JP2003333629A - Method, device, and program for supporting evaluation of video quality - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method, a system, and a program for supporting evaluation of a video quality, which perform subjective evaluation and objective evaluation of a quality of a digital video signal correspondingly to each other to quickly specify a cause of quality abnormality. <P>SOLUTION: A video quality evaluation support device 1 is provided with an encoded video reception means 10, a video decoding means 11, an encoded information extraction means 12, an encoded information conversion means 13, a synthesizing and display means 14, a graph display means 15, an operation input means 16, and a control means 17, and encoded information (parameter) related to a video quality is extracted from an encoded video signal (encoded video), and information related to the video quality is synthesized and displayed with the decoded video or is displayed as a graph on the basis of the parameter. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a quality evaluation technique for evaluating the quality of a coded digital video signal, and more particularly to visualizing coded information included in the coded digital video signal. The present invention relates to a video quality evaluation support device, a video quality evaluation support method, and a video quality evaluation support program that support quality evaluation of a video signal.

[0002]

2. Description of the Related Art Conventionally, in order to evaluate the image quality, a human being subjectively evaluates the image quality of the screen of a television or the like which reproduces and outputs the image signal. On the other hand,
The quality of an image is objectively evaluated based on numerical data obtained by measuring various data such as a signal-to-noise power ratio (SNR) of a video signal and a bit error rate (BER). As described above, conventionally, the quality of a video is evaluated by subjective evaluation and / or objective evaluation.

[0003]

However, in the above-mentioned conventional technique, the objective evaluation is intended for quality evaluation in transmission of a video signal, and image quality deterioration due to quantization when encoding a digital image is caused. It cannot be evaluated. In addition, the only way to evaluate the image quality deterioration due to this quantization is to make a subjective evaluation, and when the problem of image quality deterioration due to the quantization of digital video occurs, it is difficult to identify the cause. There was a problem.

The present invention has been made in view of the above problems, and the quality evaluation of a digital video signal is a subjective evaluation in which a human looks at the video and evaluates it, and a code obtained by encoding the digital video. Video quality evaluation support device, video quality evaluation support method, and video quality evaluation support capable of quickly identifying the cause of the quality abnormality by correlating with the objective evaluation that visualizes and evaluates the information of the encoded video The purpose is to provide the program.

[0005]

The present invention was conceived to achieve the above object. First, the video quality evaluation support apparatus according to claim 1 encodes a video signal by encoding. A video quality evaluation support device for visualizing coded information included in a video signal to support quality evaluation of the video signal when the coded video signal is decoded, and extracts the coded information from the coded video signal. Encoding information extracting means, a video decoding means for decoding the encoded video signal, and a quantization scale indicating a quantization level set for each specific block area of the video signal included in the encoding information, Quantization scale color information conversion means for converting into color information color-coded based on the value of the quantization scale, and the color information for each block area converted by this quantization scale color information conversion means to the video decoding means. Video synthesizing means for synthesizing the image area corresponding to the block area of the decoded video signal I,
It is configured to include.

According to this structure, the video quality evaluation support apparatus causes the coded information extraction means to extract the coded information from the coded video signal and the video decoding means to decode the coded video signal. At this time, based on the coded information (parameter) extracted by the coded information extraction means, the quantization scale color information conversion means sets the quantization scale indicating the quantization level set for each specific block area, Color coding is performed on the basis of the value of the quantization scale, and a video signal is synthesized by a video synthesizing unit and presented, thereby visualizing which region and how much quantization is performed on the video.

Here, the quantization scale (quantization scale value) is a value indicating the coarseness of the quantization when performing the quantization in order to reduce the code amount in the encoding of the video signal. The larger the quantization scale value, the larger the amount of information reduced by the quantization.

The video quality evaluation support apparatus according to a second aspect is the video quality evaluation support apparatus according to the first aspect, in which the quantization setting is performed for each frequency component of the video signal included in the encoded information. The present invention is characterized by including a quantization matrix graphing means for converting a quantization matrix indicating a level into color information which is color-coded based on the value of the quantization matrix and graphing it.

According to such a configuration, the video quality evaluation support apparatus uses the quantization matrix graphing means to generate the quantization matrix indicating the quantization level set for each frequency component of the video signal included in the encoded information. , It is possible to visualize which frequency component and how much quantization is performed by presenting it as a graph by color-coding based on the value of the quantization matrix.

Here, the quantization matrix is a DCT (Discrete Cos) which is a frequency component of a video signal.
ine Transform: Discrete cosine transform) This is an array of coefficients used when quantizing (dividing) coefficients, and represents the degree of quantization for each frequency component in a macroblock. The larger the value of this quantization matrix, the larger the amount of information deleted by the quantization.

Furthermore, the video quality evaluation support apparatus according to the third aspect of the present invention visualizes the coded information included in the coded video signal obtained by coding the video signal, and thereby the video when the coded video signal is decoded. A video quality evaluation support device for supporting signal quality evaluation, comprising: coded information extraction means for extracting coded information from a coded video signal; and coded information extracted by the coded information extraction means. And a motion vector position graphing means for graphing the position of the block area predicted by the motion vector as a relative position of the video signal on each screen.

According to this structure, the video quality evaluation support apparatus extracts the coded information from the coded video signal by the coded information extraction means and predicts it as the motion vector by the motion vector position graphing means. By presenting the position of the block area, which area on the video is searched for as a motion vector is visualized.

