KR0153536B1 - Scanning interpolation generation circuit and method - Google Patents

Abstract

An interpolation field generating circuit and method for converting the existing interlaced scanning method to the same number of sequential scanning methods to improve the image quality in television, and detects the frame difference and the field difference and interpolates the signal with the vertical axis according to the state of the value. The mixed output of the interpolated signal on the time axis is adjusted.

Description

Scan Interpolation Signal Generation Circuit and Method

1 is a conventional circuit diagram.

2 is a circuit diagram according to the present invention.

* Explanation of symbols for main parts of the drawings

10: first time axis interpolation means 20: first vertical axis interpolation means

30: first mixing means 40: frame difference detecting means

50: field difference detection means 60: mixing control means

70: second time axis interpolation means 80: second vertical axis interpolation means

90: second mixing means

The present invention relates to a circuit and method for improving image quality of an image display apparatus, and more particularly, to a scan interpolation signal generation circuit and method for converting interlaced scanning into progressive scanning.

In general, a method of improving the image quality of a video display device includes an HDTV method by converting a broadcast method and data compression, an EDTV method for sending additional information to an existing method, and an IDTV method for increasing scanning lines. In particular, the IDTV method converts the interlaced scan into a sequential scan in order to increase the scanning line, and performs two sequential scans in the existing interlaced scan section.

FIG. 1 is a circuit diagram of Japanese Patent Application No. 61-41290 (hereinafter referred to as a conventional patent) as a circuit for converting interlaced scanning into sequential scanning as described above. The detailed description of FIG. 1 is omitted since it is described in detail in the prior patent.

However, the conventional patent does not consider the amount of motion on the time axis, when a large motion occurs on the time axis, the screen becomes quite inconvenient.

Accordingly, an object of the present invention is to provide a scan interpolation signal generation circuit and method for obtaining a more natural and high resolution screen.

FIG. 2 is a circuit diagram according to the present invention. The second time interpolation means 70 interpolates in the time axis direction by receiving color signals and sequentially adding them in units of frames, and two adjacent horizontal lines after delaying a field by receiving the color signals. The second vertical axis interpolation means 80 and the second time axis interpolation means 70 and the second vertical axis interpolation means 80 which interpolate in the vertical direction by sequentially adding the interpolated signals are mixed with each other. A second mixing means 90 for receiving and mixing at a corresponding mixing ratio and outputting the first mixing means; and a first time axis interpolating means for interpolating in the time axis direction by sequentially adding and outputting two adjacent frame signals in units of frames in response to a luminance signal ( 10) and a first vertical axis interpolating in the vertical axis direction by sequentially adding two adjacent horizontal lines after delaying one field in response to the luminance signal. The interpolation means 20 and the signal interpolated by the first time interpolation means 10 and the signals interpolated by the first vertical axis interpolation means 20 are mixed with each other. A first mixing means (30) for mixing and outputting the resultant signal, a frame difference detecting means (40) for detecting the frame difference value by taking the luminance signal and subtracting it by the frame unit, and then taking the absolute value thereof; A field difference detecting means 50 for examining field difference values of two adjacent fields by subtracting a one field delay signal of a signal interpolated by the interpolation means 20 and a signal output by the first mixing means 30; And comparing the field difference value with a predetermined reference value, when the field difference value is larger than the reference value, the field difference value becomes smaller. When the field difference value is smaller than the reference value, the field difference value corresponds to the larger value of the field difference value and the frame difference value. Mixing ratio control system It generates a call and outputs it to the first and second mixing means (30,90) and comprises a mixing control means (60) for controlling the mixing ratio of the first and second mixing means (30,90).

The first time interpolation means 10 may include a first frame delay unit 11 for delaying an input luminance signal in units of frames, a signal delayed by the first frame delay unit 11, and a signal input without delay. The adder 12 adds and the divider 13 divides the level of the signal added by the adder 12.

The first vertical axis interpolation means 20 includes: a first field delay unit 21 for delaying an input luminance signal by one field and a first horizontal line delay for receiving a signal given by the first field delay unit 21; A line adder 22, an adder 23 for adding outputs of the first field delayer 21 and the first line delayer 22, and a signal added by the adder 23; The divider 24 is used.

