JP3701323B2 - Medium recording / reproducing apparatus - Google Patents

Description

[0001]
[Industrial application fields]
The present invention Record Recording medium Information to Record , Or , Information recorded on the recording medium The present invention relates to a medium recording / reproducing apparatus for reproducing.
[0002]
[Prior art]
As a recording medium on which information is recorded, a compact disk (hereinafter simply referred to as a CD) is widely known. Recently, a plurality of CDs are stored in storage means called magazines, and players equipped with the magazines are stored in the trunk of an automobile. Book CD autochanger devices in which body devices are arranged near the driver's seat are becoming popular.
[0003]
On the other hand, in recent years, a magneto-optical recording type mini disk cartridge (hereinafter referred to as MD) has been proposed as a recording medium in which an information recording disk is stored in a protective cartridge case. The MD can not only reproduce recorded information but also record new information or rewrite and record already recorded information.
[0004]
[Problems to be solved by the invention]
As a medium recording / reproducing apparatus for recording or reproducing such an MD, various product plans are currently being planned.
[0005]
An object of the present invention is to provide a medium recording / reproducing apparatus capable of improving the operability for ejecting a plurality of recording media from the apparatus as an autochanger apparatus, particularly for improving the convenience of handling MDs and the like. It is to provide.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, a medium recording / reproducing apparatus of the present invention comprises a medium storage means for storing a plurality of recording media in a plurality of storage areas, and a predetermined recording medium in an insertion slot. From Medium ejecting means for ejecting to a predetermined position, medium extraction detecting means for detecting that the recording medium ejected to the predetermined position is extracted, and the predetermined recording selected when the predetermined recording medium is selected Medium By the medium discharge means Insertion slot From Operation means for inputting a discharge command for setting a discharge mode for discharging; storage area specifying means for specifying a storage area for storing the recording medium; In the discharge mode Even if a predetermined time elapses after the recording medium is discharged by the medium discharging means. By the medium sampling detection means When the removal of the recording medium is not detected, the recording medium discharged to the predetermined position is stored in the apparatus, and when the discharge command is input before the predetermined time elapses, the recording medium storing operation is started. And a control means for storing the recording medium discharged to the predetermined position in the original storage area in which the recording medium was stored.
[0007]
[Action]
With this configuration, according to the medium recording / reproducing apparatus of the present invention, when the recording medium is discharged to a predetermined position, if a discharge command is input before the predetermined time elapses, the medium recording / reproducing apparatus does not enter the storage mode. Since the recording medium ejected to the predetermined position is stored in the original storage area in which the recording medium was stored, it is possible to greatly reduce the labor required for the user's input operation.
[0008]
【Example】
Embodiments of an in-vehicle MD autochanger device (hereinafter simply referred to as MD device) which is a medium recording / reproducing device of the present invention will be described below with reference to the drawings.
[0009]
The MD device inserts an MD and records and / or reproduces information recorded on the MD.
[0010]
First, a general MD used in the MD device will be described. FIG. 2 is a plan view showing a configuration of a general MD.
[0011]
In FIG. 2, reference numeral 201 denotes a cartridge case, 202 denotes an information recording disk main body which is an optical disk or magneto-optical disk having a diameter of about 6 cm housed in the cartridge case 201, and 203 denotes the disk main body 202 provided in the cartridge case 201. An access hole 204 for accessing the access hole 204 is a slide shutter (hereinafter simply referred to as a shutter) that opens and closes the access hole 203. Since the shutter 204 is closed except when in use, the disk main body 202 is protected from the external environment, and is excellent in practicality and durability.
[0012]
The types of MD include a read-only pre-mastered (PRE-M) type in which information fixed in advance is recorded, and a writable recordable (RECORDABLE) type. The pre-mastered type shutter 204 is provided only on one side of the cartridge case 201 and can irradiate the disc surface of the disc main body 202 with a light beam from a pickup described later. The recordable type shutters 204 are provided on both sides of the cartridge case 201, and when recording on the disc main body 202, a magnetic head that applies a magnetic field contacts the disc surface that is irradiated with the light beam and the opposite disc surface. It has a structure.
[0013]
Hereinafter, unless otherwise noted, for convenience of explanation, the MD that is the recording medium including the cartridge case 201 and the disk main body 202 is collectively referred to as a disk.
[0014]
Next, the MD apparatus according to the present embodiment for reproducing and / or recording the disc will be described. In the drawings, arrows X1 and X2 indicate the longitudinal direction of the MD device, and arrows Y1 and Y2 indicate the vertical direction of the MD device. Therefore, the arrow X1 side is the front side, the arrow X2 side is the back side, the arrow Y1 side is the lower side, and the arrow Y2 side is the upper side.
[0015]
FIG. 1 is a cross-sectional view showing an outline of the internal structure of the MD apparatus when a disc is inserted.
[0016]
In FIG. 1, the MD device is composed of a rectangular parallelepiped device case 1 and main parts (described later) provided inside the device case 1.
[0017]
A disc insertion slot 212 which is an insertion slot for inserting a disc is formed at the upper edge of the front of the device case 1. The insertion prevention for preventing foreign matter from entering the MD apparatus is inserted into the disc insertion slot 212. A shutter 217 is attached to be freely opened and closed.
[0018]
The main part provided in the device case 1 includes a carrier 3 that is a transport unit that transports and holds the inserted disc, and a player unit 4 that is a medium drive unit that rotationally drives the inserted disc. And a stocker 5 which is a medium storage means for storing the inserted disc.
[0019]
The carrier 3 is disposed so as to be movable up and down at the back side of the disk insertion port 212. On the upper part of the carrier 3, the inserted disk is loaded (loaded), or the loaded disk is loaded. A transport roller 215 for being stored in the stocker 5 or ejected from the disk insertion slot 212 is rotatably provided.
[0020]
The carrier 3 is provided with various sensors for detecting insertion, loading, ejection, etc. of the disk, a disk insertion sensor 216a for detecting the insertion of the disk, and a loading completion for detecting the completion of the disk loading. There are a sensor 216b, an eject sensor 216c, a disk removal sensor 216d which is a medium removal detection means for detecting whether or not a disk has been removed, and the like.
[0021]
The loading completion sensor 216b detects that the end of the disk loaded by the transport roller 215 has been completely loaded by reaching the position W in FIG. The eject sensor 216c detects that the disc has been ejected to a position where it can be taken out from the disc insertion slot 212 (reload position). The disk removal sensor 216d is provided in the vicinity of the disk insertion port 212, and whether or not a disk ejected from the carrier 3 to the disk insertion port 212 (moved to the reload position, that is, partially protruded) has been removed. Is to detect.
[0022]
The carrier 3 is provided with a carrier position sensor (not shown) that accurately detects the raising / lowering position of the carrier 3, and the carrier position sensor detects the position of the carrier 3, the disk insertion slot 212, By making the positions of the storage units, which will be described later, of the stocker 5 face each other, the horizontal movement of the disk in the front-rear direction can be performed smoothly.
[0023]
The player unit 4 is disposed below the carrier 3 so as to face the carrier 3. The player unit 4 is attached to the device case 1 so as to be slidable by a damper and an anti-vibration spring (not shown). Yes. For this reason, when the disk is driven to rotate, the damper and the anti-vibration spring are brought into a floating state, so that it is possible to prevent the vibration to the device case 1 received from the outside from being transmitted to the player unit 4. Note that the player unit 4 is fixed to the device case 1 when the disk is not being rotated. Further, when the disc is being rotated, the carrier 3 on which the disc is mounted and the player unit 4 are connected to each other, whereby the disc is attached to the turntable of the player unit 4.
[0024]
In the player unit 4, reference numeral 219 denotes a spindle motor for driving the disk rotation, and 220 denotes a turntable on which a disk (disk main body 202) is mounted. A pickup unit (PU) 221 irradiates a disk with a light beam to read information, and has a structure that slides in the radial direction of the disk mounted on the turntable 220. Further, the player unit 4 is provided with a disk mounting completion sensor 216e for detecting that a disk is mounted on the turntable 220 by the contact of the cartridge case 201.
[0025]
The stocker 5 is a rectangular parallelepiped case in which storage portions 50a to 50d, which are four storage areas for storing discs, are stacked in the vertical direction, and is further deeper than the carrier 3 when viewed from the disc insertion port 212. It is arranged on the side so that it can be raised and lowered. The storage units 50a to 50d are identified by identification numbers # 1 to # 4. The storage unit 50a is # 1, the storage unit 50b is # 2, the storage unit 50c is # 3, and the storage unit 50d is # 4. The identification numbers # 1 to # 4 correspond to the storage order in the stock mode and the ejection order in the eject mode, which will be described later. The order is # 2, # 3, # 4 sequentially from # 1. Yes.
[0026]
Each of the storage portions 50a to 50d is formed with an opening into which the disc can be inserted on the front side, and a space in which the disc can be stored horizontally is provided on the back side of each opening. In each of the storage units 50a to 50d, a stock completion sensor (51a to 51d) for detecting the completion of storage of the disk and a disk discharge / suction mechanism (not shown) for discharging or sucking the disk by a biasing force of a spring are provided. Is provided.
[0027]
The insertion preventing shutter 217 provided at the disc insertion port 212 so as to be openable and closable is in an unlocked state when the carrier 3 is in a position facing the disc insertion port 212, and the carrier 3 is opened in the storage portion 50a. It is in a locked state when it is in a position other than the position facing the part. Therefore, when the carrier 3 is in the standby state, the carrier 3 is in a position facing the opening of the storage portion 50b, and the MD device during the carrier standby is set with the insertion prevention shutter 217 locked. The intrusion of foreign matter into the inside is prevented.
[0028]
Further, the front portion of the device case 1 is provided with an operation means for performing an operation input or a front panel having an information display function. FIG. 3 is a plan view showing the front panel.
[0029]
In FIG. 3, reference numeral 102 denotes a stock key for inputting a storage command for storing the inserted disk in each storage section (50a to 50d) in the stocker 5 in the apparatus. Reference numerals 103 to 106 denote four discs stored in the storage units (50a to 50d), or MD specification keys (hereinafter simply referred to as No. 5) for specifying storage media for specifying the storage units (50a to 50d). 107 is a spare MD designation key (hereinafter simply referred to as α key), which is a spare medium designation for designating the fifth disk as a spare recording medium. Reference numerals 103a to 107a denote LED indicators provided in the respective keys. It is a lamp. No. The key 103 is used to designate a disk related to the storage section 50a. The key 104 is used to designate a disk related to the storage unit 50b. The key 105 is used to designate a disk related to the storage unit 50c. A key 106 is a disk designation key related to the storage section 50d. Note that the CPU 233 of the MD device has a No. When there are discs corresponding to the keys (103 to 106) and the α key 107, each No. No. corresponding to the keys (103 to 106) and the α key 107. It is assumed that the lamps (103a to 107a) are turned on.
[0030]
Reference numeral 108 denotes a play / pause key for inputting a performance command for playing a disc. When this key is pressed when not playing, the play mode is set. When this key is pressed while playing a disc, the pause mode or stop mode is set. Become. Reference numerals 109 to 111 denote special reproduction keys for setting a special play mode, which will be described later. The RPT key 109 is a repeat performance mode (hereinafter simply referred to as an RPT mode) in which each disk and / or each track (song) is repeatedly played. The RDM key 110 is a random performance mode (hereinafter simply referred to as RDM mode) in which each disk and / or each track is played at random, and the SCN key 111 is only the first part of each disk and / or each track one after another. A scan (search) performance mode for performance (hereinafter simply referred to as an SCN mode) is set.
[0031]
112 is a key for inputting a performance command for the next track, and 113 is a key for inputting a performance command for the next track. 114 and 115 are fast-forward keys and fast-rewind keys. When this key is pressed during the play mode, search performance is performed by so-called cue / review. Reference numeral 116 denotes an eject key for inputting an ejection command for ejecting the disk, that is, ejecting the disk. Reference numeral 117 denotes an LCD display for displaying the operating state of the apparatus. The display 117 can display, for example, a maximum of 15 digits of characters, symbols, and numbers.
[0032]
Incidentally, the MD device configured as described above has been filed by the present applicant as Japanese Patent Application No. 4-329694, Japanese Patent Application No. 4-280052 and Japanese Patent Application No. 4-82016.
