Abstract:
A digital information transmitting, receiving and/or recording/reproducing system, provided with the digital information transmitting apparatus for transmitting the digital information to a transmission path, a receiving apparatus for receiving the transmitted digital information and a recording/reproducing apparatus for the recording received digital information to a recording media and reproducing therefrom. The apparatus includes a compressor which compresses the digital information, a transmission parity signal adder which adds a transmission parity signal to the output signal of the compressor in order to correct an error occurring in the transmission path, wherein the transmission parity signal is different from a record parity signal to be added at the recording apparatus and a transmitter which transmits the transmission parity signal added compressed digital information added by the transmission parity signal adder to the transmission path.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This is a continuation application of U.S. Ser. No. 09/567,005, filed May 9, 2000, which is a continuation application of U.S. Ser. No. 09/326,595, filed Jun. 7, 1999 now U.S. Pat. No. 6,069,757, which is a continuation of U.S. application Ser. No. 09/188,303, filed Nov. 10, 1998, now U.S. Pat. No. 6,002,536, which is a continuation of U.S. application Ser. No. 08/917,176, filed Aug. 27, 1997, now U.S. Pat. No. 5,862,004, which is a continuation of U.S. application Ser. No. 08/620,879, filed Mar. 22, 1996, now U.S. Pat. No. 5,699,203, which is a continuation of U.S. application Ser. No. 08/457,597, filed Jun. 1, 1995, now U.S. Pat. No. 5,530,598, which is a continuation of U.S. application Ser. No. 08/457,486, filed Jun. 1, 1995, now U.S. Pat. No. 5,517,368, which is a continuation of U.S. application Ser. No. 08/238,528, filed May 5, 1994, now U.S. Pat. No. 5,671,095, which is a divisional of U.S. application Ser. No. 07/727,059, filed Jul. 8, 1991, now U.S. Pat. No. 5,337,199, the subject matter of which are incorporated by reference herein. 
    
    
     BACKGROUND OF THE INVENTION 
     The present invention relates to a system for transmitting a digital video signal and recording the received video signal. More particularly, the present invention relates to great extension of the range of use of a digital signal recording/reproducing system by greatly shortening a recording time through transmission of a video signal in a compressed form, and further relates to great extension of the range of use of a digital signal recording/reproducing system by making the number of signals to be recorded and a recording/reproducing time variable. 
     As a digital magnetic recording/reproducing system (hereinafter referred to as VTR) is conventionally known, for example, a D2 format VTR. In such a conventional digital VTR, the elongation or shortening of a reproducing time is possible by using variable-speed reproduction. However, the prior art reference does not at all disclose high-speed recording in which a recording time is shortened to 1/m, multiple recording in which a plurality of signals are recorded, and the compression/expansion of a recording/reproducing time. 
     The above-mentioned conventional digital VTR has a feature that a high quality is attained and there is no deterioration caused by dubbing. However, the shortening of a dubbing time is not taken into consideration. Therefore, for example, in the case where a two-hour program is to be recorded, two hours are required. Thus, there is a drawback that inconveniences are encountered in use. Also, the multiplexing of recording signals is not taken into consideration. Therefore, for example, when two kinds of programs are to be simultaneously recorded or reproduced, two VTR&#39;s are required. This also causes inconveniences in use. 
     SUMMARY OF THE INVENTION 
     An object of the present invention is to provide a digital VTR in which high-speed recording onto a tape can be made with the same format as that used in standard-speed recording, to provide a transmission signal processing system for transmitting at a high speed a video signal to be recorded by such a digital VTR, and to extend the range of use of the digital VTR by shortening a recording time. For example, the digital VTR can be used in such a manner that a two-hour program is recorded in about ten minutes and is reproduced at a standard speed. 
     The above object is achieved as follows. A video signal and an audio signal are subjected to time-base compression to 1/m, bit compression to 1/n, addition of a parity signal and modulation, and are thereafter transmitted or outputted. The transmitted signal is received, is subjected to demodulation, error correction, addition of a parity signal and modulation, and is thereafter recorded, onto a magnetic tape which travels at a travel speed m times as high as that upon normal reproduction, by use of a magnetic head on a cylinder which rotates at a frequency m times as high as that upon normal reproduction. The signal on the magnetic tape traveling at a travel speed upon normal reproduction is reproduced by a magnetic head on the cylinder which rotates at a frequency upon normal reproduction. The reproduced signal is subjected to demodulation, error correction, bit expansion of video and audio signals and D/A conversion, and is thereafter outputted. Address signals corresponding to a plurality of VTR&#39;s may be transmitted prior to a signal to be recorded. Further, control signals indicative of the start of recording and the stop of recording may be transmitted. The transmitted signals are received and error-corrected, and controls of the standby for recording, the start of recording and the stop of recording are made on the basis of the control signals. 
     With the above construction, since the video signal and the audio signal are time-base compressed to 1/m and bit-compressed to 1/n, a transmission time is shortened to 1/m and a signal band turns to m/n. The time-base compressed and bit-compressed signal is transmitted after addition of a parity signal for error correction and modulation to a code adapted for a transmission path. The transmitted signal is received and demodulated. The detection of an error produced in a transmitting system and the correction for the error can be made using the added parity signal. The error-corrected signal is added with a parity signal for correction for an error produced in a magnetic recording/reproducing system and is modulated to a code adapted for the magnetic recording/reproducing system. Upon recording, since the rotation frequency of the cylinder and the travel speed of the magnetic tape are increased by m times, the recording onto the magnetic tape can be made at an m-tuple speed. Upon reproduction, by setting the rotation frequency of the cylinder and the travel speed of the magnetic tape to normal ones, the reproduction at a normal speed can be made. The reproduced signal is code-demodulated. The detection of an error produced in the magnetic recording/reproducing system and the correction for the error can be made on the basis of the parity signal. By bit-expanding the video signal and the audio signal compressed by the transmission signal processing system, the original video and audio signal can be restored. The bit-expanded signal is converted into an analog signal by a D/A converter. Simultaneous and selective control of the start/stop of recording for a multiplicity of VTR&#39;s can be made in such a manner that the address signals corresponding to the VTR&#39;s are transmitted prior to a signal to be recorded, the correction for an error of the received signal is made, required VTR&#39;s are brought into recording standby conditions by the corrected address signals, and the controls of the start of recording and the stop of recording are made by the transmitted control signals. 
