JPH08329480A - Seeking speed controller for optical head - Google Patents

Abstract

PURPOSE: To exactly perform coarse seeking at high speed regardless of the number of working tracks by providing plural numbers of targets speed profiles from which one is selected corresponding to the number of working tracks. CONSTITUTION: This device is composed of an optical signal detecting means 11, a cross-track signal generating means 12, a counting means 13, a speed measuring means 15, a differential amplifier 16 and a control part 14 including a storage device of a target speed profile. Two kinds of target speed profiles (Fig.1 (a), (b)) are stored in the storage device for controlling the coarse seeking of an optical head. When the number of moving tracks of the optical head is large at the time of accessing, a first target speed profile of a constant speed 'A' and a constant deceleration speed 'B' of the Fig.1 (a) is selected. When the number of moving tracks of the optical head is small, a second target speed profile of a kick pulse 'C' in the Fig.1 (b) is outputted, when the head starts to move, a constant acceleration speed D is adopted and, thereafter, deceleration speed control 'E' is performed so as to enable tracking control when the head reaches the target track.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seek speed control device for an optical head, and more particularly to an optical head used in an optical disc device for recording and / or reproducing information on an optical disc such as a compact disc or a magneto-optical disc. The present invention relates to a seek speed control device.

[0002]

2. Description of the Related Art In an optical head used in an optical disk device, generally, the head position is controlled at a high speed and roughly by a linear motor or a feed screw mechanism for driving the optical head in the radial direction of the optical disk. After performing (coarse seek), the track jump by the actuator of the objective lens mounted on the optical head enables precise positioning of the information reading beam spot (dense seek).
It is done by doing. Here, it is preferable that the arrival track at the rough seek time point in the initial stage of the seek operation is closer to the target track for which the access is instructed, because the time required for the fine seek can be shortened. Further, it is preferable that the time of the rough seek itself is shorter, and generally, in order to increase the access speed, it is important to control the movement of the optical head at high speed and accurately in the rough seek.

When a disc information access instruction is issued from a host device such as a computer, the optical disc device calculates a relation between a logical number of information and a physical position on the disc to obtain a target track, and obtains a current track position. The number of tracks to be moved is calculated from the relationship with. Where, for example,
Taking a CD-ROM that uses CLV recording as an example,
Assuming that the track number is N, the recording start diameter is r ₁ , the track pitch is p, the information recording linear velocity is w _v , and the logical information number (total number of frames) is t, N = {− πr ₁ + √ ((πr ₁ ) ² + πpw _v t)} / πp ... (1). The information recording linear velocity w _v is, for example, 1.2 to 1.4 m / s in the compact disc (CD) standard.
Stipulated in the range of.

In order to perform a rough seek at high speed and accurately,
Direct recording using the number of tracks calculated by the above formula
There is a track count (DTC) method. In the DTC method, the number of cross-track signals generated each time a track is crossed is counted, the number of remaining tracks up to the target track is calculated, the target speed is calculated each time according to the number of remaining tracks, and the target speed and the actual speed are calculated. The difference between and is fed back to control the speed. When the target track is reached, the rough seek is completed and the fine seek control section (tracking control section) is turned on.

FIG. 4 (a) shows a conventional trapezoidal target velocity profile generally obtained by rough seek control. In this target velocity profile, at the beginning of the head movement, a constant acceleration is generated to gradually accelerate the head from the stopped state, and when the head reaches a predetermined speed, the head moves to constant velocity movement, and at the latter stage of the movement, it becomes constant. Decelerate with the deceleration of and stop. Such control is adopted in order to prevent the cross-track signal from being deteriorated and the accurate counting operation being impossible when the maximum speed of the head becomes excessively high.
If there is no risk of counting mistakes, for example,
A triangular profile is used, and after acceleration by maximum acceleration, deceleration by maximum deceleration is performed at an intermediate point.

FIG. 4B shows another example of a conventional target velocity profile. In this example, constant acceleration control is not performed, but a kick operation at the start of rough seek (driving the maximum output of the driver) The speed is immediately controlled to a predetermined maximum speed, and in the latter half of the movement, speed control is performed to decelerate at a predetermined deceleration.

[0007]

By the way, since the transfer mechanism for transferring the optical head in the radial direction includes a linear motor, a gear feed mechanism and the like, there are effects such as static friction and backlash of the gear. Therefore, there is a time lag from the start of driving the motor for moving the head to the actual movement of the optical head, and accurate control of the head speed is difficult immediately after the start of driving. Here, when the moving distance of the optical head is long, the control time also becomes long, so the head speed converges to the target speed during the rough seek, but when the moving distance of the head is short, it follows the target speed. There is no good control.