The first mixing means 30 includes a subtractor 31 for subtracting the output of the first time interpolation means 10 and the output of the first vertical axis interpolation means 20, and an output of the adder 31. A multiplier 32 that multiplies the mixing ratio control signal by a matching ratio corresponding to the value, and an adder 33 that adds the value multiplied by the Sungsan 32 and the output of the first vertical axis interpolation means 20. Configure.

The frame difference detecting means 40 calculates a difference between the third frame delay unit 41 delaying one frame of the luminance signal and the difference between the signal delayed by the third frame delay unit 41 and the luminance signal. The winding 42 and the absolute value 43 which detects the absolute value of the signal subtracted by the said subtractor 42 are comprised.

The field difference detecting means 50 includes a third field delay unit 51 for delaying the output of the first mixing means 30 by one field, an output of the third field delay unit 51, and the first field delay unit 51. It consists of a subtractor 52 which calculates the difference of the output of the vertical interpolation means 20. As shown in FIG.

The mixing control means 60 compares the reference value generator 61 generating a predetermined reference box with the output of the reference value and the frame difference detecting means 40 and generates a first switching signal corresponding to the comparison result. Comparing the first switching control means 62, the output of the frame difference detecting means 40 and the output of the field difference detecting means 50, and generating and outputting a second switching control signal corresponding to the comparison result. Second switching for selectively outputting the output of the frame difference detecting means 40 and the output of the field difference detecting means 50 by using the second switching control means 63 and the second switching control signal as control signals. Means 64 and first switching means 65 for selectively outputting the output of the frame difference detecting means 50 and the output of the second switching means 64 as control signals of the first switching control signal. Consists of.

The second time axis interpolation means 70, the second vertical axis interpolation means 80, and the second mixing means 90 may include the first time axis interpolation means 10, the first vertical axis interpolation means 20, Only the first mixing means 30 and the reference numerals differ, but have the same configuration.

Hereinafter, embodiments of the present invention will be described with reference to the above configuration and the accompanying drawings.

The present invention converts an interlaced scan that forms one frame into two fields into a form in which two sequential scans are performed in the same scan period so as to obtain superior image quality than the interlaced scan form.

In order to do the above, when a scan signal of one field is scanned, two sequential scans are performed in the same period by interpolating similar scan fields by interpolation through a method called interpolation and scanning together. Take form.

The present invention also has the same principle as above.

However, the interpolation may be performed in various ways. In the present invention, the interpolation is performed on the vertical axis and the time axis for the luminance signal and the color signal, and the mixture is mixed again, but the mixing ratio is adjusted through the field difference signal and the frame difference signal. Do it.

The luminance signal Y is simultaneously input to the first time axis interpolation means 10, the first vertical axis interpolation means 20, and the frame difference detection means 40. In the first time axis interpolation means 10, upon receiving the luminance signal, the first frame delay unit 11 delays one frame through the first frame delay unit 11 and the second frame delay unit 11 does not delay the other frame. The delayed signal is added. Then, the added signal is divided by 1/2 and output.

Upon receiving the luminance signal Y, the first vertical axis interpolation means 20 delays one field through the first field delay unit 21 and adds the delayed signal to the delayed signal which is one horizontal level below. Then divide it by 1/2 and output it.

The frame difference detecting means 40 delays one frame on the one hand through the third frame delay unit 41 when receiving the luminance signal Y, and on the other hand, the frame through the subtractor 42. Subtracts the delayed signal in units. Then, the absolute value 43 is taken and the absolute value of the subtracted value is taken out.

The reason for delaying one frame in the first time interpolation means 10 is to delay one frame, so that a signal delayed by one frame and a signal that are not delayed become signals of two frames that are temporally adjacent to each other, and these two adjacent frames at the same time. In order to be able to take an arbitrary signal in. And adding the signal of the delayed frame and the signal of the non-delayed frame with the adder 12 and dividing the added signal with the divider 13 again results in a frame signal having an average value of the two temporally adjacent frame signals. To get it. The signal obtained as described above becomes a signal interpolated on the time axis.

