JP2000138845A - Contour correction device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a contour correction device which enhances sharpness of the contour of an original video signal without addition of a pre-shoot/ overshoot component and to provide the contour correction device that corrects the contour, without losing a property or a structure of a signal waveform of the original video signal. SOLUTION: An input video signal S1 from an input terminal 1 is given to a correction component generating circuit 4 and a gain adjustment circuit 5, which outputs a contour correction component. Since the component includes a pre-shoot/overshoot component, an amplitude limit circuit 9 limits the pre- shoot/overshot component. An angle change detection circuit 6 obtains the angle of a signal waveform, based on amplitude difference values of adjacent sample data from the video signal S1 and intervals of the sampled data that are received from delay circuits 3(1)...3(n+1), a limit angle generating circuit 7 decides the upper and lower limit of a limit angle based on the output of the circuit 6, and a limit value generating circuit 8 generates the amplitude limit value.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to various video equipment such as a television receiver (TV), a video tape recorder (VTR), and a video disk (LD, DVD, video CD), and various image processing for handling image data. The present invention relates to a device, and more particularly to a contour correction device for improving sharpness of a contour portion of an image and improving image quality.

[0002]

2. Description of the Related Art Conventionally, as a contour correction for improving sharpness of a contour portion for improving image quality, a contour correction component is obtained by a second derivative process, and the correction component is multiplied by an appropriate coefficient and added to an original signal. (For example, Nobuyuki Yagi, et al., "Practical Digital Image Processing Learned in C Language," Ohmsha, published May 10, 1995, p. 17
3, see). An example of a conventional contour correction device will be described below with reference to FIGS. FIG.
FIG. 17 is a block diagram showing a configuration of an example of a conventional contour correction device, and FIG. 17 is a diagram showing output video signals generated by each circuit unit by the operation.

In FIG. 16, 1 is an input terminal, 2 is an output terminal, 101 is a correction component generation circuit, 102 to 107 are components of the correction component generation circuit 101, and 102 and 103 are delay circuits for delaying inputs for a predetermined time. , 104 to 106 are multiplication circuits for multiplying by a predetermined value, 107 is an addition circuit, and 109 is a delay circuit for delaying an input for a predetermined time,
8 is a gain control circuit for controlling the correction component amount, and 110 is an addition circuit.

[0004] The operation of such a conventional contour correction device will be described with reference to FIGS. 16 and 17. The video signal S1 input from the input terminal 1 is supplied to the delay circuit 102, the delay circuit 10
9. The output signal S102 of the delay circuit 102 is supplied to the multiplication circuit 106, and is supplied to the delay circuit 103 and the multiplication circuit 105. The output signal S103 of the delay circuit 103 is supplied to the multiplication circuit 104. For example, if the video signal S1 is
If the signal is as shown in FIG.
2 and the output signal S103 of the delay circuit 103 are signals as shown in FIGS. 17B and 17C, respectively. These three signals have a multiplier of-／.
, A multiplication circuit 105 having a multiplier of １ ／, and a multiplication circuit 106 having a multiplier of −−１.
Output signal S104 of multiplication circuit 104, output signal S105 of multiplication circuit 105, output signal S106 of multiplication circuit 106
Are supplied to the addition circuit 107 and added.

[0005] The addition result of the addition circuit 107 is the output signal S101 of the correction component generation circuit 101, as shown in FIG.
Is a signal obtained by secondarily differentiating the original video signal S1 as shown in FIG. Output signal S101 of correction component generation circuit 101
Is supplied to the gain control circuit 108. Assuming that the gain of the gain control circuit 108 is 2, for example, the output signal S108 of the gain control circuit 108 is a signal as shown in FIG. Output signal S108 of gain control circuit 108
Is the output signal S1 of the delay circuit 109 shown in FIG.
09 together with the output signal S2 of the contour correction device.
Is output from the output terminal 2. According to the conventional contour correction device configured as described above, the output signal S2 after the contour correction has a preshoot or an overshoot on the contour portion to improve the image quality, as can be seen from FIG. While the contour is corrected, the sharpness is improved.

As another method for improving the sharpness of a contour portion without adding a preshoot or an overshoot, a contour correction device described in Japanese Patent Application No. 5-316392 is known. Hereinafter, another example of the conventional contour correction device will be described with reference to FIGS. FIG. 18 is a block diagram showing a configuration of another example of the conventional contour correction device. FIGS. 19 and 20 are diagrams showing output video signals generated in each circuit unit by the operation of the contour correction device. is there. In FIG. 18, 1 is an input terminal, 2 is an output terminal, 201 to 204 are delay circuits, 205 is a maximum value detection circuit, 206 is a minimum value detection circuit, and 207 is a position detection circuit. An arithmetic circuit 208 has 209 and 210 as its constituent elements, and 209 is an average value circuit,
Reference numeral 10 denotes a subtraction circuit. Reference numeral 211 denotes a gain adjustment circuit, 212 denotes an adder, and 213 denotes a non-linear processing circuit.

