JPH1066023A - Compressed information output device, information compressor and compressed information recording and reproducing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform expansion processing while taking serious view of the quality of information important and the reduction of hardware scale in a device for expanding the compressed information. SOLUTION: A bit rate reduction(BRR) encoder 11 generates compressed image data by encoding and compressing input video signals 10 through a bidirectional predictive encoding system. A simplified compressing part 12 generates simplified compressed image data by performing compression processing to the input video signals 10 based on a system such as a simple thinning system, for example, different from that of the BRR encoder 11. A data interface (I/F) packing control part 13 outputs an I/F signal 14 by integrating the compressed image data as the output data of the BRR encoder 11 and the simplified compressed image data as the output data of the simplified compressing part 12 into the I/F signal of prescribed format.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compressed information output device that incorporates compressed information into a predetermined format and outputs it as a transmission signal, an information compression device that compresses and outputs information, and information that is compressed and recorded. The present invention also relates to a compressed information recording / reproducing apparatus for reproducing and outputting recorded information.

[0002]

2. Description of the Related Art A transmitting side compresses image data and transmits the compressed data, and a receiving side compresses and records the compressed image data.
In a compressed image recording / reproducing apparatus or the like which expands and outputs compressed image data at the time of reproduction, a method of compressing image data is, for example, MPEG (Moving Picture Experts).
Group) standard is a bidirectional predictive coding system. In this bidirectional prediction encoding method, encoding efficiency is improved by using bidirectional prediction.

FIG. 8 is a block diagram showing a configuration of a general image compression encoding apparatus that encodes and compresses image data. This image compression encoding apparatus is capable of input video signal 10
BRR (bit rate reduction) encoder 101 that encodes and compresses 0 using a bidirectional predictive encoding method
Then, the output data of the BRR encoder 101 is packed (packed) in a payload area of an interface (hereinafter, referred to as I / F) signal of a predetermined format, and the data I / F for outputting the I / F signal 103 is packed. An F-packing control unit 102 is provided. In this image compression encoding apparatus, an input video signal 100 is compressed by a BRR encoder 101, and the compressed image data is
The data I / F packing control unit 102 packs the data into the payload area of the I / F signal 103 and outputs it.

FIG. 9 is a block diagram showing a configuration of a general compressed image recording / reproducing apparatus. The compressed image recording / reproducing apparatus includes a BRR encoder 111 for encoding and compressing an input video signal 110 according to a bidirectional predictive encoding method,
An error correction code (hereinafter referred to as ECC) is calculated and added to the output data of the BRR encoder 111.
CC encoder 112 and this ECC encoder 112
And a recording unit 113 for converting the output data into a signal suitable for recording on the recording medium 114 and recording the signal on the recording medium 114. Here, the recording medium 114
Is a tape in a VTR (video tape recorder) or a disk in a disk device such as a hard disk or an optical (magneto-optical) disk device. The compressed image recording / reproducing apparatus shown in FIG. 9 further reproduces the recorded information from the recording medium 114, and performs error correction on output data of the reproducing section 115 using ECC. An ECC decoder 116 and output data of the ECC decoder 116 are converted into an I / F of a predetermined format.
The I / F signal 118 is packed in the payload area of the signal.
A data I / F packing control unit 117 that outputs
A BRR decoder 119 that decodes and expands output data of the CC decoder 116 and outputs the decoded data as an output video signal 120.

In this compressed image recording / reproducing apparatus, an input video signal 110 is compressed by a BRR encoder 111, and the compressed image data is sent to an ECC encoder 11.
The ECC is added by 2 and recorded on the recording medium 114 by the recording unit 113. Also, the playback unit 115
The data reproduced from the recording medium 114 by
After error correction is performed by the ECC decoder 116,
The data I / F packing control unit 117 packs the data into the payload area of the I / F signal 118 and outputs it. Alternatively, the data is decoded and expanded by the BRR decoder 119 and output as the output video signal 120.

FIG. 10 is a block diagram showing a configuration of a general compressed image decoding apparatus. The compressed image decoding apparatus inputs the I / F signal 121 in which the compressed image data is packed, unwinds (depacks) the signal packed in the payload area of the I / F signal 121, A data I / F depacking control unit 122 for extracting compressed image data in a format immediately after encoding, and output data of the data I / F depacking control unit 122 are decoded and decompressed and output as an output video signal 124. And a BRR decoder 123. In this compressed image decoding apparatus, compressed image data in a format immediately after encoding is extracted from the I / F signal 121 by the data I / F depacking control unit 122, and the pressure image data is decoded by the BRR decoder 123. The output video signal 124 is output as the output video signal 124.

