JPH09307894A - Video coder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain the efficient video coder by eliminating factors to decrease the coding efficiency in the case of applying compression coding to a telecine video image. SOLUTION: A frame frequency converter 11 receiving a telecine video image consisting of a plurality of frames detects and eliminates redundant fields. A noise filter 12 applies filtering to the input video signal in a time base direction and provides the result to a coder 13. The coder 13 applies compression coding to the video signal from which frame data are reduced to generate a bit stream.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a video coding device used for compressing and coding a telecine-converted video signal to record it on an optical disk, a magnetic disk or the like and for efficiently coding the video signal. .

[0002]

2. Description of the Related Art At present, when a video signal is to be compression-encoded, the compression-encoding is carried out as a preprocessing after removing an element which lowers the encoding efficiency. As a factor that lowers the coding efficiency, noise included in the video signal and a redundant field included in the input video signal when the input video signal is a film video are considered.

First, the redundant fields included in the film image will be described. The film image is originally 24Hz
However, it is recorded as a signal of 30 Hz in the VTR and the video recording device. The image converted to 30 Hz is called a telecine image. One frame of the video signal is composed of 2 fields, from 24Hz to 3
The conversion to 0 Hz is performed by repeatedly displaying an arbitrary field. This conversion is called 3-2 pulldown. Conversely, converting a 30 Hz video signal to 24 Hz is called inverse 3-2 pulldown, and is realized by dropping the field repeatedly displayed by 3-2 pulldown.

Generally, when encoding a film image, a telecine image is given as an input image signal. The telecine video is subjected to inverse 3-2 pulldown before coding to improve coding efficiency.

Next, 3-2 pulldown and inverse 3-2 pulldown will be described with reference to FIGS. Figure 2 is 3-2
It is a conversion diagram of a video signal in pull-down. The video signal A shown in the upper part of FIG. 2 is a 24 Hz film video.
In the video signal B shown in the lower part of FIG. 2, arbitrary fields of the video signal A, for example, field 3 and field 8 are repeatedly displayed. Such an array of video signals is called a telecine video. Here, an example is shown in which four fields (continuous eight fields) of the input video signal are repeated for two fields and converted into five frames, but the cycle of repeated fields is not particularly specified. As shown in FIG. 2, it can be seen that the telecine video includes redundant fields such as field 3 and field 8.

Next, the inverse 3-2 pulldown will be described.
FIG. 3 is a conversion diagram of a video signal in inverse 3-2 pulldown. Inverse 3-2 pull-down is to drop the repeatedly displayed fields, field 3 and field 8, of the video signal B shown in the upper part of FIG. 3 and convert it into the video signal C as shown in the lower part of FIG. . Detecting repeated fields can be calculated by calculation if the fields are cyclically repeated as shown in the example, but in general, the cycle of repeated fields is not specified, so A difference value is taken with a plurality of fields before and after, and it is judged whether or not they are the same field by this difference value. The difference value should be 0 when the compared fields are the same field, but it does not become 0 because the error such as VTR for recording / reproducing this signal is actually involved. Therefore, a threshold value is set, and it is verified whether the fields are the same field based on the magnitude relationship between the threshold value and the difference value.

Next, noise contained in the video signal will be described as one element for reducing the coding efficiency of the video signal. The noise included in the video signal is random noise, and the noise is removed by applying filters in the spatial axis direction and the time axis direction. The video signal must be encoded after removing this noise.

At present, the encoding of the video signal is carried out after removing the above-mentioned element which lowers the encoding efficiency as preprocessing. In this preprocessing, noise contained in the video signal is removed by filtering the video signal in the spatial axis direction and the time axis direction, and then redundant fields are detected, that is, inverse 3-2 pulldown is performed.

[0009]

However, when a telecine image is input, the present preprocessing method uses the inverse 3-
2 Before pull-down, noise is removed by applying filters in the spatial and temporal directions. If this is done, there will be no problem in filtering in the spatial axis direction, but if filtering in the temporal axis direction, the same field repeated by 3-2 pulldown may be judged as a different field. Therefore, reverse 3-2
When pulling down, there is a problem that the same field cannot be detected.

The present invention has been made in view of the above conventional problems, and when compression coding a telecine image, noise filtering in the time axis direction is performed after performing inverse 3-2 pulldown. Accordingly, it is an object of the present invention to eliminate the element that lowers the coding efficiency and realize a video coding apparatus with high coding efficiency.

[0011]

In order to achieve the above-mentioned object, the invention according to claim 1 of the present application is a video coding apparatus for reducing the redundancy of a video signal and performing a compression coding process. A frame frequency conversion means for inputting a video signal composed of frames and converting it into a video signal of a frame with reduced redundancy of video data, and a video signal converted by the frame frequency conversion means are input, and for each frame It is characterized by comprising a noise reducing means for removing noise and an encoding means for inputting a video signal of the noise reducing means and performing compression encoding processing.

