocked signal data from the blocking processing unit. A processing unit, a binarization processing unit that binarizes the blocked signal data from the blocking processing unit using the threshold value from the threshold value determination processing unit, and the binarization processing. And a conversion processing unit for converting the binarized signal data for each block from the unit into a corresponding numerical value. 2. A class dividing section for dividing digital signal data in which a luminance signal Y and a chrominance signal C are frequency-multiplexed into blocks and dividing into classes, and converting into a numerical value corresponding to this class division, and a class dividing section A filter coefficient is obtained by a numerical value corresponding to the class division, and a filter processing unit that separates the color signal from the signal data of each block using this filter coefficient, and a color difference signal processing that converts the output from the filter processing unit into a color difference signal An adaptive Y /, characterized in that
C separation device. 3. The class dividing unit sets a blocking processing unit for blocking digital signal data into blocks, and a threshold value for performing binarization processing on the blocked signal data from the blocking processing unit. Using the threshold value determination processing unit to determine and the threshold value from the threshold value determination processing unit,
A binarization processing unit that binarizes the blocked signal data from the blocking processing unit, and converts the binarized signal data for each block from the binarization processing unit into corresponding numerical values. 3. The adaptive Y / C separation device according to claim 2, further comprising a conversion processing unit. 4. The luminance signal Y and the chrominance signal C are divided into signal data before frequency-multiplexing and signal data after frequency-multiplexing, respectively, and the frequency is calculated by using these blocked signal data. The filter coefficient used when separating the color signal data from the multiplexed signal data is obtained by learning, and the filter coefficient for each block and the numerical value corresponding to the class division are stored in advance in a table. Adaptive Y according to claim 2, characterized in that
/ C separator. 5. A blocking processing step for blocking digital signal data into blocks, and a threshold value determination for determining a threshold value when binarizing the blocked signal data from the blocking processing step. A binarizing process for binarizing the blocked signal data from the blocking process using the threshold value from the threshold determining process, and the binarizing process. And a conversion processing step of converting the binarized signal data of each block from the step into a corresponding numerical value. 6. A class dividing step of dividing digital signal data in which a luminance signal Y and a color signal C are frequency-multiplexed into blocks and dividing into classes, and converting into a numerical value corresponding to the class division, and a class dividing step from the class dividing step. The filter coefficient is obtained by the numerical value corresponding to the class division, and the filter processing step of separating the color signal from the signal data of each block using this filter coefficient, and the color difference signal processing of converting the output from the filter processing step into the color difference signal An adaptive Y / C separation method comprising the steps of: 7. The class dividing step includes a blocking processing step for blocking digital signal data into blocks, and a threshold value for binarizing the blocked signal data from the blocking processing step. A threshold value determining process step for determining, and a binarizing process step for binarizing the blocked signal data from the blocking process step using the threshold value from the threshold value determining process step. , Above 2
7. The adaptive Y / C separation method according to claim 6, further comprising a conversion processing step of converting the binarized signal data for each block from the value conversion processing step into a corresponding numerical value. 8. The signal data before frequency-multiplexing the luminance signal Y and the color signal C and the signal data after frequency-multiplexing are respectively divided into blocks, and the frequency is divided by using these blocked signal data. The filter coefficient used when separating the color signal data from the multiplexed signal data is obtained by learning, and the filter coefficient for each block and the numerical value corresponding to the class division are stored in advance in a table. 7. The adaptive Y according to claim 6, wherein
/ C separation method.