JP3799066B2 - Recording device - Google Patents

Description

[0001]
【table of contents】
The present invention will be described in the following order.
Industrial application fields
Conventional technology (FIGS. 14 to 19)
Problems to be Solved by the Invention (FIGS. 14 to 19)
Means for solving the problems (FIGS. 1 and 2)
Action (FIGS. 1 and 2)
Example
(1) First embodiment
(1-1) Overall configuration of the embodiment (FIG. 1)
(1-2) System controller processing (FIGS. 2 and 3)
(1-3) Effects of the embodiment
(2) Second embodiment
(2-1) Recording process (FIG. 4)
(2-2) Reproduction process (FIG. 5)
(2-3) Effects of the embodiment
(3) Third embodiment (FIG. 6)
(4) Fourth embodiment (FIG. 7)
(5) Fifth embodiment (FIGS. 8 to 10)
(6) Sixth embodiment (FIG. 11)
(7) Seventh embodiment (FIGS. 12 and 13)
(8) Other embodiments
The invention's effect
[0002]
[Industrial application fields]
The present invention relates to a recording apparatus, and can be applied to, for example, a case where continuous audio data is discretely recorded on a magneto-optical disk in units of a predetermined block.
[0003]
[Prior art]
2. Description of the Related Art Conventionally, some magneto-optical disk devices have been designed so that continuous audio data can be recorded on a magneto-optical disk discretely by recording the audio data in units of predetermined blocks.
[0004]
That is, in this magneto-optical disk apparatus, the audio data that is sequentially input is input to the audio compression circuit, is blocked at a predetermined period, and is subjected to audio compression processing in units of blocks (hereinafter, this audio compressed data block is referred to as a sound group). Call).
Further, in the magneto-optical disc apparatus, the audio data of this sound group is formed by 11 consecutive blocks to form two sectors and 36 sectors to form one cluster. Can be recorded in cluster units based on the.
[0005]
That is, as shown in the form of a table in FIG. 14, in this magneto-optical disk apparatus, 2352 bytes of data can be assigned to each sector, of which vertical addresses “0” to “3” are represented. Allocate space to header.
Further, in the magneto-optical disk apparatus, the area of the vertical address “0” to “2”, 12 bytes, is allocated to the synchronization pattern (sync), the predetermined sync pattern is allocated to the area, and the subsequent vertical direction The cluster address is recorded in the first and second bytes of the address “3”.
[0006]
Here, in the magneto-optical disk device, this sector is continuously formed on the magneto-optical disk, and 36 sectors are grouped to form a cluster. A 14-bit address is used as an address for this cluster management. It is made to assign.
Further, in the magneto-optical disk apparatus, the sector address is assigned following the cluster address, and then the magneto-optical disk mode is recorded.
[0007]
In the magneto-optical disk apparatus following this header, a 2336-byte main data area is formed, and data desired by the user can be assigned to this area.
[0008]
That is, as shown in FIG. 15, in the magneto-optical disk for audio, the data of 02h is assigned as the mode data, and the data of 00h continues for 4 bytes following the header, and then the audio data is recorded. Has been made.
[0009]
In the magneto-optical disc apparatus, sound groups are assigned to the sectors formed in this way as shown in FIG.
That is, in the even sector, the main data area following the 00h data at the vertical address “4” corresponding to the table of FIG. 14 is divided into units of the area “105” in the vertical address. The sound group data is sequentially assigned to each area.
[0010]
Further, the area of “53” with the vertical address remaining after dividing the main data area in this way is assigned to the sixth sound group 5, and the sixth sound is assigned to the area from the vertical address “5” of the subsequent odd sector. Record the remaining group 5 data.
[0011]
Further, in the magneto-optical disk apparatus, with respect to the odd sector, the remaining area is divided in units of the area of “105” in the vertical direction address, and the remaining sound group is assigned to each area.
[0012]
As a result, in this type of magneto-optical disk apparatus, audio data that is sequentially input is subjected to voice compression processing to form a sound group, and a sector is formed by this sound group, and further a cluster is formed by this sector. Audio data can be recorded in units.
[0013]
That is, when recording audio data in cluster units in this way, if a large-capacity memory circuit is used as a buffer memory, for example, when a track jump occurs due to vibration during recording, it is continuously recorded by re-recording the track jumped cluster. Audio data can be recorded on a magneto-optical disk without interruption.
[0014]
Further, in the magneto-optical disk device, a recording area for recording audio data management data is formed on the inner circumference side of the magneto-optical disk, and a main data recording area made up of the cluster data is formed on the outer circumference side of the recording area. Form.
As a result, in the magneto-optical disk apparatus, the audio data can be sequentially recorded in the main data recording area in units of clusters.
[0015]
On the other hand, management data consisting of UTOC data is recorded in the management data recording area, so that the magneto-optical disk apparatus can reproduce desired audio data with reference to the UTOC data. Has been made. That is, in this UTOC data, management data is defined in units of sectors as in the main data, and is normalized for the first to fourth sectors.
[0016]
Of the first to fourth sectors, the second to fourth sectors are defined as options, and the first sector (that is, sector 0) is followed by a header as shown in FIG. Then, after assigning the cluster address, 00h data is recorded.
Further, in this first sector, after allocating predetermined code data (Maker code, Model code), data (First TNO, Last TNO) indicating main data recording start position and end position are allocated. Has been made.
[0017]
Among the first sectors, at the vertical address “11”, the disc identification data can be recorded in 2 bytes, and then a pointer (P-DFA) indicating the position of the defective area in the main data recording area. A pointer (P-EMPTY) indicating the start position of the unrecorded area of the main data recording area is assigned.
In the subsequent vertical address “12”, a pointer (P-FRA) indicating the start position of the main data recorded in the main data recording area is allocated, and subsequently a pointer (P-FR) indicating the recording start position of each data. TNO1, ..., P-TNO255) are assigned.
[0018]
As a result, in a magneto-optical disc apparatus that records and reproduces audio signals, the pointers (P-FRA, P-TNO1,..., P-TNO255) can detect the start position of each recorded song. Yes.
[0019]
That is, in the subsequent area below the longitudinal address “76”, a start address (Start address) and an end address (End address) indicating the recording start position and recording end position of the main data are recorded, and the pointer (P -FRA, P-TNO1,..., P-TNO255) indicate the recording position of this start address.
As a result, the magneto-optical disc apparatus can detect the recording position of the music designated by the user by detecting the start address and end address designated by the pointer.
[0020]
That is, at the start address and end address, as shown in FIG. 18, the cluster address is recorded 14 bits, followed by the sector address 6 bits and the sound group address 4 bits. Thus, in the magneto-optical disc apparatus, the audio data recorded in units of clusters can be subjected to processing such as cuing of music in units of clusters, sectors, and sound grapes.
A recording unit designated by this set of start address and end address is called a part.
[0021]
Further, in this UTOC data, mode data (Track mode) indicating the processing mode of each part is recorded following this start address, and thereby copy-inhibited data, write-inhibited data, audio data, stereo data, monaural data, etc. Can be identified, and further, the presence or absence of an emphasis process can be identified.
[0022]
On the other hand, in the end address, a link pointer (Link-P) indicating the connection relation of parts is recorded, and the start address corresponding to this end address is recorded with this link pointer (Link-P). The recording position can be specified.
That is, as shown in FIG. 19, when audio data is recorded for the first time on a magneto-optical disk on which no audio data is recorded, the first, second,. Thus, the audio data is recorded (FIG. 19A).
[0023]
In this case, the audio data of each performance is recorded on the magneto-optical disk by parts P1, P2, P3,... Specified by a set of start address and end address.
[0024]
On the other hand, when the performance of the fifth song having a long performance time is recorded after the second song and the fourth song are erased, the continuous audio data is divided into the second and fourth songs for the fifth song. It will be recorded with parts P2 and P4.
In such a case, in the magneto-optical disk, when the start address of the fifth music piece is designated by the pointer, the start position of the performance of the second part P2 can be detected by this start address, and further, this is combined with the start address. The recording end position of the part P2 can be detected by the end address that forms
[0025]
In the magneto-optical disk, the start address is detected in the same way as the pointer (P-FRA, P-TNO1,..., P-TNO255) of the fourth part P4 with the link pointer (Link-P) following this end address. As a result, in the magneto-optical disc apparatus, even if the recording / erasing process is repeated, the UTOC is rewritten each time so that the recording area of the magneto-optical disc is effectively used to record the audio data. Has been made to get.
