JP2003018592A - Image decoding system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image decoding system capable of reducing the capacity of a line memory which is required by an image inverse transformation part and also capable of reducing the size of a control circuit by providing a common circuit both as a circuit used for inverse transformation of an odd-numbered field and as a circuit used for inverse conversion of an even-numbered field. SOLUTION: The image decoding system comprises as CPU which decodes a compressed data and then transfers the decoded data in accordance with the line frequency of an image receiver, and an image inverse transformation part which transforms the data transferred from the CPU into the size displayed on the image receiver. The circuit used for inverse transformation of the odd- numbered field of the image inverse transformation part is also used as the circuit used for inverse transformation of the even-numbered field.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image conversion system and a data control method for an image decoding device accompanied by image conversion.

[0002]

2. Description of the Related Art In the field of mobile communication where the transmission band is limited, MPEG-4 has begun to be used as a moving image data compression method. In MPEG-4, for low bit rate transmission, for example, SDTV (Standard Definition)
on TV) format moving image data to about 1/4 size CIF
Image conversion to (Common Intermediate Format) format,
The CIF image is compressed and then transmitted as compressed data. On the receiving side, after decompressing the compressed data, C
By performing inverse conversion on the IF image, moving image data in SDTV format is obtained. In the CIF format, one frame is composed of one field, and in the SDTV format, one frame is odd.
It is composed of two fields, a field and an even field. In order to perform the image conversion process from the resolution of one frame having one field configuration to the resolution of one frame having two fields, as in the case of performing the image conversion process from the CIF format to the SDTV format, the conversion from one field before conversion is performed. A conversion process must be performed to create the later odd and even fields.

Here, FIG. 2 shows an example of the structure of a moving picture transmission apparatus using MPEG-4. The camera 2-1 outputs the captured moving image as SDTV data 2-2. The image conversion processing unit 2-3 inputs the SDTV data 2-2, performs image conversion processing, and outputs it as CIF data 2-4.
The CPU 2-5 performs compression processing on the CIF data 2-4 and also controls output of the transmission data 2-6.
The transmission data 2-6 is the reception data 1 via the transmission line 1-1.
-2 is output to the CPU 27. CPU2-7 is
Decompression processing for compressed data input as received data 1-2, writing to memory 2-9, and memory 2-
The CIF data 2-10 output from No. 9 is controlled.
Data transfer in these series of operations is performed via the data bus 2-8. The image inverse conversion processing unit 2-11 performs image inverse conversion processing on the CIF data 2-10 and outputs it as SDTV data 1-8 to the monitor 1-9.

Next, the SDTV data 2-2 is converted into CIF data 2-4, and the CIF data 2-10 is converted into SD.
An image processing method for inversely converting the image into TV data 1-8 is shown in FIG. FIG. 3 shows the image size at each processing stage. SDTV data 2 output from the camera 2-1
-2 is SDTV data 3-1 of a moving image in which one frame is composed of 480 lines × 704 pixels. The SDTV data 3-1 has a two-field structure, and one field has 240 lines × 704 pixels. In the image conversion processing unit 2-3, one frame is thinned out by removing one field from the SDTV data 3-1 composed of 480 lines × 704 pixels and deleting 240 lines of data forming the even field 3-3. It becomes the odd field data 3-2 of 240 lines. This o
By dividing 240 lines of the dd field data 3-2 into 5 lines and generating 6 lines of data from 5 lines, the CIF data 3-4 of 288 lines per frame is obtained.
Convert to.

