JP4534121B2 - Noise removal apparatus, noise removal method, and noise removal program - Google Patents

Description

The present invention relates to a noise removing device, a noise removing method, and a noise removing program for removing noise such as ringing and mosquito noise existing in the vicinity of an edge portion of a video signal.

  For example, a video signal such as an NTSC (National Television System Committee) signal received by a television receiver and detected by video detection has a steep filter characteristic for removing an audio signal component, for example. Thus, as shown in FIG. 21, a large amount of ringing 2 occurs before and after the edge portion 1 of the video signal, and when the front and rear of the edge portion 1 are flat as shown in FIG. Causes deterioration of image quality.

  Conventionally, various inventions for reducing ringing and the like in the vicinity of the edge portion of the video signal have been proposed. For example, Patent Document 1 (Japanese Patent Laid-Open No. 5-183778) describes an example of a video signal compensation circuit.

  The video signal compensation circuit described in Patent Document 1 has a configuration as shown in FIG. The configuration of FIG. 22 smoothes the ringing and makes it inconspicuous, assuming that the input video signal has passed through a low-pass filter in the vicinity of the edge portion of the input video signal where ringing has occurred.

  That is, as shown in FIG. 22, the input video signal Vi input through the input terminal 11 is supplied to the mixing circuit 12 as it is and also supplied to the mixing circuit 12 through the low-pass filter 13.

  The input video signal Vi is supplied to the ringing detection circuit 14. The ringing detection circuit 14 detects the edge portion 1 shown in FIG. 21 from the input video signal Vi, and based on this detection output, the ringing 2 will be present, and the front side of the edge portion 1 is present. The portion and the rear portion of the edge portion 1 are fixedly detected as a ringing reduction section. The ringing detection circuit 14 outputs a reduction amount α (α <1) corresponding to the detected level (level difference) of the edge portion to the mixing circuit 12 in the ringing reduction section.

The mixing circuit 12 mixes the input video signal Vi and the video signal VLi from the low-pass filter 12 at a rate corresponding to the reduction amount α. In this case, in the mixing circuit 12,
Vi × (1−α) + VLi × α
The mixing represented by

  The ringing detection circuit 14 outputs α = 0 as the reduction amount α in a portion where there is no ringing other than the edge portion, and at the front side portion of the edge portion to be the ringing reduction section and the rear side portion of the edge portion, A reduction amount α corresponding to the detected level of the edge portion is output.

  In the mixing circuit 12, if the reduction amount α = 0, no signal reduction is performed, and the input video signal Vi is output as it is through the output terminal 15 as the output video signal Vo. If the reduction amount α is not 0, the mixing circuit 12 mixes the input video signal Vi and the video signal VLi from the low-pass filter 13 at a rate corresponding to the value of the reduction amount α, and outputs the output video. The signal Vo is used. Therefore, the output video signal Vo has a reduced ringing according to the size of the edge portion.

The above-mentioned patent documents and non-patent documents are as follows.
JP-A-5-183778

  However, the conventional ringing reduction device described above is configured to simply mix the signal smoothed by the low-pass filter and the signal that does not pass the low-pass filter according to the signal reduction amount from the ringing detection circuit 14. ing.

  By the way, as shown in FIG. 21, ringing or the like generally has a small amplitude, and no ringing occurs in a signal portion such as a large amplitude edge, and even if it is not noticeable.

  However, in the conventional ringing reduction apparatus of FIG. 21, the signal that has passed through the low-pass filter is mixed with the input video signal Vi without dividing the signal into a large amplitude portion and a small amplitude portion. For this reason, a low-pass filter is also applied to a signal with a large amplitude, and the output image is blurred. In other words, the conventional apparatus has a problem that the low-pass filter is applied to a portion that is not ringing, and as a result, the output image is blurred.

  In view of the above points, an object of the present invention is to reduce a portion to be reduced without affecting signals other than those to be reduced as much as possible.

In order to solve the above problems, in the invention of claim 1,
First dividing means for dividing the input video signal into a low frequency component and a high frequency component;
A signal reduction region / reduction amount detection means for calculating a detection output corresponding to a signal reduction region and a signal reduction amount before and after an edge portion of the input video signal from the input video signal;
Second dividing means for dividing a high frequency component of the input video signal divided by the first dividing means into a large amplitude part and a small amplitude part;
Small amplitude part output control means for reducing the small amplitude part from the second dividing means in accordance with the detection output of the signal reduction region / reduction amount detection means;
A large amplitude portion of a high frequency component of the input video signal divided by the second dividing means, a small amplitude portion of a high frequency component of the input video signal from the small amplitude portion output control means, and the input video and a mixing means for mixing the low frequency components of the signal,
The second dividing means includes
Non-linear means with non-linear input / output characteristics for extracting a small amplitude portion of a high frequency component of the input video signal
With
The nonlinear means is controlled in accordance with the signal reduction amount obtained by the signal reduction region / reduction amount detection means, and a larger amplitude signal is output from the nonlinear means as the signal reduction amount is larger. The noise removal apparatus characterized by this is provided.

According to the first aspect of the present invention, the input video signal is divided into a low-frequency component and a high-frequency component, and the divided high-frequency component is further divided into a large amplitude portion and a small amplitude portion. Then, only the small amplitude portion is subjected to signal level reduction according to the signal reduction amount obtained by the signal reduction region / reduction amount detection means. It should be noted that non-linear means with non-linear input / output characteristics are used to extract the small amplitude portion of the high frequency component. This nonlinear means is controlled in accordance with the signal reduction amount, and the larger the signal reduction amount, the more the signal with a larger amplitude is output from the nonlinear means.

  Therefore, according to the first aspect of the present invention, the large amplitude portion of the high frequency component of the input video signal is not reduced, and the small amplitude portion is the signal reduction amount detected by the signal reduction region / reduction amount detecting means. Accordingly, for example, it is possible to reduce only the portion that is desired to be reduced as ringing, and image degradation can be minimized.

  According to the present invention, it is possible to effectively reduce only the portion of the input video signal that is desired to be reduced, such as ringing or mosquito noise, so that image degradation can be minimized.

