JPH0590972A - Compressed data recording and reproducing device - Google Patents

Abstract

PURPOSE:To attain high speed dubbing by recording digital data of a variable bit rate obtained by eliminating part of bits giving a quantization noise level not perceived audibly to a recording medium. CONSTITUTION:ATC audio data obtained from compression processing by an adaptive conversion coding (ATC) encoder 63 are fed to a residue bit reduction circuit device 84 being one type of variable bit rate coder via, e.g. a RAM 85, in which bit reduction giving noise less than a masking threshold level is implemented. That is, compression coding data with a prescribed bit rate recorded on a magneto-optical disk 1 are reproduced and the result is fed to the residue bit reduction circuit device 84 without implementing compression decoding processing, in which bit parts giving a quantization noise level less than the audible redundant part such as the masking threshold level is reduced and then the data are subject to compression coding at a prescribed rate or a variable bit rate and the result is recorded on an IC card 2.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compressed data recording / reproducing apparatus in which a digital audio signal or the like is bit-compressed, and in particular, data is transferred and recorded between a constant bit rate recording medium and a variable bit rate recording medium. And a compressed data recording / reproducing apparatus.

[0002]

2. Description of the Related Art The applicant of the present invention has previously disclosed a technique for bit-compressing an input digital audio signal and burst-recording a predetermined data amount as a recording unit, for example, Japanese Patent Application No. Hei 2-221364. , Japanese Patent Application No. 2-22136
5, Japanese Patent Application No. 2-222821, Japanese Patent Application No. 2-2228
No. 23 specification, drawings, etc.

This technique uses a magneto-optical disk as a recording medium, and records and reproduces AD (adaptive difference) PCM audio data defined in audio data formats of so-called CD-I (CD-interactive) and CD-ROM XA. For example, 32 sectors of this ADPCM data and several sectors for linking for interleaving processing are recorded as a recording unit on the magneto-optical disk in a burst manner.

Several modes can be selected for the ADPCM audio in the recording / reproducing apparatus using this magneto-optical disk. For example, a level A having a compression rate twice as high as that of the reproducing time of a normal CD. 4 times level B,
Eight times the level C is specified. That is, for example, in the case of the level B, the digital audio data is compressed to about 1/4, and the reproduction time (play time) of the disc recorded in the level B mode is the standard CD format (CD -DA format). This is a smaller disc, standard 12c
Since a recording / reproducing time as high as m can be obtained, the device can be downsized.

However, the rotation speed of the disk is standard C
Since it is the same as D, for example, in the case of the above level B, compressed data for a reproduction time four times as long as the predetermined time can be obtained. For this reason, for example, the same compressed data is read out four times in a time unit such as a sector or a cluster, and only the compressed data for one time is sent to the audio reproduction. Specifically, when scanning (tracking) a spiral recording track,
The reproduction operation is advanced in such a form that a track jump is performed to return to the original track position for each rotation, and the same track is repeatedly tracked four times. This means that normal compressed data needs to be obtained at least once out of, for example, four times of redundant reading, is resistant to errors due to disturbances, etc., and is particularly preferable when applied to a portable small device.

Further, in the future, it is considered to use a semiconductor memory as a recording medium, and in order to further improve the compression efficiency, compression encoding by a variable bit rate such as so-called entropy encoding is used. Specifically, the so-called IC card is used to record and reproduce an audio signal. For this IC card,
The compressed data bit-compressed at a variable bit rate is recorded and reproduced.

IC cards and the like using such a semiconductor memory are expected to have an increase in recording capacity and a reduction in price with the progress of semiconductor technology, but at the initial stage when they are supplied to the market. It is thought that the capacity is low and expensive. Therefore, it is sufficiently conceivable to transfer the contents from another inexpensive and large-capacity recording medium such as the above-mentioned magneto-optical disk to an IC card or the like for frequent rewriting and use. Specifically, for example, of the plurality of songs recorded on the magneto-optical disk, a favorite song is dubbed to an IC card, and when it is no longer needed, it is replaced with another song. In this way, by frequently rewriting the contents of the IC card, it is possible to enjoy various songs outdoors with a small number of IC cards on hand.

[0008]

By the way, for example, the music recorded on the magneto-optical disk is reproduced to reproduce the IC.
When it comes to dubbing into a card, the price per unit bit of the IC card is very expensive as compared with the price per unit bit of the magneto-optical disk. Therefore, when dubbing to the IC card, it is desirable to further compress information in addition to high efficiency coding on the magneto-optical disk.

In addition, for example, in the case where some of the plurality of songs recorded on the magneto-optical disk are to be dubbed to the IC card, in addition to the high efficiency code on the magneto-optical disk, Further, when the information is compressed, the bit rate changes depending on the content, and the data amount may differ even for the same reproduction time. Therefore, the data amount in the magneto-optical disk and the data amount in the IC card are different from each other. It can be different. For this reason, the number of songs that can be recorded on the IC card, the optimal combination of songs, and the like cannot be immediately known before recording, and it is possible to record only halfway through the song or to effectively use the remaining portion. Sometimes.

Further, when performing such dubbing, if the compressed data from the magneto-optical disk is decoded and returned to the original reproduction time, it is encoded with a variable bit rate high efficiency code and recorded in the IC card. , It takes the same time as the normal playback (actual performance time), and higher-speed dubbing is desired.

The present invention has been made in view of the above circumstances, and when the data which is bit-compressed at a constant bit rate and recorded is compressed at a fixed or variable bit rate and written to an IC card or the like. In addition, the amount of information that can be heard visually is reduced to reduce the amount of information, and when writing to an IC card or the like at a variable bit rate, the writable data amount can be instantly confirmed, and high-speed writing is possible. An object of the present invention is to provide a possible compressed data recording / reproducing apparatus.

