WO2014091569A1 - Optical information recording and reproducing system and pickup state management method - Google Patents

Abstract

An optical information recording and reproducing system and a pickup state management method are provided for a system in which a control device instructs recording and reproducing using an optical information recording and reproducing device which requires time until the optical beam irradiated from a light source is in a state optimal for recording and reproducing. This optical information recording and reproducing system is provided with an optical information recording and reproducing device which performs data recording and reproducing in an optical information recording medium, and a control device of the optical information recording and reproducing device. The control device is provided with a pickup state instruction unit which instructs the optical information recording and reproducing device to perform state transitions of a pickup equipped in the optical information recording and reproducing device, and the optical information recording and reproducing device is provided with a controller unit which controls state transitions of the pickup in accordance with instructions of the control device.

Description

Optical information recording / reproducing system and pickup state management method

The present invention relates to an optical information recording / reproducing system for recording information using holography and a pickup state management method.

While research on next-generation storage technology is underway, hologram recording technology that records digital information using holography is drawing attention.

The hologram recording technique is a method in which a signal light having page data information two-dimensionally modulated by a spatial light modulator and a reference light are superimposed inside the recording medium, and an interference fringe pattern generated at that time causes the inside of the recording medium. This is a technique for recording information by causing refractive index modulation in the optical disk. In reproducing information, if the recording medium is irradiated with the reference light used for recording in the same arrangement, the hologram recorded in the recording medium acts like a diffraction grating to generate diffracted light. This diffracted light is reproduced as the same light including the recorded signal light and phase information.

Regenerated signal light is detected two-dimensionally at high speed using a photodetector such as a CMOS or CCD. Thus, in hologram recording, two-dimensional information can be simultaneously recorded / reproduced by one hologram, and a plurality of page data can be overwritten at the same location, so that large-capacity and high-speed information can be recorded / reproduced. It is valid.

In addition, a recording / reproducing method using interference fringes such as holographic recording is easily affected by a change in wavelength. Therefore, a gas laser that can easily maintain wavelength stability and coherency is used as a recording / reproducing laser. Although solid-state lasers are used as light sources, these light sources have a problem that the apparatus is large and the manufacturing cost is high, and therefore, a semiconductor laser may be used as a light source. However, when a semiconductor laser is used as a light source, there is a problem that wavelength stability and coherency are inferior, and it takes time until the light beam emitted from the laser reaches an optimum wavelength after the start of the reproducing apparatus. Has been pointed out (for example, JP-A-2005-116063 (Patent Document 1)).

As a technique for solving this problem, Patent Document 1 discloses that “the wavelength information of the laser beam at the time of recording is recorded as a wavelength address hologram, and based on this recording, the temperature of the semiconductor laser is controlled at the time of information reproduction. It is described that a laser beam for reproduction with any wavelength can be used.

Japanese Patent Laid-Open No. 2005-116063

Patent Document 1 describes a technique for quickly starting a reproduction operation and using a reproduction laser beam having an optimum wavelength corresponding to each recording medium. Since time is required, no technology for solving the problem that the optical information recording / reproducing apparatus cannot perform recording / reproducing at the timing when the control apparatus instructs recording / reproducing is not described.

Accordingly, an object of the present invention is to solve the above problem in a system in which a control device instructs recording / reproduction using an optical information recording / reproducing device that requires time until the light beam emitted from the light source is in an optimum state for recording / reproduction. An optical information recording / reproducing system and a pickup state management method are provided.

In order to solve the above problem, it can be solved by using a controller that controls the state of the pickup as an example.

According to the present invention, in the optical information recording / reproducing apparatus using the optical information recording / reproducing apparatus that requires time until the light beam emitted from the light source is in an optimum state for recording / reproducing and the control apparatus, the control apparatus Recording / reproduction can be performed by the optical information recording / reproducing apparatus at the timing when recording / reproduction is instructed.

Issues, configurations, and effects other than those described above will be clarified by the following description of the embodiments.

The block diagram which shows the structure of the optical information recording / reproducing apparatus of an Example Schematic diagram showing an embodiment of an optical information recording / reproducing apparatus Schematic showing an embodiment of a pickup in an optical information recording / reproducing apparatus Schematic showing an embodiment of a pickup in an optical information recording / reproducing apparatus State transition diagram showing pickup state Block diagram showing the configuration of the data library system Example of recording sequence flow Example of timing for instructing transition from SLEEP state to READY state Example of timing for instructing transition from SLEEP state to READY state Example of timing for instructing transition from SLEEP state to READY state Example of timing for instructing transition from SLEEP state to READY state Example of timing for instructing transition from SLEEP state to READY state Explanatory diagram of how to determine state transition after recording Explanatory drawing of the state transition instruction method when focusing on the exchange operation State determination method and light source control flow using states State determination method and light source control flow using states

Hereinafter, examples will be described with reference to the drawings.

Embodiments of the invention will be described with reference to the accompanying drawings. FIG. 2 is a block diagram showing a recording / reproducing apparatus of an optical information recording medium for recording and / or reproducing digital information using holography.

The optical information recording / reproducing device 10 is connected to a control device 91 via an input / output control unit 90. In the case of recording, the optical information recording / reproducing apparatus 10 receives the information signal to be recorded from the control device 91 by the input / output control unit 90. In the case of reproduction, the optical information recording / reproducing apparatus 10 transmits the reproduced information signal to the control apparatus 91 by the input / output control unit 90.

