JP2010123175A - Optical disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical disk device which discriminates an optical disk of a small diameter with an adapter from an optical disk of a large diameter. <P>SOLUTION: A CD player 1 includes: an equipment body 3 in which an adapter 16 is attached to a large diameter CD2a and a large diameter DVD 4a and a small diameter CD2b and a small diameter DVD 4b having smaller diameter that the large diameter CD2a and the large diameter DVD 4a, and is housed any one of the small diameter CD 2b and small diameter DVD 4b with adapter 16 of which the outside diameter are equal to that of the large diameter CD 2a and the large diameter DVD 4a; a LD21 in which is fixed to an equipment body 3, and is provided at position which faces both sides of the adapter 16 of the small diameter CD2b and small diameter DVD 4b with adapter 16 housed in this equipment body 3 and one side of surfaces 2c, 4c of the large diameter CD2a and the large diameter DVD 4a, and irradiates a laser beam toward these; and a PD22 which is arranged with this LD21, and which can receive diffraction light of the laser beam irradiated toward one side of the surfaces 2c, 4c of the large diameter CD2a and the large diameter DVD 4a from the LD21. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an optical disc apparatus that reads information from an optical disc such as a Compact Disc, for example.

  As an optical disk such as a CD (Compact Disk), a DVD (Digital Versatile Disc), or a BD (Blu-ray Disc), an optical disk having a large diameter of, for example, 12 cm and an optical disk having a small diameter of, for example, 8 cm are used. ing. An optical disc apparatus that reads and reproduces information recorded on these optical discs (see, for example, Patent Document 1) is provided in the device main body, transport means for taking a recording medium in and out of the device main body, and a recording medium provided in the device main body. Clamping means for clamping the medium and reading information from the recording medium.

  The clamp reproducing means includes a turntable for rotating the optical disk accommodated in the apparatus main body and an optical pickup for reading information from the information recording surface of the optical disk rotated by the turntable.

  As the above-described optical disk apparatus, in order to enable reading of information on both the large-diameter optical disk and the small-diameter optical disk, an adapter is attached and the above-described small-diameter state in which the outer diameter is equal to the large-diameter optical disk. Some optical discs are housed in a device body and information is read out.

  This type of adapter includes an annular adapter body having an outer diameter equal to the outer diameter of the above-described large-sized optical disk and an inner diameter equal to the outer diameter of the aforementioned small-diameter optical disk, and an inner edge of the adapter body. And a plurality of locking claws that are locked to the outer edge of the small-diameter optical disk. The adapter body is formed so that its thickness is substantially equal to the thickness of the small-diameter optical disk. The locking claw protrudes inward from the inner edge of the adapter main body and protrudes from both surfaces of the adapter main body in order to lock to the outer edge of the small-diameter optical disc.

The above-mentioned small-diameter optical disk is fitted with an adapter with a locking claw locked to its outer edge. At this time, of course, the small-diameter optical disk and the adapter are arranged coaxially. Then, the small-diameter optical disc is accommodated in the apparatus main body with the adapter attached, and information recorded on the information recording surface is read by the clamp reproducing unit. In addition, since the above-described conventional optical disk apparatuses have the same outer diameter, information is read from these without identifying the large-diameter optical disk and the small-diameter optical disk with an adapter described above.
JP 2002-329361 A

  Since the above-described conventional optical disk apparatus does not distinguish between the above-mentioned large-diameter optical disk and the small-diameter optical disk with an adapter, when reading information from the small-diameter optical disk with an adapter, the large-diameter optical disk As in reading information from the optical pickup, the optical pickup is moved to a position facing the adapter described above. At this time, depending on the type of the adapter, the locking claw described above protrudes from both surfaces of the adapter body, so that the objective lens of the optical pickup may come into contact with the locking claw. In this case, in the worst case, the objective lens is damaged, and it may be difficult to read information from the optical disk.