[0012]

A compressed data recording / reproducing apparatus according to the present invention is a compressed data recording / reproducing apparatus having a compressed data recording system for recording an information signal on a recording medium as bit-compressed digital data. A variable bit rate digital data is obtained by removing some of the bits that give a quantization noise level that is not perceptually perceptible during the bit compression process, and the variable bit rate digital data is recorded on the recording medium. The above-mentioned problem is solved by.

The compressed data recording / reproducing apparatus according to the present invention comprises a compressed data reproducing system for reproducing at least digital data from one recording medium which is bit-compressed at a constant bit rate and recorded, and a fixed or variable bit rate. And a compressed data recording system for recording at least digital data on another recording medium which is bit-compressed and recorded by continuous reproduction of the compressed data recorded on the one recording medium of the reproducing system for masking. The above problem is solved by reducing the number of bits that give a quantization noise level below the threshold, and sending the quantization noise level to the recording system for recording on another recording medium.

At this time, without decompressing the compressed data, bits that give a quantization noise level lower than the masking threshold are deleted as they are, and then sent to the recording system and fixed or variable bit rate to the other recording medium. It is desirable to bit-compress and record in order to reduce the hardware scale and increase the compression rate.

Here, not only the data bit-compressed at the constant bit rate but also the constant bit rate compressed data is bit-compressed at the variable bit rate on the other recording medium in the one recording medium. It is preferable to record the data amount information of. Further, it is preferable that not only the variable bit rate compressed data but also data amount information at the time of bit compression recording at a constant bit rate on the one recording medium is recorded on the other recording medium.

[0016]

The compressed data recorded on the one recording medium is reduced in the number of bits that give a quantization noise level below the masking threshold and then sent to the recording system of the other recording medium. Data can be transferred. In addition, by looking at the data amount information at the time of variable bit rate compression recorded on the one recording medium, the data capacity required for recording on the other recording medium can be quickly confirmed, and the recordable song You can easily know the optimal combination of numbers and songs. This is the same in the opposite case, that is, when recording from the other recording medium to the one recording medium.

[0017]

1 is a block circuit diagram showing a schematic configuration of an embodiment of a compressed data recording / reproducing apparatus according to the present invention. The recording / reproducing apparatus of FIG. 1 is configured by combining two units, a recording / reproducing unit of a magneto-optical disk 1 which is one recording medium and a recording unit of an IC card 2 which is another recording medium, into one system. Has been done. When the signal reproduced by the reproducing system on the side of the magneto-optical disk recording / reproducing unit is recorded by the IC card recording unit, it is read by the optical head 53 from the magneto-optical disk 1 of the reproducing system and sent to the decoder 71. Reproduced compressed data that has been subjected to EFM demodulation, deinterleave processing, error correction processing, and the like, specifically, for example, ATC (Adaptive Transform Cod).
ing: adaptive conversion encoding) Audio data is sent to the memory 85 of the IC card recording unit, and this memory 85
Is subjected to variable bit rate coding processing by the surplus bit reduction circuit 84, and is recorded in the IC card 2 via the IC card interface circuit 86. In this way, the reproduced compressed data is sent to the recording system in the compressed state before being subjected to the decompression processing by the ATC decoder 73 which performs the above-mentioned ATC reverse processing, for example, and is subjected to variable bit rate coding to be subjected to the IC card 2 Recorded in. Here, instead of the IC card, various IC memories such as an IC memory cartridge and an IC memory pack may be used.

By the way, during normal reproduction (for audio listening), a predetermined data amount unit (for example, 3) is intermittently or bursted from the recording medium (magneto-optical disk 1).
Compressed data is read out in 2 sectors + several sectors and expanded to be converted into a continuous audio signal. At the time of so-called dubbing, the compressed data on the medium is continuously read and sent to the recording system. I am recording. This enables high-speed (short-time) dubbing according to the data compression rate.

The specific configuration of FIG. 1 will be described in detail below. In the magneto-optical disk recording / reproducing unit of the compressed data recording / reproducing apparatus shown in FIG. 1, the magneto-optical disk 1 rotatably driven by the spindle motor 51 is used as the recording medium. At the time of recording data on the magneto-optical disk 1, so-called magnetic field modulation recording is performed by applying a modulation magnetic field according to the recording data with the magnetic head 54 while irradiating the optical head 53 with laser light. Data is recorded along the recording track of. At the time of reproduction, the recording track of the magneto-optical disk 1 is traced with laser light by the optical head 53 to perform magneto-optical reproduction.

The optical head 53 includes, for example, a laser light source such as a laser diode, a collimator lens, an objective lens,
It is composed of a polarization beam splitter, an optical component such as a cylindrical lens, and a photodetector having a light receiving portion of a predetermined pattern. The optical head 53 is provided at a position facing the magnetic head 54 via the magneto-optical disk 1. When recording data on the magneto-optical disk 1, a magnetic head 54 is driven by a head drive circuit 66 of a recording system to be described later to apply a modulation magnetic field according to the recording data, and at the same time, the optical head 53 is used for the purpose of the magneto-optical disk 1. Thermomagnetic recording is performed by a magnetic field modulation method by irradiating the track with laser light. The optical head 53 also detects the reflected light of the laser light applied to the target track, detects a focus error by, for example, a so-called astigmatism method, and detects a tracking error by, for example, a so-called push-pull method. When reproducing data from the magneto-optical disk 1, the optical head 53 detects the focus error and the tracking error, and at the same time, detects the difference in the polarization angle (Kerr rotation angle) of the reflected light from the target track of the laser light and reproduces it. Generate a signal.

The output of the optical head 53 is supplied to the RF circuit 55. The RF circuit 55 extracts the focus error signal and the tracking error signal from the output of the optical head 53 and supplies the focus error signal and the tracking error signal to the servo control circuit 56, and binarizes the reproduction signal to reproduce the reproduction system decoder 7 to be described later.
Supply to 1.