     Another object of the present invention is to provide a digital signal recording/reproducing system in which multiple recording onto a tape can be made with the same format as that used in standard recording and simultaneous multiple reproduction is possible, and to extend the range of use of a digital VTR by compressing/expanding a recording/reproducing time in accordance with the transmission rate of a multiplexed input/output signal and the number of signals in the multiplexed input/output signal. 
     This object is achieved as follows. There are provided means for selecting one or plural desired signals from a time-base compressed and time-division multiplexed digital input signal, and helical scan recording means for making time-division multiplex recording of the selected signals with a time-base compressed speed after selection being retained. There is further provided means for reproducing the recorded signals with the rotation speed of a cylinder, a tape speed and so on being set to values proportional to the transmission rate of a reproduction signal and the number of signals to be simultaneously reproduced and with the signal being time-base expanded or being retained as time-base compressed. 
     With the above construction, N kinds of desired signals selected from the multiplexed input digital signal and time-base compressed to 1/K are subjected to time-division multiplex recording with a time-base compressed speed after selection being retained. Upon reproduction, for example, if both the cylinder rotation speed and the tape speed are set to N/K times, a recording track and a reproducing track coincide with each other and the use of a reproducing time K/N times as long as a recording time enables the reproduction of each of the N kinds of signals at a standard speed. Also, if both the cylinder rotation speed and the tape speed are set to (M×N)/K times, a recording track and a reproducing track coincide with each other and the use of a reproducing time as K/(M×N) times as long as the recording time enables the reproduction of each of the N kinds of signals at an M-tuple speed. In the case where L kinds of signals are selected from among the N kinds of reproduced signals and a processing speed at a reproduction signal processing circuit is set to L×M times as long as a standard reproduction processing speed, each of the L kinds of signals among the N kinds of multiple-recorded signals is outputted at a speed M times as high as a standard speed. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a block diagram of a digital transmission signal processing system and a recording/reproducing system according to an embodiment of the present invention; 
     FIG. 2 is a block diagram of a recording/reproducing system according to another embodiment of the present invention; 
     FIG. 3 is a diagram for explaining the conventional parity adding method; 
     FIG. 4 is a block diagram of a recording/reproducing system according to still another embodiment of the present invention; 
     FIG. 5 is a block diagram of a digital transmission signal processing system and a recording/reproducing system according to a further embodiment of the present invention; 
     FIG. 6 shows the format of control signals used in one of applications of the present invention; 
     FIG. 7 is a block diagram of a still further embodiment of the present invention; 
     FIG. 8 shows one example of the specification of signals to be recorded; 
     FIG. 9 is a block diagram of a furthermore embodiment of the present invention; 
     FIGS. 10,  11  and  12  are block diagrams of different examples of applications of the present invention; 
     FIG. 13 is a block diagram for explaining one example of the operation of the embodiment shown in FIG. 7; 
     FIG. 14 is a timing chart showing the waveforms of signals involved in the example shown in FIG. 13; 
     FIG. 15 is a block diagram for explaining another example of the operation of the embodiment shown in FIG. 7; 
     FIG. 16 is a timing chart showing the waveforms of signals involved in the example shown in FIG. 15; 
     FIG. 17 is a table showing some applications of the examples shown in FIGS. 13 and 15; 
     FIG. 18 is a block diagram of a still furthermore embodiment of the present invention; and 
     FIGS. 19 and 20 are signal diagrams for explaining different operations of the embodiment shown in FIG.  18 . 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     An embodiment of the present invention will now be explained by use of FIG.  1 . In the figure, reference numerals  1  and  40  denote magnetic tapes, numerals  2 ,  3 ,  41  and  42  magnetic heads, numerals  4  and  43  cylinders, numerals  5  and  44  capstans, numerals  10  and  50  servo control circuits, numerals  20 ,  31  and  60  demodulation circuits, numerals  21 ,  32  and  61  error correction circuits, numerals  22  and  23  compression circuits, numerals  24  and  33  parity addition circuits, numerals  25  and  34  modulation circuits, numerals  26  a transmission circuit, numeral  27  a transmission path, numeral  30  a reception circuit, numerals  62  and  63  expansion circuits, numerals  64  and  65  D/A conversion circuits, numeral  70  a video signal output terminal, and numeral  71  an audio signal output terminal. 
     Firstly, the operation of a transmission signal processing system will be explained. Digital video and audio signals recorded on the magnetic tape  1  are reproduced by the magnetic heads  2  and  3  mounted on the cylinder  4  and are inputted to the demodulation circuit  20 . The magnetic tape  1  travels by virtue of the capstan  5 . The travel speed of the magnetic tape  1  and the rotation frequency of the cylinder  4  are, for example, ten times as high as the tape travel speed and the cylinder rotation speed upon normal reproduction. Accordingly, the signal inputted to the demodulation circuit  20  is a signal time-compressed to one tenth. For example, a 120-minute signal recorded on the magnetic tape  1  can be reproduced in 12 minutes. 
     Generally, in the case where a digital signal is to be recorded on a magnetic recording medium, the signal is recorded after having been modulated into scrambled NRZ code, M 2  code or the like. The demodulation circuit  20  performs a demodulation processing, that is, a signal processing for restoring the thus modulated signal into original digital data. The signal demodulated by the demodulation circuit  20  is inputted to the error correction circuit  21  in which erroneous data produced in a magnetic recording/reproducing process is detected and the correction for the erroneous data is made. Further, the signal is separated into a video signal and an audio signal which are in turn inputted to the compression circuits  22  and  23 , respectively. The video signal is bit-compressed through, for example, discrete cosine conversion. The audio signal is bit-compressed through, for example, non-linear quantization or differential PCM. As a result, the transmission rate of the video signal and the audio signal in total is reduced to, for example, one twentieth. 
     Output signals of the compression circuits  22  and  23  are inputted to the parity addition circuit  24  for performing a signal processing which includes adding a parity signal for error correction and outputting the video signal and the audio signal serially in accordance with a transmission format. A serial output signal of the parity addition circuit  24  is inputted to the modulation circuit  25 . In the modulation circuit  25 , the serial signal is modulated in accordance with the characteristic and the frequency band of the transmission path  27 . For example, in the case where the signal is transmitted in an electric wave form, quadruple phase shift keying (QPSK) is made. The modulated signal is inputted to the transmission circuit  26  from which it is outputted to the transmission path  27 . 
     As apparent from the foregoing explanation of the operation of the transmission signal processing system, it is possible to transmit a signal at a speed which is ten times as high as a normal speed. 