The control device 91 may be a device that is directly connected to the optical information recording / reproducing device 10, or may be a device that is indirectly connected via another device on the higher level side. .

The optical information recording / reproducing apparatus 10 includes a pickup 11, a reproduction reference light optical system 12, a cure optical system 13, a disk rotation angle detection optical system 14, and a rotation motor 50. The optical information recording medium 1 is a rotation motor. 50 can be rotated.

The pickup 11 includes a light source, and plays a role of irradiating the optical information recording medium 1 with reference light and signal light to record digital information on the recording medium using holography. At this time, the information signal to be recorded is sent by the controller 89 to the spatial light modulator in the pickup 11 via the signal generator 86, and the signal light is modulated by the spatial light modulator.

When reproducing the information recorded on the optical information recording medium 1, the reproduction reference light optical system 12 generates a light wave that causes the reference light emitted from the pickup 11 to enter the optical information recording medium in a direction opposite to that during recording. Generate. The reproduction light reproduced by the reproduction reference light is detected by a photodetector (to be described later) in the pickup 11, and the signal is reproduced by the signal processing unit 85.

The irradiation time of the reference light and the signal light applied to the optical information recording medium 1 can be adjusted by controlling the opening / closing time of the shutter in the pickup 11 via the shutter control unit 87 by the controller 89.

The cure optical system 13 plays a role of generating a light beam used for pre-cure and post-cure of the optical information recording medium 1. Precure is a pre-process for irradiating a predetermined light beam in advance before irradiating the desired position with reference light and signal light when recording information at a desired position in the optical information recording medium 1. Post-cure is a post-process for irradiating a predetermined light beam after recording information at a desired position in the optical information recording medium 1 so that additional recording cannot be performed at the desired position.

The disk rotation angle detection optical system 14 is used to detect the rotation angle of the optical information recording medium 1. When the optical information recording medium 1 is adjusted to a predetermined rotation angle, a signal corresponding to the rotation angle is detected by the disk rotation angle detection optical system 14, and a disk rotation motor control unit is detected by the controller 89 using the detected signal. The rotation angle of the optical information recording medium 1 can be controlled via 88.

A predetermined light source supply current is supplied from the light source driving unit 82 to the light sources in the pickup 11, the cure optical system 13, and the disk rotation angle detection optical system 14, and each light source emits a light beam with a predetermined amount of light. Can do.

Further, the pickup 11 and the disc cure optical system 13 are provided with a mechanism capable of sliding the position in the radial direction of the optical information recording medium 1, and position control is performed via the access control unit 81.

By the way, the recording technology using the principle of angle multiplexing of holography tends to have a very small tolerance for the deviation of the reference beam angle.

Accordingly, a mechanism for detecting the deviation amount of the reference beam angle is provided in the pickup 11, a servo control signal is generated by the servo signal generation unit 83, and the deviation amount is corrected via the servo control unit 84. It is necessary to provide a servo mechanism for this purpose in the optical information recording / reproducing apparatus 10.

Further, the pickup 11, the cure optical system 13, and the disk rotation angle detection optical system 14 may be simplified by combining several optical system configurations or all optical system configurations into one.

FIG. 3 shows a recording principle in an example of a basic optical system configuration of the pickup 11 in the optical information recording / reproducing apparatus 10. The light beam emitted from the light source 301 passes through the collimator lens 302 and enters the shutter 303. When the shutter 303 is open, after the light beam passes through the shutter 303, the optical ratio of the p-polarized light and the s-polarized light becomes a desired ratio by the optical element 304 composed of, for example, a half-wave plate. After the polarization direction is controlled, the light is incident on a PBS (Polarization Beam Splitter) prism 305.

The light beam that has passed through the PBS prism 305 functions as signal light 306, and after the light beam diameter is expanded by the beam expander 308, the light beam passes through the phase mask 309, the relay lens 310, and the PBS prism 311 and passes through the spatial light modulator 312. Is incident on.

The signal light to which information is added by the spatial light modulator 312 reflects the PBS prism 311 and propagates through the relay lens 313 and the spatial filter 314. Thereafter, the signal light is condensed on the optical information recording medium 1 by the objective lens 315.

On the other hand, the light beam reflected from the PBS prism 305 functions as reference light 307 and is set to a predetermined polarization direction according to recording or reproduction by the polarization direction conversion element 316 and then galvano- lated via the mirror 317 and the mirror 318. Incident on the mirror 319. Since the angle of the galvanometer mirror 319 can be adjusted by the actuator 320, the incident angle of the reference light incident on the optical information recording medium 1 after passing through the lens 321 and the lens 322 can be set to a desired angle. In order to set the incident angle of the reference light, an element that converts the wavefront of the reference light may be used instead of the galvanometer mirror.

In this way, the signal light and the reference light are incident on the optical information recording medium 1 so as to overlap each other, whereby an interference fringe pattern is formed in the recording medium, and information is recorded by writing this pattern on the recording medium. To do. In addition, since the incident angle of the reference light incident on the optical information recording medium 1 can be changed by the galvanometer mirror 319, recording by angle multiplexing is possible.

Hereinafter, in the holograms recorded in the same region with the reference light angle changed, the holograms corresponding to the respective reference light angles will be called pages.

