JPH06349142A - Digital information recording/reproducing device - Google Patents

Abstract

PURPOSE:To simplify operation and to suppress a mistake in video recording minimally by connecting a control signal generation means of a VTR to a transmission side and a control signal detection means to a reception side. CONSTITUTION:In a transmission system 100, an input digital information signal is coded 10, and is time base compressed 20 to 1/n, and a transmission rate is accelerated to (n) times to be sent to a transmission line 30. In a reception system 200, a receiving signal is demodulated 35 to be supplied to an encoder 40 of a recording/reproducing system 300. Then, a coded signal is supplied to a magnetic heads 51a, 51b on a rotary drum 50 through a changeover switch 45 to be azimuth recorded on a magnetic tape 60. Then, a low speed data signal reproduction system decoding processed is sent to the reception system 200 to be decoded 80, and to be outputted as the original digital information signal. In such a case, a control signal for the recording/reproducing system 300 is inputted from a terminal 2, and is sent to a control signal detection circuit 65 together with an ID code through the transmission line 30, and the switch 45 is shifted, and further, a recording control signal is detected 65, and a recording state is formed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a recording / reproducing apparatus for digital information signals, and more particularly to a digital information recording apparatus for multiplexing recording information on a recording / reproducing apparatus control signal for transmission and recording by using the control signal. Reproduction device

[0002]

2. Description of the Related Art Journal of Television Engineering, Vol. 47, No. 4 (1
993) As described on pages 494 to 499,
A system has been considered in which audio and video software is transmitted via radio waves or a cable and recorded at each home.

[0003]

In such a system, a two-way system in which a user requests the sending side for video software like that of the user and a software supplier transmits the desired software is conceivable. In this case, it takes a certain predetermined time from when the video software is requested to the transmitting side until the digital information signal is actually transmitted. In other words, the transmission side is in the transmission standby state until the transmission video data is prepared or the transmission channel is vacant, and there is a problem that the user does not know when to operate the VTR.

The object of the present invention is to solve the above problems,
An object of the present invention is to provide a digital information recording / reproducing apparatus which is easy to operate and which can minimize recording errors.

[0005]

In order to achieve the above object, in the first method of the present invention, the transmitting side is provided with control signal generating means for controlling the operating state of the recording / reproducing means (VTR), and before the start of recording. The output signal of the control signal generating means is transmitted together with the digital information signal via the transmitting means, and the receiving side connects the control signal detecting means to the receiver, and the VTR is brought into a recording state by the output signal of the control signal detecting means. Try to control.

In the second method, the transmitting side is provided with control signal generating means for controlling the operating state of the VTR, and
A second transmitting means for transmitting the output signal of the control signal generating means is provided, and the output signal of the control signal generating means is transmitted via the second transmitting means before the recording is started, and the control signal detecting means is provided on the receiving side. The output signal of the control signal detecting means
The R is controlled to the recording state, and the digital information signal transmitted via the first transmission means is recorded on the VTR.

In the third method, the magnetic tape is divided into a (a is an integer of 1 or more) recording areas in advance, and one recording area is assigned to one video software.

[0008]

According to the first method, the control signal for controlling the VTR in the recording mode is transmitted by the same transmission line such as radio waves or a cable before transmitting the digital information signal of the transmitted video software. Upon reception of this control signal, the demodulator on the receiving side immediately sets the VTR to the recording state.

In the second method, the control signal for controlling the VTR in the recording mode is different from the transmission line through which the digital information signal is transmitted, such as a telephone, before the transmission of the digital information signal of the transmitted video software. The second demodulator on the receiving side, which is transmitted via the second transmission line such as a line, sets the VTR to the recording state immediately or after a certain time after receiving the control signal.

In the third method, the magnetic tape is divided into a plurality of recording areas in advance (preformatting), one recording area is assigned to one video software, and recording is sequentially performed from the tape start portion. At this time, the recording information of the video data recorded in each area is recorded at the beginning or the end of each area, and the area to be recorded next is automatically selected according to the content of the recording information. Control to do.