     The above embodiment has been shown in conjunction with the case where a signal from the VTR is reproduced. However, a signal source is not limited to the VTR and may include a magnetic disk device, an optical disk device or the like. 
     Next, explanation will be made of the operation of the VTR for receiving and recording the transmitted signal. The signal transmitted from the transmission signal processing system is received by the reception circuit  30 . The received signal is inputted to the demodulation circuit  31 . The demodulation circuit  31  is provided corresponding to the modulation and demodulates the signal to the original signal. The demodulated signal is inputted to the error correction circuit  32  in which the detection of and the correction for an error produced in the transmission path  27  are made on the basis of the parity signal added by the parity addition circuit  24 . At this time, in the case where the S/N ratio of the transmission system is not sufficient so that complete correction for the error is impossible, correction is made through, for example, signal replacement, by use of the signal correlation. 
     An output signal of the error correction circuit  32  is inputted to the parity addition circuit  33 . In the parity addition circuit  33 , a parity signal for detecting an error produced in a recording/reproducing process and making correction for the error is added. The parity-added signal is inputted to the modulation circuit  34 . In the modulation circuit  34 , the signal is modulated to scrambled NRZ code, M 2  code or the like as mentioned above. The modulated signal is recorded on the magnetic tape  40  by the magnetic heads  41  and  42  mounted on the cylinder  43 . 
     Since the signal supplied to the magnetic heads  41  and  42  is a signal which is time-base compressed to one tenth as compared with a signal upon normal operation, the servo control circuit  50  controls the cylinder  43  and the capstan  44  so that the rotation frequency of the cylinder  43  and the travel speed of the magnetic tape  40  become ten times as high as those upon normal recording. Also, in order to record a predetermined signal at a predetermined position on the magnetic tape  40 , synchronization information is detected from the received signal to control the phase of rotation of the cylinder  41  on the basis of the detected synchronization information. 
     Next, the operation of the VTR for reproducing the thus recorded signal will be explained. Upon reproduction, the travel speed of the magnetic tape  40  and the rotation frequency of the cylinder  43  are set to those upon normal reproduction. The reproduced signal is inputted to the demodulation circuit  60 . The demodulation circuit  60  is provided corresponding to the modulation circuit  34  and demodulates the modulated signal. The demodulated signal is inputted to the error correction circuit  61  in which the detection of an error produced in the magnetic recording/reproducing system and the correction for the error are made on the basis of the parity signal added by the parity addition circuit  33 . In the case where there is an error which cannot be corrected, the error is properly corrected by use of the signal correlation. Also, the signal is outputted after having been separated into a video signal and an audio signal. 
     The video signal is inputted to the expansion circuit  62 . The expansion circuit  62  is provided corresponding to the compression circuit  22  and restores the compressed video signal into the original video signal. An output signal of the expansion circuit  62  is inputted to the D/A conversion circuit  64  and is converted thereby into an analog video signal which is in turn outputted from the terminal  70 . 
     The audio signal is inputted to the expansion circuit  63 . The expansion circuit  63  is provided corresponding to the compression circuit  23  and restores the compressed audio signal into the original audio signal. An output signal of the expansion circuit  63  is inputted to the D/A conversion circuit  65  and is converted thereby into an analog audio signal which is in turn outputted from the terminal  71 . 
     In the foregoing, the embodiment of the present invention has been shown and the operation thereof has been explained. According to the present invention, a video signal and an audio signal over a long time can be transmitted and recorded in a short time, thereby making it possible to extend the range of use of the digital VTR. 
     Another embodiment of the present invention is shown in FIG.  2 . FIG. 2 is partially similar to FIG.  1 . The same parts in FIG. 2 as those in FIG. 1 are denoted by the same reference numerals as those used in FIG.  1  and detailed explanation thereof will be omitted. The embodiment shown in FIG. 2 concerns a VTR in which a signal transmitted/received at a high speed can be recorded while being monitored. 
     In FIG. 2, reference numeral  80  denotes a change-over switch, numeral  81  an error correction circuit, and numeral  82  a memory circuit. An error-corrected video signal outputted from the error correction circuit  81  is inputted through the memory circuit  82  to a terminal R side of the change-over switch  80  which is selected upon recording. The memory circuit  82  has a memory capacity for at least one field. The video signal received at a high speed is stored into a memory of the memory circuit  82  with the number of frames being reduced. The stored signal is read from the memory at a normal speed and is inputted to an expansion circuit  62 . 
     Upon reproduction, a video signal output of an error correction circuit  61  is inputted to a terminal P side of the change-over switch  80  which is selected upon reproduction. Accordingly, the operation of the embodiment of FIG. 2 upon reproduction is similar to that of the embodiment shown in FIG.  1 . 
     In the embodiment shown in FIG. 2, upon recording, the video signal outputted from the error correction circuit  81  is inputted to the expansion circuit  62  through the memory circuit  82 . Alternatively, an output signal of a modulation circuit  34  may be inputted to a demodulation circuit  60  through a memory circuit. Also, in the case where the operating speed of the demodulation circuit  60  or the error correction circuit  61  leaves a margin, a memory circuit may be properly placed at a post stage. Or, in the case where the storage capacity of the error correction circuit  61  or the expansion circuit  62  leaves a margin, the circuit may be used as a memory circuit or any additional memory circuit may be omitted. 
     As has been explained in the above, the embodiment shown in FIG. 2 makes it possible to record a received video signal while monitoring it in the form of a picture having a reduced number of frames. 
     In the embodiment shown in FIG. 1, the parity signal is added in order to make the detection of and the correction for an error which may be produced in the transmission system or the magnetic recording/reproducing system. One example of a parity adding method is shown in FIG. 3 in conjunction with the case of a D 2  format VTR. In the D 2  format VTR, a signal for one field is divided into a plurality of segments for signal processing. FIG. 3 shows one segment. In FIG. 3, reference numeral  90  represents a group of video data, numeral  91  a group of outer code parities, and numeral  92  a group of inner code parities. Firstly, outer code parities are added for data of the matrix-like arranged video data group  90  which lie in a vertical direction in FIG.  3 . Thereafter, inner code parities are added for data of the video data group  90  and the outer code parity group  91  lying in a horizontal direction in FIG. 3, thereby producing a signal to be recorded. Though detailed explanation of the generation of parities will be omitted herein, the parities are generated in accordance with a generating function G(x). 
