JP2564378B2 - MUSE signal processing circuit - Google Patents

Description

The present invention relates to a signal processing circuit of a MUSE decoder.

[Conventional technology]

Regarding the MUSE decoder, it is reported in "Development of MUSE method, NHK technology research, Showa 62, Vol. 39, No. 2". Although the enhancer is not described in the above paper, it is usually shown in "Construction of Adaptive Spatio-Temporal Interpolation Filter Used for Progressive Scan Conversion of High Definition Television, 1983 IEICE General Conference, 5-43". As described above, after the luminance signal is created, it is enhanced in the meaning of aperture compensation.

[Problems to be Solved by the Invention]

Conventional MUSE decoders are not always configured for optimal enhancement for both static and moving parts. Therefore, there is a problem that the enhancement for the stationary portion becomes insufficient, or the backlash noise of the moving portion increases.

An object of the present invention is to solve the above problems and to provide a MUSE decoder capable of outputting a high-quality image in both a still portion and a moving portion.

[Means for solving the problem]

The MUSE signal processing circuit of the present invention is provided with a still image processing system and a moving image processing system having a moving image enhancing function, and after proportionally mixing the outputs thereof with the motion signal, the enhance amount for the still image can be varied by the motion signal. Is provided.

Alternatively, the MUSE signal processing circuit of the present invention is provided with a still image processing system including a still image enhancer and a moving image processing system having a moving image enhancing function, and outputs thereof are proportionally mixed with a motion signal.

[Action]

In the first configuration, first, the moving portion is optimally enhanced by the moving image enhancing function, and only the still portion is optimally enhanced by the still image enhancer after proportional mixing.

In the second configuration, the moving part is optimally enhanced by the moving image enhance function, the still part is optimally enhanced by the still image enhancer, and then the moving part and the still part are combined by proportional mixing by the motion signal.

〔Example〕

 The present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of the present invention.
From the input terminal 1, a MUSE signal that has been AD-converted and has undergone de-emphasis processing and transmission inverse gamma correction is input.
The processing for still images is performed by the inter-frame interpolation circuit 2 and LP for still images.
This is performed by F3, the sampling frequency conversion circuit 4, and the inter-field interpolation circuit 5. The moving image processing is performed by the moving image low-pass filter (LPF) 6, the sampling frequency conversion circuit 4, and the moving image enhancer 7. The moving part detection circuit 8 inputs a motion signal to a mix circuit 9 and a still image enhancer 11 whose amount of enhancement is variable. MIX
The circuit 9 proportionally mixes the output of the inter-field interpolation circuit 5 and the output of the moving image enhancer 7 with a motion signal. The output of the MIX circuit 9 is passed through a signal processing circuit 10 such as low-range sedge replacement,
It is input to the still image enhancer 11 capable of enhancing the amount. A still image enhancer 11 capable of enhancing the amount enhances only the still portion of the input signal based on the motion signal. The moving image enhancer 7 and the still image enhancer 11 whose amount of enhancement is variable will be described in detail later.

FIG. 2 is a block diagram showing an embodiment of the present invention. From the input terminal 1, a MUSE signal that has been AD-converted and has undergone de-emphasis processing and transmission inverse gamma correction is input. The processing for still images is for interframe interpolation circuit 2 and still images
This is performed by the LPF 3, the sampling frequency conversion circuit 4, and the inter-field interpolation circuit 5. The moving picture processing is performed by the moving picture LPF 12 having the enhancing function and the sampling frequency conversion circuit 4. The moving part detecting circuit 8 inputs the moving signal to the MIX circuit 9 and the still image enhancer 11 whose amount of enhancement is variable. The MIX circuit 9 is an inter-field interpolation circuit 5
And the output of the sampling frequency conversion circuit 4 are proportionally mixed by the motion signal. The output of the MIX circuit 9 is input to a still image enhancer 11 whose amount of enhancement is variable, through a signal processing circuit 10 such as low-frequency shift change. The still image enhancer 11 with a variable amount of enhancement enhances only the still portion of the input signal based on the motion signal. The LPF12 for moving images having the enhance function will be described in detail later.