The servo control circuit 56 is composed of, for example, a focus servo control circuit, a tracking servo control circuit, a spindle motor servo control circuit, and a sled servo control circuit. The focus servo control circuit controls the focus of the optical system of the optical head 53 so that the focus error signal becomes zero. Further, the tracking servo control circuit controls the tracking of the optical system of the optical head 53 so that the tracking error signal becomes zero. Further, the spindle motor servo control circuit controls the spindle motor 51 so as to rotate the magneto-optical disk 1 at a predetermined rotation speed (for example, a constant linear speed). Further, the sled servo control circuit moves the optical head 53 and the magnetic head 54 to the target track position of the magneto-optical disk 1 designated by the system controller 57. The servo control circuit 56 that performs such various control operations sends information indicating the operating state of each unit controlled by the servo control circuit 56 to the system controller 57.

A key input operation section 58 and a display section 59 are connected to the system controller 57. The system controller 57 controls the recording system and the reproducing system in the operation mode designated by the operation input information from the key input operation unit 58. Further, the system controller 7 uses the optical head 53 and the magnetic head 54 based on the address information in sector units reproduced from the recording track of the magneto-optical disk 1 by the header time, the Q data of the subcode, or the like.
Manages a recording position and a reproducing position on the recording track traced by. Further system controller 57
Is the bit compression mode information in the ATC encoder 63, which will be described later, which is switched and selected by the key input operation unit 58, and R
The bit compression mode is displayed on the display unit 59 based on the bit compression mode information in the reproduction data obtained from the F circuit 55 through the reproduction system described later, and the data compression rate and the recording track in the bit compression mode are displayed. Based on the above reproduction position information, control is performed to display the reproduction time on the display unit 59.

This reproduction time display is based on the sector unit address information (absolute time information) reproduced from the recording track of the magneto-optical disk 1 by so-called header time or so-called sub-code Q data, and the data in the bit compression mode. By multiplying the reciprocal of the compression ratio (for example, 4 in the case of 1/4 compression), the actual time information is obtained and displayed on the display unit 9. Even at the time of recording, when absolute time information is recorded (pre-formatted) in advance on a recording track of a magneto-optical disk or the like, the pre-formatted absolute time information is read to determine the data compression rate. It is also possible to display the current position at the actual recording time by multiplying by the reciprocal.

Next, in the recording system of the recording / reproducing apparatus of this disk recording / reproducing apparatus, the analog audio input signal A _IN from the input terminal 60 is passed through the low pass filter 61 to A
The A / D converter 62 is supplied to the A / D converter 62, which quantizes the analog audio input signal A _IN . A /
The digital audio signal obtained from the D converter 62 is supplied to the ATC encoder 63. Further, the digital audio input signal D _IN from the input terminal 67 is supplied to the ATC encoder 63 via the digital input interface circuit 68. The ATC encoder 63 is
A bit compression (data compression) process corresponding to various modes in the above-described CD-I system is performed on digital audio PCM data of a predetermined transfer rate obtained by quantizing the input signal A _IN by the A / D converter 62. ,
The operation mode is designated by the system controller 57. For example, as a predetermined mode, compressed data having a sampling frequency of 44.1 kHz and an average number of bits per sample of 4 bits is used.
Consider the modes that are supplied to the four. The data transfer rate in this predetermined mode is 1/4 (18.7) of the data transfer rate (75 sectors / second) of the standard CD-DA format.
5 sectors / second).

In the embodiment shown in FIG. 1, the sampling frequency of the A / D converter 62 is, for example, the standard C mentioned above.
4 which is the sampling frequency of D-DA format
It is fixed to 4.1 kHz, and it is assumed that the ATC encoder 13 is subjected to bit compression processing from 16 bits to 4 bits after, for example, sampling rate conversion according to the compression mode is performed. is doing.
As another configuration example, the sampling frequency itself of the A / D converter 12 may be switching-controlled according to the compression mode. In this case, the switching-controlled A / D converter is used.
The cutoff frequency of the low-pass filter 61 is also switched and controlled according to the sampling frequency of the converter 12. That is, the sampling frequency of the A / D converter 62 and the cutoff frequency of the low-pass filter 61 may be simultaneously switched and controlled according to the compression mode. Also, even if you do not change the sampling frequency depending on the mode,
In the mode in which the used bits are small, the restriction on the frequency band may be strengthened.

Next, in the memory 64, writing and reading of data are controlled by the system controller 57,
It is used as a buffer memory for temporarily storing the ATC data supplied from the ATC encoder 63 and recording it on the disc as needed. That is, for example, in the above-described predetermined mode, the compressed audio data supplied from the ATC encoder 63 has a data transfer rate of ¼ of the standard CD-DA format data transfer rate (75 sectors / second), that is, 1
It is reduced to 8.75 sectors / second, and this compressed data is continuously written in the memory 14. This compressed data (ATC data) is 1 for every 4 sectors as described above.
Although it suffices to record the sectors, it is practically impossible to record every four sectors like this, so the sector continuous recording as described later is performed. This recording uses a cluster composed of a plurality of predetermined sectors (for example, 32 sectors + several sectors) as a recording unit for the same data transfer rate as the standard CD-DA format (7
It is carried out in bursts at 5 sectors / second). That is, in the memory 64, 1 according to the bit compression rate
The ATC audio data in the predetermined mode, which is continuously written at a low transfer rate of 8.75 (= 75/4) sectors / second, is burst-read as recording data at the transfer rate of 75 sectors / second. The overall data transfer rate of the read and recorded data, including the recording pause period, is as low as 18.75 sectors / sec described above, but within the time of the recording operation performed in bursts. The instantaneous data transfer rate in the above is the standard 75 sectors / sec. Therefore, when the disc rotation speed is the same as the standard CD-DA format (constant linear velocity), the same recording density and storage pattern as those of the CD-DA format are recorded.