[0011]

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 recording / reproducing apparatus according to the present invention, which is roughly divided into a transmitting system 100, a receiving system 200 and a recording / reproducing system 300, where 1 is an input terminal and 10 is an input terminal. Is a transmission system encoder, 20 is a time axis compressor, 25 is a modulator, 30 is a transmission line, 35 is a demodulator, 40 is a recording system encoder, 45 is a changeover switch, 50 is a rotary drum, and 51a and 51b are magnetic. Head, 60 is a magnetic tape, 70 is a reproducing decoder, 80 is a receiving decoder, 9
Is an output terminal, 2 is a recording / reproducing system control signal input terminal, and 65 is a recording / reproducing system control signal detecting circuit. In the magnetic heads 51a and 51b, (+) is positive azimuth and (-).
Indicates negative azimuth.

In FIG. 1, a digital information signal input from an input terminal 1 is encoded by a transmission encoder 10 in a predetermined format, and a time axis compressor 20 outputs 1
/ N is time-axis compressed to increase the transmission rate by n times, modulated by the modulator 25, and sent to the transmission line 30.

In the receiving system 200, the signal received via the transmission line 30 is demodulated by the demodulator 35, and the demodulated signal is directly recorded in the recording / reproducing system 300 in the state of being encoded in the transmitting system. It is supplied to the system encoder 40. The recording encoder 40 records and encodes the supplied signal in a format suitable for recording and reproduction.

FIG. 2 is a block diagram showing an example of the configuration of the recording system encoder 40. Reference numeral 41 is a storage circuit, 42 is an interface circuit, 43 is a parity generation circuit, and 44 is a recording signal generation circuit. In the figure, the receiving system 200
The data demodulated by the demodulator 35 is first stored in the storage circuit 41 via the interface circuit 42. FIG. 3A shows this demodulated data. Parity generation circuit 4
In 2, the parity is generated from the demodulated data stored in the storage circuit 41 and stored in the storage circuit 41. The recording signal generation circuit 43 reads the demodulated data and the parity stored in the storage circuit 41, adds the synchronization signal and the ID signal, and outputs them as a block format signal as shown in FIG.

FIG. 4 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 signal encoded by the recording system in this way is passed through the changeover switch 45 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.

FIG. 5 shows the track pattern at this time. The rotation speed of the rotary drum 50 and the running speed of the magnetic tape 60 are set to R ₁ and V ₁ as in the conventional case.
P is the track pitch, and W is the magnetic heads 51a, 5
The head width is 1b. In this embodiment, this head width W
Is set to be larger than the track pitch P, for example, 1.5 times.

During reproduction, the rotary drum 50 is rotated at the same speed R ₁ as during recording, and the magnetic tape 60 is 1 / n of that during recording.
Was run at a speed of V ₁ / n, the recorded signal of the magnetic head 51a, it is reproduced by 51b.

FIG. 6 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, the rotary drum 50 has the same speed R as that at the time of recording.
_Since the magnetic tape 60 is rotated at a speed V ₁ / n of 1 / n at the time of recording, the magnetic heads 51 a, 5
The scanning pitch of 1b is 1 / n of the track pitch P, and although the scanning angle is slightly deviated, scanning is performed n times per track. In this embodiment, n is set to 3 to simplify the description. W indicates the head width of the magnetic heads 51a and 51b. Usually, the head width W is set larger than the track pitch P, for example, 1.5 times.

FIG. 7 is a waveform diagram showing a process of extracting a signal from the n scans. In the figure, (A)
Indicates the timing when the rotary drum 50 is rotated at the conventional speed R ₁ / n, where a ₀ , b ₀ , a ₁ ,
It is assumed that the signals are reproduced in the order of b ₁ , a ₂ , b ₂ , a ₃ , b ₃ . T is this rotation period. (B) shows the timing when rotating at the speed of R ₁ (n = 3) according to the present embodiment, and (C) shows the magnetic heads 51a and 51b at this time.
This is the envelope of the signal reproduced by. in this way,
Since one track is scanned three times, and as described above, since the head width W of the magnetic heads 51a and 51b is set to 1.5 times the track pitch P, the scanning angle is recorded. Even if it deviates from the track angle, it tracks on a considerable part. Therefore, the original data (waveform D) can be obtained by taking out 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.

