KR20000064813A - Scanning apparatus for optical disc - Google Patents

Abstract

The scanning device 1 has a turntable 7 which is rotatable about a rotation axis 7a and a positioning device that is movable with respect to the turntable in a plane oriented in the transverse axis and the axis of rotation of the turntable. The positioning device includes a radiation source unit 9 and an actuator unit 23 having an objective system that can move in parallel with the rotation axis of the turntable. In addition, the scanning device moves the actuator unit and the radiation source unit with respect to each other between at least the planar separate operating positions oriented in the horizontal axis and the rotational axis of the turntable, so that the optical disc 3 having different substrate thickness and / or information density 3, It is further provided with an operating means for allowing 5) to be injected.

Description

Scanning apparatus for optical disc

The invention further comprises a positioning device and a radiation source for supporting a disk-shaped recording medium and having a turntable rotatable about a rotation axis, the positioning device operable with respect to the turntable in a plane oriented at least substantially horizontally with the rotation axis, wherein the position The determining device comprises an actuator having a base and a carrier movable with respect to the base and having an objective system, the apparatus further comprising a directing portion for directly radiating a radiation beam generated by the radiation source to the objective system. It is about.

Such injection devices are known from EP-A 0 464 912. This known scanning device has a turntable for supporting, centering and rotating an optical disk, in particular a compact disk. Such a disc has an information layer having a spiral track formed of a series of pits, which information is stored in the track in digital format, where the pits represent a series of bits. Digital information on the compact disc is covered with a transparent substrate with a nominal thickness of 1.2 mm. The scanning device further includes an electro-optical scanning unit having an objective lens and an actuator for moving the lens. In order to optically scan the disk, a semiconductor laser radiation source is used, a beam of laser light is focused on the information layer of the compact disk through the objective lens, and the substrate is disposed between the objective lens and the information layer. Since the digital information on the compact disc is protected by the substrate, possible scratches and dust particles are not present in the focal plane of the light beam that scans the disc, with relatively little effect.

To precisely focus the light beam, the actuator has a stationary actuator cross section and a movable actuator cross section, and consists of a drive coupling of a coil and a permanent magnet to move the objective lens parallel to its optical axis. During focusing, the movable actuator cross section performs a translational motion with respect to the center position. The focus servo system provides a coil drive. The actuator can also move the objective lens transversely to its optical axis for tracking.

Over time, various types of optical discs based on the "Compact Disc Standard" have been developed, namely CD-Audio, CD-ROM, CD-I and CR-R, and these CD-Audio, CD-ROM, Both CD-I and CR-R have substrates whose thickness is determined according to the values defined by this standard. Recently, a digital multifunctional disc (DVD) having two transparent substrates with one or more information layers inserted therebetween has been proposed. The substrates of the DVDs each have a nominal thickness of 0.6 mm, ie half the substrate thickness of the compact disc. In addition, the bit length and track pitch in the DVD are different from the corresponding parameters of the compact disc. Due to still different differences from these, DVDs present in various variants such as DVD-Audio, DVD-ROM, DVD-RAM and DVD-Video cannot be easily scanned by known scanning devices.

An object of the present invention is to obtain a device capable of scanning optical disks having substantially different substrate thicknesses and / or information densities by modifying known scanning devices.

In the scanning device according to the invention, the positioning device has two bodies movable relative to each other in a plane oriented at least substantially on the axis of rotation of the turntable, the base of the actuator unit being fixed to one of the bodies, The directing portion is fixed to the other of the bodies, and the objective system has an objective lens disposed adjacent to each other, each objective lens having an optical axis extending at least substantially parallel to the rotation axis of the turntable, in the latching position Latching means is provided to latch the bodies relative to each other, and at each of the positions the directing portions are arranged opposite one of the objective lenses to directly radiate a radiation beam to each objective lens along the optical axis of each objective lens. It is done.

The apparatus according to the invention allows two or more types of discs, in particular substrates having different nominal thicknesses, or transparent substrates to read different discs in that information is recorded in different ways. The number of latching positions is generally equal to the desired number of forms of the disk to be scanned, and an objective system is prepared for focusing the radiation beam at the focus in the information plane of the optical disk at each of the latching positions. To continue from one latching position to another, the directing portion and the complete actuator unit move relative to each other at a distance determined by the objective.