FIG. 4 shows a reproduction principle in an example of a basic optical system configuration of the pickup 11 in the optical information recording / reproducing apparatus 10. When reproducing the recorded information, the reference light is incident on the optical information recording medium 1 as described above, and the light beam transmitted through the optical information recording medium 1 is reflected by the galvanometer mirror 324 whose angle can be adjusted by the actuator 323. By doing so, the reproduction reference light is generated.

The reproduction light reproduced by the reproduction reference light propagates through the objective lens 315, the relay lens 313, and the spatial filter 314. Thereafter, the reproduction light passes through the PBS prism 311 and enters the photodetector 325, and the recorded signal can be reproduced. As the photodetector 325, for example, an image sensor such as a CMOS image sensor or a CCD image sensor can be used. However, any element may be used as long as page data can be reproduced.

Here, the embodiment will be described in detail with reference to FIGS.

Fig. 1 shows the blocks necessary for the explanation from Figs. 2 and 3 and the blocks necessary for solving the problem. Those already described in FIGS. 2 and 3 are omitted, and the newly added block will be described in FIG. Reference numeral 101 denotes a light source state determination unit that determines whether or not the light beam 301 necessary for the light source 301 provided in the pickup 11 to stably perform recording and reproduction is possible. An example of one condition for performing stable recording and reproduction is whether a light beam can be irradiated with a stable wavelength. For example, in a recording / reproducing method using holography, the higher the coherency (coherence) in the light source 301 is, the more stable recording and reproduction is possible. There is a method of measuring a contrast ratio using a prism. Dividing into a component that travels straight through the light beam and a component that is slightly shifted through the wedge prism, interference fringes are created to create interference fringes, and a line sensor is placed where interference fringes can occur. The contrast ratio is calculated by calculating the degree of modulation. It shows that coherency is so high that the numerical value of this modulation degree is high. Note that the method for determining whether or not the light beam can be irradiated with a stable wavelength is not limited to this method as long as it can be determined that the light source is in a laser state in which recording and reproduction can be performed. In addition, the condition for determining whether or not the light beam irradiation necessary for performing recording and reproduction stably is not limited to wavelength stability, and may be determined based on other conditions.

102 denotes a pickup state determination unit that determines a corresponding state in a state machine related to the light source of the controller 89 based on information from the light source driving unit 82, the shutter control unit 87, and the light source state determination unit 101. The three information sources for determining the state are “the amount of current that the light source driving unit 82 supplies to the light source”, “the open / closed state of the shutter 303 controlled by the shutter control unit 87”, and “the light source state determination unit 101 “The stability of the light source determined”. Next, the relationship between these three information sources and the states in the state transition diagram shown in FIG. 5 will be described.

FIG. 5 is a state transition diagram showing states that the controller 89 can control or the pickup state determination unit 102 can determine. A solid line arrow 507 indicates a transition by command control, a dotted line arrow 508 indicates a state transition by opening / closing the shutter, and a dotted line arrow 509 indicates a stay and transition by turning on / off the power supply to the recording / reproducing apparatus. ing.

501 is an OFF state, which is a state in which no power is supplied to the recording / reproducing apparatus. Therefore, unless power is supplied to the apparatus, a transition to another state cannot be made.

Reference numeral 502 denotes a SLEEP state that can be shifted by supplying power from the OFF state 501, in which only power is supplied to the apparatus and no current is supplied to the light source. Since no current is supplied, light beam irradiation is not performed, and the shutter may be opened or closed, but is normally closed. For the same reason, there is no need to worry about the stability of the light source. If there is no plan to perform recording or playback for a while, it is advantageous in terms of power consumption because the current is not supplied to the light source by shifting to the SLEEP state. Various states are assumed in the SLEEP state. For example, the SLEEP state immediately after the transition from the READY state and the SLEEP state immediately after the transition from the OFF state are the same in that no current is supplied to the light source. When the temperature of the light source is related, the temperature is different between the former and the latter, so that the time until the transition to the READY state where the wavelength of the light source is stable is surely faster in the former. Therefore, when shifting from the SLEEP state to the READY state via the WAIT state, the time required for WAIT is not constant. The same can be said for the transition from the STANBY state to the READY state described later.

503 is a WAIT state in a transient state that is always passed when shifting to the READY state of 504. In the WAIT state, the amount of current supplied to the light source is the same as in the READY state, but the light source may not be stable due to the surrounding environment such as temperature, and is not suitable for recording or playback. It is shown that. When it is determined that the light source is in a stable recording and reproducing state, the state shifts to a READY state 504. Since the WAIT state is a transitional state (light source stabilization wait state), it is not possible to instruct the WAIT state transition from the control device. Also, the condition for shifting from the WAIT state to the READY state may differ between recording and reproduction. For example, when the condition required for the stability of the light source is lower in the reproduction than in the recording, there is a possibility that the state can be shifted to the READY state at an earlier time than in the recording.

The READY state 504 is a state in which recording and reproduction can be performed at any time, but since the shutter is closed, the optical information recording medium 1 is not irradiated with a light beam. Since it is possible to enter the RUN state immediately by opening and closing the shutter, recording and playback can be performed immediately when waiting in the READY state, but current is always supplied to the light source. It is not preferable to stay in this state from the viewpoint of laser life and power consumption. By minimizing the waiting time in this state, the laser life can be extended and the power consumption can be reduced.

