JP2736342B2 - Digital data recording device and digital data reproducing device - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital data recording device such as a digital audio tape recorder for recording / reproducing a PCM audio signal and a digital data reproducing device.

[Background Art] Recently, a DAT (Digital Audio Tape Recorder), which is under development, has a subcode recording area for recording a subcode in addition to a PCM recording area for recording a PCM-converted audio signal. ing. As this subcode, various information such as a program time for each program, a tape absolute time from the tape start end, and a program number are defined. Therefore, by reproducing this subcode, the user can know these various pieces of information. In addition, information called TOC is defined in the subcode. In this TOC, information such as the start time of the first program, the start time of each program, and the last time of the last program are set as information on each program recorded on the magnetic tape, and the subcode recording of the first program is performed. The information is recorded in the area, and various information of each recorded program can be grasped only by reproducing the first program recording portion at the beginning of the magnetic tape.

[Object of the Invention] The present invention provides a digital data recording device such as the DAT described above, which provides a digital data recording device capable of recording character (character) data corresponding to each program in the TOC. This is the purpose of 1.

Further, a second object of the present invention is to record TOC including characters automatically by simply inputting characters corresponding to each program at a time, and to store character data corresponding to a subcode recording area of each program. The present invention is to provide a digital data recording device capable of recording data.

A third object of the present invention is to provide a digital data recording system capable of automatically detecting the head of each program and recording the corresponding character data simply by inputting characters corresponding to each program at once. It is to provide a device.

A fourth object of the present invention is to provide a TOC including character data.
An object of the present invention is to provide a digital data reproducing apparatus capable of reading data and displaying corresponding characters.

[Gist of the Invention] In order to achieve the above object, the invention according to claim 1 is characterized in that TOC pack data containing character data corresponding to each program from character data corresponding to each program stored in a storage means. The main point is that the TOC pack data is recorded in the subcode recording area of the first program.

According to a fourth aspect of the present invention, TOC pack data including character data corresponding to each input program is generated and recorded in a subcode recording area of a first program, and a character code for each program is generated. The point is that pack data is generated and recorded in the subcode recording area at the head of each program.

Further, according to the invention described in claim 6, character pack data is generated for each program from character data corresponding to each input program and recorded in a subcode recording area at the head of each program. The point is that you have done it.

The key point of the invention of claim 9 is that the TOC pack data is read from a magnetic tape on which the TOC pack data including the character data is recorded, and the corresponding characters are displayed.

Embodiment An embodiment of the present invention will be described below in detail with reference to FIGS. 1 to 21. This embodiment shows an example in which the present invention is applied to a rotary head type DAT (R-DAT), and a recorded program is an audio signal for a plurality of music pieces.

<Structure of Embodiment> FIG. 1 is a block diagram showing components of an R-DAT. In FIG. 1, reference numeral 11 denotes two rotary heads for recording and reproducing data on and from a magnetic tape 12. This is a rotating drum provided with 13a and 13b.
During reproduction, the magnetic tape 12 is wound obliquely over an angle of 90 °. Reference numeral 14 denotes an input terminal to which an audio signal to be recorded is applied, and reference numeral 15 denotes an A / D that samples the audio signal applied from the input terminal 14 at a sampling frequency of, for example, 48 KHz and converts it into a 16-bit digital value. It is a converter. Reference numeral 16 denotes a signal processing circuit for temporarily writing the audio signal converted into a digital value to the PCM audio data storage circuit 17 while performing an interleaving process, adding an error correction code, compressing the time axis, reading out the signal, and outputting the signal. Signal processing circuit
PCM audio signal output from 16 and subcode processing circuit 19
This is a frame synthesizing circuit for synthesizing sub-codes output from the respective sub-codes at the timing of each recording area and outputting the synthesized sub-codes. Reference numeral 20 denotes a modulation circuit that performs modulation suitable for magnetic recording on the recording signal output from the frame synthesizing circuit 18, and reference numeral 21 denotes a recording amplifier that amplifies the modulated signal and supplies the amplified signal to the rotary heads 13a and 13b.

Reference numeral 22 denotes a reproduction amplifier for amplifying the reproduction signal read by the rotary heads 13a and 13b, reference numeral 23 denotes a demodulation circuit for demodulating the reproduction signal amplified by the reproduction amplifier 22, and reference numeral 24 denotes a demodulated reproduction signal for the PCM recording area and This is a frame decomposing circuit that decomposes and outputs the data in the code recording area. The PCM audio signal output from the frame decomposition circuit 24 is sent to the signal processing circuit 16, written once in the PCM audio data storage circuit 17, subjected to error correction processing, then deinterleaved and processed on a time axis. The data is subjected to a decompression process and supplied to the D / A converter 25. The D / A converter 25 restores the PCM-converted audio signal to an analog audio signal. The analog audio signal is amplified by an amplifier 26 and then emitted by a speaker 27.

On the other hand, during recording, the subcode processing circuit 19 creates a data format to be recorded in the subcode recording area from the storage contents of the subcode data storage circuit 28 and the subcode ID storage circuit 29, and outputs the data format to the frame synthesis circuit 18. In addition, at the time of reproduction, the sub-code in the reproduction signal output from the frame decomposition circuit 24 is temporarily stored in the storage circuits 28 and 29, and necessary data is output to the control circuit 30. The control circuit 30 controls the entire system. The control circuit 30 exchanges data with a control storage circuit 31 and transmits display data to a display device via a display drive circuit 32.
Send it to 33 for various displays. Reference numeral 34 denotes a silence period detection circuit that detects a silence period in a recording signal during recording and outputs a silence period detection signal to the control circuit 30, and reference numeral 35 denotes a control circuit 30.
Is controlled under the control of the above, a mechanical unit including various mechanical systems such as a drum motor, a capstan motor, etc., 36 is a [play] key,
[Stop] key, [record] key, [pause] key, [space] key, [character] key, [line feed] key, [cursor] key, [fast forward] key, [rewind] key, [character] key , A [correction] key, a [delete] key, a [TOC] key, and a key input unit having various keys including a dubbing mode designation switch and the like.