For example, by adapting each objective lens and / or its position to only one optical disk of a given type, characterized by substrate thickness and / or information and recording density, the scanning device is given a collection of two or more disc-shaped collections. It can be adapted to simply scan one optical disc of the type. For this purpose it is only necessary to select a suitable latching position.

In a practical embodiment of the scanning device according to the invention, the directing portion is composed of a deflector such as a reflector unit having a mirror surface. In another embodiment, the objective system has two objective lenses disposed adjacent to each other, one of which is selected to cooperate with the radiation source at each of the latching positions. If the directing portion is in the form of a deflector, this deflector is optically inserted between the radiation source and the selected objective lens. This radiation source may be a stationary radiation source such as a laser radiation source.

A practical embodiment of the scanning device according to the present invention having two objective lenses disposed adjacent to each other reads and / or writes the shape of an optical disc according to the CD standard, and reads the shape of the optical disc according to the DVD standard. And / or to record.

In the case of properly selecting the position of the objective lens in the actuator unit, the actuator unit known as used in the known scanning apparatus should basically comply with almost additional requirements. The actuator units in the scanning device according to the invention differ in principle from the actuator units known from EP-A 0 464 912 by the presence of two objective lenses instead of one objective lens, in which case they are mutually different from each other. The different optical properties of the objective lens and the position of the objective lens in relation to are important.

Note that EP-A 0 727 776 discloses a scanning device using an actuator having a stationary actuator cross section having two objective lenses and an actuator cross section rotatable in a pivotal axis. The last mentioned actuator cross section can rotate pivotally with respect to the bearing pin at a relatively large angle with respect to the other cross section to position one objective lens or another objective lens in the operating position. In each of the operating positions, the actuator cross section rotatable in the pivot axis also makes a small pivotal axis movement with respect to the bearing pin during tracking and a small translation along the bearing pin during focusing. Particular drive means are used in the form of additional coils and / or magnets, since a cross-section rotatable with the pivot axis is necessary for both the movement of the large pivot axis and the movement of the small pivot axis. Such measures lead to additional mass and volume of additional electronic controls and structures, which is undesirable for the efficiency of the device. In addition, precisely defined two zero positions of the pivotable rotatable actuator cross section are required for each accurate scan of the optical disc in which the scanning device is suitably used. In the known apparatus, the zero position is obtained by the magnetic retention force, which defines the preferred position with respect to the cross section rotatable with the pivot axis. However, the zero position thus obtained cannot be easily reproduced in an accurate manner because of influences such as temperature variation and inhomogeneity of a widely spread magnetic field.

In an embodiment of the injection device according to the invention, the latching means comprises a first stop member disposed on one body and a second stop member disposed on the other body, the two stop members latching during operation. Characterized in cooperating with each other in position.

In an embodiment of the injection device according to the invention, the stop member is characterized in that the mechanical members are mechanically coupled to each other at the latching position. In addition to the advantages mentioned above, these members further have the advantage of reduced wear. In addition, the force required for operation may be smaller than if a mechanical member is used.

In an embodiment of the injection device according to the invention, the stop member is characterized in that it is a magnetic or electromagnetic member magnetically or electromagnetically coupled to each other.

In an embodiment of the injection device according to the invention, it is characterized in that actuating means are provided for moving the two bodies with respect to each other between the latching positions.

In an embodiment of the injection device according to the invention, the actuating means comprises at least one first stop member disposed on one body and a second stop member on which at least one is stopped, the first stop member being positioned It is characterized in that the bodies can be moved relative to each other from one latching position to another latching position by engaging the second stop member during operation of the determining device. By the presence of the stop member, this movement is caused by the drive device for moving the positioning device, which drive exists anyway.

In an embodiment of the injection device according to the invention, the actuating means comprises an electromagnetic drive device.

In an embodiment of the injection device according to the invention, one of the bodies has the form of a first sliding member supported in the frame, the first sliding member being translated along the first translational axis, the second body being In the form of a second sliding member supported on the first sliding member, the second sliding member can be translated along a second translational axis, at least one said axis being at least substantially perpendicular to the vertical connecting line between the optical axis of the objective lens; It is characterized in that extending in parallel. Such a configuration is practical and can be simply realized. For reasons of cost, the second sliding member can be supported in the first sliding member. If more stringent requirements are imposed on supporting the second sliding member, an embodiment in which the second sliding member is supported irrespective of the first sliding member would be preferred.

In one embodiment of the injection device according to the invention, the first translational axis and the second translational axis extend at least substantially parallel to each other. Depending on the requirements given, it may be desirable to select two translation axes that are not parallel to each other. For example, the first translational axis and the second translational axis may intersect each other at least substantially vertically.