The RUN state 505 is a state where the optical information recording medium 1 is irradiated with a light beam, that is, a state where recording or reproduction is performed, with the shutter open. When the recording / reproduction is finished, the optical information recording medium is no longer irradiated with the light beam if the shutter is closed (504, READY state). The reason why the irradiation to the optical information recording medium is turned on / off by opening / closing the shutter, rather than turning on / off the current supplied to the light source, is the presence of the WAIT state of the light source. For example, if you want to shift to the SLEEP state after setting the current supplied to the light source to zero and then move to the RUN state again, you must always go through the WAIT state, and the waiting time in the WAIT state is wasted in time . Therefore, in order for the control device to perform recording and reproduction without waiting time, it is necessary to make the time in the WAIT state as long as possible or to wait in the READY state that can immediately shift to the RUN state. In addition,
A STANBY state 506 is a state that can be shifted from the RUN state, the READY state, the WAIT state, and the SLEEP state. The shutter is closed and a current is supplied to the light source. The difference from the READY state is the amount of current to the light source. The supply current amount is in a range that is less than the current amount in the READY state and greater than the SLEEP state. By reducing the amount of current, the power consumed by the light source can be saved. There are several possible supply current settings. For example, recording or playback may not be possible, but the current may be set to a temperature that can maintain a stable wavelength, or low power consumption may be achieved. The amount of current may be reduced, or the amount of current may be increased with emphasis on the transition time to READY. Thus, a plurality of current amounts to be supplied in the STANBY state may be selectable.

Note that the WAIT state always goes through when shifting from the STANBY state to the READY state. The STANBY state is set only when the amount of current supplied to the light source can be set with a desired set value, and is not necessarily settable.

The transition from READY state to STANBY state and SLEEP state can be performed by a command issued from the connected control device. Transition from the WAIT state to the SLEEP state or the STANBY state is also possible by a command command from the control device. That is, there are three states that can be instructed by a command from the control device: SLEEP state, READY state, and STANBY state. There are two ways to shift to the OFF state: a transition without going through the SLEEP state, and a transition through the SLEEP. A table 510 summarizes the above description.

In this way, in a system where recording and playback cannot be performed unless the state of the light source is stable, the amount of current supplied to the light source can always be recorded and played back in order to perform recording and playback at the timing when the control device instructs recording and playback. Since it is necessary to maintain the recording / reproduction level, it is conceivable to stop recording / reproduction by controlling the recording / reproduction on the optical information recording medium by opening / closing the shutter. The problems when controlling using the shutter are that the current that can be recorded and reproduced is always supplied to the light source, which increases the power consumption of the recording / reproducing apparatus and the life of the light source. One point is that it gets premature. On the other hand, if power consumption and life are regarded as important and the current supplied to the light source is stopped, there arises a time problem that it takes time until the state of the light source is stabilized. In order to solve these conflicting problems, control is performed using the state of the state transition diagram as shown in FIG. By doing so, it is possible to control the supply current to the light source with a balance between power consumption and time.

The control device 91 instructs this state. Hereinafter, an example of a method for controlling the pickup state of the external control device 91 will be described.

6 constitutes a data library system using a plurality of the optical information recording / reproducing apparatuses of FIG. 1, and a higher-level device connected to the optical information recording / reproducing apparatus performs recording / reproducing control of a plurality of optical information recording media. System. In FIG. 6, locations corresponding to the control device 91 are a server 602 and a library device control circuit 605. 1 may be included in either the server 602 or the library apparatus control circuit.

The data library system 601 records data stored in the data storage device 604 from the network 603 via the server 602 on the optical information recording medium. Alternatively, data is reproduced from the optical information recording medium and sent to the network 603 via the server 602. The data library system 601 includes a plurality of optical information recording / reproducing devices, and a plurality of optical information recording media are stored in the data library system 601. The library apparatus control circuit 605 can control the optical information recording medium exchanging apparatus 606 and the optical information recording / reproducing apparatuses 10, 10a, 10b, and 10c, instruct to record / reproduce data of the optical information recording medium, and load the optical information recording medium. Instructs to exchange such as eject. The server 602 controls the data storage device 604 and the data library system 601 and manages data sent from the network 603. The data storage device 604 is controlled by the server 602 to record / reproduce data sent from the network 603. The library device control circuit 605 may be controlled not only by a request from the server 602 but also by a request via the network 603.

As an example of an assumed system, a system is assumed in which a data storage device accumulates data for recording and records data on an optical information recording / reproducing medium when a certain amount is reached. Next, referring to FIG. 7, an example of a sequence showing an example of a recording operation on an optical information recording medium on the premise of creating a schedule will be described. First, the flow of all the steps will be described, and portions that require detailed description will be individually described later.
In step 701, the schedule creation unit 103 of the control device in FIG. 1 creates a recording schedule. A schedule is a plan in which the control device performs operations such as data recording, reproduction, loading, and ejection on an optical information recording medium mounted on the optical information recording / reproducing device in what order and at what timing. . A specific example of scheduling will be described later with reference to FIGS.

In step 702, the light source state to be transferred is determined by the pickup state determination unit 104 of the control device according to the created recording schedule, and is transmitted to the operation instruction unit 105. Here, the optical information recording / reproducing apparatus is instructed to shift from the SLEEP state to the READY state in the state transition diagram of FIG. An example of instruction timing will be described later with reference to FIG.