Thus, the pointers (P-FRA, P-TNO1, ... P-TNO255) are formed corresponding to each performance recorded on the magneto-optical disk, and the corresponding parts are designated together with the link pointer. .
[0026]
On the other hand, when the second music piece is erased from the audio data continuously recorded in this way, the magneto-optical disc apparatus uses a pointer (P indicating the start position of the unrecorded area of the main data recording area). -EMPTY) specifies this erased area.
That is, in this pointer (P-EMPTY), the start address of the corresponding part is designated in the same manner as the pointer (P-FRA, P-TNO1,..., P-TNO255). For example, when the second and fourth songs are erased, the designations of the parts P2 and P4 that have been designated by the pointers (P-TNO1, P-TNO2,. The pointer (P-EMPTY) that represents, and the link pointer (Link-P) of the end address that is paired with the start address specified by this pointer can be rewritten so that the audio data can be easily deleted (FIG. 19B).
[0027]
As a result, in the magneto-optical disc apparatus, the audio data between clusters specified by the start address and end address is reproduced in cluster units, and then data processing is performed in sector units, whereby the sound group address of the start address and end address is obtained. The performance specified in the above can be played back, so that the audio data discretely recorded on the magneto-optical disc can be played back easily.
At this time, in the magneto-optical disc apparatus, the audio data is recorded in units of clusters in this way, and the audio data is reproduced in units of clusters, so that a large-capacity memory circuit can be used as a buffer memory in the same way as in recording. Even when a track jump occurs, it is possible to prevent the skipping of sound by replaying the track jumped cluster.
[0028]
[Problems to be solved by the invention]
By the way, when an audio signal output from various music sources is recorded with this type of magneto-optical disc apparatus, the audio signal may continue for a long time exceeding the recordable time of the magneto-optical disc.
In this case, it is conceivable that a continuous audio signal is continuously recorded on a plurality of magneto-optical disks by exchanging and recording the magneto-optical disk in the middle.
[0029]
However, when the audio signal continuously recorded on the magneto-optical disk is reproduced in this way, there is a problem that the management of the magneto-optical disk becomes complicated.
[0030]
That is, for example, when two music performances are already recorded on the magneto-optical disk for recording the audio signal, the UTOC is formed by recording the third music performance in the free area in the audio signal to be subsequently recorded. (FIG. 19), at the time of reproduction, unless this third piece of music is selected again for this magneto-optical disc, the continuously recorded performance cannot be reproduced following the first magneto-optical disc.
[0031]
The present invention has been made in consideration of the above points. When a continuous audio signal is recorded on a plurality of disc-shaped recording media, the management of the recording medium is simplified during playback to simplify continuous performance. The present invention intends to propose a disk device that can be reproduced.
[0032]
[Means for Solving the Problems]
In order to solve such a problem, in the present invention, a recording area capable of recording a plurality of continuous data composed of a plurality of discrete parts P1, P2, P3..., And at least each part P1, P2, P3. ... start address data Start address, end address data End address, parts P1, P2, P3 ... link data Link-P connecting between them, data P-TNO255 indicating the maximum number of parts TNO255 that can be divided, and unrecorded area Reproduction in a reproduction apparatus having a management area in which data P-ENTTY indicating a recording area is recorded, and determining the presence of other recording media 5A and 5B based on identification data recorded as link data Link-P Recording means (7A, 15, 13A, 8A, 11A, etc.) for recording data on a plurality of recording media 5A, 5B 8A, 19A), (7B, 15, 13B, 8B, 11B, 18B, 19B) and reading means (7A, 15, 13A, 8A, 8A) for reading data indicating the maximum number of parts TNO255 that can be divided from the recording media 5A, 5B. 11A, 18A, 19A), (7B, 15, 13B, 8B, 11B, 18B, 19B) and one of the plurality of recording media 5A, 5B on which the predetermined continuous data has already been recorded 5A, 5B In the case where the remaining data of other continuous data is recorded on the other recording medium 5A, 5B after the other continuous data is recorded halfway, the recording means (7A, 15, 13A, 8A, 11A, 18A, 19A), (7B, 15, 13B, 8B, 11B, 18B, 19B) to all unrecorded areas of one recording medium 5A, 5B The link data Link-P corresponding to the end address data End address indicating the position at which the recording operation of other continuous data is completed is set as data indicating the maximum number of parts TNO255 that can be divided in the one recording medium 5A, 5B. In addition, control means 7A and 7B for recording data indicating the maximum number of parts TNO255 that can be divided in the management area of one of the recording media 5A and 5B as identification data are provided.
[0047]
[Action]
According to the present invention, when recording input data across a plurality of recording media 5A and 5B, after recording other data halfway on one recording medium 5A and 5B on which predetermined data has been recorded, The link data Link-P corresponding to the end address data End address indicating the recording position of the data recorded halfway is set to the maximum value (that is, the maximum number of parts that can be divided TNO255) defined in the one recording medium 5A, 5B. By setting, continuous data recorded on the other recording medium can be easily reproduced without using special management data.
[0048]
【Example】
Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.
[0049]
(1) First embodiment
(1-1) Overall configuration of the embodiment
In FIG. 1, reference numeral 1 denotes a recording / reproducing apparatus as a whole. A compact disk player 2 reproduces a compact disk, and first and second magneto-optical disk apparatuses 3 and 4 record and reproduce magneto-optical disks 5A and 5B. .
In other words, the compact disc player 2 can reproduce a compact disc in response to an operation of a predetermined operator, and a digital audio signal obtained as a result is converted by an analog digital / digital / analog conversion circuit (AD / DA) 6. It can be converted into an analog signal and output to the outside.
[0050]
As a result, the recording / reproducing apparatus 1 is adapted to reproduce a compact disc as needed to audition a desired audio signal.
At this time, the compact disk player 2 outputs the performance time information TC of the performance time recorded in the lead-in area of the compact disk and the performance time information TC at the reproduction position to the magneto-optical disk device 3, thereby In the magnetic disk devices 3 and 4, the operation can be switched based on the performance time information, and the usability of the recording / reproducing device 1 as a whole can be improved.
[0051]
On the other hand, the magneto-optical disk devices 3 and 4 have the same recording / reproducing system, and when the magneto-optical disks 5A and 5B are loaded, the recording / reproducing system is driven, respectively, and the magneto-optical disks 5A and 5B are driven. After the UTOC data is read from the audio signal, an audio signal is recorded and reproduced based on the UTOC data.
[0052]
That is, in the magneto-optical disk devices 3 and 4, when the magneto-optical disks 5A and 5B having a diameter of 64 [mm] are loaded, control signals are sent from the system controllers 7A and 7B to the servo circuits 8A and 8B, respectively. The servo circuits 8A and 8B drive the spindle motors 9A and 9B, and the magneto-optical disks 5A and 5B are rotationally driven at a predetermined rotational speed.
[0053]
Subsequently, in the magneto-optical disk devices 3 and 4, control signals are output from the system controllers 7A and 7B to the servo circuits 8A and 8B, respectively, and the optical heads 10A and 10B are moved to the UTOC area of the magneto-optical disks 5A and 5B.
When the optical heads 10A and 10B are moved in this way, the magneto-optical disk devices 3 and 4 drive the optical heads 10A and 10B, respectively, to irradiate the magneto-optical disks 5A and 5B with the reflected light. Is received by the optical heads 10A and 10B.
[0054]
As a result, the optical heads 10A and 10B output the light reception results to the servo circuits 8A and 8B via the RF amplifiers 11A and 11B, and the servo circuits 8A and 8B thereby output the optical heads 10A and 10B based on the light reception results. 10B is tracked and focused.
Further, the optical heads 10A and 10B output the light reception results to the address decoders 12A and 12B via the RF amplifiers 11A and 11B. The address decoders 12A and 12B detect the meandering of the pregroove based on the light reception results, Thereby, the position information of each recording track allocated in advance on the magneto-optical disks 5A and 5B is detected.
[0055]
As a result, the magneto-optical disc apparatuses 3 and 4 can record audio data on a desired recording track or reproduce audio data from the desired recording track on the basis of the position information.
[0056]
In this way, when the recording track in which the UTOC data is recorded based on the position detection result of the address decoders 12A and 12B can be reproduced, the magneto-optical disk devices 3 and 4 have the RF amplifiers 11A and 11B. Are output to the encoders / decoders 13A and 13B.