If the optical head cannot converge to the target speed by the time it reaches the target track, the optical head may pass the target track, resulting in a significant delay in access time, or in the worst case, the head. There is also the danger of falling into a runaway state. As a countermeasure, it is possible to select parts such as reducing frictional elements of the head transfer mechanism, but in this case, the cost increases due to the use of special parts, and the manufacturing cost of the optical head transfer mechanism increases. To do.

In view of the above, according to the present invention, the access speed of information is high because the moving speed of the optical head can be favorably controlled during the rough seek regardless of the moving distance of the optical head.
Another object of the present invention is to provide a low-cost seek speed control device for an optical head.

[0010]

In order to achieve the above object, the seek speed control device for an optical head according to the present invention is arranged between a current track where the optical head is located before seek and a target track to which the optical head should seek. In a seek speed control device for an optical head, which calculates a target moving speed of an optical head according to the number of moving tracks of the optical head and controls the moving speed of the optical head so as to follow the target moving speed, a memory for storing a plurality of target speed profiles. Means, selection means for selecting one of the target speed profiles corresponding to the number of moving tracks, and speed control means for giving a control output to the optical head according to the selected target speed profile.

The seek speed control device for an optical head according to the present invention is a compact disc (CD), a CD-ROM,
It can be applied to an optical head of an optical disk device for any type of optical disk such as a magneto-optical disk.

In the seek speed control device for an optical head according to the present invention, preferably, the speed control means is based on one target speed profile selected when the number of moving tracks is less than a predetermined number of tracks. A predetermined large kick output is given in the initial stage of head movement, and after the optical head reaches a predetermined moving speed, the optical head is accelerated at a constant acceleration.

Further, in the above-mentioned case, when the moving amount of the optical head reaches 1/2 of the number of moving tracks, the optical head is decelerated at a constant deceleration instead of being accelerated by the constant acceleration. Controlling the head is also a preferred embodiment. Alternatively, instead of this, a predetermined deceleration for controlling the optical head is stored, and when the speed control means decelerates the optical head on the basis of the predetermined deceleration, the optical head aims at the target. It is also possible to calculate a deceleration start time point at which the optical head can be provided with a moving speed equal to or lower than a predetermined speed when reaching a track, and at that time point, the acceleration by the predetermined acceleration can be switched to the deceleration by the predetermined deceleration. I can.

The predetermined number of tracks is determined depending on the magnitude of inertia of the optical head and the driving performance of the driving device, and a value of 4000 or less is adopted, for example.

In a seek speed control device for an optical head, generally, a control unit (for example, a microcomputer built in the optical disc device) records on each track of the optical disc when controlling a transfer means for moving the optical head in the radial direction. A cross track signal is extracted from the optical signal thus obtained, and the cross track signal is counted by the counting means to obtain the number of passing tracks. Also, with the specified target track,
The target speed profile is selected according to the number of moving tracks with the current track where the head is located before seek,
Based on this, the control unit outputs the target optical head moving speed, and the speed control means is controlled so as to follow the speed to control the moving speed of the optical head.

The target speed program of the seek speed control apparatus for an optical head according to the preferred embodiment of the present invention is such that the speed of the optical head when the target track is reached becomes equal to or lower than the speed at which tracking pull-in is possible. It includes a plurality of target velocity profiles created corresponding to the magnitude. Here, the control unit selects one target speed profile suitable for the number of moving tracks calculated as described above.

In particular, when the number of moving tracks is smaller than the predetermined number of tracks, the control unit firstly determines, based on one target speed profile selected corresponding thereto,
Immediately after the start of seek, a pulse with a peak value corresponding to the maximum target speed is output. After the speed of the optical head reaches a predetermined speed from the stopped state, the optical head is accelerated at a predetermined acceleration to follow the target speed profile. Here, for example, the moving amount of the optical head is 1 / the number of moving tracks.
When it reaches 2, it immediately shifts from deceleration to deceleration and decelerates at a predetermined deceleration to follow the selected target velocity profile.

Alternatively, instead of the above, the target velocity profile corresponding to a small number of moving tracks is composed of a kick pulse application portion, an acceleration velocity profile portion, and a deceleration velocity profile portion. Here, in the first half after the head is driven, the acceleration speed control of the optical head is performed by following the acceleration speed profile portion. The actual moving speed of the optical head at a certain time is such that the speed of the optical head becomes a tracking retractable speed at the time when the target track is reached when deceleration by a predetermined deceleration is continued. When the speed defined by the standard speed profile at the time of deceleration is exceeded, switching is made so as to follow the deceleration speed profile portion instead of following the acceleration speed profile portion.

[0019]

In the seek speed control device for the optical head according to the present invention,
Since a plurality of target speed profiles are stored, and one target speed profile is selected according to the number of moving tracks of the head, when the number of moving tracks is large, a target speed profile suitable for this is selected, and the moving tracks are also selected. If the number is small, a target speed profile that allows easy speed control even with this small number of moving tracks can be selected, so that good seek speed control can be performed regardless of the number of moving tracks.

