JP2001197450A - Video signal reproducing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To resolve the problem where image quality of a sequential scanning video signal is deteriorated more than that in an interlaced scanning video signal, because the disturbance in the periphery of the outline is reduced and components of overshoots, ringings, etc., in the periphery of the outline due to outline enhancement are seen in the sequential scanning video signal. SOLUTION: An outline detection means, which detects change of a luminance signal of a main video signal, a filter means which changes frequency characteristics of the output of a sequential scanning video signal reproducing means, and a control means which controls the frequency characteristics of the filter means by the output of the outline detection means are provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a video signal reproducing apparatus for transferring various video information such as a movie material and a video material such as a DVD and a satellite broadcast and sequentially scanning and reproducing the video signal.

[0002]

2. Description of the Related Art Conventionally, video output of DVDs and satellite broadcasts is usually output by interlaced scanning so that it can be reproduced by a television receiver. With the spread of video signals and the like, video signal reproducing apparatuses for converting these interlaced video signals into progressively scanned video signals are being introduced.

FIG. 10 is a block diagram showing a configuration of a conventional video signal reproducing apparatus. In the figure, reference numeral 1 denotes a disk, in which a video signal composed of either a video signal obtained by converting a film material video into an electrical signal or a video signal using a video signal as a material is encoded in a signal form suitable for recording in advance, Modulated and recorded. Reference numeral 2 denotes a pickup, which converts a signal recorded on the disk 1 into an electric signal. Reference numeral 3 denotes a disk rotating device which rotates the disk 1 at a rotation speed suitable for reproduction. Reference numeral 4 denotes an interlaced scanning video signal reproducing circuit which demodulates and decodes the video signal recorded on the disk 1 and outputs it as an interlaced scanning video signal. 5 is NT
The SC encoder converts the interlaced scanning video signal into the NTSC video format and outputs it. Reference numeral 6 denotes an interlaced scanning video signal output terminal from which an interlaced scanning video signal reproduced from this terminal is output. Reference numeral 7 denotes a progressive scanning video signal conversion circuit, which converts the output of the interlaced scanning video signal reproducing circuit 4 into a progressive scanning video signal and outputs it. Reference numeral 8 denotes a memory having the ability to store video signals for one field, and is used for the operation of the progressive scanning video signal conversion circuit 7. Reference numeral 9 denotes a color difference converter which converts the output of the progressive scanning video signal conversion circuit 7 into a progressive scanning color difference signal and outputs the signal. Reference numeral 10 denotes a progressive scanning video signal output terminal from which a progressive scanning video signal is output to a video display device (not shown).

The operation of the conventional video signal reproducing apparatus configured as described above will be further described.

FIG. 11 is a schematic diagram showing the structure of an interlaced scanning video signal and a progressive scanning video signal of a conventional video signal reproducing apparatus. In the interlaced scanning video signal, 1/60 second
An image of the field is composed, and the two
It becomes a frame image. The number of vertical pixels in each of the two fields is 240, and the pixels are arranged so as to fill the space between the pixels in the vertical direction. In the progressive scanning signal, one frame is 1/60 second and the number of vertical pixels is 480.

In both cases, the vertical frequency is 1/60 second, and the number of horizontal scanning lines is twice as large as that of the interlaced scanning video signal. Therefore, the horizontal scanning frequency is about 15.75 KHz. On the other hand, it becomes about 31.5 KHz in the progressive scanning video signal.

FIG. 12 is a schematic diagram showing a structure of a video signal of a conventional video signal reproducing apparatus. As shown in FIG. 12, the video signal recorded on the disk 1 has two forms.
That is, a) shown in FIG. 12 is a film material. In this case, the original material is a film image composed of pictures of 24 frames per second, and 720 dots horizontally and 48 pixels vertically for each frame.
The image is compressed as a 0-dot image and recorded on the disk 1. FIG. 12B shows a video material image. In this case, the original material is an interlaced scan image of 30 frames / 60 fields per second. Each frame is 720 horizontal
Although the image has 480 dots vertically and 480 dots vertically, since it is interlaced scanning, each field has 720 horizontal dots and 240 vertical dots.
It becomes a dot image, which is compressed and recorded on the disk 1.