FIG. 2 shows the state of tracks recorded on the magnetic tape 12. As shown in FIG. 2, recording tracks having a predetermined inclination angle (about 6 degrees) are formed on the magnetic tape 12 by two rotating heads 13a. And 13b alternately and sequentially. As shown in FIG. 3, in the recording track, a PCM recording area for 128 blocks is formed in the center part, and subcode recording areas (SUB-1, SUB-2) for eight blocks are formed at both ends. In the PCM recording area, data to which an audio signal is subjected to PCM (pulse code modulation) and an error correction code is added is recorded. In the subcode recording area, as shown in FIG.
W1 consisting of sync code (8 bits) and subcode ID
(8 bits), W2 (8 bits) comprising a subcode ID and a block address, parity (8 bits) for W1 and W2, and 8 subcode blocks each having 1 subcode data (256 bits) Be recorded.

The subcode ID (8 bits), the block address and the subcode ID (8 bits) are configured as shown in FIG. 5 with two blocks as one unit. That is, the upper 4 bits of the subcode ID of the even-numbered block are controlled.
The ID and the lower 4 bits are used as the data ID, and the upper 4 bits are the PNO ID
(2) The lower 4 bits are used as PNO ID (3). For the block address and subcode ID, the most significant bit is defined as "1", the upper three bits of the even numbered block are the format ID, the lower four bits are the block address, and the uppermost bit of the odd numbered block. The three side bits are used as PNO ID (1), and the lower four bits are used as a block address. As shown in FIG. 6, a start ID serving as a control signal for cueing, that is, an ST-ID is provided in the third bit from the lower order among the four bits of the control ID. It is recorded as "1" for about 300 frames (about 9 seconds) at the beginning of the song. Also, the above PNO
In the ID (1) to PNO ID (3), the absolute tune numbers (001 to 799) of the respective tunes are recorded as program numbers.

The subcode data in the above subcode block (256
7) consists of four pack data of 64 bits per pack as shown in FIG. 7, and one byte 8 as shown in FIG.
Of the bits PC1 to PC8, the upper 4 bits of PC1 are assigned as pack items for identifying the data content of the pack data, and PC8 is assigned as parity of data of PC1 to PC7. As the pack item (4 bits), as shown in FIG. 8, "0000" indicates no information, "0001" indicates a program time indicating a recording time of each program (song),
"0010" is a tape absolute time indicating an absolute recording time from the tape start end, "0100" is set to a TOC described later, and in this embodiment, "1000" is a text character,
“1010” is assigned to each search character.

The text character and the search character will be described. In this embodiment, up to 80 characters (characters) can be recorded as subcode data for each program (song). Various characters such as a song name, a singer name, and lyrics can be considered as the characters to be recorded. The subcode data is recorded as the data of the pack format shown in FIG. 7 as described above. When the pack item for identifying the contents of the pack data is set to "1000", the pack data is a text character. Is shown. FIG. 9 shows the pack format of this text character. That is, PC1
The upper 4 bits of “PCM” are the pack item “1000”, the lower 4 bits are “SORT” indicating the contents of the included character data, and the upper 4 bits of PC2 are “FMT” indicating the code format of the character data itself, and the lower 4 bits. Four bits are "ADR" indicating the address of the pack, PC3 to PC7 are character data for a total of five characters, one character for each byte, and PC8 is parity for PC1 to PC7. Thus, the character data for a maximum of 80 characters is divided into five characters from the beginning to be a maximum of 16 text character pack data shown in FIG. In this case, "ADR" is "000
0 "to" 1111 ". The “SORT” is set to “0001” when the character data is a song song, “0010” when the character name is a singer, and “0011” when the character data is a song name. Set to “0000”. In the above “FMT”, character data is ASC
"0000" when represented by the II code, "0001" when represented by the ISO code, and "001" when represented by the JIS code
Set to "0". On the other hand, when the pack item for identifying the contents of the pack data is set to “1010”, the pack data indicates the search character. FIG. 10 shows the pack format of the search character. The pack format of the search character is the same as the pack format of the text character except that the upper 4 bits of PC1 are set to pack item “1010” and the lower 4 bits of PC2 are set to “0000”. The search character includes only the first five character data out of the character data of up to 80 characters corresponding to one program, and is used as a search code at the time of reproduction. Therefore, the lower 4 bits of PC2 indicating the address are fixed to “0000”.

