JP2007526594A - Optical device for recording and reproduction - Google Patents

Abstract

The invention relates to an optical scanning device for scanning an information carrier (12) having a track, a fixed part (10) having a radiation source (101) and means for compensating for spherical aberration (104); An optical scanning device having a movable part (11) having a folding mirror (111) and an objective lens (112), and a first moving means for moving the movable part (11) in the cross-track direction in a track selection mode The folding mirror in the fine tracking mode to move the objective lens (112) in the cross-track direction in the fine tracking mode and so that the folding mirror (111) substantially follows the objective lens (112). And a second moving unit for moving (111).

Description

  The present invention relates to an optical scanning device for scanning an information carrier having a track, the optical scanning device having means for compensating for spherical aberration.

  The invention particularly relates to an optical disc apparatus for recording on and reading from optical discs, for example CD, DVD and / or Blu-ray Disc (BD) recorders and players.

  Many optical scanning devices require a means for compensating for spherical aberration. In practice, the information carrier is often scanned by an optical scanning device through a transparent layer that protects the information layer. A small variation in the thickness of the transparent layer results in a substantial change in the spherical aberration experienced by a large aperture radiation beam transmitted through the transparent layer. Since the spacer layer between the two layers produces spherical aberration when jumping from one layer to the other, compensation for spherical aberration is also necessary to scan the multilayer information carrier.

  Various spherical aberration compensation means are known. The first embodiment is a liquid crystal cell placed in the optical path. Spherical aberration is introduced into a radiation beam in which the refractive index of the liquid crystal cell is locally changed by applying a voltage to the liquid crystal cell. The second embodiment is a compensation plate placed between two lenses. When spherical aberration needs to be introduced into the radiation beam, the compensator is placed in the optical path, and when no spherical aberration is required, the compensator is mechanically removed from the optical path. Other embodiments are known, such as birefringent folded polymer phase plates.

  Furthermore, when using a separation optical system, a plurality of optical scanning devices are often required. In particular, the optical scanning device using the separation optical system includes a fixed part having a radiation source and a movable part having a folding mirror and an objective lens. Since the heat sink is placed in the vicinity of the radiation source when the latter is fixed, the use of the separation optical system simplifies the optical scanning device and increases the life of the radiation source.

  An optical scanning apparatus that implements a separating optical system and has means for compensating for spherical aberration has a fixed part having a radiation source and means for compensating for spherical aberration, and the movable part has a folding mirror and an objective lens. Have. The optical scanning device further comprises means for moving the movable part in the cross-track direction to perform track selection. The optical scanning device also moves the objective lens in the cross-track direction to achieve fine tracking to ensure that the radiation beam remains focused in the track whatever the information carrier is eccentric. It also has means for moving.

  However, the Applicant has recognized that such optical devices produce large coma during tracking.

  An object of the present invention is an optical scanning device having means for compensating spherical aberration and a separating optical system, in which the amount of coma generated during tracking is reduced in the optical scanning device. Is to provide.

  To this end, the present invention is an optical scanning device for scanning an information carrier having a track, the optical scanning device comprising a fixed part having a radiation source and means for compensating for spherical aberration. The movable part has a folding mirror and an objective lens, and the optical scanning device has a first moving means for moving the movable part in the cross-track direction in the track selection mode, and the cross-track direction in the fine tracking mode. Proposing an optical scanning device comprising: second moving means for moving the objective lens and for moving the folding mirror in the fine tracking mode so that the folding mirror substantially follows the objective lens. .

  The inventor has recognized that the coma produced during tracking is due to the fact that the center of the means for compensating for spherical aberration does not remain aligned with the center of the objective lens in the optical path. According to the invention, the radial position of the folding mirror with respect to the radial position of the objective lens is always the same. The radial position is the position in the cross track direction. Therefore, the center of the spherical aberration compensating means is kept aligned with the center of the objective lens. Therefore, coma is reduced during tracking.

  In the first embodiment, the second moving means is adapted to move the movable part in the tracking mode. According to this embodiment, no radial actuator is used to move the folding mirror or objective lens. The movable part itself is moved during tracking. The optical scanning device is therefore relatively simple.

  In the second embodiment, the second moving means includes a first actuator for moving the objective lens and a second actuator for moving the folding mirror. This embodiment is suitable when the movable part is not moved during tracking, and is true if the weight supported by the movable part is too large.