When the material of the video signal recorded on the disk 1 is a film, as shown in a-1) of FIG.
, N, n + 1, n + 2, n + 3,... The pickup 2 converts the thus recorded film material signal into an electric signal, and the interlaced scanning video signal reproducing circuit 4 demodulates the signal, converts the signal into an interlaced scanning image, and outputs the converted signal. This is because a television monitor is generally most often used as an image display device for viewing at home, and its display format is interlaced scanning. Further, the television monitor has a rate of 30 frames / 60 fields per second. Since it is designed to handle moving images, the interlaced scanning video signal reproducing circuit 4 simultaneously operates at 24
The frame image is converted into an interlaced scan image of 30 frames / 60 fields per second and output. That is, the interlaced scanning video signal reproducing circuit 4 converts each frame of the record information into odd and even as shown in a-2) interlaced scanning video output in FIG.
n into two interlaced scan field images,
By repeatedly displaying the first field for each frame after the last field, 24 frames per second film image is converted into a 30 frames / 60 fields per second interlaced scan image and output. The NTSC encoder 5 converts the interlaced video signal reproduced in this manner into an NTSC signal.
A standard video signal is output to the interlaced scanning video signal output terminal 6. A television monitor (not shown) is connected to the interlaced scanning video signal output terminal 6, so that the user can watch the film material video converted into the interlaced scanning video.

Further, an interlaced scanning video signal reproducing circuit 4
Inputs the interlaced scanning video signal to the progressive scanning video signal conversion circuit 7. The progressive scanning video signal conversion circuit 7 is provided in FIG.
In the interlaced scan video output shown in a-2), the first field is stored in the first memory 7 for each frame, the second field is stored in the first memory 7, and the information of both is stored in the first memory 7.
By reading at the double speed for each line, a-3) in FIG.
The progressive scanning video output shown in FIG. The converted video signal is converted to an analog progressive scanning color difference signal by a color difference converter 9 and output from a progressive scanning video signal output terminal 10.
A progressive scan video signal television monitor (not shown) is connected to the progressive scan video signal output terminal 10 so that the user can view the film material video returned to the progressive scan video.

If the material of the video signal recorded on the disk 1 is video, the interlaced scanning video signal reproducing circuit 4 reads the signal recorded on the disk 1 from the output of the pickup 2 and demodulates it. 12b-2), as shown in the interlaced scanning video output, the interlaced scanning video signal is output as it is, and the NTSC encoder 5
A standard video signal is output to the interlaced scanning video output terminal 6.

Further, an interlaced scanning video signal reproducing circuit 4
Inputs the interlaced scanning video signal to the progressive scanning video signal conversion circuit 7. In the case of a video material, the progressive scanning video signal conversion circuit 7 generates a progressive scanning video signal using two pieces of field information, namely, field video information and a field located before it. At this time, the progressive scan video signal conversion circuit 7 outputs the interlaced scan video output of b-2) in FIG.
Vertical interpolation is also performed using the data of the previous field for pixels with small movement between the interlaced scan video output of the previous field, and pixels with large movement between the previous field are vertically interpolated in the same field. By generating the vertical interpolation data using the pixel data of (a), the progressive scanning video output shown in (b-3) of FIG. 12 is obtained. The converted video signal is converted to an analog progressive scanning color difference signal by a color difference converter 9 and output from a progressive scanning video signal output terminal 10.

FIG. 13 is a schematic diagram showing edge signal characteristics of a video signal of a conventional video signal reproducing apparatus. In these materials, edges are emphasized in the material state in order to increase sharpness during interlaced scanning reproduction.

This is a well-known method called a differential mask system, in which a second derivative signal of a captured main video signal is inverted and synthesized with a main video. In FIG. 13, (c) is a luminance signal of the main video signal, the edge of which is rounded. (D) is a first derivative signal of the luminance signal of the main video signal, and a peak is formed at a rising portion of the main video signal. (E) is a signal obtained by inverting the second derivative signal of the main video signal luminance signal. The signal is negative in the first half of the edge portion and positive in the second half. (F) is a signal obtained by adding a luminance signal of the main video signal and a signal obtained by inverting the secondary differential signal, and this is an output signal in which contour enhancement is performed.

By applying the contour emphasis to the material, the sharpness of the interlaced scanning video signal output is increased.

[0015]

However, in the interlaced scanning image, there is an obstruction accompanying the interlaced scanning in the outline portion, and the overshooting and ringing components around the outline due to the outline emphasis are made difficult to see. Although the image quality improvement by contour enhancement has brought good results, in the progressive scanning image, interference such as overshoot and ringing around the contour due to contour enhancement is reduced because interference around the contour is reduced and the contour is clearly visible. This is a major drawback for the video signal reproducing apparatus, in that the video signal is viewed with a lower quality than the interlaced video signal.

In the future, there is a demand for the introduction of a video signal reproducing apparatus capable of outputting a progressively scanned image which does not deteriorate in image quality compared with the interlaced scanned image visually after the progressive scan conversion.