The ATC audio data, that is, the recording data, which is read out in burst from the memory 64 at the (instantaneous) transfer rate of 75 sectors / second, is encoded by the encoder 65.
Is supplied to. Here, from the memory 64 to the encoder 65
In the data string supplied to the above, the unit of continuous recording in one recording is a cluster composed of a plurality of sectors (for example, 32 sectors) and several sectors for cluster connection arranged in the front and rear positions of the cluster. This cluster connection sector is set to be longer than the interleave length in the encoder 65, so that even if interleaved, it does not affect the data of other clusters.

The encoder 65 uses the recording data supplied from the memory 64 in bursts as described above,
Encoding processing for error correction (parity addition and interleave processing), EFM encoding processing, and the like are performed. The recording data encoded by the encoder 65 is supplied to the magnetic head drive circuit 66. The magnetic head drive circuit 66 is connected to the magnetic head 54, and drives the magnetic head 54 so as to apply the modulation magnetic field according to the recording data to the magneto-optical disk 1.

The system controller 57 controls the memory 64 as described above and, at the same time,
By this memory control, the recording position is controlled so as to continuously record the recording data read out in burst from the memory 64 on the recording track of the magneto-optical disk 2.
The recording position is controlled by controlling the recording position of the recording data which is burst-read from the memory 64 by the system controller 57 and outputting a control signal for designating the recording position on the recording track of the magneto-optical disc 1 to the servo control circuit. By feeding 56.

Next, the reproducing system of this magneto-optical disk recording / reproducing unit will be described. This reproducing system is for reproducing the record data continuously recorded on the recording track of the magneto-optical disk 1 by the above-mentioned recording system,
The decoder 71 is provided with a reproduction output obtained by tracing a recording track of the magneto-optical disk 1 with a laser beam by the optical head 53 and binarized and supplied by the RF circuit 55.

The decoder 71 corresponds to the encoder 65 in the above-mentioned recording system, and performs the above-mentioned decoding processing for error correction and EFM decoding on the reproduction output binarized by the RF circuit 55. The ATC audio data in the above-mentioned predetermined mode is
Playback is performed at a transfer rate of 75 sectors / second, which is faster than the normal transfer rate in the predetermined mode. The reproduced data obtained by the decoder 71 is supplied to the memory 72.

In the memory 72, writing and reading of data are controlled by the system controller 57, and reproduced data supplied from the decoder 71 at a transfer rate of 75 sectors / second is written in bursts at the transfer rate of 75 sectors / second. Be done. Further, in the memory 72, the reproduction data written in a burst at the transfer rate of 75 sectors / second is the normal 18.75 sectors / second in the predetermined mode.
It is read continuously at a transfer rate of seconds.

The system controller 57 writes the reproduced data in the memory 72 at a transfer rate of 75 sectors / second, and at the same time stores the reproduced data in the memory 72 at 18.7.
Memory control is performed so that data is continuously read at a transfer rate of 5 sectors / second. Further, the system controller 57 performs the above-mentioned memory control on the memory 72, and continuously reproduces the above-mentioned reproduction data written in a burst from the memory 72 from the recording track of the magneto-optical disk 1 by this memory control. Controls the playback position. This playback position is controlled by the system controller 5
This is performed by managing the reproduction position of the reproduction data read out from the memory 72 in bursts by means of 7 and supplying a control signal designating the reproduction position on the recording track of the magneto-optical disk 1 to the servo control circuit 56.

The ATC audio data in the above-mentioned predetermined mode as reproduction data continuously read from the memory 72 at a transfer rate of 18.75 sectors / second is supplied to the ATC decoder 73. This ATC decoder 73 corresponds to the ATC encoder 63 of the recording system, and the operation mode is designated by the system controller 57 to expand the 4-bit ATC data four times (bit expansion). Plays 16-bit digital audio data. The digital audio data from the ATC decoder 73 is supplied to the D / A converter 74.

The D / A converter 74 is the ATC decoder 73.
The digital audio data supplied from the device is converted into an analog signal to form an analog audio output signal A _OUT . The analog audio signal A _OUT obtained by the D / A converter 74 is output from the output terminal 76 via the low pass filter 75.

Next, the analog audio input signal A _IN from the input terminal 60 is supplied to the A / D converter 62 via the low-pass filter 61 and quantized, and then AT
The digital audio signal obtained by being encoded by the C encoder 63 can be further data-compressed (bit-compressed) and recorded in the IC card 2. The IC card recording system will be described below.

That is, the ATC audio data obtained by being compressed by the ATC encoder 63 is, for example, R
It is adapted to be sent via AM85 to a surplus bit reduction circuit unit 84 which is a kind of variable bit rate encoder. In this surplus bit reduction circuit unit 84, bits giving noise below the masking threshold. Will be reduced. This process is executed while reading / writing data from / to the memory 85. The variable bit rate compression-encoded data from the surplus bit reduction circuit 84 is recorded in the IC card 2 via the IC card interface circuit 86.

Here, the compressed data (ATC) from the decoder 71 of the reproducing system of the magneto-optical disk recording / reproducing unit is used.
The data) is sent to the memory 85 of the IC card recording unit without being expanded. This data transfer is performed by the system controller 57 controlling the memory 85 and the like during so-called high-speed dubbing. The compressed data from the memory 72 may be sent to the memory 85.

Next, a so-called high-speed digital dubbing operation will be described. First, at the time of so-called high-speed digital dubbing, the system controller 7 executes a predetermined high-speed dubbing control processing operation by operating a dubbing operation key of the key input operation unit 8. In particular,
The compressed data from the decoder 71 is sent as it is to the memory 85 of the IC card recording system, and the surplus bit reduction circuit 84
The variable bit rate encoding is performed by and is recorded in the IC card 2 via the IC card interface circuit 86. Here, when the ATC data of the above-mentioned predetermined mode is recorded on the magneto-optical disk 1, for example, the decoder 7
From 1, the quadruple compressed data is continuously read.