[0020]

EXAMPLES The present invention will be described in more detail based on the examples of the present invention.

Generally, when accessing information on an optical disk, first, a focusing servo is applied to the optical disk, the head is moved to an appropriate position in the radial direction of the disk, and then a tracking servo is applied to the optical disk. Tracking is performed by reading the position information stored in. Note that, for example, in a music CD, time information is discretely recorded in the main information as subcodes instead of position information. In this case, the formula (1) described in the related art is used. Use to convert time information to track numbers.

In the optical disc device, when an access instruction is issued from a host device such as a personal computer, a control unit (eg, control microcomputer) in the optical disc device first reads the optical information recorded on the disc. By reading, the current position of the optical head is determined. Subsequently, the target track instructed by the higher-level device, in which the information to be accessed is stored, is obtained according to the equation (1) or the like. As a result, the relative position of the target track from the current track can be calculated, and the direction in which the optical head should be moved and the number of moving tracks are determined.

The control unit loads the number of moving tracks obtained above into the counter and controls the optical head moving means to drive in the direction to be moved. While counting the cross track signal by the counter, the optical head is moved until the number of remaining tracks becomes zero, and the target track is reached. For the speed control of the optical head at this time, for example, by using the DTC method as described in the related art, accurate and high-speed head movement becomes possible.

FIGS. 1A and 1B are examples of target velocity profiles adopted in the seek velocity control device for an optical head according to an embodiment of the present invention. In the figure, the horizontal axis represents time and the vertical axis represents speed, and when the slope during acceleration / deceleration is a straight line, it indicates that the vehicle is decelerated at a constant acceleration or a constant deceleration. When the number of moving tracks T is larger than the predetermined number of tracks Tx, the target speed profile shown in FIG. 7A is used, and the constant speed ("a") is used in the initial stage of the movement, but the constant deceleration ("a") is used in the latter stage of the movement. "B") is adopted. When the number of moving tracks T is smaller than the predetermined number of tracks Tx, the target speed profile shown in FIG. These target speed profiles are stored in advance in the storage device in the control device.

The number of moving tracks T is a predetermined number of tracks Tx
If it is larger, the coarse seek time is long, so that the moving speed of the optical head can be easily converged to the target speed profile shown in FIG. in this case,
The initial acceleration specified by the target velocity profile is theoretically infinite, and in practice, acceleration is performed by making maximum use of the performance of the feed mechanism. The deceleration start is determined according to the number of remaining tracks obtained from the counting means. By following this target velocity profile, extremely fast rough seek is possible.

On the other hand, when the number T of moving tracks is smaller than the predetermined number Tx of tracks, first, at the beginning of the movement, as shown in FIG.
The kick pulse "C" as shown in (b) is output. The kick pulse is a drive output corresponding to the target speed that is the highest in the performance of the control device. By applying the kick pulse “C”, the static friction is overcome and the optical head is activated. After the optical head is activated, that is, after the optical head starts to move beyond the predetermined speed Vx, the acceleration control is switched to the constant acceleration ("d"). Generally, when the number of moving tracks T is small and the rough seek time is short, the longer the control time is, the smaller the deviation between the target speed and the actual speed is. Therefore, instead of the kick pulse, the constant acceleration control is performed. "D" is adopted. "H" is constant deceleration control,
For example, when the number of moving tracks reaches 1/2, the acceleration control "d" is switched to the deceleration control "e".

FIG. 2 is a block diagram showing the arrangement of a seek speed control device for an optical head according to an embodiment of the present invention. The control device according to the present embodiment includes an optical signal detection unit 11, a cross track signal generation unit 12, a counting unit 13, a speed measurement unit 15, a differential amplifier 16, and a control unit 14.

The optical signal detecting means 11 detects an optical signal included in the reflected light from the recording surface including the groove of the optical disk, converts it into a corresponding servo electric signal 21 and gives it to the cross track signal generating means 12. . The cross-track signal generation means 12 generates a cross-track signal 22 which gives one pulse when the optical head crosses one groove from the servo electric signal 21. Counting means 23
Counts the cross track signal 22, and the count value 23 is given to the control unit 14 in order to obtain the current position of the optical head and the number of remaining tracks to be moved. The control unit 14 calculates the number of moving tracks from the current track number and the target track number of the optical head, selects the target speed profile (a) or (b) based on this, and sets the selected target speed profile to the selected target speed profile. The corresponding target speed 24 is output to the differential amplifier 16 each time.

The speed measuring means 15 calculates the head speed 25 of the optical head at the present time by, for example, D / A converting the number of the cross track signals 12 counted within a fixed time, and differentially calculating this. Output to the amplifier 16. The differential amplifier 16 calculates the difference between the target speed and the head speed as the drive signal 26.
And is fed to a drive unit of a head transfer means (not shown) for feedback control.