[0033]
Next, a control unit that controls the MD device and a signal processing unit will be described. FIG. 4 is a block diagram showing the configuration of the control unit and signal processing unit. Since the spindle motor 219, the turntable 220, the pickup 221, the disc main body 202, and the display device 117 have already been described, description thereof will be omitted.
[0034]
In FIG. 4, reference numeral 222 denotes an RF amplifier that amplifies the high-frequency signal output from the pickup 221. Reference numeral 223 denotes a signal processing unit that converts a signal obtained from the RF amplifier 222 into a digital signal and performs predetermined processing. Reference numeral 224 denotes a memory controller for writing / reading data from the signal processing unit 223 to / from the memory 225. Reference numeral 224A denotes an audio compression / decompression unit that decompresses compressed data read from the memory 225. Although not shown in the figure, when a magnetic head is provided in the MD device so that recording is possible, the audio compression / decompression unit 224A compresses the audio signal and sends the compressed audio signal to the magnetic head. To do.
[0035]
226 is a digital filter that performs various acoustic corrections on the audio data, 227 is a D / A converter that converts the audio data that is a digital signal into an analog signal, and sends the analog audio signal, and 228 amplifies the analog audio signal Audio amplifiers 229 are speakers that output the amplified analog audio signals as audio.
[0036]
A servo processing unit 230 receives a read synchronization signal component from the RF amplifier 222 and other signals and generates a drive control signal. A driver 231 generates a drive signal for driving a light beam irradiation means, a tracking actuator, and a focus actuator (all not shown) of the pickup 221 based on a drive control signal from the servo processing unit 230, and 232 denotes the servo The driver generates a drive signal for driving a mechanical drive mechanism such as the spindle motor 219 in accordance with a drive control signal from the processing unit 230.
[0037]
Reference numeral 233 denotes a CPU as control means for controlling the entire apparatus and communicating with a center unit having a radio tuner, a tape deck function, a volume adjustment function, and the like. Reference numeral 234 denotes a key input interface that receives key input provided on the front panel shown in FIG. 3 and supplies the input data to the CPU 233. Reference numeral 235 denotes a disk loading mechanism controlled by the CPU 233, which includes the various sensors (216a to 216e) and actuators described above, and controls the operation of the carrier 3. A disk stock mechanism 236 is controlled by the CPU 233 and includes a stock completion sensor (51a to 51d) and an actuator, and controls the operation of the stocker 5. Reference numeral 237 denotes a display driver that drives the display unit 117 based on display data output from the CPU 233. Although this example is intended only for reproduction, it goes without saying that if a magnetic head is provided, a recording / reproduction system configuration is obtained.
[0038]
In addition, the MD device is used as a deck type arranged in a driver's cab, but an auto changer main body, which is mainly used in a CD auto changer device, is arranged in a trunk and communicates with the auto changer main body. It can also be used as a black box type in which an interface for performing the above is arranged in the cab. Note that the front panel shown in FIG. 3 is attached to an MD device used as a deck type.
[0039]
Now, the deck type and black box type MD devices will be described with reference to FIGS. FIG. 5 is a block diagram showing a schematic circuit of a main body of the MD device in the deck type. FIG. 6 is a block diagram showing a schematic circuit of the MD apparatus main body in the black box type.
[0040]
In FIG. 5, the deck type MD device is configured to send signals to the MD mechanism 310 which is a mechanical drive mechanism such as the spin doll motor 219 and the drivers 231 and 232, and the audio signal such as the RF amplifier 222 and the audio compression / decompression unit 224A. MD control circuit 311 which is a signal processing unit for performing processing, and the above-mentioned No. A disk presence / absence indicator 313 corresponding to the lamps (103a to 107a), a slave microcomputer 233A for controlling the MD mechanism 310 and the MD control circuit 311; a key input interface 234; a display driver 237; It has an AM / FM radio tuner and a center unit 400 having a cassette deck function and a master microcomputer 233B for serial communication. The slave microcomputer 233A and the master microcomputer 233B correspond to the CPU 233.
[0041]
In addition, the slave microcomputer 233A and the master microcomputer 233B are respectively provided with eject input ports 312A and 312B. In the case of the deck type MD device, the eject input port 312B of the master microcomputer 233B has an eject input ( The contact point of the eject key 116 is connected.
[0042]
In FIG. 6, the black box type MD device includes the MD mechanism 310, the MD control circuit 311, the disk presence / absence indicator 313, and the slave microcomputer 233A. An eject input is input to the eject input port 312A of the slave microcomputer 233A. Is connected.
[0043]
The black box type MD apparatus main body performs serial communication with the center unit 400 via an interface (not shown) having a master microcomputer 233B in the cab.
[0044]
Therefore, according to the MD apparatus, since the eject input port 312A is provided in the slave microcomputer 233A of the MD apparatus, when using the black box type, the eject input port 312A of the slave microcomputer 233A is ejected. By connecting the inputs, the slave microcomputer 233A can be shared even in the black box type as well as the deck type, and the cost required for the manufacturing process can be significantly reduced.
[0045]
In addition, since the CD autochanger device as a conventional autochanger device has only a play function, the play function is executed when the power is turned on or when the source is switched from the center unit side to the autochanger device side. It is.
[0046]
However, since the MD device has various operation modes such as a stock function and an eject function in addition to the play function, the play function is immediately executed when the power is turned on or when the source is switched to the MD device. If the user wants to switch back to various operation modes such as the stock function and eject function immediately before the power is turned off or when the source is switched to the center unit side, an input operation for selecting the various operation modes must be performed. Inconvenience that it must not occur.
[0047]
Therefore, the CPU 233 of the MD device immediately before the power is turned off, for example, when the power is turned off due to a battery voltage drop at the time of starting the engine, or when the source is switched to the radio tuner on the center unit side temporarily to hear traffic information. Alternatively, the operation mode immediately before the source switching to the center unit side is stored in a memory (not shown) of the CPU 233, and then stored in the memory when the power is turned on or when the source is switched to the MD device side. The operation was executed based on the previous operation mode. Note that the disc data, which is stored data stored in the memory, includes not only the previous mode but also data such as the disc being played, the track, the address position, and the performance mode in the play mode, for example.
[0048]
Therefore, according to the MD device, when the power is turned off or when the source is switched from the source switching to another unit other than the MD device when the power is turned on or the source is switched to the MD device, the user turns the power off. No switching operation is required to return to the operation mode immediately before or at the time of source switching.
[0049]
Further, when the source is switched while the MD device is in the eject mode or the stock mode, the control operation of the CPU 233 is continued until these operations are completed.
[0050]
Next, the operation of the CPU 233 in the MD device will be described based on the flowcharts of FIGS.
[0051]
The gist of the present invention is that a disk waiting for reloading is stored in the original storage unit in which the disk waiting for reloading is stored in accordance with a predetermined input. This processing operation corresponds to the position designation reloading process shown in FIGS.
[0052]
FIG. 7 is a flowchart of a main routine showing main processing operations in the CPU 233 of the MD apparatus.
[0053]
In FIG. 7, when the power to the MD device is turned on (ACC switch is turned on), the disk data related to the storage units (50a to 50d) of the stocker 5 and the disks in the carrier 3 are stored in the vehicle backup power supply. In step S11, it is determined whether the data is held in a memory (not shown) in the CPU 233.
[0054]
If the disk data is not held, the sensors include the disk insertion sensor 216a, loading completion sensor 216b, ejection sensor 216c, disk extraction sensor 216d, disk installation completion sensor 216e, stock completion sensor (51a to 51d), and the like. The storage unit (50a to 50d) and the disk in the carrier 3 are detected to create disk data, and the disk data (data indicating which storage unit of the stocker 5 the disk is stored in) is stored in the memory. Store (step S12).
[0055]
Next, it is determined whether or not the stock key 102 has been input (step S13). If the stock key 102 has not been input, it is determined whether or not the eject key 116 has been input (step S14). If the eject key 116 has not been input, it is determined whether or not the play key 108 has been input (step S15). If the play key 108 has not been input, it is determined whether or not the α key 107 has been input (step S16). If the α key 107 is not entered, No. It is determined whether or not the key (103 to 106) has been input (step S17). No. If the key (103 to 106) has not been input, the process proceeds to step S13. It should be noted that in a state where the loop between step S13 to step S17 is rotating, that is, a state in which no operation mode such as a stock mode, a play mode or an eject mode has been entered, no operation mode has been entered. “PAUSE” or “STOP” to notify the user is displayed on the display unit 117.
[0056]
If the disk data is held in step S11, the process proceeds to step S13.
[0057]
Further, if the stock key 102 is input in step S13, the process shifts to a stock mode in which the disk is stored in the storage unit (50a to 50d) of the stocker 5 (step S18).
[0058]
If the eject key 116 is input in step S14, the process proceeds to an eject mode in which the disc is ejected from the MD apparatus (step S19).
[0059]
Further, if the play key 108 is input in step S15, the process shifts to a play mode in which a disc is reproduced (step S20).
[0060]
If the α key 107 is input in step S16, it is determined whether or not the α flag is “1” (step S21).
[0061]
Now, the α flag will be described. When the α key 107 is input, the disc inserted from the disc insertion slot 212 is not stored in any of the storage portions (50a to 50d) even if any of the storage portions (50a to 50d) is empty. It is not stored and is mounted directly on the player unit 4. Then, the α flag becomes “1”, and the disc is not stored in these storage units (50a to 50d) until it is ejected from the MD apparatus.
[0062]
Therefore, when the α flag is “1”, even if a disk is stored in each storage section (50a to 50d), access to these disks is prohibited, and recording and / or playback can be performed directly by the α key 107 using the player. This is only for the disc mounted on the section 4.
[0063]
If the eject key 116 is input when the α flag is “1”, the α-designated disc (that is, the disc mounted on the player unit 4) is immediately ejected from the MD device, and the α flag is set to “ 0 ”. When the α flag becomes “0”, any disk stored in each storage unit (50a to 50d) is pulled out, and access to the disk becomes possible again.
[0064]
As described above, when the α flag is “1”, a single disk designated by the input of the α key 107 is selected even though the MD device is a so-called autochanger device capable of storing a plurality of discs. It will function as a single player to be accommodated.
[0065]
As will be described later, when the storage unit (50a to 50d) of the stocker 5 is full after entering the stock mode, the α flag is automatically set when the disc is inserted into the MD device. “1”.
[0066]
Now, returning to FIG. 7 based on the α flag described above.
[0067]
If the α flag is “1” in step S21, the process proceeds to step S17. If the α flag is not “1”, the process proceeds to M9 shown in FIG.
[0068]
Therefore, the processing operation of step S16 and step S21 is not shifted to any operation mode, and if the α key 107 is input when the α flag is “0”, the stock key 102 is not input. You can switch to stock mode.
[0069]
In step S17, No. If the key (103 to 106) is input, the No. It is determined whether or not the disk corresponding to the key (103 to 106) is accommodated in the device (step S22). If there is a corresponding disk, the process proceeds to step S13.
[0070]
If there is no corresponding disk in step S22, it is determined whether or not the α flag is “1” (step S23). If the α flag is “1”, the process proceeds to step S13. If the α flag is not “1” in step S23, the process proceeds to M10 shown in FIG.
[0071]
Therefore, as the processing operation of step S17, step S22 and step S23, when the operation flag is not shifted to any operation mode and the α flag is “0”, the No. corresponding to the unaccommodated empty storage unit is displayed. When the keys (103 to 106) are input, the mode can be shifted to the stock mode without the input of the stock key 102.
[0072]
Further, as the processing operation of the CPU 233, when the operation mode is in progress and the α flag is “0”, the No. corresponding to the α key 107 or the unaccommodated empty storage unit is displayed. When the keys (103 to 106) are input, the mode may be shifted to the stock mode without the input of the stock key 102.
[0073]
Next, processing operations of the CPU 233 in each stock mode, eject mode, and play mode, which are operation modes, will be described.
[0074]
The processing operation of the CPU 233 in the stock mode shown in step S18 will be described based on FIGS.
[0075]
It is determined whether or not the α flag is “1” (step S31). If the α flag is not “1”, it is determined based on the disk data whether each storage unit (50a to 50d) of the stocker 5 has an empty storage unit (step S32). If there is an empty storage section, “STOCK MODE” for notifying the user that the current operation mode has shifted to the stock mode is displayed (step S33), and it is determined whether or not a disk is stored in the carrier 3. (Step S34). If the disc is accommodated in the carrier 3, “WAIT” prompting the user to wait is displayed (step S35), and it is determined whether or not the current play operation is being performed (step S36).
