JP2010226411A - Video signal processor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the deterioration of color adjacent to a sharp edge that is caused by sampling and generating a 4:2:2 mode color difference signal from a 4:4:4 mode color difference signal and sampling and restoring the 4:4:4 mode color difference signal from the sampled/generated 4:2:2 mode color difference signal. <P>SOLUTION: The video signal processor includes an edge detection means to detect a sharp edge from a 4:4:4 mode color difference signal, a sampling pulse generation means to generate a sampling pulse for sampling at least pixels before and after the sharp edge, a sampling means to sample the 4:4:4 mode color difference signal on the basis of the sampling pulse and generate the 4:2:2 mode color difference signal, and a video signal restoring means to generate the 4:4:4 mode color difference signal by sampling and restoring at least pixels before and after the sharp edge of the 4:4:4 mode color difference signal from the 4:2:2 mode color difference signal. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

In the present invention, a 4: 2: 2 system color difference signal is sampled from a 4: 4: 4 system color difference signal, and the 4: 2: 2 system color difference signal sampled is generated as a 4: 4: 4 system color difference. The present invention relates to a video signal processing apparatus that samples and restores a signal.

As a technique related to a conventional video signal processing apparatus, a 4: 4: 4 format chroma signal and a chroma signal delayed by one pixel time are averaged, and a 4: 4: 4 format luminance signal and an averaged chroma signal are averaged. Is converted into a 4: 2: 2 format signal in a time division manner, thereby suppressing color degradation caused by converting a 4: 4: 4 format chroma signal to a 4: 2: 2 format chroma signal. A technique has been proposed (for example, Patent Document 1).
JP-A-10-262265

  However, the conventional video signal processing apparatus has a problem that even if there is a sharp change (edge) in the color difference signal, an average value of pixels before and after the sharp edge is output, so that the color deteriorates. It was.

In order to solve the above problem, the video signal processing apparatus of the present invention samples edge detection means for detecting steep edges from 4: 4: 4 color difference signals, and samples at least pixels before and after the steep edges. Pulse generating means for generating a pulse for sampling, sampling means for sampling the 4: 4: 4 color difference signal based on the pulse, and generating a 4: 2: 2 color difference signal, and the 4: 2: Video signal restoration means for generating a 4: 4: 4 color difference signal by sampling and restoring at least pixels before and after the sharp edge of the 4: 4: 4 color difference signal from the two color difference signals.

  A 4: 2: 2 color difference signal is sampled from a 4: 4: 4 color difference signal by detecting a sharp edge of the color difference signal, sampling and restoring the pixels before and after the sharp edge, and Further, it is possible to reduce the color deterioration in the vicinity of the steep edge caused by sampling and restoring the 4: 4: 4 system color difference signal from the sampled 4: 2: 2 system color difference signal.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

(Embodiment)
FIG. 1 is a block diagram showing an example of the configuration of a video signal processing apparatus 100 according to the present invention.
The edge detection means 1 detects a sharp edge of the color difference signal from the input 4: 4: 4 color difference signals (Uin, Vin), and outputs an edge pulse to the pulse generation means 2.
The pulse generation unit 2 generates a pulse for sampling pixels before and after the steep edge from the input edge pulse and the horizontal synchronization signal Hin, and outputs the pulse to the sampling unit 3 and the video signal restoration unit 4.
The sampling means 3 samples at least pixels before and after the steep edge from the input 4: 4: 4 color difference signal (Uin, Vin) based on the input pulse, and the 4: 2: 2 color difference. A signal (C signal) is generated and output to the video signal restoration means 4.
The video signal restoration unit 4 samples and restores at least pixels before and after the steep edge from the input 4: 2: 2 color difference signal (C signal), and outputs the 4: 4: 4 color difference signal (Uout, Vout). ) Is generated and output.

  FIG. 2 is a block diagram showing an example of a specific configuration of the pulse generation unit 2, the sampling unit 3, and the video signal restoration unit 4 of the video signal processing apparatus 100 of FIG. The same components as those in FIG. 1 are denoted by the same reference numerals.

  The pulse generating means 2 shown in FIG. 2 constitutes an odd edge pulse generating means 11, a sampling pulse generating means 12, and a toggle pulse generating means 13.

  The sampling means 3 shown in FIG. 2 comprises LH circuits 21 and 22, delay circuits 31 to 35, and switching circuits 51 to 53.

  The video signal restoration means 4 shown in FIG. 2 constitutes LH circuits 23 and 24, delay circuits 36 to 44, correction pixel generation means 61 and 62, and switching circuits 54 to 59.

  FIG. 3 shows an example of an operation of sampling and generating a 4: 2: 2 color difference signal (C signal) from a 4: 4: 4 color difference signal (Uin, Vin) in the video signal processing apparatus 100 of FIG. FIG.