FIG. 11 shows the BRR in FIG. 8 or FIG.
FIG. 2 is a block diagram illustrating an example of a configuration of an encoder. The BRR encoder subtracts a difference between an input video signal 130 and predicted image data described later, and a DCT that performs discrete cosine transform (hereinafter, referred to as DCT) on output data of the subtraction unit 131. And a quantization unit 133 that quantizes the output data of the DCT unit 132 and outputs it as compressed image data 134. The BRR encoder further includes a quantization unit 13
3, an inverse quantizer 135 that inversely quantizes the output data of No. 3, an inverse DCT unit 136 that performs an inverse DCT on the output data of the inverse quantizer 135, and an output data of the inverse DCT unit 136 and a prediction described later. An adder 137 for adding and outputting the image data; a frame memory (1) 138, a frame memory (2) 139 for storing the output data of the adder 137 for one frame each; A switch unit 140 for selectively outputting output data to one of the frame memories (1) 138 and (2) 139, and based on data stored in the frame memories (1) 138 and (2) 139. A prediction unit 141 that generates and outputs predicted image data; and a switch unit 14 that selectively outputs output data of the prediction unit 141 to the subtraction unit 131. It is equipped with a door. Prediction unit 141
May have a motion compensation function.

In this BRR encoder, the subtractor 131
Accordingly, a difference between the input video signal 130 and the predicted image data is obtained, and D
DCT is performed by the CT unit 132, and the DCT unit 132
Is output as image data 134 which is quantized and compressed by the quantization unit 133. The output data of the quantization unit 133 is inversely quantized by the inverse quantization unit 135, the output data of the inverse quantization unit 135 is subjected to inverse DCT by the inverse DCT unit 136, and the addition unit 137 performs The output data of the inverse DCT unit 136 and the predicted image data are added and stored in the frame memory (1) 138 or the frame memory (2) 139 via the switch 140. In the bidirectional predictive coding method, three types of coding are performed: intra-frame coding, inter-frame forward predictive coding, and bidirectional predictive coding. These are called pictures and B pictures. The prediction unit 141 calculates P
When encoding a picture, the frame memory (1) 138
Alternatively, predicted image data is generated and output based on the previous I picture or P picture stored in the frame memory (2) 139, and the predicted image data is output to the subtraction unit 131 via the switch unit 142. . Prediction unit 14
1 generates and outputs predicted image data based on the preceding and succeeding I or P pictures stored in the frame memory (1) 138 and the frame memory (2) 139 at the time of encoding a B picture. The image data is output to the subtraction unit 131 via the switch unit 142. When encoding an I-picture, the switch unit 14
No. 2 does not output the predicted image data to the subtraction unit 131, whereby the encoding is performed based only on the input video signal 130.

In this BRR encoder, field-to-frame conversion is required at the initial stage depending on the compression method, a plurality of frame memories are required in total, and the logic part is of the order of hundreds of thousands of gates. Requires large scale hardware.

FIG. 12 shows the BR in FIG. 9 or FIG.
FIG. 3 is a block diagram illustrating an example of a configuration of an R decoder. The BRR decoder receives the compressed image data 150 and inversely quantizes the image data 150, and an inverse DT that performs inverse DCT on the output data of the inverse quantization unit 151.
A CT unit 152, and an addition unit 1 that adds and outputs output data of the inverse DCT unit 152 and predicted image data described later.
53 and a frame memory (1) 15 for storing the output data of the adder 153 for one frame each.
4, a switch unit 1 for selectively outputting the output data of the frame memory (2) 155 and the adder 153 to one of the frame memory (1) 154 and the frame memory (2) 155.
A prediction unit 157 for generating and outputting predicted image data based on data stored in the frame memory (1) 154 and the frame memory (2) 155;
7, a switch unit 158 for selectively outputting the output data of No. 7 to the addition unit 153, and switching between the output data of the addition unit 153, the output data of the frame memory (1) 154, and the output data of the frame memory (2) 155, And a switch unit 159 that outputs the output video signal 160.

In this BRR decoder, the inverse quantization unit 15
1, the compressed image data 150 is inversely quantized, and the output data of the inverse quantization
The inverse DCT is performed by the T unit 152, and the output data of the inverse DCT unit 152 and the predicted image data are added and output by the adding unit 153. The output data of the adder 153 is sent to the frame memory (1) via the switch 156.
154 or the frame memory (2) 155. When decoding a P picture, the prediction unit 157 uses the frame memory (1) 154 or the frame memory (2) 1
The predicted image data is generated and output based on the previous I picture or P picture stored in 55, and the predicted image data is output to the addition unit 153 via the switch unit 158. When decoding a B picture, the prediction unit 157 determines whether the preceding or succeeding I picture or P picture stored in the frame memory (1) 154 and the frame memory (2) 155 is present.
Generate and output predicted image data based on the picture,
The predicted image data is output to the adding unit 153 via the switch unit 158. When decoding an I picture, the switch unit 158 adds the predicted image data to the addition unit 15.
3, the decoding is performed based only on the image data 150. In addition, the switch unit 159
When decoding a B picture, the output data of the adder 153 is output as an output video signal 160. When decoding an I picture or a P picture, the frame memory (1) 1
54 or the output data of the frame memory (2) 155 is output as the output video signal 160.

Also in this BRR decoder, depending on the compression method, conversion from a frame to a field is required at the final stage, and large-scale hardware similar to a BRR encoder is required.

[0013]

As a specific example of a device including a compressed image decoding device, there is an editing controller in addition to a general decoder for expanding compressed image data and displaying it on a monitor. . Here, the editing controller will be briefly described. In a video signal editing operation, in a method using a conventional VTR, several cuts of material data to be used are selected, and the cuts are sequentially dubbed to one tape. However, in the case of a recording / reproducing device such as a hard disk or a magneto-optical disk device using a disk-shaped recording medium, random access can be performed at the time of reproduction, so that actual material data need not be rearranged and re-recorded. Once a list (edit list) of which material data is to be reproduced in which order is created, the editing work can be performed by reproducing the material data according to the list. This is a method generally called nonlinear editing.