The input / output relationship of the components in the other conventional contour correction device will be described. The video signal S1 input from the input terminal 1 is delayed by the delay circuits 201 to 204. Input video signal S1, output signal S201 of delay circuit 201, output signal S20 of delay circuit 202
2. Output signal S203 of delay circuit 203 and delay circuit 2
The output signal S204 of 04 is supplied to the maximum value detection circuit 205, the minimum value detection circuit 206, and the position detection circuit 207, respectively. Also, the output signal S202 of the delay circuit 202
Is one input terminal of the subtraction circuit 210 and the addition circuit 2
12 are supplied to one of the input terminals. The output signal S205 of the maximum value detection circuit 205 is
7, are supplied to the average value circuit 209 and the non-linear processing circuit 213, respectively. The output signal S of the minimum value detection circuit 206
206 is supplied to the position detection circuit 207, the average value circuit 209, and the nonlinear processing circuit 213, respectively. Also,
The output signal S209 of the average value circuit 209 is
0 is supplied to the other input terminal. Subtraction circuit 210
Subtraction result S208 and the output signal S of the position detection circuit 207.
207 is supplied to the gain adjustment circuit 211, and the output signal S211 of the gain adjustment circuit 211 is supplied to the other input terminal of the addition circuit 212. The addition result S212 of the addition circuit 212 is subjected to nonlinear processing in the nonlinear processing circuit 213 according to the output signal S205 from the maximum value detection circuit 205 and the output signal S206 from the minimum value detection circuit 206, and is output from the output terminal 2. You.

[0008] The operation of the other conventional contour correction device will be described with reference to FIGS. In FIG. 18, it is assumed that a video signal having an outline as shown in FIG. This video signal is delayed by the delay circuits 201 to 204 to obtain signals shown in FIGS. 19A to 19E, respectively. The maximum value detection circuit 205 receives the input signals S1, S201, S201
The maximum values are output by comparing the sizes of 202, S203 and S204. Therefore, a signal shown in FIG. 19F is obtained as the output signal S205 of the maximum value detection circuit 205. The minimum value detection circuit 206 receives the input signals S1, S201, S202, S203, and S20.
4 and outputs the minimum value. Therefore, as the output signal S206 of the minimum value detection circuit 206, FIG.
9 (G) is obtained. FIG.
The signal shown in FIG. 19F and the signal shown in FIG.
Are averaged to obtain the signal shown in FIG. In the subtraction circuit 210, the output signal S of the delay circuit 202
The output signal S209 of the average value circuit 209 is subtracted from 202 to obtain a signal shown in FIG.

The position detection circuit 207 performs a logical operation from an input signal, and outputs 0 when a specific waveform is detected. In the signal as shown in FIG. 19, since a specific waveform is not detected, 1 is output as shown in FIG. 19 (J). The gain adjuster 211 sets the gain to 0 when the output signal S207 of the position detection circuit 207 is 0, and follows the original gain of the gain adjuster 211 when the output signal S207 is 1. When the gain of the gain adjuster 211 is set to 1, for example, the output signal S211 becomes the signal shown in FIG. 19K, and the adder 212 outputs the output signal S202 from the delay circuit 202 shown in FIG. Adder 2
The signal shown in FIG.
This signal is output from the nonlinear processing circuit 213 to the output signal S205 of the maximum value detection circuit 205 and the minimum value detection circuit 2
Non-linear processing is performed in accordance with the output signal S06 of FIG.

For example, by comparing the magnitudes of the signals shown in FIGS. 19 (F), 19 (G) and 19 (L), FIG.
When the signal shown in (L) is larger than the signal shown in FIG. 19 (F), the signal shown in FIG. 14 (F) is output. When the signal illustrated in FIG. 19L is smaller than the signal illustrated in FIG. 19G, the signal illustrated in FIG. 19G is output. Otherwise, the signal shown in FIG. 19 (F) is output. In other words, the amplitude is limited by using the detected maximum value or minimum value. According to this, as the output signal S2 of the nonlinear processing circuit 213, a video signal having a steep contour as shown in FIG. 19M is obtained. With the other conventional contour correction device configured as described above, it was possible to perform contour correction for improving sharpness without adding preshoot or overshoot to a contour portion for improving image quality.

[0011]

However, in the conventional contour correction device described above, the effect of the contour correction is small in a smooth contour portion, and a preshoot or an overshoot is small in a relatively steep contour portion. In some cases, this may cause a contour correction with an adverse effect such as a white line or a black line bordering the outline of the image. Further, in the other conventional contour correction device described below, since the contour correction can be performed without adding a preshoot or an overshoot, a white line or a black line can be bordered on a contour portion of an image. Adverse effects can be avoided. However, in order to avoid adding a preshoot or an overshoot, the level is limited by the maximum value and the minimum value around the target value.
As shown in FIG. 20, which is taken out from FIG. 9 to compare only the video output portion, there is a problem that the properties or structure of the signal waveform of the contour portion of the input signal and the output signal may be changed. there were. The present invention has been made in view of the above-described problems of the related art, and performs contour correction for improving the sharpness of the contour of an original video signal without adding preshoot or overshoot. It is an object of the present invention to provide a contour correction device capable of performing such correction without losing the properties or structure of a signal waveform possessed.