In step 703, when the optical information recording / reproducing apparatus receives the READY state transition instruction, the optical information recording / reproducing apparatus enters the WAIT state and waits for the light source to be in a recordable state.

In step 704, the operation instruction unit 105 of the control device monitors the pickup state of the optical information recording / reproducing device by polling or the like, and waits for the transition to the READY state. The input / output control unit 90 of the optical information recording / reproducing apparatus can return the current light source state to the operation instruction unit 105 of the control apparatus. When the control device can confirm the transition to the READY state, it issues a recording command to the optical information recording / reproducing device via the operation instruction unit 105 and issues a recording instruction.

In step 705, the optical information recording / reproducing apparatus receives a recording command, and when the data to be recorded on the optical information recording medium is ready, opens the shutter and starts the recording operation by irradiating the optical information recording medium with a light beam, Transition to RUN state.

In step 706, after the recording is completed, the shutter is closed to end the recording operation and shift to the READY state.

In step 707, the pickup state determination unit 104 performs state selection according to the next schedule created by the schedule creation unit 103. The schedule creation example in step 707 will be described later with reference to FIGS. The above is the description of the flow of all the steps, and the parts that need to be explained will be explained individually.

First, a specific example of scheduling in step 701 will be described with reference to FIGS. As an example of an assumed system, a system is assumed in which data is recorded on an optical information recording / reproducing medium when the amount of data recorded in the data storage device 604 reaches a certain amount (X bytes). There are several examples of creating a recording schedule for such a system. For example, the amount of data stored in the data storage device 604, the scheduled recording amount of data to be recorded that is managed by the server, and queued The amount of data stored in the data storage device can be predicted to some extent from the recording schedule. The reproduction schedule can be predicted based on the same concept. There are two devices that can create a recording schedule: a server 602 (plan 1) and a library device control circuit (plan 2). Add explanation from Plan 1. In the plan 1, when the server 602 records data to the data storage device 604, “whether X byte is likely to be reached in this recording” or “X byte is reached from the scheduled recording data amount and the actual recording speed. Sometime ”can be predicted to some extent by the server 602.
This will be described with reference to FIG. When the accumulated data amount is plotted on the vertical axis and the time is plotted on the horizontal axis, a line in which the accumulated data amount is plotted for each time is a solid line portion 801a. Whether a certain amount (X bytes) is reached from the scheduled recording data amount can be predicted by simple addition, and the estimated arrival time when the recording speed is constant is also a linear interpolation of 801a. It can be predicted from the dotted line portion. Further, as shown in FIG. 8B, a method of detecting a change in the amount of accumulated data in real time and updating the X byte estimated arrival time is also conceivable. Before the change is 801a and after the change is 801b. Of course, prediction may be performed by a prediction method other than linear interpolation. For example, interpolation may be performed so as to average the slope of each data increase amount instead of linear interpolation as shown in FIG.

Next, I will explain about plan 2. In the plan 2, the library device control circuit 605 needs to monitor the amount of data stored in the data storage device 604, but the server 602 supplies the data necessary for the prediction, or the data storage device By monitoring the increase speed of the data 604, the same prediction as in the plan 1 can be performed.

Next, the instruction timing in step 702 will be described with reference to FIG.
FIG. 8 shows an example of timing for instructing the transition from the SLEEP state to the READY state in 702 of FIG. Since a part of FIG. 8a has been described above, it is omitted, and only a part not described will be described. The constant amount of accumulated data Y bytes is the amount of accumulated data that will reach the time T1 before the X bytes in the prediction with a linearly interpolated line. The time T1 is the time from the SLEEP state to the final READY state via the WAIT state. That is, it is a waiting time until recording / reproduction becomes possible when the optical information recording / reproducing apparatus is viewed from the use side. Further explanation will be given with reference to FIG. In step 801d, the capacity (Y bytes) before the time T1 is estimated from the estimated arrival time of X bytes. The expected arrival time is X byte arrival expected time -T1. In step 802d, it is determined whether or not the amount of accumulated data has reached the predicted Y bytes (802a). When the Y byte is reached, a transition from the SLEEP state or the STANBY state to the READY state is instructed (step 803d).
If the Y byte has not been reached at the scheduled time, it is determined whether or not recording is stopped (= when there is no increase in accumulated data) (step 807d). If recording is stopped, transition to the SLEEP or STANBY state is made. A command is issued (step 811d), and the process ends. If it is not in the recording stop state, the predicted arrival time is corrected by recalculating the estimated arrival time of Y bytes based on the current transfer speed, the scheduled recording data amount, and the like (step 809d). After instructing the transition to the READY state in step 803d, it is determined whether or not the X byte has been reached in step 804d. If the X byte has been reached, it is determined in step 805d whether or not it is in the READY state. If the optical information recording / reproducing apparatus is not yet in the READY state, it waits until it enters the READY state. If it is in the READY state, the control device issues a recording command to the optical information recording / reproducing device (step 806d), and the processing ends. If the X byte has not been reached at the scheduled time (803a), it is determined whether recording is in a stopped state (= no increase in accumulated data) (step 808d). If in the recording stopped state, the SLEEP state or STANBY A state transition command is issued (step 811d), and the process ends. If it is not in the recording stop state, the predicted arrival time is predicted by recalculating the estimated arrival time of X bytes based on the current transfer speed and the scheduled recording data amount (step 810d). In this way, by issuing a READY transition instruction in step 803d at a time earlier by the time T1 than the estimated X-byte arrival time, the control device issues a recording command at the timing at which recording is desired without being aware of the time required for the WAIT state. It can be issued (step 806d). Further, as shown in FIG. 8e, an instruction to shift to the READY state may be issued when the X byte is reached (804a) without using the prediction. FIG. 8e is the same operation as the YES path of step 804d in FIG. 8d, but when data is recorded from the data storage device to the optical information recording medium, data encryption, parity addition, and other necessary processing are performed. If processing of data to be performed takes time, it is effective because processing can be executed in parallel with the time required for the WAIT state.