On the other hand, in the image inverse conversion processing unit 2-11, C
288 lines of CIF data 3-4 by PU2-7
Is divided into 6 lines and one line is deleted to input the CIF data 3-5 thinned from 288 lines to 240 lines to the memory 2-9.
The 240 lines of data stored in the memory 2-9 are transferred to the image inverse conversion processing unit 2-11 and the image inverse conversion processing is performed, whereby the SDTV data 3-8
Generate dd field data 3-6. Where ev
Also when the en field data 3-7 is generated, the line thinning-processed CIF stored in the memory 2-9 is used.
The data 3-5 is transferred again to the image inverse conversion processing unit 2-11. That is, the line thinned out by the conversion into the even field data is the same line as the line thinned out by the conversion into the odd field data. Therefore, 240 transferred to the image reverse conversion processing unit 2-11 for conversion into the even field data 3-7.
By performing the image reverse conversion processing different from the conversion of the odd field on the CIF data 3-5 of the line, SDTV
The even field data 3-7 of the data 3-8 is obtained. In this way, different image inverse conversion processing is performed in the odd field and the even field, because the line positions of the pixels of the SDTV data 3-8 are different from the odd field and the ev field.
It depends on the en field. In the image inverse conversion processing unit 2-11, these two field data are combined,
SDTV data 3-8 where one frame is 480 lines
Is output to the monitor 1-9. In order to display a complete moving image without loss of pixels or lines on the monitor 1-9, the SDTV data 1-8 at a constant rate required by the monitor 1-9 is output from the image inverse conversion processing unit 2-11. Monitor 1-9
Need to enter into. The SDTV data 1-8 is the CIF data 2-10 input to the image inverse conversion processing unit 2-11.
Since it is made from, the input timing of CIF data is
Determined by SDTV data 1-8. That is, S
The output timing of the DTV data 1-8 becomes the reference, and C
The image reverse conversion processing from the IF data 2-10 to the SDTV data 1-8 is performed in units of lines of the SDTV data 1-8, and the CIF data 2 output from the CPU 2-7.
-10 and the SDTV data 1-8 output from the image inverse conversion processing unit 2-11 have the same line frequency as that of the monitor 1-9.

Next, a circuit configuration for realizing the image inverse conversion processing section 2-11 will be described. First, a conversion circuit for converting odd field data is shown in FIG. Image inverse conversion processing unit 2
-11 includes a line memory 4-2, a control circuit 4-3, and a digital filter 4-4. Here, the input of the data 4-1 before the image inverse conversion to the image inverse conversion processing unit 2-11 is performed every period when the monitor 1-9 scans one line. The data 4-1 before the image reverse conversion is the control circuit 4
Is input to the line memory 4-2 by the control of -3, and 1
The line memory 4-2 outputs the data after delaying it by the line. The data delayed by one line and the data 4-1 before the image inverse conversion processing, which is the data before the delay, are input to the digital filter 4-4, multiplied by the conversion coefficients, respectively, and added to perform the image inverse conversion. The processed data 4-5 is output from the image inverse conversion processing unit 2-11.

Next, FIG. 5 shows a specific configuration of a conversion circuit for converting even field data. Unlike the conversion circuit for the odd field, the conversion circuit for the even field includes line memories 5-1 and 5-2, a control circuit 5-3, a data bus selector 5-4, and a digital filter 5-5. Here, the input of the data 4-1 before the image inverse conversion to the image inverse conversion processing unit 2-11 is 1 on the monitor 1-9.
It is performed every period for scanning a line. The input data 4-1 before the image inverse conversion is input to the line memory 5-1 and the line memory 5-2 under the control of the control circuit 5-3, and is output after being delayed by one line or two lines, respectively. It At this time, how many lines are delayed depends on how many lines the generated even field is. The delay data output from the line memory 5-1 and the delay data output from the line memory 5-2 selected by the data bus selector 5-4 or the data 4-1 before the image reverse conversion which is not delayed are the digital filter 5 It is input to -5, multiplied by a conversion coefficient different from the conversion of the odd field, added, and output from the image inverse conversion processing unit 2-11 as data 5-6 after the image inverse conversion processing.

Next, details of the image inverse conversion processing which is actually performed by the conversion circuit of the image inverse conversion processing section 2-11 described with reference to FIGS. 4 and 5 will be described. First, FIG. 6 shows line positions and conversion coefficients before and after the image reverse conversion when generating odd field data. Lines 6-1, 6-2, 6 here
-3, 6-4, 6-5, 6-6, 6-7 are line positions of the CIF data 2-10 before the image inverse conversion, and lines 6-8, 6-9, 6-10, 6 -11, 6-12, 6-
Reference numeral 13 is a line position of odd field data which constitutes SDTV data 1-8 after image reverse conversion. In line 6-8, the pixel components of lines 6-1 and 6-2 are 10: 0.
Are converted (added) so that the ratio becomes. Line 6-9
Is converted with the pixel components of lines 6-2 and 6-3 at a ratio of 8: 2. Thereafter, line 6-10 is line 6-3 and 6-4 at a ratio of 6: 4, and line 6-11 is line 6-.
4 and 6-5 are converted at a ratio of 4: 6. Line 6-
In line 12, lines 6-5 and 6-7 are converted at a ratio of 6: 4, and line 6-6 is not referred to. This 6 line CI
The conversion process is performed with the F data and the SDTV data of 5 lines as one cycle, and after line 6-13, the above conversion process is repeated.