[0012]

Means for Solving the Problems In order to solve the above-mentioned problems, the invention of each claim of the present application constitutes the following technical means. A first aspect of the present invention is a contour correction device for correcting a video signal to enhance a contour of a video, and detects a difference value of amplitude data between video signals sampled at a predetermined sample interval as an angle change value. An angle change detecting means for selecting sample data relating to a signal to be corrected based on the detection result; and a limit angle generating means for generating an upper limit angle and a lower limit angle around the angle value detected by the angle change detect means. Means for generating an amplitude data upper limit value and an amplitude data lower limit value of a video signal based on sample data relating to the signal to be corrected selected by the angle change detecting means and the angle generated by the limited angle generating means. A limit value generating means for performing an operation; and an amplitude limiting means for limiting the amplitude data value of the video signal based on the data value generated by the limit value generating means. .

According to a second aspect of the present invention, there is provided the contour correction apparatus according to the first aspect, further comprising a delay unit for delaying the input image, and developing each amplitude data of the video signal sampled at a predetermined sample interval by the delay unit. It is something to do.

According to a third aspect of the present invention, in the contour correction device according to the first or second aspect, the detection of the angle change value by the angle change detecting means is performed by a tan ^-1 operation on the sampling interval and the amplitude difference value data. It is something to do.

According to a fourth aspect of the present invention, in the contour correction apparatus according to any one of the first to third aspects, selection of sample data relating to the signal to be corrected in the angle change detecting means is performed based on the sample data. This is performed based on the absolute value of the detected angle change value.

According to a fifth aspect of the present invention, in the contour correction apparatus according to any one of the first to fourth aspects, the angle change detecting means is configured to calculate the angle change detecting means from the sample data relating to the signal to be corrected to the immediately preceding sample data. , A second subtractor for subtracting the immediately following sample data from the sample data relating to the signal to be corrected, and an output signal of the first subtractor.
a first calculating means for calculating an angle change value between sample data by performing an n ^-1 calculation, and t output signals from the second subtracting means.
second calculating means for performing an ^-1 calculation to obtain an angle change value between sample data; and comparing means for comparing an output signal of the first calculating means with an absolute value of an output signal of the second calculating means. And selecting means for selecting the output signal of the first calculating means and the output signal of the second calculating means based on the output signal of the comparing means.

According to a sixth aspect of the present invention, in the contour correction apparatus according to any one of the first to fifth aspects, the limited angle generation means includes a predetermined angle change value which is an output signal of the angle change detection means. , An subtraction unit that subtracts a predetermined angle from an angle change value that is an output signal of the angle change detection unit, an angle change value that is an output signal of the angle change detection unit, and an output of the addition unit. A first angle limiting unit that outputs the output signal of the adding unit when the signals are equal to each other and outputs zero as an upper limit when the signals are different, and an angle change value that is an output signal of the angle change detecting unit. And a second angle limiting means for comparing the output signal of the subtracting means with the output signal of the subtracting means when the sign is the same, and outputting the output signal of the subtracting means as a lower limit value of zero when the sign is different.

According to a seventh aspect of the present invention, in the contour correction apparatus according to any one of the first to sixth aspects, the limit value generation means performs a tan operation in the operation for generating the amplitude data upper limit value and the amplitude data lower limit value. It is provided with a computing means including the following.

According to an eighth aspect of the present invention, there is provided the contour correcting apparatus according to any one of the first to seventh aspects, further comprising, before the contour correction, a discretized video signal having a sampling frequency f1 as an input signal. Frequency conversion means for up-sampling the sampling frequency to f2. After the contour correction, the output signal of the contour correction means, which is a discretized video signal of the sampling frequency f2, is used as an input signal, and the sampling frequency is reduced to f1. A second frequency conversion means for sampling is provided.

[0020]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a contour correcting device according to the present invention will be described with reference to the accompanying drawings. FIG. 1 is a block diagram showing a configuration of an embodiment of an outline correction device according to the present invention. In FIG. 1, 1 is an input terminal, 2 is an output terminal, and 3 (1) to 3 (n +
1) is a delay circuit, 4 is a correction component generation circuit, 5 is a gain adjustment circuit, 6 is an angle change detection circuit, 7 is a limit angle generation circuit, 8 is a limit value generation circuit, 9 is an amplitude limit circuit, and 11 is an addition circuit. It is.