     In the embodiment shown in FIG. 1, if the same parity generation manner is employed by the parity addition circuits  24  and  33 , the error correction circuits  32  and  61  may hold the most part thereof in common. Namely, since the error correction circuits  32  and  61  are circuits which are respectively used upon recording and upon reproduction, it is possible to reduce the circuit scale or size by using the most part of the circuits  32  and  61  in common. 
     Further, in the case where the same parity generation manner is employed by the parity addition circuits  24  and  33  in the embodiment shown in FIG. 1, it is possible to further reduce the circuit scale or size of the recording/reproducing system. The construction in that case is shown in FIG. 4 as still another embodiment of the present invention. FIG. 4 is partially common to FIG. 1 or  2 . The parts in FIG. 4 common to those in FIG. 1 or  2  are denoted by the same reference numerals as those used in FIG. 1 or  2  and detailed explanation thereof will be omitted. 
     The embodiment shown in FIG. 4 is based on a concept that an error produced in a transmission system and an error produced in a magnetic recording/reproducing system are simultaneously detected and corrected by an error correction circuit  61 . Accordingly, a signal received by a reception circuit  30  is demodulated by a demodulation circuit  31  and is inputted to a modulation circuit  34  without being subjected to error correction and parity addition. The subsequent processing is the same as that in the embodiment shown in FIG. 1 or  2 . Namely, a reproduced signal is inputted to the error correction circuit  61  after demodulation by a demodulation circuit  60 . As mentioned above, an error produced in the transmission system and an error produced in the magnetic recording/reproducing system are simultaneously detected and corrected by the error correction circuit  61  in the reproducing system. 
     In the embodiment shown in FIG. 4, the error correction circuit  32  and the parity addition circuit  33  can be removed as compared with the embodiment sown in FIG. 1 or  2 , thereby making it possible to reduce the circuit scale. 
     Though having not been mentioned in the foregoing embodiments, in a helical scan VTR as shown, since a signal becomes discontinuous when a track jump is made upon reproduction, the recording is made with an amble signal being added to the heading portion of a signal. Since the addition of an amble signal is employed in the D 2  format VTR, detailed explanation thereof will be omitted. Also, in order to define a starting position of a signal, a synchronizing signal is properly added. Since the addition of a synchronizing signal is known in, for example, the D 2  format VTR, detailed explanation thereof will be omitted. 
     In the embodiment shown in FIG. 1, the addition of an amble signal may be made by the parity addition circuit  24 . Alternatively, it may be made on the recording/reproducing system side in order to enhance the efficiency of use of the transmission path  27 . In this case, the addition of an amble signal can be made by the parity addition circuit  33 . As for the embodiment shown in FIG. 4, in the case where the addition of an amble signal is to be made on the recording/reproducing system side, the amble signal can be added by the modulation circuit  34 . In the case where the addition of an amble signal is made on the recording/reproducing system side, it is possible to enhance the efficiency of use of the transmission path  27 . On the other hand, in the case where the addition of an amble signal is made on the transmission signal processing system side, the lowering of the cost of a VTR can be attained as a great effect when a signal is sent to a multiplicity of VTR&#39;s simultaneously. 
     FIG. 5 shows a further embodiment of the present invention in which the further reduction of the circuit scale of a VTR on the receiving side and hence the further lowering of the cost can be attained in the case where a signal is sent to a multiplicity of VTR&#39;s simultaneously. 
     FIG. 5 is partially common to FIG. 1,  2  or  4 . The parts in FIG. 5 common to those in FIG. 1,  2  or  4  are denoted by the same reference numerals as those used in FIG. 1,  2  or  4  and detailed explanation thereof will be omitted. In FIG. 5, reference numeral  100  denotes a modulation circuit. The embodiment shown in FIG. 5 is based on a concept that a signal processing required upon a recording mode of a VTR is performed on the transmitting side. Namely, modulation adapted for magnetic recording/reproduction, for example, a signal processing corresponding to the modulation circuit  34  shown in FIG. 4 is performed on the transmission signal processing system side. After parities have been added by a parity addition circuit  24  of the transmission signal processing system, the modulation adapted for the magnetic recording/reproduction is performed by the modulation circuit  100 . Therefore, modulation adapted for transmission is performed by a modulation circuit  25 . As a modulation system employed by the modulation circuit  100  is suitable a system which does not cause the extension of a frequency band by modulation, for example, scrambled NRZ. A signal modulated by the modulation circuit  25  is transmitted to a transmission path  27  through a transmission circuit  26  in a manner to that in the embodiment shown in FIG.  1 . 
     The signal received by a reception circuit  30  through the transmission path  27  is inputted to a demodulation circuit  31  in which the signal is subjected to demodulation corresponding to the modulation circuit  25 . Since the signal demodulated by the demodulation circuit  31  is one which has already been subjected by the modulation circuit  10  to the modulation adapted for the magnetic recording/reproduction, the signal is recorded on a magnetic tape  40  by magnetic heads  41  and  42  as it is. As a result, the same recording as that in the embodiment shown in FIG. 4 is made. An operation upon reproduction is similar to that in the embodiment shown in FIG.  4 . 
     As apparent from the above, the present embodiment makes it possible to remarkably reduce the circuit scale of the VTR. 
     According to one of applications of the present invention, it is possible to transmit a signal from a transmission signal processing system to a multiplicity of VTR&#39;s through a transmission path simultaneously and at a high speed, as has already been mentioned. In this case, it is difficult to control a multiplicity of VTR&#39;s simultaneously. Further, it is required to make a control which causes specified ones of the VTR&#39;s to perform recording operations and specified others of the VTR&#39;s not to perform recording operations. A technique for realizing such a control will be shown just below. 
     For the above purpose, control signals are transmitted prior to transmission of a signal to be recorded. One example of the control signals is shown in FIG.  6 . In the figure, reference numeral  110  denotes a synchronizing signal, numeral  111  an ID signal indicative of a control to be made, numeral  112  an address signal indicative of a VTR to be controlled, numeral  113  a control signal for bringing a VTR designated by the address signal  112  into a recording mode, numeral  114  a control signal for stopping the recording, numerals  115  and  116  blank signals, and numeral  120  a recording signal to be actually recorded. 
     The ID signal  111  indicating the transmission of the address signals  112  indicative of VTR&#39;s in which a signal is to be recorded, is transmitted at a predetermined position relative to the synchronizing signal  110  to bring each VTR into a standby condition. After all the address signals have been transmitted, the ID signal  113  is transmitted to start the recording of the signal  120  in the designated VTR&#39;s. After the signal  120  has been transmitted, the ID signal  114  to control the stop of recording is transmitted. Each of the blank signals  115  and  116  is a signal for conforming a signal transmission format to the other transmission signal and is therefore an insignificant signal portion. 