[0076]
If the play operation is currently being performed, the play operation is stopped (step S37), the disk in the carrier 3 is stored in the original storage unit based on the disk data (step S38), and the carrier 3 is inserted into the disk. The position is moved to the position facing the opening 212, that is, the insertion opening position (step S39), "STOCK STANDBY" prompting the user to prepare for disk storage is displayed (step S40), and the process proceeds to M1 shown in FIG.
[0077]
If the α flag is “1” in step S31, the user is informed that the disk cannot be stored in the stocker 5, that is, the α-designated disk (α disk) is already stored. “α-DISC” is displayed (step S41), and the stock mode is terminated. That is, the process proceeds to step S14 in FIG. If there is no empty storage unit in step S32, the process proceeds to M2 shown in FIG.
[0078]
If no disk is stored in the carrier 3 in step S34, the process proceeds to step S39. If it is determined in step S36 that no play operation is currently being performed, the process proceeds to step S38.
[0079]
In M1 shown in FIG. 9, it is determined whether or not the disk is stored in the storage unit 50a corresponding to the identification number # 1 (step S51). If the disk is stored in the storage section 50a corresponding to # 1, it is determined whether or not the disk is stored in the storage section 50b corresponding to # 2 (step S52). If the disk is stored in the storage section 50b corresponding to # 2, it is determined whether or not the disk is stored in the storage section 50c corresponding to # 3 (step S53). If the disc is stored in the storage portion 50c corresponding to # 3, the disc newly inserted from the disc insertion port 212 is set to be stored in the storage portion 50d corresponding to # 4 (step S54). ), A timer (not shown) in the CPU 233 is started (step S55).
[0080]
If no disk is stored in the storage section 50a corresponding to # 1 in step S51, the disk inserted from the disk insertion port 212 is set to be stored in the storage section 50a corresponding to # 1. (Step S56), the process proceeds to Step S55. If no disk is stored in the storage section 50b corresponding to # 2 in step S52, the disk inserted from the disk insertion port 212 is set to be stored in the storage section 50b corresponding to # 2. (Step S57), the process proceeds to Step S55. If no disk is stored in the storage section 50c corresponding to # 3 in step S53, the disk inserted from the disk insertion port 212 is set to be stored in the storage section 50c corresponding to # 3. (Step S58), the process proceeds to Step S55.
[0081]
Therefore, steps S51 to S54 and steps S56 to S58 are an auto setting process for automatically setting the storage position.
[0082]
It is determined whether or not there is a key input after the timer is started in step S55 (step S59). If there is no key input, it is determined whether or not a disc has been inserted from the disc insertion slot 212 (step S60). If a disc has not been inserted, it is determined whether or not the timer started in step S55 has timed out (step S61). If timed out, the currently displayed display is turned off (step S62), the carrier 3 is moved to a standby position, for example, a position facing the storage section 50b (step S63), and the stock mode is terminated.
[0083]
If there is a key input in step S59, the key input is the α key 107 or No. It is determined whether or not the key input (103 to 106) has been made (step S64). α key 107 or No. If the key (103 to 106) is input, the input No. It is determined whether or not the storage units (50a to 50d) corresponding to the keys (103 to 106) are empty storage units (step S65). If the input storage unit is an empty storage unit, the storage unit set in the auto setting process in step S54, step S56, step S57 or step S58 is replaced with the corresponding storage unit input in step S64. (Step S66), and the process proceeds to step S60. When there is a key input of the α key 107 in step S64, the process of step S65 is performed. From Move on to step S66 Ru .
[0084]
Therefore, steps S64, S65, and S66 are a manual setting process for arbitrarily setting the storage position.
[0085]
If there is no empty storage unit in step S65, “DISC” is displayed to notify the user that the disk is stored in the corresponding storage unit input in step S64 (step S67), and M4 shown in the figure. Migrate to In this case, the process may move to step S55.
[0086]
In step S64, the α key 107 or No. If the key (103 to 106) has not been input, it is determined whether or not the key input in step S59 was a key input for the stock key 102 (step S68). If the stock key 102 has not been input, it is determined whether or not the play key 108 has been input (step S69). If the play key 108 has not been input, it is determined whether or not the eject key 116 has been input (step S70). If the eject key 116 has not been input, the process proceeds to step S62.
[0087]
If the stock key 102 is input in step S68, the process proceeds to step S62. If the play key 108 is input in step S69, the process shifts to the play mode in step S20 shown in FIG. If the eject key 116 is input in step S70, the process proceeds to the eject mode in step S19 shown in FIG.
[0088]
If a disc is inserted from the disc insertion port 212 in step S60, the process proceeds to M3 shown in FIG.
[0089]
In M3 shown in FIG. 10, it is determined whether or not the α key 107 is input in step S59 (step S81). If the α key 107 is input, the α flag is set to “1” (step S82), and the No. corresponding to the α key 107 is set. The lamp 107a is lit and displayed (step S83), and the lit display number corresponding to the storage section (50a to 50d) that is storing the disk is displayed. The lamps (103a to 106a) are turned off (step S84), and the play mode of step S20 shown in FIG. 7 is entered. As described above, when the α disk is accommodated in the apparatus, access to the other accommodated disk is prohibited, so that the user-friendliness is improved by executing the processing operation in step S84.
[0090]
If it is determined in step S81 that the α key 107 has not been input in step S59, the automatic setting process in step S54, step S56, step S57, and step S58 shown in FIG. 9 or the manual setting process in step S66 is performed. The discs inserted from the disc insertion slot 212 are stored in the set storage portions (50a to 50d) (step S85), and the numbers corresponding to the storage portions (50a to 50d) storing the discs are stored. The lamps (103a to 106a) are turned on (step S86), and it is determined whether or not there is an empty storage unit in the stocker 5 (step S87). If there is an empty storage part, the carrier 3 is moved to the insertion port position (step S88), and the process proceeds to M5 shown in FIG.
[0091]
If there is no empty storage unit in step S87, the process proceeds to M6 shown in FIG.
[0092]
In M6 shown in FIG. 11, if there is no empty storage section, “NEXT α-DISC” is displayed to notify the user that the next disk inserted from the disk insertion slot 212 is automatically set to the α disk ( Step S101), it is determined whether or not a disk is accommodated in the carrier 3 (Step S102). If the disc is stored in the carrier 3, “WAIT” prompting the user to wait is displayed (step S103), and it is determined whether or not the current play operation is being performed (step S104). If the play operation is being performed, the play operation is stopped (step S105), and the disc for which the play operation has been stopped is stored in the original storage unit (step S106).
[0093]
Next, the carrier 3 is moved to the insertion slot position (step S107), "STOCK STANDBY" prompting the user to prepare for storing the disk is displayed (step S108), the timer is started (step S109), and the key input is It is determined whether there has been (step S110). If there is no key input, it is determined whether or not a disc has been inserted from the disc insertion slot 212 (step S111). If a disc has been inserted, the process proceeds to M7 shown in FIG. If no disc has been inserted, it is determined whether or not the timer started in step S110 has timed out (step S112). If timed out, the process proceeds to M8 shown in FIG. On the other hand, if not timed out, the process proceeds to step S110.
[0094]
If no disk is stored in the carrier 3 in step S102, the process proceeds to step S107. If the play operation is not in progress at step S104, the process proceeds to step S106.
[0095]
If there is a key input in step S110, it is determined whether or not the key input is a play key 108 key input (step S113). If the play key 108 has not been input, it is determined whether or not the eject key 116 has been input (step S114). If the eject key 116 is not input, it is determined whether or not the stock key 102 has been input (step S115). If the stock key 102 has not been input, the process proceeds to step S111.
[0096]
If the play key 108 is input in step S113, the process shifts to the play mode in step S20 shown in FIG. If the eject key 116 is input in step S114, the process proceeds to the eject mode in step S19 shown in FIG. If the stock key 102 is input in step S115, the process proceeds to M8 shown in FIG.
[0097]
In M9 shown in FIG. 10, if the α flag is not “1” in step S21 shown in FIG. 7, a timer is started (step S89), and whether or not a disc has been inserted from the disc insertion port 212 is checked. Is determined (step S90). If a disc has been inserted, the process proceeds to step S82.
[0098]
If the disk is not inserted in step S90, it is determined whether or not the timer started in step S89 has timed out (step S91). If timed out, the timer is reset (step S92), and the process proceeds to M8 shown in FIG. If the timer has not timed out in step S91, the process proceeds to step S90.
[0099]
Next, the processing operation of the CPU 233 in the eject mode shown in step S19 will be described with reference to FIGS.
[0100]
In the ejection mode, the disk in the MD apparatus is automatically ejected from the disk insertion slot 212 in a predetermined order, and the disk in the MD apparatus is arbitrarily selected and ejected from the disk insertion slot 212. The manual ejection process is performed, and the auto ejection process and the manual ejection process are alternatively selected depending on the depression time of the ejection key 116, that is, the input time. In this embodiment, when the eject key 116 is pressed for a long time, the process shifts to auto-eject processing, and when the eject key 116 is pressed for a short time, the process shifts to manual eject process.
[0101]
First, the transition to the eject mode is performed by inputting the eject key 116 (affirmative determination in step S14 in FIG. 7).
[0102]
When the eject key 116 is input, it is determined in FIG. 12 whether or not there is a disk in the MD device, that is, in the stocker 5, carrier 3 or player 4 (step S121). If there is a disk in the MD device, it is determined whether or not there is only one disk in the MD device (step S122). If there is not one disk in the MD device, a timer is started (step S123), and it is determined whether 2 seconds have passed (step S124).
[0103]
If two seconds have not elapsed, it is determined whether or not the input eject key 116 is in an OFF state, that is, whether or not the input of the eject key 116 at the time of shifting to the eject mode has been released (step) S125). If the eject key 116 is in the OFF state, the timer started in step S123 is reset (step S126), and the process proceeds to E5 shown in FIG. 15, which will be described later, that is, manual eject processing for selecting an arbitrary disk.
[0104]
If there is no disk in the MD device in step S121, the eject mode is terminated. If it is determined in step S122 that there is only one disk in the MD device, the process proceeds to E3 shown in FIG. As will be described later, the processing after E3 automatically ejects the disk existing in the apparatus. However, as shown in step S124 and step S125, the processing after E3 depends on the pressing time of the eject key 116. In a system that can select whether the disc is ejected manually or automatically, the determination in step S122 is provided, and if there is only one disc in the apparatus, the auto side is immediately selected. By doing so, it is convenient for the user without waiting for a long key press. Of course, step S122 may be omitted and the process may proceed to step S123 after an affirmative determination in step S121.
[0105]
Returning to FIG. 12, if the eject key 116 is not in the OFF state in step S125, that is, if the eject key 116 input at the time of transition to the eject mode is kept pressed, the process proceeds to step S124.
[0106]
If two seconds have elapsed in step S124, the timer started in step S123 is reset (step S127), and the process proceeds to E1 shown in FIG. 13, that is, an automatic eject process for automatically ejecting the disc. To do.
[0107]
In E1 shown in FIG. 13 as the auto-eject process, it is determined whether or not the α flag is “1” (step S131). If the α flag is “1”, the α disk is ejected from the disk insertion slot 212 to the reload position (reloadable eject position) (step S132), the timer is started (step S133), and 10 seconds have elapsed. It is determined whether or not (step S134). If 10 seconds has not elapsed, a position designation reload process described later is executed (step S200), and then it is determined whether or not the α disk at the reload position, ie, waiting for reloading, has been removed (step S135). . If the α disk has been removed, the α flag is set to “0” (step S136), and the No. corresponding to the α key 107 is set. The lamp 107a is turned off (step S137), the timer started in step S133 is reset (step S138), and the process proceeds to E2 shown in FIG.
[0108]
If the α flag is not “1” in step S131, the process proceeds to E2 shown in FIG. If the disk has not been removed in step S135, the process proceeds to step S134. If 10 seconds have elapsed in step S134, the reloading-waiting α-disk is automatically reloaded, the auto-reloaded α-disk is mounted on the player unit 4 (step S139), and the eject mode is terminated. Note that after the α disk is pulled in, the carrier 3 may be moved to the standby position described with reference to step S63.
[0109]
In E2 shown in FIG. 14, it is determined whether there is a disk stored in the # 1 storage unit 50a (step S141). If there is a disk stored in the # 1 storage section 50a, the disk stored in # 1 is ejected from the disk insertion port 212 to the reload position (step S142), and a timer is started (step S143).