FIG. 3 is a block diagram showing an embodiment of the present invention. From the input terminal 1, a MUSE signal that has been AD-converted and has undergone de-emphasis processing and transmission inverse gamma correction is input. The processing for still images is for interframe interpolation circuit 2 and still images
It is performed by the LPF 3, the sampling frequency conversion circuit 4, the inter-field interpolation circuit 5, and the still image enhancer 13.
The moving image processing is performed by the moving image LPF 6, the sampling frequency conversion circuit 4, and the moving image enhancer 7. The moving part detecting circuit 8 inputs the moving signal to the MIX circuit 9. MIX circuit 9 outputs still image enhancer 13 and moving image enhancer 7.
The output of is proportionally mixed by the motion signal. The still image enhancer 13 will be described in detail later.

FIG. 4 is a block diagram showing an embodiment of the present invention. From the input terminal 1, a MUSE signal that has been AD-converted and has undergone de-emphasis processing and transmission inverse gamma correction is input. The processing for still images is for interframe interpolation circuit 2 and still images
It is performed by the LPF 3, the sampling frequency conversion circuit 4, the inter-field interpolation circuit 5, and the still image enhancer 13.
The video processing is the LPF12 for video with the enhance function.
And sampling frequency conversion circuit 4.
The moving part detecting circuit 8 inputs the moving signal to the MIX circuit 9. The MIX circuit 9 proportionally mixes the output of the still image enhancer 13 and the output of the sampling frequency conversion circuit 4 with a motion signal.

Next, the still image enhancer 13, the still image enhancer 11 having a variable amount of enhancement, the moving image enhancer 7, and the moving image LPF 12 having the enhancing function will be described. FIG. 5 is a graph showing the transmittable area of a still image. FIG. 6 is a grab showing a transmittable area of a moving image. The still image enhancer 13 and the still image enhancer 11 with a variable amount of enhancement are the fifth
The configuration is such that the high range in the transmittable area in the figure is raised. Video enhancer 7 and video LPF12 with enhance function
Is configured to raise the high band within the transmittable band of FIG.

7 and 8 are block diagrams showing an example of the still image enhancer 13. An example of the still image enhancer in FIG. 7 is an HPF14 having a pass band in the high frequency range within the still image transferable area in FIG. 5, and a delay circuit having the same delay time as the HPF14.
15, an adder circuit 16 for adding the outputs of the HPF 14 and the delay circuit 15
Consists of An example of the still image enhancer shown in FIG.
In addition to the HPF14, delay circuit 15 and adder circuit 16 shown in the figure,
A non-linear processing circuit 17 is provided after the PF14. The HPF 14 and the non-linear processing circuit 17 will be described later.

9 and 10 are block diagrams showing an example of a still image enhancer 11 with a variable amount of enhancement. An example of the still image enhancer with a variable amount of enhancement shown in FIG. 9 is an HPF14 having a pass band in the high range within the transmittable area of the still image shown in FIG.
An attenuator 18 whose attenuation can be varied by a motion signal input from the input terminal 19, a delay circuit 15 having the same delay time as the cascade connection of the HPF 14 and the attenuator 18, and the outputs of the attenuator 18 and the delay circuit 15. It comprises an adder circuit 16 for adding. here,
The amount of attenuation of the attenuator 18 is large when the motion signal is large. 10th
An example of the still image enhancer 11 with variable amount of enhancement shown in the figure is provided with a non-linear processing circuit 17 after the HPF 14 in addition to the HPF 14, the attenuator 18, the delay circuit 15 and the addition circuit 16 of the example of FIG. It is configured.

11 and 12 are block diagrams showing an example of a moving image enhancer. An example of the moving picture enhancer in FIG. 11 is an HP whose pass band is the high frequency range within the transmission area of the moving picture in FIG.
F20, HP delay circuit 15 having the same delay time as F20, HP
It is composed of an adder circuit 16 that adds the outputs of F20 and the delay circuit 15. An example of the motion picture enhancer of FIG. 12 is the same as that of FIG.
In addition to the HPF 20, the delay circuit 15 and the adder circuit 16, a non-linear processing circuit 17 is provided in the subsequent stage of the HPF 20. HPF2
Zero will be described later.