The editing controller is a device for remotely controlling the video signal recording / reproducing device, confirming the contents of the material data, and creating an edit list file. It is configured with an image decoding device as a core.

As a method of editing a video signal using an editing controller, the following method may be used in addition to a method of performing an editing operation while remotely controlling a video signal recording / reproducing apparatus. That is, in the recording medium of the editing controller main body, all material data is first dubbed, and the editing is performed in a state of being separated from the video signal recording / reproducing device containing the original material data, that is, by the editing controller alone. is there. Generally, since the capacity of the recording medium of the editing controller body is small, when dubbing the material data, it is necessary to further compress the original compressed image data to reduce the data amount. This allows
Although the image quality after recompression deteriorates, there is no problem as long as the content can be determined. It is the editing controller
This is for creating an edit list, and when actually performing and reproducing the performance based on the list of the edit results, a video signal recording / reproducing apparatus containing the original material data before the image quality is deteriorated is used. . Further, since the editing controller often uses a notebook-type personal computer in consideration of single use and portability, a large amount of information is required if the editing controller can display a small size on the liquid crystal screen of the personal computer. It is also considered that it is not.

However, when the above-described bidirectional predictive coding method is used as a method for compressing image data, an interpolative inter-frame predictive coding from both preceding and succeeding frames is performed. There is a disadvantage that the hardware scale (including the memory capacity) of the compression encoding circuit and the compressed image decoding circuit becomes enormous. Therefore, a device that handles image data with a high compression rate needs to be equipped with hardware of a scale corresponding to the compression rate.

Therefore, it is difficult to mount large-scale hardware in a device requiring a small size and low power consumption, such as a portable device, so that it is difficult to handle image data having a high compression ratio. There is a problem that is.
As a result, for example, it has been difficult to realize a portable editing controller that handles image data with a high compression ratio.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and an object of the present invention is to provide a device for expanding compressed information to perform expansion processing with emphasis on the quality of information, and to reduce the scale of hardware. It is an object of the present invention to provide a compressed information output device, an information compression device, and a compressed information recording / reproducing device which can select whether to perform a decompression process with emphasis on image quality.

[0019]

According to a first aspect of the present invention, there is provided a compressed information output apparatus which incorporates compressed information into a predetermined format and outputs the information as a transmission signal. 1 for the first compressed information obtained by performing the compression process 1 and the information to be transmitted.
And a transmission signal output means for incorporating the second compression information obtained by performing the second compression processing by a method different from the above compression processing into a predetermined format and outputting the transmission signal as a transmission signal.

According to a third aspect of the present invention, there is provided an information compression apparatus which performs first compression processing on information to be transmitted to generate first compression information, and performs first compression processing on the information to be transmitted. A second compression processing unit that performs a second compression process using a method different from that of the first compression processing unit to generate second compression information; and a first compression processing unit that generates the second compression information. Transmission signal output means for incorporating the compression information and the second compression information generated by the second compression processing means into a predetermined format and outputting the transmission signal as a transmission signal.

According to a sixth aspect of the present invention, there is provided a compressed information recording / reproducing apparatus.
First compression processing means for performing first compression processing on input information to generate first compression information; and recording the first compression information generated by the first compression processing means on a recording medium. Recording means, a reproducing means for reproducing the first compressed information recorded on the recording medium, and a decompressing means for performing decompression processing on the first compressed information reproduced by the reproducing means and outputting reproduced information. Means, and second compression processing means for performing second compression processing on the reproduction information obtained by the decompression means using a method different from that of the first compression processing means to generate second compression information; Transmission signal output means for incorporating the first compressed information reproduced by the reproducing means and the second compressed information generated by the second compression processing means into a predetermined format and outputting as a transmission signal It is.

According to the first aspect of the present invention, there is provided a compressed information output apparatus, wherein the transmission signal output means outputs first information to the information to be transmitted.
The first compressed information obtained by performing the second compression processing and the second compression information obtained by performing the second compression processing on the information to be transmitted by a method different from the first compression processing are described below. It is incorporated in a predetermined format and output as a transmission signal.

According to the third aspect of the present invention, the information to be transmitted is subjected to the first compression processing by the first compression processing means to generate the first compressed information, and the second compression processing means. The information to be transmitted is first processed by the processing means.
The second compression processing is performed by a method different from that of the first compression processing means to generate second compression information, and the transmission signal output means generates the first compression information generated by the first compression processing means.
And the second compressed information generated by the second compression processing means are incorporated into a predetermined format and output as a transmission signal.

In the compressed information recording / reproducing apparatus according to the sixth aspect, the first compression processing means performs first compression processing on the input information to generate first compressed information. The compressed information is recorded on the recording medium by the recording means. Further, the first compressed information recorded on the recording medium is reproduced by the reproducing means, and the expanded first compressed information is subjected to decompression processing by the decompressing means, and the reproduced information is output. Further, the reproduction information obtained by the decompression means is subjected to the first compression processing by the second compression processing means.
The second compression processing is performed by a method different from that of the compression processing means, the second compression information is generated, and the first compression information reproduced by the reproduction means and the second compression processing are generated by the transmission signal output means. The second compressed information generated by the means is combined with a predetermined format and output as a transmission signal.

