JP2006202474A - Recorder - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To record data in a recording medium at high speed and to reproduce the recorded data during recording. <P>SOLUTION: AV data reproduced at N-fold speed and supplied at high speed from a data supply source 1 is stored as non-compressed data 22 in a temporary storage device 5 through a path 2, a system bus 3 and a path 21 with a data format as it is. The stored non-compressed data 22 are processed in a period when a compression-ciphering/decompression-deciphering apparatus 6 can be used, and stored as compressed data 18. On the other hand, corresponding non-compressed data 22 which becomes unnecessary is deleted. The compression-ciphering/decompression-deciphering apparatus 6 has a compression-ciphering part 7, a decompression-deciphering part 8 and a bypass 24 which does not pass through the decompression-deciphering part 8. During recording, optional compressed data 18 stored in a storage device 5 or data recorded presently itself can be reproduced. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a recording apparatus for audio data and / or video data, for example.

  Audio and / or video data (hereinafter simply referred to as AV data) from a data supply source can be recorded on a hard disk device of a personal computer (personal computer) and output from the hard disk device. FIG. 5 shows an example of such a recording / reproducing apparatus. In FIG. 5, reference numeral 1 denotes a data supply source such as a CD (Compact Disc) -ROM drive. For example, CD-DA (Digital Audio) is reproduced by the CD-ROM drive, and audio data can be reproduced. Not only the CD-ROM drive but also a CD player may be used as the data supply source 1. AV data from the data supply source 1 is supplied to the system bus 3 via the path 2.

  A CPU 4, a storage device (for example, a hard disk device) 5, and a compression / encryption / decompression / decryption device 6 are connected to the system bus 3. This configuration is realized by a general personal computer, and the whole or a part of the compression / encryption / decompression / decryption device 6 may be realized by software. The CPU 4 controls data transfer, write / read operations of the storage device 5, operations of the compression / encryption / decompression / decryption device 6, and the like.

  The compression / encryption / decompression / decryption device 6 includes a compression / encryption unit 7 and an expansion / decryption unit 8. The compression / encryption unit 7 compresses and encodes the AV data received from the system bus 3 via the path 13 and encrypts the compressed data. The compressed and encrypted data is output to the system bus 3 via the path 14.

  The storage device 5 stores compressed / encrypted data (hereinafter simply referred to as compressed data) 18 input from the system bus 3 via the path 17. In addition, the compressed data 18 is output to the system bus 3 via the path 19. By storing the compressed data in the storage device 5, the storage capacity of the storage device 5 can be used effectively. Further, by storing the encrypted data, it is possible to protect the copyright of the AV data.

  The decompression / decryption unit 8 receives the compressed data 18 from the storage device 5 via the system bus 3 and the path 15 and performs decryption of encryption and decompression of compression. The decrypted and decompressed data is sent to the system bus 3 via the path 16. Further, the AV data decoded and expanded by the expansion / decoding unit 8 is supplied to the D / A converter 10 via the path 9. The audio signal converted from digital to analog by the D / A converter 10 is taken out to the analog output unit 12.

  When recording AV data from the data supply source 1 in the storage device 5 (data supply source 1 → path 2 → system bus 3 → path 13 → compression / encryption unit 7 → path 14 → system bus 3 → path 17 → Data flows along the path of the storage device 5) and the compressed data 18 is stored in the storage device 5. When the compressed data 18 stored in the storage device 5 is reproduced (storage device 5 → path 19 → system bus 3 → path 15 → decompression / decoding unit 8 → path 9 → D / A converter 10 → analog output) Data flows along the route of section 12).

  The above-described recording / reproducing system has a problem that AV data from the data supply source 1 cannot be recorded at high speed. Since a CD player, a CD-ROM drive, a DVD (Digital Versatile Disc or Digital Video Disc) drive and the like can perform N-times high-speed data transfer, the data supply source 1 does not become a bottleneck in realizing high-speed recording. Further, the path such as the path 2 and the system bus 3 can operate at high speed. Furthermore, since the recording speed of the storage device 5 is sufficiently high, there is no problem. The problem is that the processing capability of the compression / encryption / decompression / decryption device 6 is low. This becomes a bottleneck in realizing high-speed recording, and the processing performance of the entire system depends on the apparatus 6.

  In order to enable high-speed recording of the system, a high-performance compression / encryption / decompression / decryption device 6 is required. However, in general, data compression / encryption requires complicated arithmetic processing, and it is difficult to increase the speed, and a high-speed device is expensive.