According to the present invention, after the progressive scan conversion, the resolution is not visually deteriorated as compared with the interlaced scan image, and the edge enhancement component does not cause overshoot or ringing of the edge, so that the image quality is not significantly impaired. It is an object of the present invention to provide a video signal reproducing device capable of outputting a scanned video.

[0018]

According to the present invention, there is provided an interlaced scanning video signal reproducing means for outputting a main video signal as an interlaced scanning video signal, and outputting the main video signal as a progressively scanned video signal. Progressive scanning video signal reproducing means; contour detecting means for detecting a change in the luminance signal of the main video signal; filter means for changing the frequency characteristic of the output of the progressive scanning video signal reproducing means; Control means for controlling the characteristic, wherein the control means controls the high-frequency characteristic of the filter means in accordance with the magnitude of the contour component of the luminance signal output from the progressive scanning video signal reproducing means detected by the contour detection means. ,
Video signal reproduction that reduces overshoot and ringing around the contour by limiting the frequency characteristics around the contour, and enables the output of progressively scanned images without any deterioration in image quality compared to the interlaced scan image visually. A device is obtained.

[0019]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The invention according to claim 1 of the present invention is an interlaced scanning video signal reproducing means for outputting a main video signal as an interlaced scanning video signal, and a sequential output for outputting the main video signal as a progressively scanned video signal. Scanning video signal reproducing means, contour detecting means for detecting a change in the luminance signal of the main video signal, filter means for changing the frequency characteristic of the output of the progressive scanning video signal reproducing means, and frequency characteristic of the filter means by the output of the contour detecting means Control means for controlling the high-frequency characteristic of the filter means in accordance with the magnitude of the contour component of the luminance signal output from the progressive scanning video signal reproducing means detected by the contour detection means. By limiting the frequency characteristics around the contour, overshoot and ringing around the contour are reduced,
A video signal reproducing apparatus which can output a progressively scanned image without deterioration in image quality as compared with the interlaced scanned image can be obtained.

In the invention according to a second aspect of the present invention, the contour detection means outputs the absolute value of the primary differential value of the luminance signal output from the progressive scanning video signal reproducing means, thereby outputting the progressive scanning video output. The contour is detected, and the control means controls the high-frequency characteristic of the filter means in accordance with the magnitude of the contour component of the luminance signal output from the progressive scanning video signal reproducing means detected by the contour detection means, thereby controlling the vicinity of the contour. Provided is a video signal reproducing apparatus capable of reducing overshooting and ringing around a contour by restricting a frequency characteristic and outputting a progressively scanned image with no deterioration in image quality as compared with an interlaced scanned image visually. .

According to a third aspect of the present invention, the control means controls the high-frequency characteristic of the filter means in accordance with the magnitude of the contour component of the luminance signal output from the progressive scanning video signal reproducing means detected by the contour detecting means. , By changing the filter stepwise according to the size of the contour, limiting the frequency characteristics around the contour, reducing overshoot and ringing around the contour, and skipping visually Provided is a video signal reproducing apparatus capable of outputting progressively scanned video without deterioration in image quality as compared with video.

According to a fourth aspect of the present invention, the control means makes the frequency characteristics of the filter means different between when the main video signal is a film material and when the video signal is a material. By changing the limit amount of frequency characteristics around the contour according to the material, the overshoot and ringing around the contour are reduced, and the progressively scanned image is not visually degraded compared to the interlaced scan image. To provide a video signal reproducing device capable of outputting a video signal.

According to a fifth aspect of the present invention, the progressive scanning video signal reproducing means converts the output of the interlaced scanning video signal reproducing means to a scanning line, and the control means controls the progressive scanning video signal detected by the contour detecting means. By controlling the high-frequency characteristics of the filter means in accordance with the magnitude of the contour component of the luminance signal output from the reproducing means, limiting the frequency characteristics around the contour to reduce overshoot and ringing around the contour. Thus, it is possible to obtain a video signal reproducing apparatus which can output a progressively scanned image without deterioration in image quality as compared with an interlaced scanned image.