     In the embodiments shown in FIGS. 1 and 5, those control signals are produced by a control signal generation circuit  130  and are transmitted with parities which are added by the parity addition circuit  24  for making correction for an error produced during transmission. 
     In the VTR shown in FIG. 1, the control signals are detected by a control circuit  131  after the reception by the reception circuit  30 , the demodulation by the demodulation circuit  31  and the correction by the error correction circuit  32  for an error produced during transmission to make a control for the recording and the stop of recording in the recording/reproducing system. 
     In the case of the VTR&#39;s shown in FIGS. 4 and 5, an output signal of the demodulation circuit  31  is inputted to the error correction circuit  61  for a need of making correction for an error produced during transmission and error-corrected control signals are inputted to a control circuit  131 . In a change-over circuit  132 , the terminal R side for selecting an output signal of the demodulation circuit  31  is selected upon recording and the terminal P side for selecting an output signal of the demodulation circuit  60  is selected upon reproduction. 
     As apparent from the foregoing, the present embodiment makes it possible to control a multiplicity of VTR&#39;s selectively and simultaneously. 
     Also, the use of the change-over circuit  132  and a memory circuit makes it possible to record a signal while monitoring it in the form of a picture having a reduced number of frames, as explained in conjunction with the embodiment shown in FIG.  2 . 
     Next, a still further embodiment of the present invention will be explained by use of FIG.  7 . In the figure, reference numeral  301  denotes an input terminal for standard analog video signal, numeral  302  an input terminal for standard digital video signal, numeral  303  an input terminal for high-speed digital video signal, numeral  305  a recording system mode change-over switch, numeral  306  a recording system change-over signal generation circuit, numeral  310  an A/D converter, numeral  320  a change-over circuit, numeral  330  a data compression circuit, numeral  340  a change-over circuit, numeral  350  a recording system signal processing circuit for performing a signal processing which includes addition of error correction code and modulation for recording, numeral  370  a cylinder, numeral  371  a magnetic tape, numerals  372  and  372 ′ magnetic heads, numeral  380  a reproducing system signal processing circuit for performing a signal processing which includes demodulation for reproduction, error detection and error correction. Numeral  390  a change-over circuit, numeral  400  a data expansion circuit, numeral  420  a D/A converter, numeral  431  an output terminal for standard analog video signal, numeral  432  an output terminal for standard digital video signal, numeral  433  an output terminal for high-speed digital video signal, numeral  435  a reproducing system mode change-over switch, and numeral  436  a reproducing system change-over signal generation circuit. 
     The present embodiment is an example of a digital magnetic recording/reproducing system which has recording modes of standard-speed recording and high-speed recording and reproduction modes of standard-speed reproduction and high-speed reproduction. FIG. 8 shows one example of the specification of input video signals. 
     Firstly, explanation will be made of standard-speed recording. A digital signal into which an analog video signal inputted from the input terminal  301  is converted by the A/D converter  310  or an equivalent digital signal which is inputted from the input terminal  302 , is switched or selected by the change-over circuit  320 , is subjected to a predetermined data compression processing by the data compression circuit  330  and is thereafter inputted to a terminal  340   a  of the change-over circuit  340 . In the change-over circuit  340 , a change-over to connect the terminal  340   a  and a terminal  340   c  is made by a change-over signal from the recording system change-over signal generation circuit  306 . Thereby, the data-compressed signal is inputted to the recording system signal processing circuit  350 . In the recording system signal processing circuit  350 , a signal processing such as channel division, addition of error correction code and modulation for recording is performed at a predetermined processing clock adapted for the data-compressed signal. Thereafter, the signal is supplied to the magnetic heads  372  and  372 ′ mounted on the cylinder  370  so that it is recorded onto the magnetic tape  371 . The cylinder  370  and the magnetic tape  371  are controlled by a servo control circuit  360 . The servo control circuit  360  controls a cylinder motor and a capstan motor so as to provide a cylinder rotation speed and a tape speed for standard speed and so as to be synchronized with the input video signal. 
     Next, explanation will be made of high-speed recording. A high-speed digital video signal inputted from the input terminal  303  is sent to a terminal  340   b  of the change-over circuit  340 . Since the high-speed digital video signal is a signal which has already been subjected to a data compression processing, it is not necessary to pass the signal through the data compression circuit  330 . A change-over to connect the terminal  340   b  and the terminal  340   c  is made by a change-over signal from the recording system change-over signal generation circuit  306  so that the high-speed digital video signal is inputted to the recording system signal processing circuit  350 . In the recording system signal processing circuit  350 , a signal processing similar to that in the case of the standard-speed recording is performed at a predetermined processing clock adapted for the high-speed digital video signal. Thereafter, the signal is supplied to the magnetic heads  372  and  372 ′ mounted on the cylinder  370  so that it is recorded onto the magnetic tape  371 . The cylinder  370  and the magnetic tape  371  are controlled by the servo control circuit  360 . The servo control circuit  360  control the cylinder motor and the capstan motor so as to provide a predetermined cylinder rotation speed and a predetermined tape speed and so as to be synchronized with the input video signal. 
     In the present invention, the recording onto the tape can be made with the quite same format in both the standard-speed recording and the high-speed recording, thereby making it possible to greatly shorten a recording time in the high-speed recording mode. 
     Next, explanation will be made of a signal processing upon reproduction. In the present embodiment, the recording pattern on the magnetic tape is the same whichever of the standard-speed recording and the high-speed recording is selected as a recording mode. Therefore, either standard-speed reproduction or high-speed reproduction can be selected irrespective of the recording mode. 
     Firstly, the standard-speed reproduction will be explained. The servo control circuit  360  controls the cylinder motor and the capstan motor so that a cylinder rotation speed and a tape speed for standard speed are provided. A signal reproduced by the magnetic heads  372  and  372 ′ is inputted to the reproducing system signal processing circuit  380 . In the reproducing system signal processing circuit  380 , a signal processing such as demodulation for reproduction, channel synthesis, error detection and error correction is performed at a predetermined processing clock adapted for the standard-speed reproduction. Thereafter, the signal is supplied to a terminal  390   a  of the change-over circuit  390 . In the change-over circuit  390 , a change-over to connect the terminal  390   a  and a terminal  390   c  is made upon standard-speed reproduction by a change-over signal from the reproducing system change-over signal generation circuit  436 . Thereby, the reproduced signal is supplied to the data expansion circuit  400 . In the data expansion circuit  400 , a signal processing reverse to the data compression processing upon recording is performed so that the signal is restored to the original signal. Thereby, the original transmission rate is restored. The data-expanded reproduction signal is sent to the D/A converter  420  on one hand to be outputted as an analog video signal from the output terminal  431  after D/A conversion and is sent to the output terminal  432  on the other hand to be outputted as a digital video signal therefrom. 
