JPH07273758A - System and device for digital information transmission/ reception and recording/reproducing - Google Patents

Abstract

PURPOSE:To enable many subscribers to simultaneously receive or record information in the system where information where video software or the like is made secret is transmitted through a satellite. CONSTITUTION:A transmission system 100 collectively transmits discrimination codes of plural subscribers, who request reception, before transmitting an essential digital information signal. A reception system 200 detects its own discrimination code from plural discrimination codes received in advance and decodes the digital information signal made secret based on this discrimination code. When the received signal is recorded, a recording and reproducing system 300 is set to the recording waiting state in the middle of discrimination code reception and receives an REC start signal multiplexed in the head of the essential digital information to start automatic recording and stops recording by the last REC end signal. The signal made secret is recorded as it is at this time, and the reproduced signal is decoded in the reception system 200.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital information signal transmitting / receiving and recording / reproducing system and apparatus, and more particularly to
The present invention relates to a digital information transmission / reception and recording / reproduction system and apparatus suitable for simultaneous transmission / reception or recording / reproduction of many confidential digital information signals by a large number of subscribers.

[0002]

2. Description of the Related Art Television Society Journal, Vol.47, No.
4 (1993), pp. 494, p. 494-499, a system is conceived in which audio and video software and the like are transmitted via radio waves or cables and recorded at each home.

[0003]

Now, considering a system in which a satellite is used as a transmission path and video software or the like is encrypted and transmitted so that only the subscriber can decipher it.
The target system will be a large-scale system with tens of thousands to hundreds of thousands of households (subscribers). At this time, it is necessary to transmit an identification code such as a key code for decryption and a subscriber number, but how to transmit the large number of identification codes of tens of thousands to hundreds of thousands of households becomes a problem. .

That is, in the conventional method of transmitting in the subcode area provided separately from the main data area,
Due to the low transmission capacity, it was impossible to send identification codes for tens of thousands of households.

The object of the present invention is to solve the above problems,
An object of the present invention is to provide a digital information transmission / reception and recording / reproducing system and apparatus capable of collectively transmitting a large number of identification codes for tens of thousands to hundreds of thousands of households and receiving or recording / reproducing simultaneously for a large number of subscribers.

[0006]

In order to achieve the above object, in the present invention, the identification codes of all requested subscribers are transmitted by using the main data area prior to the transmission of the original digital information signal. I tried to send them all at once.

Further, at the time of transmitting the original digital information signal, a start signal indicating it is added at the beginning of the signal.
The end signal is multiplexed at the tail.

[0008]

Since the identification code is transmitted using the main data area, it is possible to secure the same transmission rate and transmission capacity as the original digital information signal, and it is possible to sufficiently cope with the increase in the number of receiving households.

When recording a digital information signal, recording is started by a start signal multiplexed at the beginning of the signal and stopped by an end signal at the end. This enables automatic recording and prevents recording failure.

[0010]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of a digital information transmitting / receiving and recording / reproducing system and apparatus according to the present invention, which is roughly a transmitting system 100 and a receiving system 20.
0, divided into recording / reproducing system 300. And transmission system 1
00 is composed of a scrambler 12, an identification code generator 13, a changeover switch 14, a transmission system encoder 15 and a modulator 17, and a reception system 200 is a demodulator 21, a reception system decoder 22, a changeover switch 23, a desk. The recording / reproducing system 300 includes a rambler 24 and an identification code storage circuit 25.
Is composed of a recording system encoder 30, a changeover switch 35, a recording / reproducing system control circuit 36, a reproducing system decoder 40, a rotary drum 50, magnetic heads 51a and 51b, a magnetic tape 60 and a servo circuit 70. 3 is an input terminal, 4 is a transmission line, and 5 is an output terminal.

First, the operation of the transmission system 100 will be described.
The digital information signal input from the input terminal 3 is kept secret in the scrambler 12. The identification code generator 13 generates an identification code such as a key code or a subscriber number so that only the requesting subscriber can decrypt it. The confidential digital information signal and the identification code are switched by the switching switch 14 and sequentially encoded by the transmission system encoder 15 in a predetermined format. Then, the encoded digital information signal and the identification code are sequentially modulated by the modulator 17 and sent to the transmission line 4.