  FIG. 4 shows an example of an operation of sampling and restoring the 4: 2: 2 system color difference signal (C signal) to the 4: 4: 4 system color difference signal (Uout, Vout) in the video signal processing apparatus 100 of FIG. FIG.

  Hereinafter, the operation of the video signal processing apparatus 100 in FIG. 2 will be described with reference to FIGS. 3 and 4.

  The edge detection means 1 uses the input 4: 4: 4 color difference signals (Uin, Vin (1)) to sharp edges of the color difference signals (in this embodiment, they are referred to as edge 1 and edge 2). Then, an edge pulse (2) that becomes Hi for each pixel before and after edge 1 and edge 2 is generated and output to odd edge pulse generation means 11 and sampling pulse generation means 12.

  Here, the steep edge is, for example, a large change in hue or a large change in gradation (for example, when a change in the gradation of Uin or Vin changes 64 or more in 256 gradations). Various known methods such as setting a high-pass filter and a threshold can be applied, and description thereof is omitted here.

The toggle pulse generating means 13 generates a toggle pulse (3) for toggling Hi and Lo every 1T (T is one clock cycle of the video signal processing apparatus 100) in synchronization with the input horizontal synchronization signal Hin, and an odd edge pulse. The data is output to the generation unit 11, the sampling pulse generation unit 12, and the delay circuit 35.
The odd edge pulse generation means 11 determines Hi from the input edge pulse (2) and toggle pulse (3) Hi one pixel before and after the edge when the edge is an odd delay from the falling edge of the horizontal synchronizing signal Hin. Generates an odd edge pulse (4) of Lo and outputs it to the delay circuit.
The sampling pulse generation means 12 outputs Hi from the input edge pulse (2) and toggle pulse (3) at least for 2T period before and after the edge, and repeats Hi and Lo for every 1T during periods other than before and after the edge. (5) is generated and output to the LH circuit 21, the LH circuit 22, and the delay circuit 44.
In the sampling means 3, the LH circuit 21 outputs Uin after 1T when the sampling pulse (5) is Hi, and outputs when the sampling pulse (5) is Lo according to the input sampling pulse (5). Holds the output signal (6).
In response to the input sampling pulse (5), the LH circuit 22 outputs the input signal Vin after 1T when the sampling pulse (5) is Hi, and an output signal when the sampling pulse (5) is Lo. (10).
The delay circuit 31 delays the output signal (6) of the LH circuit 21 by 1T (7).
The delay circuit 32 delays the output signal (10) of the LH circuit 22 by 1T (11).
The delay circuit 34 delays the odd edge pulse (4) by 1T and outputs it to the switching circuit 51, the switching circuit 52, and the delay circuit 42 (8).
The switching circuit 51 outputs the output signal (6) of the LH circuit 21 and the output signal (7) of the delay circuit 31 according to the output signal (8) of the delay circuit 34, and the output signal (8) of the delay circuit 34 is Hi. In this case, the output signal (7) of the delay circuit 31 is selected and, if the output signal (8) of the delay circuit 34 is Lo, the output signal (6) of the LH circuit 21 is selected and output (9).
The switching circuit 52 outputs the output signal (10) of the LH circuit 22 and the output signal (11) of the delay circuit 32 according to the output signal (8) of the delay circuit 34, and the output signal (8) of the delay circuit 34 is Hi. In this case, the output signal (11) of the delay circuit 32 is selected, and when the output signal (8) of the delay circuit 34 is Lo, the output signal (10) of the LH circuit 22 is selected and output (12).
The delay circuit 33 delays the output signal (12) of the switching circuit 52 by 1T (13).
The delay circuit 35 delays the toggle pulse (3) by 2T (14).
The switching circuit 53 outputs the output signal (9) of the switching circuit 51 and the output signal (13) of the delay circuit 33 according to the output signal (14) of the delay circuit 35, and the output signal (14) of the delay circuit 35 is Hi. In this case, the output signal (9) of the switching circuit 51 is selected, and if the output signal (14) of the delay circuit 35 is Lo, the output signal (13) of the delay circuit 33 is selected to generate a C signal and output it. (15).
In the video signal restoration means 4, the delay circuit 41 delays the output signal (14) of the delay circuit 35 (16). The delay amount is the same as the delay amount until the output signal (15) of the switching circuit 53 is input to the video signal restoration means 4.
In response to the output signal (16) of the delay circuit 41, the LH circuit 53 outputs the C signal (15) when the output signal (16) of the delay circuit 41 is Hi, and the output signal (16 of the delay circuit 41). ) Is Lo, the output signal is held (17).
In response to the output signal (16) of the delay circuit 41, the LH circuit 24 outputs the C signal (15) when the output signal (16) of the delay circuit 41 is Lo, and the output signal (16 of the delay circuit 41). ) Is Hi, the output signal is held (19).