[0110]
If there is no disk stored in the # 1 storage section 50a in step S141, it is determined whether there is a disk stored in the # 2 storage section 50b (step S144). If there is a disk stored in the # 2 storage section 50b, the disk stored in the # 2 storage section 50b is ejected from the disk insertion port 212 to the reload position (step S145), and the process proceeds to step S143.
[0111]
If there is no disk stored in the # 2 storage section 50b in step S144, it is determined whether there is a disk stored in the # 3 storage section 50c (step S146). If there is a disk stored in the # 3 storage section 50c, the disk stored in the # 3 storage section 50c is ejected from the disk insertion port 212 to the reload position (step S147), and the process proceeds to step S143.
[0112]
If there is no disk stored in the # 3 storage section 50c in step S146, it is determined whether there is a disk stored in the # 4 storage section 50d (step S148). If there is a disk stored in the # 4 storage section 50d, the disk stored in the # 4 storage section 50d is ejected from the disk insertion port 212 to the reload position (step S149), and the process proceeds to step S143.
[0113]
If there is no disk stored in the # 4 storage section 50d in step S148, it is determined whether or not the α flag is “1” (step S150). If the α flag is not “1”, the eject mode is terminated.
[0114]
In step S143, the timer is started, and it is determined whether 10 seconds have elapsed (step S151). If 10 seconds has not elapsed, a position designation reload process, which will be described later, is performed (step S200), and it is determined whether or not the reloading standby disk has been removed (step S152). If the disc has been removed, the No. corresponding to the storage portion of the removed disc is stored. The lamps (103a to 106a) are turned off (step S153), the timer started in step S143 is reset (step S154), and the process proceeds to step S141.
[0115]
If the disk has not been removed in step S152, the process proceeds to step S151. If 10 seconds have elapsed in step S151, the reloading standby disk is automatically reloaded, the autoreloaded disk is stored in the original storage unit (step S155), and the ejection mode is terminated.
[0116]
If the α flag is “1” in step S150, the process proceeds to E4 shown in FIG.
[0117]
In the processing operation of step S122 shown in FIG. 12 described above, if there is one disk in the MD device, the process moves to the E3 auto-eject processing shown in FIG. Since the disc is automatically ejected by preventing a situation where the disc is ejected by manual operation when there is only one disc, the user's operation can be saved.
[0118]
Further, in E5 shown in FIG. 15 as the manual eject process, it is determined whether or not the α flag is “1” (step S161). If the α flag is “1”, the α disk is ejected to the reload position (step S162), the timer is started (step S163), and it is determined whether 10 seconds have elapsed (step S164). If 10 seconds has not elapsed, a position designation reload process (to be described later) is performed (step S200), and it is determined whether or not the α disk waiting for reloading has been pulled out (step S165). If the disk has been pulled out, the α flag is set to “0” (step S166), and the α key 107 No. The lamp 107a is turned off (step S167), the timer started in step S163 is reset (step S168), and the process proceeds to E7 shown in FIG.
[0119]
If the α flag is not “1” in step S161, the process proceeds to E7 shown in FIG.
[0120]
If the disk has not been pulled out in step S165, the process proceeds to step S164. If 10 seconds have elapsed in step S164, the process proceeds to E6 shown in FIG.
[0121]
In E7 shown in FIG. 16, it is determined whether or not there is a disk in the MD device (step S171). If there is a disk in the MD device, it is determined whether or not there is only one disk in the MD device (step S172). If there is not one disk in the MD device, each No. corresponding to the storage unit (50a to 50d) in which the disk in the MD device is to be stored. The lamps (103a to 106a) are blinked (step S173), and it is determined whether or not the eject key 116 has been input (step S174). In addition, No. in step S173. The blinking display of the lamps (103a to 106a) is to prompt the user that there is a disc that can be ejected.
[0122]
If the eject key 116 has not been input, it is determined whether or not the stock key 102 has been input (step S175). If the stock key 102 has not been input, it is determined whether or not the play key 108 has been input (step S176). If the play key 108 has not been input, No. It is determined whether or not the key (103 to 106) has been input (step S177). No. If the key (103 to 106) is input, the input No. It is determined whether there is a disk corresponding to the key (103 to 106) (step S178). If there is a corresponding disk, the corresponding disk is ejected from the disk insertion port 212 to the reload position (step S179), a timer is started (step S180), and it is determined whether or not 10 seconds have passed (step S181). If 10 seconds has not elapsed, a position designation reload process described later is performed (step S200), and it is determined whether or not the reloading standby disk has been removed (step S182). If the disc has been removed, the No. corresponding to the removed disc. No. of the key (103 to 106). The lamps (103a to 106a) are turned off (step S183), the timer started in step S180 is reset (step S184), and the process proceeds to step S171.
[0123]
If there is no disk in the MD device in step S171, the eject mode is terminated.
[0124]
If it is determined in step S172 that there is one disk in the MD device, the process proceeds to E3 shown in FIG. If the eject key 116 is input in step S174, the eject mode is terminated.
[0125]
If the stock key 102 is input in step S175, the process proceeds to the stock mode in step S18 shown in FIG. If the play key 108 is input in step S176, the process shifts to the play mode in step S20 shown in FIG.
[0126]
In step S177, No. If the key (103 to 106) has not been input, or if there is no corresponding disk in step S178, the process proceeds to step S174.
[0127]
It should be noted that in the processing operations in steps S177 and S178, No. specifying the disk to be ejected. When waiting for the input of the keys (103 to 106), the No. corresponding to the unaccommodated empty storage section. When the key (103 to 106) is input, the mode may be shifted to the stock mode. In this case, even if the user is in the eject mode, the user can quickly shift to the stock mode without input operation of the stock key 102.
[0128]
If the disk has not been removed in step S182, the process proceeds to step S181. If 10 seconds have elapsed in step S181, the reloading standby disk is automatically reloaded, the autoreloaded disk is stored in the original storage unit (step S185), and blinked in step S173. No. The lamps (103a to 106a) are turned on (step S186), and the eject mode is terminated.
[0129]
In addition, before the timer started in step S180 passes 10 seconds, No. If the key (103 to 106) or the α key 107 is input, the disk waiting for reloading is automatically reloaded, and after the automatically reloaded disk is stored in the original storage unit, the key input is performed. No. corresponds to the empty storage section. If it is a key (103 to 106), the input No. The disc may be stored in an empty storage unit corresponding to the keys (103 to 106), or if the key input is the α key 107, the mode may be shifted to a stock mode to be mounted on the player unit 4. .
[0130]
In this case, even if the user is in the eject mode, the user can quickly shift to the stock mode without input operation of the stock key 102.
[0131]
The reason why the disk waiting for reloading is automatically reloaded after a lapse of a predetermined time is to ensure the integrity of the disk and the MD device against foreign matters such as dust and dust, especially in the case of in-vehicle use. This is to prevent the disk from dropping due to vibration.
[0132]
Therefore, according to the eject mode, the user can select the disc to be ejected by providing an auto eject process for automatically ejecting the disc in the MD device from the disc insertion slot 212 in a predetermined order. No operation is necessary.
[0133]
In addition, according to the eject mode, each eject process such as the auto eject process and the manual eject process can be selected, so that the user can select a user-friendly eject process.
[0134]
In addition, since the selection of these ejection processes is alternatively selected according to the depression time of the ejection key 116, that is, the difference in the input time, it is not necessary to add an input key and a sufficient key space can be secured. .
[0135]
Next, the processing operation of the CPU 233 in the position designation reload process in step S200 will be described with reference to FIGS. 17 and 18 are flowcharts showing the processing operation of the CPU 233 in the position designation reloading process of the first embodiment.
[0136]
In the first embodiment, the position designation reloading process is performed when the eject key 116 is input while the disk is waiting for reloading. If it is not an α disk, the eject mode is continued after being stored in the original storage section.
[0137]
In FIG. 17, it is determined whether the disk ejected to the reload position, that is, the disk waiting for reloading is an α disk (step S201). If the reloading standby disk is an α disk, it is determined whether or not the eject key 116 has been input (step S202). If the eject key 116 has not been input, it is determined whether or not there is an empty storage unit in the stocker 5 (step S203). If there is no empty storage section, it is determined whether or not the stock key 102 has been input (step S204). If the stock key 102 has not been input, it is determined whether or not the α key 107 has been input (step S205). If the α key 107 has not been input, the position designation reload process is terminated.
[0138]
If the reloading standby disk is not an α disk in step S201, the process proceeds to E11 shown in FIG.
[0139]
If the eject key 116 is input in step S202, the reloading standby disc is loaded on the player unit 4 (step S206), and it is determined whether the α key 107 is input (step S206). Step S207). Note that step S207 may be omitted.
[0140]
If the α key 107 has been input, it is determined whether or not the process at the time of shifting to the position designation reload process is a manual eject process (step S208). If it is a manual eject process (if it is execution of step S200 shown in FIG. 15 or FIG. 16), it will transfer to E10 shown in FIG. Further, if it is not manual ejection processing, that is, if it is auto ejection processing (if execution of step S200 shown in FIG. 13 or FIG. 14), the process proceeds to E4 shown in FIG.
[0141]
If there is an empty storage unit in step S203, the process proceeds to E12 shown in FIG. If the stock key 102 is input in step S204, it is determined whether or not the α key 107 is input (step S209). Note that step S209 may be omitted.
[0142]
If the α key 107 is input, the reloading standby disc is automatically reloaded, and the auto-reloaded disc is loaded on the player unit 4 (step S210), and the play mode shown in FIG. Move to P1. In addition, although it shifted to P1 of play mode after the process of step S210, you may make it complete | finish this position designation reload process.
[0143]
In E11 shown in FIG. 18, it is determined whether or not the eject key 116 has been input (step S221). If the eject key 116 has not been input, it is determined whether or not the stock key 102 has been input (step S222). If the stock key 102 has not been input, it is determined whether or not the α key 107 has been input (step S223). If the α key 107 is not input, the No. corresponding to the empty storage section is displayed. It is determined whether or not the key (103 to 106) has been input (step S224). Applicable No. If the key (103 to 106) is input, the input No. The disk waiting for reloading is stored in the empty storage part corresponding to the key (103 to 106) (step S225), and the No. corresponding to the disk waiting for reloading is stored. The lamps (103a to 106a) are turned off, and the numbers corresponding to the storage units (50a to 50d) storing the discs are stored. No. of the key (103 to 106). The lamps (103a to 106a) are turned on (step S226), and the process proceeds to E13 shown in FIG.
[0144]
Note that in the process of step S224, step S225, step S226, and the like, No. By inputting the keys (103 to 106), it is possible to store the disk in the waiting state for reloading in an arbitrary empty storage unit without shifting to the stock mode and to perform an input operation for shifting again to the eject mode. However, since the eject mode is continued, it is possible to greatly reduce the labor required for the user's input operation.
[0145]
Further, after the process of step S226, the process proceeds to E13 shown in FIG. 16, but the position designation reload process may be terminated or the process may be shifted to the stock mode.
[0146]
If the stock key 102 is input in step S222, the α key 107 and the No. corresponding to the empty storage unit are displayed. No. corresponding to the keys (103 to 106). After blinking the lamps (103a to 107a), it is determined whether or not the α key 107 is input (step S227). If the α key 107 is not input, the No. corresponding to the empty storage section is displayed. It is determined whether or not a key (103 to 106) has been input (step S228). No. corresponding to the empty storage section. If the key (103 to 106) has not been input, the process proceeds to step S227. In step S228, the No. corresponding to the empty storage unit is displayed. If the key (103 to 106) has been input, the process proceeds to step S225.
[0147]
In step S222, the stock key 102 is input, and in step S228, the No. corresponding to the empty storage unit is displayed. If the key (103 to 106) has been input, the eject mode can be set even if there is no input operation for storing the disc in the waiting state for reloading in an arbitrary empty storage section and shifting to the eject mode again. Since the operation is continued, it is possible to greatly reduce the time and effort required for the user's input operation.
[0148]
If the α key 107 is input in step S223, the process proceeds to E14 shown in FIG. If the α key 107 is input in step S227, the process proceeds to E15 shown in the figure.