According to a second aspect of the present invention, there is provided a video coding apparatus for reducing the redundancy of a video signal and performing compression coding processing, wherein a video signal composed of a plurality of frames is input and the current processing is performed. Of the same field detected by the field detection means for comparing the video data of the target field and the video data of a plurality of fields located before and after the field detection means to detect whether or not they are the same field, , A drop field means for discarding one of them, a noise reduction means for inputting the video signal of the drop field means and removing noise for each frame, and a code for inputting the video signal of the noise reduction means and performing compression encoding processing And a conversion means.

According to a third aspect of the present invention, there is provided a video coding device for reducing the redundancy of a video signal and performing compression coding processing, wherein a video signal composed of a plurality of frames is input and video data of the video data is input. Frame frequency conversion means for converting into a video signal of a frame with reduced redundancy, and noise reduction means for inputting the video signal converted by the frame frequency conversion means and removing noise in the time axis direction for each frame,
Coding means for inputting the video signal of the noise reducing means and performing compression coding processing is provided.

According to a fourth aspect of the present invention, there is provided a video encoding device for reducing the redundancy of a video signal and performing compression encoding processing, wherein a video signal composed of a plurality of frames is input and the present processing is performed. Of the same field detected by the field detection means for comparing the video data of the target field and the video data of a plurality of fields located before and after the field detection means to detect whether or not they are the same field, , A drop field means for discarding one of them, a video signal converted by the frame frequency conversion means are input, and a noise reduction means for removing noise in the time axis direction for each frame, and a video signal of the noise reduction means are input. However, the encoding means for performing the compression encoding processing is provided.

According to this structure, when a video signal composed of a plurality of frames is input, the frame frequency conversion means converts the video data into a frame video signal with reduced redundancy. The noise reduction means inputs the frequency-converted video signal and removes noise for each frame.
The encoding means inputs the video signal of the noise reducing means and performs compression encoding processing. In this way, in the case of a frame including the same video data like a video signal of telecine conversion, the amount of data to be compression-encoded is reduced in advance.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION A video encoding apparatus according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing the overall configuration of a video encoding device according to this embodiment. The video encoding device includes a frame frequency converter 11, a noise filter 12, and an encoder 13.

The frame frequency converter 11 inputs a telecine image over a plurality of frames and converts the frame frequency into a film image frequency. The noise filter 12 inputs the video signal output from the frame frequency converter 11 and removes noise in the time axis direction. The encoder 13 inputs the video signal of the noise filter 12 and performs compression encoding processing.

An example of the structure of the frame frequency converter 11 is shown in FIG. The frame frequency converter 11 includes a field memory 41, a field detector 42, and a drop field device 43. The field memory 41 is a memory that stores video signals of a plurality of fields in field units. The field detector 42 is the field memory 4
The field data held in 1 is compared to detect fields having the same image. The drop field device 43 drops (discards) one of the two fields detected as the same by the field detector 42 and leaves the other fields.

Next, a configuration example of the noise filter 12 is shown in FIG.
Shown in The noise filter 12 filters the input video signal in the time axis direction. The noise filter 12 given as an example here is a 3-tap filter, and has two delay devices 61 and 62 connected in cascade to the input terminals, a multiplier 63 that multiplies the input signal by a constant k1, and an output of the delay device 61. Multiplier 6 that multiplies by a constant k2
4, a multiplier 65 that multiplies the output of the delay device 62 by a constant k3,
It is composed of an adder 66 that adds the outputs of the multipliers 63 and 64, and an adder 67 that adds the outputs of the multiplier 65 and the adder 66.

The encoder 13 shown in FIG.
The video signal from which noise in the time axis direction has been removed by 2 is input, and compression coding processing is performed using, for example, MPEG.

The operation of the video coding apparatus thus configured will be described. FIG. 5 shows the frame frequency converter 11
6 is a conversion diagram of a video signal showing the operation of FIG. It is assumed that the video signal input to the frame frequency converter 11 of FIG. 1 or 4 is a telecine video. This video signal is divided into a top field and a bottom field and input, as shown in FIG. The symbols below each field in this figure indicate the input order of each field, 1t, 1b, 2t, 2b, 3
.. are written in the field memory 41 of FIG. 4 in this order. When the field data stored in the field memory 41 is given to the field detector 42,
It is compared with fields of the same parity that are located before and after the field currently being processed. The comparison here is shown in FIG.
As shown in (b), for example, in the case of the top field 2t, the comparison is made with the signals of the top fields 1t and 3t that are temporally positioned before and after.

As a comparison method, a difference between fields is taken, and if the difference is smaller than a predetermined threshold value, it is judged as the same field and detected. FIG. 5 (c)
Shows the same field with the same concentration. As shown in this figure, the field 2t is 3t and the field 4b is 5b.
Then, it was detected that the field 7t is the same as the field 8t, and the field 9b is the same field as the field 10b. The same field was not detected in other fields.

When the same field is detected by the field detector 42, the drop field device 4 of FIG.
3 drops one of the same fields detected,
Output other. As shown in FIGS. 5C and 5D, fields 3t, 5b, 8t, and 10 detected as the same field are detected.
b is dropped and printed. In this way, the video signal input to the frame frequency converter 11 is converted into a video signal having a frame frequency with less redundancy and then output.