In an embodiment of the scanning device according to the invention, one of the bodies has the form of a pivot member which is rotatable about a pivot axis parallel to the axis of rotation of the turntable, the other body being supported against the pivot member, And can move about the pivot axis member along a line extending at least substantially parallel with the vertical connecting line between the optical axes of. In this embodiment, it is possible to simply and still accurately mount the actuator unit by means known per se.

In the embodiment of the injection apparatus according to the present invention, the base of the actuator unit is fixed to the pivot member, and the directing portion is fixed to another body. The other body may also be a pivot member, but is preferably configured as a sliding member.

In the embodiment of the injection apparatus according to the present invention, the directing portion is provided with a deflector. This deflector may be for example a reflector or a prism.

Moreover, the present invention relates to an optical reproducing apparatus comprising the scanning device according to the present invention housed in a housing.

The invention furthermore relates to a system comprising an optical disk of the first type and an optical disk of the second type, each having an optically transparent substrate and an optically scannable information layer on the substrate, and a scanning device according to the invention. It is about. The difference between the disk of the first type and the disk of the second type mainly belongs to the difference in the thickness of the substrate and / or the density of the information in the information layer. In a practical embodiment, the disk of the first type has a CD and the disk of the second type has a DVD.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. In the drawings,

1 is a schematic perspective view of an embodiment of a system according to the invention,

2 is a schematic perspective view showing an embodiment of an injection apparatus according to the present invention,

3 is a schematic perspective view showing an embodiment of an optical player according to the present invention.

The system according to the invention shown in FIG. 1 comprises an optical disc of the first form, an optical disc of the second form, and a scanning device 1 according to the invention. The optical disc of the first form is a CD, of which an optical disc 3 is shown, and the optical disc of the second form is a DVD. Among the forms mentioned at the end, an optical disc 5 is shown. The scanning device 1 is rotatable about the rotating shaft 7a and has a turntable 7 for supporting one of the disk-shaped recording mediums, that is, one of the optical disks 3 and 5 described above. The scanning device 1 further comprises a radiation source, in particular a semiconductor laser 9, and a positioning device 11. The positioning device 11 is movable with respect to each other and has two bodies 13 and 15 respectively configured as the sliding members 13 and 15. The two sliding members 13, 15 can be translated along the guiding means radially or at least substantially radially relative to the turntable 7. In this embodiment, the guide means is provided in the frame 18 and has two slide bars 17 and 19 extending through a bearing (not shown) of the sliding members 13 and 15. The electromagnetic actuator 23 has a base 21 fixed to the sliding member 13. This actuator 23 is movable relative to the base 21 and has a carrier 25 having an objective system having two objective lenses 27a and 27b. The lenses 27a and 27b, which are arranged in a row when viewed in a direction parallel to the slide bars 17 and 19, respectively have optical axes 27a1 and 27b1 extending in parallel with the rotational axis 7a of the turntable 7. . The carrier 25 is fixed to the base 21 via a hingeable or flexible suspension so that the objectives 27a and 27b are focused (indicated by arrow F) and the tracking direction (arrows). In the direction indicated by T). Coil system 33 was installed to drive carrier 25. EP-A 464,912 (described herein by reference) describes an example of a suspension of the carrier circuit 25 and the magnetic circuit 31 having the coil system 33.

The directing portion 35, that is, the planar mirror in the present embodiment is fixed to the sliding member 15, and is used to direct the radiation beam emitted by the radiation source 9 to the objective lens 27a or 27b.

The injection device 1 according to the invention is provided with latching means for latching the sliding members 13, 15 with respect to each other in exactly two defined latching positions. These latching positions are determined by these relative positions of the lens systems 27a and 27b, where the radiation beam 37 produced by the radiation source 9 is directed and then objective 27a or objective 27b. Penetrate In Fig. 1, the sliding members 13, 15 are shown in the latching position with respect to each other, where the radiation beam is directed along the optical axis 27b1 of the objective lens 27b after passing through the directing portion 35. In another latching position, the sliding members 13 and 15 have been moved over a distance similar to the distance between the optical axes 27a1 and 27b1 with respect to the latching position shown, and the radiation beam is reflected by the directing portion 35 and then the optical axis. Is oriented along (27a1). In the present embodiment, the latching means comprises two pairs of magnetic members 39a, 39b and 41a, 41b, and opposite surfaces of each pair of members are polarized oppositely, so that the sliding members 13 and 15 are latched. In each of are magnetically coupled to each other. In the latching position shown, this is caused by the members 39a and 39b, and in the other latching positions by the members 41a and 41b.