In order to perform the contour correction processing, each component has the following input / output relationship and constitutes a circuit. The video signal S1 input from the input terminal 1 is supplied to the correction component generation circuit 4 and the delay circuit 3 (1). The output signal S4 of the correction component generation circuit 4 is supplied to a gain adjustment circuit 5. The output signal S5 of the gain adjustment circuit 5 is supplied to one input terminal of the addition circuit 11. Delay circuit 3 (1) to delay circuit 3
In (n + 1), (n + 1) delay circuits are connected in series to delay the video signal S1 by a maximum of (n + 1) data samples. The output signal S3 (n) of the delay circuit 3 (n-1)
-1), the output signal S3 (n) of the delay circuit 3 (n) and the output signal S3 (n + 1) of the delay circuit 3 (n + 1) are supplied to the angle change detection circuit 6, and furthermore, the output signal of the delay circuit 3 (n). The output signal S3 (n) is supplied to the other input terminal of the adder circuit 11. The output signals S6A and S6B of the angle change detection circuit 6 are supplied to one input terminal of the limit angle generation circuit 7 and one input terminal of the limit value generation circuit 8, respectively. The output signal S7 of the limit angle generation circuit 7 is supplied to the other input terminal of the limit value generation circuit 8. The output signal S11 of the adder circuit 11 is subjected to non-linear processing in the amplitude limiting circuit 9 in accordance with the output signal S8 of the limit value generating circuit 8, and is output from the output terminal 2 as an output signal S2.

FIGS. 1 to 11 and FIGS. 13 to 15 show the operation of the circuit of this embodiment of the contour correction device according to the present invention.
, And will be described in detail below. In FIG. 1, it is assumed that a video signal having an outline as shown in FIG. A correction component of the outline is generated from the input video signal S1 by the correction component generation circuit 4. The correction component generation circuit 4 can be constituted by, for example, a 7-tap symmetrical FIR filter as shown in FIG. In FIG. 2, 41 (1) to 41 (6) are delay circuits, and 42 (0) to 42 (0) to
42 (6) is a multiplication circuit, and 43 is an addition circuit. As an operation of the circuit, first, the input video signal S1 is delayed by the delay circuits 41 (1) to 41 (6). After the delay, the input signal S1 and the delay circuits 41 (1) to 41 (6) are delayed. 41 (6) output signals S41 (1) to S41 (6)
Are multiplied by the coefficients K1 to K4 shown in FIG. 2 by the multiplication circuits 42 (0) to 42 (6), respectively, and then added by the addition circuit 43.

Here, K1 = 12/16, K2 = -3
/ 16, K3 = −2 / 16, K4 = −1 / 16, and high-pass filter characteristics as shown in FIG. The correction component of the contour by the correction component generation circuit 4 becomes a signal as shown in FIG. Here, the configuration of the correction component generation circuit 4 is a 7-tap symmetric FIR filter, but a 3-tap symmetric FIR filter as described in the conventional example may be used. Although not shown, a symmetric FIR filter, an asymmetric FIR filter, or an IIR filter having an arbitrary number of taps may be used. The characteristics are shown in FIG.
Or a band-pass filter characteristic for extracting a specific frequency component.

The gain of the output signal S4 of the correction component generation circuit 4 is appropriately controlled by the gain control circuit 5.
Here, the gain is set to 2, and as a result, a signal as shown in FIG. The video signal S1 input from the input terminal 1 is delayed by the delay circuits 3 (1) to 3 (n + 1). At this time, the output signal S3 of the delay circuit 3 (n)
(N) shows the correction component generation circuit 4 and the gain control circuit 5
Are delayed by n data samples corresponding to the delay amount n required for the signal processing of the delay circuits 3 (1) to 3 (n + 1).
Is a time-invariant characteristic and does not change its waveform-like characteristics. Therefore, in FIG. 13, the same waveform (A)
It is expressed as Output signal S3 of delay circuit 3 (n)
(N) and the output signal S5 of the gain control circuit 5
The signals are added up by 1 to produce a signal as shown in FIG.

The output signal S3 (n) of the delay circuit 3 (n-1)
-1), the output signal S3 (n) of the delay circuit 3 (n) and the output signal S3 (n + 1) of the delay circuit 3 (n + 1) change the angle between the data sample immediately before and after the data sample of interest by an angle. The angle and the data sample value, which are obtained by the detection circuit 6 and whose absolute value is smaller, are selected.
FIG. 4 shows the configuration of the angle change detection circuit 6. In FIG. 4, 61 and 62 are subtraction circuits, 63 and 64 are tan- ¹ operation circuits, 65 is a comparison circuit, and 66 and 67 are selection circuits.