  In the compression / encryption / decompression / decryption device 6, the compression / encryption unit 7 and the decompression / decryption unit 8 usually share a part of the circuit, so that both can operate simultaneously. Can not. As a result, there is a problem that any data stored in the storage device 5 cannot be expanded / decrypted during data recording.

  Therefore, the object of the present invention is to enable high-speed recording regardless of the processing performance of data compression / encryption, and to store different data stored simultaneously with data compression / encryption recording. It is an object to provide a recording apparatus and a recording / reproducing apparatus capable of reproducing data.

In order to solve the above-described problems, the present invention provides:
An input means for inputting an uncompressed signal;
A recording means for recording an uncompressed signal on a storage medium at a speed faster than the speed reproduced at a single speed;
Reading means for reading the uncompressed signal from the storage medium;
Compression means for compressing an uncompressed signal recorded in a storage medium and generating a compressed signal;
Control means for controlling the recording means to record the uncompressed signal input from the input means on the storage medium, and
The control means
The reading means reads the uncompressed signal from the storage medium, the compression means compresses the uncompressed signal recorded on the storage medium to generate a compressed signal, and the recording means is controlled to record the compressed signal on the storage medium. The recording apparatus characterized by the above.

  According to the present invention, high-speed recording can be achieved even when a low-speed compression / decompression apparatus is used by recording non-compressed data on a recording medium at a speed higher than the speed reproduced at a single speed. In the present invention, since compression processing is not performed during recording, reproduction can be performed simultaneously with recording even when only one compression / decompression apparatus is provided.

  Hereinafter, an embodiment of the present invention will be described. In one embodiment, the present invention is applied to a system similar to that shown in FIG. That is, AV data from the data supply source 1 is recorded in, for example, a storage device 5 (for example, a hard disk device) of a personal computer, and is output from the storage device 5. The data supply source 1 is a CD-ROM drive, a CD player, a DVD drive, or the like. By reproducing the CD-DA at N times speed (24 times speed, 48 times speed, etc.) by the CD-ROM drive, AV data is supplied to the system bus 3 through the path 2 at high speed. The data supply source 1 may be a receiving unit that receives data transmitted via a network, such as a music distribution system, instead of a recording medium playback device. Furthermore, the data supply source 1 may be composed of a plurality of input devices such as the drive and the receiving unit, and a selection unit that controls one of them.

  A CPU 4, a storage device 5, a compression / encryption / decompression / decryption device 6, an operation unit 13 and a display unit 14 are connected to the system bus 3. The CPU 4 follows the program and receives an operation signal from the operation unit 13 to transfer data, write / read operations of the storage device 5, operations of the compression / encryption / decompression / decryption device 6, and the display unit 14. Controls display operation and the like. The operation unit 13 is a keyboard, a switch, a GUI, or the like operated by the user. When the user operates the operation unit 13, an operation (recording operation, reproduction operation, etc.) is designated, and data to be recorded / reproduced is designated. The display unit 14 displays an operation state, data to be recorded / reproduced, and the like. The configuration of FIG. 1 is realized by a general personal computer, and the compression / encryption / decompression / decryption device 6 may be entirely or partially realized by software.

  The compression / encryption / decompression / decryption device 6 includes a compression / encryption unit 7 and an expansion / decryption unit 8, and the compression / encryption unit 7 receives from the system bus 3 via the path 13. The AV data is compressed and encoded, the compressed data is encrypted, and the compressed and encrypted data is output to the system bus 3 via the path 14.

  The decompression / decryption unit 8 receives the compressed data 18 via the system bus 3 and the path 15 and performs decryption of encryption and decompression of compression. The decrypted and decompressed data is sent to the system bus 3 via the path 16. Further, the AV data decoded and expanded by the expansion / decoding unit 8 is supplied to the D / A converter 10 via the path 9. The audio signal converted from digital to analog by the D / A converter 10 is taken out to the analog output unit 12.

  In one embodiment, a path (referred to as a bypass) 24 that does not pass through the decompression / decryption unit 8 is provided inside or outside the compression / encryption / decompression / decryption device 6. AV data that has passed through the bypass 24 is supplied to the D / A converter 10 via the path 9. The D / A converter 10 is selectively supplied with the output of the expansion / decoding unit 8 and the data that has passed through the bypass 24. This selection is controlled by the CPU 4.