  Embodiments of a video signal processing apparatus and method according to the present invention will be described below with reference to the drawings.

  FIG. 1 is a block diagram showing the overall configuration of the video signal processing apparatus according to the embodiment, and this example is an example in the case of reducing ringing existing before and after the edge portion of an input video signal.

  The input video signal Vi is supplied through the input terminal 21 to the band dividing circuit 22 and the signal reduction region / reduction amount detection circuit 50 constituting the first dividing means.

  The signal reduction region / reduction amount detection circuit 50 detects an edge portion of the input video signal Vi, and sets a predetermined region before and after the detected edge portion as a signal reduction region, as described later in detail. A detection output α corresponding to the signal reduction amount detected based on the edge portion is output. That is, as shown in FIG. 21, the signal reduction region / reduction amount detection circuit 50 sets the interval where the ringing before and after the edge portion will exist as the signal reduction region, It is estimated that ringing corresponding to the size will occur, and the detection output α is generated and output so that the amount of signal reduction corresponds to the size of the edge portion.

  The band dividing circuit 22 includes a high frequency component extracting circuit 30 and a subtracting circuit 31. The high frequency component extraction circuit 30 extracts the high frequency component VHi from the input video signal Vi. The subtraction circuit 31 subtracts the high frequency component VHi from the high frequency component extraction circuit 30 from the input video signal Vi to extract the low frequency component VLi of the input video signal. The band dividing circuit 22 is configured by the high frequency component extracting circuit 30 and the subtracting circuit 31 as in this example, where the ringing occurs at the edge portion and in the high frequency, and will be described later. This is because the ringing can be reduced by reducing the signal for the high frequency component.

  The low frequency component VLi from the band dividing circuit 22 is supplied to the mixing circuit 27, and the high frequency component VHi is supplied to the amplitude dividing circuit 23 constituting the second dividing means.

  The amplitude division circuit 23 includes a small amplitude partial extraction circuit 40 and a subtraction circuit 41. The small amplitude portion extraction circuit 40 is configured by a nonlinear conversion circuit having nonlinear characteristics as shown in FIG. 2 as input / output characteristics, and only the small amplitude portion SVHi of the high frequency component VHi of the input video signal Vi is obtained. Extract. The subtraction circuit 41 subtracts the small amplitude partial output SVHi from the small amplitude partial extraction circuit 40 from the high frequency component VHi of the input video signal Vi, and outputs the large amplitude portion BVHi of the high frequency component VHi of the input video signal Vi. To do.

  As shown in FIG. 2, the small-amplitude partial extraction circuit 40 outputs an output signal proportional to the high-frequency component VHi of the input video signal Vi when the input video signal Vi has a small amplitude due to the input / output nonlinear characteristics. When the high frequency component VHi of Vi has a large amplitude, the output is zero. In this embodiment, as will be described later, the nonlinear characteristic of the small amplitude partial extraction circuit 40 has a signal reduction region and a signal reduction amount before and after the edge of the input video signal from the signal reduction region / reduction amount detection circuit 50. The maximum amplitude value of the small amplitude portion to be output is controlled according to the corresponding detection output α.

  That is, in the small amplitude portion extraction circuit 40, when the detection output α is small, as shown in FIG. 2A, the maximum amplitude value of the small amplitude portion to be output is reduced, and when the detection output α is large, FIG. As shown in A), the maximum amplitude value of the small amplitude portion to be output is increased. That is, the amount of the large amplitude portion output from the small amplitude portion extraction circuit 40 is controlled according to the detection output α of the signal reduction region / reduction amount detection circuit 50, and the smaller the detection output α is, the smaller the amplitude portion extraction circuit is. From 40, control is performed so that a component having a larger amplitude is output.

  This is because when the detection output α is small, the ringing is small, so the maximum amplitude of the signal detected as a small amplitude portion may be small, but when the detection output α is large, it is better to increase the amount of reduction of ringing. It is.

  In this example, the large amplitude portion BVHi of the high frequency component VHi of the input video signal obtained from the amplitude dividing circuit 23 is supplied to the mixing circuit 27 through the output control circuit 24 and the input video signal from the band dividing circuit 22 is supplied. It is mixed with the low frequency component VLi. The small amplitude portion SVHi of the high frequency component VHi of the input video signal obtained from the amplitude dividing circuit 23 is supplied to the mixing circuit 28 through the output control circuit 25 and mixed with the output signal of the mixing circuit 27. In the example of FIG. 1, the mixing circuit 27 is provided in the preceding stage of the mixing circuit 28, but the mixing circuit 28 may be provided in the preceding stage of the mixing circuit 27, and one mixing circuit 27 and 28 are provided. It may be summarized in.

  The output control circuit 25 reduces the small amplitude portion SVHi of the high frequency component VHi of the input video signal in accordance with the detection output α of the signal reduction region / reduction amount detection circuit 50. Therefore, the larger the detection output α, the larger the reduction amount of the small amplitude portion SVHi of the high frequency component VHi of the input video signal. The output of the output control circuit 25 is supplied to the mixing circuit 28 and mixed with the signal from the mixing circuit 27.

  In this example, the output control circuit 24 also reduces the output of the large amplitude portion BVHi from the amplitude division circuit 23 in accordance with the detection output α of the signal reduction region / reduction amount detection circuit 50. The detection output α is supplied to the output control circuit 24 through the 1 / m circuit 26 so that it becomes 1 / m (m> 1) as compared with the small amplitude component SVHi. The output of the output control circuit 24 is supplied to the mixing circuit 27 and mixed with the low frequency component VLi of the input video signal.

  In addition, without providing the output control circuit 24 and the 1 / m circuit 26, the large amplitude portion BVHi from the amplitude dividing circuit 23 is supplied to the mixing circuit 27 as it is, and is mixed with the low frequency component VLi of the input video signal. May be.

  In this embodiment, an output video signal Vo is obtained as an output of the mixing circuit 28 and is output to the next stage through the output terminal 29.

  The video signal processing apparatus according to this embodiment has the above-described configuration. Of the high frequency components of the input video signal, the large amplitude portion is not reduced, and the small amplitude portion is the signal reduction region / reduction amount detection circuit 50. Since reduction is performed according to the detected signal reduction amount, for example, it is possible to reduce only the portion where ringing occurs, and image degradation can be minimized.