According to a sixth aspect of the present invention, the interlaced scanning video signal reproducing means converts the output of the progressive scanning video signal reproducing means into a scanning line, and the control means controls the progressive scanning video signal detected by the contour detecting means. By controlling the high-frequency characteristics of the filter means in accordance with the magnitude of the contour component of the luminance signal output from the reproducing means, limiting the frequency characteristics around the contour to reduce overshoot and ringing around the contour. Thus, it is possible to obtain a video signal reproducing apparatus which can output a progressively scanned image without deterioration in image quality as compared with an interlaced scanned image.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1) FIG. 1 is a block diagram showing a configuration of a video signal reproducing apparatus according to Embodiment 1 of the present invention. In FIG. 1, reference numeral 1 denotes a disk, and a main video signal composed of either a video signal obtained by converting a film material video into an electric signal or a video signal using a video signal as a material,
It is encoded in a signal form suitable for recording in advance, modulated and recorded. Reference numeral 2 denotes a pickup, which converts a signal recorded on the disk 1 into an electric signal. Reference numeral 3 denotes a disk rotating device which rotates the disk 1 at a rotation speed suitable for reproduction. Reference numeral 4 denotes an interlaced scanning video signal reproducing circuit.
, Demodulates and decodes the main video signal recorded on the main video signal, and outputs it as an interlaced scanning video signal. Reference numeral 5 denotes an NTSC encoder which converts an interlaced scanning video signal into an NTSC video format and outputs it. Reference numeral 6 denotes an interlaced scanning video signal output terminal from which an interlaced scanning video output reproduced from this terminal is output. Reference numeral 7 denotes a progressive scanning video signal conversion circuit, which converts the output of the interlaced scanning video signal reproducing circuit 4 into a progressive scanning video signal and outputs it. Reference numeral 8 denotes a memory having the ability to store video signals for one field, and is used for the operation of the progressive scanning video signal conversion circuit 7. Reference numeral 9 denotes a color difference converter which converts the output of the progressive scanning video signal conversion circuit 7 into a progressive scanning color difference signal and outputs the signal. Reference numeral 10 denotes a progressive scanning video signal output terminal from which a progressive scanning video signal is output to a video display device (not shown). Reference numeral 11 denotes a primary differentiating circuit which outputs the absolute value of the primary differentiation of the luminance output of the progressive scanning video signal converting circuit 7. 1
A control circuit 2 controls the frequency characteristics of the variable filter 13 according to the output of the primary differentiating circuit 11 and the output of the material discriminating circuit 14. Reference numeral 13 denotes a variable filter circuit which changes the frequency characteristics of the output of the progressive scanning video signal conversion circuit 7 according to the setting of the control circuit 12. Reference numeral 14 denotes a material discriminating circuit, which discriminates from the output of the pickup 2 whether the material of the video signal recorded on the disc 1 is a film or a video, and outputs it to the control circuit 12. Reference numeral 15 denotes a first switch, which allows the user to switch the control circuit 12 on and off.

The operation of the video signal reproducing apparatus according to the present embodiment configured as described above will be further described.

FIG. 2 is a schematic diagram showing the structures of the interlaced scanning video signal and the progressive scanning video signal of the video signal reproducing apparatus according to the first embodiment of the present invention. In the interlaced scanning video signal, 1
An image of one field is constituted by / 60 seconds, and two images are combined to form an image of one frame. The number of vertical pixels in each of the two fields is 240, and the pixels are arranged so as to fill the space between the pixels in the vertical direction. In the progressive scanning signal, one frame is 1/60 second and the number of vertical pixels is 4
80.

In both cases, the vertical frequency is 1/60 second, and the number of horizontal scanning lines is twice as large as that of the interlaced scanning video signal, so that the horizontal scanning frequency is about 15.75 KHz. On the other hand, it becomes about 31.5 KHz in the progressive scanning video signal.

FIG. 3 is a schematic diagram showing a structure of a video signal of the video signal reproducing apparatus according to the first embodiment of the present invention. As shown in FIG. 3, the video signal recorded on the disk 1 has two forms. That is, a) shown in FIG. 3 is a film material,
In this case, the original material is a film image composed of pictures of 24 frames per second, and is compressed and recorded on the disk 1 as an image of 720 horizontal dots and 480 vertical dots for each frame. B) shown in FIG. 3 is a video material image, in which the original material is 30 frames per second
This is an interlaced scan image of field 0. Each frame is an image of 720 horizontal dots and 480 vertical dots, but since it is interlaced scanning, each field becomes an image of 720 horizontal dots and 240 vertical dots, and is compressed and recorded on the disk 1.