Next, FIG. 7 shows line positions and conversion coefficients before and after the image reverse conversion when generating the even field data. Lines 6-1, 6-2, 6-3, 6-4, 6-
5, 6-6 and 6-7 are CIF data 2 before image reverse conversion
-10 line position, lines 7-1, 7-2, 7-3,
7-4, 7-5, and 7-6 are line positions of the even field data forming the SDTV data 1-8 after the image reverse conversion. Here, the line 7-1 is the line 6-1
And 6-2 are converted so that the pixel component has a ratio of 4: 6.
(Added). Line 7-2 includes lines 6-2 and 6-
The 3 pixel components are converted at a ratio of 2: 8. Thereafter, the line 7-3 is converted at a ratio of 0:10 between the lines 6-3 and 6-4, and the line 7-4 is converted at a ratio of the lines 6-5 and 6-7 at 8: 2. Line 7-5 is converted at a ratio of lines 6-5 and 6-7 of 3: 7, and line 6-6 is not referred to. Conversion processing for generating 5 lines of SDTV data from 6 lines of CIF data is performed as one cycle, and the above conversion processing is repeated after lines 7-6.

Next, the SDTV data 1-8 shown in FIG.
FIG. 8 shows the temporal flow of inputting CIF data and the temporal flow of outputting SDTV data when performing the inverse conversion process for the image inverse conversion for generating the odd field of FIG.
Will be explained. FIG. 8 shows the input / output timing of the line of the image inverse conversion processing unit 2-11, and time flows from left to right. Lines 8-1, 8-2, 8-3, 8-4,
Reference numerals 8-5, 8-6, 8-7 are lines of the CIF data 2-10 before the image reverse conversion, and lines 8-8, 8-9, 8
Reference numerals -10, 8-11, 8-12, and 8-13 are lines of odd fields that form the SDTV data 1-8 after the image reverse conversion. CIF to the image reverse conversion processing unit 2-11
The input of the data 2-4 is performed every time one line is scanned by the monitor 1-9. First, in the first one-line period, the data of the line 8-1 is output from the CPU 2-7, and the line memory 4-2 in the image inverse conversion processing unit 2-11 is output.
Remember. In the next one line period, the data of line 8-2 is output from the CPU 2-7. At the same time,
The data of the line 8-1 stored in the line memory 4-2 in the image inverse conversion processing unit 2-11 is output, and the conversion process is performed on the 2-line data to generate the data of the line 8-8. After that, every time the monitor 1-9 scans one line, the lines 8-2 and 8-3 to the line 8-9,
Line 8-10 from line 8-3 and 8-4, line 8
The data of line 8-11 is generated from -4 and 8-5.
However, in the period of the 6th line from the start of the image inverse conversion, C
Under the control of the PU 2-7, the data of the next line 8-7 is output without outputting the line 8-6.

By this operation, the line 8-12 is generated from the lines 8-5 and 8-7. The processing up to this point is one cycle of the image inverse conversion, and the subsequent conversion is a repetition of this cycle. Therefore, the conversion is repeated in the same manner as the line 8-7 in the line 8-7 and the line 8-13 in the line 8-13. Here, odd of SDTV data 1-8
In the field conversion, the capacity of the line memory used inside the image inverse conversion processing unit 2-11 is only one line memory for one line. Also, the inverse conversion process is
Since the conversion processing is repeated for two lines, that is, the line output from the memory in the image inverse conversion processing unit 2-11 and the input line to the image inverse conversion processing unit 2-11, it can be configured with a simple control circuit. It is possible.