Next, the instruction timing in step 707 will be described with reference to FIGS. FIG. 9 is a diagram for explaining how to determine the next transition state when recording is completed. While the recording 901 is being executed, the state is the RUN state (902), and the state is shifted from the RUN state to the READY state by closing the shutter. After that, an example of controlling the state according to the scheduled recording schedule will be described. First, the time periods T1 to T3 from 903 to 905 are defined. Reference numeral 903 denotes a time from the SLEEP state to the READY state through the WAIT state in the state transition diagram of FIG. Reference numeral 904 denotes the time required to complete the transition from the STANBY state to the READY state via the WAIT state in the state transition diagram of FIG. As described with reference to FIG. 5, T1 and T2 are variable depending on the state of the light source, but here, a maximum time is assumed. Reference numeral 905 denotes a waiting time from the end of the recording 901 to the start of the next recording. The time width of the READY state that shifts from the RUN state 902 when the shutter is closed differs depending on the timing of the next state transition instruction. First, an explanation will be given from the case of transition to the SLEEP state of 906 and 907.
The case of 906 is when the time of T3 is longer than T1. In this case, the time until the next recording has room, so if the transition to the READY state is instructed before the start of recording T1, the READY state is reached by the next recording start timing even if the WAIT state is passed again. The control device can start recording without waiting time. Moreover, the optical information recording / reproducing apparatus side cuts off the supply current to the light source, thereby contributing to the extension of the life of the light source and the reduction of power consumption.
In the case of 907, after the transition to the SLEEP state, there is no plan for the next recording, so the state is in the SLEEP state until the next schedule is determined by the recording start prediction described with reference to FIG. In some cases, it may be possible to turn off the power of the apparatus and shift to the OFF state. However, from the viewpoint of the light source, both supply currents are zero, so there is no difference.
A case 908 is a case where the time of T3 is shorter than T1 and longer than T2. In this case, when the transition to the SLEEP state is made, the preparation for recording of the light source is not in time until the start of the next recording. Even through the WAIT state, it is possible to return to the READY state by the next recording start timing, and the control device can start recording without waiting time. Further, the optical information recording / reproducing apparatus side realizes a long life of the light source and a reduction in power consumption by suppressing the supply current to the light source.
The case of 909 is a case where the time of T3 is shorter than T1 than T2. In this case, when the transition to the SLEEP state or STANBY state is made, the preparation for recording of the light source is not in time until the start of the next recording, so the controller can start recording without waiting time by instructing to maintain the READY state. It becomes.

As described above, in consideration of the time until the next recording start and the time required to move to the READY state, it is possible to start recording without waiting time from the control device side by instructing the state to be shifted at the end of recording. From the viewpoint of the optical information recording / reproducing apparatus, there is an advantage that the life of the light source can be extended and the power consumption can be reduced by cutting off the supply current to the light source. The description has been given by taking the case of recording as an example, but it can be considered in the same way whether the case is a reproduction case or a case where recording and reproduction are mixed, and the same effect can be obtained.

FIG. 10 shows a state transition instruction method when paying attention to the replacement operation of the optical information recording medium such as loading and ejecting of the optical information recording medium. First, 1004 and 1005 will be described. Reference numeral 1004 denotes a definition of a START STOP UNIT command (Operation Code (1Bh)) of an existing ATAPI (AT Attachment Packet Interface) packet command, and an ATAPI compatible device loads and ejects using this command. A black frame indicated by Rsv is an undefined area at present, and there are cases where there are undefined bits in the definition of an existing command. Consider using this undefined to instruct state transition. Using 2 bits in the area indicated by Rsv, for example, 1005 is defined using 2 bits of bits 3 and 4 of Byte5. 00 indicates that the current state is maintained, 01 indicates the transition to the SLEEP state, 10 indicates the transition to the STANBY state, and 11 indicates the transition to the READY state. Note that this definition may be anywhere as long as it is an undefined place. In this case, since the shutter control is not performed by the control device but by the optical information recording / reproducing device, the instruction to enter the RUN state is not included, but the shutter control is considered by the control device. May use 3 bits to add a definition to transition to the RUN state.
A case 1001 is a case where the library apparatus control circuit 605 newly loads the optical information recording medium 1 to the optical information recording medium exchanging apparatus 606 and the optical information recording / reproducing apparatus 10. When the library apparatus control circuit 605 loads the optical information recording medium 1, if the commands defined in 1004 and 1005 are used, the optical information recording medium exchange apparatus 606 is instructed to load with a single command instruction. In addition, the optical information recording / reproducing apparatus 10 can be instructed to shift to the READY state. Examples 1002 and 1003 are cases where the optical information recording medium 1 loaded in the optical information recording / reproducing apparatus 10 is ejected. Although both are the same in that they are ejected, the contents specified in 1005 differ depending on whether or not a new optical information recording medium is loaded after ejection. In the case of 1002, since a new optical information recording medium is loaded and scheduled to be recorded after ejection, the READY state is instructed. In the case of 1003, no new optical information recording medium is scheduled to be loaded after ejection. Instruct the SLEEP state. Efficient recording / reproduction control as viewed from the library device control circuit, power saving and longer life of the optical information recording / reproducing device by instructing the pickup state at the same time as ejecting the currently installed optical information recording medium Can be quickly instructed.