When the material of the video signal recorded on the disk 1 is a film, as shown in a-1) of FIG.
On a disc made of film material, the frame number is ...
are recorded in the order of n, n + 1, n + 2, n + 3,... The pickup 2 converts the thus recorded film material signal into an electric signal, and the interlaced scanning video signal reproducing circuit 4 demodulates the signal, converts the signal into an interlaced scanning image, and outputs the converted signal. This is because a television monitor is generally most often used as an image display device for viewing at home, and its display format is interlaced scanning.
Because it is designed to handle 0-field video,
At the same time, the interlaced scanning video signal reproducing circuit 4 converts an image of 24 frames per second into an interlaced scanning video of 30 frames / 60 fields per second and outputs it. That is, the interlaced scanning video signal reproducing circuit 4 converts each frame of the recording information into odd and even as shown in a-2) interlaced scanning video output in FIG.
By dividing the frame image into two interlaced scan field images and displaying the first field repeatedly after the last field for each frame, a film image of 24 frames per second is converted into an interlaced scan image of 30 frames per second / 60 fields. Output.

When the material of the video signal recorded on the disk 1 is video, the interlaced scanning video signal reproducing circuit 4 reads the signal recorded on the disk 1 from the output of the pickup 2 and demodulates the signal. As shown in 3b-2), the interlaced scanning video signal is output as it is as the interlaced scanning video signal.

The NTSC encoder 5 converts the interlaced scanning video signal thus reproduced into an NTSC standard video signal, and outputs it to the interlaced scanning video signal output terminal 6.
A television monitor (not shown) is connected to the interlaced scanning video signal output terminal 6 so that the user can watch the video material video reproduced as the interlaced scanning video.

Further, the interlaced scanning video signal reproducing circuit 4
Inputs the interlaced scanning video signal to the progressive scanning video signal conversion circuit 7. When the material is a film, the progressive scan video signal conversion circuit 7 stores the head scan field of the interlaced scan video output shown in a-2) of FIG. Field into first memory 8
, And the information of both is read out at a double speed line by line to obtain a progressively scanned video output shown in a-3) of FIG. When the material is video, the progressive scanning video signal conversion circuit 7 generates a progressive scanning video signal using two pieces of field information, namely, field video information and a field located before it. At this time, the progressive scan video signal conversion circuit 7 outputs the data of the previous field for the pixel having a small motion between the interlaced scan video output of b-2) of FIG. 3 and the interlace scan video output of the immediately preceding field. The vertical scanning data shown in FIG. 3B-3) is generated by generating vertical interpolation data from upper and lower pixel data in the same field for pixels having a large movement between the previous field and the vertical interpolation using Get output.

The output of the progressive scanning video signal conversion circuit 7 is 1
It is input to the next differentiating circuit 11 and the variable filter circuit 13.

FIG. 4 is a block diagram showing a configuration of the primary differentiating circuit 11 of the video signal reproducing apparatus according to the first embodiment of the present invention. In FIG. 4, reference numeral 16 denotes a first DFF, which gives a delay obtained by a clock input to a luminance signal input and outputs it. Reference numeral 17 denotes a first subtractor, which inputs a luminance signal and a first DF.
The difference between the outputs of F17 is determined. 18 is a (-1) multiplier,
The sign of the output of the first subtractor 17 is inverted. Reference numeral 19 denotes a second switch, which switches and outputs the outputs of the first subtractor 17 and the (-1) multiplier 18 in accordance with the sign output of the first subtractor 17.

With such a configuration, the first subtractor 17
Outputs the difference value of the luminance signal before and after being delayed by the first DFF 16. That is, the output of the first subtractor 17 determines the differential value of the luminance signal. The differential value of the luminance signal can take both positive and negative values depending on the change direction of the luminance signal. Therefore, the sign output of the first subtractor 17 is
By switching the output of the multiplier 18 and the output of the (-1) multiplier 18 in which the sign of the value is changed, a positive value, that is, the absolute value of the luminance differential component can always be obtained from the second switch 19.

FIG. 5 is a block diagram showing a configuration of the variable filter circuit 13 of the video signal reproducing device according to the first embodiment of the present invention.

In the figure, reference numeral 20 denotes a first delay circuit,
The input luminance signal is delayed for a predetermined time and output.
Reference numeral 21 denotes a second DFF, which gives an input signal a delay obtained by a clock input and outputs it. 22 is the third DF
F, giving the input signal a delay obtained by the clock input and outputting it. 23 is a first adder, which adds the outputs of the first delay circuit 20 and the third DFF 22. 2
Reference numeral 4 denotes a (1/4) multiplier, which multiplies the output of the first adder 23 by 1/4 and outputs the result. Reference numeral 25 denotes a (1/2) multiplier, which multiplies the output of the second DFF 21 by 1/2 and outputs the result.
Reference numeral 26 denotes a second subtractor, which subtracts the output of the (１ ／) multiplier 25 from the output of the (１ ／) multiplier 24 and outputs the result. 27 is a (k / 16) multiplier, and a second subtractor 2
6 is multiplied by k / 16 and output. Reference numeral 28 denotes a third subtractor, which subtracts the output of the (k / 16) multiplier 27 from the output of the second DFF 21 and outputs the result. Reference numeral 29 denotes a second delay circuit, which delays the input of the color difference signal by a predetermined time and outputs it.