     Next, explanation will be made of the high-speed reproduction. The servo control circuit  360  controls the cylinder motor and the capstan motor so that a predetermined cylinder rotation speed and a predetermined tape speed adapted for the high-speed reproduction are provided. A signal reproduced by the magnetic heads  372  and  372 ′ is inputted to the reproducing system signal processing circuit  380 . In the reproducing system signal processing circuit  380 , a signal processing such as demodulation for reproduction, channel synthesis, error detection and error correction is performed at a predetermined processing clocks adapted for the high-speed reproduction. Thereafter, the high-speed reproduction signal is supplied to the terminal  390   a  of the change-over circuit  390 . In the change-over circuit  390 , a change-over to connect the terminal  390   a  and a terminal  390   b  is made upon high-speed reproduction. Thereby, the high-speed digital video signal is outputted from the output terminal  433 . 
     A furthermore embodiment of the present invention will be explained by use of FIG.  9 . The construction of the present embodiment is similar to that of the embodiment shown in FIG. 7 but is different therefrom in that the change-over circuit  340  is placed at a different position, the change-over circuit  390  used in FIG. 7 is eliminated and a change-over circuit  345  is newly added. 
     An input/output signal upon standard-speed recording/reproduction in the present embodiment is the same as that in the embodiment shown in FIG.  7 . As for high-speed recording and high-speed reproduction, however, the present embodiment is different from the embodiment of FIG. 7 in that the transmission of a high-speed digital video signal is made in the form of a recording format. Accordingly, upon high-speed recording, the high-speed digital video signal is not passed through a recording system signal processing circuit  350  but is recorded onto a tape through the change-over circuit  340  as it is. Upon high-speed reproduction, a reproduced signal is subjected to a signal processing for reproduction such as error detection and error correction by a reproducing system signal processing circuit  380  and is thereafter inputted to a terminal  345   b  of the change-over circuit  345 . The signal supplied through the change-over circuit  345  to the recording system side signal processing circuit  350  is subjected to a signal processing for recording such as addition of error correction code and modulation for recording by the signal processing circuit  350  to form a recording format and is thereafter outputted as a high-speed digital video signal from an output terminal  433 . 
     The embodiments shown in FIGS. 7 and 9 have feature that high-speed recording and high-speed reproduction are possible. The best use of this feature can be made for dubbing or data communication with the result of effective shortening of a dubbing time, a data communication time or a data circuit line occupation time. Also, though those embodiments have been mentioned in conjunction with an example in which all of standard-speed recording, high-speed recording, standard-speed reproduction and high-speed reproduction modes are involved, it is not necessarily required to implement all of those modes. There may be considered an example in which only a necessary mode is provided in compliance with the purpose of use. FIG. 10 shows an embodiment in which a high-speed recording function is provided as a recording mode and at least a high-speed reproduction function is provided as a reproduction mode. Also, there may be considered an embodiment as a system for the exclusive use for reproduction in which at least a high-speed reproduction function is provided, as shown in FIG.  11 . Further, FIG. 12 shows an embodiment in which a high-speed recording function is provided as a recording mode and a standard-speed reproduction function is provided as a reproduction mode. 
     FIG. 13 is a block diagram of one example of the magnetic recording/reproducing system of the embodiment of FIG. 7 for explaining processings subsequent to the compression processing. In FIG. 13, reference numeral  201  denotes a synchronization detection circuit, numeral  204  a recording modulation circuit, numeral  205  a cylinder servo control circuit, numeral  206  a capstan servo (or tape speed) control circuit, numeral  207  a reproduction reference signal generation circuit, numeral  210  a demodulation circuit, numeral  211  a cylinder, numeral  212  a pair of recording heads, numeral  213  a pair of reproducing heads, numeral  214  a capstan which controls the tape speed, numeral  215  a magnetic tape, numeral  216  a delivery reel, and numeral  217  a take-up reel. FIG. 14 is a timing chart of input and output signals in the example shown in FIG.  13  and schematically illustrate a compressed picture signal  251  which is an input signal, a synchronizing signal  252  of the picture signal, a standard-speed reproduction signal  255  which is an output signal, and a reproduction synchronizing signal  256 . 
     In the shown example, n-tuple speed recording is realized by making a tape speed and a cylinder rotation speed upon recording n times as high as those upon standard-speed reproduction. As shown in FIG. 14, the compressed video signal as an input signal of the circuit shown in FIG.  13  and the synchronizing signal include information  251  for n pictures and n synchronizing pulses  252  synchronous therewith in a time when one picture is reproduced at a standard speed. The picture information is converted into a predetermined recording format by the recording modulation circuit  204  and is recorded onto the magnetic tape  215  by the recording heads  212 . At this time, a synchronizing signal for the cylinder servo control circuit  205  and the capstan servo control circuit  206  is increased by n times in compliance with the n-tuple speed video signal, as shown by  252  in FIG. 14, so that the rotation speed of the cylinder  211  and the feed speed of the magnetic tape  215  are increased by n times. Thereby, the recording onto the tape can be made with the quite same recording format as that in the case of the standard-speed recording. Upon reproduction, a synchronizing signal for the cylinder servo control circuit  205  and the capstan servo control circuit  206  is supplied from the reproduction reference signal generation circuit  207  to restore the cylinder rotation speed and the tape feed speed to those upon standard-speed reproduction, and a signal read by the reproducing heads  213  is demodulated by the demodulation circuit  210  and is outputted therefrom. In the circuit shown in FIG. 13, if the input video signal and the synchronizing signal are ones of standard speed, standard-speed recording is possible. Also, n-tuple speed reproduction is possible if the frequency of an output signal from the reproduction reference signal generation circuit is increased by n times. 