FIG. 13 shows a block diagram of an example of the moving picture LPF 12 having the enhancing function. Reference numeral 21 is a 1H delay circuit for vertical delay, and 22, 23, and 24 are horizontal LPFs having different characteristics. FIG. 14 is a block diagram showing an example of the horizontal LPFs 22, 23, 24. In FIG. 14, 25 is a 1-dot delay circuit for horizontal delay, and 26 is a coefficient unit. The delay time of the 1-dot delay circuit 25 is one cycle of 32.4 MHz. Horizontal LPF 22, 23,
24 coefficients α ₀ ²² , α ₁ ²² , α ₂ ²² , α ₃ ²² , α ₀ ²³ , α ₁ ²³ , α ₂ ²³ ,
α ₃ ²³ , α ₀ ²⁴ , α ₁ ²⁴ , α ₂ ²⁴ , α ₃ ²⁴ have a transmission band of the moving image of FIG. 6 as a pass band, and have a DC gain of 1, and the moving image of FIG. High gain within the transmittable band is 1
Set so that it is above.

Next, the still image HPF 14, the moving image HPF 20, and the non-linear processing circuit 17 will be described. HP for still images in Figs. 15 and 16
The block diagram of an example of F14 is shown. In the figure 27 is a delay time of 48.
A 1-dot delay circuit for one cycle of 6 MHz is shown. The HPF14 for still images in FIG. 15 has a peak at a horizontal frequency of 24.3 MHz. The coefficients β ₀ , β ₁ , β ₂ , β _{3 in} FIG. 16 are the HPF14 for still images.
Is set so as to have a peak within the transmittable band of the still image in FIG. For example, β ₀ = 0, Let β ₃ = 0. At this time, HPF14 for still images in Fig. 16
Has peaks at (horizontal frequency = 24.3 MHz, vertical frequency = 0 TV lines) and (horizontal frequency = 0 MHz, vertical frequency = 562.5 TV lines). FIG. 17 shows a block diagram of an example of the moving picture HPF 20. The moving picture HPF20 shown in FIG. 17 has a peak at a horizontal frequency of 12.2 MHz. FIG. 18 is a graph showing an example of output characteristics of the non-linear processing circuit 17. The output is set to zero when the input has a small amplitude because of noise suppression, and the output is clipped when the input has a large amplitude because of ringing suppression.

Finally, a block diagram of one embodiment of the present invention is shown in FIGS. 19 and 20 as an eclectic configuration of the embodiment shown in FIGS.

〔The invention's effect〕

According to the present invention, since different enhancers act on the stationary part and the moving part, the amount of enhancement of the stationary part and the center frequency of the enhancement can be optimally set independently of those of the moving part. The central frequencies of quantity and enhancement can be optimally set independently of those of the stationary part. Therefore, it is possible to provide a MUSE decoder that outputs a high-quality image.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of the present invention, FIG. 2 is a block diagram of an embodiment of the present invention, FIG. 3 is a block diagram of an embodiment of the present invention, and FIG. FIG. 5 is a block diagram of an embodiment, FIG. 5 is a graph of a transmittable area of a still image, FIG. 6 is a graph of a transmittable area of a moving image, FIG. 7 is a block diagram showing an example of a still image enhancer, and FIG. FIG. 9 is a block diagram of an example of a still image enhancer, FIG. 9 is a block diagram of an example of a still image enhancer with a variable enhancement amount, FIG. 10 is a block diagram of an example of a still image enhancer with a variable enhancement amount, and FIG. A block diagram of an example of the video enhancer 7,
FIG. 12 is a block diagram of an example of the moving image enhancer 7, FIG.
Fig. 14 is a block diagram of an example of a moving image LPF with an enhancement function, Fig. 14 is a block diagram of an example of a horizontal LPF, Fig. 15 is a block diagram of an example of a still image HPF, and Fig. 16 is a still image HPF. FIG. 17 is a block diagram of an example of a moving image HPF, FIG. 18 is a graph of an example of input characteristics of a non-linear processing circuit, FIG. 19 is a block diagram of an embodiment of the present invention, and FIG.
The figure is a block diagram of one embodiment of the present invention. Explanation of code 2 …… Frame interpolation circuit, 3 …… LPF for still image, 4 …… Sampling frequency conversion circuit, 5 …… Field interpolation circuit, 6…
… Video LPF, 7 …… Video enhancer, 8 …… Moving part detection circuit, 9 …… MIX circuit, 11 …… Still image enhancer with variable amount of enhancement, 12 …… Video LPF with enhance function, 1
3 …… Still image enhancer, 14 …… Still image HPF, 17 …… Non-linear processing circuit, 18 …… Attenuator, 20 …… Video HPF, 21…
… 1H delay circuit, 22 ・ 23 ・ 24 …… Horizontal LPF, 25 …… 1 dot delay circuit, 26 …… Coefficient unit, 27 …… 1 dot delay circuit