Thus, by rotating the rotary drum 50 at the same speed as during recording during reproduction as well, the frequency during reproduction can be increased without lowering the coefficient n of time axis compression, and the desired reproduction output can be obtained. The level can be secured. Also, the rotation control of the rotary drum 50 is simplified. Further, since the scanning is performed n times per track, the data can be reproduced even if the tracking is deviated, so that there is an effect that the precise tracking control is unnecessary.

FIG. 8 is a block diagram showing an example of the configuration of a reproducing system decoder 70 for performing the processing of the entire reproducing system including the processing for extracting a signal from the above n times of scanning, and 71 is a storage circuit. , 72 is a block reproduction circuit, 73 is an error correction circuit, and 74 is a reproduction signal output circuit. In the figure, the signals reproduced by the magnetic heads 51a and 51b are first inputted to the block reproducing circuit 72. The block reproducing circuit 72 detects the sync signal and the ID signal,
The data is stored in a predetermined position on the memory circuit 71 based on the track number and the block number in the ID signal. Error correction circuit 73
Then, an error in the reproduced data is corrected using the parity stored in the storage circuit 71, and at the same time, a pointer indicating the error state is generated and stored in the storage circuit 71. At this time, the data of the same track number and block number is input to the memory circuit 71 n times, but the data with the best error state is finally stored by the pointer. The reproduction signal output circuit 74 reads the data after the error correction processing stored in the storage circuit 71 in the order of the track number and the block number, and outputs the time-axis expanded low speed data.

The low-speed data signal subjected to the reproduction system decoding process in this manner is sent to the reception system 200, and is decoded by the reception system decoder 80 in the transmission system. Then, the signal decoded into this original digital information signal is output terminal 9
Will be output.

As described above, by arranging the receiving system decoder 80 after the recording / reproducing section 300 instead of before it, the receiving system decoder 80 can perform low-speed processing.

In such a system, a certain predetermined time is required from when the user requests the image software like himself to when the image data signal is actually transmitted. In other words, the transmission side is in the transmission standby state until the transmission video data is prepared or the transmission channel is vacant, which causes a problem that the user does not know when to operate the recording / reproducing system 300. Therefore, it is desirable that the recording / reproducing system 300 be controlled by the video data transmitting side.

The embodiment shown in FIG. 1 shows an example in which a recording / reproducing system control signal is multiplexed with a digital information signal transmitted by a satellite or a cable as the transmission path 30 and transmitted. For example, a signal that causes the recording / reproducing system 300 to be in a recording (hereinafter, referred to as REC) standby state (the drum 50 is rotating and the magnetic tape 60 is in a stop state) about 2 minutes before the video signal to be actually recorded is transmitted. Is input from the recording / reproducing system control signal input terminal 2, and the modulator 25,
Home and recording / reproducing system 3 for receiving via transmission line 30
It is transmitted together with an ID code for identifying 00. The demodulator 35, which has received this, sends the received data to the recording / reproducing system control signal detecting circuit 65, and switches the changeover switch 45 of the recording / reproducing system 300 to enter the REC standby state.

Next, about 1 second before the digital information signal is transmitted, a signal for putting the recording / reproducing system 300 into the REC state is transmitted, and the recording / reproducing system control signal detecting circuit 65 causes the recording / reproducing system 3 to operate.
00 is set to the REC state, and the digital information signal is recorded on the magnetic tape 60. At the end of the digital information signal, a stop signal is immediately transmitted to stop the recording / reproducing system 300.

With such a configuration, the user confirms that the magnetic tape 60 is inserted in the recording / reproducing system 300, and the recording / reproducing system 300 itself controlled by the transmitting system 100 performs the subsequent operation processing. Since it is performed, no operation is required and recording can be performed reliably. This control data is (1)
Since there are only three states of REC standby, (2) REC, and (3) stop, 2 bits are sufficient. Also, the transmission time is not limited to the above value.

FIG. 9 shows an embodiment of the transmission data format according to the present invention.