Next, the SDTV data 1-8 shown in FIG.
FIG. 9 shows a temporal flow of inputting CIF data and a temporal flow of outputting SDTV data when performing conversion processing for image inverse conversion for generating even field data of. Lines 8-1, 8-2, 8-3, 8-
4, 8-5, 8-6, and 8-7 are CIFs before the image reverse conversion.
It is a line of data 2-10, and lines 9-1 and 9-
Reference numerals 2, 9-3, 9-4, 9-5 and 9-6 are even field data that form the SDTV data 1-8 after the image reverse conversion. CIF to the image reverse conversion processing unit 2-11
The input of the data 2-10 is performed every period when the monitor 1-9 scans one line. First, in the first one line period, the data of the line 8-1 is output from the CPU 2-7, and the line memory 5 in the image inverse conversion processing unit 2-11 is output.
Store in -1. In the next one line period, line 8
-2 data is output from the CPU 2-7 and stored in the line memory 5-2 in the image inverse conversion processing unit 2-11. In the next one-line period, the image inverse conversion processing unit 2-1
Line 8-stored in the line memory 5-1
1 and the line 8-2 stored in the line memory 5-2
An image inverse conversion process is performed on this to generate the data of line 9-1.

Also, during this period, the data of the line 8-3 is output from the CPU 2-7 and the image inverse conversion processing unit 2-1.
It is stored in the line memory 5-1 in the No. 1. Thereafter, the line 8-2 is set every time one line is scanned by the monitor 1-9.
And 8-3 to generate the data of line 9-2,
-3 and 8-4 generate the data of line 9-3. However, in the period of the 6th line from the start of the image inverse conversion, the CP
Line 8-7 is output under the control of U2-7. By this operation, the data of line 9-4 is generated from the data of lines 8-5 and 8-7. In the period of the 7th line from the start of the image reverse conversion, the lines 8-5 and 8-7 used in the image reverse conversion of the 6th line period are used again to generate the data of the line 9-5. 6 lines so far C
The image reverse conversion process for generating SDTV data of 5 lines from the IF data is set as one cycle, and the subsequent conversion is a repetition of this cycle. Therefore, line 8-7 is line 8-1
Similarly, the conversion of line 9-6 is repeated in the same manner as line 9-1. In this way, SDTV data 1
Unlike the conversion of the odd field, the capacity of the line memory used inside the image inverse conversion processing unit 2-11 in the conversion of the even field of −8 requires two line memories for one line. In addition, the inverse conversion processing is performed by using the two lines output from the two line memories mounted in the image inverse conversion processing unit 2-11 and the three lines of the input lines to the image inverse conversion processing unit 2-11. , The conversion process is performed on any two lines, and the control that is different for only one period in one cycle of the image inverse conversion increases the control circuit scale.

[0014]

[Problems to be Solved by the Invention] As described above,
When converting an image such as CIF data in which one frame is composed of one field to an image such as SDTV in which one frame is composed of two fields, the number of lines of the image before the image conversion is displayed on the monitor. By performing line thinning processing so that the number of lines is the same as
In the odd field, the image reverse conversion can be performed by using only one line memory for one line. However, the even field requires two line memories for one line. Further, since control is performed differently for one period in one cycle of the image inverse conversion, the constant processing is not repeated and the control circuit scale increases. As described above, in the conventional image inverse conversion method, CIs obtained by thinning lines are used.
The image reverse conversion process is performed on the F data to reduce the memory capacity in the image conversion processing unit required for conversion of the odd field of the SDTV data, thus reducing the control circuit scale. However, in the conversion of the even field, even if the image inversion processing is performed on the CIF data thinned out of the lines, two line memories are required, and different control is performed for only one period within one cycle of the image inversion conversion. Therefore, it is impossible to reduce the line memory capacity and the control circuit scale in the image conversion processing unit, which hinders the reduction of the circuit size of the image conversion processing unit. The present invention eliminates these drawbacks,
Image decoding capable of reducing the line memory capacity and the control circuit scale required in the image inverse conversion processing unit by making the circuit used for the inverse conversion of the odd field and the circuit used for the inverse conversion of the even field common The purpose is to realize the device.