The injection device 1 according to the present invention is provided with a driving device for moving the slide members 13, 15 along the guide means 17, 19. The drive device includes an electric motor 43 fixed to the frame 18 and a power transmission unit having a pinion 45. Pinion 45 engages a toothed rack 47 located above slide member 13. When current flows through the electric motor, the two sliding members 13, 15 join them through the members 39a, 39b and 41a, 41b as long as there is movement within the same distance, ie within the operating range of the positioning device. Because of this, it is moved at the same time. In the present embodiment, this operating range is radially limited by the two frame portions 18a and 18b of the frame 18.

The injection device 1 according to the invention is provided with actuation means for moving the sliding members 13, 15 with respect to each other between the two latching positions. In addition to the drives 43, 45, these actuating means include two second slide member members formed by the frame portions 18a, 18b and two first stop members forming part of the slide member 15 ( 49a, 49b). When the two sliding members 13 and 15 are moved along the slide bars 17 and 19 from the position shown in the radial direction away from the turntable 7 when an electric current is applied to the electric motor 43, the first stop member 49a. ) Momentarily contact the second stop member 18a, and as a result the slide member 15 is stopped. In this case, the sliding member 13 is still driven, and since the driving force is greater than the coercive force between the magnetic members 39a and 39b, the sliding member 13 is moved more than a distance d until the latching position is reached, where The magnetic members 41a and 41b couple between the slide members 13 and 15.

The scanning device 101 according to the present invention shown in FIG. 2 is provided with a turntable 107 which is rotatable about the rotation axis 107a and supports a disk-shaped recording medium having different substrate thicknesses and / or information densities. . The scanning device 101 further comprises a positioning device and a radiation source 109 operable with respect to the turntable 107 in a plane oriented at least in a substantially horizontal axis with the rotation axis 107a. The movable positioning device includes an actuator 123 having a base 121 and a carrier 125 that is movable relative to the base 121 and has an objective system. The positioning device further comprises a directing portion 135 for directly radiating the radiation beam 137 generated by the radiation source in the form of a deflector, in particular a reflector, directly to the objective system. The positioning device has two bodies in the form of sliding members 113 and 115 that are movable relative to each other in a plane oriented at least substantially in the horizontal axis of the turntable 107, and of the actuator unit 123. The base 121 is fixed to one of the bodies, that is, the sliding member 13 in this embodiment. The directing portion 135 is fixed to the other body, ie the sliding member 115. The objective system includes two objective lenses disposed adjacent to each other, in this embodiment, objective lenses 127a and 127b, each of which extends at least substantially parallel to the rotation axis 107a of the turntable 107. It has optical axes 127a1 and 127b1.

Except for the objectives, see EP-A 464,912 for information on the construction of the actuator units.

The injection device 101 has a drive with an electric motor 143 having a pinion 145 that engages with the toothed rack 147 of the sliding member 115. The sliding member 115 can be translated along the guide means 117, 119 having two slide bars 117, 119. The sliding member 113 can be translated to a limited range with respect to the sliding member 115, so that the guide member is guided by the guide edges 117a and 119a of the sliding member 115. Since the slide bars 117 and 119 extend at least substantially radially with respect to the turntable 107, and the guide edges 117a and 119a extend parallel to the slide bars 117 and 119, the slide members 113, 115 may be translated along at least substantially radially extending first translational axis T1 and second translational axis T2. Further, both axes T1 and T2 extend at least substantially parallel to the vertical connection line l between the optical axes 127a1 and 127b1 of the objective lenses 127a and 127b.

The scanning device 101 is defined in such a way that, in the latching position, the directing portion 135 is disposed opposite to one of the objective lenses 127a or 127b to orient the radiation beam 137 along each optical axis 127a1 or 127b1. And latching means for latching the sliding members 113 and 115 with respect to each other in the latched position. The latching means comprises a first mechanical stop member in the form of an elastic latching hook 139a disposed on the sliding member 113, and a second stop member in the form of two latching recesses 139b1, 139b2. It is provided.