  Advantageously, the optical scanning device further comprises means for detecting the position of the objective lens and means for transmitting a signal representative of the position to the second actuator. This allows control of the radial position of the folding mirror relative to the radial position of the objective lens with relatively high accuracy.

  Preferably, the first and second actuators are controlled by the same tracking signal. In this case, no means for detecting the position of the objective lens is required, which simplifies the optical scanning device.

  These and other features of the invention will be described and elucidated with reference to the embodiments described in detail below.

  The present invention will now be described in detail by way of example with reference to the accompanying drawings.

  An optical scanning device according to the prior art is shown in FIG. This optical scanning device has a fixed part 10 and a movable part 11. The fixed portion 10 includes a radiation source 101, a beam splitter 102, a collimator lens 103, a spherical aberration compensation unit 104, a servo lens 105, and a detection unit 112. The movable part 11 has a folding mirror 111 and an objective lens 112. This optical device is intended for scanning the information carrier 12.

  During a scanning operation, which can be a writing operation or a reading scan, the information carrier 12 is scanned by a radiation beam generated by the radiation source 101. The collimator lens 103 and the objective lens 112 focus the radiation beam in the information layer of the information carrier 12. It is possible to detect a focus error signal corresponding to an error in the positioning of the radiation beam in the information layer. This focus error signal is detected by the detection means 106 so as to compensate for the focus error of the radiation beam and can be used to correct the axial position of the objective lens 112. For this purpose, the controller drives the actuator to move the objective lens in the axial direction.

  The information carrier has a track on which data is recorded. In order to scan a predetermined track, the radiation beam needs to be focused on the predetermined track. For this purpose, the movable part 11 is moved in the cross-track direction with a recognized movement S, so that the radiation beam reaches the desired track. This corresponds to the track selection mode, where the movable part is moved in the cross-track direction until the radiation beam is focused on the desired track. Once the radiation beam is focused on the desired track, the radiation beam needs to remain focused on the track during rotation of the information carrier 12. However, the information carrier exhibits eccentricity. Therefore, the objective lens 112 is moved so that the radiation beam remains focused in the track. This corresponds to a tracking mode, in which the objective lens is moved in the cross-track direction with a recognized movement T so that the radiation beam remains focused in the desired track.

  The movable part is usually moved by a linear motor in the track selection mode, and the objective lens 112 is usually moved by an actuator in the tracking mode. The actuator is controlled by a tracking signal that represents the difference between the position of the radiation beam and the center of the track. Since track selection and tracking are known to those skilled in the art, further description is omitted.

  FIG. 2 shows part of an optical scanning device according to the prior art in the tracking mode. As shown in FIG. 2, the displacement of the objective lens 112 during tracking leads to the center of the spherical aberration compensating means 104 not being kept aligned with the center of the objective lens 112 in the optical path. Applicant has recognized that coma occurs under this circumstance. This does not occur without the spherical aberration compensation means 104. Actually, coma aberration is caused by the introduction of wavefront aberration in the radiation beam by the spherical compensation means 104 as compared to the decentering of the objective lens 112 with respect to the spherical aberration compensation means 104.

  An optical scanning device according to the first embodiment of the present invention is shown in FIG. In FIG. 3, reference numbers corresponding to those in FIG. 1 represent the same elements. According to the first embodiment, the folding mirror 111 and the objective lens 112 are provided in the movable portion 11, and therefore, radial displacement between the movable portion 11 and the objective lens 12 is not possible. This means that the optical scanning device of FIG. 3 does not have any radial actuator that moves the objective lens in the cross-track direction compared to the prior art optical scanning device. Instead, the moving means is used during tracking so as to move the movable portion 11 in the cross track direction along with the movement T. These moving means can be moving means used for moving the movable part 11 in the cross track direction in the track selection mode. For example, a linear motor used for the movable part 11 in the track selection mode can be used in the tracking mode. This linear motor needs to have a relatively large stroke to move the movable part 11 during track selection and a relatively large bandwidth to move the movable part 11 in the track mode. As an alternative, the moving means used for moving the movable part 11 in the tracking mode can comprise a one-dimensional radial actuator. Examples of suitable one-dimensional actuators are linear electromagnetic actuators and piezoelectric ceramic actuators, which are known to those skilled in the art. This one-dimensional radial actuator needs to have a relatively wide bandwidth for moving the movable part 11 in the tracking mode. This is possible in an optical scanning device using a separation optical system, in which the total weight of the movable part is relatively light compared to the total weight of the sledge in an optical device not using the separation optical system.