  Accordingly, an object of the present invention is to provide an optical disc apparatus capable of discriminating, for example, a small-diameter optical disc with an adapter and a large-diameter optical disc.

  In order to solve the above-mentioned problems and achieve the object, the present invention according to claim 1 includes a large-diameter optical disk, and an adapter attached to an optical disk having a smaller diameter than the large-diameter optical disk. An apparatus main body accommodating either one of a small-diameter optical disk with an adapter having the same outer diameter, an adapter of a small-diameter optical disk with an adapter fixed to the apparatus main body and accommodated in the apparatus main body, and the large A light emitting element which is provided at a position facing both the information recording surface of the optical disk having a diameter and irradiates a laser beam toward these, and the light emitting element arranged side by side from the light emitting element. And a light receiving element capable of receiving the diffracted light of the laser light irradiated toward the information recording surface.

  Hereinafter, an optical disc apparatus according to an embodiment of the present invention will be described. An optical disk device according to an embodiment of the present invention includes a light receiving element that receives diffracted light reflected by an information recording surface of an optical disk of laser light from a light emitting element, arranged side by side with the light emitting element, and further the light emitting element is a device. A laser beam is applied to an adapter of a small-diameter optical disc with an adapter in the main body, and the information recording surface of the large-diameter optical disc of the apparatus main body is arranged at a position to irradiate the laser beam.

  In this way, since the adapter does not have fine pits formed on the information recording surface of the optical disk, when a small-diameter optical disk with an adapter is accommodated in the device body, the adapter of the laser beam from the light emitting element The light receiving element cannot receive the laser beam reflected by the surface. Furthermore, when a large-diameter optical disk is accommodated in the device body, the light-receiving element reliably receives the diffracted light of the laser light reflected from the information recording surface of the large-diameter optical disk of the laser light from the light-emitting element. Can do. Therefore, depending on whether or not the light receiving element has received the above-described diffracted light, whether the optical disk accommodated in the device main body is a small-diameter optical disk with an adapter or a large-diameter optical disk is reliably identified. be able to.

  In the present embodiment, a plurality of light receiving elements are provided corresponding to the types of large-diameter optical disks accommodated in the apparatus body, and the plurality of light-receiving elements are reflected by the information recording surface of the corresponding large-diameter optical disks. You may arrange | position in the position which can receive the diffracted light to be received. In this case, even if the device can reproduce a plurality of types of optical disks by determining whether any of the plurality of light receiving elements has received the above-described diffracted light, the optical disk accommodated in the apparatus main body Can be reliably identified as either a small-diameter optical disk with an adapter or a large-diameter optical disk. Further, by identifying the light receiving element that has received the diffracted light among the plurality of light receiving elements, the type of the large-diameter optical disk described above can be identified.

  Further, one light receiving element may be arranged at a position where it can receive diffracted lights of different orders from different types of large-diameter optical disks. In this case, a single light receiving element can be used for a plurality of types of large-diameter optical disks.

  In this case, for example, the light receiving element is positioned at a position where the angle between the line segment connecting the light emitting element and the portion facing the light emitting element on the information recording surface and the line segment connecting the light receiving element and the portion is 23 degrees. It may be arranged. In this case, a single light receiving element can receive the second-order diffracted light reflected from the information recording surface of the CD and the first-order diffracted light reflected from the information recording surface of the DVD.