[0149]
In step S224, the No. corresponding to the empty storage unit is displayed. If the key (103 to 106) has not been input, the position designation reload process is terminated. If the eject key 116 is input in step S221, the reloading standby disk is automatically reloaded, and the autoreloaded disk is stored in the original storage unit (step S229). The process proceeds to E13 shown. Note that the affirmative judgment of step S221 and the processing operation of step S229 correspond to claim 1, and the transition to E13 shown in FIG. 16 after the processing of step S229 corresponds to claim 2. Further, the affirmative determination in step S203 and the processing operation in step S206 correspond to claims 3 and 4.
[0150]
According to the position designation reloading process of the first embodiment, when the eject key 116 is input even if a predetermined time until the auto reloading is started in the eject mode, the disk waiting for reloading is automatically reloaded. If the auto-reloaded disc is an α disc, the disc is placed in the original storage unit after the disc is mounted on the player unit 4 or if the auto-reloaded disc is not an α disc. Since the eject mode is continued after the storage, the user's input operation can be greatly reduced.
[0151]
Further, according to the position designation reloading process of the first embodiment, the No. corresponding to the empty storage unit is not required even if the predetermined time until the auto-reloading is started in the eject mode. When the keys (103 to 106) are input, the disk waiting for reloading is automatically reloaded, and the automatically reloaded disk is referred to as the input No. Since the eject mode is continued after being stored in the empty storage portion corresponding to the keys (103 to 106), it is possible to greatly reduce the time and effort required for the user's input operation.
[0152]
In the position designation reloading process of the first embodiment, when the eject key 116 is input, the reloading waiting disk is automatically reloaded into the MD device, but the user is waiting for the reloading. Even when the disc is pushed in by hand, the disc may be automatically reloaded into the MD device without key input. In this case, the CPU 233 of the MD device uses the α disc as the auto-reloaded disc. If there is, the disc is mounted on the player unit 4, or if the disc is not an α disc, the disc is stored in the original storage unit.
[0153]
Further, if the α disk is mounted on the player unit 4 by auto reload, the play mode P1 shown in FIG. 23 may be entered, or the position designation reload process may be terminated. May be.
[0154]
Next, the processing operation of the CPU 233 in the position designation reload process of the second embodiment will be described. In addition, the same code | symbol is attached | subjected to what overlaps with 1st Example, and the description is abbreviate | omitted.
[0155]
In the position designation reload process of the second embodiment, in addition to the position designation reload process of the first embodiment, the disk waiting for reloading at the time of the position designation reload process of the first embodiment is stored in the original storage section. If the disk is stored in a storage unit other than the storage unit storing the disk, the disk is ejected in a predetermined order.
[0156]
FIG. 19 is a flowchart showing the processing operation of the CPU 233 in the position designation reloading process of the second embodiment.
[0157]
After the process of step S229 shown in FIG. 18 in the position designation reload process of the first embodiment, the process proceeds to E20 shown in FIG.
[0158]
In E20 shown in FIG. 19, it is determined whether or not the processing step at the time of shifting to the position designation reload processing is manual ejection processing (step S231). If it is a manual ejection process, the process proceeds to E13 shown in FIG. Note that step S231 may be omitted and the process may directly move to step S232 after E20.
[0159]
If it is not manual eject processing, that is, if it is auto eject processing, it is determined whether or not the disc stored in step S229 shown in FIG. 18 is the disc stored in the # 1 storage section 50a (see FIG. 18). Step S232). If the disk is stored in the # 1 storage section 50a, it is determined whether there is a disk stored in the # 2 storage section 50b (step S233). If there is a disk stored in the # 2 storage section 50b, the disk stored in the # 2 storage section 50b is ejected to the reload position (step S234), and the process proceeds to E17 shown in FIG.
[0160]
If there is no disk stored in the # 2 storage section 50b in step S233, it is determined whether there is a disk stored in the # 3 storage section 50c (step S235). If there is a disk stored in the # 3 storage section 50c, the disk stored in the # 3 storage section 50c is ejected to the reload position (step S236), and the process proceeds to E17 shown in FIG.
[0161]
If there is no disk stored in the # 3 storage section 50c in step S235, it is determined whether there is a disk stored in the # 4 storage section 50d (step S237). If there is a disk stored in the # 4 storage section 50d, the disk stored in the # 4 storage section 50d is ejected to the reload position (step S238), and the process proceeds to E17 shown in FIG.
[0162]
If there is no disk stored in the # 4 storage section 50d in step S237, the disk stored in the # 1 storage section 50a is ejected to the reload position (step S239), and E17 shown in FIG. Migrate to
[0163]
If the disk stored in step S229 shown in FIG. 18 in step S232 is not the disk stored in the # 1 storage section 50a, the process proceeds to E16 shown in FIG.
[0164]
In E16 shown in FIG. 20, it is determined whether or not the disk stored in step S229 shown in FIG. 18 is a disk stored in the # 2 storage section 50b (step S241). If there is a disk stored in the # 2 storage section 50b, it is determined whether there is a disk stored in the # 3 storage section 50c (step S242). If there is a disk stored in the # 3 storage section 50c, the disk stored in the # 3 storage section 50c is ejected to the reload position (step S243), and the process proceeds to E19 shown in FIG.
[0165]
If there is no disk stored in the # 3 storage section 50c in step S242, it is determined whether there is a disk stored in the # 4 storage section 50d (step S244). If there is a disk stored in the # 4 storage section 50d, the disk stored in the # 4 storage section 50d is ejected to the reload position (step S245), and the process proceeds to E19 shown in FIG.
[0166]
If there is no disk stored in the # 4 storage section 50d in step S244, it is determined whether there is a disk stored in the # 1 storage section 50a (step S246). If there is a disk stored in the # 1 storage section 50a, the disk stored in the # 1 storage section 50a is ejected to the reload position (step S247), and the process proceeds to E19 shown in FIG.
[0167]
If there is no disk stored in the # 1 storage section 50a in step S246, the disk stored in the # 2 storage section 50b is ejected to the reload position (step S262). The process proceeds to E19 shown.
[0168]
If the disk stored in step S229 shown in FIG. 18 in step S241 is not the disk stored in the # 2 storage section 50b, the disk stored in step S229 shown in FIG. 18 is stored in # 3. It is determined whether the disk is stored in the unit 50c (step S248). If the disk is stored in the # 3 storage section 50c, it is determined whether there is a disk stored in the # 4 storage section 50d (step S249). If there is a disk stored in the # 4 storage section 50d, the disk stored in the # 4 storage section 50d is ejected to the reload position (step S250), and the process proceeds to E19 shown in FIG.
[0169]
If there is no disk stored in the # 4 storage section 50d in step S249, it is determined whether there is a disk stored in the # 1 storage section 50a (step S251). If there is a disk stored in the # 1 storage section 50a, the disk stored in the # 1 storage section 50a is ejected to the reload position (step S252), and the process proceeds to E19 shown in FIG.
[0170]
If there is no disk stored in the # 1 storage section 50a in step S251, it is determined whether there is a disk stored in the # 2 storage section 50b (step S253). If there is a disk stored in the # 2 storage section 50b, the disk stored in the # 2 storage section 50b is ejected to the reload position (step S254), and the process proceeds to E19 shown in FIG.
[0171]
If there is no disk stored in the # 2 storage section 50b in step S253, the disk stored in the # 3 storage section 50c is ejected to the reload position (step S263), and E19 shown in FIG. Migrate to
[0172]
If the disk stored in step S229 shown in FIG. 18 in step S248 is not the disk stored in the # 3 storage section 50c, the disk is stored in the # 4 storage section 50d. The process proceeds to E18 in the figure.
[0173]
In E18 in the figure, it is determined whether there is a disk stored in the # 1 storage section 50a (step S256). If there is a disk stored in the # 1 storage section 50a, the disk stored in the # 1 storage section 50a is ejected to the reload position (step S257), and the process proceeds to E19 shown in FIG.
[0174]
If there is no disk stored in the # 1 storage section 50a in step S256, it is determined whether there is a disk stored in the # 2 storage section 50b (step S258). If there is a disk stored in the # 2 storage section 50b, the disk stored in the # 2 storage section 50b is ejected to the reload position (step S259), and the process proceeds to E19 shown in FIG.
[0175]
If there is no disk stored in the # 2 storage section 50b in step S258, it is determined whether there is a disk stored in the # 3 storage section 50c (step S260). If there is a disk stored in the # 3 storage section 50c, the disk stored in the # 3 storage section 50c is ejected to the reload position (step S261), and the process proceeds to E19 shown in FIG.
[0176]
If there is no disk stored in the # 3 storage section 50c in step S260, the disk stored in the # 4 storage section 50d is ejected to the reload position (step S264), and E19 shown in FIG. Migrate to
[0177]
If the disk stored in step S229 shown in FIG. 18 in step S255 is not the disk stored in the # 4 storage section 50d, the process similarly proceeds to E19 shown in FIG.
[0178]
According to the position specification reloading process of the second embodiment, not only the effect of the position specification reloading process of the first embodiment, but also the disk waiting for reloading at the time of the position specification reloading process of the first embodiment is originally stored. Since the disc is automatically ejected in a predetermined order if the disc is stored in a storage portion other than the storage portion in which the disc is stored, the user can It is possible to remarkably reduce the operation labor when ejecting a disk stored in another storage unit other than the original storage unit in which the disk is stored during the position designation reloading process of the first embodiment.
[0179]
Next, the backup eject mode when the power is turned off will be described. 21 and 22 are flowcharts showing the processing operation of the CPU 233 in the backup eject mode.
[0180]
In the backup eject mode, even when the power is turned off, that is, when the ACC switch is turned off, the CPU 233 is energized by the power supply from the backup power supply, and the disk in the MD device is ejected. The CPU 233 starts the backup eject mode when the eject key 116 is input when the power is off.
[0181]
In FIG. 21, it is determined whether or not the α flag is “1” (step S271). If the α flag is “1”, the α disk is ejected from the disk insertion slot 212 to the reload position (step S272), a timer is started (step S273), and it is determined whether 10 seconds have elapsed (step S273). Step S274). If 10 seconds has not elapsed, it is determined whether or not the reloading standby disk has been removed (step S275). If the disk has been removed, the α flag is set to “0” (step S276), and the No. corresponding to the removed α disk is set. The lamp 107a is turned off (step S277), the timer started in step S273 is reset (step S278), and the process proceeds to E30 shown in FIG.
[0182]
If the α flag is not “1” in step S271, the process proceeds to E30 shown in FIG.
[0183]
If it is determined in step S275 that the α disk waiting for reloading has not been removed, the process proceeds to step S274. If 10 seconds have passed in step S274, the reloading standby α-disk is automatically reloaded, and the auto-reloaded disk is mounted on the player unit 4 or the carrier 3 is moved to the standby position. (Step S279), the backup eject mode is terminated, and the CPU 233 is deactivated again.
[0184]
In E30 shown in FIG. 22, it is determined whether or not there is a disk in the MD device (step S281). If there is a disk in the MD apparatus, the No. corresponding to the storage unit (50a to 50d) in which the disk in the MD apparatus is stored. No. of the key (103 to 106). The lamps (103a to 106a) are blinked (step S282), the timer is started (step S283), and it is determined whether or not 5 seconds have passed (step S284). If 5 seconds have not passed, No. It is determined whether or not the key (103 to 106) has been input (step S285). No. If the key (103 to 106) is input, the input No. It is determined whether or not there is a corresponding disk corresponding to the key (103 to 106) (step S286). If there is a corresponding disk, the timer started in step S283 is reset (step S287), and the corresponding disk is ejected to the reload position (step S288). In step S282, no. The lamps (103a to 106a) are displayed in a blinking manner. No. of the lamps (103a to 106a). This is to prompt the user that there is a disc that can be ejected in the storage section (50a to 50d) corresponding to the key (103 to 106).
[0185]
Next, a timer is started (step S289), and it is determined whether 10 seconds have elapsed (step S290). If 10 seconds has not elapsed, it is determined whether or not the reloading standby disk has been removed (step S291). If the disk has not been removed, the flashing No. corresponding to the removed disk is displayed. The lamps (103a to 106a) are turned off (step S292), the timer started in step S289 is reset (step S293), and the process proceeds to step S281.
[0186]
In step S285, no. If the key (103 to 106) has not been input, or if there is no corresponding disk in step S286, the process proceeds to step S284. If 5 seconds have elapsed in step S284, the backup eject mode is terminated and the CPU 233 is deactivated again.