This motion vector is used in a coding system such as MPEG2 which is coded by a motion compensation technique.
A region that is recognized as the same region is searched from a temporally previous or subsequent frame in the video, and the searched region is referred to.

The video quality evaluation support apparatus according to a fourth aspect of the present invention visualizes the coded information included in the coded video signal obtained by coding the video signal, and thereby the video when the coded video signal is decoded. A video quality evaluation support device for supporting signal quality evaluation, comprising: coded information extraction means for extracting coded information from a coded video signal; and coded information extracted by the coded information extraction means. A motion vector code amount calculating means for calculating a motion vector code amount of a region predicted by a motion vector for each specific block region in each screen of a video signal, and based on the coding information extracted by the coding information extracting device Then, the orthogonal transformation code amount calculation means for calculating the orthogonal transformation code amount of the area coded by the orthogonal transformation, the motion vector code amount, and the orthogonal transformation code amount are paired. A code amount graphing means for graphed, and configured to include a.

According to this structure, the video quality evaluation support apparatus extracts the coded information from the coded video signal by the coded information extraction means, and the motion vector code amount calculation means in each screen of the video signal. The motion vector code amount of the region predicted by the motion vector for each specific block region is calculated, and the orthogonal transform code amount calculation means calculates the orthogonal transform code amount of the region coded as the orthogonal transform. Then, the code amount graphing means presents the motion vector code amount and the orthogonal transform code amount by comparing them with each other by, for example, a bar graph or the like to present the motion vector code amount and the orthogonal transform code amount in the encoded video information. Visualize the percentage.

Here, the motion vector code amount means the number of bits of a code in which each frame of the video signal is encoded as a motion vector, and the orthogonal transformation code amount is the DCT which is a frequency component of each frame of the video signal. (Discrete Cosine Transform) The number of bits of a code encoded as a coefficient.

Further, in the video quality evaluation support method according to the present invention, the video when the coded video signal is decoded by visualizing the coded information included in the coded video signal obtained by coding the video signal. A video quality evaluation support method for supporting signal quality evaluation, comprising extracting coding information from a coded video signal, and performing a quantization process for each specific block area of the video signal included in the coding information. A quantization scale indicating the level and / or a quantization matrix indicating the quantization level set for each frequency component of the video signal is color-coded based on the value indicating the quantization level, and the encoded video signal is It is characterized in that the decoded video signal is combined and displayed.

According to this method, the video quality evaluation support method extracts the coding information from the coded video signal, and sets the quantization information set for each specific block area included in the coding information. The quantization scale indicating the level is color-coded based on the value of the quantization scale to visualize which region on the image and how much quantization is performed.
Further, the quantization matrix indicating the quantization level set for each frequency component of the video signal included in the encoded information is color-coded based on the value of the quantization matrix,
Visualize by combining with video signal.

The video quality evaluation support method according to claim 6 is a video when the coded video signal is decoded by visualizing the coded information included in the coded video signal obtained by coding the video signal. A video quality evaluation support method for supporting signal quality evaluation, comprising: extracting coded information from a coded video signal, and determining the position of a block area predicted by a motion vector based on the coded information. It is characterized in that it is graphed as a relative position on each screen of.

According to this method, the video quality evaluation support method extracts the coded information from the coded video signal and presents the position of the block area predicted by the motion vector included in the coded information. By doing so, it is possible to visualize which area on the video is searched for as a motion vector.

Further, the video quality evaluation support method according to claim 7 is a video when the coded video signal is decoded by visualizing the coded information included in the coded video signal obtained by coding the video signal. A video quality evaluation supporting method for supporting signal quality evaluation, wherein coding information is extracted from a coded video signal, and a motion vector for each specific block area in each screen of the video signal is based on the coding information. Is calculated by calculating the motion vector code amount of the region predicted by the above and the orthogonal transform code amount of the region coded by the orthogonal transform, and comparing the motion vector code amount with the orthogonal transform code amount and graphing them. And

According to this method, the video quality evaluation support method includes the motion vector code amount of the area predicted by the motion vector from the coded information extracted from the coded video signal and the area coded by the orthogonal transform. The orthogonal transformation code amount is calculated. Then, the motion vector code amount and the orthogonal transform code amount are compared and presented by, for example, a bar graph or the like to visualize the ratio of the motion vector code amount and the orthogonal transform code amount in the encoded video information.

The video quality evaluation support program according to claim 8 visualizes the coded information included in the coded video signal obtained by coding the video signal, thereby the video when the coded video signal is decoded. In order to support the signal quality evaluation, the computer uses a coded information extraction unit that extracts coded information from the coded video signal, a video decoding unit that decodes the coded video signal, and a video signal included in the coded information. Quantization scale color information conversion means for converting a quantization scale indicating a quantization level set for each specific block area into color information color-coded based on the value of the quantization scale, and this quantization scale color information A video in which the color information for each block area converted by the conversion means is combined with a video area corresponding to the block area of the video signal decoded by the video decoding means. It characterized in that to function as a forming means.

According to this structure, the video quality evaluation support program causes the coded information extraction means to extract the coded information from the coded video signal and the video decoding means to decode the coded video signal. At this time, based on the coded information (parameter) extracted by the coded information extraction means, the quantization scale color information conversion means sets the quantization scale indicating the quantization level set for each specific block area, Color coding is performed on the basis of the value of the quantization scale, and a video signal is synthesized by a video synthesizing unit and presented, thereby visualizing which region and how much quantization is performed on the video.