It should be noted that the method for indicating the state to be shifted to after the completion of recording 901 in FIG. 9 can also be performed using the empty bits of the recording command as in the cases 1004 and 1005 in FIG. Usually, a recording command is often issued multiple times in succession, and the command is queued, and there is a time difference between the recording command issuance timing and the end of data recording on the actual optical information recording medium corresponding to the recording command. is there. Therefore, the transition to the state specified by the empty bit is not at the time of command reception, but after data recording on the optical information recording medium for the recording command is completed.

As described above, when the control apparatus performs recording / reproduction using an optical information recording / reproducing apparatus that takes time until the light source is actually in an optimum state, the control apparatus side that manages the recording / reproduction schedule performs the optical information. By performing state control of the pickup of the recording / reproducing apparatus, it is possible to perform recording / reproducing as viewed from the control apparatus side with good timing, further reducing power consumption of the optical information recording / reproducing apparatus viewed from the optical information recording / reproducing apparatus side, Long life can be realized.

Finally, the processing flow for determining the pickup state is summarized in FIG. 11a. Step 1101a for determining “the amount of current that the light source driving unit 82 supplies to the light source”, step 1102a for determining “opening / closing state of the shutter 303 controlled by the shutter control unit 87”, and “light source state determining unit 101 The pickup state can be determined by executing the steps 1103a for determining the “stability of the determined light source” and the steps 1104a for determining the “state of the pickup 11” based on these pieces of information. FIG. 11b is a flow until the current to the light source is supplied in accordance with an instruction from the control device. A recording / playback schedule is created (step 1101b), the transition state of the pickup state according to the schedule is instructed (step 1102b), and current is supplied to the light source according to the transition state (step 1103b).

In addition, this invention is not limited to the above-mentioned Example, Various modifications are included. For example, the above-described embodiments have been described in detail for easy understanding of the present invention, and are not necessarily limited to those having all the configurations described. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. Further, it is possible to add, delete, and replace other configurations for a part of the configuration of each embodiment.

In addition, each of the above-described configurations, functions, processing units, processing means, and the like may be realized by hardware by designing a part or all of them, for example, by an integration unit. Each of the above-described configurations, functions, and the like may be realized by software by interpreting and executing a program that realizes each function by the processor. Information such as programs, tables, and files for realizing each function can be stored in a memory, a hard disk, a recording device such as an SSD (Solid State Drive), or a recording medium such as an IC card or an SD card.

Also, the control lines and information lines indicate what is considered necessary for the explanation, and not all the control lines and information lines on the product are necessarily shown. Actually, it may be considered that almost all the components are connected to each other.

DESCRIPTION OF SYMBOLS 1 ... Optical information recording medium, 10 ... Optical information recording / reproducing apparatus, 11 ... Pickup,
12 ... Reference light optical system for reproduction, 13 ... Disc Cure optical system,
14 ... Optical system for detecting disk rotation angle, 81 ... Access control unit,
82... Light source drive unit, 83... Servo signal generation unit,
84: Servo control unit, 85: Signal processing unit, 86: Signal generation unit,
87... Shutter control unit, 88... Disk rotation motor control unit,
89 ... Controller, 90 ... Input / output control unit, 91 ... Control device,
301 ... light source, 303 ... shutter, 306 ... signal light, 307 ... reference light,
308 ... Beam expander, 309 ... Phase mask
310 ... relay lens, 311 ... PBS prism,
312 ... Spatial light modulator, 313 ... Relay lens, 314 ... Spatial filter,
315 ... objective lens, 316 ... polarization direction conversion element, 320 ... actuator,
321 ... lens, 322 ... lens, 323 ... actuator,
324 ... Mirror, 325 ... Photodetector, 406 ... Diffracted signal light

Claims (18)