[0025]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 shows the first embodiment of the present invention.
FIG. 3 is a block diagram illustrating a configuration of an image compression encoding device as an information compression device according to the embodiment. This image compression encoding apparatus encodes and compresses an input video signal 10 by a bidirectional predictive encoding method, and generates a BRR encoder 11 as first compression processing means for generating compressed image data as first compression information. And a simple compression section 12 as a second compression processing means for performing compression processing on the input video signal 10 by a method different from that of the BRR encoder 11 to generate simple compressed image data as second compression information.
, The output data of the BRR encoder 11 and the simple compression unit 1
And a data I / F packing control unit 13 that incorporates the output data of No. 2 into an I / F signal of a predetermined format and outputs an I / F signal 14 as a transmission signal. The configuration of the BRR encoder 11 is, for example, the same as that shown in FIG. In addition, the simple compression unit 12 includes a BR
This is to generate simplified compressed image data that allows simpler expansion processing than the compressed image data generated by the R encoder 11. The data I / F packing control unit 13 controls each of the compressed image data and the simple compressed image data so that the device that inputs and processes the I / F signal 14 can process the compressed image data and the simple compressed image data independently. And independent control information is added to the output. In this image compression encoding device, the data I / F packing control unit 13 corresponds to the compression information output device according to the present invention.

Here, an outline of the operation of the image compression encoding apparatus according to the present embodiment will be described. In this image compression encoding device, the input video signal 10 is compressed by the BRR encoder 11 to generate compressed image data,
The simple compression unit 12 compresses the input video signal 10 to generate simple compressed image data, and the data I / F packing control unit 13 converts the compressed image data and the simple compressed image data into the payload area of the I / F signal 14. Is packed and output. The simple compression unit 12 and the data I
The operation of the / F packing control unit 13 will be described later in detail together with the second embodiment.

FIG. 2 is a block diagram showing a configuration of a compressed image recording / reproducing apparatus as a compressed information recording / reproducing apparatus according to a second embodiment of the present invention. This compressed image recording / reproducing apparatus encodes an input video signal 20 by a bidirectional predictive encoding method, compresses the input video signal 20, and generates BRR as first compression processing means for generating compressed image data as first compression information.
An encoder 21, an ECC encoder 22 for calculating and adding an ECC to the output data of the BRR encoder 21, and converting the output data of the ECC encoder 22 into a signal suitable for recording on a recording medium 24 for recording And a recording unit 23 for recording on the medium 24.
Here, the recording medium 24 is a tape in a VTR,
This is a disk or the like in a disk device such as a hard disk or an optical (magneto-optical) disk device.

The compressed image recording / reproducing apparatus according to the present embodiment further includes a reproducing unit 25 for reproducing recorded information from a recording medium 24, and an output data of the reproducing unit 25 using ECC. ECC decoder 2 for error correction
6 and a BRR for decoding and expanding the output data of the ECC decoder 26 and outputting it as an output video signal 30.
A decoder 29 and a second compression processing means for performing compression processing on the output data of the BRR decoder 29 by a method different from that of the BRR encoder 21 to generate simplified compressed image data as second compression information. The simple compression unit 31, the output data of the ECC decoder 26, and the output data of the simple compression unit 31 are converted into an I / F of a predetermined format.
And a data I / F packing control unit 27 which is incorporated in the signal and outputs an I / F signal 28 as a transmission signal.

The configuration of the BRR encoder 21 is, for example, the same as that shown in FIG. The configuration of the BRR decoder 29 is obtained, for example, by adding a later-described special reproduction processing circuit to the circuit shown in FIG. Also, the simple compression unit 3
Numeral 1 is for generating simple compressed image data that allows simpler expansion processing than the compressed image data generated by the BRR encoder 21. Data I / F
The packing control unit 27 controls each of the compressed image data and the simple compressed image data independently so that the device that inputs and processes the I / F signal 28 can process the compressed image data and the simple compressed image data independently. The control information is added and output. In this compressed image recording / reproducing device, the data I / F packing control unit 27 corresponds to the compressed information output device of the present invention.

FIG. 3 shows the BRR decoder 29 in FIG.
FIG. 3 is a block diagram showing a configuration of a special reproduction processing circuit in FIG.
This special reproduction processing circuit is provided, for example, at the subsequent stage of the circuit shown in FIG. 12 and receives the image data 32 after the expansion processing and performs jog reproduction (frame-by-frame reproduction, slow reproduction), shuttle reproduction (high-speed reproduction), and the like. A memory controller 33 for controlling special playback at a playback speed different from the playback speed during normal playback, and a memory controller 33 connected to the memory controller 33;
A special reproduction memory 34 used for special reproduction is provided. Addresses for writing and reading data to and from the special reproduction memory 34 are controlled by a system control unit (not shown) in accordance with a reproduction speed requested by the user, whereby special reproduction is realized. ing. The output data of the memory controller 33 is the BRR decoder 29 shown in FIG.
Output video signal 30.