  In the storage device 5, AV data input from the system bus 3 via the path 17 is temporarily stored as uncompressed data 22, and thereafter, compressed data 18 is stored. In addition, the compressed data 18 is output to the system bus 3 via the path 19. By storing the compressed data in the storage device 5, the storage capacity of the storage device 5 can be used effectively. Further, by storing the encrypted data, it is possible to protect the copyright of the AV data.

  As AV data compression methods, when the AV data is audio data, ATRAC (Adaptive Transfer Acoustic Coding), MP3 (MPEG1 Audio Layer III), etc. can be used. When the AV data is video data, MPEG or the like can be used. Can be used. For example, when ATRAC is used, data can be compressed to 1/10 or less. As an encryption method, scrambling, DES (Data Encryption Standard), embedding of digital watermark information, or the like can be used.

  AV data from the data supply source 1 is, for example, blocked in units of specified capacity, and the compression / encryption unit 7 performs compression in units of blocks. When ATRAC is used as compression encoding of audio data, the amount of data compressed by ATRAC or audio data of an integral multiple thereof is made one block. In the case of video data, when MPEG is used for compression encoding, one video frame or an integral multiple of the data is made one block. The sizes of these blocks are merely examples, and various sizes can be set.

  In this embodiment, non-compressed data 22 that is not compressed / encrypted other than the compressed data 18 is stored in the storage device 5. Uncompressed data is stored in the storage device 5 via the system bus 3 and the path 21, and is output to the system bus 3 via the path 23. That is, the AV data supplied from the data supply source 1 is temporarily stored as uncompressed data 22 in the storage device 5 through the path 2, the system bus 3, and the path 21 in the same data format.

  In this way, the AV data from the data supply source 1 is recorded as uncompressed data in the storage device 5, and therefore does not pass through the compression / encryption / decompression / decryption device 6. As a result, high-speed recording is possible by making full use of the capability of the data supply source 1. Also, it is not necessary to use a compression / encryption / decompression / decryption device 6 capable of high-speed processing (generally expensive).

  Recording uncompressed data in the storage device 5 causes problems in terms of reduction in use efficiency of storage capacity and copyright protection. The problem is that the data from the data supply source 1 is transferred to the storage device 5, the non-compressed data 22 is temporarily stored in the storage device 5, and finally the compressed data 18 that has been compressed / encrypted is stored. It is solved by memorizing. That is, the non-compressed data 22 once stored in the storage device 5 is processed at a time when the compression / encryption / decompression / decryption device 6 can be used, and is stored as the compressed data 18, while the non-compressed data 22 that is no longer needed. The compressed data 22 is completely deleted.

  Since the compression / encryption process and the uncompressed data deletion process can be performed in the background at a time when the system load is low, the response speed of the process selected by the user is not affected. In one embodiment, when non-compressed data is compressed / encrypted in this way and the resulting compressed data is stored in the storage device 5, the corresponding uncompressed data is deleted (erased) from the storage device 5. The The recording of the compressed data and the deletion of the corresponding non-compressed data are performed for each predetermined data amount such as a block unit or a file unit.

  In the embodiment, only one compression / encryption / decompression / decryption device 6 is provided. Nevertheless, even when data is recorded, the data being recorded is stored in the storage device 5. It is possible to reproduce any compressed data 18 that has been recorded.

  When storing uncompressed data in the storage device 5, the attribute data as shown in FIG. 2 is added by the CPU 4 for each file of the uncompressed data, and the attribute data and the uncompressed data are stored in the storage device 5 as the uncompressed data 22. Is done. In FIG. 2, 22a is a file of uncompressed data (AV data), and 22b is attribute data added for each file. In the case of audio data, one song is often associated with one file. In the case of video data, one image is associated with one file if it is a still image, and in the case of a movie, a series of movies from the start of shooting to the end of shooting is associated with one file. There are many. The attribute data 22b includes a data size 31, a file name 32, a read permission flag 33, and the like. The attribute data 22b is used for controlling the reading of data from the storage device 5.

  The data size 31 indicates the file size of uncompressed data. The file name 32 is a file name of an uncompressed data file given from the data supply source 1. The file name 32 is not limited to the one given by the CPU 4 but can be given by a user operation. Further, in addition to specifying the file by the file name, it is possible to distinguish between compression and non-compression. The read permission flag 33 is a flag indicating whether or not uncompressed data can be read from the storage device 5. When the flag 33 indicates read permission, the uncompressed data 22 can be read from the storage device 5. On the other hand, when the flag 33 indicates that reading is not permitted, reading is permitted only for compression / encryption by the compression / encryption unit 7. Note that attribute data such as a data size and a file name is also added to the compressed data 18. The attribute data is stored in the storage device 5 as file management information.