  Hereinafter, a player apparatus 1 as an example of an optical disk apparatus according to an embodiment of the present invention will be described with reference to FIGS. A player apparatus 1 shown in FIG. 1 or the like is attached to an automobile instrument panel (hereinafter referred to as an instrument panel) as a moving body, and is used as a relatively large-diameter optical disc having an outer diameter of, for example, 12 cm. The user selects a large-diameter CD 2a or a large-diameter DVD 4a and a small-diameter CD 2b or a small-diameter DVD 4b as a relatively small-diameter optical disk having an outer diameter of, for example, 8 cm, and among these CD 2a, 2b and DVD 4a, 4b. One of them is accommodated in the device main body 3. The player device 1 is a device that reads (reproduces) information recorded on any of the CDs 2a and 2b and the DVDs 4a and 4b accommodated in the device body 3 and outputs the information as sound. As shown in FIGS. 3 (a) and 3 (b), the CDs 2a, 2b and DVDs 4a, 4b are, of course, formed in a disk shape, that is, a disk shape with a central hole in the center. It is a recording medium that records information that can be read by a device. Further, in the above-described CDs 2a, 2b and DVDs 4a, 4b, one of these surfaces 2c, 2d, 4c, 4d (shown in FIGS. 4 and 5) forms an information recording surface on which information is recorded. Of course, a number of fine pits are provided on one of the surfaces 2c, 2d, 4c and 4d as the information recording surface. Of course, the CDs 2a and 2b and the DVDs 4a and 4b have different pit sizes and intervals. For this reason, in the CDs 2a and 2b and the DVDs 4a and 4b, the reflected light of the laser light applied to one of the surfaces 2c, 2d, 4c, and 4d as the information recording surface becomes diffracted light.

  Note that the reflected light of the laser beam irradiated on the information recording surface of the optical disc such as the CD 2a, 2b and the DVD 4a, 4b described above satisfies the following formula 1.

  In Equation 1, d is the interval between the pits in the radial direction of the optical disk, α is the angle of the laser beam incident on the information recording surface with respect to the axis orthogonal to the information recording surface, and β is from the information recording surface. The angle of the reflected diffracted light with respect to the axis orthogonal to the information recording surface, m is the order, and λ is the wavelength of the laser light incident on the information recording surface. That is, when laser light is incident on these surfaces 2c, 2d, 4c, and 4d along a direction orthogonal to one of the surfaces 2c, 2d, 4c, and 4d as the information recording surface, the one surface 2c , 2d, 4c, and 4d are emitted in a direction that intersects a direction orthogonal to one of the surfaces 2c, 2d, 4c, and 4d. That is, it becomes diffracted light. Note that the above-mentioned CDs 2a, 2b, DVDs 4a, 4b and BD have different angles from the direction perpendicular to the information recording surface of the diffracted light, because the distance between the ds, i.e., radial pits, is different from each other. Different from each other.

  The large diameter CD 2a and the large diameter DVD 4a are accommodated in the apparatus main body 3 as they are, and the small diameter CD 2b and the small diameter DVD 4b are inside the apparatus main body 3 with the adapter 16 attached as shown in FIG. Is housed in. The adapter 16 is made of various known materials such as synthetic resin. As shown in FIG. 3B, the outer diameter is equal to the outer diameter of the large diameter CD2a and the large diameter DVD 4a, and the inner diameter is the small diameter CD2b. An annular adapter body 16a having the same outer diameter as that of the small-diameter DVD 4b, and a plurality of latching claws 16b provided on the inner edge portion of the adapter main body 16a and latched on the outer edge portions of the small-diameter CD 2b and the small-diameter DVD 4b. .

  The adapter body 16 is formed so that its thickness is substantially equal to the thickness of the small diameter CD 2b and the small diameter DVD 4b. The locking claws 16b are a pair of claw portions 16c that are convex from both surfaces of the adapter main body 16a and protrude to the inner peripheral side of the inner edge of the adapter main body 16a in order to lock to the outer edge portions of the small diameter CD 2b and the small diameter DVD 4b. It has. The locking claw 16b sandwiches the outer edge portions of the small diameter CD2b and the small diameter DVD 4b between the pair of claw portions 16c, and locks the outer edge portions of the small diameter CD2b and the small diameter DVD 4b. When the adapter 16 is attached to the outer edges of the small diameter CD 2b and the small diameter DVD 4b, the adapter 16 is, of course, arranged coaxially with the small diameter CD 2b and the small diameter DVD 4b.