Here, an outline of the operation of the compressed image recording / reproducing apparatus according to the present embodiment will be described. In this compressed image recording / reproducing apparatus, an input video signal 20 is compressed by a BRR encoder 21 to generate compressed image data.
CC is added, and the recording unit 23 records the recording medium 2
4 recorded. The compressed image data reproduced from the recording medium 24 by the reproducing unit 25 is sent to the data I / F packing control unit 27 and the BRR decoder 29 after error correction is performed by the ECC decoder 26. The BRR decoder 29 decodes and expands the output data of the ECC decoder 26, and outputs it as an output video signal 30. In addition, the simple compression unit 31 includes the BRR decoder 2
9 is subjected to compression processing to generate simple compressed image data. Data I / F packing control unit 27
Is the output data of the ECC decoder 26 and the simple compression unit 31
Is packed in the payload area of the I / F signal in a predetermined format, and the I / F signal 28 is output. The operations of the simple compression section 31 and the data I / F packing control section 27 will be described in detail below.

Next, the operation of the simple compression section 12 in FIG. 1 and the simple compression section 31 in FIG. 2 will be described in detail with reference to FIG. The simple compression units 12 and 31 use a compression method that enables simple decompression processing and reduces the scale of hardware required for decompression processing, without deteriorating image quality after decompression. Compress. As such a compression method, for example, there is a simple thinning method. Here, it is assumed that the simple compression units 12 and 31 use this simple thinning method. The simple thinning method is a method of reducing information by thinning data in at least one of the horizontal direction and the vertical direction of the screen. FIG. 4 shows an operation when data is thinned to 1/4 in both the horizontal and vertical directions by the simple thinning method. In this figure, (a) shows data before compression, and (b) shows data after compression. The numbers in the figure represent pixel numbers. In this example, pixel 0 is obtained from the data before compression shown in FIG.
Like 0,04,08, ..., 40,44,48, ...
Pixel data is extracted at a rate of one pixel for every four pixels in both the horizontal direction and the vertical direction, and the extracted pixel data forms compressed data as shown in FIG.

In this simple thinning method, although the number of pixels decreases, the image quality deteriorates, but the compression ratio increases. Moreover, since it does not use the correlation in the time axis direction and only thins out the data,
The simple compression units 12 and 31 can be realized only by a FIFO (first in first out) memory corresponding to the number of pixels after compression and a simple control circuit (about 1000 gates). Although some hardware is added, a certain degree of image quality improvement can be achieved by applying a filter in the two-dimensional directions of the horizontal direction and the vertical direction. Such simple compression units 12, 31
When the image data is compressed by using, the device for expanding the compressed image data can also be realized by small-scale hardware like the simple compression units 12 and 31.

A well-known simple decimation method is a 共通 common intermediate format (hereinafter referred to as QCIF).
It is written. ). In this QCIF, the luminance signal is formatted into 176 pixels per line and 144 lines per frame in the television system of 625 scanning lines and 50 fields as in the PAL system, and is scanned in the NTSC system or the like. In the television system of 525 lines and 60 fields, the luminance signal is 1
The format is 176 pixels per line, 120 lines per frame. For example, 625 scanning lines,
In the QCIF for the 50-field television system, the total information amount including the luminance signal and the color difference signal is as follows.
176 × 2 × 144 × 8 (bits) = 0.4 Mbits /
It becomes a frame. Therefore, it can be seen that with this thinning out of the size, compression processing is possible only with a 0.4 Mbit FIFO memory.

Next, the operations of the data I / F packing control unit 13 in FIG. 1 and the data I / F packing control unit 27 in FIG. 2 will be described in detail with reference to FIGS. In the data I / F packing control units 13 and 27, compressed image data as output data of the BRR encoder 11 in FIG. 1 or the ECC decoder 26 in FIG. Are incorporated into an I / F signal of a predetermined format, and I / F signals 14 and 28 as a transmission signal are output.

FIG. 5 shows the data I / F packing control unit 1.
3A and 3B conceptually show the operations 3 and 27. FIG.
2A shows image data (hereinafter, referred to as uncompressed image data) 41 before being compressed by the input video signals 10 and 20 input to the BRR encoder 11 in FIG. 1 or the BRR encoder 21 in FIG. 5 (b)
FIG. 4 shows compressed image data 42 which is output data of the BRR encoders 11 and 21. FIG. In FIG. 5A, a group of uncompressed image data corresponds to a GOP (group of pictures), which is a group of compression processing. This GOP-based uncompressed image data is
The BRR encoders 11 and 21 convert the compressed image data 42 into GOP units at this time.
As shown in (b), the amount of information is reduced. As shown in FIG. 5C, the data I / F packing control units 102 and 117 in the conventional apparatus shown in FIGS.
The compressed image data 52 output from the I / F 16 is packed in the payload area 43 of the I / F signal in a predetermined format, and the I / F signal is output. In FIG. 5C, reference numeral 44 denotes a control data part in the I / F signal. On the other hand, the data I / F packing control unit 13 according to the first or second embodiment of the present invention,
27, the compressed image data 42 is packed into the payload area 43 of the I / F signal of a predetermined format as shown in FIG. 45 are packed into the empty area of the payload area 43 of the I / F signal to form one I / F.
The compressed image data 42 and the simplified compressed image data 45 are transmitted by the F signal. FIG.
Although not shown in (d), the compressed image data 42 and the simplified compressed image data 45 are independently converted into the compressed image data 42 and the simplified compressed image data 45 in an apparatus that inputs and processes an I / F signal. Independent control information is added to enable processing.