  In this embodiment, the high-frequency component extraction circuit 30 and the signal reduction region / reduction amount detection circuit 50 are configured as described below, so that it is possible to satisfactorily reduce the signal portion desired to be reduced. Therefore, image degradation can be further suppressed.

[More Detailed Configuration of Video Signal Processing Device of Embodiment]
Although the configuration of FIG. 1 can be configured as an analog circuit, in this embodiment, the configuration is configured as a digital circuit. Therefore, the input video signal Vi is a digital video signal with a sampling frequency of 13.5 MHz, and a high-pass filter using a digital filter is used for the high-frequency component extraction circuit 30 of the band dividing circuit 22. In this case, as the digital filter, either an FIR (Finite Impulse Response) type or an IIR (Infinite Impulse Response) type can be used.

  FIG. 3 shows an example of the configuration of an FIR type digital filter. A plurality of one-sample delay circuits 61 connected in series to an input signal, and coefficients are applied to the input signal and the output signal of each delay circuit 61. A plurality of coefficient multiplication circuits 62 to be multiplied and a sum calculation circuit 63 for calculating the sum of the outputs of the plurality of coefficient multiplication circuits 62, and an output signal is output from the sum calculation circuit 63. This digital filter has filter coefficients W0, W1, W2... W (n−2), W (n−1) multiplied by the number of taps (number of delay circuits 61 + 1) and a plurality of coefficient multiplication circuits 62. ) (N is the number of taps), a filter having a desired characteristic can be configured.

  As described above, the band dividing circuit 22 forms a low-pass filter by the high-frequency component extraction circuit 30 and the subtraction circuit 31. Therefore, the characteristics of the high-pass filter as the high-frequency component extraction circuit 30 directly affect the characteristics of the low-pass filter that extracts the low-frequency component of the input video signal Vi.

  In this embodiment, the characteristic of the high-pass filter as the high-frequency component extraction circuit 30 is, for example, as shown in FIG. As shown in A), it is desirable that the cutoff frequency is high and the attenuation characteristics are steep. Such high-pass filter characteristics can be constituted by a digital filter having a large number of taps.

  However, when a high-pass filter as the high-frequency component extraction circuit 30 is configured using such a digital filter having a large number of taps, the number of taps is large, and therefore, it is affected by sample data in the vicinity of the target sample data. For this reason, when the edge of the signal exists in the vicinity, the low-pass filter output from the subtracting circuit 31 has a bump in the flat signal portion near the edge.

  For example, when an edge portion of a signal as shown in FIG. 5A is passed through a low-pass filter composed of a high-pass filter and a subtracting circuit having a large number of taps, as shown in FIG. A bump 64 is generated in the vicinity of the edge portion of the portion. On the other hand, in the case of a digital filter with a small number of taps, the cut-off frequency is lowered and the attenuation characteristic is slow as shown in FIG. 4B. However, since the number of taps is small, FIG. As shown in C), the flat portions before and after the edge portions are not bumpy.

<Configuration of Band Division Circuit 22>
Considering the above, in this embodiment, the high frequency component extraction circuit 30 of the band dividing circuit 22 is configured as shown in FIG.

  That is, in this embodiment, a first high-pass filter 301 composed of a digital filter with a large number of taps and a second high-pass filter 302 composed of a digital filter with a small number of taps are provided, and the input video signal Vi is received by each high-pass filter. 301 and 302 are supplied. The outputs of these high pass filters 301 and 302 are supplied to the mixing circuit 305 through output control circuits 303 and 304, respectively. The mixed output from the mixing circuit 305 is used as the output of the high frequency component extraction circuit 30.

  In the case of this example, for example, a 9-tap digital filter is used as the first high-pass filter 301, and the filter coefficients W1 to W9 are as shown in FIG. The second high-pass filter 302 is a 3-tap digital filter, for example, and the filter coefficients W1 to W3 are as shown in FIG.

  Note that the characteristics shown in FIG. 4A described above are those of the high-pass filter 301, and the characteristics shown in FIG. 4B are those of the high-pass filter 302.

  In this example, the high frequency component extraction circuit 30 is provided with a flat portion detection circuit 306 that detects a flat portion of the input video signal Vi. In this example, the flat part detection circuit 306 includes a filter 311 and an absolute value conversion circuit 312 for detecting a flat part on the front side (advanced phase side) with respect to the target sample position, and a rear side (lag behind the target sample position). Filter 313 and absolute value circuit 314 for detecting a flat portion on the phase side, minimum value detection circuit 315 for detecting the minimum value of the output of absolute value circuit 312 and absolute value circuit 314, and minimum value detection It comprises a non-linear conversion circuit 316 that generates a detection output value β (β ≦ 1) corresponding to the degree of flatness of the signal from the output of the circuit 315.

  In this example, the filters 311 and 312 are composed of, for example, a 7-tap digital filter. The filter coefficient is that of the filter 311 as shown in FIG. 9, and that of the filter 313 is shown in FIG. It is supposed to be something like this.

  The input / output nonlinear characteristics of the nonlinear conversion circuit 316 are as shown in FIG. That is, as shown in FIG. 11, the detected output value β is β = 0 when the minimum value detected by the minimum value detection circuit 315 is smaller than the first predetermined value θ1, and the first predetermined value θ1. When the value is larger than the value, the value depends on the input value. When the minimum value detected by the minimum value detection circuit 315 becomes larger than the second predetermined value θ2, the detected output value β is made constant.

  Then, a detection output value β corresponding to the degree of flatness of the signal from the flat portion detection circuit 306 is supplied to the output control circuits 303 and 304. The output control circuit 303 outputs the output of the high-pass filter 301 multiplied by the detection output value β to the mixing circuit 305. The output control circuit 304 outputs a product obtained by multiplying the output of the high-pass filter 301 by (1−β) to the mixing circuit 305.