1. An optical information recording / reproducing system for recording information using holography,
   An optical information recording / reproducing apparatus for recording / reproducing data on an optical information recording medium;
   A control device for controlling the optical information recording / reproducing device,
   The optical information recording / reproducing apparatus includes a pickup having a laser light source, and a controller for controlling the pickup,
   The optical information recording / reproducing system, wherein the control device includes a pickup state instruction unit that instructs the controller to change the state of the pickup.
2. The optical information recording / reproducing system according to claim 1,
   The controller is
   The emission stability of the laser light source provided in the pickup,
   A current supply state to the laser light source;
   And an optical information recording / reproducing system that controls the state transition of the pickup based on an open / close state of a shutter that is provided in the pickup and serves to block a light beam emitted from the laser light source.
3. The optical information recording / reproducing system according to claim 2,
   The controller is
   An optical information recording / reproducing system, wherein an amount of current corresponding to a pickup state instructed by a pickup state instructing unit of the control device is supplied to the laser light source.
4. The optical information recording / reproducing system according to claim 3,
   The controller is
   SLEEP state in which supply of current to the laser light source is stopped and the shutter is closed,
   A current necessary for recording or reproduction is supplied to the laser light source, the laser light source state satisfies a condition for performing stable recording or reproduction, and the shutter is closed READY state,
   A current necessary for recording or reproduction is supplied to the laser light source, the laser light source state does not satisfy the conditions for recording or reproduction, and the shutter is closed. WAIT state,
   And a current necessary for recording or reproduction is supplied to the laser light source, the laser light source state satisfies a condition for performing stable recording or reproduction, and the shutter is opened. RUN state in
   An optical information recording / reproducing system, which is included in a state for managing state transition of the pickup.
5. The optical information recording / reproducing system according to claim 4,
   The controller is
   The STANBY state in which a current that is not sufficient to perform recording or reproduction is supplied to the laser light source and the shutter is closed is included in the state for managing the state transition of the pickup. Optical information recording / playback system.
6. The optical information recording / reproducing system according to claim 5,
   The controller is
   An optical information recording / reproducing system characterized in that a plurality of supply current amounts to the laser light source in the STANBY state can be set.
7. The optical information recording / reproducing system according to claim 6,
   A command 1 for instructing recording issued from the control device to the optical information recording / reproducing device;
   Command 2 for instructing playback,
   Command 3 for instructing loading of the optical information recording medium;
   Command 4 for instructing ejection of the optical information recording medium;
   Command 5, which has an operation code dedicated to state transition instructions
   One or all of the commands
   An optical information recording / reproducing system characterized in that pickup state instruction information is included.
8. The optical information recording / reproducing system according to claim 7,
   Timing when the controller controls the state of the pickup,
   For commands 1 and 2, after the recording / reproduction for the data length instructed to the optical information recording medium is completed,
   An optical information recording / reproducing system characterized in that the commands 3, 4, and 5 are simultaneously issued when the commands are issued.
9. The optical information recording / reproducing system according to claim 1,
   The optical information recording / reproducing apparatus includes a pickup state determination unit that determines the state of the pickup,
   The pickup state determination unit
   The emission stability of the laser light source provided in the pickup,
   A current supply state to the laser light source;
   And an optical information recording / reproducing system that determines a state transition of the pickup based on an open / closed state of the shutter.
10. In a pickup state management method in an optical information recording / reproducing system having an optical information recording / reproducing apparatus for performing data recording / reproducing of an optical information recording medium using a pickup, and a controller for the optical information recording / reproducing apparatus,
    A pickup state management method, wherein the control device instructs the optical information recording / reproducing device to perform a pickup state transition, and the optical information recording / reproducing device controls the pickup state transition in accordance with the instruction.
11. The pickup state management method according to claim 10,
    When the pickup performs data recording and reproduction using a light source for irradiating a light beam and a shutter that serves to block the light beam,
    A pickup state management method comprising: controlling state transition of the pickup based on light emission stability of a light source, a current supply state to the light source, and an open / close state of a shutter.
12. The pickup state management method according to claim 11,
    A pickup state management method, characterized in that control is performed so that a current amount corresponding to a pickup state instructed by the control device is supplied to a light source.
13. The pickup state management method according to claim 12,
    The state for managing the state transition of the pickup is:
    SLEEP state in which supply of current to the light source is stopped and the shutter is closed,
    A current necessary for recording or reproduction is supplied to the light source, the light source state satisfies a condition for performing stable recording or reproduction, and the shutter is closed. READY state,
    A WAIT state in which a current required for recording or reproduction is supplied to the light source, the light source state does not satisfy a condition for performing recording or reproduction, and the shutter is closed ,
    And a current required for recording or reproduction is supplied to the light source, the light source state satisfies a condition for performing stable recording or reproduction, and the shutter is opened. RUN state,
    A pickup state management method comprising:
14. The pickup state management method according to claim 13,
    The state for managing the state transition of the pickup is:
    A pickup state management method comprising a STANBY state in which a current that is not sufficient to perform recording or reproduction with respect to the light source is supplied and the shutter is closed.
15. The pickup state management method according to claim 14,
    A pickup state management method, wherein a plurality of supply current amounts to the light source in the STANBY state can be set.
16. The pickup state management method according to claim 15,
    A command 1 for instructing recording issued from the control device to the optical information recording / reproducing device;
    Command 2 for instructing playback,
    Command 3 for instructing loading of the optical information recording medium;
    Command 4 for instructing ejection of the optical information recording medium;
    Command 5, which has an operation code dedicated to state transition instructions
    One or all of the commands
    A pickup state management method comprising pickup state instruction information.
17. The pick-up state management method according to claim 16,
    The timing for controlling the state of the pickup is
    For commands 1 and 2, after the recording / reproduction for the data length instructed to the optical information recording medium is completed,
    A pickup state management method characterized in that the commands 3, 4, and 5 are simultaneously issued when the commands are issued.
18. The pickup state management method according to claim 10,
    When the pickup performs data recording and reproduction using a light source for irradiating a light beam and a shutter that serves to block the light beam,
    A pickup state management method, comprising: determining a state of the pickup based on a light emission stability of a light source, a current supply state to the light source, and an open / close state of a shutter.

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