Furthermore, a video quality evaluation support program according to a ninth aspect is the same as the video quality evaluation support program according to the eighth aspect, in which quantization is set for each frequency component of the video signal included in the encoded information. It is characterized in that it functions as a quantization matrix graphing means for converting the quantization matrix indicating the level of 1 into the color information that is color-coded based on the value of the quantization matrix and graphing it.

According to such a configuration, the video quality evaluation support program causes the quantization matrix graphing means to
By presenting a quantization matrix that indicates the level of quantization set for each frequency component of the video signal included in the encoded information by color coding based on the value of the quantization matrix, which frequency component is displayed. Visualize how much quantization is done.

Further, the video quality evaluation support program according to the tenth aspect of the present invention visualizes the coded information included in the coded video signal obtained by coding the video signal, thereby decoding the coded video signal. In order to support the quality evaluation of the video signal, the computer uses a coded information extraction means for extracting coded information from the coded video signal, and a motion vector based on the coded information extracted by the coded information extraction means. The position of the block area predicted by
It is characterized by functioning as motion vector position graphing means for graphing the relative position of the video signal on each screen.

According to this structure, the video quality evaluation support program extracts the coded information from the coded video signal by the coded information extraction means, and predicts it as a motion vector by the motion vector position graphing means. By presenting the position of the block area, which area on the video is searched for as a motion vector is visualized.

The video quality evaluation support program according to claim 11 visualizes the coded information included in the coded video signal obtained by coding the video signal, thereby decoding the coded video signal. In order to support the signal quality evaluation, the computer uses a coded information extraction means for extracting coded information from the coded video signal, and based on the coded information extracted by the coded information extraction means, On the basis of the coded information extracted by the motion vector code amount calculating means for calculating the motion vector code amount of the area predicted by the motion vector for each specific block area on each screen, and the orthogonal transformation, Orthogonal transform code amount calculating means for calculating the orthogonal transform code amount of the encoded area, comparing the motion vector code amount with the orthogonal transform code amount. Code amount graphing means for graphing,
It is characterized by making it function as.

According to this structure, the video quality evaluation support program extracts the coded information from the coded video signal by the coded information extraction means, and the motion vector code amount calculation means in each screen of the video signal. The motion vector code amount of the region predicted by the motion vector for each specific block region is calculated, and the orthogonal transform code amount calculation means calculates the orthogonal transform code amount of the region coded as the orthogonal transform. Then, the code amount graphing means presents the motion vector code amount and the orthogonal transform code amount by comparing them with each other by, for example, a bar graph or the like to present the motion vector code amount and the orthogonal transform code amount in the encoded video information. Visualize the percentage.

[0031]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. (Structure of Video Quality Evaluation Supporting Device) FIG. 1 is a block diagram showing the structure of a video quality evaluation supporting device according to the present invention. As shown in FIG. 1, the video quality evaluation support apparatus 1 extracts coding information (parameters) related to video quality from a coded video signal (coded video), and encodes the coding information related to video quality. Is displayed on the decoded video, or is displayed in the form of a graph to identify the factor of the quality deterioration of the video. Note that, here, as the signal input to the video quality evaluation support apparatus 1, a digital video signal is an MPEG2 (Moving Picture E).
The transport stream (TS: Transport Stream) is compressed and encoded by the xperts Group 2) to be stream data.

The video quality evaluation support device 1 includes a coded video receiving means 10, a video decoding means 11, a coded information extraction means 12, a coded information conversion means 13, a composite display means 14, and a graph display. Means 15 and operation input means 16
And a control means 17.

The coded video receiving means 10 receives the coded video signal (transport stream) and outputs it to the video decoding means 11 and the coded information extraction means 12. The coded video receiving means 10 receives a coded video signal (transport stream) broadcast by digital broadcasting, and also records a program stream (PS: Program) recorded on a digital recording medium such as a DVD.
Alternatively, it may be a form of inputting "am Stream".

The video decoding means 11 decodes the coded video signal input from the coded video receiving means 10 and outputs it as a video signal. The video signal decoded here is output to the synthesis display unit 14.

The coded information extraction means 12 extracts coded information (parameters) from the coded video signal input from the coded video receiving means 10. In addition, here
In addition to parameters related to video quality, various parameters will be extracted for the purpose of analyzing video.

Here, the parameters extracted by the encoded information extracting means 12 will be described with reference to FIGS. 8 to 12. 8 to 12 show the contents of each layer of the layered structure showing the structure of the MPEG2 data. MPEG2 includes a sequence layer, a GOP layer, a picture layer, a slice layer, a macroblock layer, and a block layer. FIG. 8 is a sequence layer, FIG. 9 is a GOP layer, FIG. 10 is a picture layer, FIG. 11 is a slice layer, and FIG. 12 is an abbreviation for the macroblock layer,
It shows the content, bit length, execution classification (extraction execution) regarding whether to perform extraction, and parameter display method (remarks). It should be noted that the block layer does not extract parameters, and therefore is not shown.

For example, FIG. 8 shows that the coding information extracting means 12 extracts the number of horizontal pixels (HSV) from the sequence layer and displays it on the video screen in a superimposed manner. Further, for example, from the macroblock layer of FIG. 12, the quantization scale value (QSC: Quantizer) is
Scale Code) is extracted and displayed by color on the video screen. 8 to 1
Since 2 indicates a general parameter of MPEG2, detailed description will be omitted. Also, the encoded information extraction means 1
The individual parameters extracted by 2 will be sequentially described later. Returning to FIG. 1, the description will be continued.