2 (A) and 2 (B) are diagrams showing an example of the configuration of the digital information signal and the identification code encoded by the transmission encoder 15, respectively. (A) shows a coding structure of a digital information signal, and a synchronization signal (S
YNC), subcode, data (digital information signal), and parity are used as a segment type signal. In this subcode, a control signal for a recording / reproducing system 300, which will be described later, such as a REC start signal or R
The EC end signal is also inserted.

Here, conventionally, as described above, the above-mentioned identification code is transmitted in the sub-code area therein. However, there is a problem that the transmission capacity of this subcode is so small that it cannot be applied to a large-scale subscriber system. Therefore, in the present invention, as shown in (B), the identification code is transmitted in the main data area. And
As shown in FIG. 3, this encoded identification code is transmitted prior to the digital information signal. Further, during this identification code transmission period, the recording / reproducing system 300, which will be described later, is set up in the recording standby state, and the digital information signal transmitted thereafter is automatically recorded.

In the receiving system 200, the signal received via the transmission line 4 is demodulated by the demodulator 21, and the demodulated signal is sequentially sent by the receiving system decoder 22 to the identification code and the digital information signal sent. Decrypt. The decoded identification code and digital information signal are supplied to the descrambler 24 via the changeover switch 23. The descrambler 24 first compares the sent identification code with its own identification code Di from the identification code storage circuit 25, and decodes the requested digital information signal. Then, the decoded digital information signal is output from the output terminal 5.

As described above, by transmitting the identification code by using the large-capacity main data area prior to the transmission of the digital information signal, it becomes possible to cope with a large-scale subscriber system. Since the format of the segment format for transmitting this identification signal is the same as the format of the original digital information signal to be transmitted next, the circuits of the transmission system encoder 15 and the reception system decoder 22 are simplified. Has the advantage that

Next, the operation of recording and reproducing the requested digital information signal will be described.

In the recording / reproducing system 300, the changeover switch 23
An identification code and a digital information signal which are sequentially decoded by the receiving system decoder 22 are received via, and the recording / reproducing system control circuit 36 first collates the transmitted identification code with its own identification code Di, and then transmits the same. It is determined whether or not the received digital information signal is the one requested. As a result, when a request is made, the recording / reproducing system control circuit 36 further sets up the recording system encoder 30, the changeover switch 35, and the servo circuit 70 in a recording standby state. After receiving the REC start signal transmitted subsequently, the recording mode is set and the requested digital information signal is supplied to the recording encoder 30 to start recording.

The recording system encoder 30 records and encodes the supplied signal in a format suitable for recording and reproduction.
FIG. 4 is a block diagram showing an example of the configuration of the recording encoder 30. Reference numeral 31 is a storage circuit, 32 is an interface circuit, 33 is a parity generation circuit, and 34 is a recording signal generation circuit. In the figure, the sent digital information signal (data) is first stored in the storage circuit 31 via the interface circuit 32. FIG. 5A shows this data. In the parity generation circuit 33, the storage circuit 31
The parity is generated from the data stored in
Store in 1. In the recording signal generation circuit 34, the storage circuit 3
The data and parity stored in No. 1 are read, the synchronization signal (SYNC) and the ID signal are added, and the signals are output as a block format signal as shown in FIG.

FIG. 6 shows an example of the structure of the ID signal. For example, a track number for identifying a recording track, a block number for identifying a position in the track, a recording time on the tape, and a program number. Etc., and parity for error detection and correction of the ID signal. The sent identification code of the device itself is also inserted in the control information.

The signal thus encoded by the recording system is passed through the change-over switch 35 to the 18 of the rotary drum 50.
Magnetic heads 51a, 5 mounted at positions facing each other by 0 degree
1b and is recorded on the magnetic tape 60 in azimuth. At this time, the servo circuit 70 controls the rotational speed of the rotary drum 50 to R and the running speed of the magnetic tape 60 to V. In the magnetic heads 51a and 51b, (+) indicates positive azimuth and (−) indicates negative azimuth.