  According to the first embodiment, the objective lens 112 and the folding mirror 111 are movable together with only the movable part 11 in the radial direction, so that the radial position of the folding mirror 111 is always relative to the radial position of the objective lens 112. Kept the same. Therefore, the eccentricity that occurs during tracking in the prior art no longer occurs in the optical scanning device according to this first embodiment of the invention, as shown in FIG. Therefore, no coma occurs during tracking according to the first embodiment of the present invention.

  It should be noted that the optical scanning device according to this first embodiment of the present invention is also simpler than the optical scanning device according to the prior art. In the prior art optical scanning device, a two-dimensional actuator is provided in the movable part 11 to move the objective lens 112 with the respective movements F and T. In the optical scanning device according to the first embodiment of the present invention, the one-dimensional actuator is attached to the movable portion 11 so as to move the objective lens 112 with the movements F and T. One-dimensional actuators are simple, not bulky, and cheaper than two-dimensional actuators.

  An optical scanning device according to the second embodiment of the present invention is shown in FIG. In FIG. 4, reference numerals that are the same as those in FIG. 1 indicate the same elements. According to the second embodiment, the movable part 11 has first and second actuators, which are not shown in FIG. The first actuator is designed to move the objective lens 112 in the tracking direction in the tracking mode with the movement T1, and the second actuator moves the folding mirror 111 in the tracking direction in the tracking mode with the movement T2. Designed to let you. The first actuator can be a two-dimensional actuator designed to move the objective lens 112 with movement T1 and movement F. Alternatively, other one-dimensional actuators can be used to move the objective lens 112 with movement F.

  According to this second embodiment of the invention, the movements T1 and T2 are substantially the same. Accordingly, the radial position of the folding mirror 111 is always kept substantially the same as the radial position of the objective lens 112. The eccentricity that occurs during tracking in the prior art does not occur or is not affected in the optical scanning device according to the second embodiment of the present invention. Therefore, no coma occurs during tracking according to the second embodiment of the present invention.

  The first method moves the radial position of the objective lens 112 during tracking so that the movement T2 is substantially the same as the movement T1, ie, the folding mirror 111 follows the radial movement of the objective lens during tracking. Have to measure. Depending on the measurement position relative to the position of the folding mirror 111, a signal is sent to the actuator that moves the folding mirror 111, so that the folding mirror is moved until it reaches the same radial position as the objective lens 112.

  The second method comprises controlling the second actuator with the same signal that controls the first actuator. As described with reference to FIG. 1, the conventional optical scanning device has means for generating a tracking signal, which is an actuator that moves the objective lens to move the objective lens during tracking. Sent to. This tracking signal represents the difference between the position of the radiation beam and the center of the track. This tracking signal is obtained, for example, by a so-called three-spot push-pull tracking method. When the actuator that moves the folding mirror 111 is controlled by the same signal as the actuator that moves the objective lens 112, the folding mirror 111 has the same movement as the objective lens 112.

  The use of the term “comprising” and its derivatives does not exclude the presence of any other elements other than those defined in any claim. The singular representation of an element does not exclude the presence of a plurality of such elements.

It is a figure which shows the optical scanning device according to a prior art. It is a figure which shows a part of optical scanning apparatus of FIG. 1 during tracking. It is a figure which shows the optical scanning device according to 1st Embodiment of this invention. It is a figure which shows the optical scanning device according to 2nd Embodiment of this invention.

Claims (5)

An optical scanning device for scanning an information carrier having a track comprising:
A fixed part having a radiation source and means for compensating spherical aberration; and a movable part having a folding mirror and an objective lens;
An optical scanning device having
First moving means for moving the movable part in the cross-track direction in a track selection mode; and for moving the objective lens in the cross-track direction in a fine tracking mode and the folding mirror substantially follows the objective lens A second moving means for moving the folding mirror in the fine tracking mode;
An optical scanning device comprising:   2. The optical scanning device according to claim 1, wherein the second moving unit is adapted to move the movable part in the fine tracking mode.   2. The optical scanning device according to claim 1, wherein the second moving unit includes a first actuator for moving the objective lens and a second actuator for moving the folding mirror. 3. An optical scanning device.   4. The optical scanning device according to claim 3, further comprising means for detecting the position of the objective lens and means for transmitting a signal representing the position to the second actuator. An optical scanning device characterized by the above.   4. The optical scanning device according to claim 3, wherein the first and second actuators are controlled by the same tracking signal.

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