The coded information conversion means 13 comprises a text conversion part 13a and a color information conversion part (quantization scale color information conversion means, quantization matrix color information conversion means) 13b, which is extracted by the coded information extraction means 12. The encoded information (parameter) thus converted is converted into text information and color information.

The text conversion unit 13a converts the numerical data that can be displayed as a character string into the character code that is the text information among the parameters extracted by the encoded information extraction means 12. The text information converted here is output to the synthesis display unit 14. For example, numerical data such as the number of horizontal pixels (HSV) (see FIG. 8) is converted into a character code. The display position information for displaying this text information is set in advance according to the type of parameter,
It is assumed that the text information includes the display position information. Alternatively, the display position information may be input from the operation input means 16.

The color information conversion unit 13b converts a value having a level among the parameters extracted by the encoding information extraction means 12 into color information in which the level is color-coded stepwise. For example, quantization scale value (QSC)
According to the value of (see FIG. 12), color coding is performed based on the maximum value and the minimum value that the value can take, and the quantization scale value is converted into color information. This quantizer scale value (QSC)
Are continuously output from the color information conversion unit 13b in units of macroblocks forming a video frame. The details of this color information will be described later.

The synthesis display means 14 is a text synthesis section 14
a and a video synthesizing unit (video synthesizing means) 14b, and outputs a synthetic video in which the video information decoded by the video decoding means 11 is combined with the text information and color information converted by the encoding information converting means 13. It is a thing.

The text synthesizing unit 14a synthesizes a text (character) on the video signal decoded by the video decoding unit 11 based on the text information converted by the text converting unit 13a of the coded information converting unit 13 (super-in). The paused composite video signal (composite video) is generated. As a result, various information of the video can be confirmed as text on the screen during video reproduction.

The video synthesizing unit 14b synthesizes color information with the video signal decoded by the video decoding unit 11 based on the color information converted by the color information converting unit 13b of the coding information converting unit 13. (Synthesized image) is generated. The composite video generated here is displayed as a video screen on a display device (not shown).

For example, when a quantized scale value (QSC) (see FIG. 12) is combined as color information into a video signal, the video signal is converted into a black and white video signal having only luminance information, and the color information is added to the black and white video signal. To synthesize. This makes it possible to confirm in which part of the image the amount of data has been reduced due to the quantization, while checking the outline of the image content.

Although the composite display means 14 outputs only the composite video here, the video signal (original video) decoded by the video decoding means 11 and the composite video are switched and output, or The screen may be divided to display the original video and the composite video at the same time.

Here, referring to FIG. 2, the composite display means 1
The composite image generated by No. 4 will be described. Figure 2
2A shows the content of the original video decoded by the video decoding means 11, and FIG. 2B shows the content of the composite video output from the composite display means 14.

In MPEG2, there are two modes (non-linear step and linear step) in which the maximum value of the quantization scale value differs for each picture. These two modes are
Quantization (Q) scale type (QST) (see FIG. 10)
Specified by. Therefore, as shown in 2a of FIG. 2B, the color information of the quantization scale value in the nonlinear step is
When the maximum quantization scale value is "112", it is red (Re
d), the case of "56" is green (Green), the minimum is "1"
In the case of, the color classification is performed stepwise such as blue. Further, as shown in 2b, the color information of the quantization scale value in the linear step is red (Red) when the quantization scale value is maximum "64", green (Green) when the quantization scale value is "32", and minimum "1". In the case of “”, the color classification is performed stepwise such as blue.

Further, the composite image of FIG. 2B is shown in FIG.
Since only the color information of the video content of (a) is converted, the video content can be confirmed. In this way, by displaying the information of the quantization scale value by color coding on the screen, it is possible to confirm in which part of the screen the quantization is mostly performed. Returning to FIG. 1, the description will be continued.

The graph display means 15 is a quantization matrix graphing section (quantization matrix graphing means) 15a.
A motion vector position graphing unit (motion vector position graphing means) 15b, a code amount calculating unit (motion vector code amount calculating means, orthogonal transform code amount calculating means) 15c, a code amount graphing unit (code amount graphing). Means) 15d,
Based on the coded information (parameters) extracted by the coded information extraction means 12, various parameters are graphed to generate and output a graph image.

The quantization matrix graphing unit 15a, in the coded information (parameters) extracted by the coded information extraction means 12, is a quantization indicating the level of quantization set for each frequency component of the video signal. The matrix is converted into color information in which the levels are color-coded stepwise, and is graphed.

This quantization matrix is used for intra MB (macroblock) quantization matrix data (IQM), non-intra MB quantization matrix data (NIQM), and color difference intra MB shown in the picture layer parameters of FIG. Quantization matrix data (CIQM), quantization matrix data for color difference non-intra MB (CNIQ)
It is the numerical value of M).

FIG. 4 shows an example of converting a quantization matrix into color information. As shown in FIG. 4, the quantization matrix graphing unit 15a sets the value of the quantization matrix to the minimum value "1".
To the maximum value "255" are converted into colors corresponding to the values of each quantization matrix based on the color definition table 4e in which colors are defined stepwise, and the values of the quantization matrix are graphed. FIG. 4 shows quantization matrix data (IQM) 4a for luminance intra MB, quantization matrix data (NIQM) 4b for luminance non-intra MB, quantization matrix data (CIQM) 4c for color difference intra MB, and color difference non-intra MB. Quantization matrix data (CNIQM) 4d
It shows an example in which is displayed in color.