  An embodiment of the present invention will be described in more detail with reference to the flowcharts of FIGS. FIG. 3 shows the flow of processing when AV data is recorded at a high speed and at the same time the recorded AV data is reproduced at a normal speed. FIG. 4 shows the flow of processing when reproducing other AV data (compressed data) while AV data is being recorded at high speed. The processing shown in these flowcharts is control performed by the CPU 4.

  Regarding the processing of FIG. 3, the flow of processing on the recording side will be described first. The first AV data (first file) is supplied from the data supply source 1 (step S1), and the data is transferred to the storage device 5 through the path 2 and the system bus 3 at N times speed (step S2). . In step S <b> 3, the uncompressed data 22 is stored in the storage device 5. In this case, the uncompressed data has a block unit delimiter.

  In the next step S4, it is determined whether another AV data exists. If it is determined in step S4 that another AV data exists, the data supply source 1 is switched so that another AV data is output in step S5. For example, the drive is controlled to play another song (track) on the CD.

  In step S6, the n (= 2) th input AV data is supplied from the data supply source 1, and the data is transferred to the storage device 5 through the path 2 and the system bus 3 at N times speed (step S7). In step S <b> 8, the uncompressed data 22 is stored in the storage device 5. Then, the process returns to step S4 for determining whether or not another AV data exists. If there is AV data to be recorded, the same recording process as described above is repeated. Attribute data is added to the non-compressed data 22 recorded in the storage device 5, and a read permission flag 33 in the attribute data is set to indicate that reading is permitted or not permitted. For example, reading only once is permitted, and reading after the second time is not permitted.

  As described above, since the process of recording uncompressed AV data does not require the process of the compression / encryption / decompression / decryption device 6, high-speed recording is possible by making full use of the ability of the data supply source 1. It becomes. Further, as the compression / encryption / decompression / decryption device 6, an inexpensive device with low speed processing can be used.

  Next, uncompressed data 22 is read from the storage device 5 in step S9. The read uncompressed data is supplied to the compression / encryption unit 7 via the path 23, the system bus 3, and the path 13, and subjected to compression and encryption processing (step S10). Then, the compressed data 18 is stored in the storage device 5 through the path 14, the system bus 3 and the path 17. The read permission flag in the attribute data added to the compressed data 18 indicates read permission. In step S12, compression / encryption processing is performed, and the same uncompressed data file as the data stored in the storage device 5 is deleted. This completes the high-speed recording process. The compression / encryption process (step S10) and the uncompressed data deletion process (step S12) are performed in the background when the system load is low.

  In parallel with the high-speed recording process described above, recorded AV data can be reproduced. The processing on the reproduction side will be described. In step S21, uncompressed data 22 is read from the storage device 5 asynchronously with the recording of AV data in the storage device 5. The uncompressed data 22 is read at a normal speed. The normal speed is relative to the speed (high speed) of the data source 1. For example, the rate of audio data when a CD-DA is reproduced at a normal speed is the normal speed as in a normal CD player. When the AV data is written to the storage device 5 at high speed, while the uncompressed data 22 is read asynchronously, the speed difference between the writing speed and the reading speed is absorbed by the storage device 5.

  The read uncompressed data is transferred at a normal speed (step S22). In step S23, AV data is reproduced. That is, the read uncompressed data is reproduced in the path of (path 23 → system bus 3 → bypass 24 → path 9 → D / A converter 10 → path 11 → output unit 12). Thus, the compression / encryption / decompression / decryption device 6 is bypassed and its function is not used. Therefore, step S10 (AV data compression and encryption) at the time of high-speed recording can be performed without any trouble.

  With reference to FIG. 4, a process for reproducing other AV data (compressed data) while AV data is being recorded at high speed will be described. The high-speed recording process of AV data is the same as that shown in FIG. 3, and the corresponding steps are denoted by the same reference numerals and the description thereof is omitted.

  On the reproduction side, the compressed data 18 is read from the storage device 5 in step S25. The compressed data is supplied to the decompression / decryption unit 8 in the compression / encryption / decompression / decryption device 6 via the path (path 19 → system bus 3 → path 15), and decryption of encryption is performed. Then, compression encoding is expanded (step S26). The AV data obtained by the decoding and decompression processing is output to the output unit 12 at the normal speed via the path (path 9 → D / A converter 10 → path 11) (step S27). In this way, AV data is reproduced (step S28).