In addition, the reason for delaying the luminance signal input through the first field delay unit 21 by the first vertical axis interpolation means 20 by one field is to generate the interpolated field of the field currently being scanned. In other words, in interlaced scanning, one frame is divided into two fields, and each field has odd or even lines. Therefore, one field must be delayed so that interpolated signals are not scanned. This is because scanning can be performed on lines of even fields when scanning odd fields. After the one-field delayed signal is delayed one horizontal line through the first line delay unit 22, the delayed signal and the one-field delayed signal are added through the adder 23, and the added value is added. The division by the divider 24 is to take the average of the level values of each pixel of two adjacent horizontal lines in the delayed field. The signal thus obtained becomes a signal interpolated on the vertical axis.

Obtaining the difference between two adjacent frames in the frame difference detecting means 40 is for detecting the degree of motion of the image, and the frame difference detecting means 40 obtains the difference between two adjacent frames and outputs the absolute value thereof. This is a signal corresponding to the momentum between two adjacent frames.

The first mixing means 30 mixes the outputs of the first time axis interpolation means 10 and the first vertical axis interpolation means 20 with the output of the first switching means 65 of the mixing control means 60. According to the mixing ratio determined by the mix and output. The mixing ratio determined by the mixing ratio control signal is a field difference value and a frame difference value detected by the field difference detecting means 50 and the frame difference detecting means 40 in the mixing control means 60 in a predetermined logic state. Refers to the value of the mixing ratio control signal to be output after the comparison. The mixing ratio control signal has a different value depending on the amount of motion of the image between two adjacent fields and two adjacent frames. As described above, the signal output from the first mixing means 30 becomes a luminance interpolation signal for sequential scanning.

The field difference detecting means 50 subtracts a signal obtained by delaying the output of the first vertical interpolation means 20 and the first mixing means 30 by one field, which is used to detect the momentum between two adjacent fields. will be.

At this time, the delay of the output of the first mixing means 30 by one field is performed by the third field delay unit 51, and the output of the first vertical axis interpolation means 20 and the third field delay unit 51. Subtracting the output of) is performed through the subtractor 52.

The mixing control means 60 receives the output of the field difference detecting means 50 and the output of the frame difference detecting means 40 as inputs to generate the mixed ratio control signal. 50) and the mixing ratio of the first mixing means 30 in accordance with the amount of motion detected by the frame difference detecting means 40.

The mixing control means 60 includes a reference value generator 61, a first switching control means 62, a second switching control means 63, a second switch means 64, and a first switching means 65. It is composed of

The reference value generator 61 generates an arbitrary reference value, and the first switching control means 62 compares the reference value generated by the reference value generator 61 with the level of the output of the frame difference detecting means 40, and then A predetermined first switching control signal corresponding to the comparison result is generated and output.

The second switching control means 63 compares the level of the output of the frame difference detecting means 40 and the field difference detecting means 50, and generates and outputs a predetermined second switching control signal corresponding to the comparison result. .

The second switching control means 64 receives the second switching control signal, which is the output of the second switching control means 63, and corresponds to the frame difference detecting means 40 and the field difference detecting means in response to the logic state thereof. The output of 50) is selectively output. At this time, the signal output by the second switching control means 64 becomes a larger signal of the two output signals of the frame difference detecting means 40 and the field difference detecting means 50.

The first switching means 65 receives the first switching control signal, which is the output of the first switching control means 62, and outputs the frame difference detecting means 40 and the second according to the logic state of the signal. And selectively outputs the output of the switching means 64. At this time, if the output of the frame difference detecting means 40 is less than or equal to the reference value, the first switching means 65 is the frame difference detecting means 40. Select outputs the output of the second switching means 64. Otherwise, the output of the second switching means 64 is selected and output by the first mixing means 30. Is a mixing ratio control signal for controlling the mixing ratio.

Finally, when the mixing ratio control signal is CS, the output signal of the frame difference detecting means 40 is fr, the output signal of the field difference detecting means 50 is fi, and the reference value is Th1.

If fr ≤ Th1, then CS = fr,

If fr> Th1, CS = (the larger of fr and fi).