Therefore, at the time of the above high-speed dubbing, it is quadrupled in real time from the magneto-optical disk 1 (in the above-mentioned predetermined mode)
The compressed data corresponding to the time of is obtained continuously, and this is directly subjected to the variable length coding to the IC card 2
Since it is recorded on, it is possible to realize 4 times faster dubbing.
If the compression mode is different, the magnification of the dubbing speed is also different. Further, dubbing may be performed at a high speed equal to or higher than the compression ratio. In this case, the magneto-optical disk 1 may be rotated at a high speed at a speed several times the steady speed.

The magneto-optical disk 1 shown in FIG.
As shown in (1), at the same time that the data bit-compressed and encoded at a constant bit rate is recorded, the data amount when the data is bit-compressed and encoded by the variable bit rate encoder 3 (that is, in the IC card 2). Information of the data recording capacity required for recording) is recorded. By doing so, for example, the number of songs that can be recorded in the IC card 2 and the combination of songs among the songs recorded on the magneto-optical disk 1 can be immediately known by reading the data amount information. ..

On the contrary, in the IC card 2, not only the data bit-compressed and encoded at the variable bit rate,
By recording the data amount information of the data bit-compressed and encoded at a constant bit rate, it is possible to quickly know the data amount when the data such as music data is sent from the IC card 2 to the magneto-optical disk 1 for recording. it can.

FIG. 3 shows a front external view of the compressed data recording / reproducing apparatus 5 having the structure shown in FIG. 1, in which a magneto-optical disk insertion portion 6 and an IC card insertion slot 7 are provided.

Next, in the ATC encoder and decoder section of FIG. 1, an input digital signal such as an audio PCM signal is subjected to band division coding (SBC), adaptive transform coding (ATC) and adaptive bit allocation (APC-AB). A technique for performing high-efficiency encoding using each technique will be described with reference to FIG.

In the concrete high-efficiency coding apparatus shown in FIG. 4, the input digital signal is divided into a plurality of frequency bands by a filter or the like, and the higher the frequency band is, the wider the bandwidth is selected to be orthogonal to each frequency band. By performing conversion, the obtained spectrum data on the frequency axis is adaptively bit-assigned and coded for each so-called critical band (critical band) in consideration of human auditory characteristics described later.
Of course, the band division width by the filter or the like may be equal division width. Further, in the embodiment of the present invention, the block size (block length) is adaptively changed according to the input signal before the orthogonal transformation, and the floating process is performed for each block.

That is, in FIG. 4, an audio PCM signal of 0 to 20 kHz, for example, is supplied to the input terminal 10. This input signal is divided into a band of 0 to 10 kHz and a band of 10 to 20 kHz by a band dividing filter 11 such as a so-called QMF filter, and a signal of a band of 0 to 10 kHz is also divided into 0 to 0 by a band dividing filter 12 such as a so-called QMF filter. It is divided into a 5 kHz band and a 5 kHz to 10 kHz band. 10k from band splitting filter 11
A signal in the band of up to 20 kHz is an example of an orthogonal transformation circuit MD
The signal is sent to a CT (Modified Discrete Cosine Transform) circuit 13, and the band division filter 1
The signal in the 5 kHz to 10 kHz band from 2 is sent to the MDCT circuit 14
And the signals in the band of 0 to 5 kHz from the band division filter 12 are sent to the MDCT circuit 15 to be subjected to MDCT processing.

Regarding the above MDCT, for example, ICASSP,
1987, Subband / Transform CodingUsing Filter Bank De
signs Based on Time Domain Aliasing Cancellation,
JPPrincen, ABBradley, Modified DCT, Univ. Of S
urrey, Royal Melbourne Inst. of Tech.

Here, each MDCT circuit 13, 14, 15
FIG. 5 shows a specific example of the standard input signal for the blocks for each band supplied to. In the specific example of FIG. 5, the frequency band is widened and the time resolution is increased (the block length is shortened) on the higher frequency side. That is,
1 block B for signals in the low frequency band of 0 to 5 kHz
L _L and, for example, a 1024 sample, also of mid-range 5k~
For signals in the 10 kHz band, the length T _BL on the low frequency side is
Of the block BL _L of each of the blocks is divided into blocks BL _M1 and BL _M2 each having a length T _BL / 2, and 10 k to 10
For a signal in the 20 kHz band, a block BL having a length T _BL / 4 that is ¼ each of the above low-frequency block BL _L
Blocked with _H1 , BL _H2 , BL _H3 and BL _H4 .
When considering a band of 0 to 22 kHz as an input signal, the low band is 0 to 5.5 kHz and the middle band is 5.5 k to 11
The high frequency band is 11 kHz to 22 kHz.

Referring again to FIG. 4, each MDCT circuit 13,
The spectrum data on the frequency axis or the MDCT coefficient data obtained by the MDCT processing at 14 and 15 are collected for each so-called critical band and sent to the adaptive bit allocation encoding circuit 18. The critical band is a frequency band divided in consideration of human auditory characteristics, and the band of a pure tone when the pure tone is masked by narrow band noise of the same strength near the frequency of the pure tone. That is. This critical band has a wider bandwidth as it goes to a higher frequency band, and the entire frequency band of 0 to 20 kHz is divided into, for example, 25 critical bands.

The permissible noise calculating circuit 20 obtains the permissible noise amount for each critical band in consideration of the so-called masking effect based on the spectrum data divided for each critical band, and the permissible noise amount and each critical band. The number of allocated bits is calculated for each critical band based on the energy or the peak value of each spectrum, and each spectrum data (or MDCT coefficient is calculated according to the number of bits allocated by the adaptive bit allocation encoding circuit 18 for each critical band). (Data) is requantized. The data encoded in this way is taken out via the output terminal 19.