The delay circuit 36 delays the output signal (17) of the LH circuit 23 by 1T (18).
The delay circuit 37 delays the output signal (18) of the delay circuit 36 by 1T (20).
The delay circuit 39 delays the output signal (19) of the LH circuit 24 by 1T (29).
The interpolation pixel generation means 61 generates an interpolation pixel from the output signal (18) of the delay circuit 36. For example, an average of two pixels adjacent in the horizontal direction is set as an interpolation pixel (23).
The interpolation pixel generation means 62 generates an interpolation pixel from the output signal (19) of the LH circuit 24. For example, an average of two pixels adjacent in the horizontal direction is set as an interpolation pixel (31).
The delay circuit 38 delays the output signal (23) of the interpolation pixel generation means 61 by 1T (24).
The delay circuit 40 delays the output signal (31) of the interpolation pixel generation means 62 by 1T (32).
The delay circuit 42 delays the output signal (8) of the delay circuit 34 (21). The delay amount is the same as the delay until the output signal (15) of the switching circuit 53 is input to the switching circuit.
The switching circuit 54 outputs the output signal (18) of the delay circuit 36 and the output signal (20) of the delay circuit 37 according to the output signal (21) of the delay circuit 42, and the output signal (21) of the delay circuit 42 is Hi. In this case, the output signal (18) of the delay circuit 36 is selected, and when the output signal (21) of the delay circuit 42 is Lo, the output (20) of the delay circuit 37 is selected (22).
The switching circuit 55 outputs the output signal (19) of the LH circuit 24 and the output signal (29) of the delay circuit 39 according to the output signal (21) of the delay circuit 42, and the output signal (21) of the delay circuit 42 is Hi. In this case, the output signal (19) of the LH circuit 24 is selected, and when the output signal (21) of the delay circuit 42 is Lo, the output (29) of the delay circuit 39 is selected (30).
The delay circuit 43 delays the output signal (21) of the delay circuit 42 (25). The delay amount is the same as the delay until the output signal (15) of the switching circuit 53 is input to the switching circuit 56.
According to the output signal (25) of the delay circuit 43, the switching circuit 56 outputs the output signal (23) of the interpolation pixel generation means 61 and the output signal (24) of the delay circuit 38 according to the output signal (25) of the delay circuit 43. In the case of Hi, the output signal (23) of the interpolation pixel generation means 61 is selected, and in the case where the output signal (25) of the delay circuit 43 is Lo, the output (24) of the delay circuit 38 is selected (26).
The switching circuit 57 outputs the output signal (25) of the delay circuit 43 according to the output signal (25) of the delay circuit 43 and the output signal (31) of the interpolation pixel generation means 62 and the output signal (32) of the delay circuit 40. In the case of Hi, the output signal (31) of the interpolation pixel generating means 62 is selected, and in the case where the output signal (25) of the delay circuit 43 is Lo, the output (32) of the delay circuit 40 is selected (33).
The delay circuit 44 delays the sampling pulse (5) (27). The delay amount is the same as the delay until the output signal (15) of the switching circuit 53 is input to the switching circuit 40.
The switching circuit 58 outputs the output signal (22) of the switching circuit 54 and the output signal (26) of the switching circuit 56 according to the output signal (27) of the delay circuit 44, and the output signal (27) of the delay circuit 44 is Hi. In this case, the output signal (22) of the switching circuit 54 is selected, and when the output signal (27) of the delay circuit 44 is Lo, the output signal (26) of the switching circuit 56 is selected (28).
The switching circuit 59 outputs the output signal (30) of the switching circuit 55 and the output signal (33) of the switching circuit 57 according to the output signal (27) of the delay circuit 44, and the output signal (27) of the delay circuit 44 is Hi. In this case, the output signal (30) of the switching circuit 55 is selected, and when the output signal (27) of the delay circuit 44 is Lo, the output signal (33) of the switching circuit 57 is selected (34).
According to the present invention, steep edges (edge 1 and edge 2) of the color difference signal are detected from the input 4: 4: 4 color difference signals (Uin, Vin), and pixels (U4) before and after the steep edge are detected. , U5, U13, U14, V4, V5, V13, and V14), sampling from 4: 4: 4 system color difference signal to 4: 2: 2 system color difference signal, and further sampling It is possible to reduce the color deterioration in the vicinity of the steep edge caused by sampling and restoring the 4: 4: 4 system color difference signal from the generated 4: 2: 2 system color difference signal.