[0187]
On the other hand, if the disk waiting for reloading is not removed in step S291, the process proceeds to step S290. If 10 seconds have passed in step S290, the reloading standby disk is automatically reloaded, the autoreloaded disk is stored in the original storage unit (step S294), and the blinking No. is displayed. The lamps (103a to 106a) are turned on (step S295), and the backup eject mode is terminated.
[0188]
According to the backup eject mode, even when the power is turned off, the disk in the MD device can be selected and ejected by inputting the eject key 116.
[0189]
Next, the play mode shown in step S20 will be described based on FIGS.
[0190]
First, main processing operations of the CPU 233 in the play mode will be described with reference to FIGS.
[0191]
In FIG. 23, it is determined whether or not the α flag is “1” (step S301). If the α flag is “1”, “PLAY MODE” for notifying the user that the current mode is the play mode is displayed (step S 302), and whether or not a disc is mounted on the player unit 4. Determination is made (step S303). If no disc is loaded on the player unit 4, the disc is loaded on the player unit 4 (step S304), and the process proceeds to a play process (step S400) described later. If a disc is loaded on the player unit 4 in step S303, the process proceeds to step S400.
[0192]
If the α flag is not “1” in step S301, it is determined whether there is a disk in the MD device (step S305). If there is a disc in the MD device, “PLAY MODE” for notifying the user that the current mode is the play mode is displayed (step S306), and whether there are a plurality of discs in the MD device. Is determined (step S307). If there are a plurality of discs, the No. corresponding to the disc in the MD apparatus. The lamps (103a to 106a) are blinked (step S308), and the process proceeds to P2 shown in FIG. In step S308, the No. corresponding to the disc stored in the MD device is displayed. The lamps (103a to 106a) are blinked to prompt the user to select a disk.
[0193]
If there is no disc in the MD device in step S305, “NO DISC” is displayed to notify the user that there is no disc to play (step S309), and the play mode is terminated.
[0194]
If it is determined in step S307 that there are not a plurality of disks, it is determined whether or not a disk is accommodated in the carrier 3 (step S310). If a disk is stored in the carrier 3, the process proceeds to step S303. If no disk is stored in the carrier 3, the disk is stored in the carrier 3 (step S311), and the process proceeds to step S304.
[0195]
In P2 shown in FIG. 24, it is determined whether or not the play key 108 is input (step S321). If the play key 108 has not been input, it is determined whether or not the stock key 102 has been input (step S322). If the stock key 102 has not been input, it is determined whether or not the eject key 116 has been input (step S323). If the eject key 116 is not input, the α key 107 or No. It is determined whether or not the key (103 to 106) has been input (step S324).
[0196]
α key 107 or No. If the key (103 to 106) is input, the input α key 107 or No. It is determined whether or not there is a corresponding disk corresponding to the key (103 to 106) (step S325). If there is a corresponding disk, it is determined whether or not the disk is accommodated in the carrier 3 (step S326). If no disk is stored in the carrier 3, the input No. The corresponding disk corresponding to the key (103 to 106) or the α key 107 is accommodated in the carrier 3 (step S327), the corresponding disk is mounted on the player unit 4 (step S328), and the process proceeds to P1 shown in FIG. .
[0197]
If the play key 108 is input in step S321, the currently displayed display is turned off (step S329), and the process proceeds to P3 shown in FIG. If the stock key 102 is input in step S322, the process proceeds to the stock mode in step S18 shown in FIG. If the eject key 116 is input in step S323, the process shifts to the eject mode in step S19 shown in FIG.
[0198]
In step S324, the α key 107 or No. If the key (103 to 106) has not been input, the process proceeds to step S321. If there is no corresponding disk in step S325, “NO DISC” for notifying the user that there is no such disk is displayed (step S330), and the process proceeds to step S321.
[0199]
If a disk is stored in the carrier 3 in step S326, the No. corresponding to the disk is stored. And the input No. No. of the key (103 to 106). Are the same (step S331). If they are not the same, the disk in the carrier 3 is stored in the original storage unit (step S332), and the process proceeds to step S327. If it is the same in step S331, the process proceeds to step S328.
[0200]
Next, the processing operation of the CPU 233 in the play process of step S400 will be described based on the flowchart of FIG.
[0201]
It is determined whether or not the play process shown in FIG. 25 is the all-disc random (hereinafter, simply referred to as all-disc RDM) mode (step S401). If it is the all-disc RDM mode, the process proceeds to the all-disc RDM processing described later (step S410). If it is not the all-disc RDM mode, it is determined whether or not it is the one-disc random (hereinafter, simply one-disc RDM) mode (step S402). If the 1-disk RDM mode is selected, the process proceeds to a 1-disk RDM process described later (step S420).
[0202]
If it is not the one-disk RDM mode in step S402, it is determined whether or not it is a disk repeat (hereinafter simply referred to as disk RPT) mode (step S403). If it is the disk RPT mode, the process proceeds to a disk RPT process to be described later (step S430).
[0203]
If it is determined in step S403 that the mode is not the disc RPT mode, it is determined whether or not the one-track repeat mode is set (step S404). If it is the 1-tune repeat mode, the process proceeds to a 1-tune RPT process described later (step S440).
[0204]
If it is not the single-tune RPT mode in step S404, it is determined whether or not it is a disk scan (hereinafter simply referred to as a disk SCN) mode (step S405). If it is the disk SCN mode, the process proceeds to disk SCN processing described later (step S450).
[0205]
If it is not the disc SCN mode in step S405, it is determined whether or not the mode is the all scan (hereinafter, simply referred to as all SCN) mode (step S406). If it is the all SCN mode, the process proceeds to the all SCN process described later (step S460).
[0206]
On the other hand, if it is determined in step S406 that the mode is not the all SCN mode, the process proceeds to a normal play process described later (step S470). In the play process, No. In the lamps (103a to 106a), blinking is displayed for the one corresponding to the disc being played, lighting is displayed for the one corresponding to the storage portion (50a to 50d) in which the disc is being stored, and an empty storage portion (not storing the disc) Those corresponding to 50a to 50d) are turned off.
[0207]
Next, the processing operation of the CPU 233 in the normal play process of step S470 shown in FIG. 25 will be described based on FIG.
[0208]
In FIG. 26, it is determined whether or not the normal play process is currently being performed (step S471). If the normal play process is being performed, it is determined whether or not the performance of the song on the disc being processed is completed (step S472). If the performance of the song is finished, it is determined whether or not there is a next song (step S473). If there is a next song, an address is set at the head of the song (step S474), a play operation is started (step S475), and the process proceeds to step S472.
[0209]
If the performance of the song has not ended in step S472, key input, that is, operation mode keys such as the stock key 102 and the eject key 116, and special playback keys such as the RPT key 109, the RDM key 110, and the SCN key 111 are provided. Or No. for disk selection. It is determined whether or not there is a key input such as a key (103 to 106) (step S476). If there is no key input, the process proceeds to step S472. If there is a key input, the process proceeds to a play interrupt process described later (step S500).
[0210]
If there is no song to be played next in step S473, it is determined whether there is a disc to be played next (step S477). If there is a disk to be played next, the disk on which the music performance has been completed is replaced with the next disk (step S478), and the No. corresponding to the replaced disk is changed. The lamps (103a to 106a) are displayed blinking (step S479), the address is set to the first song on the disc (step S480), and the process proceeds to step S475.
[0211]
If it is determined in step S471 that the current play process is not being performed, the process proceeds to step S479. If there is no disc to be played next in step S477, the process proceeds to step S480.
[0212]
In the normal play process, when all of the performance of the disc in the MD apparatus is completed, the performance is started again from the first song on the first disc.
[0213]
Next, the processing operation of the CPU 233 in the play interrupt processing of step S500 shown in FIG. 26 will be described with reference to FIGS.
[0214]
The play interrupt process is such that if there is a key input during a play operation, the process is shifted to the key input processing mode or the play operation is started for the key input disc. It is a thing. The key input includes an operation mode key, a special reproduction key, and a No. key, excluding function keys such as the FF key 114 and the FB key 115. This is key input for keys (103 to 106).
[0215]
In FIG. 27, it is determined whether or not the RDM key 110 has been input (step S501). If the RDM key 110 has been input, the display in the RPT mode or SCN mode described later is turned off, the RPT mode or SCN mode is released (step S502), and the process proceeds to the RDM setting process described later. (Step S540).
[0216]
If the RDM key 110 has not been input in step S501, it is determined whether or not the RPT key 109 has been input (step S503). If the RPT key 109 has been input, the display in the RDM mode or SCN mode described later is turned off, the RDM mode or SCN mode is released (step S504), and the RPT setting process described later is entered. (Step S550).
[0217]
If the RPT key 109 has not been input in step S503, it is determined whether or not the SCN key 111 has been input (step S505). If the SCN key 111 has been input, the currently displayed display relating to the RDM mode or RPT mode described later is turned off, the RDM mode or RPT mode is released (step S506), and the process proceeds to the SCN setting process described later. (Step S560).
[0218]
If the SCN key 111 has not been input in step S505, it is determined whether or not the play key 108 has been input (step S507). If the play key 108 is input, the process proceeds to P6 shown in FIG. When the play key 108 is input, the play interrupt process is terminated and the process returns to the immediately preceding process.
[0219]
If the play key 108 is not input in step S507, it is determined whether or not the eject key 116 is input (step S508). If the eject key 116 is input, the process proceeds to the eject mode in step S19 shown in FIG. If the eject key 116 has not been input, it is determined whether or not the stock key 102 has been input. If the stock key 102 has been input, the process proceeds to the stock mode in step S18 shown in FIG. If the stock key 102 has not been input, it is determined whether or not the α flag is “1” (step S510). If the α flag is “1”, the process shifts to the process mode in the play mode immediately before the shift to the play interrupt process. If the α flag is not “1”, the process proceeds to P4 shown in FIG.
[0220]
In P4 shown in FIG. 28, No. 1 corresponding to the storage section 50a of # 1. It is determined whether or not the key 103 has been input (step S521). No. If the key 103 is not input, the No. corresponding to the storage section 50b of # 2 is displayed. It is determined whether or not the key 104 has been input (step S522). No. If the key 104 has not been input, the No. corresponding to the storage section 50c of # 3. It is determined whether or not the key 105 has been input (step S523). No. If the key 105 has not been input, the No. corresponding to the storage section 50d of # 4. It is determined whether or not the key 106 has been input (step S524).
[0221]
In step S521, step S522, step S523, or step S524, No. If the key (103 to 106) is input, each input No. It is determined whether there is a corresponding disk stored in the storage unit (50a-50d) corresponding to the key (103-106) (step S525). If there is a corresponding disc, it is determined whether or not the currently playing disc is the corresponding disc (step S526). If it is not the disc, the play operation is stopped (step S527), and the stopped disc is stored in the original storage unit (step S528). The corresponding disc corresponding to the key (103 to 106) is loaded on the player unit 4 (step S529), the display during the special playback mode such as the RDM mode, the RPT mode, and the SCN mode is turned off, and the special playback mode is turned off. Is released (step S530), and the process proceeds to P5 shown in FIG. Therefore, in this case, after that, the process proceeds to the normal play process of step S470, and the normal play is performed on the selected disc.
[0222]
If there is no corresponding disk in step S525, or if the disk being played in step S526 is the corresponding disk, or in step S524, the No. corresponding to the storage section 50d of # 4. If the key 106 has not been input, the processing mode immediately before the transition to the play interrupt processing is entered.
[0223]
According to the play interrupt processing, when an operation mode key for switching operation modes such as the stock key 102 and the eject key 116 or a special reproduction key such as the RDM key 110 is input during the play operation, the input processing mode is input. No. during the play operation. When the key (103 to 106) is input, the input No. Since the play operation is started with respect to the disc corresponding to the key (103 to 106), the operability in the MD device can be remarkably improved.
[0224]
Next, the RDM setting process in step S540 shown in FIG. 27 will be described.
[0225]
In the RDM mode, all-disc RDM processing for performing random performance for all songs on all discs in the MD device, and one-disc RDM for performing random performance for all songs on one disc. In the RDM setting process, the all-disk RDM process and the one-disk RDM process are selected depending on the input time (pressing time) of the RDM key 110.
[0226]
However, according to the RDM setting process, when only one disk can be accessed, for example, when the α flag is “1” or when there is only one disk in the MD device, all When the disk RDM processing is executed, the display 117 displays “DISC RDM” for notifying the user that the current processing mode is all-disk RDM processing, and the control contents are different from the one-disk RDM processing. There may be a situation in which the user is misunderstood because there is not.