Next, FIG. 6 is a block circuit diagram showing a schematic configuration of a specific example of the allowable noise calculating circuit 20. In FIG. 6, the input terminal 21 is supplied with spectrum data on the frequency axis from each of the MDCT circuits 13, 14 and 15.

The input data on the frequency axis is sent to the energy calculation circuit 22 for each band, and the energy for each critical band (critical band) is calculated, for example, as the sum of the amplitude values in the band. It is required by things. Instead of the energy for each band, the peak value, the average value, etc. of the amplitude value may be used. As the output from the energy calculating circuit 22, for example, the spectrum of the total sum value of each band is generally called a Bark spectrum. FIG. 7 shows the Bark spectrum SB for each such critical band. However, in FIG. 7, the number of bands of the critical band is represented by 12 bands (B _{1 to} B ₁₂ ) in order to simplify the illustration.

Here, in order to consider the influence of the Bark spectrum SB on so-called masking, a convolution process is performed such that the Bark spectrum SB is multiplied by a predetermined weighting function and added. Therefore, the output of the energy calculation circuit 22 for each band, that is, each value of the Bark spectrum SB is sent to the convolution filter circuit 23. The convolution filter circuit 23 includes, for example, a plurality of delay elements that sequentially delay input data,
It is composed of a plurality of multipliers (for example, 25 multipliers corresponding to each band) that multiply the outputs from these delay elements by a filter coefficient (weighting function), and a sum adder that sums the outputs of the multipliers. It is something. By this convolution processing, the sum total of the portion indicated by the dotted line in FIG. 7 is obtained. In addition,
The masking is a phenomenon in which one signal is masked by another signal and becomes inaudible due to human auditory characteristics. , There is the same time masking effect by the signal on the frequency axis.
Due to these masking effects, even if there is noise in the masked portion, this noise will not be heard. Therefore, in the actual audio signal, the noise within the masked range is regarded as an acceptable noise.

Here, a specific example of the multiplication coefficient (filter coefficient) of each multiplier of the convolution filter circuit 23 will be described. When the coefficient of the multiplier M corresponding to an arbitrary band is 1, the multiplier is M-1 gives a coefficient of 0.15, multiplier M-2 gives a coefficient of 0.0019, and multiplier M-3 gives a coefficient of 0.0000.
086, a multiplier M + 1 gives a coefficient of 0.4, and a multiplier M + 2
By multiplying the output of each delay element by a coefficient of 0.06 with a coefficient of 0.007 by a multiplier M + 3, the convolution processing of the Bark spectrum SB is performed. However, M is 1
It is an arbitrary integer of 25.

Next, the output of the convolution filter circuit 23 is sent to the subtractor 24. The subtractor 24 calculates a level α corresponding to an allowable noise level described later in the convoluted area. The level α corresponding to the permissible noise level (permissible noise level)
Is a level at which an allowable noise level is obtained for each critical band by performing inverse convolution processing, as described later. Here, the subtractor 24 is supplied with an allowance function (a function expressing a masking level) for obtaining the level α. The level α is controlled by increasing or decreasing this allowance function. The permissible function is (n-
ai) It is supplied from the function generating circuit 25.

That is, the level α corresponding to the allowable noise level can be calculated by the following equation (1), where i is the number given in order from the low band of the critical band. α = S- (n-ai) (1) In this equation (1), n and a are constants, a> 0, S is the intensity of the convolved Bark spectrum, and (1)
In the formula, (n-ai) is the admissible function. In this embodiment, n = 38,
Since a = 1, there was no sound quality deterioration at this time, and good encoding was possible.

In this way, the level α is obtained, and this data is transmitted to the divider 26. The divider 26 is for inversely convolving the level α in the convolved area. Therefore, by performing this inverse convolution processing,
The masking threshold can be obtained from the level α. That is, this masking spectrum becomes the allowable noise spectrum. Although the above-mentioned inverse convolution processing requires complicated calculation, in this embodiment, the inverse convolution is performed using the simplified divider 26.

Next, the masking threshold is transmitted to the subtractor 28 via the synthesizing circuit 27. Here, the output from the energy detection circuit 22 for each band, that is, the above-described Bark spectrum SB is supplied to the subtractor 28 via the delay circuit 29. Therefore, the subtractor 28 performs the subtraction operation on the masking threshold and the Bark spectrum SB, so that the Bark spectrum SB is obtained as shown in FIG.
Is masked below the level indicated by the level of the masking threshold MS.

The output from the subtracter 28 is taken out via the allowable noise correction circuit 30 and the output terminal 31,
For example, the allocation bit number information is sent to a ROM or the like (not shown) in which it is stored in advance. This ROM or the like is assigned to each band in accordance with the output (the level of the difference between the energy of each band and the output of the noise level setting means) obtained from the subtraction circuit 28 via the allowable noise correction circuit 30. Output bit number information. By sending this allocation bit number information to the adaptive bit allocation encoding circuit 18, the MDC
The spectrum data on the frequency axis from the T circuits 13, 14, and 15 are quantized by the number of bits assigned to each band.

That is, in summary, in the adaptive bit allocation coding circuit 18, each band is allocated with the number of bits allocated according to the level of the difference between the energy of each band of the critical band and the output of the noise level setting means. Each spectrum data will be quantized. The delay circuit 29 is provided to delay the Bark spectrum SB from the energy detection circuit 22 in consideration of the delay amount in each circuit before the synthesis circuit 27.