The end of recording is the same as the start when the R received
The recording mode is released and stopped by the EC end signal. In this way, since the control of the recording / reproducing system 300 is all performed by the received signal from the transmitting system 100, the user can surely record the desired software without touching anything. Further, since the transmitting side can collectively transmit the identification code, it is possible to control the automatic recording of many subscribers at the same time.

The reproducing system decoder 40 includes a magnetic head 51a,
The signal reproduced by 51b and input through the changeover switch 35 is decoded. FIG. 7 is a block diagram showing an example of the structure of the reproduction system decoder 40, in which 41 is a storage circuit, 42 is a block reproduction circuit, 43 is an error correction circuit, 4
Reference numeral 4 is a reproduction signal output circuit. In the figure, the signals reproduced by the magnetic heads 51a and 51b are first input to the block reproducing circuit 42. This block reproduction circuit 4
2, the sync signal and the ID signal are detected, and the storage circuit 4 is determined from the track number and the block number in the ID signal.
1 is stored in a predetermined position. In the error correction circuit 43,
An error in the reproduced data is corrected using the parity stored in the storage circuit 41, and the corrected data is stored in the storage circuit 41.
Remember. In the reproduction signal output circuit 44, the storage circuit 41
The data after the error correction processing stored in is read and output in the order of the track number and the block number.

The data signal decoded in the reproducing system in this way is sent to the receiving system 200 and supplied to the descrambler 24 through the switching switch 23. The descrambler 24 decodes by the above-mentioned operation and outputs the decoded signal from the output terminal 5.

As described above, in this embodiment, the identification code is transmitted in the main data area prior to the digital information signal, so that it can be applied to a large-scale subscriber system of tens of thousands or more households. . Further, the recording / reproducing system 300 is set up in the recording standby state during this identification code transmission period, and the recording / reproducing system 300 is controlled to be automatically recorded by the REC start signal or the REC end signal. There is an effect that the digital information signal can be surely recorded without touching 300.

Although not particularly described in the above embodiment, the identification code may be transmitted during the transmission of the digital information signal as in the conventional case. In this case, in a large-scale subscriber system, the transmission frequency per subscriber is reduced, but the subscriber can be identified more reliably.
In addition, since the receiving side constantly monitors the operating state of its own machine, there is an effect that there is no recording failure.

FIG. 8 is a block diagram showing another embodiment of a digital information transmission / reception and recording / reproducing system and apparatus according to the present invention. The present invention is applied to a subscriber system for highly efficient digital compression coding of video software for transmission. This is an example of application. Here, 1 and 2 are input terminals, 11 is MP
EG encoders, 26 are MPEG decoders, 6 and 7 are output terminals, and 52a and 52b are magnetic heads. Parts corresponding to those in FIG.

In the transmission system 100, the image signal input from the input terminal 1 and the audio signal input from the input terminal 2 are input to the MPEG encoder 11 in, for example, MP.
High-efficiency digital compression coding is performed using the EG (Moving Picture Expert Group) method. Hereinafter, as in the embodiment of FIG. 1, the digital information signal composed of the digital compression-encoded image and audio signals is sent to the scrambler 1.
2, the identification code from the identification code generator 13 is switched to the identification code, and the transmission switch encoder 15 sequentially encodes the identification code from the identification code from the identification code generator 13. Then, the encoded digital information signal and the identification code are sequentially modulated by the modulator 17 and sent to the transmission line 4. At this time, the encoded identification code is transmitted prior to the digital information signal, the recording / reproducing system 300 is set up in the recording standby state during the identification code transmission period, and the digital information signal transmitted thereafter is automatically recorded. What is shown in FIG.
Is the same as.

In the receiving system 200, similarly, the signal received via the transmission path 4 is demodulated by the demodulator 21 and decoded by the receiving system decoder 22. The decoded identification code and digital information signal are supplied to the descrambler 24 via the changeover switch 23, and the requested digital information signal is decoded. Then, the MPEG decoder 26
The original image and audio signals are decoded by and output from the output terminals 6 and 7, respectively.

Next, in the recording / reproducing system 300, the identification code and the digital information signal decoded by the receiving system decoder 22 are received via the changeover switch 23, and the recording / reproducing system control circuit 36 is first received while receiving the identification code. The recording system encoder 30, the changeover switch 35 and the servo circuit 70
To record standby. Then, after receiving the REC start signal, the automatic recording of the requested digital information signal is started, and the automatic recording is ended by the received REC end signal.