FIG. 6 shows an example of an I / F signal format according to the first or second embodiment of the present invention.
FIG. 3 is an explanatory diagram for describing a storage state of compressed image data and simple compressed image data when a DDI (serial digital data interface) format is used. The example shown in FIG. 6 is an example of a case where a compression process is performed by forming one GOP with two frames. FIG. 6A shows image data before compression (uncompressed image data).
(B) represents the image data after compression. In this example, based on the uncompressed image data (1) for two frames (= 1 GOP), compressed image data D1 and simple compressed image data 61 and 62 are generated, and the following two frames (=
Based on the uncompressed image data (2) for one GOP), the compressed image data D2 and the simple compressed image data 63, 64
Has been generated. The same applies to the following. Also, control data 65, 66,... As control information are added to the respective compressed image data D1, D2,. The control data 65, 66,... Include information indicating the content of the corresponding data, information indicating the length of the data,
It contains information such as time code. FIG. 6C shows a state where the compressed image data and the simple compressed image data shown in FIG. 6B are stored in the SDDI format. In the SDDI format, as shown in FIG. 6D, during one horizontal period (1H), an end synchronization code EAV indicating the end of the active line, and a horizontal ancillary data portion HANC as an auxiliary data portion are sequentially provided from the beginning. , A start synchronization code SAV indicating the start of the active line, and a payload area. When the compressed image data shown in FIG. 6B is put on the SDDI format, the control data and the compressed image data are divided into lengths that can be stored in the 1H payload area in the SDDI format, and each is divided into the SDDI format. In the 1H payload area. In the example shown in FIG. 6C, the control data 65 is shown as having a length that can be stored in the 1H payload area in the SDDI format, but the length of the control data is shorter than this. May be good or long. FIG. 6E shows data D1-1 and D1-D1 having a length that can store the compressed image data D1 in the 1H payload area in the SDDI format.
2, D1-3, D1-4,..., D1-N. These data D1-1 to D1-
N are stored in the 1H payload area in the SDDI format, as shown in FIG. 6C. The same applies to the simple compressed image data. The control data for the simple compressed image data and the simple compressed image data are divided into lengths that can be stored in the 1H payload area in the SDDI format, and the divided data are respectively divided into the SDDI format. It is stored in the 1H payload area. In FIG. 6C, reference numeral 69 denotes
3 shows divided control data and simplified compressed image data. As shown in FIG. 6C, control data is added to each of the compressed image data and each of the simplified compressed image data. Therefore, in an apparatus that inputs and processes an I / F signal based on the control data, The compressed image data and the simplified compressed image data can be independently processed without referring to the other data area at all. In FIG. 6C, reference numeral 68 indicates an empty area where no data is stored in the payload area. As described above, an empty area may be provided between the compressed image data and the simple compressed image data, or may be stored without providing an empty area between the compressed image data and the simple compressed image data.

Next, the operation of the special reproduction processing circuit shown in FIG. 3 will be described. In this special reproduction processing circuit, the data writing and reading addresses of the special reproduction memory 34 by the memory controller 33 are controlled by a system control unit (not shown) according to the reproduction speed requested by the user, and the special reproduction is realized. . Here, at the time of special reproduction, since data in GOP units is reproduced at irregular intervals, the special reproduction processing circuit performs special reproduction processing such that the motion of the reproduced image is smooth.

Here, an example of the special reproduction process will be described with reference to FIG. In this example, 2 frames are 1 GO
This is an example of a case where a compression process is performed by configuring P. FIG.
(A) represents a frame of image data before compression, and the numbers in the figure represent frame numbers. FIG.
(B) shows the compressed image data, and the numbers in the figure represent GOP numbers. In this example, FIG.
As shown in (a) and (b), the BRR encoder 21 in the compressed image recording / reproducing apparatus shown in FIG.
Compressed image data for one GOP is generated based on the image data for two frames, and the compressed image data is recorded on the recording medium 24. FIG. 7 (c) shows that B
This shows image data obtained by decompression by the RR decoder 29. Thus, during normal playback,
The compressed image data for each GOP is reproduced from the recording medium 24, and the BRR decoder 29 expands the image data for two frames from the compressed image data for one GOP.

On the other hand, for example, the playback speed is 1 /
2 at the time of slow reproduction, as shown in FIG.
The playback speed of the compressed image data in OP units is の that of normal playback. FIG. 7E shows image data obtained by decompression by the BRR decoder 29 at this time. Thus, the reproduction speed is 1 / the speed of the normal reproduction.
At the time of slow reproduction of frame 2, for example, after image data of frame “00” and frame “01” corresponding to GOP “0” is obtained, frame “1” corresponding to GOP “1” is obtained.
No new image data is obtained until the image data of frame 0 and frame 11 is obtained, and during this time, the image data of frame 01 is stored in the memory, and this image data is repeatedly output. In such a case, the motion of the obtained reproduced image becomes unnatural.Therefore, in the special reproduction processing circuit, if the image data of the frame “00” and the frame “01” corresponding to the GOP “0” is obtained, for example, , The frame “00” and the frame “0”
The image data of "1" is stored in the special reproduction memory 34, and until the compressed image data corresponding to the next GOP "1" is reproduced, as shown in FIG.
0 ”,“ 01 ”, and“ 01 ”in this order.
4 and outputs the compressed image data. As a result, the motion of the obtained reproduced image becomes smooth.