The operation of the thus configured variable filter circuit 13 of the video signal reproducing apparatus according to the first embodiment of the present invention will be described.

The second DFF 21 and the third DFF 22
, A first adder 23, a (1/4) multiplier 24,
(1/2) multiplier 25, second subtractor 26, (k /
16) The multiplier 27 and the third subtractor 28 constitute a filter circuit, and the transfer function H (Z) is expressed as follows: H (Z) = 1− (k / 16) · (Z ⁻¹ / 4-1) / 2 + Z
^{1/4) where, Z -1 = exp (-jωt)} , ω: the signal angular frequency, t: a clock period.

FIG. 6 is a diagram showing frequency characteristics of the variable filter circuit 13 of the video signal reproducing device according to the first embodiment of the present invention.

The vertical axis of the figure is the gain, and the horizontal axis is the frequency. fs / 2 is half the clock frequency fs.

As shown in the figure, when k = 0, the frequency characteristic becomes flat, and as k decreases, the high-frequency characteristic deteriorates.
At the time of −8, the frequency fs / 2, which is half of the clock frequency fs
Has a characteristic that the gain is 0.5.

FIG. 7 is a block diagram showing a configuration of the control circuit 12 of the video signal reproducing apparatus according to the first embodiment of the present invention.

In the figure, reference numeral 30 denotes a first comparator, which compares the input of the primary differential absolute value signal with a predetermined first threshold value and outputs the result. Reference numeral 31 denotes a first mono-multi, which is triggered when the first comparator 30 detects that the primary differential absolute value signal input is larger than a first threshold, and generates a pulse for a predetermined time. A second comparator 32 compares the input of the primary differential absolute value signal with a predetermined second threshold value and outputs the result. 33 is the second
Is triggered when the second comparator 32 detects that the primary differential absolute value signal input is larger than the second threshold value, and generates a pulse for a fixed time. Reference numeral 34 denotes a third comparator which compares the input of the primary differential absolute value signal with a predetermined third threshold value and outputs the result. Reference numeral 35 denotes a third mono-multi, which is triggered when the third comparator 34 detects that the primary differential absolute value signal input is larger than a third threshold, and generates a pulse for a predetermined time. 36 is a fourth comparator,
The first differential absolute value signal input is compared with a predetermined fourth threshold value and output. 37 is a third mono-multi,
The fourth comparator 34 is triggered when it detects that the primary differential absolute value signal input is larger than the fourth threshold value, and generates a pulse for a fixed time. Reference numeral 38 denotes a k decision circuit, which includes a first monomulti 31 and a second monomulti 3.
3, a third monomulti 35, and a fourth monomulti 37
Then, the value of k is determined and output based on the material determination input and the switch input.

Since the input luminance signal takes an 8-bit width value, in FIG. 7, the first-order absolute value signal value can take an 8-bit value, that is, a value from 0 to 255. Therefore, the first
Are set to 128, the second threshold is set to 64, the third threshold is set to 32, and the fourth threshold is set to 16.

That is, the first monomulti 31 generates a pulse having a fixed time width when the first derivative absolute value signal value exceeds 128, and the second monomulti 33 generates the first derivative absolute value signal value of 6.
When the signal value exceeds 4, the third monomulti 35 generates a pulse having a predetermined time width when the first derivative absolute value signal value exceeds 32, and the fourth monomulti 37 generates the first derivative absolute signal. When the value signal value exceeds 16, a pulse of a fixed time width is generated.

Now, when there is a switch input, the logic of the k decision circuit is set as shown in Table 1.

[0050]

[Table 1]

The logic of the k decision circuit is always set to k = 0 when there is no switch input.

FIG. 8 is a timing chart showing the edge signal characteristics of the video signal of the video signal reproducing apparatus according to the first embodiment of the present invention. In these materials, edges are emphasized in the material state in order to increase sharpness during interlaced scanning reproduction.

This is called a differential mask method, which is well known, and is a method of inverting a secondary differential signal of a captured main video signal and synthesizing it with the main video. In the figure, (c) is a luminance signal of the main video signal, and the edge is dull. (D) is a first derivative signal of the luminance signal of the main video signal, and a peak is formed at a rising portion of the main video signal. (E) is a signal obtained by inverting the second derivative signal of the main video signal luminance signal. The signal is negative in the first half of the edge portion and positive in the second half. (F) is a signal obtained by adding a luminance signal of the main video signal and a signal obtained by inverting the secondary differential signal, and this is an output signal in which contour enhancement is performed. That is, in FIG. 1, the video signal output from the interlaced scanning video signal output terminal 6 outputs the video signal whose edge is emphasized.