Here, in the encoder / decoders 13A and 13B, the operation is switched between the recording mode and the reproduction mode. In the reproduction mode, the output signals of the RF amplifiers 11A and 11B are sequentially demodulated to obtain demodulated data, and the demodulated data is error-corrected. Process.
[0057]
This error correction processing is error correction processing based on a CIRC (cross interleave reed solomon code) error correction code recorded by being added to audio data or the like. Therefore, in this type of magneto-optical disc apparatus, at the time of recording, This error correction code is added to record audio data and the like.
When the data of each sector assigned to the UTOC is reproduced from the recording area of the UTOC data in this way, in the magneto-optical disk devices 3 and 4, the UTOC data necessary for the TOC memory provided in the system controllers 7A and 7B, respectively. Is stored.
[0058]
When the UTOC data is read in this way, in the magneto-optical disk devices 3 and 4, the operation of a predetermined operator is monitored by the system controller 7A, thereby detecting the user's key operation. Respond to switch operation.
That is, in this embodiment, a system controller 7A for controlling the operation of the magneto-optical disk device 3 is assigned to the main system controller, and control commands are sent from the system controller 7A to the system controller 7B and the system controller of the compact disk player. Control the overall operation.
[0059]
In this system controller 7A, the entire operation is switched in response to a key operation, and the total performance time of the magneto-optical disks 5A and 5B, the entire compact disk, the elapsed time of the performance being played back, via a predetermined display unit, The remaining performance time of the performance being played, the remaining performance time of the entire performance, the track number of the performance being played, etc. are displayed. Further, when performance recording date / time, disk name, track name, etc. are recorded on the compact disk and the magneto-optical disks 5A and 5B, such information is also displayed in response to the user's operation.
[0060]
On the other hand, when the recording mode is set in response to the user's operation, the magneto-optical disk devices 3 and 4 receive the audio signal A1 sequentially input by the common digital analog / analog digital conversion circuit 6 at the sampling frequency. After converting to a digital signal of 44.1 [kHz] and 16-bit quantized bits, the compression / decompression circuit 14 performs voice compression processing in a predetermined cycle unit, thereby forming a sound group and reducing the amount of data to almost 1/5. To do.
In this audio compression, audio data is compressed by applying a modified DCT (modified deiscreat cosine toransform) technique.
[0061]
Further, in the magneto-optical disk devices 3 and 4, the audio data DA1 is temporarily stored in the memory circuit 16 via the memory controller 15, and then sequentially output to the encoder / decoder 13A or 13B in response to a user operation.
In the memory circuit 16, a large-capacity memory is allocated so that audio data for several seconds at maximum can be stored in terms of the audio signal A1.
[0062]
Here, the encoders / decoders 13A and 13B divide the audio data sequentially input using the memory circuit 16 into predetermined blocks to generate error correction codes, and then use a modulation scheme suitable for recording on a magneto-optical disk ( In other words, it is modulated by 8-14 modulation which is EFM modulation), and the recording data obtained as a result is output to the magnetic head drive circuits 18A and 18B.
At this time, the magneto-optical disk devices 3 and 4 drive the servo circuits 8A and 8B based on the UTOC data detected in advance to move the optical heads 10A and 10B and the magnetic heads 19A and 19B to unrecorded recording tracks. .
Thus, in the magneto-optical disk devices 3 and 4, the magnetic heads 19A and 19B are driven in accordance with the recording data, and the modulation magnetic field formed by the magnetic heads 19A and 19B is applied to the desired recording tracks of the magneto-optical disks 5A and 5B. Apply.
[0063]
In this state, the magneto-optical disk apparatuses 3 and 4 intermittently irradiate the application position of the modulation magnetic field with the optical heads 10A and 10B, thereby applying the thermomagnetic recording technique to high-density audio. Data can be recorded.
Further, in the magneto-optical disk devices 3 and 4, the reflected light of the light beam is detected by the optical heads 10A and 10B, and the detection result is output to the address decoders 12A and 12B via the RF amplifiers 11A and 11B. Thus, the position information recorded in advance on each recording track is detected by the address decoders 12A and 12B.
As a result, the magneto-optical disk devices 3 and 4 can record audio data sequentially on a desired recording track based on the position information detection result.
[0064]
At the time of this recording, in the magneto-optical disk devices 3 and 4, the encoder / decoders 13A and 13B add a header to the audio data of the sound group to form a sector, and this sector forms a cluster. As a result, the audio data is recorded in units of clusters.
[0065]
As a result, in the magneto-optical disk devices 3 and 4, the track jump is detected based on the position information detection result obtained from the address decoders 12A and 12B and the focus error signal obtained via the optical heads 10A and 10B. Then, the recording operation is stopped and returned to the original recording track, and the recording of the audio data is resumed from the tracked recording track.
At this time, in the magneto-optical disk devices 3 and 4, the audio data stored in the memory circuit 16 is output again in units of clusters, thereby avoiding the loss of audio data by using the memory circuit 16 as a buffer memory. Even when the magneto-optical disk devices 3 and 4 vibrate or the like as a whole, the audio signal can be continuously recorded.
[0066]
On the other hand, in the reproduction mode, the magneto-optical disk devices 3 and 4 reduce the light amount of the optical data output from the optical heads 10A and 10B in the same manner as in the case of reproducing the UTOC data. By detecting the change in the polarization plane of the reflected light obtained from 5B, the recording data of the magneto-optical disks 5A and 5B is reproduced using the Kerr effect.
That is, in the magneto-optical disk devices 3 and 4, the output signals of the RF amplifiers 11A and 11B are demodulated by the encoder / decoders 13A and 13B, subjected to error correction processing, and then output to the memory controller 15.
[0067]
Here, in the magneto-optical disk devices 3 and 4, the memory circuit 16 is used as a buffer memory in the same way as at the time of recording, and the reproduced audio data is output to the compression / decompression circuit 14 where voice decompression processing is performed.
As a result, in the magneto-optical disk devices 3 and 4, the compression / decompression circuit 14 demodulates the audio data into a digital audio signal, and then outputs it in the form of an analog signal via the analog digital / digital analog conversion circuit 6. ing.
[0068]
Further, at the time of this reproduction, the magneto-optical disk devices 3 and 4 are adapted to detect the track jump by monitoring the continuity of the sub-data added to the main data, and if necessary, based on the detection result. Thus, audio data is repeatedly reproduced from the same recording track in units of clusters.
As a result, the magneto-optical disc apparatuses 3 and 4 can reproduce audio signals while preventing sound interruption even when a track jump is performed during reproduction.
[0069]
When recording / reproducing the magneto-optical disks 5A and 5B in this way, the system controllers 7A and 7B respectively update the TOC data stored in the TOC memory as necessary. When the magneto-optical disks 5A and 5B are ejected, the TOC data of the magneto-optical disks 5A and 5B are updated with the TOC data stored in the TOC memory, respectively.
As a result, the magneto-optical disk devices 3 and 4 can record and reproduce desired data with reference to the updated TOC data at the time of subsequent recording and reproduction.
[0070]
Furthermore, in this embodiment, the recording / reproducing apparatus 1 can directly input the digital audio signal output from the compact disc player 2 to the compression / decompression circuit 14, and thereby the digital audio signal reproduced by the compact disc player 2 can be received. Recording can be performed by the magneto-optical disk devices 3 and 4.
The recording / reproducing apparatus 1 is adapted to be able to mutually input / output audio data to be recorded / reproduced between the encoder / decoders 13A and 13B, thereby setting the magneto-optical disk apparatuses 3 and 4 to the recording / reproducing mode accordingly. An audio signal can be dubbed between the magneto-optical disks 5A and 5B.
[0071]
(1-2) System controller processing
Here, when the digital audio signal reproduced by the compact disk player 2 is dubbed by the magneto-optical disk device 3, the system controllers 7A and 7B execute the processing procedure shown in FIGS. 2 and 3, respectively, thereby continuously reproducing. The recorded digital audio signal is recorded across the magneto-optical disks 5A and 5B as necessary.
[0072]
That is, the system controller 7A sets the magneto-optical disk device 3 to the recording standby state and sets the compact disk player 2 to the reproduction standby state, and then starts the step SP1 when the user presses the recording start operator. The process proceeds to SP2, where the compact disk player 2 starts to reproduce the compact disk and starts recording the digital audio signal reproduced by the magneto-optical disk device 3.