As described above, according to the image compression encoding apparatus according to the first embodiment of the present invention or the compressed image recording / reproducing apparatus according to the second embodiment of the present invention, the BR
The compressed image data, which is the output data of the R encoder 11 or the ECC decoder 26, and the simple compressed image data, which is the output data of the simple compression units 12 and 31, are incorporated into an I / F signal of a predetermined format, and the I / F signal 14 , 28 are output, the device that expands the compressed information by inputting the I / F signals 14 and 28 expands the compressed image data with emphasis on image quality, although the hardware scale is increased. Alternatively, it is possible to select whether to decompress the simplified compressed image data with an emphasis on downsizing the hardware scale, although the image quality is degraded. In particular, in the case of a portable type simple monitor or editing controller, by selecting the latter, the hardware scale is drastically reduced, and a small-sized, low-power-consumption, and low-cost device can be realized.

Further, when the material data is recompressed and recorded on the recording medium of the editing controller body, the compression format of the editing controller is changed to the simple compression unit 12,
If it is combined with the compression format in 31, the editing controller can directly record the input signal without doing anything, and in this respect, hardware can be reduced.

Further, in the image compression encoding apparatus according to the first embodiment of the present invention or the compressed image recording / reproducing apparatus according to the second embodiment of the present invention, the I / F signals 14 and 28 Independent control information is added to the compressed image data and the simple compressed image data.
In a device that inputs and processes the I / F signals 14 and 28, the compressed image data and the simplified compressed image data can be processed independently.

Further, in the compressed image recording / reproducing apparatus according to the second embodiment of the present invention, the BRR decoder 29 performs a special reproduction process for smoothing the movement of the reproduced image on the video signal. Since the simple compression section 31 performs the compression processing to generate the simple compressed image data, in the device that inputs the I / F signal 28 and expands the simple compressed image data, the movement of the reproduced image is smooth. Such processing becomes unnecessary, and in this regard, hardware can be reduced.

The present invention is not limited to the above embodiments. For example, the first compression processing and the second compression processing are respectively performed by a bidirectional predictive coding method and a simple decimation method. There is no limitation, and each method may be used. The information to be compressed is not limited to image data, but may be other types of data such as audio data. Further, the format for transmitting the compressed information is not limited to the examples described in the above embodiments, and other formats may be used.

[0046]

As described above, according to the compression information output device of the first or second aspect, the first compression processing is performed on the information to be transmitted by the transmission signal output means. 1 for the compressed information and the information to be transmitted
Since the second compression information obtained by performing the second compression processing by a method different from the compression processing of the above is integrated into a predetermined format and output as a transmission signal, a device for expanding the compressed information In this case, there is an effect that it is possible to select between performing expansion processing with an emphasis on the quality of information and performing expansion processing with an emphasis on reducing the scale of hardware.

According to the compression information output device of the present invention, independent control information is added to each of the first compression information and the second compression information and output. Item 1 In addition to the effect of the compression information output device described in Item 1, the first compression information and the second compression information can be independently processed in a device that inputs and processes a transmission signal output from the compression information output device. This has the effect of being possible.

According to the information compression apparatus of any one of claims 3 to 5, the first compression processing means performs the first compression processing on the information to be transmitted to perform the first compression processing. Information, and by the second compression processing means,
The information to be transmitted is subjected to a second compression process using a method different from that of the first compression processing means to generate second compression information, and the transmission signal output means generates the first compression information and the second compression information. The compressed information is embedded in a predetermined format and output as a transmission signal.Therefore, in a device for expanding compressed information, it is possible to perform expansion processing with emphasis on the quality of information, This makes it possible to select to perform a decompression process with emphasis on image formation.

According to the information compression apparatus of the present invention, independent control information is added to each of the first compression information and the second compression information and output.
In addition to the effect of the information compression device according to the third aspect, the first compression information and the second compression information can be independently processed in the device that receives and processes the transmission signal output from the information compression device. This has the effect of becoming

Further, according to the compressed information recording / reproducing apparatus of the present invention, the first compression processing means performs the first compression processing on the input information to perform the first compression processing. Information is generated, the first compressed information is recorded on a recording medium by a recording means, and the first compressed information recorded on the recording medium is reproduced by a reproducing means, and the reproduced first compressed information is reproduced. The reproduction information is output by performing decompression processing by the decompression means, and the reproduction information obtained by the decompression means is subjected to a method different from the first compression processing means by the second compression processing means. To generate the second compressed information, and the transmission signal output means, the first compressed information reproduced by the reproducing means and the second compression information generated by the second compression processing means. Information and Since it is embedded in a fixed format and output as a transmission signal, in a device that expands compressed information, expansion processing that emphasizes information quality and expansion that emphasizes miniaturization of hardware scale are performed. It is possible to select to perform processing.