[0015]

In order to achieve the above-mentioned object, the present invention achieves the above-mentioned object by decoding a compressed data and transferring the decoded data in accordance with the line frequency of a receiver, and a CPU from the CPU. In an image decoding apparatus having an image inverse conversion processing unit for converting the transferred data into a size that can be displayed by the receiver, a circuit and an even circuit used for inverse conversion of the odd field of the image inverse conversion processing unit.
This is a common circuit used for the field reverse conversion. In addition, the image size transferred by the CPU is set to CI.
F, the image size displayed on the receiver is SDTV. Further, a circuit used in the reverse conversion of the odd field and a circuit used in the reverse conversion of the even field of the image reverse conversion processing unit are used as a line memory for delaying the data before the image reverse conversion by one line under the control of the control circuit. , The data delayed by one line and the data before the image inverse conversion process are input, and each is multiplied by a predetermined conversion coefficient and added. That is, the line frequency of the data to be decoded is thinned out so that the predetermined line is equal to the line frequency of the receiver, and the conversion coefficient of a certain line of the data to be decoded is set so that the image inverse conversion is a constant process repetition. By changing,
It is possible to reduce the capacity of the line memory used for the image inverse conversion and reduce the scale of the control circuit for the write control of the line memory.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION The configuration of an image decoding apparatus according to the present invention will be described in detail below with reference to FIG. Note that FIG. 1 shows the configuration from the transmission line 1-1 to the monitor 1-9 in FIG. 2, and the rest of the configuration is the same as in FIG. The transmission path 1-1 outputs the received data 1-2 such as image compression data to the CPU 1-3. CPU 1-3
Performs image expansion processing on the compressed data input as the received data 1-2, writing to the memory 1-6, and output control of the CIF data 1-5 from the memory 1-6.
Further, the data transfer by the CPU 1-3 for these series of operations uses the data bus 1-4. The image inverse conversion processing unit 1-7 performs image inverse conversion processing on the input CIF data 1-5, converts it into SDTV data 1-8, and outputs it to the monitor 1-9.

Next, FIG. 3 shows an image processing method for inversely converting the CIF data 1-5 into SDTV data 1-8. In the image reverse conversion processing unit 1-7, the CPU 1-3 divides the CIF data 3-4 of 288 lines into 6 lines and deletes one line of the CIF data 3-4.
The CIF data 3-5 thinned from the line to 240 lines is input to the memory 1-6. This memory 1-6
The 240 lines of data stored in are transferred to the image inverse conversion processing unit 1-7, and the image inverse conversion processing is performed to generate the odd field data 3-6 of the SDTV data 3-8. In the data generation of the even field 3-7, the CIF data 3-5 stored in the memory 1-6 that has undergone the line thinning processing is again processed by the image inverse conversion processing unit 1.
Transfer to -7. That is, the line thinned out in the data conversion of the even field is the same line as the line thinned out in the data conversion of the odd field. even
240 lines of CIF data transferred to the image inverse conversion processing unit 1-7 for conversion into field data 3-7
5 performs the image reverse conversion processing different from the data conversion of the odd field, and thus the SDTV data 3-8 e
It becomes the data 3-7 of the ven field. Different image conversion processes are performed for the odd field and the even field because the pixel line positions of the SDTV data 3-8 are
Due to the difference between the odd field and the even field. The image inverse conversion processing unit 1-7 combines the two field data and outputs SDTV data 3-8 in which one frame has 480 lines to the monitor 1-9. In FIG. 1, the image before the image inverse conversion process is the CIF data 3-4,
The processed image is SDTV data 3-8, but it can be used in various formats as long as the number of lines is converted.

Here, the circuit configuration of the image inverse conversion processing unit 1-7 for performing the image inverse conversion processing in the image decoding apparatus according to the present invention will be described. First, the odd field conversion circuit has the same circuit configuration as the conventional odd field conversion described with reference to FIG. Then even
The field data conversion circuit will be described in detail with reference to FIG. The image inverse conversion processing unit 1-7 includes a line memory 4-2, a control circuit 4-3, and a digital filter 10.
-1. The input of the data 4-1 before the image inverse conversion to the image inverse conversion processing unit 1-7 is 1 on the monitor 1-9.
It is performed every scanning line period. The data 4-1 before the image reverse conversion is input to the line memory 4-2 under the control of the control circuit 4-3, delayed by one line, and output from the line memory 4-2. The data delayed by this one line and the data 4-1 before the image inverse conversion process, which is the data before the delay, are input to the digital filter 10-1, multiplied by the conversion coefficient and added, and the data after the image inverse conversion process is added. Data 1
0-2 is output from the image inverse conversion processing unit 1-7. Thus, the eve in the image decoding device according to the present invention
Since the n-field data conversion circuit is different from the odd-field data conversion circuit (FIG. 4) only in the digital filter, the number of line memories and the control circuit can be used as a circuit common to the odd field.