By the way, at the time of synthesizing by the above-mentioned synthesizing circuit 27, the data which is supplied from the minimum audible curve generating circuit 32 and which shows a so-called minimum audible curve RC which is a human auditory characteristic as shown in FIG. The masking threshold MS can be combined. In this minimum audible curve, if the absolute noise level is below this minimum audible curve, the noise will not be heard. Even if the coding is the same, the minimum audible curve differs depending on, for example, the difference in reproduction volume at the time of reproduction. However, in a realistic digital system, for example, how to enter music into a 16-bit dynamic range is very different. Therefore, if the quantization noise in the most audible frequency band around 4 kHz is not heard, it is considered that the quantization noise below the level of the minimum audible curve is not heard in other frequency bands. Therefore, it is assumed that the system is used in such a manner that the noise near the 4 kHz of the word length of the system cannot be heard, and the minimum audible curve R
When C and the masking threshold MS are combined together to obtain the allowable noise level, the allowable noise level in this case can be up to the shaded portion in FIG. 9. In this embodiment, the level of 4 kHz of the minimum audible curve is set to the minimum level corresponding to 20 bits, for example. In addition, this FIG.
Also shows the signal spectrum SS.

The allowable noise correction circuit 30 corrects the allowable noise level in the output from the subtractor 28 based on the information of the equal loudness curve sent from the correction information output circuit 33. Here, the equal loudness curve is a characteristic curve relating to human auditory characteristics, and is obtained by, for example, obtaining the sound pressure of sound at each frequency heard at the same loudness as a pure tone of 1 kHz, and connecting the curves. Also called sensitivity curve. Further, this equal loudness curve draws a curve substantially the same as the minimum audible curve RC shown in FIG. In this equal loudness curve, for example, in the vicinity of 4 kHz, the sound pressure is 8 at 1 kHz.
Even if it goes down by -10 dB, it sounds as loud as 1 kHz, and conversely, at around 50 kHz, it is about 15 dB lower than the sound pressure at 1 kHz.
It doesn't sound the same unless it's high. Therefore, it is understood that the noise (allowable noise level) exceeding the level of the minimum audible curve should have the frequency characteristic given by the curve corresponding to the equal loudness curve.
From this, it is understood that correcting the permissible noise level in consideration of the equal loudness curve is suitable for human auditory characteristics.

Here, the correction information output circuit 33 is provided between the detection output of the output information amount (data amount) at the time of quantization in the encoding circuit 18 and the bit rate target value of the final encoded data. The allowable noise level may be corrected based on the error information. This is because the total number of bits obtained by performing temporary adaptive bit allocation in advance for all bit allocation unit blocks is a fixed number of bits (target value) determined by the bit rate of the final encoded output data. There is an error with respect to, and bit allocation is performed again so that the error is zero. That is, when the total number of allocated bits is smaller than the target value, the difference bit number is allocated and added to each unit block, and when the total allocated bit number is larger than the target value, the difference bit number is added to each unit block. It is allotted to and scraped.

In order to do this, an error in the total allocation bit number from the target value is detected, and the correction information output circuit 33 corrects each allocation bit number according to the error data. Is output. Here, when the error data indicates a bit number shortage, it can be considered that the data amount is larger than the target value because a large number of bits are used per unit block. Further, when the error data is data indicating a bit number surplus, it can be considered that the number of bits per unit block is small and the data amount is smaller than the target value. Therefore, the correction information output circuit 33 outputs the correction value for correcting the allowable noise level in the output from the subtractor 28 based on the error data, for example, based on the information data of the equal loudness curve. Data will be output. By transmitting the correction value as described above to the allowable noise correction circuit 30, the allowable noise level from the subtractor 28 is corrected. In another embodiment, the bits of the target value may be fixedly assigned to each block from the beginning. At this time, a large reduction in the amount of calculation can be obtained. In yet another embodiment, bit allocation can be performed depending on the signal size of each block. At this time, it is possible to minimize the noise energy.

Next, FIG. 10 shows the residual bit reduction circuit 8 described above.
A specific example of the removable bit reduction circuit 101 corresponding to 4 is shown. In FIG. 10, A shown in FIG.
The output from the TC encoder 63 is the MDCT coefficient a and
It consists of bit length information b and floating information c. The bit length information b shows what kind of bit length the MDCT coefficient a is quantized, and the floating information c shows what kind of normalization processing is performed on the MDCT coefficient a. ATC encoder 6
The removal of the auditorily redundant portion contained in the output from the 3 or the removal of the redundancy is performed as follows.

First, by obtaining the coefficient size of each block using the floating information c and the MDCT coefficient a, the masking threshold calculation circuit 102 uses the method described with reference to FIG. Calculate the threshold. Next, the bit length calculation circuit 103 calculates the bit length in the same manner as described with reference to FIG.
The removable bit calculation circuit 104 extracts the removable bit portion by comparing with the bit length information b of the ATC encoder output. The final bit length determination circuit 106
The bit length information b of the ATC encoder output is compared with the output from the removable bit calculation circuit 104 to determine the final bit length, and the removable bit removal circuit 105 is controlled.
The MDCT coefficient a ′ whose removal of removable bits is reduced by the removable bit removal circuit 105, the floating information c, and the final bit length information b ′ output from the final bit length determination circuit 106 are, for example, as shown in FIG. Is sent to the IC card interface circuit 86 or the like.

The present invention is not limited to the above embodiment, and for example, the reproducing system of the one recording medium and the recording system of the other recording medium do not have to be integrated. It is also possible to connect between them with a data transfer cable. Further, the present invention can be applied not only to audio PCM signals but also to signal processing devices for digital audio (speech) signals, digital video signals and the like. Further, the above-described minimum audible curve synthesizing process may not be performed. In this case, the minimum audible curve generating circuit 32 and the synthesizing circuit 27 are unnecessary, and the output from the subtractor 24 is
After being inversely convolved by the divider 26, it is immediately transmitted to the subtractor 28. Further, by driving the magneto-optical disk 1 at a rotation speed higher than the steady speed, dubbing at a higher speed than the bit compression rate may be performed. In this case, high-speed dubbing can be performed within the range permitted by the data transfer rate. Furthermore, in addition to the above IC memory card, various IC memories such as an IC memory cartridge and an IC memory pack can be used.