     FIG. 15 is a block diagram of another example of the magnetic recording/reproducing system of the embodiment of FIG. 7 for explaining processings subsequent to the compression processing. FIG. 16 is a timing chart of input and output signals in the example shown in FIG.  15 . In FIG. 15, the same reference numerals as those used in FIG. 13 denote the same or equivalent components as or to those shown in FIG.  13 . In FIG. 15, reference numeral  202  denotes a÷m circuit, numeral  203  recording system memories, numeral  208  a÷m circuit, and numeral  209  reproducing system memories. In FIG. 16, the same reference numerals as those used in FIG. 14 denote the same or equivalent signals as or to those shown in FIG.  14 . In FIG. 16, reference numeral  253  denotes outputs of the recording system memories  203  and numeral  254  denotes an output of the ÷m circuit  208  or a synchronizing signal divided by m. 
     The embodiment shown in FIG. 15 is an example in which m pairs of recording heads are used to simultaneously record magnetic signals for m pictures on m tracks, thereby realizing high-speed recording while suppressing an increase in the cylinder rotation speed. Upon reproduction, m pairs of reproducing heads are used. Though FIG. 15 shows the case where two pairs of recording heads  212  are used to simultaneously record information for two pictures on two tracks, three or more pairs of heads can be used in a similar manner. 
     FIG. 17 is a table showing some examples of the tape speed and the cylinder rotation speed (rpm) in the embodiments shown in FIGS. 13 and 15. In the table, high-speed recording or reproduction at a speed ten times as high as the standard speed is shown by way of example. Design for implementing another high-speed recording or reproduction is similarly possible. In the table shown in FIG. 17, examples {circle around (1)}, {circle around (2)} and {circle around (3)} correspond to the embodiment shown in FIG.  13  and examples {circle around (4)} and {circle around (5)} correspond to the embodiment shown in FIG.  15 . 
     A still furthermore embodiment of a digital signal recording/reproducing system of the present invention will be explained by use of a block diagram shown in FIG.  18 . 
     In FIG. 18, reference numeral  501  denotes a signal input terminal to which a plurality of video signals are inputted in a time-division multiplex form, numeral  502  a recording selection signal input terminal to which a recording selection signal for selecting one or plural signals to be recorded from the multiplexed input signal is inputted, numeral  503  a recording signal selection circuit for selecting the signals to be recorded from the multiplexed input signal in accordance with the recording selection signal from the input terminal  502 , numeral  504  a recording signal processing circuit for subjecting the selected signals to a digital processing for recording onto a recording medium, numerals  505  and  505 ′ magnetic heads, numeral  506  a rotating drum, numeral  507  a magnetic tape or the recording medium, numeral  508  a servo circuit for controlling the rotation of the drum  506  and the travel of the tape  507 , numeral  511  a reproduction selection signal input terminal to which a reproduction selection signal for selecting one or plural signals to be out-putted as a reproduction signal from among the multiple-recorded and reproduced signals is inputted, numeral  509  a reproduction signal selection circuit for selecting the signals to be outputted as a reproduction signal from among the multiple-recorded and reproduced signals in accordance with the reproduction selection signal from the input terminal  511 , numeral  510  a reproduction signal processing circuit for subjecting the selected signals to a digital processing, and numeral  512  a reproduction signal output terminal. 
     The time-division multiplexed input video signal from the signal input terminal  501  is supplied to the recording signal selection circuit  503 . The recording signal selection circuit  503  is also supplied with the recording selection signal from the recording selection signal input terminal  502  to make the selection of signals to be recorded. For example, in the case where six kinds of video signals A, B, C, D, E and F are inputted in a time-division multiplex form as shown in (a) of FIG.  19  and four signals A, B, C and D thereof are to be selected and recorded, an output of the recording signal selection circuit  503  is as shown in (b) of FIG.  19 . Such an output signal of the recording signal selection circuit  503  is inputted to the recording signal processing circuit  504  which in turn performs a signal processing for recording such as addition of error correction code. Also, the recording signal selection circuit  503  produces a speed control signal on the basis of the number of signals in the time-division multiplexed input video signal, the transmission rate of the input signal and the number of signals to be recorded which are selected by the recording selection signal. The speed control signal is supplied to the recording signal processing circuit  504  and the servo circuit  508 . For example, in the case where the input video signal is time-division multiplexed to sextuplet with each of six signals in the multiplexed input signal being transmitted at a rate time-base compressed to 1/6 and four signals among the six signals in the multiplexed input signal are to be selectively recorded, a signal indicative of a quadruple speed is produced as the speed control signal. Also, in the case where the input video signal is time-division multiplexed to sextuplet with each of six signals in the multiplexed input signal being transmitted at a rate time-base compressed to 1/12 and four signals among the six signals in the multiplexed input signal are to be selectively recorded, a signal indicative of a octuple speed is produced as the speed control signal. Namely, in the case where an input signal is multiplexed to N-plet, the compression rate of each of the N signals in the multiplexed input signal is 1/K and the number of signals to be selectively recorded is L, a speed control signal indicative of an (L×K)/N-tuple speed is produced. The operating speed of the recording signal processing circuit  504  which processes a signal from the recording signal selection circuit  503 , is changed in accordance with the speed control signal. For example, in the case of a speed control signal indicative of a quadruple speed, the recording signal processing circuit  504  performs a signal processing at a speed four times as high as a normal speed and supplies the processed signal to the magnetic heads  505  and  505 ′. Here, for example, in the case where the input video signal is time-division multiplexed to sextuplet with each of the six signals in the multiplexed input signal being transmitted at a rate time-base compressed to 1/6 and a speed control signal indicative of a quadruple speed is used to selectively record four signals from among the six signals, the speed of an input signal inputted to the recording signal processing circuit  504  is four times as high as that of one video signal having a normal speed and the recording signal processing circuit  504  processes this quadruple-speed input signal at a quadruple speed and supplies the processed signal to the magnetic heads, thereby making it possible to record all of the four selected signals. Also, if the recording signal selection circuit  503  is constructed so that signals to be selectively recorded are sequentially changed for every one track on the tape, compatibility can be held in regard to the number of signals to be selectively recorded and a processing speed by causing the recording signal processing circuit  504  to perform a completed processing for every one track. In the following, explanation will be made in conjunction with the case where each video signal is recorded in such a form completed for every track. However, it should be noted in advance that the present invention is applicable to another recording system, for example, a system in which signals are recorded in a form changed for every pixel, line or field. On the other hand, the servo circuit  508  supplied with the speed control signal indicative of the quadruple speed controls the rotation speed of the rotating drum  506  so that it becomes four times as high as a normal speed and the travel speed of the magnetic tape  507  so that it becomes four times as high as a normal speed. Thereby, four signals A, B, C and D are alternately recorded on successive tracks of the magnetic tape  507 , as shown in FIG.  20 . According to the control mentioned above, the pattern of recording tracks on the tape becomes the same irrespective of the number of signals in the multiplexed input signal, the transmission rate of each signal and the number of signals to be selectively recorded. In order to make a control upon reproduction easy, it is preferable that the number of selectively recorded signals and the identification codes or signal numbers thereof (for example, A, B, C and D or 0, 1, 2 and 3) are recorded as an ID signal for every track. 