At this time, the recording system encoder 30 has the same configuration as that of FIG. 4, and records and encodes the supplied signal in a block format suitable for recording and reproduction similar to that of FIG. Output as a recording signal of. The two-system recording signals are supplied to the two sets of magnetic heads 51a, 52b and 51b, 52a via the changeover switch 35, and are recorded on the magnetic tape 60 in azimuth. Servo circuit 70
At this time, the rotational speed of the rotary drum 50 is controlled to R2, and the running speed of the magnetic tape 60 is controlled to V2. In the magnetic heads 51a, 52b and 51b, 52a,
(+) Indicates positive azimuth and (-) indicates negative azimuth.

On the other hand, the reproducing system decoder 40 is constructed in the same manner as in FIG. 7, and has magnetic heads 51a, 52b and 51b, 5
Decode the signal reproduced by 2a. Then, the decoded signal is sent to the receiving system 200, and the switching switch 23
Is supplied to the descrambler 24 via. The descrambler 24 decodes it by the above-mentioned operation, decodes it into the original image and audio signals by the MPEG decoder 26, and outputs it from the output terminals 6 and 7, respectively.

As described above, also in this embodiment, since the identification code is transmitted in the main data area prior to the digital information signal, it can be applied to a large-scale subscriber system of tens of thousands or more households. Further, the recording / reproducing system 300 is set up in the recording standby state during this identification code transmission period, and the recording / reproducing system 300 is controlled so as to be automatically recorded by the REC start signal and the REC end signal. The effect is that the requested video software can be recorded without fail.

FIG. 9 is a block diagram showing another embodiment of a digital information transmission / reception and recording / reproducing system and apparatus according to the present invention, in which a digital information signal is time-axis compressed and transmitted / recorded at high speed, and at the time of reproduction. This is an example in which the present invention is applied to a system for reproducing at the original speed. here,
Reference numeral 16 is a time axis compressor, and other parts corresponding to those in FIG.

In the transmission system 100, the digital information signal input from the input terminal 3 is encrypted in the scrambler 12, switched by the identification code from the identification code generator 13 and the switching switch 14, and the transmission system encoder. At 15, the data is sequentially encoded in the same format as in FIG. Then, the encoded digital information signal and the identification code are 1 / N by the time axis compressor 16.
(N is an integer of 2 or more) and the transmission rate is N
It is doubled in speed and modulated by the modulator 17, and the transmission line 4
Sent to. At this time, the encoded identification code is transmitted prior to the digital information signal, the recording / reproducing system 300 is set up in the recording standby state during the identification code transmission period, and the digital information signal transmitted thereafter is automatically recorded. What is done is the same as in FIG.

In the receiving system 200, the signal received via the transmission path 4 is demodulated by the demodulator 21 and the receiving system decoder 22
Decrypt by. Then, the decoded identification code and digital information signal are supplied to the recording / reproducing system 300.

In the recording / reproducing system 300, the receiving system decoder 22
Upon receiving the identification code and the digital information signal decoded by, the recording / reproducing system control circuit 36 sets up the recording system encoder 30, the changeover switch 35 and the servo circuit 70 in a recording standby state while receiving the identification code. Then, after receiving the REC start signal, the automatic recording of the requested digital information signal is started, and the automatic recording is ended by the received REC end signal.

At this time, the recording system encoder 30 has the same configuration as that shown in FIG. 4, records and encodes the supplied signal in the block format suitable for recording and reproduction as shown in FIG. The encoded signal is supplied to the magnetic heads 51a and 51b via the changeover switch 35 and recorded on the magnetic tape 60 in azimuth. At this time, the servo circuit 70 controls the rotational speed of the rotary drum 50 to R and the running speed of the magnetic tape 60 to V.

During reproduction, the servo circuit 70 rotates the rotary drum 50 at the same rotation speed R as during recording, and the magnetic tape 60 runs at a running speed V / N that is 1 / N during recording.
Then, the recorded signal is reproduced by the magnetic heads 51a and 51b.