The operation of this circuit is performed by the subtraction circuit 61.
From the output signal S3 (n) of the delay circuit 3 (n),
The output signal S3 (n + 1) of (n + 1) is subtracted, and the output signal S3 of the delay circuit 3 (n) is subtracted by the subtraction circuit 62.
From (n), the output signal S3 (n-
1) is subtracted. The output signal S61 of the subtraction circuit 61 is
The following operation f (63) is performed in the tan ^-1 operation circuit 63. f (63) = tan ^-1 (“S61” / t) where “S61” is the output signal S61 of the subtraction circuit 61,
t is an arbitrarily set constant. The meaning of the above operation is shown in FIG.
The output signal S3 of the delay circuit 3 (n)
Assuming that the value of (n) is VD3 (n) and the value of the output signal S3 (n + 1) of the delay circuit 3 (n + 1) is VD3 (n + 1), the angle between the data samples shown in FIG. That is, θ _BR is required.

Similarly, the output signal S62 of the subtraction circuit 62
Is subjected to the following operation f (64) in the tan ^-1 operation circuit 64. f (64) = tan ⁻¹ (“S62” / t) where “S62” is the output signal S62 of the subtraction circuit 62,
t is an arbitrarily set constant. Delay circuit 3 (n-1)
Assuming that the value of the output signal S3 (n-1) is VD3 (n-1), the angle θ _FR between data samples as shown in FIG. 5 is obtained by the operation f (64).

The comparing circuit 65 compares the absolute values of θ _BR and θ _FR , and as a result, the smaller angle of the absolute value is selected by the selecting circuit 66, and the output signal S of the delay circuit 3 (n + 1) is selected.
3 (n + 1) and the output signal S3 of the delay circuit 3 (n-1)
The value of the smaller absolute value of (n-1) is
7 is selected. The angle selected by the selection circuit 66 becomes a signal having an angle as shown in FIG. From the output signal S6A of the angle change detection circuit 6 thus obtained, the upper limit value and the lower limit value of the restriction angle are generated by the restriction angle generation circuit 7.

FIG. 6 shows the configuration of the limit angle generation circuit 7.
6, reference numeral 71 denotes an addition circuit, 72 denotes a subtraction circuit, and 7 denotes a subtraction circuit.
Reference numerals 3 and 74 are angle limiting circuits. Circuit operation, adder circuit
71, the output signal S6A of the angle change detection circuit 6 becomes θ
_MRGIs added, and the upper limit value of the limit angle as shown in FIG.
Generated. The angle change detection circuit 6 is provided by the subtraction circuit 72.
Output signal S6A to θ_MRGIs subtracted, as shown in FIG.
Such a lower limit value of the limit angle is generated. As shown in FIG.
The angle limiting circuit 73 is connected to the output signal S71 of the adding circuit 71 and
The output signal S6A of the angle change detection circuit 6 is compared, and the angle change
When the output signal S6A of the conversion detection circuit 6 is not zero,
The output signal S71 of the path 71 and the output signal of the angle change detection circuit 6
If the sign of the signal S6A is different, zero is output and the signs are equal.
Output the output signal S71 of the adder circuit 71 as it is.
I do.

The output signal S6 of the angle change detection circuit 6
When A is zero, the angle limiting circuit 73 outputs zero. FIG.
As shown in the figure, the angle limiting circuit 74 compares the output signal S72 of the subtraction circuit 72 with the output signal S6A of the angle change detection circuit 6, and when the output signal S6A of the angle change detection circuit 6 is other than zero, When the sign of the output signal S72 and the sign of the output signal S6A of the angle change detection circuit 6 are different, zero is output, and when the sign is equal, the output signal S72 of the subtraction circuit 72 is outputted.
Is output as is. When the output signal S6A of the angle change detecting circuit 6 is zero, the angle limiting circuit 74 outputs zero. The upper limit value and the lower limit value of the limit angle become a signal having an angle as shown in FIG. The output signal S7 of the limited angle generation circuit 7 and the output signal S6B of the angle change detection circuit 6 are
The upper limit value and the lower limit value of the limit value are generated by the limit value generation circuit 8.

FIG. 8 shows the configuration of the limit value generation circuit 8. 8, 81 and 82 are tan operation circuits, and 83 and 84.
Is a multiplication circuit, and 85 and 86 are addition circuits. The operation of the circuit is as follows. The output signal S7A of the limited angle generation circuit 7, which is the upper limit value of the limited angle, is output from the tan operation circuit 81 and the multiplication circuit 83.
, That is, the following calculation is performed. f (81 · 83) = t × tan (“S7A”) where “S7A” is the output signal S of the limited angle generation circuit 7.
7A and t are constants set arbitrarily earlier.

The output signal S7B of the limit angle generation circuit 7, which is the lower limit value of the limit angle, is subjected to a calculation process by the tan calculation circuit 82 and the multiplication circuit 84, that is, the following calculation is performed. f (82 · 84) = t × tan (“S7B”) where “S7B” is the output signal S of the limited angle generation circuit 7.
7B and t are constants arbitrarily set earlier. Output signal S83 of multiplication circuit 83 and output signal S of multiplication circuit 84
An area 84 is added to the output signal S6B of the angle change detection circuit 6 by an adder circuit 85 and an adder circuit 86, respectively, and is surrounded by an upper limit value and a lower limit value as shown in FIG. Signal having the following limit value:

FIG. 10 shows the configuration of the amplitude limiting circuit 9. In FIG. 10, reference numerals 91 and 92 denote comparison circuits, and reference numeral 93 denotes a selection circuit. The operation of the circuit is such that the input output signal S11 of the addition circuit 11 is the output signal S8 of the limit value generation circuit 8,
Non-linear processing is performed according to A and S8B. For example, the output signal S11 of the adder circuit 11 and the output signals S8A and S8B (FIG. 13G) of the limit value generating circuit 8 shown in FIG. Are compared by comparison circuits 91 and 92.