The above-mentioned TOC will be described. TOC (Table of conte
nts) is data corresponding to the table of contents of the magnetic tape recording program, and is recorded as pack data in the subcode data. When the pack item is set to “0100”, the pack data It will be shown. Fig. 11 shows the pack format of this TOC. That is, the upper 4 bits of PC1 are the pack item “010
0, the next 4th bit is “0”, the lower 3 bits are the program number “PNO1”, and the upper 4 bits and lower 4 bits of PC2 are the program numbers “PNO2” and “PN”.
O3 ". PC3 is “POINT” indicating the data content of this TOC, and PC4 to PC6 are “hour”,
The data of "minute" and "second", PC7 is data indicating the number of frames, and PC8 is a parity for PC1 to PC7. Thus, the data included in the TOC pack is identified by “POINT” as shown in FIG.
That is, when “POINT” is B0 (1011 0000), PC1 to PC2
PNO (program number) indicates the total number of TOCs, PC4 to PC7
Are all “0”. "POINT" is A
When 0 (1010 0000), the PNO of PC1 to PC2 indicates the first song number, and the time data of PC4 to PC7 is the first song (program).
Indicates the start time, and “POINT” is 00 to 99 (0000 0000
1001 1001) When PNO of PC1 ~ PC2 is each song number, PC4 ~ P
The time data of C7 indicates the start time of each song. Also, "POIN
When "T" is A1 (1010 0001), the PNO of PC1 to PC2 indicates the last song number, and the time data of PC4 to PC7 indicates the last time of the last song. Further, in the present embodiment, the definition of “POINT” is extended and CA
In the case of (1100 1010) and CB (1100 1011), the data included in the TOC pack is assigned to character data.

The TOC pack data including the character data will be described. In the present embodiment, as described above, character data of up to 80 characters is recorded in the pack data of the pack item "1000" by one program. Character data corresponding to each program is also recorded as TOC. In this case, the TOC pack in which “POINT” is set to CA includes the first three characters out of the character data of up to 80 characters of one program, and the subsequent character group is divided into three characters. “POINT” is included in the POC pack set in the CB. FIGS. 13 (a) and 13 (b) show the format of a TOC pack including this character data. That is, as shown in FIG. 13 (a), the TOC pack in which “POINT” is set to CA
PC2 is the same as other TOC packs, and the PC3 "POIN
"T" is CA, that is, "1100 1010", the upper 4 bits of PC4 are "SORT", the lower 4 bits are "FMT", and PC5 ~
PC7 is character data of 3 characters, PC8 is PC1 ~ P
Parity of C7 is assumed. "SORT" and "FMT" above
Indicates the content and code format of each character as in the case of the pack item “1000”. In addition, "PO
As shown in FIG. 13 (b), the TOC pack in which “INT” is set to CB has the same PC1, PC2, and PC8 as other TOC packs,
The `` POINT '' of PC3 is CB, that is, `` 1100 1011 '', PC4
The upper 4 bits are "SORT", the lower 4 bits are "ADR", and PC5 to PC7 are character data of three characters. "SORT" above indicates the content of the character, "ADR"
Indicates an address. In this case, a maximum of 80 characters are recorded in one program, and the first three characters are CA
Since the characters are included in the TOC pack and the subsequent characters are divided into three characters and included in the TOC pack of the CB, "ADR" is set in a cyclic manner from "0000" to "1111" according to the character order. Will be done.

The TOC pack data is recorded in the subcode recording area of the first program on the magnetic tape, the character pack data is recorded in the subcode recording area at the head of each program, and the other pack data is recorded in the subcode recording area of each program. It is recorded in the code recording area. Four pack data are allocated in the subcode block, and 64 packs are recorded in one track and 128 packs are recorded in one frame (two tracks) (of which 16 picks are error correction codes).

<Operation of Embodiment> Next, the operation of the above embodiment will be described.

Normally, the audio signal applied from the input terminal 14 is converted into PCM and is recorded in the PCM recording area on the magnetic tape 12 by turning off the post-recording mode switch and operating the “record” key. In this case, the silent period detection circuit 34 detects a silent period in the recording signal, and outputs a silent period detection signal to the control circuit 30 when detecting a silent period of, for example, -42 dB or less from the full scale level for 4 seconds or more. The control circuit 30 determines that the falling of the detection signal is the head of the music and sends a control signal to the subcode processing circuit 19. As a result, the subcode processing circuit 19 stores the subcode ID storage circuit 29.
"1" is stored as a cueing control signal (ST-ID) and the music number PNO is stored while being updated, and each time data of items "0001" to "0011" is stored under the control of the control circuit 30. The data is stored in the sub-code data storage circuit 28 as the data in the above-described pack format. Then, the data is read out from each of the storage circuits 28 and 29 at the timing of the subcode recording area, and the data of the subcode block is generated and supplied to the frame synthesizing circuit 18, so that the data shown in FIG. In the track format, the PCM audio signal is stored in the PCM recording area, and the subcode is stored in the subcode recording area.

By operating the "play" key, the data recorded on the magnetic tape 12 is reproduced by the rotary heads 13a and 13b, and the audio signal is restored to the original analog signal and emitted from the speaker 27. Further, the subcode recorded in the subcode recording area is decomposed by the frame decomposing circuit 24 and sent to the subcode processing circuit 19. The subcode processing circuit 19 sequentially stores the subcode data in the input reproduced subcode in the subcode data storage circuit 28, reads out the subcode data of the required item, and supplies the read subcode data to the control circuit 30, and the control circuit 30 For example, item "000
The program time data of "1" is given to the display device 33 via the display drive circuit 32, and the display device 33 displays the program time.

Next, a case where character data is recorded as a subcode will be described. Character data is recorded in a post-recording mode in which the post-recording mode switch is set to an on state. In this embodiment, character data of up to 80 characters is recorded for each program.

First, it is assumed that five pieces of music are recorded in the PCM audio recording area on the magnetic tape 12 in the recording format described above. In the subcode recording area, the tape absolute time of the pack item “0010” from the beginning of the tape to the end of the tape and the program time of the pack item “0001” from the beginning to the end of each song are recorded. The start ID (ST-I
D) and the music number PNO are recorded. Also,
In a normal reproduction state, it is assumed that all information of the subcode recording area is managed by the control circuit 30.