  As shown in FIGS. 1 and 2, the player apparatus 1 includes an apparatus main body 3 (shown in FIG. 1), a transport unit 5 as a transport means, a clamp playback unit 6 as a clamp playback means, and a linkage means. An interlocking mechanism, a determination unit 7 (shown in FIGS. 4 and 5) as a determination unit, and μCOM as a control unit are provided.

  In the following, the arrow Y in FIG. 1 parallel to both the surface of the CD 2a, 2b, DVD 4a, 4b and the transport direction of the CD 2a, 2b, DVD 4a, 4b of the transport unit 5 is described as the depth direction of the player device 1. An arrow X that is parallel to the surfaces of the CDs 2a and 2b and DVDs 4a and 4b and orthogonal to the depth direction Y is referred to as the width direction of the player device 1, and the surfaces of the CDs 2a and 2b and DVDs 4a and 4b An arrow Z orthogonal to all is referred to as a thickness direction of the player device 1.

  The apparatus main body 3 includes an outer case 8 shown in FIG. 1 made of synthetic resin, metal, or the like, and a chassis main body 9 shown in FIG.

  The outer case 8 is formed in a flat box shape. When the outer case 8 is attached to the above-mentioned instrument panel, a front face 8a (shown in FIG. 1) facing the occupant is provided with one insertion slot 10 through which CDs 2a, 2b and DVDs 4a, 4b can be taken in and out. The front surface 8a is one surface of the outer case 8 that is exposed to the outside of the instrument panel when the player case 1 is attached to the instrument panel.

  The insertion port 10 passes through the outer wall of the outer case 8. The insertion slot 10 can pass CDs 2a and 2b and DVDs 4a and 4b inside. Through the insertion slot 10, the CDs 2 a and 2 b and the DVDs 4 a and 4 b are accommodated in or discharged from the outer case 8, that is, the device main body 3. That is, the insertion slot 10 allows the CDs 2a and 2b and the DVDs 4a and 4b to be inserted into and removed from the apparatus main body 3.

  Furthermore, a display panel 11 and various switches 12 are provided on the front surface 8a described above.

  The display panel 11 includes a display surface as a display area that is exposed to the front surface 8a and displays various types of information to the user. The display panel 11 displays information such as the name of the program being reproduced on the display surface.

  The various switches 12 constitute an operation unit for the user to operate. When the switch 12 is operated by a user or the like, for example, the programs of the CDs 2a and 2b and DVDs 4a and 4b to be played back by the clamp playback unit 6 and the insertion and removal of the CDs 2a and 2b and DVDs 4a and 4b are performed.

  As shown in FIG. 2 and the like, the chassis main body 9 is configured by attaching a plurality of bent sheet metals and the like to each other. As shown in FIG. 2, the chassis main body 9 includes a substantially flat bottom wall 13, a substantially flat ceiling wall 15 opposed to the bottom wall 13 with a space therebetween, and the bottom wall 13 and the ceiling wall 15. A plurality of continuous peripheral walls 14. Each of the walls 13, 14, 15 is provided with a plurality of openings for reducing the weight and securing the rigidity of the chassis body 9.

  The transport unit 5 includes a roller arm and a disc guide 17 that are disposed in the vicinity of the insertion slot 10 and that are provided so as to be able to contact and separate from each other. The roller arm includes a conveyance roller that is rotationally driven by a drive source such as a motor. The roller arm is rotatably supported on the bottom wall 13 around one edge, and the conveying roller is provided on the other edge. The roller arm is biased by a coil spring (not shown) in a direction in which the other edge, that is, the transport roller approaches the disk guide 17.

  The disk guide 17 is supported by the chassis body 9 so as to be slidable along the thickness direction Z.

  The roller arm and the disk guide 17 having the above-described configuration are provided so as to be able to contact and separate from each other, and the conveyance rollers are rotationally driven by a motor with the CDs 2a and 2b and the DVDs 4a and 4b sandwiched therebetween. Then, the CDs 2a and 2b and the DVDs 4a and 4b are taken in and out of the device main body 3.