  In this embodiment, the odd-numbered color difference signals such as 1, 3, 5,... Are thinned out from the 4: 4: 4 color difference signals (Uin, Vin (1)) to 4: 2: 2. When generating the color difference signal (C signal (15)) of the system, the odd edge pulse generation means 11 generates the odd edge pulse (4) so as not to thin out U5 and V5 of the steep edge 1. However, the present invention is not limited to this, and the even-numbered color difference signals such as 2, 4, 6,... Are thinned out from the 4: 4: 4 color difference signals (Uin, Vin (1)). The configuration is such that a 4: 2: 2 color difference signal (C signal) is generated. In FIG. 2, even edge pulse generation means is provided in place of the odd edge pulse generation means 11, and the edge starts from the fall of the horizontal synchronization signal Hin. For even delays, One pixel before and after Hi, generate an even edge pulse of Lo in the case of other, it may be configured without thinning the U14 and V14 of steep edges 2.

  The present invention is not limited to the above-described embodiments, and various design changes can be made without departing from the scope of the technical idea described in the claims. It is.

  The present invention samples and generates a 4: 2: 2 system color difference signal from a 4: 4: 4 system color difference signal, and further generates a 4: 4: 4 system color sample signal from the generated 4: 2: 2 system color difference signal. It is possible to reduce the color deterioration near the steep edge of the color difference signal caused by sampling and decoding the color difference signal, which is useful in a video signal processing apparatus.

The block diagram which shows the structure of the video signal processing apparatus in embodiment of this invention 1 is a block diagram showing an example of a specific configuration of pulse generation means, sampling means, and video signal restoration means in the video signal processing apparatus of FIG. 2 is a diagram illustrating an example of an operation of sampling and generating a 4: 2: 2 color difference signal from a 4: 4: 4 color difference signal in the video signal processing apparatus 100 of FIG. 2 is a diagram illustrating an example of an operation of sampling and restoring a 4: 2: 2 system color difference signal to a 4: 4: 4 system color difference signal in the video signal processing apparatus 100 of FIG.

DESCRIPTION OF SYMBOLS 1 Edge detection means 2 Pulse generation means 3 Sampling means 4 Video signal restoration means 11 Odd edge pulse generation means 12 Sampling pulse generation means 13 Toggle pulse generation means 21-24 LH circuit 31-44 Delay circuit 51-59 Switching circuit 60, 61 Interpolation Pixel generation means 100 Video signal processing apparatus

Claims (3)

Edge detection means for detecting steep edges from 4: 4: 4 color difference signals;
Pulse generating means for generating a pulse for sampling pixels before and after the steep edge; and
Sampling means for sampling the 4: 4: 4 system color difference signal based on the pulse and generating a 4: 2: 2 system color difference signal;
Video signal restoration means for generating a 4: 4: 4 color difference signal by sampling and restoring at least pixels before and after the sharp edge of the 4: 4: 4 color difference signal from the 4: 2: 2 color difference signal. When,
A video signal processing apparatus comprising: The pulse generation means includes
A toggle pulse generating means for generating a toggle pulse that repeats Hi and Lo every clock cycle in synchronization with the horizontal synchronization signal;
When the steep edge is an odd delay from the falling edge of the horizontal synchronization signal from the edge pulse generated by the edge detection means and the toggle pulse, each pixel before and after the steep edge is Hi, In this case, odd edge pulse generation means for generating Lo odd edge pulses;
Sampling generation means for generating sampling pulses that repeats Hi and Lo at every clock cycle for at least two clock periods before and after the edge from the edge pulse and the toggle pulse, and for periods other than before and after the edge;
When the sampling means generates a 4: 2: 2 color difference signal by thinning out odd-numbered pixels from the 4: 4: 4 color difference signal, the odd delay of the odd delay pulse and the sampling pulse is generated. 2. A video signal processing apparatus according to claim 1, wherein one pixel after a sharp edge is sampled. The pulse generation means includes
A toggle pulse generating means for generating a toggle pulse that repeats Hi and Lo every clock cycle in synchronization with the horizontal synchronization signal;
When the steep edge from the edge pulse generated by the edge detection means and the toggle pulse is an even delay from the fall of the horizontal synchronization signal, each pixel before and after the steep edge is Hi, An even edge pulse generating means for generating an even edge pulse of Lo in the case;
Sampling generation means for generating sampling pulses that repeats Hi and Lo at every clock cycle for at least two clock periods before and after the edge from the edge pulse and the toggle pulse, and for periods other than before and after the edge;
When the sampling unit generates a 4: 2: 2 color difference signal by thinning out even-numbered pixels from a 4: 4: 4 color difference signal, the even delay pulse is generated based on the even edge pulse and the sampling pulse. 2. A video signal processing apparatus according to claim 1, wherein one pixel after a sharp edge is sampled.

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