In the latching position shown in Fig. 2, the directing portion 135 directs the radiation beam 137 along the optical axis 127b1 of the objective lens 127b, and the hook 139a is engaged in the depression 139b1. In another latching position, not shown, the directing portion 135 directs the radiation beam 137 along the optical axis 127a1 of the objective lens 127a, and the hook 139a engages in the depression 139b1. In both cases, the sliding members 113 and 115 are locked in preparation for movement with respect to each other during scanning of the recording medium disposed on the turntable 107.

The injection device 101 is provided with actuation means for moving the two sliding members 113, 115 with respect to each other between the latching positions. These actuating means have a first stop member 149 disposed on the slide member 113 and two stationary second stop members 118a and 118b. The first stop member 149 has a protruding shape, and the second stop members 118a and 118b respectively fixed to the frame 118 form a piston rod. The first stop member 149 radiates the sliding members 113 and 115 without the stop member 149 contacting the stop member 118a or 118b during scanning with respect to the second stop member 118a and 118b. It is arranged to move together in the direction. However, when the sliding members are moved together in a radially outer or inner position, the stop member 149 comes into contact with each stop member 118a or 118b. If such outward displacement occurs from the latching position shown, the driven sliding member 115 will make a small run after the stop member 149 contacts the stop member 118a, and the latching hook 139a latches. It is separated from the depression 136b1 and engaged with the latching depression 139b2 to couple the slide members 113 and 115 to each other at different latching positions.

The optical reproducing apparatus according to the present invention shown in FIG. 3 includes a scanning device 201 housed in the housing 200. The scanning device 201 is particularly suitable for scanning different optical disks in terms of transparent substrate and information density. The scanning device 201 is supported in the frame 218 and includes a turntable 207 having a centering portion 207c for the optical disk and a support surface 207b. The frame 218 is optionally fixed to the housing 200 in an elastic or braking manner, and the turntable 207 is rotatable about the axis of rotation 207a. The scanning device 201 further includes a radiation source 209 and a positioning device operable in a plane oriented with a rotation axis and a transverse axis, the positioning device comprising an actuator unit having a base 221 and a carrier 225. 223, the carrier 225 is movable relative to the base 221, and has an objective system having two objective lenses 227a and 227b. The positioning device further includes a directing portion 235 for directly radiating the radiation beam 237 emitted by the radiation source to the objective system. The positioning device has two bodies, i.e., the pivot member 213 and the slide member 115, and the pivot member 213 and the slide member 115 are the rotation axis 207a and the horizontal axis of the turntable 207. Movable in relation to each other in a plane oriented. The pivot member 213 is rotatable about a pivot axis 213a parallel to the rotational axis 207a of the turntable 207, and the slide member 215 of the turntable 207 along the guide means 217,219. It can be translated radially about the axis of rotation 207a. The directing portion 235 is connected to a sliding member 215 which can be driven by a drive device having an electric motor 243 in this embodiment, via a pinion 245 and a toothed rack 247. It is fixed. The base 221 of the actuator unit 223 is fixed to the pivot member 213 rotatably mounted in the pivot member 215 in the slide member 215 in this embodiment. Except for the objectives 227a and 227b, the actuator unit 223 is of the same type as described in detail in US Pat. No. 4,817,076 (described herein by reference). The actuator unit 223 has a bearing pin 202 extending in parallel with the rotation axis 207a of the turntable 207, and the carrier 225 has a small rotational movement about the central axis of the bearing pin 202 for tracking. Can be done.

Moreover, the carrier 225 can make small translational movements in the longitudinal direction of the bearing pins 202 to focus. The actuator unit further includes a magnetic circuit having a drive coil. The objective lenses 227a and 227b have optical axes 227a1 and 227b1, respectively, and the vertical connection line l between the optical axes 227a1 and 227b1 extends in parallel with the guide means 217 and 219, and thus the sliding member 215 Extend parallel to the translational direction of

Pivoting member 213 has a toothed segment 240 engaged with a toothed rack 242 of actuation member 244. In this embodiment, the actuation member 244 is mounted in the sliding member 214 to be slidable radially between two positions, one of the two positions being shown in FIG. In the illustrated position of the operating member 244, the pivot shaft member 213 and the sliding member 215 are latched to each other, that is, the directing portion 235 moves the radiation beam 237 to the objective lens 227b. It is in the latching position to direct. The actuation member 244 is latched relative to the sliding member 215 by an elastic latching hook 239a that engages the latching depression 239b1.