For example, in the intra-MB quantization matrix data (IQM) 4a, the region where the horizontal frequency component u and the vertical frequency component v are high is red (Red), and the quantization reduces the amount of information. It means that

The motion vector position graphing unit 15b graphs the motion vector search range and the position of the macroblock coded by the motion vector in the coded information (parameters) extracted by the coded information extraction means 12. It will be transformed. In motion-compensated interframe predictive coding such as MPEG2, if the motion vector search range is excessively widened, the amount of calculation for searching the motion vector position becomes enormous, and in general, the motion vector search range is limited and motion is limited. The efficiency of the vector position search process is improved.

This motion vector position graphing unit 15b
Is the forward horizontal motion vector search range (F
HFC), forward vertical motion vector search range (FVF)
C), backward horizontal motion vector search range (BHFC),
The magnitude is represented by the numerical value of the backward vertical motion vector search range (BVFC). Further, whether or not the macroblock is coded by the motion vector is determined by the presence or absence of the bit (bit between MHC and DV) indicating the motion vector of the macroblock layer in FIG.

FIG. 5 shows an example of displaying the motion vector position. FIG. 5A shows a motion vector search range 5 on a picture.
The example which displayed a is shown. The motion vector search range 5a is the motion vector search range (FHF).
C, FVFC, BHFC, BVFC) can be displayed for each picture, forward direction or backward direction.

Further, FIG. 5B shows an example in which the macroblock position 5b encoded by the motion vector is plotted on the motion vector search range 5a. This makes it possible to visualize in which part of the screen the motion vector is searched, and it is possible to evaluate the motion search in encoding from the relationship between the motion of the video and the motion vector. .

The code amount calculation unit 15c, among the coded information (parameters) extracted by the coded information extraction means 12,
It calculates a motion vector code amount of a region predicted by a motion vector for each specific block region on each screen, and an orthogonal transform code amount of a region coded by orthogonal transform.

In the code amount calculation unit 15c, the
The motion vector code amount is calculated by adding the number of bits of n Vectors (the number of bits of MHC to DV indicating the motion vector of the macroblock layer of FIG. 12). Also,
The coded block P is the orthogonal transform code amount.
The number of bits of the attern (the pattern number (CB indicating the pattern of the coding block of the macroblock layer of FIG. 12
P420, CBP1, CBP2) and the number of bits of the block layer (not shown)) are added. Note that only the number of bits in the block layer may be used as the orthogonal transform code amount.

The code amount graphing unit 15d compares the motion vector code amount calculated by the code amount calculating unit 15c and the orthogonal transformation code amount as consumption bits occupied in the coded video signal and graphs them. . In MPEG2, the amount of information so that the accuracy of motion-compensated prediction and the DCT coefficient obtained by discrete cosine transform of the prediction error caused by motion prediction are included in the band (line capacity) as factors that affect the image quality of encoded video. Fluctuates depending on the degree of quantization. Therefore, in the code amount graphing unit 15d, the prediction accuracy of the motion compensation prediction is set to the motion vector code amount (MV),
Degree of quantization of DCT coefficient is orthogonal transform code amount (DCT)
To visualize as.

Here, the graph image generated by the code amount graphing section 15d will be described with reference to FIG. FIG. 6 shows an example of a graph image in which the consumed bits that the motion vector code amount and the orthogonal transformation code amount occupy in the encoded video signal are graphed. FIG. 6A shows a motion vector amount (MV) and an orthogonal transform code amount (D) in the encoded video signal.
CT), header information (Headed) in the encoded video signal
r: all the parameters of the picture layer of FIG. 10 and the slice layer of FIG. 11 and the quantization scale value (QSC) of the macroblock layer of FIG. 12 are represented by a bar graph. It should be noted that here, at the same time, the transmission rate of the encoded video signal (Bi
(rate) is also shown as a line graph.

In this way, the cause of the image quality deterioration can be specified by graphing the consumed bits that the motion vector code amount and the orthogonal transformation code amount occupy in the encoded video signal. For example, although the image quality is deteriorated and the image at that time is uniform on the entire screen and motion estimation is easy,
When the ratio of the orthogonal transform code amount is large, it can be said that there is not enough bandwidth to encode the video with sufficient quality because the prediction error is large. Further, for example, when the image quality is deteriorated in an image with a large amount of motion vector coding in an image with a large amount of motion, it is assumed that there is a large motion error and there is no band for quantizing the DCT coefficient.

Further, FIG. 6B shows an example in which the bit amount of each picture (I picture, P picture, B picture) is bar-graphed. This is the code amount calculation unit 15c
In FIG. 1, the picture type (PC
This can be realized by determining the picture in T), calculating the bit amount for each picture, and graphing the bit amount in the code amount graphing unit 15d (FIG. 1).

Further, in FIG. 6C, an example in which the average quantization scale value (Aveg.Q) of each frame and the image quality evaluation value (Quality) which is a numerical representation of the image quality evaluation are displayed in a time-series line graph form Shows. Here, the image quality evaluation value is obtained by the equation (1).