Then, a magnetic tape on which these five songs of music were recorded
With respect to 12, characters corresponding to the 1 to 5 songs shown in FIG. 14 are input. First, the dubbing mode switch is turned on to input characters, and the [character] key is operated.
Up to 78 characters, including spaces, can be input. The characters are input using the [A] to [Z], [Character] keys such as numbers and symbols, and the [Space] key for setting a space between characters. If there is a mistake in the character input, the character to be corrected is designated by using the [cursor] key, and the character is newly input. The characters to be input may be, for example, the singer's name or the first 78 characters of the song poem in addition to the song name. Each time a character for one song is input, the [line feed] key is operated, and characters for five songs shown in FIG. 14 are all input collectively.

The control circuit 30 inputs an operation signal of each key operated for character input, and sequentially stores corresponding key codes for each music piece in a predetermined area of the control storage circuit 31. Next, when the [Play] key is operated, the control circuit
30 executes the control shown in the flowchart of FIG.

That is, after rewinding the magnetic tape 12 to the tape start end, the control circuit 30 performs cueing of the start end of the first music (the fifteenth track).
Figure Step S1). The beginning of the beginning of the first song is the ST-ID recorded over the first 300 frames of the song.
The magnetic tape 12 is reproduced from the beginning of the tape at a normal rated speed, and the ST-ID detected by the subcode processing circuit 19 and stored in the subcode ID storage circuit 31 during this time. Is read out and checked by the control circuit 30. Then
When the start of the first music piece is located by the control circuit 30, the control circuit 30 generates TOC pack data based on the key code or the like of the input character stored in the control storage circuit 31 (see FIG. 4). Step S2). Here, at the point in time when five pieces of music are recorded, information to be recorded as the TOC shown in FIG. 12 is stored in a predetermined area of the control storage circuit 31 under the control of the control circuit 30. I do. First, the control circuit 30 generates TOC pack data of the character shown in FIGS. 13A and 13B based on the key code of the input character stored in the control storage circuit 31, and generates the subcode processing circuit. Send to 19.

Thus, the control circuit 30 sets “0100” indicating the TOC as a pack item, then “0”, and “000” as the PNO1.
0, PNO2 as "0000", PNO3 as "0001" (PNO indicates song number 1), and POINT as "1100 1010" (= C
A), "0000" indicating general-purpose code as SORT, as FMT
"0000" indicating the ASCII code is output as PC1 to PC4 for each 8 bits and 1 byte. Next, the key code of the first three characters "ALL" of the input character "ALLEGRO" of the first song is read out from the control storage circuit 31, and one character is converted into an 8-bit ASCII code and output. Outputs 1-byte parity for byte data. The subcode processing circuit 19 stores the data (PC1 to PC8) sequentially input one byte at a time in the subcode data storage circuit 28 as one pack data. The control circuit 30 outputs the same data as described above for PC1 and PC2 for the key code of the next three characters "EGR", and the point of PC3 is "1100 1011" (= C
B), SORT of PC4 outputs "0000", ADR outputs "0001" (= 1), converts the key code of three characters "EGR" to 8-bit ASCII code, outputs it, and outputs it. Outputs 1-byte parity for byte data. The subcode processing circuit 19 stores the input data of PC1 to PC8 in the subcode data storage circuit 28 as one pack data. Then, the next characters "0" and 1
PC1 to PC3 output the same data as in the case of the above-mentioned character "EGR" for the key code of "line feed" entered as the character delimiter of the song, the PC4 SORT is "0000", and the ADR is "00".
After outputting "10" (= 2), the characters "0" and "line feed"
Is converted to 8-bit ASCII code and output. In this case, the ASCII code of “line feed” is output after being converted into two ASCII codes of a carriage return (CR) and a line feed (LF). If the input characters are divided into three characters and less than three characters, ASCI
Outputs I code "NULL" (NL). And this PC1
To PC8 are also stored in the subcode storage circuit 28 as one pack data. This completes the generation of the character TOC pack data for the input character “ALLEGRO” of the first music. As described above, the first three characters are generated in the TOC pack format of POINT = CA shown in FIG. 13 (a), and the subsequent three characters are shown in FIG. 13 (b).
POINT = Address "ADR" in TOC pack format of CB
Are generated in order from “1”.

In this way, the character TOC pack data is similarly generated for the input characters of the second to fifth music pieces.
Further, information to be recorded as the TOC already stored in the control storage circuit 31 is also shown in each POINT shown in FIG.
Each is generated as the TOC pack format in FIG.

Next, the control circuit 30 generates character pack data based on the key code of the input character stored in the control storage circuit 31 (step S3). First, the control circuit 30
Is the input character "ALLEGRO" for the first song from the control storage circuit 31
Is read, and the text character pack data shown in FIG. 9 is generated and sent to the subcode processing circuit 19.

That is, the control circuit 30 has “1000” indicating a text character as a pack item, SORT indicates “0000” indicating a general-purpose code, FMT indicates “0000” indicating an ASCII code, and an address.
ADR is set to “0000”, PC1 to PC2 in 8 bit 1 byte
Output data. Next, the input character of the first song "ALLEGR
The key code of the first five characters "ALLEG" of "O" is read from the control storage circuit 31, and one character is converted into an 8-bit ASCII code and output as data of PC3 to PC7. Outputs 1-byte parity. The subcode processing circuit 19 stores the data (PC1 to PC8) sequentially input one byte at a time as one pack data in the subcode data storage circuit 28. The control circuit 30 reads the next character "RO" and the key code of the "line feed" input as a delimiter of the character of the first song, and reads PC1 to PC
Output as C8 data. In this case, the address ADR is output as “0001” as data that is incremented from the previous time. The ASCII code corresponding to the key code of "line feed" is converted into two ASCII codes, carriage return (CR) and line feed (LF), and is outputted.
ULL ”(NL) is output. Thus, the generation of the pack data of the text character for the input character of the first music is completed.