[0073]
In this state, the system controller 7A subsequently proceeds to step SP3, where the compact disk player 2 and the magneto-optical disk device 3 continue to reproduce and record, and the recording position information output from the address decoder 12A at the subsequent step SP4. Based on the above, the remaining time until the final recording position of the magneto-optical disk 5A is detected.
Here, the system controller 7A outputs a control signal to the compact disk player 2 in advance to detect the performance time of the compact disk to be dubbed, and further detects the recordable time of the magneto-optical disk 5A. When the recordable time is exceeded, it is determined that the entire performance of the compact disk cannot be recorded on the magneto-optical disk 5A.
[0074]
Further, when the system controller 7A determines that the entire performance of the compact disk cannot be recorded, the system controller 7A determines whether or not the remaining time until the final recording position is within a predetermined time (in this example, several seconds), If a negative result is obtained here, the process returns to step SP3, but if the remaining time is within a predetermined time, the process proceeds to step SP5, where a standby signal is output to the system controller 7B, and the magneto-optical disk apparatus 4 is recorded. Launch in standby state.
[0075]
That is, when the user selects a dubbing operation mode and starts recording with the magneto-optical disk device 3, the system controller 7B rises to an operating state in response to a control signal output from the system controller 7A, and step SP6 (FIG. 3). ) To step SP7 where it is determined whether or not a standby signal has been input from the system controller 7A. If a negative result is obtained, step SP7 is repeated.
On the other hand, when a standby signal is input, an affirmative result is obtained at step SP7, and the process proceeds to step SP8, where the magneto-optical disk 5B loaded in the magneto-optical disk device 4 is recordable. Determine whether or not.
[0076]
Here, in this type of magneto-optical disk, in addition to the recordable magneto-optical disk, there is also a read-only optical disk, so that the system controller 7B allows the PTOC of the PTOC formed in the lead-in area of the magneto-optical disk 5B. It is determined whether or not the magneto-optical disk can be recorded / reproduced with reference to the data. If a negative result is obtained here, the process proceeds to step SP9 and the processing procedure is terminated.
On the other hand, when a recordable magneto-optical disk is loaded, when a positive result is obtained in step SP8, the system controller 7B moves to step SP10 and accesses the TOC memory to detect UTOC data. Thus, it is determined whether or not the magneto-optical disk has no audio signal recorded.
[0077]
If a positive result is obtained here, the system controller 7B proceeds directly to step SP11, whereas if a negative result is obtained, the system controller 7B proceeds to step SP12, accesses the TOC memory to update the UTOC data, and then proceeds to step SP11. Move.
In this updating process, the system controller 7B updates the track number of the performance recorded on the magneto-optical disk 5B by 1 respectively, so that the track number can be assigned to the first track number. Update.
[0078]
Thus, in the magneto-optical disc apparatus 4, by setting the track number of the performance to be subsequently recorded as the first track number, at the time of playback, the magneto-optical disc 5B is loaded and the playback operator is simply pressed. From this performance, the magneto-optical disk 5B can be reproduced.
That is, in this type of magneto-optical disc apparatus, by reproducing the audio data in the order of track number, the track number can be updated and the playback order can be specified easily.
As a result, for example, a magneto-optical disk remaining in the recording area can be loaded into the first magneto-optical disk device 3 to record a continuous audio signal, and the magneto-optical disk can be used efficiently correspondingly.
[0079]
When the track number is updated as necessary in this way, the system controller 7B moves to step SP11, where it sends an OK signal indicating that recording is possible to the system controller 7A, and then to the step SP13. Move to recording standby mode.
Subsequently, the system controller 7B moves to step SP14, where it determines whether or not a recording start signal instructing the start of recording has been input from the system controller 7A, and returns to step SP13 when a negative result is obtained.
[0080]
Thus, the system controller 7B waits for an instruction to start recording from the system controller 7A while keeping the magneto-optical disk device 4 in a recordable state.
[0081]
On the other hand, when the system controller 7A sends a standby signal, the system controller 7 moves to step SP15, and after continuing the recording process here, at step SP16, determines whether or not the recording position of the magneto-optical disk 5A is the final address of the recordable area. To do.
If a negative result is obtained here, the system controller 7A returns to step SP15. On the other hand, when the final address is reached, the system controller 7A moves to step SP17 because a positive result is obtained.
[0082]
Here, the system controller 7A determines whether or not an OK signal has been input from the system controller 7B. If a negative result is obtained, the system controller 7A moves to step SP18 and ends this process.
On the other hand, when an OK signal is input from the system controller 7B, an affirmative result is obtained in step SP17, so that the system controller 7A moves to step SP19, where the TOC memory is accessed to update the UTOC data. To do.
[0083]
That is, in this update process, the system controller 7A sets the value of the link pointer corresponding to the end address of the audio signal recorded so far to a predetermined value, thereby performing the performance desired by the user (in this case, the audio signal of the compact disc). Is not recorded on the magneto-optical disk 5A, and identification data indicating that recording is subsequently performed on the magneto-optical disk 5B is recorded on the magneto-optical disk 5A.
[0084]
That is, the system controller 7A subsequently moves to step SP20, controls recording stop, and then sends a recording start signal to the system controller 7B at step SP21, and ends this processing procedure at step SP18.
As a result, the system controller 7A updates the UTOC of the magneto-optical disk 5A with the contents of the TOC memory when the magneto-optical disk 5A is ejected, and further when the power of the recording / reproducing apparatus 1 is shut off, thereby identifying this. Data is recorded on the magneto-optical disk 5A.
[0085]
In the subsequent reproduction of the magneto-optical disk 5A, the system controllers 7A and 7B display a message indicating that there is a subsequent performance on a predetermined display means on the basis of the identification data. Even when recording is performed on the magneto-optical disks 5A and 5B, the management of the magneto-optical disks 5A and 5B can be simplified.
In this embodiment, the system controller 7A assigns the maximum data of the link pointer as the identification data (hereinafter referred to as connection data) to indicate that the following magneto-optical disk exists. .
[0086]
On the other hand, when the recording start signal is input from the system controller 7A, the system controller 7B obtains an affirmative result at step SP14 and moves to step SP22, whereby the output data of the memory controller 15 is transferred to the encoder / decoder 13A. Instead, the data is input to the encoder / decoder 13B, and the output data is sequentially recorded on the magneto-optical disk 5B.
[0087]
When the recording is completed and the compact disc player 2 completes the reproducing operation, the system controller 7B moves to step SP9, stops the recording operation, and completes this processing procedure.
As a result, the system controller 7B updates the UTOC of the magneto-optical disk 5B with the contents of the TOC memory when the magneto-optical disk 5B is ejected, and further when the power of the recording / reproducing apparatus 1 is shut off. The track number is recorded on the magneto-optical disk 5B.
[0088]
Thus, in the magneto-optical disk device 4, when the subsequent magneto-optical disk 5B is reproduced, the audio data is reproduced according to this track number, and the performance following the magneto-optical disk 5A can be reproduced first. Is recorded on a plurality of magneto-optical disks 5A and 5B, the continuous performance can be reproduced simply by continuously reproducing the magneto-optical disks 5A and 5B, and management of the magneto-optical disks 5A and 5B can be performed. It can be simplified.
[0089]
When the recording operation is switched between the magneto-optical discs 5A and 5B as described above, and further during reproduction, the operation is switched between the magneto-optical disc devices 3 and 4 to reproduce a continuous audio signal. In this case, the large-capacity memory circuit 16 is used as a buffer memory so that continuous audio data can be continuously recorded and reproduced even if the recording and reproducing operation is temporarily interrupted when the operation is switched.
In particular, in this type of magneto-optical disc apparatus, audio data is recorded and reproduced in units of clusters formed by sectors, and thus the audio data output from different reproducing devices is combined and output through the buffer memory. When recording audio data, the audio data can be surely combined. Further, when continuous audio data is divided and recorded, the audio data can be divided so that it can be reproduced continuously. Even when the performance is recorded so as to straddle the audio data, the audio data can be reliably recorded and reproduced.
[0090]
(1-3) Effects of the embodiment
According to the above configuration, when a continuous performance is recorded on the plurality of magneto-optical disks 5A and 5B by switching the operations of the two magneto-optical disk devices, there is a subsequent performance by assigning link pointers to connection data. By further updating the track number so that the subsequent performance can be reproduced first, it is possible to simply reproduce the magneto-optical disks 5A and 5B in succession and thereby reproduce the continuous performance. Management of the disks 5A and 5B can be simplified.