Image quality evaluation value = −3.65 + 0.21 (Q−
ave) +83.79 (STD-ave) +9.18 (STD-max) ......... (1)

Here, Q-ave represents the in-frame average value of the quantization scale value, STD-ave represents the average value of the in-frame deviation of the quantization scale value for 15 frames, and STD-max is. , The maximum value of the deviation of the quantization scale value within a frame for 15 frames is shown.
Expression (1) is an example of digitizing the image quality evaluation, and is not limited to this. Thus, by extracting and visualizing the parameters in the encoded video, it is possible to quickly identify the cause of the quality abnormality. Returning to FIG. 1, the description will be continued.

The operation input means 16 is for inputting operation contents from an external operation panel (not shown) or the like. For example, the contents of the composite image output from the composite display unit 14 and the graph image output from the graph display unit 15 are switched for each parameter, and the picture to be displayed is switched.

The control means 17 includes the image quality evaluation support device 1
It controls the whole and is composed of a CPU and its peripheral circuits. The control means 17 generates a menu screen for operating the video quality evaluation support apparatus 1, displays the menu screen as a composite image via the composite display means 14, or displays a graph via the graph display means 15. The screen such as graph switching is displayed as an image.

The configuration of the video quality evaluation support apparatus 1 has been described above based on the embodiment, but the present invention is not limited to this. For example, the graph display means 15 may be deleted from the video quality evaluation support device 1 and only the composite video may be output. Furthermore, with the graph display means 15 deleted, the encoded information extraction means 12
It is also possible to adopt a form in which the parameter extracted in step 1 is output to the outside, and a graph image is generated by making a graph based on the parameter by an external personal computer (PC) or the like. In addition, the video quality evaluation support device 1
It is also possible to realize each means in the computer as each functional program, and it is also possible to combine each functional program and operate as a video quality evaluation support program.

(Operation of Video Quality Evaluation Supporting Device) Next, the operation of the video quality evaluation supporting device 1 will be described. [Example of Synthetic Video Output] First, an operation example of outputting a synthetic video will be described with reference to FIGS. 1 and 2. In the video quality evaluation support device 1, the coded video receiving means 10 receives the coded video signal (TS: transport stream), and the video decoding means 11 decodes the coded video signal. On the other hand, the coded video signal received by the coded video receiving means 10 is
Encoding information (parameter) is extracted.

Numerical data that can be displayed as a character string by the parameters extracted by the encoding information extracting means 12 are
It is converted into a character code by the text conversion unit 13a,
The text synthesizing unit 14a synthesizes the video decoded by the video decoding means 11. Further, the quantization scale value (QSC) extracted by the encoding information extraction means 12 is converted into color information based on the quantization level by the color information conversion unit 13b. Then, the video synthesizing unit 14b converts the video decoded by the video decoding means 11 into a monochrome video signal having only luminance information, and synthesizes the monochrome video signal with color information of the quantization scale value.

The synthesized image synthesized here is shown in FIG.
As shown in, while confirming the outline of the contents of the image, it is possible to confirm in which part of the image much data is reduced by the quantization. Although FIG. 2 (b) does not show an example in which character codes are combined, it can be displayed using a general superimposing technique.

[Graph image output example] Next, FIG. 1 and FIG.
An operation example of outputting a graph image will be described with reference to FIG. FIG. 3 shows an example of a graph image screen 3 displaying a graph image. In the video quality evaluation support device 1, the coded video receiving means 10 receives the coded video signal (TS: transport stream), and the coding information extracting means 12 extracts the coding information (parameter).

In the video quality evaluation support apparatus 1, the quantization matrix graphing unit 15a causes the quantization matrix values of the parameters extracted by the encoding information extracting means 12 to be the minimum value "1" to the maximum value "255". The colors are added in stages until the graph is formed as the quantization matrix information 30. In the quantization matrix information 30, an example is shown in which the luminance quantization matrix for each picture is graphed, but it may be switched to the color difference quantization matrix based on the switching signal input from the operation input unit 16. .

Further, in the video quality evaluation support apparatus 1, the motion vector position graphing unit 15b graphs the motion vector search range of the parameter extracted by the coding information extraction means 12 as the motion vector information 31. The motion vector information 31 shows an example in which only the motion vector search range is displayed, but the macroblock position encoded by the motion vector may be plotted and displayed in the motion vector search range.

Further, in the video quality evaluation support apparatus 1, the code amount calculation unit 15c encodes the motion vector code amount of the region predicted by the motion vector from the parameters extracted by the encoding information extraction unit 12 and the orthogonal transformation. The orthogonal transform code amount of the converted region is calculated, and the code amount graphing unit 15d graphs the motion vector code amount (MV) and the orthogonal transform code amount (DCT) as consumed bit information 32. The consumed bit information 32 may be in a form of switching and displaying the screens (a) to (c) described in FIG. 6.

The graph image screen 3 shows an example in which various kinds of information are displayed as the header information 33 from the parameters extracted by the encoding information extracting means 12.
For example, sequence information (Sequence Layer)
In r) 33a, the information on the parameters of the sequence layer in FIG. 8 is displayed as text information. Further, in the GOP information (GOP Layer) 33b, the information on the parameters of the GOP layer in FIG. 9 is displayed by an ON / OFF flag. In addition, picture information (PictureLayer)
r) 33c displays the information of the parameter of the picture layer of FIG. 10 as text information. As described above, the content of the header information that cannot be displayed as a graph is displayed on the graph image screen 3 as text information or ON / OFF flag information.