If the frame frequency of the input video signal is 30
In the case of a video signal of Hz, the same field is not repeatedly displayed, so the field detector 42 does not detect the same field. In this case, the input and output of the frame frequency converter 11 are the same signal. It should be noted that the frame frequency converter 11 may be anything as long as it performs inverse 3-2 pulldown.

Next, the video signal subjected to the inverse 3-2 pulldown by the frame frequency converter 11 is applied to the noise filter 12 shown in FIG. The input video signal here is V (t), the multiplication coefficients (filter coefficients) of the multipliers 63, 64 and 65 are k1, k2 and k3, and the delay time of the delay devices 61 and 62 is T (transfer function is D ), The output of the noise filter 12 is V (t) × k1 + V (t−T) × D × k2 + V (t−
2T) × D ² × k3. Therefore, when the pixel value of the input video signal V (t) input at the time t includes a noise component, the input video signals V (t), V (t-T), V (t-2).
The weighted average of the pixel values in T) is output.

The noise filter 12 shown in FIG.
It was a tap filter, but it is not limited to this.
Further, the noise filter 12 may be anything as long as it removes noise in the time axis direction of the input video signal.

The video signal from which the noise component has been reduced in this way becomes an inverse 3-2 pulldown video signal with less redundancy. The amount of frame data included in a unit time is shown in FIG.
24/30 compared to the video signal B shown in FIG. When this video signal is given to the encoder 13 of FIG.
Due to the EG standard compression, the amount of transfer data is significantly reduced and recorded on an optical disk, a magnetic disk, or the like.

[0028]

As described above, according to the present invention, when the telecine image is compression-encoded, the inverse 3-2 pulldown is accurately performed, and the element that lowers the encoding efficiency is removed. Then, efficient encoding processing can be realized. Particularly in the image coding apparatus of the present invention, since the inverse 3-2 pulldown is performed before the noise removal processing in the time axis direction, whether the input video signal is a telecine video or a video signal. , It is possible to remove the elements that reduce the coding efficiency. That is, the encoding process can be performed with high encoding efficiency regardless of the type of the input video signal.

[Brief description of drawings]

FIG. 1 is a block diagram showing an overall configuration of a video encoding device according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing 3-2 pulldown conversion of a video signal.

FIG. 3 is an explanatory diagram showing inverse 3-2 pulldown conversion of a video signal.

FIG. 4 is a block diagram of a frame frequency converter configuring the video encoding device of the present embodiment.

FIG. 5 is a frame signal conversion diagram showing the operation of the frame frequency converter of the present embodiment.

FIG. 6 is a block diagram of a noise filter included in the video encoding device according to the present embodiment.

[Explanation of symbols]

 11 Frame frequency converter 12 Noise filter 13 Encoder 41 Field memory 42 Field detector 43 Drop field device 61, 62 Delay device 63, 64, 65 Multiplier 66, 67 Adder

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Claims (4)

[Claims] 1. A video coding apparatus for reducing the redundancy of a video signal and performing compression coding, comprising: inputting a video signal composed of a plurality of frames; Frame frequency conversion means for converting into a video signal, noise reduction means for inputting the video signal converted by the frame frequency conversion means and removing noise for each frame, and inputting and compressing the video signal of the noise reduction means A video encoding device comprising: an encoding unit that performs an encoding process. 2. A video encoding apparatus for reducing the redundancy of a video signal and performing compression encoding processing, wherein a video signal composed of a plurality of frames is input, and video data of a field to be currently processed. , And the video data of a plurality of fields located before and after that,
Field detection means for detecting whether or not they are the same field, drop field means for discarding one of the same fields detected by the field detection means, and a video signal of the drop field means is input, and for each frame A video encoding device comprising: a noise reducing unit that removes noise; and an encoding unit that inputs the video signal of the noise reducing unit and performs compression encoding processing. 3. A video coding apparatus for reducing the redundancy of a video signal and performing compression coding, wherein a video signal composed of a plurality of frames is input, and the redundancy of the video data is reduced. A frame frequency conversion means for converting into a video signal; a noise reduction means for inputting the video signal converted by the frame frequency conversion means and removing noise in the time axis direction for each frame; and a video signal of the noise reduction means A video encoding device, comprising: an encoding unit that inputs and performs compression encoding processing. 4. A video coding apparatus for reducing the redundancy of a video signal and performing compression coding, wherein a video signal composed of a plurality of frames is input, and video data of a field to be currently processed. , And the video data of a plurality of fields located before and after that,
The field detection means for detecting whether or not they are the same field, the drop field means for discarding one of the same fields detected by the field detection means, and the video signal converted by the frame frequency conversion means are input. A video coding apparatus comprising: a noise reduction unit that removes noise in the time axis direction for each frame; and a coding unit that inputs the video signal of the noise reduction unit and performs compression coding processing. .