FIG. 3 shows a target speed output routine which is a part of a control flowchart in the seek speed control device for an optical head of the above embodiment. When an access command is issued from the host device and this is accepted, control according to this target speed output routine starts. First, the current address is calculated (step S1), and the current track number is obtained from this (step S2). The moving direction is determined from the target head number included in the access information and the current track number (step S3). Subsequently, the number T of moving tracks, which is the difference between the current track number and the target track number, is obtained (step S4). After the initial setting for seek (step S5), it is determined whether the number of moving tracks T is larger than a predetermined number of tracks Tx (step S6), and if T> Tx, the first target speed profile is selected. Then, a normal seek process is performed (step S7).

If T <Tx in step S6, the second target velocity profile is selected, and the process according to this is performed as follows. First, a kick pulse is output (step S8). When the optical head starts moving from the stopped state and it is detected that the speed V becomes higher than the predetermined speed Vx (step S9), the acceleration speed control is continuously performed and a constant acceleration is given (step S9).
10). When it is determined that the optical head has reached the area to be decelerated based on the predetermined deceleration program data (step S11), the deceleration speed control is performed (step S1).
2). When the optical head reaches the target head, the rough seek ends, and at that time, the moving speed of the optical head has already reached a speed at which tracking control can be performed, so that it is possible to immediately shift to the dense seek. This enables high speed access of the optical head.

Although the present invention has been described based on the embodiments thereof, the seek speed control device for an optical head of the present invention is not limited to the configuration of the above-mentioned embodiments, and the configuration of the above-mentioned embodiments is not limited thereto. The seek control device of the optical head with various modifications and changes is also included in the scope of the present invention. For example, in the above-described embodiment, an example has been described in which the acceleration and deceleration of the optical head are constant, but the acceleration and the deceleration do not necessarily have to be constant.

[0033]

As described above, the seek speed control device for an optical head according to the present invention has a plurality of target speed profiles, one of which is selected in accordance with the number of moving tracks, so that the number of moving tracks can be controlled. The present invention has a remarkable effect of increasing the access speed of information in the optical disk device because it enables high-speed and accurate rough seek regardless of size.

[Brief description of drawings]

FIG. 1 is an example of a target velocity profile adopted in a seek velocity device for an optical head according to an embodiment of the present invention, and (a) and (b) respectively correspond to a large and small number of moving tracks. Graph.

FIG. 2 is a block diagram showing a configuration of a seek speed control device of the above embodiment.

FIG. 3 is a flowchart showing processing in the seek speed control device of the above embodiment.

4A and 4B are target speed profiles of speed control performed by a conventional optical head, respectively.

[Explanation of symbols]

 11 Optical Signal Detecting Means 12 Cross Track Signal Detecting Means 13 Counting Means 14 Control Section 15 Speed Measuring Means 16 Differential Amplifier 21 Optical Signals 22 Cross Track Signals 23 Count Values 24 Target Speed 25 Head Speed 26 Drive Signals

Claims (5)

[Claims] 1. A target moving speed of an optical head is calculated according to the number of moving tracks between a current track where the optical head is located before seek and a target track to be sought by the optical head, and the target moving speed is tracked. In a seek speed control device for an optical head for controlling the moving speed of an optical head, a storage means for storing a plurality of target speed profiles, and a selection means for selecting one of the target speed profiles corresponding to the number of moving tracks, A seek speed control method for an optical head, comprising: speed control means for controlling the moving speed of the optical head according to a selected target speed profile. 2. The speed control means accelerates the optical head with a predetermined pulse output at the start of movement of the optical head based on a target speed profile selected when the number of moving tracks is smaller than the predetermined number of tracks. The seek speed control device for an optical head according to claim 1, wherein the optical head is accelerated at a constant acceleration after the optical head reaches a predetermined moving speed. 3. The speed control means, when the moving amount of the optical head reaches 1/2 of the number of moving tracks, following the acceleration of the optical head by the constant acceleration, carries out the optical deceleration at a constant deceleration. The speed control device for an optical head according to claim 2, wherein the head is decelerated. 4. The storage means stores a predetermined deceleration, and when the speed control means decelerates the optical head based on the predetermined deceleration, the optical head reaches a target track. At this time, a deceleration start time point at which a moving speed equal to or lower than a predetermined speed is given to the optical head is calculated, and at the deceleration start time point obtained by the calculation, from the acceleration by the predetermined acceleration to the deceleration of the optical head by the predetermined deceleration. Switching, claim 2
An optical head speed control device according to. 5. The speed control device for an optical head according to claim 1, wherein the predetermined number of tracks is 4000 or less.