KR19990074889A - Video decoding device and decoding method - Google Patents

Abstract

According to a video decoding method of the present invention, a first step of storing output data of an inverse quantization unit in a first region of a buffer unit, an inverse discrete cosine transform unit reads data of the first region, and then performs a first inverse discrete cosine transform, A second step of storing a result in a second area of the buffer part; another data output from the inverse quantization part is stored in the first area, and the second inverse discrete cosine transformed data of the second area And a fourth step of sequentially filling the entire third area by repeatedly performing the third step of storing the third area and the first, second, and third steps.

Description

Video decoding device and decoding method

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an MPEG-2, and more particularly, to a video decoding apparatus and a decoding method suitable for decoding compressed video data.

In general, a video decoding apparatus includes a variable length decoder (VLD) 11, an inverse scan 12, and an inverse quantizer 13, as shown in FIG. 1. And an Inverse Discrete Cosine Transform 14.

The variable length decoding unit 11 performs variable length decoding from the compressed data in the form of a bitstream.

The inverse scan unit 12 converts the one-dimensional DCT coefficient, which is the output of the variable length decoding unit 11, into two dimensions again according to a scanning method.

The inverse quantizer 13 causes an inverse quantization arithmetic and saturation of the output of the inverse scan unit 12, and the DCT of the encoder and IDCT of the decoder do not match. Mismatch control is performed to prevent accumulating.

An inverse discrete cosine transform 14 is an inverse process of a discrete cosine transform performed in the encoding process, and receives an output signal of the inverse quantization unit 13 from a signal obtained by discrete cosine transform. Perform the process of conversion to the original signal.

Here, motion compensation is performed after the inverse discrete cosine transform unit 14.

Hereinafter, a video decoding apparatus according to the prior art will be described with reference to FIGS. 2 to 3.

2 is a detailed view of an inverse quantization unit and an inverse discrete cosine transform unit of a video decoding apparatus according to the prior art.

As shown in FIG. 2, the inverse quantization unit 13 stores the inverse quantization result in the first buffer unit 13a.

The inverse discrete cosine transform unit 14 reads the result stored in the first buffer unit 13a, performs inverse discrete cosine transform (first inverse discrete cosine transform), and then stores the result of the second buffer unit 14a. Store in the first area.

At this time, while the result of the first buffer unit 13a is read and the inverse discrete cosine transform is performed, the inverse quantizer 13 stores the result of dequantization in the first buffer unit 13a.

While the second inverse quantization result is stored in the first buffer unit 13a, the inverse discrete cosine transform unit 14 performs inverse discrete cosine transform on the result stored in the second buffer unit 14a (secondary inverse discrete). Cosine transform).

In this way, the inverse quantization unit 13 and the inverse discrete cosine transform unit 14 are enabled to store timings of their own result values in the first buffer unit 13a and the second buffer unit 14a. 3 is shown.

As shown in FIG. 3, the first and second inverse discrete cosine transforms are not performed while the output of the inverse quantization unit 13 is stored in the first buffer unit 13a.

Thereafter, the inverse discrete cosine transform unit 14 reads the result value stored in the first buffer unit 13a and performs a first order inverse discrete cosine transform to store the result in the second buffer unit 14a.

When the first inverse discrete cosine transform is completed, the output of the inverse quantization unit 13 is again stored in the first buffer unit 13a, and at the same time, the inverse discrete cosine transform unit 14 stores the first stored in the second buffer unit 14a. Inverse discrete cosine transformed by reading the inverse discrete cosine transformed value.

Thus, the form in which data is stored in the 1st buffer part 13a and the 2nd buffer part 14a is shown in FIG.

As shown in FIG. 3, after the inverse discrete cosine transforming unit 14 reads the data stored in the first buffer unit 13a and converts the first inverse discrete cosine, the result is returned to the second buffer unit 14a. It is stored in a 1st area | region (refer FIG. 2).

Thereafter, the instantaneous discrete cosine transform unit 14 reads the data stored in the first area of the second buffer unit 14a and outputs the second output when the output of the inverse quantizer 13 is stored in the first buffer unit 13a. After the inverse discrete cosine transform is performed, the result is stored in block 1 (see FIG. 2) of the second buffer unit 14a.

When the above process is repeatedly performed and all the blocks 4 of the second buffer unit 14a are filled up, the data stored in the block 1 is sequentially output.

In this case, although shown to block 4 in Figure 3 may have more blocks.

As a result, the conventional video decoding apparatus uses two buffers in performing inverse quantization and inverse discrete cosine transform.

However, the conventional video decoding apparatus as described above is inefficient despite the use of two buffer units. That is, in the case of the second buffer unit, while the block 1 to the block 4 are all filled, while the block 2, block 3, block 4 is not used while being stored in the first block 1, the buffer unit is inefficiently used. .

An object of the present invention is to provide a video decoding apparatus and a decoding method which can efficiently use a layout when designing a hardware because only one buffer unit is used to solve the above problems.

1 is a block diagram of a general video decoding apparatus

2 is a detailed view of a video decoding apparatus according to the prior art;

3 is a timing diagram of a video decoding apparatus according to the prior art.

4 is a block diagram of a video decoding apparatus of the present invention

5 is a diagram illustrating a read and write operation of a buffer unit for explaining a video decoding method according to the present invention.