When the output signal S11 of the adding circuit 11 is larger than the output signal S8A of the limit value generating circuit 8 which is the upper limit value of the amplitude control, the output signal S8A of the limit value generating circuit 8 is output. When the output signal S11 of the adder circuit 11 is smaller than the output signal S8B of the limit value generation circuit 8, which is the lower limit value of the amplitude control, the output signal S8B of the limit value generation circuit 8 is output. Otherwise, the output signal S11 of the adder circuit 11 is output. That is, the amplitude is limited using the upper limit value or the lower limit value generated by the limit value generation circuit 8.
According to this, as the output signal S2 of the amplitude limiting circuit 9,
As shown in FIG. 13 (I), a video signal having a sharp contour is obtained.

As described above, according to the above embodiment of the present invention, the contour correction component is added by the upper limit value and the lower limit value generated by the angle change detecting means, the limit angle generating means, and the limit value generating means. Since the amplitude control of the video signal is performed, the effect of the contour correction can be sufficiently obtained even in a gentle contour portion, and the contour correction can be realized even in a relatively steep contour portion without adding a preshoot or an overshoot.
Also, according to the correction device of the present invention, the signal waveform property of the original video signal can be reduced even for a signal that may lose the signal waveform property or the geometric structure of the original video signal in the conventional contour correction apparatus. Alternatively, such correction can be performed without losing the structure. This will be described below.

Referring to FIG. 14, FIG. 14A shows a signal which may lose the characteristic or geometric structure of the signal waveform of the original video signal in the conventional contour correction device. Is input, the above-described correction device according to the present invention performs the expected correction operation as described below. The output signal S4 of the correction component generation circuit 4 that has processed the input shown in FIG. 14A is a signal as shown in FIG. 14B, and the output signal S5 of the gain control circuit 5 is the signal shown in FIG.
14C, the output signal S11 of the adding circuit 11 becomes a signal as shown in FIG. 14D, and the output signal S6A of the angle change detecting circuit 6 becomes as shown in FIG. Output signal S7 of the limited angle generation circuit 7.
A and S7B become signals as shown in FIG. 14 (F), and output signals S8A and S8B of the limit value generating circuit 8 become signals as shown in FIG. 14 (G), as shown in FIG. 14 (H). These signals are output by the amplitude limiting circuit 9 as shown in FIG. As a result, the output signal S3 (n) of the delay circuit 3 (n) shown in FIG.
As can be seen from the output signal S2 of the contour correction device (B), it is possible to perform the contour correction without changing the properties of the waveform before and after the correction and without losing the geometric structure. In addition,
Compared to FIG. 20 showing the conventional example, the difference in the result can be seen.

Next, another embodiment of the contour correcting apparatus according to the present invention will be described with reference to the accompanying drawings. FIG.
2 is a block diagram showing the configuration of this embodiment of the contour correction device according to the present invention. In FIG.
Reference numeral 10 denotes the contour correction device described in the above embodiment of the present invention, reference numeral 20 denotes a first frequency conversion circuit, and reference numeral 30 denotes a second frequency conversion circuit. In the procedure of the processing operation of the present apparatus, the video signal S1 input from the input terminal 1 is first supplied to the first frequency conversion circuit 20 before being input to the contour correction circuit. The output signal S20 of the first frequency conversion circuit 20 is supplied to the contour correction device 10. The output signal S10 of the contour correction device 10 is supplied to the second frequency conversion circuit 30. The output signal of the second frequency conversion circuit 30 is output from the output terminal 2.

The video signal S1 has, for example, a sampling frequency f1
It is assumed that the signal is sampled by. The first frequency conversion circuit 20 up-samples the input video signal S1 from a sampling frequency f1 to a sampling frequency f2 which is an integral multiple of f1. The output signal S10 of the contour correction device 10 that has performed the contour correction at the sampling frequency f2 is down-sampled to the original sampling frequency f1 by the second frequency conversion circuit 30. As described above, according to this embodiment of the present invention, the sampling frequency is changed from f1 to f1 before the contour correction device.
2, the contour correction described in the above-described embodiment of the present invention is performed, and the sampling frequency is down-sampled from f2 to f1 in the subsequent stage, so that the load on the circuit connected to the subsequent stage is further reduced. Without increasing
Further, it is possible to alleviate the deterioration of the image quality due to the return noise of the harmonic component generated in the nonlinear processing of the contour correction device.