     In the above example, the recording of the time-division multiplexed signal has been mentioned. However, it is needless to say that the present invention is also applicable to the case where the number of multipet signal components in an input video signal is 1 or the input video signal is not multiplexed. In such a case, since the recording signal processing circuit  504  and the servo circuit  508  operate at speeds proportional to the transmission rate of the input video signal, an effect is manifested, for example, in high-speed dubbing. As apparent from the foregoing explanation of the operation, it is of course that a multiplexed signal can be recorded at a high speed. 
     Upon reproduction, a signal reproduced from the magnetic tape  507  by the magnetic heads  505  and  505 ′ mounted on the rotating drum  506  is inputted to the reproduction signal selection circuit  509 . The reproduction signal selection circuit  509  produces a speed control signal, for example, by detecting the number of multiple-recorded signals from the ID signal included in the reproduced signal and sends the speed control signal to the servo circuit  508 . The speed control signal is a signal indicative of a speed four times as high as the normal reproduction speed in the case where the number of multiple-recorded signals is 4 and a signal indicative of a sextuple speed in the case where it is 6. In the case of the quadruple speed, the servo control circuit  508  supplied with the speed control signal indicative of the quadruple speed controls the rotation speed of the rotating drum  506  so that it becomes four times as high as a normal speed and the travel speed of the magnetic tape  7  so that it becomes four times as high as a normal speed. Thereby, there can be traced all of signals recorded so that the recording track pattern on the tape becomes the same irrespective of the number of signals to be selectively recorded. In a system which has not a signal indicative of the number of selectively recorded signals, there may be employed a method in which the speed control signal is manually set. In a system in which the number of signals to be recorded on the tape is fixed, the speed control signal has a fixed value. The reproduction signal selection circuit  509  receives a reproduction selection signal inputted from the reproduction selection signal input terminal  511  to select a desired signal(s) from among the signals reproduced by the magnetic heads  505  and  505 ′ and to output the selected signal as a reproduction signal to the reproduction signal processing circuit  510 . The reproduction signal selection circuit  509  also outputs a selection number signal indicative of the number of selected signals to the reproduction signal processing circuit  510 . 
     The reproduction signal processing circuit  510  performs a signal processing such as code error correction processing and picture signal processing for the reproduction signal at a processing speed corresponding, to the selection number signal and outputs the processed reproduction signal from the output terminal  512 . For example, in the case where the number indicated by the selection number signal is 2, the signal processing speed is two times as high as a normal speed and various processings are performed for each selected signal. For example, in the case where signals A and C are selected, the signals A and C are outputted alternately for each field. In the case where the number indicated by the selection number signal is 1, for example, when the reproduction selection signal from the reproduction selection signal input terminal  511  selects only the signal C, the reproduction signal processing circuit  510  performs the signal processing at the normal speed to output the signal as reproduced at a normal speed. As apparent from the above, the present embodiment makes it possible to simultaneously record any number of signals selected from among a plurality of signals in a multiplexed video signal and to simultaneously reproduce any number of signals from among the recorded signals. 
     In the case where a plurality of signals are simultaneously reproduced, a construction for outputting the reproduced signals from separate output terminals simultaneously and in parallel may be employed, particularly, in the case of an analog output, as a method other than the construction in which the plurality of reproduced signals are outputted in a time-division multiplex form, as mentioned above. Though in the above-mentioned example the reproduction signal is outputted at a reproduction speed for a usual video signal, the transmission rate of the reproduction signal may be made higher than the reproduction speed for the usual video signal in order to transmit the reproduction signal to another system in an analog or digital signal form at a high rate or to perform high-speed dubbing which is one of effects of the present embodiment. This can be realized in such a manner that the fundamental operating speed of there producing system is set to be higher than a normal reproduction speed and the operating speeds of the servo circuit  508 , the reproduction signal selection circuit  509  and the reproduction signal processing circuit  510  are changed in accordance with the number of multiple-recorded signals and/or the number of signals to be outputted as a reproduction signal with the above fundamental speed being the standard. If the transmission rate of a reproduction signal is made variable so that a rate adapted for a transmission path to which the reproduction signal is to be connected or the performance or function of a recorder by which the reproduction signal is to be recorded, can be selected. 
     As mentioned above, according to the present embodiment, it is possible to simultaneously record any number of signals selected from among a plurality of signals in a multiplexed video signal and to reproduce any number of signals from among the recorded signals at any speed. Also, in the case where a plurality of signals are selected and reproduced and the plurality of reproduced signals are simultaneously outputted in a time-division multiplex form or from separate output terminals in parallel, it is possible to arbitrarily set the transmission rate of an output signal. 
     The present embodiment has been explained in conjunction with the case where the present invention is applied to a helical-scan digital-recording VTR. It is of course that a similar effect can be obtained in the case where the present invention is applied to a fixed head VTR. The fixed head system is convenient for the structuring of a system since it has a higher degree of freedom for the setting of the units of division of a signal subjected to time-division multiple recording as compared with the helical scan system. Also, it is of course that the present invention is applicable to a recording/reproducing equipment other than the VTR or is applicable to a digital signal processing and analog recording system. 
     The present invention can be applied to not only the case where an input signal is time-division multiplexed, as mentioned above, but also the case where a plurality of signals are inputted simultaneously and in parallel. In the latter case, the recording signal selection circuit  503  is constructed to receive the input signals in parallel. 
     As has been mentioned in the foregoing, according to the present invention, it is possible to realize a digital VTR in which high-speed recording onto a tape can be made with the same format as that used in standard-speed reproduction. Further, there can be realized a transmission signal processing for transmitting at a high rate a video signal to be recorded by such a digital VTR. Also, in the case where a signal transmitted from the transmission signal processing system is to be recorded by a multiplicity of VTR&#39;s, it is possible to designate those ones of the multiplicity of VTR&#39;s by which recording is to be made and to make a control of the start/stop of recording.