Explanation of symbols for main parts of the drawings

11: variable length decoding unit 12: reverse scanning unit

13 inverse quantization unit 13a: first buffer unit

14: inverse discrete cosine transform unit 14a: second buffer unit

41: buffer part

The video decoding apparatus of the present invention for achieving the above object is a video decoding apparatus for reconstructing the compressed video data to the original video data, the dequantization operation and saturation of the data in which the variable length decoded data is converted into two-dimensional The inverse quantizer for performing mismatch control to prevent errors from accumulating due to mismatch between the DCT of the encoding apparatus and the IDCT of the decoding apparatus, and receiving two inverse discrete cosine transforms after receiving the output signals of the inverse quantizer. An inverse discrete cosine transform unit for converting a signal to a signal, a first region for storing only the output of the inverse quantization unit, a second region for storing a first-order transformed result by the inverse discrete cosine transform unit, and the inverse discrete cosine The inverse discrete by receiving the output of the inverse quantization unit divided into a third area for storing the result of the quadratic transformation by the conversion unit And a buffer unit for outputting to the sine transform unit and simultaneously storing the output of the inverse discrete cosine transform unit. The video decoding method of the present invention includes a first step of storing output data of the inverse quantizer unit in a first region of the buffer unit; A second step in which the discrete cosine transformer reads the data of the first region and performs the first inverse discrete cosine transform, and stores the result in the second region of the buffer portion, and outputs the first quantized portion to the first region. The third step of storing the second data and the second inverse discrete cosine-conversion and storing the data of the second area in the third area of the buffer unit, and repeatedly performing the first, second, third step The fourth step is characterized by sequentially filling the entire third region.

Hereinafter, a video decoding apparatus and a decoding method of the present invention will be described with reference to the accompanying drawings.

4 is a block diagram of a video decoding apparatus of the present invention.

As shown in FIG. 4, the video decoding apparatus of the present invention comprises an inverse quantization unit 13, an inverse discrete cosine transform unit 14, and a buffer unit 41. As shown in FIG.

Here, the functions of the inverse quantization unit 13 and the inverse discrete cosine transform unit 14 are the same as in the prior art.

The buffer unit 41 may store the output of the inverse quantization unit 13 and simultaneously store the first inverse discrete cosine transformed value and the second inverse discrete cosine transformed value.

To this end, only the addressing logic that writes to and reads from the buffer unit 41 is modified.

That is, one buffer unit 41 shares the output value of the inverse quantization unit 13 with the first and second inverse discrete cosine transform values.

5 shows how the output value of the inverse quantizer and the first and second inverse discrete cosine transform values are stored.

As shown in FIG. 5, during t1, the output value (data) of the inverse quantization unit 13 is stored in the first area of the buffer unit 41. As shown in FIG.

Subsequently, during t2, the inverse discrete cosine transform unit 14 reads data stored in the first region, performs first-order inverse discrete cosine transformation, and stores the result in the second region that does not overlap with the first region. .

After the first inverse discrete cosine transform is performed, the output value of the inverse quantization unit 13 is again stored in the first region of the buffer unit 41 while the inverse discrete cosine transform unit 14 is stored in the second region for t3. After reading, perform quadratic inverse discrete cosine transform and store the result in block 1 of the third region.

Subsequently, the inverse discrete cosine transform unit 14 reads the data stored in the first region during t4, performs the first inverse discrete cosine transformation, and stores the result in the second region.

After the first inverse discrete cosine transform is performed, the output value of the quantization unit 13 is again stored in the first region of the buffer unit 41 during t5, and at the same time, the data stored in the second region is inversely discrete cosine transform unit 14. Second order inverse discrete cosine transform and then stored in block 2.

By repeating this process, all data is filled up to block 4.

Here, the data does not collide in the first area and the second area by different timings for writing and reading the data in the first area and the second area.

The buffer unit 41 according to the present invention has a capacity for storing data sequentially output from the inverse quantization unit 13 and a capacity for storing a first inverse discrete cosine transformed result and a second cosine transform. Use memory with the capacity to store the results.

The input / output ports of the data are multiported so that data collisions do not occur when data is written or read.

As described above, two buffer units are used by using a buffer unit capable of writing and reading the inverse quantization unit, the first inverse discrete cosine transformed result, and the second inverse discrete cosine transformed result. The cost is reduced by minimizing the capacity of the buffer unit, and the layout can be efficiently used when designing the hardware.

Claims (4)

In the video decoding apparatus for restoring the compressed video data to the original video data, An inverse quantization unit performs inverse quantization and saturation on data obtained by converting variable-length decoded data into two dimensions, and an inconsistency control to prevent errors from accumulating because DCT of an encoding device and IDCT of a decoding device do not match. Wow, An inverse discrete cosine transform unit which receives the output signal of the inverse quantization unit and converts the inverse discrete cosine two times into an original signal; A first region for storing only the output of the inverse quantization unit, a second region for storing the first-order transformed result by the inverse discrete cosine transform unit, and a second-converted result by the inverse discrete cosine transform unit And a buffer unit which is divided into a third area, receives the output of the inverse quantization unit, outputs the output to the inverse discrete cosine transform unit, and simultaneously stores the output of the inverse discrete cosine transform unit. The method of claim 1, And the buffer unit is a memory having multiple input / output ports. A first step of storing output data of the inverse quantization unit in a first area of the buffer unit, A second step in which an inverse discrete cosine transformer reads data of the first region and performs first order inverse discrete cosine transform, and stores the result in a second region of the buffer unit; A third step of storing another data output from the inverse quantization unit in the first region and simultaneously storing the data of the second region by second inverse discrete cosine conversion and storing the data in a third region of the buffer unit; And a fourth step of sequentially filling the entire third area by repeatedly performing the first, second, and third steps. The method of claim 3, wherein Storing only data output from the inverse quantization unit in the first region, storing only the first inverse discrete cosine transformed value in the second region, and storing only the second inverse discrete cosine transformed result value in the third region. Video decoding method characterized in that.