By moving the actuating member 224 from the position shown toward the tentable 207, the movement of the pivot shaft is moved to the pivot shaft member 213 and moved to the actuator unit 223. When latching hook 239a engages with latching depression 239b2, a new latching position of pivot member 213 and sliding member 215 is reached. In this latching position, the directing portion 235 directs the radiation beam 237 to the objective lens 227a. Movement of the actuating member 244 arises from the movement of the sliding members 215, 149, for which actuating means 218a, 218b, 249 play an important role. Momentarily, while the sliding member 215 moves from the position shown in FIG. 3 to a position away from the turntable, the protrusion 249 of the operating member 244 will continue to be held by the stop stop member 218a. As the slide member continues to move, the actuating member 244 is moved relative to the slide member 215 so that the latching hook 239a engages with the latching depression 239b2. When the sliding member 215 moves toward the turntable 207 starting in the present situation, the illustrated latching position can be obtained again through the cooperation of the protrusion 249 and the stop stop member 218b.

Obviously, the optical reproducing apparatus according to the present invention further includes the necessary optical and electronic components known per se.

Note that the present invention is not limited to the examples shown herein. For example, the sliding member in the embodiment shown in FIG. 3 may be configured as a pivot member. In addition, the pivot member in the embodiment shown in FIG. 3 need not necessarily be supported in the slide member. In addition, the stop means and / or actuation means may be configured in other ways than shown.

Claims (15)

A turntable supporting a disk-shaped recording medium and rotatable about an axis of rotation, further comprising a positioning device and a radiation source operable with respect to the turntable in a plane oriented at least substantially transverse to the axis of rotation, the positioning device comprising: An injection apparatus comprising an actuator having a base and a carrier movable with respect to the base, the actuator having a directing portion for directly radiating a radiation beam generated by a radiation source to the objective system, the apparatus comprising: The positioning device has two bodies movable relative to each other in a plane oriented at least substantially transversely to the axis of rotation of the turntable, the base of the actuator unit being fixed to one of the bodies, the directing portion being one of the other of the bodies. Fixed to the body, the objective system having an objective lens disposed adjacent to each other, each objective lens having an optical axis extending at least substantially parallel to the axis of rotation of the turntable, the latching of the body relative to each other in a latching position A latching means is provided, wherein at each of the positions, the directing portion is arranged opposite to one of the objective lenses so as to directly radiate a radiation beam to each objective lens along the optical axis of each objective lens. The method of claim 1, Said latching means having a first stop member disposed on one body and a second stop member disposed on another body, the two members being configured to cooperate with one another in a latching position during operation. The method of claim 2, And the stop member is a mechanical member mechanically coupled to each other at a latching position. The method of claim 2, And the stop member is a magnetic or electromagnetic member magnetically or electromagnetically coupled to each other. The method according to any of the preceding claims, An injection device, characterized in that actuating means are provided for moving the two bodies relative to each other between the latching positions. The method of claim 5, The actuating means has at least one first stop member and at least one stationary second stop member disposed on a body, the first stop member engaged with the second stop member during operation of the positioning device. An injection device characterized in that the bodies can be moved relative to one another from a latching position to another latching position. The method of claim 5, And said actuating means comprises an electromagnetic drive. The method according to any of the preceding claims, One of the bodies has the form of a first sliding member supported in the frame, the first sliding member can be translated along the first translation axis, and the second body is a second sliding member supported on the first sliding member. Having a second form, wherein the second sliding member can be translated along a second translation axis, at least one said axis extending at least substantially parallel to a vertical connection line between the optical axes of the objective lens Injector. The method of claim 8, And the first translational axis and the second translational axis extend at least substantially parallel to each other. The method according to claim 8, 9 or 10, And the second sliding member is supported irrespective of the first sliding member. The method according to any one of claims 1 to 7, One of the bodies has the form of a pivot member which is rotatable about a pivot axis parallel to the axis of rotation of the turntable, the other body being supported relative to the pivot axis member and at least substantially with a vertical connection line between the optical axes of the objective lens. An injection device characterized in that it can move relative to a pivot member along a line extending in parallel. The method of claim 11, And the base of the actuator unit is fixed to the pivot member and the directing portion is fixed to the other body. The method according to any of the preceding claims, And the directing portion has a deflector. An optical reproducing apparatus, comprising the scanning device according to any one of the preceding claims housed in a housing. An optical disk of a first type and an optical disk of a second type, each having an optically transparent substrate and an optically scannable information layer present on said substrate, -A system comprising the injection device according to any one of claims 1 to 13.