Details of the image reverse conversion processing performed by the even field data conversion circuit shown in FIG. 10 will be described. First, the line position and the conversion coefficient before and after the image reverse conversion when generating the even field data of the SDTV data 1-8 will be described with reference to FIG. Line 6-
1, 6-2, 6-3, 6-4, 6-5, 6-6, 6-7
Is the position of the line of the CIF data 1-5 before the image reverse conversion, lines 7-1, 7-2, 7-3, 11-1, 7-
Reference numerals 5 and 7-6 are line positions of the even field which configures the SDTV data 1-8 after the image reverse conversion. Here, the CIF data 1-5 to the image inverse conversion processing unit 1-7
Is input for each period of scanning one line on the monitor 1-9. First, in the first one-line period, in the line 7-1, the pixel components of the lines 6-1 and 6-2 are 4: 6.
Is converted to a ratio of. After that, line 7-
2 is converted so that the pixel components of the lines 6-2 and 6-3 have a ratio of 2: 8, and the line 7-3 is converted so that the pixel components of the lines 6-3 and 6-4 have a ratio of 0:10. . Here, unlike the conventional inverse conversion described with reference to FIG. 7, the line 11-1 is conventionally converted so that the pixel components of the lines 6-5 and 6-7 have a ratio of 8: 2. However, in the present invention, conversion is performed so that the pixel components of the lines 6-4 and 6-5 have a ratio of 0:10. Then, the line 7-5 is converted so that the pixel components of the lines 6-5 and 6-7 have a ratio of 3: 7, and the line 6-6 is not referred to. Line 7
After -6, the above conversion method is repeated. By changing the conversion coefficient so that conversion is performed at such a ratio, od
The conversion procedure of the d field and the even field is made common.

Next, the SDTV data 1-shown in FIG.
FIG. 12 shows the temporal flow of inputting CIF data and the temporal flow of outputting SDTV data when performing the inverse transformation processing for the image inverse transformation for generating the even field of No. 8. That is, FIG. 12 shows the image reverse conversion processing unit 1.
It represents the input / output of line -7, and time flows from left to right. Lines 8-1, 8-2, 8-3, 8-4, 8
-5, 8-6, and 8-7 are lines of the CIF data 1-5 before the image inverse conversion, lines 9-1, 9-2, 9-3, and 1.
2-1, 9-5 and 9-6 are data of odd fields which form the SDTV data 1-8 after the image reverse conversion. CIF data 1-5 to the image inverse conversion processing unit 1-7
Is input every time one line is scanned by the monitor 1-9. First, in the first one-line period, the line 8-1 outputs from the CPU 1-3, and the image inverse conversion processing unit 1
It is stored in the line memory 4-2 in -7. In the next one line period, the line 8-2 outputs from the CPU 1-3, and at the same time, the line 8-1 stored in the line memory 4-2 in the image inverse conversion processing unit 1-7 outputs. , And inverse conversion processing is performed on these two lines to generate line 9-1. After that, the lines 8-2 and 8-3 to line 9-2, the lines 8-3 and 8-4 to line 9-3, and the line 8-4 are output every one line period at the output rate of the monitor 1-9. 8-
Generate line 12-1 from 5. But line 8
During the period of the 6th line from the input of -1 to the image inverse conversion processing unit 1-7, the line 8- is controlled by the CPU 1-3.
The next line 8-7 is output without outputting 6. By this operation, the line 9-5 is generated from the lines 8-5 and 8-7. The processing up to this point is one cycle of the image inverse conversion, and the subsequent conversion is a repetition of this cycle. Therefore, the line 8-7 is similarly converted to the line 8-1, and the line 9-6 is similar to the line 9-1.