  That is, when the detection output value β is small, that is, when the signal is flat, a signal including a larger amount of the output of the high-pass filter 302 including a digital filter with a small number of taps is used as the output of the high-frequency component extraction circuit 30 and is detected. When the output value β is large and the signal is not flat, the bump 64 is inconspicuous, and the output of the high-frequency component extraction circuit 30 is a signal having a large number of taps and containing more output from the high-pass filter 301 originally intended to be used. And

  Therefore, according to this embodiment, in the flat portion of the signal, the mixing ratio of the output of the high-pass filter 302 composed of a digital filter with a small number of taps is increased, so that it is difficult to be affected by samples near the target sample position. Therefore, the occurrence of bumps 64 as shown in FIG. 5B can be reduced in the flat portions before and after the edge portion.

  In the above-described configuration, the two input signals of the mixing circuit 305 are not shown because the number of taps of the digital filter is different, but a delay circuit for synchronizing each input signal as a target sample position. However, it goes without saying that each system is provided. Similarly, the flat part detection circuit 306 and the subtraction circuit 31 are also provided with a delay circuit for timing adjustment, but the illustration is omitted for the sake of simplicity. The same applies to other circuit parts described later.

<Detailed Configuration Example of Signal Reduction Area / Reduction Amount Detection Circuit 50>
Next, a detailed configuration example of the signal reduction region / reduction amount detection circuit 50 in this embodiment will be described. The signal reduction region / reduction amount detection circuit 50 according to this embodiment determines how far a region from the edge portion is to be a signal reduction region according to the occurrence of ringing that occurs in the target input video signal Vi. It has a configuration that can be set easily. For this reason, in this embodiment, for example, the state of occurrence of ringing occurring in the target input video signal Vi is examined in advance, and the distance from the edge portion is determined as the signal reduction region according to the state of occurrence. I am trying to decide.

  FIG. 12 is a block diagram showing a configuration example of the signal reduction region / reduction amount detection circuit 50 in this embodiment. 13 to 16 are diagrams for explaining a configuration example of the signal reduction region / reduction amount detection circuit 50 in this embodiment. The configuration of the signal reduction region / reduction amount detection circuit 50 in this embodiment will be described below with reference to FIGS.

  As shown in FIG. 12, in the signal reduction region / reduction amount detection circuit 50 in this embodiment, an input video signal (digital video signal) Vi is supplied to a high-pass filter 501 constituted by a digital filter. In this example, the high-pass filter 501 is a 5-tap digital filter, and the filter coefficient is, for example, as shown in FIG.

  The output S1 of the high-pass filter 501 is supplied to the absolute value circuit 502 to be converted into an absolute value, and the absolute value output S2 is supplied to the nonlinear conversion circuits 503 and 504. These nonlinear conversion circuits 503 and 504, as will be described in detail later, ringing is conspicuous at the edge portion of the large amplitude and not conspicuous at the edge portion of the medium amplitude or the small amplitude. It is provided in order to change the detection judgment as to whether or not the ringing occurs at the edge portion having a small amplitude.

  These non-linear circuits 503 and 504 are supplied to low-pass filters 505 and 506, respectively, which are digital filters. In this example, the low-pass filters 505 and 506 are both 3-tap digital filters having filter coefficients as shown in FIG.

  The output S3 of the low-pass filter 505 is supplied to the signal reduction region setting circuit 507. The signal reduction region setting circuit 507 includes a plurality of delay circuits 508 to 512 for setting a signal reduction region, amplifiers 513 to 516, and a maximum value detection circuit 517.

  In the signal reduction region setting circuit 507, the output S3 of the low-pass filter 505 is delayed by the delay circuit 510 by a predetermined delay amount DLc. In this example, the output S4 of the delay circuit 510 is a signal at the sample position of interest. Then, the delay circuits 508 and 509 delay the output S3 of the low-pass filter 505 by a different delay amount that is smaller than the delay amount DLc, respectively, and obtain signals S5 and S6 at time points before the output S4 at the sample position of interest. .

  Further, the delay circuits 511 and 512 further delay the output S4 of the delay circuit 510, thereby delaying the output S3 of the low-pass filter 505 by a different delay amount, which is larger than the delay amount DLc, respectively. Signals S7 and S8 at a later time are obtained.

  In this embodiment, the delay amounts of the delay circuits 508 to 512 are set as follows, for example. That is, the delay amount DLc of the delay circuit 510 is 17 samples, the delay amount of the delay circuit 508 is 0 samples (no delay), and the delay amount of the delay circuit 509 is 8 samples. The delay amount of the delay circuit 511 is 9 samples, and the delay amount of the delay circuit 512 is 17 samples.

  Therefore, in this example, the output S4 of the delay circuit 510 and the output S5 of the delay circuit 508 are separated by 17 samples, and the output S4 of the delay circuit 510 and the output S6 of the delay circuit 509 are separated by 9 samples, respectively. Since the delay amount of the delay circuit 511 is 9 samples and the delay amount of the delay circuit 512 is 17 samples, the signals S5, S6, S7, and S8 are centered on the output S4 of the delay circuit 510. The signals are at different positions for the same time before and after.

  The outputs S5, S6 and S7, S8 of the delay circuits 508, 509 and the delay circuits 511, 512 are supplied to the maximum value detection circuit 517 through the amplifiers 513, 514, 515, 516, respectively. The maximum value detection circuit 517 outputs the maximum value of the input signals S5, S6 and S7, S8 at each time point. The output S9 of the maximum value detection circuit 517 is supplied to the division circuit 518.

  The output of the low-pass filter 506 is supplied to the division circuit 518 through a delay circuit 519 having a delay amount equal to that of the delay circuit 510 that obtains the output S4 of the sample position of interest. The delay circuit 519 is for synchronizing the output of the low-pass filter 506 with the sample position of interest.

  The division circuit 518 divides the output S9 of the maximum value detection circuit 517 by the output of the low-pass filter 506 through the delay circuit 519. Note that in the division circuit 518, when the value of the output of the low-pass filter 506 through the delay circuit 519 is zero, the value of the output of the low-pass filter 506 is replaced with the minimum value that can be expressed, and division is performed.