In FIG. 9, the synchronization signal, ID data, and I
It is composed of a parity for D data, a digital information signal to be recorded, and an error correction code for a digital information signal. For example, DAT (Digital Audio Tap).
e), the same as that used in BS PCM voice, etc., and is general.

As shown in FIG. 9, the above-mentioned recording / reproducing system control signal may be put in this ID data section together with the home / recording / reproducing system (VTR) discrimination signal (user code). At this time, if the recording format shown in FIG. 3 is followed, the recording / reproducing system control signal will also be recorded, but it is possible to control not to record only the control signal by the recording signal generation circuit 44, Further, even if recording is performed, the reproducing system decoder 70 may be controlled so as to ignore this signal during reproduction.

FIG. 10 is a block diagram showing another embodiment of the present invention. The same parts as those in FIG. 1 are denoted by the same reference numerals, 26 is a modulator, 31 is a transmission line, and 36 is a demodulator. 1 is different from that of FIG.
, Which is transmitted by a telephone line, for example, and is provided with a dedicated modulator 26 and demodulator 36. The actual transmission data may be 2-bit information as described in the embodiment of FIG. 1, and in the embodiment of FIG. 10, no extra information signal is superposed on the transmission line 30 for transmitting the digital information signal. This has the effect of simplifying the system hardware. Also, the modulator 26 and the demodulator 36 may be low-speed ones.

However, in the present embodiment, when a telephone line is used as the transmission line 31, it takes about 2 seconds to connect the line, and when the line is very busy, the recording / reproducing system 300 is used. There is a possibility that a state in which the REC state cannot be switched instantaneously occurs. Therefore, as described above, at the time of transmitting the REC standby signal which is transmitted about 2 minutes before the digital information signal is transmitted, the reservation information of the recording time is transmitted in advance, and the recording / reproducing system 300 is set to the REC state at the digital information signal transmission start time. Just do it.
Of course, the built-in timer of the recording / reproducing system 300 may be always synchronized with the transmitting side timer, or the timer may be synchronized when the REC standby signal is transmitted. With this configuration, the recording / reproducing system 30 that transmits data via the transmission path 31.
Although the control information amount of 0 increases, the recording / reproducing system 3
00 can be reliably controlled to the REC standby, REC, and stop states. This method can of course be applied to the embodiment shown in FIG.

In the embodiment shown in FIG. 10, the transmission line 3
Since a two-way reception is possible because the telephone line is used for 1, the transmitting side can judge the operating condition of the recording / reproducing system 300. Therefore, if the receiving side has a modulator and the transmitting side has a demodulator, the recording / reproducing system It is also possible to issue a warning to the user when 300 is malfunctioning. Therefore, there is an effect that recording can be more surely performed in the embodiment of FIG. .

Under the control of the recording / reproducing system 300 as shown in FIGS. 1 and 10, the recording / reproducing system 300 has at least three modes including a reproducing mode for the user to operate, a fast-forward mode, and a rewinding mode. Since it can be configured with only a switch for switching between, the operation of the device is very simple.

FIG. 11 is a diagram showing an example of the recording format of the magnetic tape 60 used in the recording / reproducing system 300. In FIG. 11, the magnetic tape 60 is divided into, for example, three areas in the longitudinal direction so that three video software can be continuously recorded.

Here, if another set of magnetic heads 51a and 51b is provided to form two channels and n = 6, for example, to record software for 2 hours (120 minutes), use of the magnetic tape 60 is used. The amount corresponds to 40 minutes on a conventional VTR. Generally, movie software requires less than two and a half hours, so a recording area of 50 minutes is required for each movie. For example, if a commercially available 160-minute tape is used, three software can be recorded continuously. become.

In the embodiment of FIG. 11, the magnetic tape 60 is pre-formatted in advance, and the recording information is recorded at the leading positions of the recording areas divided into three areas, area 1, area 2 and area 3. This information includes the area number,
There are recording time data, recording date data, etc., and in addition, title data may be recorded. Also, the recording time data and recording date data of the digital information signal of the previous area are recorded again at the head positions of area 2 and area 3, respectively.