On the graph image screen 3, the coded video signal input to the coded video receiving means 10 is disconnected (line disconnection), as indicated by the error information 34.
It is also possible to display physical error information such as input packets not being continuous. this is,
This can be realized by monitoring the coded video signal input by the coded video receiving means 10. Here, for example, when a failure occurs in the input of the encoded video signal, FIG.
The message screen of (a) is displayed on the graph image screen 3. Then, when the failure is recovered, the confirmation screen of FIG. 7B is further displayed, and the supervisor confirms. With the above operation, the video quality evaluation support device 1 can support the video quality evaluation while checking the video in real time.

[0079]

As described above, the video quality evaluation support apparatus, the video quality evaluation support method and the video quality evaluation support program according to the present invention have the following excellent effects.

According to the invention of claim 1, claim 5 or claim 8, when a coded video signal obtained by coding a video signal is reproduced, it is set for each specific block area of the video signal. The quantization scale that shows the level of quantization can be displayed in different colors, so when the image quality is degraded, you can visually check where on the screen you are performing a lot of quantization to cause the image quality degradation. Can be confirmed. This makes it possible to assist in identifying the factor of image quality deterioration.

According to the invention described in claim 2, claim 5 or claim 9, when a coded video signal obtained by coding a video signal is reproduced, quantization indicating a quantization level for each frequency component is performed. Since the matrix can be displayed in different colors, it is possible to visually confirm which frequency component is particularly deteriorated when the image quality is deteriorated. This makes it possible to assist in identifying the factor of image quality deterioration.

According to the invention described in claim 3, claim 6 or claim 10, when the coded video signal obtained by coding the video signal is reproduced, the motion vector searched for each macroblock in the screen. However, it is possible to visually check how much the image matches the actual movement of the image. With this, when the block-shaped deterioration occurs in the image, the relationship between the deterioration and the motion vector detection range can be visualized to assist in identifying the factor of the image quality deterioration. Furthermore, in a coding method that performs coding by motion compensation prediction such as MPEG2, it is possible to determine the quality of a motion search algorithm that occupies most of the calculation amount.

According to the fourth, seventh or eleventh aspect of the invention, in the coded video signal obtained by coding the video signal, the motion vector code amount of the region predicted by the motion vector and the orthogonal transformation It becomes possible to visualize and present the ratio of consumed bits to the orthogonal transform code amount of the encoded area. This makes it possible to assist in identifying the factor of image quality deterioration from the actual motion of the video and the ratio of the consumed bits.

[Brief description of drawings]

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

FIG. 2 is an example of a screen showing a composite image in which the levels of the quantization scale according to the embodiment of the present invention are displayed in different colors.

FIG. 3 is an example of a screen showing a graph image according to the embodiment of the present invention.

FIG. 4 is a matrix diagram showing an example of converting a quantization matrix into color information according to the embodiment of the present invention.

FIG. 5 is an explanatory diagram for explaining an example of displaying a motion vector search range and a motion vector position according to the embodiment of the present invention.

FIG. 6 is a graph showing a ratio of consumed bits according to the embodiment of the present invention.

FIG. 7 is an example of a screen displaying a message of the video quality evaluation support device according to the exemplary embodiment of the present invention.

FIG. 8 is a parameter diagram for explaining parameters of a sequence layer.

FIG. 9 is a parameter diagram for explaining parameters of a GOP layer.

FIG. 10 is a parameter diagram for explaining parameters of a picture layer.

FIG. 11 is a parameter diagram for explaining parameters of a slice layer.

FIG. 12 is a parameter diagram for explaining parameters of a macroblock layer.

[Explanation of symbols]

1 ... Video quality evaluation support device 10 ... Coded video receiving means 11 ... Video decoding means 12 ... Coded information extraction means 13 ... Coded information conversion means 13a ... Text conversion part 13b ... Color information conversion Section (quantization scale color information conversion means, quantization matrix color information conversion means) 14 ... Compositing display means 14a ... Text composition section 14b ... Video composition section (video composition means) 15 ... Graph display means 15a. Quantization matrix graphing unit (quantization matrix graphing unit) 15b ... Motion vector position graphing unit (motion vector position graphing unit) 15c ... Code amount calculation unit (motion vector code amount calculation unit, orthogonal transformation code amount) Calculation means) 15d ... Code amount graphing unit (code amount graphing means) 16 ... Operation input means 17 ... Control means 18 ... Bus

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Masaaki Kurosumi             1-10-11 Kinuta, Setagaya-ku, Tokyo, Japan             Broadcasting Association Broadcast Technology Institute (72) Inventor Tomohiko Sugimoto             1-10-11 Kinuta, Setagaya-ku, Tokyo, Japan             Broadcasting Association Broadcast Technology Institute (72) Inventor Eisuke Nakasu             1-10-11 Kinuta, Setagaya-ku, Tokyo, Japan             Broadcasting Association Broadcast Technology Institute (72) Inventor Takahiro Hamada             2-12-23, Nakameguro, Meguro-ku, Tokyo Stocks             Company C Didy Media Will F term (reference) 5B057 BA29 CE08 CE16 CG01 CH01                       CH11                 5C059 KK47 MA00 MA01 MA23 MC14                       NN03 PP04 SS02 SS13 UA02                       UA05                 5C061 BB07 BB09                 5J064 BA16 BB03 BC16

Claims (11)