[0091]
(2) Second embodiment
(2-1) Recording process
In this embodiment, the system controllers 7A and 7B record a digital audio signal continuous across a plurality of magneto-optical disks by executing the processing procedure shown in FIG.
That is, first, the system controller 7A sets the magneto-optical disc device 3 and the compact disc player 2 in a recording standby state and a playback standby state in response to the operation of the user's operation element, and then the user selects the recording start operation element. When the pressing operation is performed, the process proceeds from step SP26 to step SP27, where the compact disk player 2 starts reproducing the compact disk and starts recording the digital audio signal reproduced by the magneto-optical disk device 3.
[0092]
In this state, the system controller 7A subsequently moves to step SP28 where the compact disk player 2 and the magneto-optical disk device 3 continue to reproduce and record, and the recording position information output from the address decoder 12A at the subsequent step SP29. The remaining time until the final recording position of the magneto-optical disk 5A is detected based on the above.
Here, when the performance time exceeds the recordable time based on the pre-detected performance time of the compact disk and the recordable time of the magneto-optical disk 5A, the system controller 7A plays the compact disk on the magneto-optical disk 5A. Judge that all cannot be recorded.
[0093]
Further, when the system controller 7A determines that the performance of the compact disk cannot be recorded, the system controller 7A determines whether or not the final recording position has been reached based on the recording position information output from the address decoder 12A. When it is obtained, the process returns to step SP28, but when the final recording position is reached, the process proceeds to step SP30, where the TOC memory is accessed to update the UTOC data, and the link corresponding to the end address of the audio signal recorded so far. Allocate connection data to the pointer.
As a result, in this embodiment, when the recording of the first magneto-optical disk 5A is completed, the connection data indicating that the subsequent digital audio signal is recorded on the magneto-optical disk 5B is recorded on the magneto-optical disk 5A. Yes.
[0094]
That is, the system controller 7A subsequently proceeds to step SP31, and after stopping the recording operation, the system controller 7A sends a recording start signal to the system controller 7B at step SP32, whereby the magneto-optical disk device 4 continues to record the digital audio signal. To start.
As a result, the system controller 7A updates the UTOC of the magneto-optical disk 5A with the contents of the TOC memory when the magneto-optical disk 5A is ejected, and further when the power of the recording / reproducing apparatus 1 is shut off. Data is recorded on the magneto-optical disk 5A.
[0095]
Accordingly, when the magneto-optical disk 5A is subsequently reproduced, the system controllers 7A and 7B display a message indicating that there is a subsequent performance on a predetermined display means based on the connection data, and thereby a plurality of continuous performances are displayed. Even when recording is performed on the magneto-optical disks 5A and 5B, management of the magneto-optical disks 5A and 5B can be simplified.
On the other hand, when the start signal is input, the system controller 7B moves to step SP34, where it determines whether or not the magneto-optical disk 5B loaded in the magneto-optical disk device 4 is a recordable magneto-optical disk.
[0096]
If a negative result is obtained here, the system controller 7B moves to step SP35 and issues a predetermined control command to the system controller 7A, and the system controller 7A accesses the TOC memory in response to this control command. The link pointer assigned to the connection data is rewritten to the original link pointer.
[0097]
That is, in this case, since the recordable magneto-optical disk 5B is not loaded in the magneto-optical disk apparatus 4, the recording / reproducing apparatus 1 cannot record the subsequent digital audio signal. By rewriting the data, the fact that there is a magneto-optical disk on which a digital audio signal that has been mistakenly recorded is present during subsequent playback is not displayed.
As a result, the system controller 7B subsequently moves to step SP36 to complete this processing procedure.
[0098]
On the other hand, if an affirmative result is obtained at step SP34, the system controller 7B moves to step SP37, and accesses the TOC memory to detect UTOC data, thereby detecting the magneto-optical disk on which no audio signal is recorded. Judge whether or not.
If a positive result is obtained here, the system controller 7B proceeds directly to step SP38 and starts recording of the subsequent audio data and proceeds to step SP36, whereas if a negative result is obtained, the system controller 7B proceeds to step SP39 and TOC. The memory is accessed to update the UTOC data, and the process proceeds to step SP38.
In this updating process, the system controller 7B updates the track number of the performance recorded on the magneto-optical disk 5B by 1 respectively, so that the track number can be assigned to the first track number. Update.
[0099]
As a result, the magneto-optical disk device 4 updates the TOC table while waiting for the recording of the first magneto-optical disk 5A to be completed, and subsequently records a continuous performance on the magneto-optical disk 5B and updates the TOC table. At the time of reproduction, the magneto-optical disk 5B can be reproduced from this performance simply by loading the magneto-optical disk 5B and simply pressing the reproduction operation element.
[0100]
(2-2) Reproduction processing
That is, as shown in FIG. 5, at the time of reproduction, the system controllers 7A and 7B move from step SP46 to step SP47, where the reproduction of the magneto-optical disk 5A or 5B is started in response to the user's operation, and then step SP48. Then, the reproducing operation is continued.
[0101]
Subsequently, at step SP49, the system controllers 7A and 7B determine whether the reproduction position of the magneto-optical disk 5A or 5B is the final position based on the position information output from the address decoder 12A or 12B.
If an affirmative result is obtained here, the system controllers 7A and 7B move to step SP50 to stop the reproduction operation, and then access the TOC memory to access the link pointer corresponding to the end address of the audio signal reproduced so far. Detect value.
[0102]
As a result, the system controllers 7A and 7B determine whether or not there is a subsequent performance. If a negative result is obtained here, the process proceeds to step SP51, and the processing procedure is completed. If a negative result is obtained here, step SP52. Then, a reproduction start signal is output to instruct the system controller 7B or 7A that has been waiting until then to start reproduction.
[0103]
In response to this, the system controller 7B or 7A accesses the UTOC data previously reproduced and stored in the TOC memory in the following step SP53, thereby detecting the track number and starting the reproduction of the audio data from the first track. To do.
Thereby, the system controller 7B or 7A sequentially outputs the audio data obtained by reproducing the magneto-optical disk 5B or 5A to the memory circuit 16 which has sequentially stored and output the audio data of the magneto-optical disk 5A or 5B. When the series of processing is completed, the process proceeds to step SP51 to complete the processing procedure.
[0104]
(2-3) Effects of the embodiment
According to the configuration of FIG. 4, even if the UTOC is updated after the recording of the first magneto-optical disk is completed, and then a continuous performance is recorded on the second magneto-optical disk, the first and second optical disks are recorded. By updating the UTOC of the magnetic disk, the same effect as that of the first embodiment can be obtained.
[0105]
(3) Third embodiment
In this embodiment, after the recording of the first magneto-optical disk 5A is completed, the TOC data of the second magneto-optical disk 5B is updated while the audio signal is being recorded on the second magneto-optical disk 5B. To do.
[0106]
That is, as shown in FIG. 6, first, the system controller 7A sets the magneto-optical disc device 3 and the compact disc player 2 in a recording standby state and a playback standby state in response to the operation of the user's operator, When the recording start operator is pressed, the process proceeds from step SP56 to step SP57, where the compact disk player 2 starts reproducing the compact disk and starts recording the digital audio signal reproduced by the magneto-optical disk device 3.
[0107]
In this state, the system controller 7A subsequently moves to step SP58 where the compact disk player 2 and the magneto-optical disk device 3 continue to play and record, and when the performance time exceeds the recordable time at the subsequent step SP59, It is determined whether or not the final recording position has been reached based on the recording position information output from the address decoder 12A.
If a negative result is obtained here, the system controller 7A returns to step SP58, whereas when it reaches the final recording position, it moves to step SP60, where it accesses the TOC memory to update the UTOC data and record until then. The link pointer corresponding to the end address of the audio signal is set in the connection data.
[0108]
Subsequently, the system controller 7A moves to step SP61, and after stopping the recording operation, sends a recording start signal to the system controller 7B, whereby the magneto-optical disk device 4 starts recording a digital audio signal.
As a result, the system controller 7A updates the UTOC of the magneto-optical disk 5A with the contents of the TOC memory when the magneto-optical disk 5A is ejected, and further when the power of the recording / reproducing apparatus 1 is shut off. Is recorded on the magneto-optical disk 5A.
[0109]
On the other hand, when the start signal is input, the system controller 7B proceeds to step SP62, where it determines whether or not the magneto-optical disk 5B loaded in the magneto-optical disk device 4 is a recordable magneto-optical disk.