  Since the compression / encryption / decompression / decryption device 6 is used in the reproduction process, the processes in steps S9, S10, S11 and S12 (AV data compression and encryption and deletion of the corresponding uncompressed data) are performed. The process waits until the apparatus 6 becomes usable (until the reproduction is completed) (step S13). When the compression / encryption / decompression / decryption device 6 is released in step S13, step S9 (reading of uncompressed data), step S10 (compression and encryption of AV data), step S11 (to the storage device 5). ), And the processing up to step S12 (deletion of uncompressed data) is executed.

  As can be seen from the processing shown in the flowchart of FIG. 4, unlike the AV data during high-speed recording, any compressed data 18 stored in the storage device 5 can be reproduced simultaneously with high-speed recording.

  Furthermore, in the process shown in FIG. 4, the read permission flag in the attribute data is used to prohibit reading of non-compressed data from the storage device 5 other than that used for compression, thereby being used for compression. It may be prohibited to read uncompressed data from the storage device 5 for other purposes.

  In one embodiment, compression and encryption processing and decompression and decryption processing are performed. However, it is not always necessary to perform encryption and decryption processing. The present invention can also be applied to recording / reproduction of digital data such as computer software in addition to AV data. Furthermore, in the present invention, a semiconductor memory such as a flash memory can be used as the storage device 5 in addition to the hard disk.

1 is a block diagram illustrating a configuration of an entire system according to an embodiment of the present invention. It is an approximate line figure for explaining attribute data in one embodiment of this invention. 3 is a flowchart for explaining an example of a recording and reproducing operation according to an embodiment of the present invention. It is a flowchart for demonstrating the other example of the recording and reproduction | regeneration operation | movement in one Embodiment of this invention. 1 is a block diagram of an example of a recording / reproducing system for explaining the present invention.

Explanation of symbols

1 ... Data supply source 3 ... System bus 4 ... CPU
5 ... Storage device 6 ... Compression / encryption / decompression / decryption device 7 ... Compression / encryption unit 8 ... Decompression / decryption unit 18 ... Compressed data 22 ... Uncompressed data

Claims (7)

An input means for inputting an uncompressed signal;
Recording means for recording the uncompressed signal on the storage medium at a speed faster than the speed reproduced at the normal speed;
Reading means for reading the uncompressed signal from the storage medium;
Compression means for compressing the uncompressed signal recorded in the storage medium to generate a compressed signal;
Control means for controlling the recording means to record an uncompressed signal input from the input means on the storage medium,
The control means includes
The reading unit reads the uncompressed signal from the storage medium, the compression unit compresses the uncompressed signal recorded on the storage medium to generate the compressed signal, and the recording unit stores the uncompressed signal on the storage medium. A recording apparatus that controls to record a compressed signal.   2. The recording apparatus according to claim 1, wherein the non-compressed signal recorded on the storage medium is erased when the compressed signal is recorded on the storage medium. The reading means reads the compressed signal recorded on the storage medium,
2. The recording apparatus according to claim 1, wherein the control means controls to read out the compressed signal recorded in the storage medium. Decompression means for decompressing the compressed signal recorded on the storage medium to generate a reproduction signal;
Replay means for replaying the replay signal, and
While the control means records the uncompressed signal input from the input means on the storage medium by the recording means, the reading means reads another compressed signal stored in the storage medium, 2. A recording apparatus according to claim 1, wherein said expansion means generates a reproduction signal from said another compressed signal, and said reproduction means controls to reproduce said reproduction signal. The control means includes
The reading means reads the uncompressed signal from the storage medium when the system load is low, the compression means compresses the uncompressed signal recorded on the storage medium to generate the compressed signal, and the recording means The recording apparatus according to claim 1, wherein the recording apparatus controls the compressed signal to be recorded on the storage medium. Reproducing means for reproducing the uncompressed signal recorded in the recording means,
The control means includes
The non-compressed signal input from the input means is recorded on the storage medium by the recording means, and the non-compressed signal recorded on the storage medium is read and reproduced from the output means. The recording apparatus according to 1. The control means controls the uncompressed signal input from the input means to be recorded on the storage medium by the recording means at a speed higher than the processing speed compressed by the compression means. 6. The recording device according to 6.

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