Next, the control circuit 30 reads the key code of the first five characters "ALLEG" in the input characters of the first music from the control storage circuit 31, generates search character pack data shown in FIG. Send to circuit 19.

That is, the control circuit 30 sets “1010” indicating a search character as a pack item, “0000” indicating a general-purpose code as SORT, “0000” indicating an ASCII code as FMT, and “0000” indicating “0” as an address. , And output as data of PC1 and PC2 in units of 8 bits and 1 byte. Next, the key code of the first five characters "ALLEG" of the first song is read out from the control storage circuit 31, and one character is converted into an 8-bit ASCII code and P
Output as C3 to PC7 data, and already output PC1 to PC
Output 1-byte parity for 7 The subcode processing circuit 19 stores data (PC
1 to PC8) are stored in the subcode data storage circuit 28 as one pack data. Thus, the generation of the search character back data is completed.

When the generation of the TOC pack data and the character pack data is completed in this way, the control circuit 30 executes control for recording the TOC and the first music character on the magnetic tape 12 (step S4).

At the tape start end of the magnetic tape 12, a leader tape unit for optically detecting the tape end is provided as shown in FIG. 18, and a magnetic tape unit is provided following the leader tape unit. . The start end is a lead-in area of a predetermined length, and the PCM follows the format shown in FIG.
Audio is recorded as silence. Each program (song) is recorded after about one second from the lead-in area. The ST-ID is recorded in the first 300 frames of each song as described above. The TOC is recorded at the beginning of the first song, and the search character is the beginning of each song
Text characters are recorded in 300 frames, and text characters are recorded from the beginning of each song.

Thus, the control circuit 30 runs the magnetic tape 12 at which the beginning of the first music is caught at the rated speed,
The control unit 35 controls the mechanism unit 35 to rotate the rotary drum 11 so that only the subcode recording area is in the recording state and the other areas are in the reproducing state. Then, the TOC pack data, the search character pack data, and the text character pack data are read from the subcode data storage circuit 28. The subcode processing circuit 19 transfers these pack data to the frame synthesizing circuit 18 at the timing of the subcode recording area.
And the pack data is recorded over one frame in the subcode recording area on the magnetic tape 12. This process is repeatedly executed, and the TOC pack data is recorded over, for example, 33 frames from the start of the first song as shown in FIG. Also, as shown in FIG. 16, the same text character pack data is recorded in the order of addresses, and two frames are recorded.
It is recorded continuously as shown in the figure. At this time, the control circuit
Reference numeral 30 denotes the eighth from the information stored in the control storage circuit 31 (the information to be recorded as the TOC stored at the time of recording the music).
Each of the pack items "0001", "0010", "00" shown in the figure
The data (program time, tape absolute time, tape running time) corresponding to “11” is calculated for each frame to generate pack data, and the ST-ID is set to “1”, and the same subcode data as before dubbing is used. The control operation is executed so as to be recorded together with the TOC and the character data.

When the above processing is executed and after-recording to the sub-code recording area is performed over the first 300 frames of the first music, the processing shifts from step S5 to step S6. In the process of step S6, the magnetic tape 12 is fast-forwarded in the reproduction state, and the beginning of the next music piece (the second music piece) is searched.
When the beginning of the second song is located, the control circuit 30 reads the key code of the input character of the second song from the control storage circuit 31 and performs the same processing as in the case of the first song to execute the text character pack. Data and search character pack data are generated and sent to the subcode processing circuit 19 (step S7). Next, the control circuit 30 performs control for recording the character of the second song, and starts from the beginning of the second song.
After-recording to the subcode recording area is performed over 300 frames (steps S8 and S9). Thereafter, processing for recording a character at the beginning of each song (steps S6 to S6)
When step 9) is repeatedly executed, and this processing is executed for the characters of each piece of music input collectively (step S10), the post-recording processing is completed.

By the above-described post-recording process, the TOC including the character data is recorded on the magnetic tape 12 at the beginning of the first song as shown in FIG. 17, and the character data is recorded at the beginning of each song as shown in FIG. Is recorded. This magnetic tape
When the [12] is played back by operating the [PLAY] key, the recorded PCM data is played back, an audio signal is emitted from the speaker 27, and the control circuit 30 executes the processing shown in FIG. And text characters are displayed.