FIG. 10 is a diagram showing the track pattern at the time of this reproduction. The solid line shows the recorded track pattern, and the broken line shows the scanning loci of the magnetic heads 51a and 51b. In this way, since the rotary drum 50 is rotated at the same rotation speed R as during recording and the magnetic tape 60 is run at the running speed V / N that is 1 / N during recording, the magnetic head 51
The scanning pitch of a and 51b is 1 / N of the track pitch P.
Therefore, although the scanning angle varies depending on the value of N, scanning is performed N times per track. W indicates the head width of the magnetic heads 51a and 51b. Usually, this head width W is larger than the track pitch P, for example, 1.5.
Doubled.

FIG. 11 is a waveform diagram showing a process of extracting a signal from the N (for example, N = 3) times of scanning. In the figure, (A) shows the rotary drum 50 at the original speed R / N.
It shows the timing when rotating with, at this time,
_{a 0, b 0, a 1} , b 1, a 2, b 2, a 3, forward by a signal b ₃ is assumed to be reproduced. T is this rotation period. (B)
Shows the timing when rotated at the speed of R according to the present embodiment, and (C) is the envelope of the signal reproduced by the magnetic heads 51a and 51b at this time. Like this one
Scanning is performed three times per track, and as described above, the head width W of the magnetic heads 51a and 51b is set to 1.5 times the track pitch P.
Even if the scanning angle is deviated from the recording track angle, on-track occurs in a considerable part. Therefore, the original data (waveform D) can be obtained by extracting the signal from which the reproduction output level is most obtained. Then, if this is expanded three times on the time axis, the target low-speed signal (waveform E) can be reproduced.

The process of extracting a signal from the N scans is performed by the reproducing system decoder 40 shown in FIG. In FIG. 7, the signals reproduced by the magnetic heads 51a and 51b are first input to the block reproducing circuit 42. In the block reproducing circuit 42, the sync signal and I
The D signal is detected and stored in a predetermined position on the memory circuit 41 from the track number and block number in the ID signal. The error correction circuit 43 corrects an error in the reproduced data using the parity stored in the storage circuit 41, and at the same time, generates a pointer indicating the error state, and the storage circuit 4
Store in 1. At this time, the data of the same track number and block number are input to the memory circuit 41 N times, but the data with the best error state is finally stored by the pointer. The reproduction signal output circuit 44 reads the error-corrected data stored in the storage circuit 41 in the order of the track number and the block number, and outputs the low-speed data expanded in the time axis.

The low-speed data signal subjected to the reproduction system decoding process in this manner is sent to the reception system 200 and decoded by the descrambler 24. The signal decoded into the original digital information signal is output from the output terminal 5.

As described above, also in this embodiment, since the identification code is transmitted in the main data area prior to the digital information signal, it can be applied to a large-scale subscriber system of tens of thousands or more households. Further, the recording / reproducing system 300 is set up in the recording standby state during this identification code transmission period, and the recording / reproducing system 300 is controlled so as to be automatically recorded by the REC start signal and the REC end signal. The effect is that the requested digital information signal can be recorded without fail.

Further, during reproduction, the rotary drum 50 is rotated at the same speed as during recording so that the time axis compression coefficient N
It is possible to increase the frequency during reproduction without lowering, and to secure a desired reproduction output level. Also, the rotating drum 5
The rotation control of 0 becomes easy. Furthermore, N per track
Since the scanning is performed once, the data can be reproduced even if the tracking is deviated, so that there is also an effect that precise tracking control is unnecessary.

In the above embodiment, the rotation speed of the rotary drum 50 is set to be the same at the time of recording and at the time of reproduction, but the rotation speed of the rotating drum 50 at the time of recording is the original speed. It may be rotated at a speed of 1 / N. In this case, the scanning of the magnetic heads 51a and 51b is exactly the same during recording and reproduction, and the processing of the reproducing system decoder 40 is simplified. However, the reproduction frequency decreases as the time axis compression coefficient N increases, and the reproduction output level decreases accordingly. Therefore, there is a problem that the value of N cannot be increased so much.