[0227]
Therefore, in order to overcome such a situation, the RDM setting process prohibits the transition to the all-disk RDM process when only one disk can be accessed, and immediately performs the one-disk RDM process. It is intended to migrate.
[0228]
FIG. 29 is a flowchart showing the processing operation of the CPU 233 in the RDM setting process.
[0229]
In the RDM setting process shown in FIG. 29, it is determined whether or not the current processing mode is the RDM mode (step S541). If it is the RDM mode, the RDM mode is canceled (step S542), the display relating to each RDM process described later is turned off (step S543), and the process proceeds to the play process (P5) in FIG. In this case, since all the special playback modes are cancelled, the process proceeds to the normal play process in step S470.
[0230]
If the current processing mode is not the RDM mode in step S541, it is determined whether or not the α flag is “1” (step S544). If the α flag is not “1”, it is determined whether or not there is only one disk in the MD device (step S545). If there is no disk, a timer is started (step S546), and it is determined whether 2 seconds have passed (step S547). If two seconds have not elapsed, it is determined whether or not the input of the RDM key 110 input in step S501 shown in FIG. 27 has been turned off (step S548). If the input of the RDM key 110 is in the OFF state, a one-disk RDM mode for executing a one-disk RDM process to be described later is set (step S601), and the process proceeds to P5 shown in FIG.
[0231]
If the α flag is “1” in step S544, or if there is one disk in the apparatus in step S545, the process proceeds to step S601.
If the input of the RDM key 110 is not in the OFF state in step S548, the process proceeds to step S547. If 2 seconds have elapsed in step S547, that is, the RDM key 110 has been pressed for 2 seconds. For example, after setting the all disk RDM mode for executing the all disk RDM processing described later (step S602), the process proceeds to P5 shown in FIG.
[0232]
According to the RDM setting process, when only one disk can be accessed, for example, when the α flag is “1” or when there is only one disk in the MD device, the all disk RDM process Since it is prohibited to shift to the one-disk RDM process unconditionally, it is possible to reliably overcome a situation in which the user misidentifies the current processing mode, and the RDM key 110 It is also possible to overcome the situation where the operation time is delayed due to the detection of the long press of.
[0233]
Next, the processing operation of the CPU 233 in the all-disc RDM processing (step S410 in FIG. 25) will be described based on the flowchart shown in FIG.
[0234]
In FIG. 30, “DISC RDM” for notifying the user that the current processing mode is all-disc RDM processing is displayed (step S411). If the current operation is executing the play operation, the play operation is stopped. (Step S412), a random number is generated to select a disk in the apparatus (Step S413), and it is determined whether or not the selected disk is the same as the disk currently mounted on the player unit 4. Determination is made (step S414).
[0235]
If the selected disc and the disc mounted on the player unit 4 are not the same, the disc mounted on the player unit 4 is exchanged with the selected disc (step S415), and the exchanged disc is performed. A random number is generated for a song corresponding to the disc to select a song (step S416), a play operation is started for the selected song (step S417), and whether or not the performance of the song is finished. Is determined (step S418). If the performance of the song has been completed, the process proceeds to step S412.
[0236]
If the same disk is found in step S414, the process proceeds to step S416. If the performance of the song is not finished in step S418, key input, that is, as described above, the operation mode key, special playback key, No. It is determined whether or not there is a key input of the keys (103 to 106) (step S419). If there is no key input, the process proceeds to step S418. If there is a key input, the process proceeds to the play interrupt process shown in FIG.
[0237]
Next, the processing operation of the CPU 233 in the one-disk RDM processing (step S420 in FIG. 25) will be described based on the flowchart shown in FIG.
[0238]
In FIG. 31, “RDM” for notifying the user that the current processing mode is 1-disc RDM processing is displayed (step S421). If the current operation is executing the play operation, the play operation is stopped ( Step S422) A random number is generated for a song corresponding to one disc to select a song (Step S423), and a play operation is started for the selected song (Step S424). It is determined whether or not the performance is finished (step S425). If the performance of the music has been completed, the process proceeds to step S422.
[0239]
If the song has not ended in step S425, the key input, that is, the operation mode key, special reproduction key, No. It is determined whether or not there is a key input of the keys (103 to 106) (step S426). If there is no key input, the process proceeds to step S425. If there is any key input in step S426, the process proceeds to the above-described play interrupt process shown in FIG. 27 in step S500.
[0240]
In the RDM mode in the above embodiment, the disk and / or music is selected based on the random number, but the disk or / and music is selected based on the code string of the linear m-sequence feedback connection method. Anyway.
[0241]
Next, the RPT setting process in step S550 shown in FIG. 27 will be described.
[0242]
In the RPT mode, one disc is selected from all the discs in the MD apparatus, and a disc RPT process for performing repeat performance on all the songs on the selected disc, There is one song RPT processing for selecting one song from the songs and performing repeat performance on the song. The RPT setting processing is performed by inputting the disc RPT processing and one song RPT processing to the RPT key 109. The selection is made according to the difference in time (pressing time).
[0243]
However, according to the RPT setting process, when only one disk can be accessed, for example, when the α flag is “1” or when there is only one disk in the MD device, the disk When the RPT process is executed, “DISC RPT” for notifying the user that the current processing mode is the disc RPT process is displayed on the display 117, and the control content is not different from the normal play process. In some cases, the user is misunderstood.
[0244]
Therefore, in order to overcome this situation, the RPT setting process prohibits the transition to the disk RPT process when only one disk can be accessed, and immediately shifts to the one-track RPT process. It is what you do.
[0245]
FIG. 32 is a flowchart showing the processing operation of the CPU 233 in the RPT setting process.
[0246]
In FIG. 32, it is determined whether or not the current processing mode is the RPT mode (step S551). If the mode is the RPT mode, the RPT mode is canceled (step S552), the currently displayed display relating to each RPT process to be described later is turned off (step S553), and the process proceeds to the play process (P5) in FIG. In this case, since all the special playback modes are cancelled, the process proceeds to the normal play process (see FIG. 26) in step S470.
[0247]
If the current processing mode is not the RPT mode, it is determined whether or not the α flag is “1” (step S554). If the α flag is not “1”, it is determined whether or not there is only one disk in the MD device (step S555). If there is no disk, a timer is started (step S556), and it is determined whether 2 seconds have passed (step S557). If two seconds have not elapsed, it is determined whether or not the input of the RPT key 109 input in step S503 shown in FIG. 27 is in an OFF state (step S558). If the input of the RPT key 109 is in the OFF state, after setting a single music RPT mode for executing the single music RPT process described later (step S603), the process proceeds to P5 shown in FIG.
[0248]
If the input of the RPT key 109 is not in the OFF state in step S558, the process proceeds to step S557. If two seconds have elapsed in step S557, a disk RPT mode for executing disk RPT processing to be described later is set (step S604), and then the process proceeds to P5 shown in FIG.
[0249]
If the α flag is “1” in step S554, or if there is one disk in the MD device in step S555, the process proceeds to step S603.
[0250]
According to the RPT setting process, when only one disk can be accessed, for example, when the α flag is “1” or when there is only one disk in the MD device, the disk RPT process is performed. Since the transition to the one-track RPT process is unconditionally prohibited, it is possible to reliably overcome a situation in which the user misidentifies the current processing mode, and the RPT key 109 It is possible to overcome the situation where the operation time is delayed due to the detection of the long press.
[0251]
Next, the processing operation of the CPU 233 in the disk RPT process (step S430 in FIG. 25) will be described based on the flowchart shown in FIG.
[0252]
In FIG. 33, “DISC RPT” for notifying the user that the current processing mode is the disc RPT processing is displayed (step S431), and if it is being played, it is determined whether or not the currently playing song has ended. (Step S432). If the currently played song has ended, it is determined whether there is a song to be played next (step S433). If there is a song to be played next, an address is set at the head of the song (step S434), a play operation is started for the song with the address set (step S435), and the process proceeds to step S432.
[0253]
If the performance of the song is not finished in step S432, the key input, the operation mode key, special reproduction key, No. It is determined whether or not there is a key input of the keys (103 to 106) (step S436). If there is no key input, the process proceeds to step S432. If there is a key input, the process proceeds to the play interrupt process shown in FIG.
[0254]
If there is no next song to be played in step S433, an address is set at the beginning of the song on the disc (step S437), and the process proceeds to step S435.
[0255]
Next, the processing operation of the CPU 233 in the one-music RPT process (step S440 in FIG. 25) will be described based on the flowchart shown in FIG.
[0256]
In FIG. 34, “RPT” is displayed to notify the user that the current processing mode is the one-music RPT process (step S441). If the music is being played, it is determined whether or not the music has been played. (Step S442). If the performance of the song has been completed, an address is set at the head position of the song (step S443), a play operation is started (step S444), and the process proceeds to step S442.
[0257]
If the performance of the song has not ended in step S442, the key input, the operation mode key, the special reproduction key, and the No. It is determined whether or not there is a key input of the keys (103 to 106) (step S445). If there is no key input, the process proceeds to step S442. If there is a key input, the process proceeds to the play interrupt process shown in FIG.
[0258]
Next, the SCN setting process in step S560 shown in FIG. 27 will be described.
[0259]
In the SCN mode, a disc SCN process in which only the beginning of the first song of all discs in the MD device is scanned for a predetermined time, for example, 10 seconds, and all songs on all discs in the MD device are performed. All SCN processing for scanning the beginning of a song for only 10 seconds, and this SCN setting processing is different from disc SCN processing and all SCN processing due to the difference in input time (pressing time) of the SCN key 111. To choose.
[0260]
However, according to the SCN setting process, when only one disk can be accessed, for example, when the α flag is “1” or when there is only one disk in the MD device, the disk When the SCN process is executed, the control content is merely useful for continuously scanning only the beginning of the first song on the single disc, and there is no utility value. In addition, the display 117 has the current processing mode. If “DISC SCN” for notifying the user that the disk SCN process is being displayed is displayed, the user may be misidentified.
[0261]
Therefore, in order to overcome such a situation, the SCN setting process prohibits the shift to the disk SCN process when only one disk can be accessed, and immediately shifts to the all SCN process. It is what I did.
[0262]
FIG. 35 is a flowchart showing the processing operation of the CPU 233 in the SCN setting process.
[0263]
In the SCN setting process shown in FIG. 35, it is determined whether or not the current processing mode is the SCN mode (step S561). If the current processing mode is the SCN mode, the SCN mode is canceled (step S562), the display during display related to each SCN processing described later is turned off (step S563), and the play processing (P5) in FIG. Transition. In this case, since all the special playback modes are cancelled, the process proceeds to the normal play process (see FIG. 26) in step S470.
[0264]
If it is not the SCN mode in step S561, it is determined whether or not the α flag is “1” (step S564). If the α flag is not “1”, it is determined whether or not there is one disk in the MD device (step S565). If there is not one disk in the MD device, a timer is started (step S566), and it is determined whether two seconds have passed (step S567). If two seconds have not elapsed, it is determined whether or not the input of the SCN key 111 input in step S505 shown in FIG. 27 is in an OFF state (step S568). If the input of the input SCN key 111 is in an OFF state, an all SCN mode for executing an all SCN process to be described later is set (step S605), and the process proceeds to P5 shown in FIG.
[0265]
If the input of the SCN key 111 is not OFF in step S568, the process proceeds to step S567. If two seconds have elapsed in step S567, a disk SCN mode for executing disk SCN processing described later is set (step S606), and then the process proceeds to P5 shown in FIG.
[0266]
If the α flag is “1” in step S564, or if there is one disk in the MD device in step S565, the process proceeds to step S605.
[0267]
According to the SCN setting process, when only one disk can be accessed, for example, when the α flag is “1” or when there is only one disk in the MD device, the disk SCN process is performed. Since the transition to the SCN processing is prohibited unconditionally, it is possible to reliably overcome a situation in which the user is misidentified in the current processing mode and the length of the SCN key 111. It is possible to overcome the situation where the operation time is delayed due to the detection of the push.
[0268]
Next, the processing operation of the CPU 233 in the disk SCN processing (step S450 in FIG. 25) will be described based on the flowchart shown in FIG.
[0269]
In FIG. 36, “DISC SCN” for notifying the user that the current processing mode is disk SCN processing is displayed (step S451). If the current performance is being performed, the play operation is stopped (step S452). The disc whose play operation has been stopped is replaced with the next disc (step S453), and is set at the start address of the first song of the exchanged disc (step S454), and the play operation is performed on the set song. It is started (step S455) and it is determined whether 10 seconds have passed (step S456). If 10 seconds have elapsed, the process proceeds to step S452.