If a negative result is obtained here, the system controller 7B moves to step SP63 and issues a predetermined control command to the system controller 7A, and the system controller 7A accesses the TOC memory in response to this control command. After rewriting the link pointer assigned to the connection data to the original link pointer, the process proceeds to step SP64 to complete the processing procedure.
[0110]
On the other hand, if an affirmative result is obtained at step SP62, the system controller 7B moves to step SP65 and accesses the TOC memory to detect the UTOC data, thereby detecting the magneto-optical disk on which no audio signal is recorded. Judge whether or not.
If an affirmative result is obtained here, the system controller 7B proceeds directly to step SP66 and starts recording of the subsequent audio data and proceeds to step SP64, whereas if a negative result is obtained, the system controller 7B proceeds to step SP67.
[0111]
Here, the system controller 7B moves to step SP68 after starting the subsequent recording. When the recording is continued here, it is determined whether or not the memory circuit 16 has sufficient free space at the subsequent step SP69.
In other words, in this type of magneto-optical disc apparatus, when audio data is recorded / reproduced via the memory circuit 16 and cannot be recorded / reproduced correctly, the audio data is recorded / reproduced in units of clusters. It has been made to redo.
[0112]
As a result, the system controller 7B detects the free space in the memory circuit 16 and determines that there is sufficient time to interrupt the recording operation and update the UTOC data. Then, the system controller 7B proceeds to step SP70, and after temporarily interrupting the recording operation, The TOC memory is accessed to update the UTOC data, thereby rewriting the track number and proceeding to the next step SP71.
On the other hand, if a negative result is obtained in step SP69, the system controller 7B returns to step SP68 and continues the recording operation.
[0113]
Thus, the system controller 7B temporarily interrupts the recording operation of the second magneto-optical disk 5B and updates the UTOC, then proceeds to step SP71 to continue the recording operation, and proceeds to step SP64.
[0114]
According to the configuration shown in FIG. 6, even if the UTOC is updated during recording of the second magneto-optical disk, the same effect as in the first embodiment can be obtained.
[0115]
(4) Fourth embodiment
In this embodiment, after the recording of the second magneto-optical disk 5B is completed, the TOC data of the second magneto-optical disk 5B is updated.
[0116]
That is, as shown in FIG. 7, the system controller 7A first sets the magneto-optical disc device 3 and the compact disc player 2 to the recording standby state and the playback standby state in response to the operation of the user's operator, When the recording start operator is pressed, the process proceeds from step SP75 to step SP76, where the compact disk player 2 starts reproducing the compact disk and starts recording the digital audio signal reproduced by the magneto-optical disk device 3.
[0117]
In this state, the system controller 7A subsequently moves to step SP77, where the playback and recording operations of the compact disk player 2 and the magneto-optical disk device 3 are continued, and when the performance time exceeds the recordable time at the subsequent step SP78, It is determined whether or not the final recording position has been reached based on the recording position information output from the address decoder 12A.
If a negative result is obtained here, the system controller 7A returns to step SP77. On the other hand, when the final recording position is reached, the system controller 7A moves to step SP79, where the TOC memory is accessed to update the UTOC data, and the link pointer is updated. Allocate connection data.
[0118]
Subsequently, the system controller 7A moves to step SP80, controls the stop of the recording operation, and then sends a recording start signal to the system controller 7B, thereby starting recording of the digital audio signal that continues in the magneto-optical disk device 4, In response to this, the system controller 7B moves to step SP81, and determines whether or not the magneto-optical disk 5B loaded in the magneto-optical disk device 4 is a recordable magneto-optical disk.
If a negative result is obtained here, the system controller 7B moves to step SP82 and issues a predetermined control command to the system controller 7A. The system controller 7A responds to this control command and the link pointer assigned to the connection data. Is rewritten to the original link pointer, and then the process proceeds to step SP83 to complete the processing procedure.
[0119]
On the other hand, if an affirmative result is obtained at step SP81, the system controller 7B moves to step SP84 to determine whether or not the magneto-optical disk has no audio signal recorded, and when an affirmative result is obtained, The process proceeds to step SP85, recording of the subsequent audio data is started, and the process proceeds to step SP83.
On the other hand, if a negative result is obtained in step SP84, the system controller 7B moves to step SP86 and starts the subsequent recording. After moving to step SP87 and continuing the recording operation, the recording ends in the subsequent step SP88. Determine whether or not.
[0120]
When the system controller 7B determines that the reproduction of the compact disk player 2 is completed based on the time information output from the compact disk player 2, the system controller 7B determines that the necessary recording is completed on the magneto-optical disk device 4 side. The process proceeds to step SP89, where the TOC memory is accessed to update the UTOC data, whereby the track number is rewritten and the process proceeds to step SP83.
On the other hand, if a negative result is obtained in step SP88, the system controller 7B returns to step SP87.
[0121]
According to the configuration shown in FIG. 7, even if the recording of the second magneto-optical disk 5B is completed and the TOC data of the second magneto-optical disk 5B is updated, the same effect as in the first embodiment is obtained. Obtainable.
[0122]
(5) Fifth embodiment
In FIG. 8, in which parts corresponding to those in FIG. 1 are denoted by the same reference numerals, reference numeral 25 denotes a recording / reproducing apparatus in which a compact disk player and a magneto-optical disk apparatus are integrated as a whole. When the continuous performance of the compact disk player 2 cannot be recorded on the magnetic disk 5A, the continuous performance across the plurality of magneto-optical disks is recorded by exchanging the magneto-optical disk and restarting the recording operation. .
[0123]
That is, in the magneto-optical disk apparatus, the entire operation is controlled by the system controller 7A, and the system controller 7A executes the processing procedure shown in FIG. 9 to record audio data.
That is, the system controller 7A sets the magneto-optical disc device and the compact disc player 2 in a recording standby state and a playback standby state in response to the operation of the user's operator, and then the user presses the recording start operator. The process proceeds from step SP90 to step SP91, where the compact disk player 2 starts up the compact disk and the magneto-optical disk apparatus in the respective reproduction and recording states, and then proceeds to step SP92 to continue the recording operation.
[0124]
In this state, the system controller 7A subsequently moves to step SP93 to determine whether or not the final recording position of the magneto-optical disk has been approached. If a negative result is obtained here, the process returns to step SP92, whereas the final recording position. If the time is within the predetermined seconds, the process proceeds to step SP94 where a warning is generated by driving a predetermined warning means to warn the user that the recording end position has been approached.
[0125]
Subsequently, the system controller 7A proceeds to step SP95 and continues the recording process, and then proceeds to step SP96 to determine whether or not the final recording position has been reached based on the recording position information output from the address decoder 12A.
If a negative result is obtained here, the system controller 7A returns to step SP95. On the other hand, when the final recording position is reached, the system controller 7A moves to step SP97, where the TOC memory is accessed to update the UTOC data to the link pointer. Allocate connection data.
[0126]
Subsequently, the system controller 7A moves to step SP98 and issues an alarm to warn the user that the recording of the first magneto-optical disk 5A has been completed. Then, the system controller 7A moves to step SP99 and controls the recording operation to stop. The magneto-optical disk 5A is discharged.
Subsequently, the system controller 7A moves to step SPP100, and when a new magneto-optical disk is loaded here, it moves from step SP101 to step SP102, and whether or not the loaded magneto-optical disk 5B is a recordable magneto-optical disk. to decide.
[0127]
If a negative result is obtained here, the system controller 7A returns to step SP99. On the other hand, if a positive result is obtained, the system controller 7A moves to step SP103 to determine whether the magneto-optical disk has no recorded audio signal. If an affirmative result is obtained here, the process proceeds to step SP104, recording of the subsequent audio data is started, and then the process proceeds to step SP105 to complete the processing procedure.
The system controller 7A stores the sequentially input audio data in the memory circuit 16 during the period from the end of recording on the first magneto-optical disk 5A to the start of recording on the second magneto-optical disk. When the recording of the second magneto-optical disk is started, the accumulated audio data is sequentially recorded, so that the audio data is continuously recorded on the first and second magneto-optical disks. It is made to be able to do.
[0128]
That is, in this type of magneto-optical disc apparatus, the audio data is intermittently recorded on the magneto-optical disc by switching the transfer speed of the audio data by the input / output of the memory circuit 16, and the track jump is thereby performed. However, as long as the capacity of the memory circuit 16 does not become full, the recording operation is repeated many times so that continuous audio data can be reliably recorded.