  By the processing in the above-described nonlinear conversion circuits 503 and 504 and the division circuit 518, the ringing is easily detected at the edge portion of the large amplitude where the ringing is conspicuous, and the edge of the medium amplitude or small amplitude where the ringing is not so conspicuous. In part, the detection sensitivity of ringing is lowered.

  That is, in this embodiment, the non-linear conversion circuit 503 has an input / output characteristic in the small amplitude and medium amplitude regions of the input signal as shown in FIG. Also, it is assumed that it has a non-linear characteristic lifted as shown by a solid line. That is, the nonlinear conversion circuit 503 outputs an output signal at a lower output level than the linear case when the input signal is equal to or lower than the predetermined level θ2, and the linear signal when the input signal is equal to or higher than the predetermined level θ2. The output signal is output at a higher output level.

  On the other hand, as shown in FIG. 15B, the input / output characteristics of the non-linear conversion circuit 504 are more solid as shown by a solid line than in the case of a linear form as shown by a broken line, as shown in FIG. It has the nonlinear characteristics raised. That is, the nonlinear conversion circuit 504 outputs an output signal at an output level larger than the linear case when the input signal is equal to or lower than the predetermined level θ2, and when the input signal is equal to or higher than the predetermined level θ2, An output signal is output at a lower output level.

  In the division circuit 518, as described above, the output obtained by passing the output of the nonlinear conversion circuit 503 through the low-pass filter 505 is divided by the output obtained by passing the output of the nonlinear circuit 504 through the low-pass filter 506. The large amplitude portion is emphasized and easily detected as ringing, and the small amplitude portion is difficult to detect as ringing.

  This will be further described with reference to FIGS. 16 and 17.

  That is, as shown in FIG. 16A, when the signal has a large amplitude, the ringing is also large. On the other hand, when the signal has a medium amplitude and a small amplitude, as shown in FIG. Even if ringing or a signal similar to ringing occurs in the edge portion, it becomes small and is not noticeable on the display image.

  When a circuit having a linear input / output characteristic is provided instead of the non-linear conversion circuits 503 and 504, the division circuit 518 outputs a detection output regardless of whether the signal has a large amplitude or a medium amplitude or a small amplitude. The value will be similar.

  On the other hand, when the nonlinear conversion circuits 503 and 504 having nonlinear input / output characteristics are provided, when the signal has a large amplitude, the nonlinear conversion circuit 503 outputs the signal with a larger amplitude. In the non-linear conversion circuit 504, the output is output with the amplitude reduced. In the division circuit 518, the signal on the nonlinear conversion circuit 503 side becomes a numerator and the signal on the nonlinear conversion circuit 504 side becomes a denominator, so that the division result is more emphasized as shown in FIG. Detected.

  Further, when the nonlinear conversion circuits 503 and 504 having nonlinear input / output characteristics are provided, if the signal has medium amplitude and small amplitude, the nonlinear conversion circuit 503 outputs the signal with smaller amplitude, In the nonlinear conversion circuit 504, the amplitude is output with a larger amplitude. Therefore, the division result in the division circuit 518 is detected as being smaller as shown in FIG.

  Therefore, the ringing in the large amplitude portion is more easily detected, and the detection sensitivity of the ringing is lowered in the medium amplitude portion and the small amplitude portion.

  The output of the division circuit 518 is supplied to a non-linear conversion circuit 520 for generating a detection output value α corresponding to the period and amount of reduction of ringing. This nonlinear conversion circuit 520 has input / output nonlinear characteristics similar to those shown in FIG. That is, the detected output value α from the nonlinear conversion circuit 520 is α = 0 when the output of the division circuit 518 is smaller than the first predetermined value θ1, and according to the input value when the output is larger than the first predetermined value θ1. It becomes constant when it becomes larger than the second predetermined value θ2.

  The output of the non-linear conversion circuit 520 is supplied to the spreading circuit 521, and after being subjected to processing for extending the period for reducing ringing back and forth, it is outputted as the detection output value α of the signal reduction region / reduction amount detection circuit 50. In this example, the spreading circuit 521 widens one sample back and forth as a signal reduction region. Note that the spreading circuit 521 may not be provided depending on the applied input video signal Vi.

  Next, the operation of the signal reduction region / reduction amount detection circuit 50 will be described with reference to FIG. 18 and FIG. Here, a case where an input video signal Vi having an edge portion with ringing as shown in FIG. 18A is supplied to the signal reduction region / reduction amount detection circuit 50 will be described.

  When the edge portion as shown in FIG. 18A is supplied to the high-pass filter 501, as the output S1, a signal obtained by differentiating the edge portion is output as shown in FIG. 18B. The output signal S1 is passed through the absolute value conversion circuit 502, and a signal as shown in FIG. 18C is obtained as the output signal S2. In FIG. 18B and subsequent figures, ringing is omitted for the sake of simplicity except for the waveform diagram of FIG.

  Then, after passing through the non-linear conversion circuits 503 and 504, respectively, they are supplied to the low-pass filters 505 and 506. From these low-pass filters 505 and 506, the output S2 of the absolute value conversion circuit 502 as shown in FIG. Is obtained by smoothing the output signal S3.

  Since the signal obtained by delaying the signal S3 shown in FIG. 18D by the delay circuit 510 is the output signal S4 at the sample position of interest, the signal shown in FIG. 18D is considered as the output S4. , 509 and 511, 512 outputs S5, S6 and S7, S8 are as shown in FIGS. 18E, 18F, 18G, and 18H.

  Therefore, the output S9 of the maximum value detection circuit 517 is a signal obtained by combining the outputs S7 and S8 at the front part of the edge part as shown in FIG. 18 (I), and is output at the rear part of the edge part. The signal is a combination of S5 and S6. When this is expanded by the spreading circuit 521, a signal as shown in FIG.

  Therefore, by supplying the signal shown in FIG. 18 (J) as the detection output value α to the output control circuits 24 and 25, the output terminal 29 is connected to the edge portion as shown in FIG. 18 (K). An output signal Vo with reduced front and rear ringing is obtained.