[0069]

As is clear from the above description, according to the compressed data recording / reproducing apparatus of the present invention, the bit which gives the quantization noise level which cannot be heard audibly from the bit-compressed digital data. Since the variable bit rate data obtained by deleting a part of the above is recorded on a recording medium such as an IC card, it is possible to efficiently perform further bit compression while suppressing deterioration of sound quality.

Further, according to the compressed data recording / reproducing apparatus of the present invention, the bit-compressed digital data is reproduced from one recording medium (magneto-optical disk or the like), and the bit data is directly processed (bit expansion processing or the like is performed). Instead, a variable bit rate bit compression process that reduces the number of bits that give a noise level below the masking threshold is performed and recorded directly on another recording medium (for example, an IC card). So-called high-speed dubbing can be performed, and dubbing can be performed efficiently in a short time.

Further, on one recording medium such as a magneto-optical disk, simultaneously with the data compressed and encoded at a constant bit rate, data amount information when compressed and encoded at the data variable bit rate is recorded. Or
By recording the data amount information when compressed and encoded at a constant bit rate at the same time as the variable bit rate compression encoded data in another recording medium such as an IC card, the number of songs when transferring songs and the optimum combination You can know immediately.

[Brief description of drawings]

FIG. 1 is a block circuit diagram showing a configuration example of an embodiment of a compressed data recording / reproducing apparatus according to the present invention.

FIG. 2 is a diagram showing recorded contents of a magneto-optical disk 1 and an IC card 2.

FIG. 3 is a schematic front view showing an example of the external appearance of the apparatus of this embodiment.

FIG. 4 is a block circuit diagram showing a specific example of a high-efficiency compression encoding apparatus that can be used for constant bit rate compression encoding of the above-described embodiment.

5 is a diagram showing a specific example of division into bands in the apparatus of FIG. 4 and blocking in the time axis direction in each band.

6 is a block circuit diagram showing a specific example of an allowable noise calculation circuit 18 of the apparatus of FIG.

FIG. 7 is a diagram showing a Bark spectrum.

FIG. 8 is a diagram showing a masking spectrum.

FIG. 9 is a diagram in which a minimum audible curve and a masking spectrum are combined.

FIG. 10 is a block circuit diagram showing a specific example of a surplus bit reduction circuit.

[Explanation of symbols]

1 ... Magneto-optical disk 2 ... IC card 11, 12 ... Band division filter 13, 14, 15 ... Orthogonal transformation circuit (MDCT circuit) 18 ... -Adaptive bit allocation coding circuit 20-Allowable noise calculation circuit 22-Energy detection circuit for each band 23-Convolution filter circuit 27-Synthesis circuit 28- ... Subtractor 30 ... Allowable noise correction circuit 32 ... Minimum audible curve generation circuit 33 ... Correction information output circuit 53 ... Optical head 54 ... Magnetic head 56 ... Servo control circuit 57 ... System controller 62, 83 ... A / D converter 63 ... ATC encoder 64, 72, 85. Memory 65 ... Encoder 66 ... Magnetic head drive circuit 71 Decoder 73 ATC decoder 74 D / A converter 84 Surplus bit reduction circuit 86 IC card interface Circuit 101-Removable Bit Reduction Circuit 102-Masking Threshold Calculation Circuit 103-Removable Bit Calculation Circuit 104-Removable Bit Removal Circuit 105- ..Final bit length determination circuit

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification number Office reference number FI technical display location G11B 20/10 341 Z 7923-5D 27/034

Claims (11)

[Claims] 1. A compressed data recording / reproducing apparatus having a compressed data recording system for recording an information signal as bit-compressed digital data on a recording medium, wherein quantization noise which is not perceptually perceptible during the bit compression processing. A compressed data recording / reproducing apparatus characterized in that variable bit rate digital data is obtained by removing a part of bits that give a level, and the variable bit rate digital data is recorded on the recording medium. 2. A compressed data reproducing system for reproducing digital data from one recording medium in which an information signal is bit-compressed at a constant bit rate and recorded, and an information signal is bit-coded at a variable bit rate on another recording medium. A compressed data recording system for compressing and recording, reproducing compressed data from the one recording medium of the reproducing system, and removing a part of bits that give a quantization noise level that is not perceptually perceived. A compressed data recording / reproducing apparatus characterized in that the variable bit rate digital data obtained by the above method is recorded on the other recording medium of the recording system. 3. The compressed data recording according to claim 1, wherein the quantization noise level is a quantization noise level lower than an allowable noise level determined by a masking threshold and a minimum audible limit. Playback device. 4. The compressed data recording / reproducing apparatus according to claim 1, wherein the recording medium is an IC memory or an IC memory card. 5. The compressed data recording / reproducing apparatus according to claim 2, wherein the one recording medium is a disk and the other recording medium is an IC memory or an IC memory card. 6. The compressed data recording / reproducing apparatus according to claim 1 or 4, wherein the recording medium has recorded therein bit rate data amount information before variable bit rate processing. 7. The compressed data recording / reproducing apparatus according to claim 2, wherein the one recording medium has recorded therein data amount information for recording on the other recording medium. .. 8. The compressed data recording / reproducing apparatus according to claim 2, wherein the other recording medium has recorded therein the data amount information recorded in the one recording medium. . 9. The compressed data according to claim 1, wherein the bit compression processing is performed by a high efficiency code for quantizing a sample in a small block subdivided in time and frequency. Recording / playback device. 10. A highly efficient bit-compressing process which provides a noise characteristic in which an allowable noise spectrum is changed by a difference between the number of bits giving an allowable noise determined by a masking threshold and a minimum audible limit and the total number of usable bits. 10. The compressed data recording / reproducing apparatus according to claim 9, wherein the compressed data recording / reproducing apparatus is processed by a code. 11. The compressed data recording / reproducing apparatus according to claim 9, wherein the sub information includes floating information and bit length information.