Thus, the ev of SDTV data 1-8
In the data conversion of the en field, the capacity of the line memory used inside the image inverse conversion processing unit 1-7 is odd.
Line memory 1 for one line, similar to field conversion
There is only one. Also in the procedure of the inverse conversion process, od
Since it is the same as the d field, the conversion processing is repeated for two lines, that is, the line output from the line memory 4-2 in the image inverse conversion processing unit 1-7 and the input line to the image inverse conversion processing unit 1-7. It is possible to configure with a simple control circuit. As described above, in the image decoding device according to the present invention, the SD processing is performed so that the data processing procedure is shared by the conversion processing of the odd field and the even field.
The conversion coefficient of TV data 1-8 was changed. The change is a change in the conversion process of the even field from 8: 2 to 0:10 for the conversion coefficient used to generate one line of SDTV data in one cycle of the image reverse conversion.
In this way, by changing the conversion coefficient, the line memory for one line can be set to 1 in the conversion of the even field as well as the odd field of the SDTV data 1-8.
The conversion can be performed by using only one piece. In addition, the inverse conversion process is performed by dividing the line output from the line memory in the image inverse conversion processing unit and the line input to the image inverse conversion processing unit into two.
Since the conversion process is repeated for the line, it can be configured with a simple control circuit.

[0022]

As described above, according to the present invention, a predetermined line is thinned out so that the line frequency of the data to be decoded becomes equal to the line frequency of the receiver, so that the image inverse conversion is a constant process repeated. By changing the conversion coefficient of a specific line of data to be decoded, it is possible to reduce the capacity of the line memory used for the image inverse conversion and reduce the control circuit scale such as the write control of the line memory.

[Brief description of drawings]

FIG. 1 is a block diagram showing the configuration of an embodiment of an image decoding apparatus according to the present invention.

FIG. 2 is a block diagram showing the configuration of an example of a conventional image decoding device.

FIG. 3 is a diagram showing a conventional image inverse conversion processing method.

FIG. 4 is a block diagram showing a configuration of a conversion circuit of an odd field in the image reverse conversion processing.

FIG. 5 is a block diagram showing a configuration of a conventional even field conversion circuit.

FIG. 6 is a diagram showing a line position and a conversion coefficient of an odd field after the conventional image inverse conversion.

FIG. 7 is a diagram showing line positions and conversion coefficients of an even field after the conventional image reverse conversion.

8 is a diagram showing a temporal flow before and after image inverse conversion in the case of the image inverse conversion shown in FIG.

9 is a diagram showing a temporal flow before and after image inverse conversion in the case of the image inverse conversion shown in FIG.

FIG. 10 is a block diagram showing a configuration of an even field conversion circuit of the present invention.

FIG. 11 is a diagram showing line positions and conversion coefficients of an even field after image reverse conversion according to the present invention.

12 is a diagram showing a temporal flow before and after image inverse conversion in the case of the image inverse conversion shown in FIG.

[Explanation of symbols]

1-1: transmission path, 1-2: received data, 1-3: CP
U, 1-4: data bus, 1-5: CIF data, 1-
6: memory, 1-7: image inverse conversion processing unit, 1-8: SD
TV data, 1-9: monitor, 2-1: camera, 2-
2: SDTV data, 2-3: image conversion processing unit, 2-
4: CIF data, 2-5: CPU, 2-6: transmission data, 4-1: data before image reverse conversion, 4-2: line memory, 4-3: control circuit, 4-4: digital filter,
4-5: Data after image inverse conversion, 10-1: Digital filter, 10-2: Data after image inverse conversion.

Continued front page    F-term (reference) 5C059 KK06 LB05 LB07 LB12 LB13                       LB15 MA00 PP04 SS10 TA69                       TB09 TC31 UA05 UA32                 5C063 AA01 AA20 AB03 AC01 BA09                       BA20 CA01 CA05 CA12

Claims (3)

[Claims] 1. A CPU that decodes compressed data and transfers the decoded data according to the line frequency of the receiver, and a size of the data transferred from the CPU that can be displayed on the receiver. In an image decoding device having an image inverse conversion processing unit for conversion, a circuit used in inverse conversion of the odd field of the image inverse conversion processing unit and eve
An image decoding device characterized in that a circuit used for inverse conversion of n fields is shared. 2. The image decoding device according to claim 1,
An image decoding device characterized in that the image size transferred by the CPU is CIF and the image size displayed by the receiver is SDTV. 3. The image decoding apparatus according to claim 1 or 2, wherein a circuit used for inverse conversion of odd fields and a circuit used for inverse conversion of even fields of the image inverse conversion processing unit are controlled by a control circuit. It is composed of a line memory that delays the data before the image inverse conversion by one line, and a digital filter that inputs the data delayed by the one line and the data before the image inverse conversion process and multiplies them by a predetermined conversion coefficient and adds them. An image decoding device characterized by the above.