[0039]

As described above, according to the present invention, there are provided delay means for delaying an input video signal, first subtraction means for subtracting a data sample immediately before a data sample of interest from an output signal of the delay means, Second subtraction means for subtracting the immediately following data sample from the data sample of interest of the output signal of the delay means, and tan ^-1 operation on the output signal of the first subtraction means to determine the angle between the data samples A first calculating means, a second calculating means for performing an tan ^-1 operation on an output signal of the second subtracting means to obtain an angle between data samples, an output signal of the first calculating means, and a second Comparing means for comparing the absolute value of the output signal of the calculating means, and selecting means for selecting the output signal of the first calculating means and the output signal of the second calculating means based on the output signal of the comparing means. , An angle change detection means comprising selection means for selecting an output signal of the delay means based on an output signal of the comparison means; an addition means for adding a predetermined angle to an output signal of the angle change detection means; Subtracting means for subtracting a predetermined angle from the output signal of the detecting means; and comparing the output signal of the angle change detecting means with the output signal of the adding means. The first angle limiting means that outputs zero as an upper limit value, and the output signal of the angle change detecting means and the output signal of the subtracting means are compared. In this case, a limiting angle generating means including a second angle limiting means for outputting zero as a lower limit value, and tan based on an output signal of the angle change detecting means and an output signal of the limiting angle generating means. Limit value generating means for performing an operation including arithmetic operation to generate a data amplitude upper limit value and a data amplitude lower limit value, and amplitude limiting means for limiting a value of a video signal based on an output signal of the limit value generating means. , It has a sufficient effect even on gentle contours, without adding preshoot or overshoot,
A high-quality contour-corrected image can be obtained without losing the geometric structure of the original video signal. Further, a first frequency converting means for inputting a discretized video signal of the sampling frequency f1 as an input signal and up-sampling the sampling frequency to f2, and a contour correcting means for inputting an output signal of the first frequency converting means as an input signal. The output signal of the contour correction means, which is a discretized video signal having a sampling frequency f2, is used as an input signal, and the sampling frequency is set to f
By providing the second frequency converting means for down-sampling to 1, the contour correction amount can be varied more precisely, and the aliasing noise of the harmonic component generated by the non-linear processing in the amplitude limiting means of the contour correcting device. Can reduce the deterioration of the image quality.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an embodiment of a contour correction device according to the present invention.

FIG. 2 is a block diagram illustrating a configuration example of a correction component generation circuit that is an element of the contour correction device illustrated in FIG.

FIG. 3 is a diagram showing characteristics of the correction component generation circuit shown in FIG. 2;

4 is a block diagram illustrating a configuration example of an angle change detection circuit that is an element of the contour correction device illustrated in FIG.

5 is a diagram showing a video signal related to a process for explaining the operation of the angle change detection circuit shown in FIG.

6 is a block diagram illustrating a configuration example of a limited angle generation circuit that is an element of the contour correction device illustrated in FIG. 1;

7 is a diagram showing a video signal related to a process for explaining the operation of the limited angle generation circuit shown in FIG.

FIG. 8 is a block diagram illustrating an example of a configuration of a limit value generating unit that is an element of the contour correction device illustrated in FIG. 1;

9 is a diagram showing a video signal related to a process for explaining an operation of the limit value generation circuit shown in FIG.

10 is a block diagram illustrating a configuration example of an amplitude limit value circuit that is an element of the contour correction device illustrated in FIG.

11 is a diagram showing a video signal related to a process for explaining the operation of the amplitude limiting circuit shown in FIG.

FIG. 12 is a block diagram showing a configuration of another embodiment of the contour correction device according to the present invention.

13 is a diagram illustrating an example of an output video signal generated in each circuit unit by the operation of the contour correction device illustrated in FIG. 1;

14 is a diagram illustrating an example of an output video signal generated in each circuit unit by the operation of the contour correction device illustrated in FIG. 1;

FIG. 15 is a diagram for explaining the properties of a part of the video signal of FIG. 14;

FIG. 16 is a block diagram illustrating a configuration of an example of a conventional contour correction device.

17 is a diagram showing output video signals generated in each circuit unit by the operation of the conventional contour correction device of FIG.

FIG. 18 is a block diagram showing a configuration of another example of the conventional contour correction device.

19 is a diagram showing output video signals generated in each circuit unit by the operation of the conventional contour correction device of FIG.