[0047]

As described above, according to the present invention, in a large-scale subscriber system that transmits a confidential digital information signal via a satellite or the like, a large number of subscribers who have made a request simultaneously receive the request. In addition, when recording and reproducing the digital information signal, automatic recording is possible, so that there is an effect that recording can be surely performed without failure.

[0048]

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a digital information recording / reproducing apparatus according to the present invention.

FIG. 2 is a block diagram showing a configuration example of a recording encoder according to the present invention.

FIG. 3 is a diagram showing input / output signals of the recording encoder shown in FIG.

FIG. 4 is a diagram showing a configuration example of an ID signal.

5 is a diagram showing a track pattern at the time of recording in the embodiment of FIG.

FIG. 6 is a diagram showing a track pattern during reproduction in the embodiment of FIG.

FIG. 7 is a diagram showing an operation at the time of reproduction of the embodiment shown in FIG.

FIG. 8 is a block diagram showing a configuration example of a reproduction system decoder according to the present invention.

FIG. 9 is a diagram showing an example of a transmission format.

FIG. 10 is a diagram showing an example of a transmission format of a digital information signal according to the present invention.

FIG. 11 is a diagram showing a second example of a transmission format of a digital information signal according to the present invention.

[Explanation of symbols]

 11 ... MPEG encoder, 12 ... Scrambler, 13 ... Identification code generator, 15 ... Transmission system encoder, 16 ... Time axis compressor, 17 ... Modulator, 21 ... Demodulator, 22 ... Reception system decoder, 24 ... Identification code storage circuit, 25 ... Descrambler, 26 ... MPEG decoder, 30 ... Recording system encoder, 36 ... Recording / reproducing system control circuit, 40 ... Reproducing system decoder, 50 ... Rotating drum, 51a, 51b, 52a, 52b ... Magnetic head, 60 ... Magnetic tape, 70 ... Servo circuit, 100 ... Transmission system, 200 ... Reception system, 300 ... Recording / reproduction system.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hideo Nishijima 292 Yoshida-cho, Totsuka-ku, Yokohama, Kanagawa Stock Company, Hitachi Media Media Research Laboratories (72) Inventor Hiroaki Ono 292 Yoshida-cho, Totsuka-ku, Yokohama, Kanagawa Inside Hitachi Media Media Research Laboratories (72) Hiroo Okamoto Inventor Hiroo Okamoto 292 Yoshida-cho, Totsuka-ku, Yokohama, Kanagawa Stock Company Inside Hitachi Media Media Research Laboratories (72) Ino Owashi 292 Yoshida-cho Totsuka-ku, Yokohama Hitachi, Ltd. Visual Media Laboratory (72) Inventor Takao Arai 292 Yoshida-cho, Totsuka-ku, Yokohama, Kanagawa Stock Company Hitachi Visual Media Laboratory

Claims (10)