  As can be understood from the above description, the delay circuits 508, 509, 511, and 512 are circuits for generating a signal reduction region. By changing the delay amounts of the delay circuits 508, 509, 511, and 512, it is possible to easily change and set the width of the signal reduction region before and after the edge portion. In this example, the signal reduction regions before and after the edge portion are generated by two delay circuits, but the number is also changed according to the width of the signal reduction region. Thus, a signal reduction region having a desired width can be generated.

  Therefore, by checking in advance the occurrence of ringing that occurs in the target input video signal Vi and setting the number of delay circuits and the delay amount constituting the signal reduction region setting circuit 507 according to the occurrence, A desired signal reduction region can be obtained. Note that the signal reduction region may be set according to the occurrence state of ringing or the like, and does not have to be a front and rear target section with the edge portion as the center.

  When there are no flat portions before and after the edge portion, even if there is ringing, it is not noticeable. Therefore, it is not necessary to reduce the signal in these portions, and the detection output value α may be zero or a minute value. In the signal reduction region / reduction amount detection circuit 50 of this embodiment, this point is also taken into account by the above-described configuration.

  That is, for example, when the input video signal Vi is a signal composed of only edges as shown in FIG. 19A, the output S1 of the high-pass filter 501 is almost input as shown in FIG. 19B. The signal appears as it is. Then, as shown in FIG. 19C, the absolute value circuit 502 obtains a signal S2 in which the signal S1 is all folded back to positive polarity.

  From the low-pass filters 505 and 506, as shown in FIG. 19D, a substantially DC signal S3 obtained by smoothing the high-frequency signal S2 is obtained. For this reason, as shown in FIG. 19E, the output signal S9 of the maximum value detection circuit 517 is also substantially a DC signal. Accordingly, the output of the dividing circuit 518 is obtained as a small constant value as shown in FIG. 19F, and the detected output value α is almost zero or a minute value. Therefore, the output video signal Vo is as shown in FIG. As shown in G), the input video signal Vi is a signal that is output without being substantially reduced.

  In consideration of the fact that the level of ringing decreases as the distance from the edge portion increases, the signal in the signal reduction region generated by the delay circuits 508 to 512 decreases as the distance from the edge decreases. You may make it be a simple signal.

  For example, in the signal reduction region / reduction amount detection circuit 50 described above, weighting is performed so as to lower the level of the output of the delay circuit farther from the sample position of interest. For example, in the case of FIG. 12 described above, as shown in FIGS. 20A and 20D, the levels of the outputs S5 and S8 of the delay circuits 508 and 512 are lowered. Weighting is performed, and the levels of the outputs of the delay circuits 509 and 511 are not lowered as shown in FIGS.

  In this way, as shown in FIG. 20E, the output S9 of the maximum value detection circuit 517 becomes a signal whose level becomes lower at the front part and the rear part of the edge part as it leaves the edge part. Ideally, a signal obtained by smoothing the output S9 is preferable as shown in FIG.

[Other Embodiments and Modifications]
In the amplitude dividing circuit 23, the subtracting circuit 41 subtracts the small amplitude portion extracted by the small amplitude portion extracting circuit 40 from the output VHi from the high frequency component extracting circuit 30 so as to obtain a large amplitude portion. However, without providing the subtracting circuit 41, the output VHi from the high frequency component extraction circuit 30 is passed through a nonlinear conversion circuit having an input / output nonlinear characteristic that outputs only the large amplitude portion, so that the high frequency component is output. Of course, a large amplitude portion may be extracted.

  In the above description, the case where ringing is reduced has been described. However, when an image is compressed by MPEG (Moving Picture Experts Group), the vicinity of a signal having a large amplitude is caused by the loss of signal components. The video signal processing apparatus according to the present invention can also be applied to reduce mosquito noise generated in the flat portion of the image signal in the same manner as described above.

  Further, the video signal processing apparatus according to the present invention can be applied not only to the processing in the horizontal direction for the video signal but also to the processing in the vertical direction. That is, the present invention can be applied not only to the reduction processing of ringing and mosquito noise occurring in the horizontal direction of the screen, but also to the reduction processing of mosquito noise occurring in the vertical direction of the screen.

  Moreover, although the above-described configuration is a digital circuit configuration in which the input video signal is a digital video signal, it is of course possible to have an analog circuit configuration for an analog input video signal.

  When digital input video signals are to be processed, the above-described video signal processing device is not configured by a hardware digital circuit, but all processing is programmed and software is executed by a computer using the program. The processing can be executed by the processing.

It is a block diagram which shows the example of a whole structure of embodiment of the video signal processing apparatus by this invention. It is a figure for demonstrating the input-output characteristic of the one part circuit of the structure of FIG. It is a figure for demonstrating a digital filter. It is a figure for demonstrating the frequency characteristic of a high pass filter. It is a figure for demonstrating the malfunction which generate | occur | produces by the difference in the tap number of a filter. FIG. 2 is a block diagram illustrating a more detailed configuration example of a part of the band dividing circuit of FIG. 1. It is a figure which shows the example of the filter coefficient of a digital filter. It is a figure which shows the example of the filter coefficient of a digital filter. It is a figure which shows the example of the filter coefficient of a digital filter. It is a figure which shows the example of the filter coefficient of a digital filter. It is a figure which shows an example of the input-output nonlinear characteristic of the nonlinear conversion circuit used for a part of circuit of FIG. FIG. 2 is a block diagram illustrating a more detailed configuration example of a part of the signal reduction region / reduction amount detection circuit of FIG. 1. It is a figure which shows the example of the filter coefficient of a digital filter. It is a figure which shows the example of the filter coefficient of a digital filter. It is a figure used for description of the circuit of FIG. It is a figure used for description of the circuit of FIG. It is a figure used for description of the circuit of FIG. It is a wave form diagram used for operation | movement description of the circuit of FIG. It is a wave form diagram used for operation | movement description of the circuit of FIG. It is a figure used for description of the other example of the circuit of FIG. It is a figure for demonstrating the ringing of the edge part vicinity. It is a block diagram which shows an example of the conventional ringing reduction apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 22 ... Band division circuit, 23 ... Amplitude division circuit, 24, 25 ... Output control circuit, 27, 28 ... Mixing circuit, 30 ... High frequency component extraction circuit, 40 ... Small amplitude partial extraction circuit, 50 ... Signal reduction area | region reduction Quantity detection circuit 301... High-pass filter with a large number of taps 302. High-pass filter with a small number of taps 305... Mixing circuit 306 ... Flat part detection circuit 501... High-pass filter 502 502 Absolute value circuit 503 504. Non-linear conversion circuit, 505, 506 ... low pass filter, 508 to 512 and 519 ... delay circuit, 517 ... maximum value detection circuit, 518 ... division circuit

