KR100727909B1 - A decoding method for reducing delay time - Google Patents

Abstract

The present invention relates to a decoding method, and more particularly, to a decoding method of reducing a delay time for continuously operating a decoder by adjusting a margin width of a decoding buffer according to characteristics of an input image. A decoding method having a reduced delay time is a video signal decoding method, comprising: (a) sequentially storing a video signal in a buffer in which a margin width is set; (b) decoding the video signals stored in the buffer and searching for header information among the decoded video signals; And (c) detecting the type of the video signal from the header information and changing the margin width of the buffer according to the type of the video signal. According to the present invention, the decoder can operate the decoder continuously by adjusting the margin width of the decoding input buffer according to the characteristics of the input image, thereby reducing the delay time, thereby eliminating the inconvenience that the user feels when viewing the image signal. have.

Description

A decoding method for reducing delay time

1 is a diagram illustrating a general decoding input buffer structure.

2 is a diagram illustrating a margin width of a decoding input buffer having a conventional fixed size.

3 is a block diagram showing the configuration of a decoding apparatus with reduced delay time.

4 is a flowchart illustrating an operation of a decoding method with reduced delay time according to the present invention.

5 is a diagram illustrating a margin width of a decoding input buffer adjusted according to an input image.

The present invention relates to a decoding method, and more particularly, to a decoding method of reducing a delay time for continuously operating a decoder by adjusting a margin width of a decoding buffer according to characteristics of an input image.

1 is a diagram showing the structure of a general decoding buffer.

2 is a diagram showing a margin width of a decoding buffer having a conventional fixed size.

In FIG. 1, the concept of input (In) and output (Out) of the decoding input buffer refers to valid data input / output based on the buffer. Since no data is recorded when the decoding input buffer is initially allocated as shown in Fig. 1A, the buffer becomes the input position In = 0 of valid data, and data is read from this buffer once. Since it did not go, the output position of valid data Out = 0. (b) shows that valid data is input to the decoding input buffer. The size of this buffer is larger than the data input position In and the output position Out = 0. (c) is the case where the input and output of the valid data occur simultaneously. The input position In of the valid data is larger than the output position Out and smaller than the buffer size. (d) indicates that valid data is inputted to the end of the buffer. The input position In of the valid data is equal to the buffer size and is larger than the output position Out. (e) is a case where the input valid data is circulated. The output position Out is larger than the input position In and smaller than the buffer size. (f) indicates that the valid data to be output indicates the end of the buffer. The output position Out is equal to the buffer size and larger than the input position In. (g) indicates that the valid data to be output is circulated. The input position In is larger than the output position Out and smaller than the buffer size.

I / O management of the decoding input buffer occurs in the following order. First, the real data may be input or output only if sufficient space / data exists before the input / output occurs from the decoding input buffer and the content is satisfied. Second, with read / write operations occurring on the actual decoding input buffer, it is important to treat the decoding input buffer as a circular queue to efficiently use the assigned decoding input buffer size. Here, the input position and output position values return to zero if they become larger than the buffer size during the operation. After pointer update, update the part indicating the valid data size.

In the above term, valid data means data that is not output once (ie, waiting to be output in the future) after being input once. The free space refers to an area in which data has never been input or has been output once since input (that is, it can be input again because it has already been output).

The free width (free space) of the decoding input buffer may be set sufficiently so that the decoder does not stop running due to lack of data, but this causes a problem of causing delay in decoding. Therefore, the more you set the buffer width, the greater the delay. If the delay time of the image data is long, the user may feel uncomfortable when viewing the screen. In the related art, as shown in FIG. 2, the margin width is fixed so that a fixed delay is generated regardless of the type of the image data. .

 The technical problem to be achieved by the present invention is to provide a decoding method of reducing the delay time to continuously operate the decoder by adjusting the margin width of the decoding input buffer according to the characteristics of the input image.

A decoding method for reducing a delay time for solving the technical problem to be achieved by the present invention is a video signal decoding method comprising: (a) sequentially storing a video signal in a buffer having a predetermined width; (b) decoding the video signals stored in the buffer and searching for header information among the decoded video signals; And (c) detecting the type of the video signal from the header information and changing the margin width of the buffer according to the type of the video signal.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

3 is a block diagram showing the configuration of a decoding apparatus with reduced delay time.

The apparatus shown in FIG. 3 includes a decoding input buffer 30 for storing an encoded bit stream, a decoder 31 for decoding a bit stream from the decoding input buffer 30, and a header of the bit stream decoded in the decoder 31. Control means 32 for outputting a switching control signal for changing the margin width of the decoding input buffer 30 in accordance with the information, switching the margin width of the decoding input buffer 30 in accordance with the switching control signal of the control means 32 The switch 33 is comprised.

4 is a flowchart illustrating an operation of a decoding method with reduced delay time according to the present invention.