FIG. 20 is a diagram for explaining the properties of a part of the video signal in FIG. 19;

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Input terminal, 2 ... Output terminal, 3 (1) -3 (n + 1) ... Delay circuit, 4 ... Correction component generation circuit, 41 (1) -41 (6) ... Delay circuit, 42 (0) -42 ( 6) Multiplication circuit, 43 Addition circuit, 5 Gain control circuit, 6 Angle change detection circuit, 61, 62 Subtraction circuit, 63, 64 Tan- ¹ arithmetic circuit, 65 Comparison circuit, 66, 67 ... Selection circuit, 7: limited angle generation circuit, 71: addition circuit, 72: subtraction circuit, 73, 74: angle restriction circuit, 8: restriction value generation circuit, 81, 82: tan operation circuit, 83, 84: multiplication circuit, 85, 86 ... addition circuit, 9 ... amplitude limiting circuit, 91, 92 ... comparison circuit, 93 ... selection circuit, 10 ... contour correction device, 11 ... addition circuit, 20 ... first frequency conversion circuit, 30 ... second Frequency conversion circuit, 101 ... correction component generation circuit, 02, 103: delay circuit, 104 to 106: multiplication circuit, 107: addition circuit, 108: gain control circuit, 109: delay circuit, 110: addition circuit, 201 to 204: delay circuit, 205: maximum value detection circuit, 206 ... Minimum value detection circuit, 207 ... Position detection circuit, 208 ... Calculation circuit, 209 ... Average value circuit, 210 ... Subtraction circuit, 211 ... Gain adjustment circuit, 212 ... Addition circuit, 213 ... Non-linear processing circuit

 ────────────────────────────────────────────────── ─── Continuing from the front page (72) Inventor Shugoro Harihara 22-22, Nagaikecho, Abeno-ku, Osaka-shi, Osaka F-term (reference) 5C021 PA12 PA16 PA28 PA36 PA42 PA53 PA56 PA57 PA58 PA62 PA66 PA72 PA84 RA02 RB04 RB08 SA25 XB03 YC10

Claims (8)

[Claims] 1. A contour correction device for correcting a video signal in order to enhance a contour of a video, wherein a difference value of amplitude data between the video signals sampled at a predetermined sample interval is detected as an angle change value. Angle change detection means for selecting sample data relating to a signal to be corrected based on the detection result, and limit angle generation means for generating an upper limit angle and a lower limit angle around an angle value detected by the angle change detection means; Calculating an amplitude data upper limit value and an amplitude data lower limit value of the video signal based on the sample data relating to the signal to be corrected selected by the angle change detecting means and the angle generated by the limited angle generating means. Limit value generating means for performing, and amplitude limiting means for limiting the amplitude data value of the video signal by the data value generated by the limit value generating means. That contour correction apparatus. 2. The contour correction device according to claim 1, further comprising a delay unit for delaying the input image, wherein the delay unit expands each amplitude data of the video signal sampled at a predetermined sample interval. An outline correction device characterized by the above-mentioned. 3. The contour correction device according to claim 1, wherein the detection of the angle change value by the angle change detection means is performed by a tan ^-1 operation on the sampling interval and the amplitude difference value data. An outline correction device characterized by the above-mentioned. 4. The contour correction apparatus according to claim 1, wherein the angle change detecting means detects selection of sample data relating to the signal to be corrected, which is to be corrected, from the sample data. A contour correction device characterized in that the correction is performed based on the absolute value of the value. 5. The contour correction device according to claim 1, wherein the angle change detection unit subtracts the immediately preceding sample data from the sample data relating to the signal to be corrected to be noted. , A second subtractor for subtracting the immediately following sample data from the sample data relating to the signal to be corrected, and a tan ^-1 operation performed on the output signal of the first subtractor. A first calculating means for calculating an angle change value between the sample data, a second calculating means for performing a tan ^-1 calculation on an output signal of the second subtracting means to obtain an angle change value between sample data, Comparing means for comparing the output signal of the calculating means with the absolute value of the output signal of the second calculating means; and the output signal of the first calculating means and the second signal based on the output signal of the comparing means. Contour correcting device, characterized in that it comprises a selection means for selecting an output signal of the unit. 6. The contour correction device according to claim 1, wherein the limit angle generation unit adds a predetermined angle to an angle change value that is an output signal of the angle change detection unit. Subtracting means for subtracting a predetermined angle from an angle change value output from the angle change detecting means; comparing the angle change value output from the angle change detecting means with the output signal from the adding means; When the angle is equal, the output signal of the adding means is output, and when the angle is different, the first angle limiting means outputs zero as an upper limit value. A contour correction device comprising: a second angle limiting unit that compares output signals and outputs the output signal of the subtraction unit when the signs are equal, and outputs zero as a lower limit when the signs are different. 7. The contour correction device according to claim 1, wherein the limit value generation unit includes a calculation unit including a tan calculation in a calculation for generating an amplitude data upper limit value and an amplitude data lower limit value. A contour correction device characterized by the above-mentioned. 8. The contour correction device according to claim 1, further comprising a sampling frequency f1 as an input signal and a sampling frequency up to f2 before performing the contour correction. A second frequency converting means for inputting the output signal of the contour correcting means, which is a discretized video signal having a sampling frequency f2, as an input signal after the contour correction, and down-sampling the sampling frequency to f1. A contour correction device comprising frequency conversion means.