Claims (21)

First dividing means for dividing the input video signal into a low frequency component and a high frequency component;
A signal reduction region / reduction amount detection means for calculating a detection output corresponding to a signal reduction region and a signal reduction amount before and after an edge portion of the input video signal from the input video signal;
Second dividing means for dividing a high frequency component of the input video signal divided by the first dividing means into a large amplitude part and a small amplitude part;
Small amplitude part output control means for reducing the small amplitude part from the second dividing means in accordance with the detection output of the signal reduction region / reduction amount detection means;
A large amplitude portion of a high frequency component of the input video signal divided by the second dividing means, a small amplitude portion of a high frequency component of the input video signal from the small amplitude portion output control means, and the input video and a mixing means for mixing the low frequency components of the signal,
The second dividing means includes
Non-linear means with non-linear input / output characteristics for extracting a small amplitude portion of a high frequency component of the input video signal
With
The nonlinear means is controlled in accordance with the signal reduction amount obtained by the signal reduction region / reduction amount detection means, and a larger amplitude signal is output from the nonlinear means as the signal reduction amount is larger. The noise removal apparatus characterized by the above-mentioned. In the noise removal apparatus of Claim 1 ,
The input video signal is a digital signal,
The first dividing means includes
A first digital filter having a steep attenuation characteristic and a large number of taps;
A second digital filter having a damping characteristic slower than that of the first digital filter and having a smaller number of taps, and
A noise removing apparatus comprising: a second mixing unit that mixes the output of the first digital filter and the output of the second digital filter. In the noise removal apparatus of Claim 2 ,
The noise removal apparatus characterized in that the mixing ratio of the output of the second digital filter in the second mixing means is increased as the level of the input video signal is flatter. In the noise removal apparatus of Claim 1 ,
The signal reduction region / reduction amount detection means includes:
A high-pass filter for extracting a high-frequency component of the input video signal;
Absolute value obtaining means for obtaining an absolute value of the output signal of the high pass filter;
A first low pass filter for extracting a low frequency component of the output of the absolute value converting means;
By delaying the output of the first low-pass filter by an amount smaller than the first predetermined amount, with the position where the output of the first low-pass filter is delayed by a first predetermined amount as the signal position of interest, By obtaining a first output at a time point before the target signal position and delaying the output of the first low-pass filter by an amount larger than the first predetermined amount, Means for obtaining a second output of time;
Wherein the first output a second output and is supplied as an input signal, and a maximum value output means for outputting the maximum value of the input signal,
A noise removal apparatus that generates a detection output corresponding to the signal reduction region and the signal reduction amount based on the output of the maximum value output means. In the noise removal apparatus of Claim 4 ,
Dividing means for dividing the output of the maximum value output means by the low-frequency component of the output of the absolute value converting means delayed by the first predetermined amount;
Based on the output of the said division means, the detection output according to the said signal reduction area | region and signal reduction amount is produced | generated. The noise removal apparatus characterized by the above-mentioned. In the noise removal apparatus of Claim 4 ,
A second low-pass filter for extracting a low-frequency component of the output of the absolute value converting means;
Dividing means for dividing the output of the maximum value calculating means by the output of the second low-pass filter delayed by the first predetermined amount;
A first non-linear processing means provided in a preceding stage of the first low-pass filter, wherein the input / output characteristics are lower than those in the case of linearity in a region of small amplitude and medium amplitude of the input signal;
Wherein provided upstream of the second low-pass filter, input and output characteristics, the small amplitude and medium amplitude domain of the input signal, further comprising a second nonlinear processing means of the non-linear characteristic raised than linear A featured noise removal device. In the noise removal apparatus of Claim 4 ,
Each of the first output and the second output includes a plurality of delay outputs obtained by delaying the output of the first low-pass filter by different delay amounts,
The noise removal apparatus characterized by lowering the output level of an output farther from the target signal position among the plurality of delayed outputs. A first dividing step for dividing the input video signal into a low frequency component and a high frequency component;
A signal reduction region / reduction amount detection step for calculating a detection output corresponding to a signal reduction region and a signal reduction amount before and after an edge portion of the input video signal from the input video signal;
A second division step of dividing the high frequency component of the input video signal divided by the first division step into a large amplitude portion and a small amplitude portion;
A small amplitude portion output control step for reducing the small amplitude portion divided in the second division step in accordance with the detection output calculated by the signal reduction region / reduction amount detection step ;
A high-amplitude portion of the high-frequency component of the input video signal divided in the second division step; a small-amplitude portion of the high-frequency component of the input video signal that is output-controlled in the small-amplitude partial output control step; and a mixing step of mixing the low frequency component of the input video signal,
In the second division step, in order to extract a small amplitude portion of a high frequency component of the input video signal, nonlinear processing whose input / output characteristics are nonlinear characteristics is performed,
The nonlinear characteristic is controlled in accordance with the signal reduction amount obtained in the signal reduction region / reduction amount detection step, and a larger amplitude signal is output as the signal reduction amount is larger. A characteristic noise removal method. In the noise removal method of Claim 8 ,
The input video signal is a digital signal,
The band dividing step includes
A first digital filter having a steep attenuation characteristic and a large number of taps and a second digital filter having a damping characteristic slower than the first digital filter and a small number of taps are used, and the output of the first digital filter If the noise removing method characterized in that it comprises a second mixing step of mixing an output of said second digital filter. In the noise removal method of Claim 9 ,
The noise removal method characterized by increasing the mixing ratio of the output of the second digital filter in the second mixing step as the level of the input video signal is flatter. In the noise removal method of Claim 8 ,
The signal reduction region / reduction amount detection step includes:
A high frequency component extracting step of extracting a high frequency component of the input video signal;
An absolute value conversion step for obtaining an absolute value of the high frequency component output obtained in the high frequency component extraction step;
A first low frequency component extracting step for extracting a low frequency component of the output of the absolute value converting step;