That is, when the [playback] key is operated with the post-recording mode switch turned off, the control circuit 30 controls the mechanical unit 35 and each circuit to set the tape playback state (step S1 in FIG. 19).
1). This reproduction state is continued until the end of the tape is detected or the operation of the [Stop] key is detected in step S12. The start and end of the tape are detected by optically detecting the translucent leader tape formed at the start and end of the magnetic tape, and the control circuit 30 determines the output of a detector (not shown). It is done by doing. Thus, in the tape playback state, the subcode recorded in the subcode recording area by the frame decomposition circuit 24 is sent to the subcode processing circuit 19. Subcode processing circuit
Reference numeral 19 denotes a subcode ID storage circuit 29 for storing the subcode ID data.
The subcode data having parity is stored for each pack item, such as the program time of the pack item "0001", the absolute tape time of the pack item "0010", and the text character data of the pack item "1000". The subcode data is stored in the subcode data storage circuit 28. In this playback state, the control circuit 30 has given an ST-ID output command to the subcode processing circuit 19 (step S13), and determines whether or not the tape has reached the head position of each music piece. When the beginning position of the music is reached, the ST-ID recorded over 300 frames of the music head is reproduced, and the subcode processing circuit 19 sends out an ST-ID detection signal to the control circuit 30. Control circuit
When the ST-ID detection signal is input, as a process of step S14, the sub-code processing circuit 19 gives a PNO detection command to the sub-code processing circuit 19 to determine whether or not the first music piece (PNO = 1). PNO
When it is detected as = 1, the subcode processing circuit 19 sends a detection signal to the control circuit 30. The control circuit 30 determines that the current tape position is the beginning of the first music piece, and performs processing for reading the TOC pack data.
This is because the pack item is “01” in the pack data sequentially stored in the subcode data storage circuit 28 during reproduction.
00 '' TOC pack, and POINT executes an instruction for sequentially outputting pack data of CA and CB by the subcode processing circuit 19.
This is the process given to. Receiving this instruction, the subcode processing circuit 19 sequentially outputs the character TOC pack data stored in the subcode data storage circuit 28 to the control circuit 30. The control circuit 30
The character data of PC5 to PC7 is converted into display data and stored in the display register of the control storage circuit 31. In this case, the music data is stored for each music number based on the PNOs of the PC1 and PC2, and the POINT of the PC3 stores the character data of the CA first, and thereafter the POINT of the PC3 stores the character data of the CB in address order. The control circuit 30 sequentially sends the TOC character from the display register of the TOC character control storage circuit 31 already read in the processing of step 15 to the display device 33 via the display drive circuit 32 to display the TOC character (step 15). S16). In this case, in the TOC display area of the display device 33, characters are displayed for each song number, for example, as shown in FIG. Since the character data of the TOC includes all the music titles of all the recorded music pieces, the display of the TOC character makes it possible to easily recognize all the recorded music titles at once. Further, the control circuit 30 gives an instruction to the sub-code processing circuit 19 to output the text character pack data whose pack item is “1000” and the address “ADR” sequentially from “0000” (step S17). The subcode processing circuit 19 receives this instruction, and stores the subcode data storage circuit.
The corresponding pack data stored in 28 is sequentially output to the control circuit 30. The control circuit 30 converts the character data of PC3 to PC7 in the pack data of the text character into display data and stores the display data in the display register of the control storage circuit 31. As shown in FIG. 16, the text character pack data is multiplex-recorded for each two frames, so that the text character pack data has sufficient redundancy to reproduce without error at the time of constant speed reproduction.

Next, the control circuit 30 sequentially reads the character data already read in the processing of step S17 from the display register of the control storage circuit 31 as the processing of step S18.
Through the display device 33 to display a text character. The display of this text character is
As shown in FIG. 16, in the next step S17, the text character pack data of the next song recorded at the beginning of the song is continuously read and displayed until a new song is displayed. The character is always displayed. For the second and subsequent songs, only the text characters are displayed by the processing of step S14, and if the end of the tape is detected by the processing of step S12 during reproduction, the control circuit 30 controls the mechanism section 35 to The tape running is stopped (step S19).

On the other hand, character display can be performed even when the tape is running at high speed. When the [fast-forward] key or the [rewind] key is operated with the post-recording mode switch turned off, the control circuit 30 executes the control operation shown in the flowchart of FIG. Control circuit 30 steps
In the process of S20, the mechanism unit 35 and each circuit are controlled to set a high-speed playback state in which the tape is transported at a speed of 100 times. When the [Fast Forward] key is operated, the tape is fed in the forward direction, and when the [Rewind] key is operated, the tape is fed in the reverse direction. However, in the high-speed playback state, the frame decomposition circuit 24
The subcode recorded in the subcode recording area is sent to the subcode processing circuit 19. The subcode processing circuit 19 stores the subcode ID data in the subcode ID storage circuit 29, and stores the subcode data with parity for each pack item, for example, the program time of the pack item "0001", the pack item The subcode data storage circuit 28 stores the tape absolute time of “0010” and the search character data of the pack item “1010” separately. This high-speed playback is continued until the end of the tape or the operation of the [STOP] key is detected in step S21, and then the control circuit 30 sends the pack item “1010” to the subcode processing circuit 19.
Is given (step S22). Receiving this instruction, the subcode processing circuit 19 outputs the corresponding pack data stored in the subcode data storage circuit 28 to the control circuit 30, if any. The control circuit 30 converts the character codes of PC3 to PC7 in the search character pack data into display data and stores them in the display register of the control storage circuit 31 (step S23). As shown in FIG. 16, the search character pack data has multiplexed recording of the pack data over 300 frames, and thus has sufficient redundancy to reproduce without error during high-speed reproduction. That is, at the time of high-speed reproduction, the rotary heads 13a and 13b scan over a plurality of oblique recording tracks as shown in FIG. Multiple recording of search character pack data over 300 frames
Even with such a head scan at the time of high-speed reproduction, data of any one of the tracks is long enough to be reliably reproduced.

Next, the control circuit 30 sequentially sends out the character data already read in the process of step S23 from the display register of the control storage circuit 31 to the display device 33 via the display drive circuit 32 to display the search character. . The display of the character is continued until the character data as the search code of the next music recorded at the head of the music is newly read and displayed in the next steps S27 and S28. By repeating this operation (steps S20 to S24), the character data recorded at the time of high-speed reproduction is displayed one after another. It is possible to know in a very short time what kind of song is being recorded.