Here, the case where three kinds of software are recorded at different dates and times will be described. Normally, the digital information signal is recorded in the order of area 1 → area 2 → area 3. When recording up to area 3, magnetic tape 6
0 is rewound and then recorded in area 1. At this time, the recording date data recorded in the foremost part or the last part of area 1 is read, and if the digital information signal in area 1 is still within the expiration date. Fast-forwards the magnetic tape 60, then refers to the recording date data in area 2, and once again within the expiration date, temporarily cancels the recording mode and waits for input from the user. If the user does not need it even if the expiration date of the already recorded software remains, the user sets the recording / reproducing system 300 again to the REC mode and records in either area 1 or area 2. If all the software is still needed, the magnetic tape 60 is replaced. This operation may be performed in the REC standby state described above.

By the area division structure of this tape, 3
Since the two areas are accessed uniformly, the tape damage is dispersed and the life of the magnetic tape 60 can be extended. Therefore, the user need not take out the magnetic tape 60 from the recording / reproducing system 300 frequently without worrying about the remaining amount of the magnetic tape 60, and the reliability of the mechanical section is also improved. Further, since the recording start position is known in advance, there is also an advantage that cueing can be performed at an extremely high speed. Further, the control of the recording / reproducing system 300 is simple and the hardware cost is low.

With the above construction, when the digital information signal to be recorded exceeds two and a half hours, it is sufficient to control so as to use two areas. Further, as shown in FIG. 11, in the area 3, the recorded information recording section may be located immediately after the digital information signal recording section, not at the end of the area. Similarly, the recording information of area 1 and area 2 may be immediately after the digital information signal recording section of each area.

The recording time and recording date data signals are shown in FIG.
Although it may be put in the ID shown in, the magnetic tape 60 is generally stopped at the time when one piece of software is finished. Therefore, it is better to use the format described in FIG. Speed increases. When the user stops the magnetic tape 60 in the middle of the area, the magnetic tape 60 may be fast-forwarded or rewound to the area recording information section.

FIG. 12 shows another embodiment of the magnetic tape format. According to the format of FIG. 12, the recorded data information is recorded at the beginning of the area immediately before recording starts and at the beginning of the next area immediately after recording ends, respectively. This feature is that since the recording information of other areas is entered at the start of area 2 and area 3, the search speed can be further increased as compared with the embodiment of FIG.

The area division method of the recording magnetic tape 60 has been described above. In the recording / reproducing system 300 shown in FIGS. 1 and 10, the digital information signal is sequentially supplied from the head of the magnetic tape 60 without dividing the area. You may record it.

In consideration of the high speed search, the recording information of this area recording information is preferably about 10 seconds, and multiple writing of data is performed.

In the system as described above,
The next REC standby signal may be input during reproduction of the digital information signal recorded by the recording / reproducing system 300.
At this time, the magnetic tape 60 is controlled so that the magnetic tape 60 can be immediately fed to the next area or rewound to start recording. At the same time, a display indicating REC standby is provided on the TV screen or a part of the receiver.
Next, when the recording / reproducing system 300 is in the REC state, the screen may be switched to a normal TV broadcast screen to display during REC, or the TV screen may be turned off. These controls can be easily performed by a microcomputer installed in a normal VTR.

Needless to say, conventional TV broadcasting can be recorded by connecting a normal video signal processing circuit to the recording / reproducing system 300.

[0049]

As described above, by using the magnetic recording / reproducing apparatus of the present invention, the digital information signal transmitted by the satellite or the cable can be surely recorded.

Further, in another embodiment, by recording the magnetic tape by dividing it into areas, it is possible to perform a cue search at a higher speed and to extend the life of the tape.

[0051]

[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 waveform chart showing an operation during 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 a configuration example of an output signal of a transmission encoder according to the present invention.

FIG. 10 is a block diagram showing another embodiment of the digital information recording / reproducing apparatus according to the present invention.

FIG. 11 is an area division diagram of a magnetic tape showing another embodiment of the present invention.

FIG. 12 is an arrangement diagram of recorded information signals showing another embodiment of the present invention.