FIG. 9 is a timing chart showing the operation of the primary differentiating circuit 11, the control circuit 12, and the variable filter circuit of the video signal reproducing apparatus according to the first embodiment of the present invention. In the figure,
(g) shows the luminance signal input to the variable filter circuit, which is the luminance signal output of the progressive scanning video signal conversion circuit 7 in FIG. As described above, this signal is contour-emphasized. FIG. 9 (h) shows the output of the primary differentiating circuit. When this is shown to the control circuit 12, the output of the primary differentiating circuit exceeding the threshold value of the first comparator 30 of FIG. Mono multi 31 is triggered,
Generates "1". Now, when the material is a film and the switch is turned on, the output of the k decision circuit 38 in FIG. 7 is based on the logic shown in Table 1, and as shown in FIG. A certain time after the first threshold is exceeded, k
= −8, otherwise k = 0. Now, if the delay time of the first delay circuit is set to be half of the time during which the first mono-multi 31 outputs 1, as shown in FIG. It is possible to set k = -8 for a certain time before and after the contour appears in the output of the delay circuit, and to set k = 0 otherwise. As shown in FIG. 6, the characteristic of the variable filter circuit 13 becomes a low-pass filter when k = −8. Therefore, as shown in FIG. It is possible to obtain a natural waveform that has been removed and has no contour emphasis. K = 0 except for the periphery of the contour, and the variable filter circuit 13
Since the frequency characteristics of the image signal become flat, the details of the video signal are preserved, and the resolution does not deteriorate.

The second delay circuit 29 in FIG. 5 functions to delay the color difference signal in accordance with the delay of the luminance signal generated by the first delay circuit 20 and the second DFF 21.

Similarly, according to the peak value of the contour, Table 1
The frequency characteristic of the contour portion is controlled by the logic shown in (1), and accurate correction is performed according to the strength of the contour. Also, in Table 1, the value of k is different between the case where the material is video and the case where the material is film. This is because, in the case of film, the outline is smoothed to obtain an image quality closer to that of a movie. is there.

The progressive scanning video signal from which the contour enhancement has been removed in this manner is converted into an analog progressive scanning chrominance signal by the color difference converter 9 and the progressive scanning video signal output terminal 10
Output from The progressive scan video signal output terminal 10 is connected to a progressive scan video signal television monitor (not shown) so that the user can view the video material video converted into the progressive scan video. The user can also disable the contour emphasis removal function by using the first switch 15.

As described above, according to the video signal reproducing apparatus of the first embodiment of the present invention, after the progressive scan conversion, the resolution is not visually deteriorated as compared with the interlaced scan video, and the edge emphasis component is the edge. It is possible to provide a video signal reproducing device capable of outputting progressively scanned video without causing significant overshoot or ringing and thereby significantly deteriorating the image quality.

In the above description, the magnitude of the contour is determined and corrected by using four types of thresholds. However, the effect of the present invention does not change regardless of the type. The effect of the present invention can be expected as long as the variable filter circuit characteristic is a low-pass filter, and the circuit configuration is not limited to the circuit shown in FIG. In addition, the value of k is changed according to the material discrimination. However, it is not always necessary to change the value. Even if k is the same for the film material and the video material, the effect of the present invention is to remove the edge enhancement component. Is possible. Although the control function can be switched on and off by the user, the effect of the present invention can be obtained even if the control function is fixed in the on state. Further, the value of k can be selected in several steps by the user, and the strength of contour removal can be varied according to the user's preference. Although a circuit block description is shown in FIG. 1, each element after reference numeral 4 in the drawing may be replaced by a microprocessor or the like and realized by software.

Further, the example in which the video signal reproducing device is constituted by a disk device has been described, but other video signal reproducing devices such as a tape device, a broadcast receiver (wireless / wired),
Alternatively, the present invention can be similarly applied to an image reproducing apparatus using a semiconductor memory in which a rapid increase in capacity is in progress, or a video signal reproducing apparatus for inputting video through Internet distribution.

[0061]

As described above, according to the present invention, the overshoot and ringing around the contour are reduced by limiting the frequency characteristics around the contour, and the visual characteristics are also compared with the interlaced scanning image. Thus, a video signal reproducing apparatus capable of outputting progressively scanned video without deterioration in image quality can be obtained.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a video signal reproducing device according to a first embodiment of the present invention.