  As shown in FIG. 2, the clamp reproduction unit 6 includes a carriage chassis (not shown) and a clamp arm 18. The carriage chassis includes a chassis main body made of sheet metal or the like, a turntable (not shown) attached to the chassis main body, and an optical pickup unit (not shown) attached to the chassis main body.

  The chassis main body is formed in a substantially flat plate shape. The turntable is formed in a disk shape and is rotatably supported by the chassis body. The turntable enters the center holes of the CDs 2a and 2b and the DVDs 4a and 4b. The turntable rotates the CDs 2a and 2b and the DVDs 4a and 4b by a driving force of a spindle motor attached to the chassis body. The optical pickup unit reads information from the CD 2 rotated by the turntable.

  The clamp arm 18 includes an arm main body 19 made of sheet metal or the like, and a clamper 25. The arm body 19 is formed in a substantially flat plate shape. The carriage chassis is supported by the chassis main body so as to be rotatable about an end portion away from the insertion port 10. The rotation center of the arm body 19 is parallel to the width direction X.

  The clamper 25 is arranged at a position facing the turntable. The clamper 25 is formed in a disc shape and is rotatably supported by the arm body 19. When the arm body 19 approaches the chassis body, the clamper 25 can sandwich the CDs 2a and 2b and the DVDs 4a and 4b with the turntable. Further, the carriage chassis and the clamp arm 18 of the clamp reproduction unit 6 are urged toward each other by an urging means such as a spring (not shown).

  The clamp reproducing unit 6 having the above-described configuration is supported in the chassis main body 9 so as to be movable with respect to the device main body 3 by a damper made of an elastic body such as rubber (not shown) and a coil spring. In the clamp reproduction unit 6, the clamp arm 18 and the carriage chassis are close to each other, and the CD 2a, 2b and DVD 4a, 4b are sandwiched between the turntable and the clamper 25 (that is, CD 2a, 2b, DVD 4a, 4b between each other). The CD 2a, 2b and DVD 4a, 4b are rotated by the turntable, and the information recorded on the CD 2a, 2b, DVD 4a, 4b is read by the optical pickup unit.

  In the interlocking mechanism, when the disk guide 17 of the transport unit 5 and the transport roller are separated from each other, the turntable of the carriage chassis of the clamp reproduction unit 6 and the clamper 25 approach each other, and the disk guide 17 of the transport unit 5 and the transport roller are When approaching each other, the transport unit 5 and the clamp reproduction unit 6 are interlocked so that the turntable of the carriage chassis of the clamp reproduction unit 6 and the clamper 25 are separated from each other.

  Further, the above-described interlocking mechanism makes the roller arm of the transport unit 5 and the disk guide 17 close to each other when transporting the CDs 2a, 2b and DVDs 4a, 4b into and out of the device main body 3, thereby bringing the carriage chassis of the clamp reproduction unit 6 into the carriage chassis. And the clamp arm 18 are kept away from each other. When the CD 2a, 2b, DVD 4a, 4b is inserted into the apparatus body 3, the interlocking mechanism brings the turntable and the clamper 25 close to each other and clamps the CD 2a, 2b, DVD 4a, 4b between them. The roller arm of the transport unit 5 and the disc guide 17 are moved away from each other.

  4 and 5, the determination unit 7 is mounted on the printed wiring board 20, one LD (laser diode) 21 as a light emitting element mounted on the printed wiring board 20, and the printed wiring board 20. And a single PD (photodiode) 22 as a light receiving element. The printed wiring board 20 includes an insulating substrate and a conductor pattern formed according to a predetermined pattern on the surface of the substrate. The printed wiring board 20 is fixed to the bottom wall 13 of the chassis body 9. The conductor pattern of the printed wiring board 20 is electrically connected to μCOM.