The flowchart shown in FIG. 4 includes the steps of storing the input bit stream in the decoding input buffer (40), determining whether the stored bit stream amount is larger than the set buffer margin width (41), and the buffer stream width at which the bit stream amount is set. Waiting for it to become larger (42), starting decoding (43), decoded input with the amount of bit stream remaining in the decoded input buffer set when reading Variable Length Decoding (VLD) bits required for decoding from the decoded input buffer; Determining whether it is greater than the buffer free width (44), waiting until the bit stream amount is larger than the set width of the set decoding input buffer (45), continuing decoding (46), retrieving decoded header information Step 47, Inter / Intra, Sub QCIF / QCIF / CIF (Sub Quarter Common Intermediate Format / Quarter Common Intermediate Format / Common Intermediate Format), quantization variables and many A step 48 of changing the margin width of the decoding input buffer according to various compression options and the like.

5 is a diagram illustrating a margin width of a decoding input buffer adjusted according to an input image.

Next, the present invention will be described in detail with reference to Figs.

A bit stream transmitted from a communication network (not shown) or externally is sequentially stored in the decoding input buffer 30 (step 40).

It is determined whether the bit streams sequentially stored in the decoding input buffer 30 are larger than the preset buffer margin width (step 41). The margin width of the decoding input buffer 30 of the present invention is changed differently according to the decoded header information rather than the conventional fixed margin width.

The margin width of the decoding input buffer 30 is changed differently according to the intra mode using only the correlation in the frame of the encoded bit stream transmitted from the communication network or the outside and the inter mode having the correlation between the frames. In addition, the margin width of the decoding input buffer 30 is changed differently according to Sub QCIF / QCIF / CIF, which is a screen size mode transmitted from the communication network or the outside. In addition, the margin width of the decoding input buffer 30 is changed differently according to a mode in which the quantization variable, which changes frequently, is applied in multiple stages. In addition, the margin width of the decoding input buffer 30 is changed differently according to various option modes for compressing the bit stream transmitted from the communication network or the outside. Moreover, although each of these modes operates independently to change the margin width of the decoding input buffer 30, the margin width of the decoding input buffer 30 can be changed in multiple steps by combining the respective modes.

It is determined whether the amount of the bit stream stored in the decoding input buffer 30 is greater than the preset buffer margin width. When the amount of the bit stream stored in the decoding input buffer 30 is smaller than the preset buffer margin width, the decoding input buffer 30 is determined. Wait until it is larger than the margin (steps 41 and 42). That is, the bit stream is continuously stored until the amount of the stored bit stream is greater than the preset width of the decoding input buffer 30.

If the amount of the bit stream stored in the decoding input buffer 30 is larger than the preset buffer margin width, decoding is started (step 43). The decoder 31 starts decoding to read and display the bit stream from the decoding input buffer 30.

When reading Variable Length Decoding (VLD) bits required for decoding from the decoding input buffer 30, it is determined whether the amount of bit stream remaining in the decoding input buffer 30 is greater than the set decoding input buffer 30 allowable width (44). step).

If the amount of bit stream remaining in the decoding input buffer 30 is smaller than the set decoding input buffer 30 allowable width, it waits until the bit stream amount is larger than the set allowance width of the decoding input buffer 30 (step 45).

If the amount of bit stream remaining in the decoding input buffer 30 is larger than the set width of the decoding input buffer 30, decoding is continued (step 46).

The header width of the decoded bit stream is retrieved to change the margin width of the decoding input buffer differently according to Inter / Intra, Sub QCIF / QCIF / CIF, quantization variables, and various compression options (steps 47 and 48).

The header information output from the decoder 31 is input to the control means 32, and the control means 32 outputs a switching control signal for changing the margin width of the decoding input buffer 30 according to the header information. The switching control signals output from the control means 32 are simultaneously output in a combined form, so that the switching means 33 switch them.

The structure of the decoding input buffer 30 is the same as in the prior art, and the margin width of the buffer is changed by the switching control signal of the control means 32 as shown in FIG. FIG. 5A shows the margin width of the decoding input buffer 30 according to the picture type. As shown in (a), in the intra mode, the free width of the buffer 30 is changed to be larger than the free width of the buffer 30 in the inter mode, and in the inter mode, the free width of the buffer 30 is changed in the intra mode buffer ( 30) Change smaller than the margin width. Because inter-frame correlations exist in the inter mode, many macroblocks are skipped, and the amount of data required is relatively small compared to the intra mode that does not use inter-frame correlation information. In H.263, the minimum number of bits required per 1 GOB (Group Of Block) is 446 bits in intra mode and 40 bits in inter mode. Accordingly, it can be seen that the intra mode should have a larger width of the buffer than the inter mode.

Since the portion of the data output at the output position of FIG. 5 (a) during decoding is to take every necessary bit in the VLD process, the decoding header portion can be seen whether the decoding portion is intra mode or inter mode. The margin width of the decoding input buffer 30 can be adjusted.