Thus, in the recording / reproducing apparatus 25, the memory circuit 16 is used as a buffer memory, and the magneto-optical disk can be exchanged using the time until the capacity of the memory circuit 16 becomes full.
[0129]
Thus, in this embodiment, a memory circuit having a larger capacity than that of the first to fourth embodiments is applied as the memory circuit 16, so that the magneto-optical disk is exchanged to generate a continuous audio signal. Recording can be performed across a plurality of magneto-optical disks.
[0130]
On the other hand, if a negative result is obtained in step SP103, the system controller 7B proceeds to step SP106, where the track number is updated and the process proceeds to step SP104 in the same manner as in the first to fourth embodiments.
[0131]
By the way, when recording a continuous audio signal by exchanging the magneto-optical disk in this way, it may be considered that the user does not replace the magneto-optical disk.
Therefore, the system controller 7A determines whether or not there is a margin in the memory circuit 16 in step SP101. If an affirmative result is obtained here, the process proceeds to step SP102. Move on to SP107.
Here, the system controller 7A displays that the audio signal cannot be continuously recorded (ie, the sound is interrupted) because the replacement of the magneto-optical disk is delayed via the predetermined display means, and then step SP105. To complete the processing procedure.
[0132]
On the other hand, at the time of reproduction, the system controller 7A executes the processing procedure shown in FIG. 10, thereby reproducing a plurality of magneto-optical disks on which continuous audio signals are recorded.
In other words, when the user presses the playback start operator, the system controller 7A moves from step SP110 to step SP111, sets the magneto-optical disk device to the playback mode, and then moves to step SP112 to continue the playback operation.
[0133]
In this state, the system controller 7A moves to step SP113, and determines whether or not the final recording position of the track currently being reproduced is approached based on the output data and UTOC data of the address decoder 12A, and a negative result is obtained here. Return to step SP112.
On the other hand, if a positive result is obtained in step SP113, the system controller 7A moves to step SP114, where a predetermined alarm is issued to warn the user that the reproducing magneto-optical disk has approached the reproduction end position. To do.
[0134]
Further, the system controller 7A subsequently proceeds to step SP115 and continues the reproduction operation, and then proceeds to step SP116 to determine whether or not the track being reproduced has reached the final reproduction position.
If a negative result is obtained here, the system controller 7A returns to step SP115, whereas if a negative result is obtained in step SP116, the system controller 7A moves to step SP117, where the TOC memory is accessed to access the link pointer. Thus, it is determined whether or not there is a magneto-optical disk in which the subsequent performance is recorded.
[0135]
If a negative result is obtained here, the system controller 7A moves to step SP118 and ends this processing procedure. On the other hand, if a positive result is obtained here, the system controller 7A moves to step SP119 to issue an alarm and continue the performance. After prompting the user to load the recorded magneto-optical disk, the magneto-optical disk is ejected at step SP120.
Subsequently, when the user replaces the magneto-optical disk at step SP121, the system controller 7A accesses the UTOC at the subsequent step SP122 and stores the UTOC data in the TOC memory. Then, based on this UTOC data, the system controller 7A reads the optical data from the first track. The reproduction of the magnetic disk is started, and the audio data sequentially reproduced in the subsequent step SP123 is accumulated in the memory circuit 16, and the process proceeds to step SP118.
[0136]
Thus, even during reproduction, the magneto-optical disk apparatus uses the memory circuit 16 as a buffer memory to reproduce continuous audio data, thereby interrupting the sound while exchanging the magneto-optical disk using the capacity of the buffer memory. Can be prevented in advance.
[0137]
According to the configuration of FIG. 8, even if the magneto-optical disk is replaced by a single magneto-optical disk device, the same effect as in the first embodiment can be obtained.
[0138]
(6) Sixth embodiment
In this embodiment, in addition to the case where the audio data cannot be recorded on the first magneto-optical disk, when the user operates a predetermined operation element, the subsequent audio signal is recorded on the second magneto-optical disk. To do.
That is, as shown in FIG. 11, the system controller 7A sets the magneto-optical disc device and the compact disc player 2 to the recording standby and playback standby states in response to the operation of the user's operator, and then the user starts recording. When the operator is pressed, the process proceeds from step SP130 to step SP131, where the compact disk player 2 starts up the compact disk and the magneto-optical disk device in their respective playback and recording states, and then proceeds to step SP132 to continue the recording operation. To do.
[0139]
In this state, the system controller 7A subsequently proceeds to step SP133, where it is determined whether or not the user has pressed the interruption operator for instructing the interruption of recording, and if a negative result is obtained here, step SP134 is obtained. Then, it is determined whether or not the final recording position of the magneto-optical disk has been approached.
If a negative result is obtained here, the system controller 7A returns to step SP132, whereas if a positive result is obtained here, the system controller 7A moves to step SP135 and issues a warning to the user that the recording end position has been approached. Warning.
[0140]
Subsequently, the system controller 7A moves to step SP136 and continues the recording process, and then moves to step SP137, where it judges again whether or not the user has pressed the interrupting operator, and a negative result is obtained here. Then, the process proceeds to step SP138 to determine whether or not it is the final recording position of the magneto-optical disk.
If a negative result is obtained here, the system controller 7A returns to step SP136. On the other hand, when the final recording position is reached, the system controller 7A moves to step SP139, where the TOC memory is accessed to update the UTOC data, and to the link pointer. Allocate connection data.
[0141]
Subsequently, the system controller 7A moves to step SP140 and issues a warning to warn the user that the recording of the first magneto-optical disk 5A has been completed. Then, the system controller 7A moves to step SP141 and controls the recording operation to stop. The magneto-optical disk 5A is discharged.
Subsequently, the system controller 7A moves to step SPP142, and when a new magneto-optical disk is loaded here, it moves from step SP142 to step SP143, and whether or not the loaded magneto-optical disk 5B is a recordable magneto-optical disk. to decide.
[0142]
If a negative result is obtained here, the system controller 7A returns to step SP141, whereas if an affirmative result is obtained, the system controller 7A moves to step SP144 and determines whether or not the magneto-optical disk has no recorded audio signal. .
If an affirmative result is obtained here, the system controller 7A moves to step SP145, starts recording the subsequent audio data, and then moves to step SP146 to complete the processing procedure.
On the other hand, if a negative result is obtained in step SP144, the system controller 7B moves to step SP147, where the track number is updated in the same manner as in the first to fourth embodiments, and the process moves to step SP145.
[0143]
On the other hand, when the user presses the interrupting operator, the system controller 7A moves to step SP148 when a positive result is obtained in step SP133 or step SP137, and the cluster being recorded is recorded to the end. Thereafter, the process proceeds to step SP149.
Here, the system controller 7A accesses the TOC memory to update the UTOC data, sets the position where recording was interrupted as an end address, assigns it to the link pointer corresponding to this end address, and moves to step SP141. .
[0144]
Thus, when the user forcibly suspends recording, even when recording over a plurality of magneto-optical discs, continuous audio signals can be reproduced with a simple operation.
[0145]
(7) Seventh embodiment
In this embodiment, a predetermined magneto-optical disk is selected from a plurality of magneto-optical disks loaded in a predetermined cartridge, loaded into a spindle motor, and this auto-magnetic disk is adapted to record and reproduce this magneto-optical disk. The present invention is applied to a type of magneto-optical disc apparatus, and records and reproduces a continuous audio signal so as to straddle a plurality of magneto-optical discs.
[0146]
That is, in this embodiment, as shown in FIG. 12, in the system controller that controls the overall operation, the process proceeds from step SP154 to step SP155 in response to the user's operation, starts the recording operation, and then proceeds to step SP156. This recording operation is continued.
Thus, in the magneto-optical disk apparatus, an audio signal inputted from the outside is sequentially recorded on the magneto-optical disk selected by the user, and it is determined whether or not it is the final recording position of this magneto-optical disk in the following step SP157.
[0147]
If a negative result is obtained here, the system controller returns to step SP156. On the other hand, if a positive result is obtained here, the system controller moves to step SP158, where the TOC memory is accessed to update the UTOC data. Allocate connection data to the pointer.
Subsequently, the system controller moves to step SP160, stops the recording operation, moves to step SP161, exchanges the disk, and moves to step SP162.
[0148]
Here, the system controller determines whether or not the loaded magneto-optical disk 5B is a recordable magneto-optical disk. If a negative result is obtained, the process returns to step SP161. If a positive result is obtained, the system controller returns to step SP163. Then, it is determined whether or not the magneto-optical disk has no recorded audio signal.