[Claims] 1. A system comprising a transmission system for transmitting a confidential digital information signal and a reception system for receiving the confidential digital information signal transmitted from the transmission system, wherein the transmission system comprises a plurality of transmission systems. In the receiving system, a plurality of identification codes for decoding the confidential digital information signal are collectively transmitted prior to the transmission of the digital information signal, and the receiving system first receives the plurality of received plurality of identification codes. A digital information transmitting / receiving system, characterized in that it detects its own identification code from the identification codes and decodes the confidential digital information signal based on it. 2. The digital information transmitting / receiving system according to claim 1, wherein the plurality of identification codes and the confidential digital information signal are encoded into a format of the same segment format and transmitted. 3. A transmitting system for transmitting a confidential digital information signal, a receiving system for receiving the confidential digital information signal transmitted from the transmitting system, and the confidential digital received by the receiving system. In a system comprising a recording / reproducing system for recording / reproducing an information signal on / from a recording medium, the transmitting system collectively includes a plurality of identification codes for decoding the encrypted digital information signals in a plurality of the receiving systems, Transmitting prior to the transmission of the digital information signal, the receiving system supplies the received identification code and the encrypted digital information signal to the recording / reproducing system, and reproduces the confidential information in the recording / reproducing system. The recording / reproducing system receives the signal received by the receiving system and waits for recording while receiving the identification code. Is set up in the state, the digital information recording and reproducing system, characterized in that the subsequently sent the incoming digital information signal the polarized automatically recorded and supplied to the receiving system by reproducing the recorded signal. 4. The recording / reproducing system according to claim 3, wherein the recording operation is started after receiving a recording start signal transmitted subsequently to the plurality of identification codes, and the recording end signal is transmitted at the end by the recording end signal. A digital information recording / reproducing system characterized by being controlled so as to stop a recording operation. 5. The digital information recording / reproducing system according to claim 3, wherein the plurality of identification codes and the confidential digital information signal are encoded in the same segment format and transmitted. 6. The secret digital information signal according to claim 3, wherein the confidential digital information signal is time-axis compressed, transmitted and recorded at a high speed, and reproduced at a predetermined speed before the time-axis compression. A digital information recording / reproducing system characterized by expanding the time axis. 7. A system comprising a transmission system for transmitting a digital information signal and a reception system for receiving the digital information signal transmitted from the transmission system, wherein the transmission system secures the digital information signal. Anonymizing means, an identification code generating means for generating a plurality of identification codes for decoding the anonymized digital information signals in the plurality of receiving systems, the anonymized digital information signals and the plurality of identification codes And a switching unit for switching the output signal of the switching unit in a predetermined format, and a modulation unit for modulating the output signal of the encoding unit. A demodulation means for demodulating the signal, a decoding means for decoding the demodulated signal, and a decoding means for decoding the encrypted digital information signal. The storage means for storing its own identification code, the plurality of identification codes decoded by the decoding means and the own identification code are collated, and by using this, the anonymized digital information decoded by the decoding means A digital information transmitting / receiving apparatus comprising: a decoding means for decoding a signal, wherein the plurality of identification codes are collectively transmitted prior to the transmission of the confidential digital information signal. 8. A transmitting system for transmitting a digital information signal, a receiving system for receiving the digital information signal transmitted from the transmitting system, and recording and reproducing the digital information signal received by the receiving system on a recording medium. In the system comprising a recording / reproducing system, the transmitting system generates an anonymization means for anonymizing the digital information signal, and a plurality of identification codes for decoding the anonymized digital information signals in a plurality of the receiving systems. Identification code generating means, switching means for switching the confidential digital information signal and the plurality of identification codes, encoding means for encoding the output signal of the switching means in a predetermined format, and the encoding And a modulation means for modulating the output signal of the means, wherein the plurality of identification codes are collectively and The reception system transmits prior to the transmission of the digital information signal, the receiving system demodulates the received signal, the decoding unit decodes the demodulated signal, and the decrypted digital information signal. Storage means for storing its own identification code, the plurality of identification codes decoded by the decoding means are collated with the own identification code, and using this, the anonymized digital information signal decoded by the decoding means And a second encoding means for encoding the encrypted digital information signal decoded by the decoding means in a second format, and a second decoding means for decoding the encrypted digital information signal. Recording / reproducing means for recording the output signal of the encoding means on a recording medium and reproducing the recorded signal, and a second decoding means for decoding the signal reproduced from the recording medium. Which is set up in a recording standby state while receiving the identification code, automatically records the confidential digital information signal sent thereafter, reproduces the recorded signal and supplies it to the receiving system. A digital information recording / reproducing apparatus characterized by the above. 9. The recording / reproducing system according to claim 8, wherein the recording operation is started after receiving a recording start signal transmitted subsequently to the plurality of identification codes, and the recording end signal is transmitted at the end by the recording end signal. A digital information recording / reproducing apparatus characterized by being controlled so as to stop a recording operation. 10. The transmission system according to claim 8 or 9, wherein the transmission system further outputs an output signal of the encoding means by 1 / N (N is an integer of 2 or more).
A time axis compression means for time axis compression, the modulation means is configured to modulate the output signal of the time axis compression means, and the recording / reproducing means outputs the output signal of the second encoding means to a predetermined value. The signal is recorded on the recording medium at a speed, and the recorded signal is 1 / th of the predetermined speed.
It is configured to reproduce at a speed of N, and the transmission and recording time of the digital information signal is 1 / N
A digital information recording / reproducing apparatus characterized by being shortened to.