FIG. 5B shows the margin width of the decoding input buffer 30 according to the picture size shown in the sequence header of the header information. As shown in (b), in the CIF mode among the CIF mode, the QCIF mode, and the CIF mode, the free width of the buffer 30 is changed to be larger than the free width of the buffer 30 in the QCIF mode, and the buffer 30 in the QCIF mode is used. Change larger than the margin width. In the Sub QCIF mode, the margin width of the buffer 30 is changed to be smaller than the margin width of the buffer 30 in the QCIF mode. Because the CIF mode has a screen size of 352 × 288, the QCIF mode has a screen size of 176 × 144, and the Sub QCIF mode has a screen size of 88 × 72, and the amount of data varies depending on the screen size. Change the width differently.

The portion of the data output at the output position of Figure 5 (b) during decoding is to take every necessary bit in the VLD process, so looking at the decoding header portion, it is now known whether the decoding portion is Sub QCIF mode, QCIF mode or CIF mode The width of the decoding input buffer 30 may be adjusted using this information. You can also adjust the margin width by combining the inter / intra mode and the sub QCIF / QCIF / CIF mode.

FIG. 5C shows the margin width of the decoding input buffer 30 according to the quantization variable in the header information. The quantization variable varies from 1 to 31 every macroblock, every GOB, every sequence, and differs depending on DC and AC. Therefore, the changing range is divided into predetermined steps and different margin widths are set according to the steps. As shown in (c), the transform range of the quantization variable is applied in four steps. When the value of the quantization variable is greater than 20, the margin width of the buffer 30 is changed to be larger than the buffer width of the buffer 30 when the value of the quantization variable is between 15 and 20, and the value between the quantization parameter and the parameter is between 15 and 20. The width of the buffer 30 is changed to be smaller than that of the quantization variable value is greater than 20 and larger than that of the quantization variable value is between 10 and 15, and when the quantization variable value is between 10 and 15, Change the margin width to smaller than if the value of the quantization variable is between 15 and 20.

Since the portion of the data output at the output position of FIG. 5 (c) at the time of decoding is to take every necessary bit in the VLD process, the decoding header portion shows that the decoding portion is the value of the quantization variable at this stage. The allowable width of the input buffer 30 can be adjusted. You can also adjust the margin width by combining the Angularization parameter value, Inter / Intra mode and Sub QCIF / QCIF / CIF mode.

FIG. 5D illustrates the margin width of the decoding input buffer 30 according to various compression options in the header information. As an example, the setting of the margin width according to Annex I, which is set to precisely correct an error according to the amount of information transmitted, will be described. First, the header information is searched to change the margin width larger when Annex I is on than when it is off. When Annex I is on, it indicates that error correction is performed precisely among the transmitted bit streams. If the error information is large, the error information is increased against the actual content of one frame, and thus the total amount of information is increased. ) Change the margin width to greater than when Annex I is off.

Since the portion of the data output at the output position of FIG. 5 (d) at the time of decoding is to take every necessary bit in the VLD process, the decoding header portion shows that the compression portion is using which compression option. The margin width of the buffer 30 can be adjusted. You can also adjust the margin by combining compression options, inter / intra mode, sub QCIF / QCIF / CIF mode, and the Angularization parameter values.

The present invention is not limited to the above-described embodiments and can be modified by those skilled in the art within the spirit of the invention.

As described above, according to the present invention, the decoder can operate the decoder continuously by adjusting the margin width of the decoding input buffer according to the characteristics of the input video, thereby reducing the delay time, thereby eliminating the inconvenience that the user feels when viewing the video signal. It can be effective.

Claims (7)

A video signal decoding method, (a) sequentially storing video signals in a buffer having a predetermined width; (b) decoding the video signals stored in the buffer and searching for header information among the decoded video signals; And (c) detecting the type of the video signal from the header information, and changing the margin width of the buffer according to the type of the video signal. The method of claim 1, wherein in step (b) When the amount of the stored video signal is less than the free width of the buffer, the step (a) is repeated until the amount of the stored video signal is larger than the free width of the buffer, the decoding with reduced delay time Way. The method according to claim 1, wherein in the step (c), the type of the video signal is one of an inter mode and an intra mode having different signal processing amounts according to whether or not there is correlation in a frame. A decoding method with reduced latency, characterized in that the free width of the buffer is changed differently. The method of claim 1, wherein in the step (c), when the type of the video signal is any one of a sub-QCIF mode, a QCIF mode, and a CIF mode having different screen sizes, the buffer widths are respectively set according to the mode. Decoding method with reduced latency, characterized by a different change. 2. The method of claim 1, wherein in step (c), when the type of the video signal is any one of modes of applying quantization parameters to the video signal in multiple stages, the margin width of the buffer is changed differently according to the mode. A decoding method with reduced delay time, characterized in that. The method of claim 1, wherein in step (c), when the type of the video signal is any one of predetermined option modes for compressing the zero signal, changing the margin width of the buffer differently according to the mode. Decoding method with reduced latency. The decoding method of claim 3, wherein the margin width of the buffer can be changed in multiple steps by combining the respective modes in step (c).

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