Looking back at the first mixing means 30, the first mixing means 30 is composed of a subtractor 31, a multiplier 32 and an adder 33, the subtractor 31 is the first time axis interpolation The output of the means 10 subtracts the output of the first vertical axis interpolation means 20, and the Sungsan 32 is a mixed ratio control signal that is an output of the subtractor 31 and an output of the mixing control means 60. Multiply and output The adder 33 adds and outputs the output of the multiplier 32.

Herein, when the output of the first time axis interpolation means 10 is referred to as Tfy, the output of the first vertical axis interpolation means 20 is referred to as Vfy, and the mixing ratio control signal is referred to as CS, the output of the adder 33 is output. That is, Y 'which is the output of the first mixing means 30,

Y '= Tfy (1-CS) + VfyCS.

The description of the second time axis interpolation means 70, the second vertical axis interpolation means 80, and the second mixing means 90 has been omitted, which means that the input is the chroma signal C and that each of the means is the first time axis interpolation. This is because the means 10, the second vertical axis interpolation means 20, and the first mixing means 30 are the same except that the reference numerals are different. However, in order to distinguish the components corresponding to the first frame delay unit 11, the first field delay unit 21, and the first line delay unit 22, the second frame delay unit 71 and the second field delay unit It is referred to as group 81, the second line delay unit 82.

If the output of the second mixing means 90 is C ', the output of the second time axis interpolation means 70 is Tfc, and the output of the second vertical axis interpolation means 80 is Vfc, C 'is

C '= Tfc * (1-CS) + Vfc * CS.

In the above description, Y 'and C' are referred to as interpolation field signals, which are interpolated luminance and chroma interpolation signals generated by the present invention in order to convert them into sequential scans.

As described above, the present invention detects the amount of motion using the field difference and the frame difference, and generates an interpolation field by appropriately mixing the interpolated signal on the time axis and the interpolated signal on the vertical axis, and thus the interpolated image is considerably natural. There is an advantage.

Claims (11)