FIG. 2 is a schematic diagram showing the structures of an interlaced scanning video signal and a progressive scanning video signal.

FIG. 3 is a schematic diagram showing a structure of a video signal according to the first embodiment;

FIG. 4 shows one of the video signal reproducing apparatuses according to the first embodiment of the present invention.
The block diagram which shows the internal structure of the next differentiating circuit 11.

FIG. 5 is a block diagram showing an internal configuration of a variable filter circuit 13 of the video signal reproducing device according to the first embodiment of the present invention.

FIG. 6 is a diagram illustrating frequency characteristics of a variable filter circuit 13 of the video signal reproducing device according to the first embodiment of the present invention.

FIG. 7 is a block diagram showing an internal configuration of a control circuit 12 of the video signal reproducing device according to the first embodiment of the present invention.

FIG. 8 is a timing chart showing edge signal characteristics of a video signal of the video signal reproducing device according to the first embodiment of the present invention.

FIG. 9 shows one of the video signal reproducing apparatuses according to the first embodiment of the present invention.
FIG. 4 is a timing chart showing the operation of the secondary differentiating circuit 11, the control circuit 12, and the variable filter circuit.

FIG. 10 is a block diagram showing a configuration of a conventional video signal reproducing apparatus.

FIG. 11 is a schematic diagram showing the structures of an interlaced scanning video signal and a progressive scanning video signal of a conventional video signal reproducing apparatus.

FIG. 12 is a schematic diagram showing a structure of a video signal of a conventional video signal reproducing device.

FIG. 13 is a timing chart showing edge signal characteristics of a video signal of a video signal reproducing device of a conventional video signal reproducing device.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 disc 2 pickup 3 disc rotating device 4 interlaced scanning video signal reproducing circuit 5 NTSC encoder 6 interlaced scanning video signal output terminal 7 progressive scanning video signal conversion circuit 8 memory 9 color difference converter 10 progressive scanning video signal output terminal 11 primary differentiating circuit 12 Control circuit 13 Variable filter circuit 14 Material discriminating circuit 15 First switch 16 First DFF 17 First subtracter 18 (-1) Multiplier 19 Second switch 20 First delay circuit 21 Second DFF 22 Third DFF 23 First adder 24 (1/4) multiplier 25 (1/2) multiplier 26 Second subtractor 27 (k / 16) multiplier 28 Third subtractor 29 Second Delay circuit 30 First comparator 31 First monomulti 32 Second comparator 33 Second monomulti 34 Third Comparator 35 Third mono multi 36 Fourth comparator 37 Fourth mono multi 38 k decision circuit

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5B057 BA30 CE06 DC16 DC22 5C021 PA17 PA31 PA42 PA53 PA57 PA66 PA67 PA75 PA79 PA82 PA83 RA02 RB03 SA21 XB03 XB06 5C063 AA01 AA06 AC01 BA04 CA18 5L096 FA06 GA02 GA08 GA41 GA55 HA02H KK31

Claims (6)

[Claims] 1. A video signal reproduction for reproducing a main video signal composed of either a first type of video signal obtained by converting a film material video into an electrical signal or a second type of video signal using a video signal as a material. An interlaced scanning video signal reproducing means for outputting the main video signal as an interlaced scanning video signal; a progressive scanning video signal reproducing means for outputting the main video signal as a progressive scanning video signal; Contour detecting means for detecting a change in a luminance signal; filter means for changing a frequency characteristic of an output of the progressive scanning video signal reproducing means; and control means for controlling a frequency characteristic of the filter means by the output of the contour detecting means. A video signal reproducing device characterized by the following. 2. The video signal reproducing apparatus according to claim 1, wherein said contour detecting means outputs the absolute value of a primary differential value of the luminance signal output from the progressive scanning video signal reproducing means. 3. The control means controls the high-frequency characteristic of the filter means according to the magnitude of the contour component of the luminance signal output from the progressive scanning video signal reproducing means detected by the contour detecting means. Item 3. The video signal reproducing device according to Item 1. 4. The video signal reproduction according to claim 1, wherein the control means makes the frequency characteristic of the filter means different between when the main video signal is a film material and when the video signal is a material. apparatus. 5. The video signal reproducing apparatus according to claim 1, wherein the progressive scanning video signal reproducing means converts the output of the interlaced scanning video signal reproducing means into a scanning line. 6. The video signal reproducing apparatus according to claim 1, wherein the interlaced scanning video signal reproducing means converts the output of the progressively scanned video signal reproducing means into a scanning line.