  As shown in FIG. 4, the LD 21 is relative to the one surface 2c, 4c of the large diameter CD 2a and the large diameter DVD 4a accommodated in the apparatus main body 3 and clamped by the clamp reproducing unit 6 along the thickness direction Z. In addition, as shown in FIG. 5, the surface of the adapter 16 of the small-diameter CD 2b and the small-diameter DVD 4b with the adapter 16 accommodated in the apparatus main body 3 and clamped by the clamp reproducing unit 6 is opposed in the thickness direction Z. Placed in position. The LD 21 emits laser light toward the one surface 2c, 4c and the surface of the adapter 16 along the thickness direction Z, that is, along the direction orthogonal to the one surface 2c, 2d, 4c, 4d. To do. In the illustrated example, the LD 21 emits laser light having a wavelength of 0.3 μm.

  Since the PD 22 is mounted on the printed wiring board 20, it is aligned with the LD 21 along one surface 2c, 2d, 4c, 4d of the CD 2a, 2b and the DVD 4a, 4b as the information recording surface described above. The PD 22 is arranged at a position where it can receive the diffracted light irradiated from the LD 21 toward one of the surfaces 2c and 4c of the large diameter CD 2a and the large diameter DVD 4a and reflected by the one surface 2c and 4c.

  In the illustrated example, as shown in FIG. 4, a line segment L (indicated by a one-dot chain line in FIG. 4) that connects the LD 21 and the LD 21 and a location K that opposes the one surface 2c, 4c along the thickness direction Z. PD22 is arranged at a position where an angle θ formed by a line segment M (shown by a one-dot chain line in FIG. 4) connecting PD22 and the portion K is 23 degrees. In the above-mentioned formula 1, in the large-diameter CD2a, when α is 0 degree, the order is 2, and the wavelength of the laser beam is 0.3 μm, β is about 23 degrees. In the large-diameter DVD 4a, the above-described α is 0. If the degree is 1 and the wavelength of the laser beam is 0.3 μm, β is about 23 degrees. That is, in the illustrated example, the PD 22 is disposed at a position where it can receive both the second-order diffracted light reflected from the large-diameter CD 2a and the first-order diffracted light reflected from the large-diameter DVD 4a. Thus, one PD 22 is arranged at a position where it can receive diffracted lights of different orders reflected from the information recording surfaces of different types of large-diameter optical disks.

  Further, the PD 22 is connected to the μCOM, and outputs to the μCOM whether or not the diffracted light described above has been received.

  The μCOM includes a central processing unit (CPU) that performs various processes according to a program, a ROM that is a read-only memory that stores a program for processes performed by the CPU, a work area that is used in various processes performed by the CPU, A RAM, which is a readable / writable memory having a data storage area for storing various data, is built in, and these are connected to each other by a bus line.

  The μCOM is connected to the transport unit 5, the clamp reproduction unit 6, and the interlocking mechanism according to the command input from the switch 12 and the output of the sensor that detects that the CDs 2 a and 2 b and DVDs 4 a and 4 b are inserted. These operations are controlled to control the entire player device 1.

  The above-described μCOM has a disk guide 17 in a state where none of the large diameter CD 2a, large diameter DVD 4a, small diameter CD 2b with adapter 16 and small diameter DVD 4b with adapter 16 is accommodated in the insertion port 10 in the apparatus body 3. And the roller arm are moved closer to each other, and the carriage chassis and the clamp arm 18 are moved away from each other. Furthermore, μCOM keeps the optical pickup unit closest to the turntable. When one of the large diameter CD 2a, the large diameter DVD 4a, the small diameter CD 2b with the adapter 16 and the small diameter DVD 4b with the adapter 16 is inserted into the insertion port 10, the μCOM is one of these sensors. Is detected, and the conveying roller is driven to rotate.

  Thereafter, the μCOM causes the clamp reproduction unit 6 to clamp any of the optical disks described above, and moves the disk guide 17 and the roller arm of the transport unit 5 away from each other. Then, μCOM emits laser light from the LD 21 of the determination unit 7 and determines whether or not the diffracted light of the PD 22 is received.