The low frequency obtained in the first low frequency component extraction step with the position obtained by delaying the low frequency component output obtained in the first low frequency component extraction step by a first predetermined amount as a target signal position By delaying the component output by an amount smaller than the first predetermined amount, a first output at a time point before the target signal position is obtained, and obtained in the first low-frequency component extraction step. Obtaining a second output at a later time than the signal position of interest by delaying a low-frequency component output by an amount greater than the first predetermined amount;
As the first output and the second output and the input signal, and a maximum value output step of outputting the maximum value,
On the basis of the output of the maximum value output step, the noise removing method and generating a detection output corresponding to the signal reduction region and signal reduction amount. In the noise removing method according to claim 1 1,
A division step of dividing the output of the maximum value output step by the delay of the low frequency component of the output of the absolute value step by the first predetermined amount,
On the basis of the output of the division step, the noise removing method and generating a detection output corresponding to the signal reduction region and signal reduction amount. In the noise removing method according to claim 1 1,
A second low frequency component extracting step for extracting a low frequency component of the output of the absolute value step;
A division step of dividing the output of the maximum value calculation step by the output of the second low frequency component extraction step delayed by the first predetermined amount;
A first non-linear operation is performed before the first low-frequency component extraction step, and performs processing of non-linear characteristics that are lower than those in the case of linearity in the regions of small and medium amplitudes of the input signal. Processing steps;
Second nonlinear processing is performed before the second low-frequency component extracting step, and performs processing of nonlinear characteristics in which the input / output characteristics are raised in the small amplitude and medium amplitude regions of the input signal as compared with the linear case. Step and
Noise removing method characterized by comprising a. In the noise removing method according to claim 1 1,
Each of the first output and the second output includes a plurality of outputs obtained by delaying the output of the first low-frequency component extraction step by different delay amounts,
The noise removal method characterized by lowering the output level of an output farther from the target signal position among the plurality of outputs. In order to reduce the noise near the edge of the input video signal,
A first dividing means for dividing the input video signal into a low-frequency component and a high-frequency component,
A signal reduction region / reduction amount detection means for calculating a detection output corresponding to a signal reduction region and a signal reduction amount before and after an edge portion of the input video signal from the input video signal;
A second dividing means for dividing the high frequency component of the input video signal divided by said first dividing means to a large amplitude portion and a small amplitude portion,
A small amplitude portion output control means for reducing the small amplitude portion from the second dividing means in accordance with the detection output of the signal reduction region / reduction amount detection means;
A large amplitude portion of a high frequency component of the input video signal divided by the second dividing means, a small amplitude portion of a high frequency component of the input video signal from the small amplitude portion output control means, and the input video Mixing means for mixing the low frequency components of the signal ;
With
The second dividing means includes
Non-linear means with non-linear input / output characteristics for extracting a small amplitude portion of a high frequency component of the input video signal
With
The nonlinear means is controlled in accordance with the signal reduction amount obtained by the signal reduction region / reduction amount detection means, and a larger amplitude signal is output from the nonlinear means as the signal reduction amount is larger.
The noise removal program for functioning as a noise removal apparatus characterized by the above-mentioned . The noise removal program according to claim 15,
The first dividing means includes
The output of the attenuation characteristic is a first digital filter means is often steep and the number of taps, the attenuation characteristic is mixing the output of the second digital filter means is less slow the number of taps than the first digital filter means 2 including the mixing means
The noise removal program for functioning as a noise removal apparatus characterized by the above-mentioned . In the noise removal program according to claim 16 ,
A noise removal program for functioning as a noise removal device , characterized in that the mixing ratio of the output of the second digital filter in the first mixing means is increased as the level of the input video signal is flatter. The noise removal program according to claim 15 ,
The signal reduction region / reduction amount detection means includes:
A high-pass filter means for extracting a high frequency component of the input video signal,
And absolute value means for obtaining the absolute value of the output signal of said high-pass filter,
A first low pass filter means for extracting a low frequency component of the output of said absolute value means,
Delaying the output of the first low-pass filter means by an amount smaller than the first predetermined amount, with the position where the output of the first low-pass filter means is delayed by a first predetermined amount as a target signal position To obtain a first output at a time point before the target signal position, and delay the output of the first low-pass filter means by an amount larger than the first predetermined amount, thereby It means for obtaining a second output time points after,
Wherein the first output a second output and is supplied as an input signal, and a maximum value output means for outputting the maximum value of the input signal,
A noise removal program for functioning as a noise removal device , wherein a detection output corresponding to the signal reduction region and the signal reduction amount is generated based on an output of the maximum value output means. The noise removal program according to claim 18 ,
Dividing means for dividing the output of the maximum value calculating means by the low frequency component of the output of the absolute value converting means delayed by the first predetermined amount
With
A noise removal program for functioning as a noise removal device , characterized in that a detection output corresponding to the signal reduction region and the signal reduction amount is generated based on the output of the division means. The noise removal program according to claim 18 ,
A second low-pass filter means for extracting a low frequency component of the output of said absolute value means,
The output of said maximum value calculation means, and division means for dividing an output of said second low-pass filter means which is delayed by the first predetermined amount,
Wherein provided upstream of the first low-pass filter means, input-output characteristics, the small amplitude and medium amplitude domain of the input signal, a first nonlinear processing means of the non-linear characteristic drops have than linear,
A second non-linear processing means provided in a preceding stage of the second low-pass filter means, wherein the input / output characteristics are higher than those in the linear case in the small and medium amplitude regions of the input signal ;
The noise removal program for functioning as a noise removal apparatus characterized by providing . The noise removal program according to claim 18 ,
Each of the first output and the second output consists of a plurality of outputs obtained by delaying the output of the first low-pass filter means by different delay amounts,
A noise removal program for functioning as a noise removal device , wherein the output level of the output farther from the target signal position among the plurality of outputs is lowered.

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