According to the compressed information recording / reproducing apparatus of the present invention, independent control information is added to each of the first compressed information and the second compressed information and output. In addition to the effect of the compressed information recording / reproducing device according to claim 6, the device for inputting and processing the transmission signal output from the compressed information recording / reproducing device independently processes the first compressed information and the second compressed information. This has the effect of making it possible to

Further, according to the compressed information recording / reproducing apparatus of the ninth aspect, the change of the reproduction information is performed by the special reproduction processing means included in the decompression means during the special reproduction at a reproduction speed different from the reproduction speed during the normal reproduction. Since the smoothing process is performed, in addition to the effect of the compressed information recording / reproducing device according to claim 6, the transmission signal output from the compressed information recording / reproducing device is input to process the second compressed information. In such a device, it is not necessary to perform a process for smoothing the change of the reproduction information at the time of the special reproduction, so that the hardware scale can be reduced.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of an image compression encoding device according to a first embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a compressed image recording / reproducing apparatus according to a second embodiment of the present invention.

FIG. 3 is a block diagram showing a configuration of a special reproduction processing circuit in the BRR decoder in FIG. 2;

FIG. 4 is an explanatory diagram for explaining an operation of a simple compression unit in FIG. 1 or FIG. 2;

FIG. 5 is an explanatory diagram conceptually showing an operation of a data I / F packing control unit in FIG. 1 or FIG. 2;

FIG. 6 is a diagram for describing a storage state of compressed image data and simplified compressed image data when an SDDI format is used as an example of an I / F signal format according to the first or second embodiment of the present invention; FIG.

FIG. 7 is an explanatory diagram for describing an example of a special reproduction process by the special reproduction processing circuit shown in FIG. 3;

FIG. 8 is a block diagram illustrating a configuration of a general image compression encoding apparatus.

FIG. 9 is a block diagram illustrating a configuration of a general compressed image recording / reproducing apparatus.

FIG. 10 is a block diagram illustrating a configuration of a general compressed image decoding device.

11 is a block diagram illustrating an example of a configuration of a BRR encoder in FIG. 8 or FIG.

FIG. 12 is a block diagram showing an example of a configuration of a BRR decoder in FIG. 9 or FIG.

[Explanation of symbols]

10 input video signal, 11 BRR encoder, 12
... simple compression unit, 13 ... data I / F packing control unit,
14 ... I / F signal

Claims (9)

[Claims] 1. A compressed information output device for incorporating compressed information into a predetermined format and outputting it as a transmission signal, wherein the first compressed information obtained by performing a first compression process on information to be transmitted. And a second compression information obtained by performing a second compression process on the information to be transmitted by a method different from the first compression process, into a predetermined format, and output the transmission signal as a transmission signal. Means for outputting compressed information, comprising: 2. The transmission signal means is capable of independently processing the first compressed information and the second compressed information in an apparatus for inputting and processing a transmission signal output from the transmission signal means. The compression information output device according to claim 1, wherein independent control information is added to each of the first compression information and the second compression information and output. 3. A first compression processing means for performing first compression processing on information to be transmitted to generate first compression information, and said first compression processing on information to be transmitted. Second compression processing means for performing second compression processing by a method different from the means to generate second compression information; first compression information generated by the first compression processing means; Generated by the compression processing means
Transmission signal output means for incorporating the compressed information into a predetermined format and outputting the transmission information as a transmission signal. 4. The second compression processing means generates second compression information which enables simpler decompression processing than the first compression information generated by the first compression processing means. The information compression apparatus according to claim 3, wherein the information compression is performed. 5. The transmission signal means is capable of independently processing the first compressed information and the second compressed information in an apparatus for inputting and processing a transmission signal output from the transmission signal means. 4. The information compression apparatus according to claim 3, wherein independent control information is added to each of the first compression information and the second compression information and output. 6. First compression processing means for performing first compression processing on input information to generate first compression information, and first compression information generated by the first compression processing means. A recording unit for recording the first compressed information recorded on the recording medium, a decompression process for the first compressed information reproduced by the reproducing unit, Decompression means for outputting reproduction information; and performing second compression processing on the reproduction information obtained by the decompression means using a method different from that of the first compression processing means to generate second compression information. A second compression processing unit, and the first compression information reproduced by the reproduction unit and the second compression information generated by the second compression processing unit are incorporated into a predetermined format and output as a transmission signal. Transmission signal Compressed information recording and reproducing apparatus is characterized in that a force means. 7. The second compression processing means generates second compression information that allows simpler decompression processing than the first compression information generated by the first compression processing means. 7. The compressed information recording / reproducing apparatus according to claim 6, wherein: 8. The transmission signal means is capable of independently processing the first compressed information and the second compressed information in a device for inputting and processing the transmission signal output from the transmission signal means. 7. The compressed information recording / reproducing apparatus according to claim 6, wherein independent control information is added to each of the first compressed information and the second compressed information and output. 9. The apparatus according to claim 1, wherein said decompression means includes a special reproduction processing means for performing a process for smoothing a change in reproduction information during special reproduction at a reproduction speed different from the reproduction speed at normal reproduction. Item 7. A compressed information recording / reproducing apparatus according to Item 6.