If a negative result is obtained here, the system controller moves to step SP164, starts recording the subsequent audio data, and then moves to step SP165 to complete the processing procedure.
[0149]
On the other hand, if a positive result is obtained in step SP163, the process proceeds to step SP166, and the UTOC is updated in the same manner as in the above-described embodiment, and the process proceeds to step SP164.
[0150]
On the other hand, as shown in FIG. 13, at the time of reproduction, the system controller moves from step SP170 to step SP171, sets the magneto-optical disk device to the reproduction mode, then moves to step SP172, and continues the reproduction operation.
[0151]
In this state, the system controller 7A moves to step SP173, and determines whether or not the final reproduction position of the currently reproduced track is approached based on the output data and UTOC data of the address decoder 12A, and a negative result is obtained here. Return to step SP172.
On the other hand, if an affirmative result is obtained in step SP173, the system controller moves to step SP174, and detects whether or not there is a subsequent magneto-optical disk by detecting the presence or absence of connection data assigned to the link pointer. If a negative result is obtained here, the process proceeds to step SP175.
[0152]
Here, after exchanging the magneto-optical disk, the system controller moves to step SP176 to reproduce the exchanged magneto-optical disk, and moves to step SP177 to complete the processing procedure.
[0153]
On the other hand, if an affirmative result is obtained at step SP174, the system controller moves to step SP178 and replaces the disk, and then starts reproducing the magneto-optical disk at step SP179.
Further, the system controller then moves to step SP180, where the audio data is stored in the memory circuit 16 made up of a buffer memory so that the reproduced sound is not interrupted, and then moves to step SP177.
[0154]
Thus, in this embodiment, the present invention can be applied to an autochanger to detect the presence or absence of connection data, and based on the detection result, the following magneto-optical disk can be reproduced to reproduce the audio signal without interruption.
[0155]
(8) Other embodiments
In the above-described embodiment, the case of recording a reproduction signal of a compact disk player has been described. However, the present invention is not limited to this, and the case of recording a digital audio signal output from various signal sources is further analog. The present invention can be widely applied when recording an audio signal consisting of a signal.
[0156]
Furthermore, in the above-described embodiment, the case where an alarm is generated to call the user's attention has been described. However, the present invention is not limited to this, and various warnings such as a case where a warning is issued to the user via a predetermined display means. The means can be widely applied.
[0157]
Further, in the first to fourth embodiments described above, the case where the memory circuit is shared has been described. However, the present invention is not limited to this, and when only the analog digital conversion circuit is shared, the encoder / decoder is also shared. It can be widely applied to such cases.
[0158]
Further, in the above-described embodiment, the case where the reproduction order is set by shifting the track number has been described. However, the present invention is not limited to this, and the track that has been set to be reproduced first has been described. The playback order may be switched by switching the track number between the performance of the number.
[0159]
Furthermore, in the above-described embodiment, the case where the link pointer is assigned to the identification data has been described. However, the present invention is not limited to this, and the case where the link pointer is assigned to the UTOC is used. Can be widely applied to.
[0160]
Further, in the above-described embodiment, when two magneto-optical disk devices are held integrally with a compact disk player, and when the magneto-optical disk device and compact disk player are held together, an auto-changer is provided. Although the case where the present invention is applied to the magneto-optical disk apparatus has been described, the present invention is not limited to this, and can be widely applied to a case where two magneto-optical disk apparatuses are connected and used.
[0161]
【The invention's effect】
As described above, according to the present invention, when recording input data across a plurality of recording media, after recording other data halfway on one recording medium on which predetermined data has been recorded, By setting the link data corresponding to the end address data indicating the recording position of the recorded data up to the maximum number of parts that can be divided on the one recording medium, no special management data is used. The continuous recording data recorded on the other recording medium can also be reproduced, and thus a recording apparatus capable of easily reproducing the continuous data can be obtained.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a recording / reproducing apparatus according to an embodiment of the present invention.
FIG. 2 is a flowchart for explaining the operation on the first magneto-optical disk apparatus side;
FIG. 3 is a flowchart for explaining the operation on the second magneto-optical disk apparatus side.
FIG. 4 is a flowchart for explaining a recording process according to the second embodiment.
FIG. 5 is a flowchart for explaining the reproduction processing of the second embodiment.
FIG. 6 is a flowchart for explaining the operation of the third embodiment.
FIG. 7 is a flowchart for explaining the operation of the fourth embodiment.
FIG. 8 is a block diagram showing a recording / reproducing apparatus according to a fifth embodiment.
FIG. 9 is a flowchart for explaining the recording process.
FIG. 10 is a flowchart for explaining the reproduction process.
FIG. 11 is a flowchart for explaining the operation of the sixth embodiment.
FIG. 12 is a flowchart for explaining a recording process according to the seventh embodiment.
FIG. 13 is a flowchart for explaining the reproduction process.
FIG. 14 is a chart for explaining a recording format of main data.
FIG. 15 is a chart showing a case where the main data is audio data.
FIG. 16 is a schematic diagram for explaining a sound group;
FIG. 17 is a chart for explaining the UTOC of sector 0;
FIG. 18 is a schematic diagram for explaining a start address and an end address.
FIG. 19 is a schematic diagram for explaining parts;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1,25 ... Recording / reproducing apparatus, 2 ... Compact disk player, 3, 4 ... Magneto-optical disk apparatus, 5A, 5B ... Magneto-optical disk, 7A, 7B ... System controller, 16 ... Memory circuit.

Claims (11)

Recording area that can record multiple continuous data composed of multiple discrete parts, at least start address data and end address data of each part, link data connecting parts, and maximum number of parts that can be divided reproducing in the reproducing device and data indicating an unrecorded area of the data and the recording area is closed and a management area recorded, to determine the presence of another recording medium based on the identification data recorded as the link data indicating Recording means for recording data on a plurality of recording media,
Reading means for reading data indicating the maximum number of parts that can be divided from the recording medium;
Of the plurality of recording media, the other continuous data is recorded halfway on one recording medium in which predetermined continuous data has already been recorded, and the remaining data of the other continuous data is recorded on the other recording medium. The link data corresponding to the end address data indicating the position where the recording operation of the other continuous data to the entire unrecorded area of the one recording medium by the recording means is completed. set in the recording medium to the data representing the maximum divisible number of parts, that the data indicating the maximum divisible number of parts in the management area of the one recording medium described above comprising a control means for recording as the identification data A recording apparatus.   When the unrecorded area in the recording area of the one recording medium falls below a predetermined value, the control means stops the recording operation of the continuous data on the one recording medium by the recording means, and then the identification data The recording apparatus according to claim 1, wherein:   The recording apparatus according to claim 1, wherein the control unit records the identification data when a data recording operation on the one recording medium and the other recording medium is completed.   The recording apparatus according to claim 1, wherein the recording unit includes at least two recording heads.   The control means determines whether or not data can be recorded on the other recording medium after recording a part of the continuous data on one of the plurality of recording media, and records the data. 2. The recording apparatus according to claim 1, wherein if it is determined that the recording data cannot be recorded, the identification data recorded on the one recording medium is erased.   The control means updates the management data of the other recording medium so that the remaining data of the continuous data is reproduced first when reproducing the data recorded on the other recording medium. The recording apparatus according to claim 1. The management data comprises at least a track number indicating continuous data recorded on the recording medium,
The control means replaces continuous data recorded on the other recording medium with a track number indicating remaining data and a track number indicating data recorded in advance on the other recording medium. Item 7. The recording device according to Item 6. The management data comprises at least a track number indicating continuous data recorded on the recording medium,
The control means sets the track number indicating the remaining data of the continuous data recorded on the other recording medium to a minimum value and sets the track number indicating other data previously recorded on the other recording medium. The recording apparatus according to claim 6, wherein the recording apparatus is increased.   The control means records the management data of the other recording medium after recording the continuous data halfway on the one recording medium and before starting the remaining data recording of the continuous data on the other recording medium. The recording apparatus according to claim 6, wherein the recording apparatus is updated.   The control means updates the management data of the other recording medium after the recording of the data on the one recording medium and the recording of the data on the other recording medium are completed. The recording device described. The recording apparatus further comprises memory means for temporarily storing the continuous data,
The control means detects the free space of the memory means at the time of the remaining data recording operation of the continuous data to the other recording medium, and interrupts the recording operation when the free space exceeds a predetermined amount. 7. The recording apparatus according to claim 6, wherein the management data of the other recording medium is updated.

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