In a television scan interpolation circuit, a second time interpolation means 70 interpolates in the time axis direction by receiving color signals and sequentially adding them in units of frames, and delays one field in response to the color signals, and sequentially two adjacent horizontal lines. The second vertical axis interpolation means 80 and the second time axis interpolation means 70 and the second vertical axis interpolation means 80 which interpolate in the vertical direction are added to each other to receive a predetermined mixing ratio control signal. A second mixing means 90 for mixing and outputting at a mixing ratio corresponding thereto and a first time axis interpolating means for interpolating in the period axis direction by sequentially adding and outputting two adjacent frame signals in units of frames in response to a luminance signal (( 10) and a first vertical axis interpolating the vertical axis by sequentially adding two adjacent horizontal lines after delaying one field in response to the luminance signal. The interpolation means 20 and the signal interpolated by the first time axis interpolation means 10 and the signals interpolated by the first vertical axis interpolation means 20 are mixed with each other. A first mixing means 30 for mixing and outputting at a mixing ratio, a frame difference detecting means 40 for detecting a frame difference value by taking the luminance signal and subtracting it in units of frames and taking an absolute value thereof; A field difference detecting means 50 for detecting field difference values of two adjacent fields by subtracting a one field delay signal of a signal interpolated by the vertical interpolation means 20 and a signal output by the first mixing means 30; And comparing the field difference value with a predetermined reference value, when the field difference value is larger than the reference value, the field difference value becomes smaller. When the field difference value is smaller than the reference value, the field difference value corresponds to the larger value of the field difference value and the frame difference value. Mixing ratio control system Is generated and output to the first and second mixing means (30, 90) characterized in that it comprises a mixing control means 60 for controlling the mixing ratio of the first and second mixing means (30, 90) Scan interpolation signal generation circuit. The first time delay interpolation means (10) includes a first frame delay unit (11) for delaying an input luminance signal in units of frames, and a signal delayed by the first frame delay unit (11). And an adder (12) for adding the input signal without delay and a divider (13) for dividing the level of the signal added by the adder (12). 2. The first horizontal axis interpolation means (20) according to claim 1, wherein the first vertical axis interpolation means (20) receives a signal delayed by the first field delay unit (21) and the first field delay unit (21) for delaying the input luminance signal by one field. A delayed first line delayer 22, an adder 23 that adds outputs of the first field delayer 21 and the first line delayer 22, and the adder 23, And a divider (24) for dividing the signal. The method of claim 1, wherein the first mixing means (30) comprises: a subtractor (31) for subtracting the output of the first time axis interpolation means (10) and the output of the first vertical axis interpolation means (20), A multiplier 32 that receives the output of the adder 31 and multiplies by a mixing ratio corresponding to the value of the mixing ratio control signal, adds the value multiplied by the multiplier 32 and the output of the first vertical axis interpolation means 20. Scan interpolation signal generation circuit, characterized in that consisting of an adder (33). The frame difference detecting means (40) according to claim 1, wherein the frame difference detecting means (40) comprises: a second frame delay (41) for delaying the luminance signal by one frame, a signal delayed by the third frame delay (41), and the brightness signal. And a subtractor (42) for calculating the difference of the difference and an absolute value (43) for detecting the absolute value of the signal subtracted by the subtractor (42). 2. The field difference detecting means (50) according to claim 1, wherein the field difference detecting means (50) comprises a third field delay (51) for delaying the output of the first mixing means (30) by one field and the third field delay (51). And a subtractor (52) for calculating a difference between an output and an output of the first vertical axis interpolation means (20). The method according to claim 1, wherein the mixing control means (60) compares the reference value generator (61) generating a predetermined reference value with the output of the reference value and the frame difference detecting means (40) and corresponding to the comparison result. Comparing the output of the frame difference detecting means 40 with the output of the field difference detecting means 50 and the second switching control corresponding to the result of the comparison. Selectively outputting the output of the frame difference detecting means 40 and the output of the field difference detecting means 50 by using the second switching control means 63 for generating and outputting a signal and the second switching control signal as a control signal. A first switching means for outputting the output of the frame difference detecting means 50 and the output of the second switching means 64 selectively using the second switching means 64 for outputting and the first switching control signal as a control signal; Scan interpolation signal, characterized in that consisting of a switching means (65) As saenghoe. The second time delay interpolation means (70) includes: a second frame delay (71) for delaying an input color signal by one frame, the second frame delay (71), and the second frame delay (2). And an adder 72 for adding the delayed signal and the color signal input without delay, and a divider 73 for dividing the level of the signal added by the interleaver 72. A scan interpolation signal generation circuit. 2. The second vertical axis interpolation means (80) according to claim 1, wherein the second vertical axis interpolation means (80) receives a second field delay unit (81) for delaying the input color signal by one field and a signal delayed by the second field delay unit (81). A second line delay unit 82 for delaying horizontal lines, an adder 83 for adding outputs of the second field delay unit 81 and the second line delay unit 82, and the adder 83 And a divider (84) for dividing the added signal. 2. The first mixing means (90) according to claim 1, further comprising: a subtractor (91) for subtracting the output of the second time axis interpolation means (70) and the output of the second vertical axis interpolation means (80), and the adder ( A multiplier 92 which receives the output of 91 and multiplies by a ratio corresponding to the value of the mixing ratio control signal, and an adder which adds the value multiplied by the multiplier 92 and the output by the second vertical axis interpolation means 80; A scan interpolation signal generation circuit, characterized by comprising (93). In the scanning interpolation method of television, the color and luminance signals are sequentially added in units of frames to interpolate in the time axis direction, and the two adjacent horizontal lines are sequentially added after delaying one field by receiving the color and luminance signals in the vertical axis direction. After interpolation, the signals interpolated in the direction of the time axis and the vertical axis are mixed, and a predetermined mixing ratio control signal is received and mixed at a corresponding mixing ratio, and the output is outputted. The luminance or color signal is subtracted in units of frames to take an absolute value. Detecting a frame difference value, subtracting a signal obtained by delaying the interpolated signal and the mixed output signal by one field, detecting a field difference value, comparing the field difference value with a reference value, and then If the value is larger than the reference value, the field difference value is obtained. If the field difference value is smaller than the reference value value, And generating a interpolated field signal by generating a mixed ratio control signal corresponding to a larger value of the field difference value and the frame difference value, and then controlling the mixing ratio through the mixed ratio control signal.