[Claims] 1. A video quality evaluation support device for supporting the quality evaluation of a video signal when the coded video signal is decoded by visualizing the coding information included in the coded video signal, which is obtained by coding the video signal. Which is a coding information extracting unit that extracts the coding information from the coding video signal, a video decoding unit that decodes the coding video signal, and a specific one of the video signals included in the coding information. Quantization scale color information conversion means for converting a quantization scale indicating a quantization level set for each block area into color information color-coded based on the value of the quantization scale, and this quantization scale color information conversion Video composition for synthesizing the color information for each block area converted by the means into a video area corresponding to the block area of the video signal decoded by the video decoding means. Video quality evaluation support apparatus characterized in that it comprises a stage, a. 2. A quantization matrix indicating a quantization level set for each frequency component of the video signal included in the coded information is converted into color information which is color-coded based on the value of the quantization matrix. The image quality evaluation support apparatus according to claim 1, further comprising: a quantization matrix graphing unit that graphs the image quality. 3. A video quality evaluation support device for supporting the quality evaluation of a video signal when the coded video signal is decoded by visualizing the coding information included in the coded video signal, which is obtained by coding the video signal. Which is a block area predicted by a motion vector based on the coding information extracted by the coding information extracting means for extracting the coding information from the coded video signal. And a motion vector position graphing unit that graphs the position as a relative position on each screen of the video signal. 4. A video quality evaluation support device for supporting the quality evaluation of a video signal when the coded video signal is decoded by visualizing the coded information included in the coded video signal obtained by coding the video signal. Which is based on the coded information extracted by the coded information extracting means for extracting the coded information from the coded video signal, and the coded information extracted by the coded information extracting means. Motion vector code amount calculation means for calculating the motion vector code amount of the area predicted by the motion vector for each block area, and coded by orthogonal transformation based on the coding information extracted by the coding information extraction means. Orthogonal transformation code amount calculating means for calculating the orthogonal transformation code amount of the converted region, the motion vector code amount, and the orthogonal transformation code amount are compared. Video quality evaluation support apparatus characterized by comprising a code amount graphing means for rough of a. 5. A video quality evaluation support method for supporting the quality evaluation of a video signal when the coded video signal is decoded by visualizing the coding information included in the coded video signal, which is obtained by coding the video signal. Wherein the encoding information is extracted from the encoded video signal, and a quantization scale indicating a level of quantization set for each specific block area of the video signal included in the encoding information, and / Alternatively, the quantization matrix indicating the quantization level set for each frequency component of the video signal is color-coded based on the value indicating the quantization level, and the encoded video signal is synthesized with the decoded video signal. A video quality evaluation support method characterized by displaying the same. 6. A video quality evaluation support method for supporting the quality evaluation of a video signal when the coded video signal is decoded by visualizing the coding information included in the coded video signal, which is obtained by coding the video signal. That is, the coded information is extracted from the coded video signal, and the position of the block area predicted by the motion vector based on the coded information is plotted as a relative position in each screen of the video signal. A video quality evaluation support method characterized by: 7. A video quality evaluation support method for supporting the quality evaluation of a video signal when the coded video signal is decoded by visualizing the coded information included in the coded video signal obtained by coding the video signal. That is, the encoded information is extracted from the encoded video signal, and based on the encoded information, a motion vector of a region predicted by a motion vector for each specific block region in each screen of the video signal. A video quality evaluation, characterized in that a code amount and an orthogonal transform code amount of a region coded by orthogonal transform are calculated, and the motion vector code amount and the orthogonal transform code amount are compared and graphed. How to help. 8. A computer is provided for supporting the quality evaluation of the video signal when the coded video signal is decoded by visualizing the coded information included in the coded video signal, which is obtained by coding the video signal. A coded information extraction unit that extracts the coded information from the coded video signal, a video decoding unit that decodes the coded video signal, and set for each specific block area of the video signal included in the coded information Quantization scale indicating the level of quantization, quantization scale color information conversion means for converting into color information color-coded based on the value of the quantization scale, the quantization scale color information conversion means Video combining means for combining color information for each block area with a video area corresponding to the block area of the video signal decoded by the video decoding means, Image quality evaluation support program, characterized in that to function. 9. A quantization matrix indicating a quantization level set for each frequency component of the video signal included in the coded information is converted into color information that is color-coded based on the value of the quantization matrix. 9. The image quality evaluation support program according to claim 8, which is caused to function as a quantization matrix graphing means for graphing. 10. A computer is provided for supporting the quality evaluation of the video signal when the coded video signal is decoded by visualizing the coded information included in the coded video signal, which is obtained by coding the video signal. An encoding information extracting unit that extracts the encoding information from the encoded video signal; a position of a block region predicted by a motion vector based on the encoding information extracted by the encoding information extracting unit; A video quality evaluation support program that functions as a motion vector position graphing unit that graphs the relative position of the video signal on each screen. 11. A computer is provided for supporting the quality evaluation of a video signal when the coded video signal is decoded by visualizing the coded information included in the coded video signal, which is obtained by coding the video signal. An encoding information extracting means for extracting the encoding information from the encoded video signal, based on the encoding information extracted by the encoding information extracting means, for each specific block area in each screen of the video signal Motion vector code amount calculation means for calculating the motion vector code amount of the region predicted by the motion vector of the region, of the region coded by orthogonal transformation based on the coding information extracted by the coding information extraction means. Orthogonal transform code amount calculating means for calculating the orthogonal transform code amount, and graphing by comparing the motion vector code amount and the orthogonal transform code amount. Video quality evaluation support program for causing a code amount graphed means functions as a.