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Ichio Nakagawa 292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa Inside the Home Appliance Research Laboratory, Hitachi, Ltd. (72) Inventor Yuichi Ninomiya 1-10-11 Kinuta, Setagaya-ku, Tokyo Issue Broadcasting Technology Institute, Japan Broadcasting Corporation

Claims (4)

(57) [Claims] 1. A signal processing circuit for processing a MUSE signal, the signal processing circuit being connected to an input terminal to which the MUSE signal is input, the interframe interpolating circuit, the still image low-pass filter, the sampling frequency converting circuit, and the interfield internal circuit. A still image processing system circuit comprising an insertion circuit; a moving image processing system circuit comprising a moving image low-pass filter, a sampling frequency conversion circuit, and a moving image enhancer connected to the input terminal; and connected to the interframe interpolation circuit. A motion part detection circuit; and a mixing circuit for proportionally mixing the output signal of the still image processing system circuit and the output signal of the moving image processing system circuit based on the motion signal which is the output signal of the motion part detection circuit. And ;, a still image enhancer that is connected to the mix circuit and the motion part detection circuit and can change the amount of enhancement based on the motion signal of the motion part detection circuit MUSE signal processing circuit, characterized in that it is composed of a. 2. A signal processing circuit for processing a MUSE signal, the signal processing circuit being connected to an input terminal to which the MUSE signal is input, the interframe interpolating circuit, the still image low-pass filter, the sampling frequency converting circuit, and the interfield internal circuit. A still image processing system circuit including an insertion circuit; a moving image processing system circuit including a moving image low-pass filter having an enhancing effect in a pass band and a sampling frequency conversion circuit, which is connected to the input terminal; A motion part detection circuit connected to the circuit; a mix for proportionally mixing the output signal of the still image processing system circuit and the output signal of the moving image processing system circuit based on the motion signal which is the output signal of the motion detection circuit Circuit; a still image enhancer that is connected to the mix circuit and the motion part detection circuit and can change the amount of enhancement based on the motion signal MUSE signal processing circuit, characterized by being composed Ri. 3. A signal processing circuit for processing a MUSE signal, the signal processing circuit being connected to an input terminal to which the MUSE signal is input, the interframe interpolating circuit, the still image low-pass filter, the sampling frequency converting circuit, and the interfield internal circuit. A still image processing system circuit including an insertion circuit and a still image enhancer; a moving image processing system circuit including a moving image low-pass filter, a sampling frequency conversion circuit, and a moving image enhancer connected to the input terminal; A MUSE signal processing circuit characterized by comprising a mix circuit for proportionally mixing the output signal of the system circuit and the output signal of the moving image processing system circuit based on the motion signal which is the output signal of the motion part detection circuit. . 4. A signal processing circuit for processing a MUSE signal, wherein the MUSE signal is connected to an input terminal, and an interframe interpolating circuit, a still image low-pass filter, a sampling frequency converting circuit, and an interfield interpolating circuit are provided. A still image processing system circuit including a still image enhancer; a moving image processing system circuit including a moving image low-pass filter having an enhancement effect in a pass band and a sampling frequency conversion circuit; a moving part detection circuit; MUSE signal processing characterized by comprising a mix circuit for proportionally mixing the output signal of the processing system circuit and the output signal of the moving image processing system circuit based on the motion signal which is the output signal of the motion part detection circuit circuit.