With the magnetic tape 12 on which the search character data is thus recorded, it is possible to perform a search by song title. In this case, the dubbing mode switch is turned off, the first five characters of the title of the music to be searched are input using the [character] key, and the [character] key and the [reproduction] key are operated. The data of the first five characters of the input music title are stored in the control storage circuit 31 under the control of the control circuit 30. Further, the control circuit 30 controls the mechanical unit 35 to transfer the magnetic tape 12 at, for example, a speed of 100 times, and during this time, the rotating heads 13 and 1
4 Play the data. The subcode processing circuit 19 inputs the data of the subcode recording area in the reproduction signal, and when the search item pack data of the pack item “1010” is input, the PC3 to PC7 in the pack data are input.
Is transmitted to the control circuit 30. Control circuit
Numeral 30 represents the transmitted reproduction character data and the data of the first five characters of the music title stored in the control storage circuit 31 in the ASCII format.
The comparison with the data converted into the I code is performed, and when the matching reproduction character data is transmitted, the transfer of the magnetic tape 12 is stopped, and the reproduction is performed after locating the beginning of the S-ID. Thus, a search by a desired music title can be performed.

The recording of the TOC in the post-recording mode described above is performed based on the character data input by the [character] key of the key input unit 36. However, the TOC is not recorded, and only the character data of each song is recorded. It is also possible to record TOC including character data on the magnetic tape recorded at the beginning of each song without performing character input. In this case, all the recorded portions of the magnetic tape are reproduced in a normal reproduction state in advance, the text characters recorded at the beginning of each music are read for all the music, and each text character is stored in a predetermined area of the control storage circuit 31. It is stored together with information such as the start time of the music. In this state, turn on the post-recording mode switch and operate the [TOC] key. As a result, the control circuit 30 executes the control shown in the flowchart of FIG.

That is, after rewinding the magnetic tape to the beginning of the tape, the control circuit 30 finds the beginning of the beginning of the first music (step S26 in FIG. 21). The beginning of the beginning of the first song is the ST-ID recorded over the first 300 frames of the song.
The magnetic tape is reproduced from the beginning of the tape at the normal rated speed, and the ST-ID detected by the subcode processing circuit 19 and stored in the subcode ID storage circuit 31 during this time. This is performed by the control circuit 30 reading and checking. Then, when the start of the first music is caught by the control circuit 30, the control circuit 30 next generates TOC pack data based on information such as text characters stored in the control storage circuit 31. Perform (step S27). First, the control circuit 30 generates TOC pack data of the characters for all the songs shown in FIGS. 13 (a) and 13 (b) based on the text characters stored in the control storage circuit 31, 1
Send to 9. Further, information to be recorded as the TOC already stored in the control storage circuit 31 is also generated as the TOC pack format of FIG. 11 for each point shown in FIG.

Next, the control circuit 30 generates character pack data based on the text character data of the first music stored in the control storage circuit 31 (step S28). This processing is to generate the text character pack and the search character pack data shown in FIGS. 9 and 10 from the stored text character data of the first music. Thus, when the generation of the TOC pack data and the character pack data is completed, the control circuit 30
Executes the control for recording the TOC and the first character on the magnetic tape (step S29). When this recording is performed for 300 frames (step S30), the post-recording processing of only the TOC is completed.

[Effects of the Invention] As described in detail above, according to the first aspect of the present invention, characters corresponding to character data recorded in each program can be collectively recorded as TOC. Just by reading the TOC, the recorded characters for all programs can be grasped instantaneously, and the operability is greatly improved by using them for cueing and display.

According to the fourth aspect of the present invention, it is possible to automatically record the TOC including the character and the character for each program by simply inputting the characters for each program at a time. This eliminates the need for a complicated operation of recording the data, thereby greatly improving the operability.

Further, according to the invention of claim 6, it is possible to automatically record characters for each program simply by inputting characters for each program at a time, and to manually search for each program and individually This eliminates the need for a complicated operation of inputting and recording a character on the device, thereby greatly improving operability.

According to the ninth aspect of the present invention, it is possible to read and display the TOC pack data including the character, and the user can view the TOC display which is indicated only by reproducing the TOC recording portion, thereby displaying the recorded character. There is an advantage that it can be grasped instantly.

[Brief description of the drawings]

FIG. 1 is a block diagram showing one embodiment of the present invention, FIG. 2 is a diagram showing recording tracks on a magnetic tape in this embodiment, FIG. 3 is a diagram showing a format of one track in FIG. FIG. 4 is a diagram showing the format of one block of a subcode recorded in the subcode recording area of FIG. 3, and FIG.
The figure shows the format of the subcode ID in the subcode block, FIG. 6 shows the format of the control ID in the subcode ID, and FIG. 7 is recorded in the subcode data of FIG. FIG. 8 is a diagram showing the format of pack data, FIG. 8 is a pack item table showing the contents of pack data corresponding to each pack item of the pack data of FIG. 7, and FIG. 9 is a diagram when the pack item is set to a text character. Pack format, Fig. 10 shows the pack format when the pack item is set to the search character, Fig. 11 shows the pack format when the pack item is set to the TOC, and Fig. 12 shows the data contents according to each POINT of the TOC. 13 (a) and (b) show the TOC data format when the POC of the TOC is set to CA and CB. Shows a recording character example for the flowchart FIG. 15 showing the control process schematic of a control circuit in the after-recording mode, the 16
The figure shows the recording and display state of character data.
FIG. 17 is a diagram showing the recorded contents of the TOC, FIG. 18 is a diagram showing the recording position of each data on the magnetic tape, FIG. 19 is a flowchart showing an outline of the control processing of the control circuit at the time of constant speed reproduction, FIG. FIG. 21 is a flowchart showing an outline of control processing of the control circuit at the time of high-speed reproduction, and FIG. 21 is a diagram showing an outline of control processing of the control circuit when recording only the TOC. 11 ... Rotating drum, 12 ... Magnetic tape, 13a, 13b ... Rotating head, 18 ... Frame combining circuit, 19 ... Subcode processing circuit, 24 ... Frame disassembling circuit, 30 ... Control circuit,
33 display device, 36 key input unit.