[Explanation of symbols]

100 ... Transmission system, 200 ... Reception system, 300 ... Recording / reproduction system 1 ... Input terminal, 10 ... Transmission system encoder, 20 ... Time axis compressor, 25 ... Modulator, 30 ... Transmission line, 35 ... Demodulator, 4
0 ... Recording system encoder, 45 ... Changeover switch, 50 ... Rotating drum, 60 ... Magnetic tape, 70 ... Reproduction system decoder, 80
... reception system decoder, 2 ... recording / reproduction system control signal input terminal 65 ... recording / reproduction system control signal detection circuit, 26 ... modulator,
31 ... Transmission path, 36 ... Demodulator

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Hiroo Okamoto Inventor Hiroo Okamoto 292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa Inside the Video Media Research Laboratory, Hitachi, Ltd. (72) Nobutaka Amada 292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa Hitachi, Ltd. Visual Media Research Center

Claims (3)

[Claims] 1. A coding means for coding a digital information signal to be transmitted in a predetermined format, a time compression means for time-axis compressing an output signal of the coding means to 1 / n, and the time-axis compression means. Means for modulating the output signal of the transmitting means, a transmitting means for transmitting the output signal of the modulating means via a transmission line, a demodulating means for demodulating the output signal of the transmitting means, and an output signal of the demodulating means for a predetermined signal. Recording / reproducing means for recording on a magnetic tape at a speed n times the speed and reproducing the signal recorded on the magnetic tape at the predetermined speed, and a signal reproduced from the recording / reproducing means according to the predetermined format. A digital information recording / reproducing apparatus comprising a decoding means for decoding and shortening the transmission and recording time of the digital information signal to 1 / n. Control for controlling the operating state of the recording / reproducing means on the transmission side. Signal generation means, the output signal of the control signal generation means is transmitted together with the digital information signal via the transmission means, and the control signal detection means is connected to the output of the demodulation means on the receiving side to detect the control signal. A digital information recording / reproducing apparatus characterized in that the operation state of the recording / reproducing means is controlled by an output signal of the means. 2. A coding means for coding a digital information signal to be transmitted in a predetermined format, a time compression means for time-axis compressing an output signal of the coding means to 1 / n, and the time-axis compression means. Means for modulating the output signal of the first transmitting means, first transmitting means for transmitting the output signal of the modulating means via a transmission path, demodulating means for demodulating the output signal of the first transmitting means, and the demodulating means And a recording / reproducing means for reproducing the signal recorded on the magnetic tape at a predetermined speed, and a signal reproduced from the recording / reproducing means. A digital information recording / reproducing apparatus having a transmission / recording time of the digital information signal shortened to 1 / n, comprising a decoding means for decoding in accordance with the predetermined format, and an operating state of the recording / reproducing means on the transmission side. Control signal generating means for controlling is transmitted, the output signal of the control signal generating means is transmitted by the second transmitting means, control signal detecting means is provided on the receiving side, and the recording / reproducing is performed by the output signal of the control signal detecting means. A digital information recording / reproducing apparatus characterized by controlling the operating state of the means. 3. Encoding means for encoding a digital information signal to be transmitted in a predetermined format, time compression means for time-axis compressing the output signal of the encoding means to 1 / n, and said time-axis compression means. Means for modulating the output signal of the transmitting means, a transmitting means for transmitting the output signal of the modulating means via a transmission line, a demodulating means for demodulating the output signal of the transmitting means, and an output signal of the demodulating means for a predetermined signal. Recording / reproducing means for recording on a magnetic tape at a speed n times the speed and reproducing the signal recorded on the magnetic tape at the predetermined speed, and a signal reproduced from the recording / reproducing means according to the predetermined format. A digital information recording / reproducing apparatus comprising a decoding means for decoding and shortening the transmission and recording time of the digital information signal to 1 / n, wherein the magnetic tape is a (a is an integer of 1 or more) in advance. Divided into pieces of the recording area, the head portion of the recording area divided respectively, and finally part, digital information recording and reproducing apparatus is characterized in that so as to record the record recording information data of the recording area.