[0270]
If 10 seconds has not elapsed in step S456, key input, as described above, the operation mode key, special reproduction key, No. It is determined whether or not there is a key input of the keys (103 to 106) (step S457). If there is no key input, the process proceeds to step S456. If there is such a key input, the process proceeds to the play interrupt process shown in FIG.
[0271]
Next, the processing operation of the CPU 233 in the all SCN process (step S460 in FIG. 25) will be described based on the flowchart shown in FIG.
[0272]
In FIG. 37, “SCN” is displayed to notify the user that the current processing mode is all SCN processing (step S461), and if the current performance is being performed, the play operation is stopped (step S462), and the next song It is determined whether or not there is (step S463). If there is a next song, an address is set at the head of the next song to be played (step S464), a play operation for the song is started (step S465), and it is determined whether 10 seconds have elapsed (step S465). Step S466). If 10 seconds has elapsed, the process proceeds to step S462.
[0273]
If there is no next song in step S463, the disc on which the song has been played is exchanged for the next disc (step S467), and set to the first address of the first song for the exchanged disc (step S468). The process proceeds to step S465.
[0274]
If 10 seconds has not elapsed in step S466, key input, as described above, the operation mode key, special reproduction key, No. It is determined whether or not there is a key input of the keys (103 to 106) (step S469). If there is no key input, the process proceeds to step S466. If there is a key input, the process proceeds to the play interrupt process shown in FIG.
[0275]
Now, according to the MD apparatus to which the medium recording / reproducing apparatus of the present invention configured as described above is applied, when the eject key 116 is input during the disk reload standby, the reload is performed without shifting to the stock mode. If the waiting disk is not an α disk, the reloading waiting disk is stored in the original storage unit in which the disk is stored, and if the reloading waiting disk is an α disk, Since the disc is mounted on the player unit 4, it is possible to greatly reduce the operation time required for the user's input operation.
[0276]
In the above embodiment, the carrier 3 and the player unit 4 are configured to be independent. However, as another embodiment, the player unit 4 may be incorporated in the carrier 3 to have an integrated structure. According to such a configuration, the player unit 4 is displaced in the Y1 and Y2 directions of FIG. 1, so that the disc mounted on the carrier 3 can be rapidly driven to rotate.
[0277]
In the above embodiment, the α flag is set to “1” in response to the input of the α key 107, but the stocker 5 cannot be stored, for example, all the storage units (50a to 50d) are full. In this case, the CPU 233 may detect the case where the stocker 5 fails for some reason, and the α flag may be set to “1”. In particular, when detecting that the stocker 5 has failed. Alternatively, failure detection means for detecting the failure state of the stocker 5 may be provided in the MD device, and the α flag may be set to “1” in accordance with a detection signal from the failure detection means.
[0278]
In the above embodiment, the standby position of the carrier 3 is the position facing the opening of the storage section 50b. However, the position is not limited to the position facing the storage section 50b. Any position may be used as long as the disk insertion port 212 is not opened. For example, when the standby position is a position facing the storage unit 50c, the storage order is changed from the storage unit 50c to the storage unit 50d, the storage unit 50a, and the storage unit 50b, or from the storage unit 50c to the storage unit 50d. The storage unit 50b, the storage unit 50a, and the like may be used. Further, the standby position is not only the position where each storage unit (50a to 50d) faces, but the intermediate position between the storage unit 50a and the storage unit 50b, the intermediate position between the storage unit 50b and the storage unit 50c, the storage unit 50c, An intermediate position between the storage unit 50d and an intermediate position between the storage unit 50d and the player unit 4 may be used.
[0279]
Further, in the above embodiment, the identification number is a predetermined order regarding access to each storage unit and the disk stored in the storage unit, such as the storage order in the stock mode, the ejection order in the eject mode, and the performance order in the play mode. Although # 1 is the storage unit 50a, # 2 is the storage unit 50b, # 3 is the storage unit 50c, and # 4 is the storage unit 50d, # 1 is the storage unit 50b, # 2 is the storage unit 50c, and # 3. Needless to say, the storage unit 50d and # 4 may be the storage unit 50a, and various predetermined orders can be changed.
[0280]
In the above-described embodiment, the opening / closing operation of the insertion prevention shutter 217 with respect to the disk insertion port 212 is performed in conjunction with the lifting / lowering operation of the carrier 3. For example, the insertion prevention shutter 217 may be opened and closed in response to an electrical command.
[0281]
In the above embodiment, the reproduction-only MD device has been described. However, the same effect can be obtained by adopting the same configuration for the MD device capable of recording. Further, the play / pause key 108 may be a play / stop key, and a stop key or a pause key may be provided separately from the play key.
[0282]
In the above embodiment, a maximum of five disks can be stored. Needless to say, a larger number of disks can be stored by increasing the number of storage units of the stocker 5.
[0283]
In the above embodiment, since the recording medium is MD, it is applied to an MD apparatus. However, the recording medium is an optical recording medium such as a CD or a video disk, or a magnetic recording medium such as a floppy disk. Needless to say, the present invention can also be applied to apparatuses that handle these recording media.
[0284]
When the determination at step S23 in FIG. 7 is negative, the process proceeds to step S33 in FIG. 8. However, for example, after the process proceeds to step S60 in FIG. 9 and the disc is inserted, the process proceeds to step S81 in FIG. After the processing, No. input in step S17 in step S85. You may make it accommodate a disk in the empty storage part corresponding to a key (103-106).
[0285]
Further, as described above and with respect to steps S16, 17, 21-23 in FIG. When the keys (103 to 106) are input, if there is no corresponding disk corresponding to these key inputs, and if the α key 107 is input, the subsequently inserted disk is mounted on the player unit 4. Or No. If the key (103 to 106) is input, the inserted disc is stored in the empty storage portion. However, the operation mode is not specified. For example, during the ejection operation or play Even during operation, the α key 107 or No. When the keys (103 to 106) are input, if there is no corresponding disk corresponding to these key inputs, and if the α key 107 is input, the subsequently inserted disk is mounted on the player unit 4. Or No. If the key (103 to 106) is input, the disk inserted thereafter may be stored in the empty storage unit. After that, you can enter stock mode.
[0286]
It should be noted that the α key 107 or the No. 10 key is used while waiting for a disk reload during the ejection operation (for example, waiting for 10 seconds in step S151). When the key (103 to 106) is input, if the corresponding disk does not exist, the reloading standby disk is returned to the original storage unit, and if the α key 107 is input, the player unit 4 is After that, insert the inserted disc or no. If the key (103 to 106) is input, the disk inserted thereafter may be stored in the empty storage unit.
[0287]
【The invention's effect】
According to the medium recording / reproducing apparatus of the present invention configured as described above, when the recording medium is discharged to a predetermined position and the discharge command is input before the predetermined time elapses, the storage mode is entered. Since the recording medium discharged to the predetermined position is stored in the original storage area in which the recording medium was stored, it is possible to greatly reduce the labor required for the user's input operation. .
[Brief description of the drawings]
FIG. 1 is a cross-sectional view schematically showing an internal structure of a vehicle-mounted MD autochanger device according to an embodiment of the present invention.
FIG. 2 is a plan view showing a configuration of a general MD.
FIG. 3 is a plan view showing a front panel.
FIG. 4 is a block diagram showing a configuration of the in-vehicle MD autochanger device.
FIG. 5 is a block diagram showing a schematic circuit of the in-vehicle MD autochanger device of the deck type in the present embodiment.
FIG. 6 is a block diagram showing a schematic circuit when the in-vehicle MD autochanger device is applied to a black box type as another embodiment.
FIG. 7 is a flowchart showing a main routine of a CPU in the in-vehicle MD autochanger device.
FIG. 8 is a flowchart showing a processing operation of a CPU in a stock mode.
FIG. 9 is a flowchart showing a processing operation of a CPU in a stock mode.
FIG. 10 is a flowchart showing processing operations of a CPU in a stock mode.
FIG. 11 is a flowchart showing processing operations of a CPU in a stock mode.
FIG. 12 is a flowchart showing processing operations of the CPU in the eject mode.
FIG. 13 is a flowchart showing the processing operation of the CPU in auto-eject processing in the eject mode.
FIG. 14 is a flowchart showing the processing operation of the CPU in auto-eject processing in the eject mode.
FIG. 15 is a flowchart showing a processing operation of a CPU in a manual eject process in the eject mode.
FIG. 16 is a flowchart showing a processing operation of a CPU in a manual eject process in the eject mode.
FIG. 17 is a flowchart showing the processing operation of the CPU in the position designation reload process of the first embodiment.
FIG. 18 is a flowchart showing the processing operation of the CPU in the position designation reload process of the first embodiment.
FIG. 19 is a flowchart illustrating a processing operation of a CPU in a position designation reload process according to the second embodiment.
FIG. 20 is a flowchart illustrating a processing operation of a CPU in a position designation reload process according to the second embodiment.
FIG. 21 is a flowchart showing a processing operation of a CPU in a backup eject mode.
FIG. 22 is a flowchart showing a processing operation of a CPU in a backup eject mode.
FIG. 23 is a flowchart showing processing operations of the CPU in the play mode.
FIG. 24 is a flowchart showing processing operations of the CPU in the play mode.
FIG. 25 is a flowchart showing processing operations of a CPU in play processing in play mode.
FIG. 26 is a flowchart showing processing operations of the CPU in normal play processing in the play mode.
FIG. 27 is a flowchart illustrating processing operations of a CPU in play interrupt processing in a play mode.
FIG. 28 is a flowchart showing processing operations of a CPU in play interrupt processing in play mode.
FIG. 29 is a flowchart illustrating processing operations of a CPU in RDM setting processing in a play mode.
FIG. 30 is a flowchart showing processing operations of a CPU in all-disk RDM processing.
FIG. 31 is a flowchart showing a processing operation of a CPU in a one-disk RDM process.
FIG. 32 is a flowchart showing processing operations of the CPU in the RPT setting process in the play mode.
FIG. 33 is a flowchart showing processing operations of a CPU in disk RPT processing.
FIG. 34 is a flowchart showing the processing operation of the CPU in the one-music RPT process.
FIG. 35 is a flowchart showing processing operations of the CPU in play mode SCN setting processing;
FIG. 36 is a flowchart showing processing operations of a CPU in disk SCN processing.
FIG. 37 is a flowchart showing processing operations of a CPU in all-SCN processing.
[Explanation of symbols]
3 Carrier (conveying means)
5 Stocker (medium storage means)
50a-50d storage part (storage area)
103-106 No. Key (specify storage medium)
116 Eject key (discharge command)
216d Disc extraction sensor (medium extraction detection means)
233 CPU (control means)

Claims (4)

Medium storage means for storing a plurality of recording media in a plurality of storage areas respectively;
Medium discharge means for discharging a predetermined recording medium from the insertion port to a predetermined position;
Medium extraction detecting means for detecting that the recording medium discharged to the predetermined position has been extracted;
An operation means for inputting a discharge command for setting a discharge mode for discharging the selected predetermined recording medium from the insertion port by the medium discharge means when a predetermined recording medium is selected;
Storage area specifying means for specifying a storage area for storing the recording medium;
If the removal of the recording medium is not detected by the medium removal detection means after the recording medium is discharged by the medium discharge means in the discharge mode, the recording medium discharged to the predetermined position is removed. When the ejection command is input before the predetermined time elapses, the recording medium starts to be stored, and the recording medium discharged to the predetermined position is stored in the recording medium. A medium recording / reproducing apparatus comprising control means for storing in an original storage area.   2. The medium recording / reproducing apparatus according to claim 1, wherein the control means stores the discharged recording medium in the original storage area based on the storage data and then shifts to the discharge mode again.   3. The medium recording / reproducing apparatus according to claim 1, wherein the operation unit includes a spare medium designation for designating a spare recording medium not stored in the storage area.   The apparatus further includes a medium driving unit that mounts the recording medium, reproduces information recorded on the mounted recording medium, or records new information on the recording medium, and the control unit is discharged to the predetermined position. When the recording medium is a spare recording medium, when the ejection command is input before a predetermined time elapses, the spare recording medium ejected to the predetermined position is mounted on the medium driving means. The medium recording / reproducing apparatus according to claim 3.

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