Claims (10)

(57) [Claims] 1. Digital data is recorded on a magnetic tape in a frame unit in which one track composed of a PCM recording area and a subcode recording area is paired with two tracks, and pack data is recorded in the subcode recording area. In a digital data storage device which records as a subcode and the pack data is recorded in a form including an identification code for identifying the data content of the pack data, the digital data of a plurality of programs recorded on the magnetic tape, Storage means for storing character data corresponding to each program in advance; and character data corresponding to each program sequentially read from the storage means, and TOC pack data corresponding to each program generated from the read character data. Means, and TOC pack data corresponding to each program generated by the generation means. Recording means for inputting data and storing the TOC pack data in a subcode recording area of a first program recorded on the magnetic tape, wherein the generating means converts the read character data into pack data. In addition to executing the generating operation for generating the data as the data within, the generating operation for generating the code indicating the TOC as the identification code is executed, and the TO corresponding to each program is executed.
A digital data recording device for generating and outputting C-pack data. 2. The digital data recording apparatus according to claim 1, wherein said storage means stores character data corresponding to each program input by an input means for inputting characters. 3. Pack data including character data corresponding to each program is recorded in the subcode recording area of the magnetic tape, and the storage means is obtained by reproducing the subcode recording area of the magnetic tape. 2. The digital data recording apparatus according to claim 1, wherein character data corresponding to each program stored is stored. 4. Digital data is recorded on a magnetic tape in a frame unit in which one track composed of a PCM recording area and a subcode recording area is a set of two tracks, and pack data is recorded in the subcode recording area. It is recorded as a subcode, and the pack data is recorded in a form including an identification code for identifying the data content of the pack data.
In a digital data storage device for recording digital data for a plurality of programs in a PCM recording area and recording a control signal for cueing in the subcode recording area at the beginning of each program, characters are input. Input means; storage means for storing character data corresponding to each program input by the input means; character data corresponding to each program sequentially read from the storage means; Generating means for generating TOC pack data and character pack data corresponding to the above, and inputting the TOC pack data corresponding to each program generated by the generating means, and recording the subcode of the first program recorded on the magnetic tape First recording means for storing the TOC pack data in an area; Character pack data corresponding to each program generated by the generation means is input, the head of each program is searched for by the control signal for cueing, and the character pack data corresponding to the program is stored in a sub-program of the program. Second to record from the beginning in the code recording area
Recording means; and the generating means stores the read character data in the TO
A TOC pack data generating operation for generating a code indicating TOC as the identification code while generating the data as C pack data and generating the read character data as data in the character pack data and indicating a character mode. A digital data recording device for performing a character pack data generation operation for generating a code as the identification code. 5. The identification code of the TOC pack data includes a character string including a predetermined number of character data at the beginning of a character string corresponding to one program and a character string including character data of subsequent characters. The digital data recording apparatus according to claim 1, wherein the digital data recording apparatus is generated by changing the following. 6. Digital data is recorded on a magnetic tape in a frame unit in which one track composed of a PCM recording area and a subcode recording area is paired with two tracks, and pack data is recorded in the subcode recording area. It is recorded as a subcode, and the pack data is recorded in a form including an identification code for identifying the data content of the pack data.
In a digital data storage device for recording digital data for a plurality of programs in a PCM recording area and recording a control signal for cueing in the subcode recording area at the beginning of each program, characters are input. Input means; storage means for storing character data corresponding to each program input by the input means; and character data corresponding to each program sequentially read from the storage means; Generating means for generating corresponding character pack data; inputting character pack data corresponding to each program generated by the generating means; cueing a head of each program by the cueing control signal; The character pack data corresponding to the program Recording means for recording from the beginning in the subcode recording area, wherein the generating means generates the read character data as data in character pack data, and sets a code indicating a character mode to the identification code. A digital data recording device, which performs a generation operation of generating a digital data. 7. The character pack data includes search character pack data including character data of a predetermined number of characters at the beginning of an input character string for one program and character data of the entire input character string for each predetermined number of characters. Text character pack data
7. A digital data recording apparatus according to claim 6, wherein said identification code is changed and generated by said generation means. 8. The digital data recording apparatus according to claim 7, wherein said search character pack data is recorded in a subcode recording area in which a control signal for cueing is recorded. 9. A magnetic tape on which digital data for a plurality of programs is recorded in a frame unit in which one track composed of a PCM recording area and a subcode recording area is a set of two tracks, wherein the subcode recording is performed. In the area, the pack data is recorded as a subcode, and the pack data is recorded in a form including an identification code for identifying the data content of the pack data, and the TOC pack including the character data in the subcode recording area of the first program. In a digital data reproducing apparatus for reproducing a magnetic tape on which data is recorded, at the time of reproduction, the TOC pack data including the character data recorded in the subcode recording area of the head program is read, and the corresponding character data is read. Detecting means for detecting, and character data detected by the detecting means. Display means for displaying corresponding characters (characters). The TOC pack data includes character data for a predetermined predetermined character in a character string corresponding to one program, and subsequent characters The identification code is recorded on the magnetic tape by changing the identification code with that including the character data of the character, and the detection means detects character data corresponding to the original continuous character string based on the identification code. Digital data playback device characterized by the following. 10. The TOC pack data is recorded on the magnetic tape so as to include character data respectively corresponding to each recorded program and a program number indicating a recording order of each program. 10. The digital data reproducing apparatus according to claim 9, wherein said detecting means detects character data corresponding to each program number, and said display means displays characters corresponding to each program number.