  At this time, if the large-diameter CD 2a or the large-diameter DVD 4a is accommodated in the device main body 3, the LD 21 moves along the thickness direction Z as shown in FIG. , 4c. The laser light emitted from the LD 21 along the arrow S1 in FIG. 4 is reflected by one of the surfaces 2c and 4c as the information recording surface and received by the PD 22 as diffracted light along the arrow J1 in FIG. Is done. Further, when the small-diameter CD 2b with the adapter 16 or the small-diameter DVD 4b with the adapter 16 is accommodated in the device body 3, the LD 21 is relative to the surface of the adapter 16 along the thickness direction Z as shown in FIG. is doing. Laser light emitted from the LD 21 along the arrow S2 in FIG. 5 is reflected by the surface of the adapter 16 along the arrow J2 in FIG. 5 and is not received by the PD 22.

  μCOM determines whether a large-diameter CD 2a or a large-diameter DVD 4a, a small-diameter CD 2b with an adapter, or a small-diameter DVD 4b with an adapter is accommodated in the device body 3 depending on whether or not the diffracted light from the PD 22 is received. To do. When the large-diameter CD 2a or the large-diameter DVD 4a is accommodated in the device body 3, the μCOM has the above-described large-diameter CD 2a or large-diameter so that the optical pickup portion faces the one surface 2c or 4c. It is moved along the radial direction of the diameter DVD 4a, and information is read out from these and reproduced. Further, when the small diameter CD 2b with an adapter or the small diameter DVD 4b with an adapter is accommodated in the apparatus main body 3, μCOM is opposed to one of these surfaces 2d and 4d and not to the surface of the adapter 16. As described above, while restricting the movement of the optical pickup unit, the optical pickup unit is moved along the radial direction of the small-diameter CD2b with an adapter or the small-diameter DVD 4b with an adapter, and information is read out and reproduced.

  According to the present embodiment, the PD 22 that receives the diffracted light reflected by the one surface 2c, 4c as the information recording surface of the large diameter CD 2a of the laser light from the LD 21 and the large diameter DVD 4a is arranged side by side with the LD 21. Yes. Further, the LD 21 is used to irradiate the adapter 16 of the small diameter CD 2b with the adapter 16 and the small diameter DVD 4b with the adapter 16 in the apparatus main body 3 with a laser beam and as an information recording surface of the large diameter CD 2a and the large diameter DVD 4a of the apparatus main body 3. It arrange | positions in the position which irradiates a laser beam to one surface 2c, 4c.

  For this reason, since there are no fine pits formed on one surface 2c, 4c, 2d, 4d of the CD 2a, 2b and the DVD 4a, 4b on the surface of the adapter 16, the small diameter CD 2b with the adapter 16 and the adapter 16 are attached. When the small-diameter DVD 4b is accommodated in the device body 3, the PD 22 cannot receive the laser light reflected by the surface of the adapter 16. Further, when the large diameter CD 2a and the large diameter DVD 4a are accommodated in the apparatus main body 3, the diffracted light of the laser light reflected by the one surface 2c, 4c of the large diameter CD 2a and the large diameter DVD 4a of the laser light from the LD 21 is changed. The PD 22 can reliably receive light. Therefore, depending on whether or not the PD 22 has received the diffracted light described above, the optical disk accommodated in the device main body 3 includes the small-diameter CD 2b with the adapter 16, the small-diameter DVD 4b with the adapter 16, the large-diameter CD 2a, and the large-diameter DVD 4a. Can be reliably identified.

  Furthermore, one PD 22 is arranged at a position where it can receive different orders of diffracted light from different types of large diameter CD 2a and large diameter DVD 4a. For this reason, a single PD 22 can handle a plurality of types of large-diameter CDs 2a and large-diameter DVDs 4a.

  In the above-described embodiment, the second-order diffracted light of the laser beam reflected by the one surface 2c of the large-diameter CD 2a and the first-order diffracted light of the laser beam reflected by the one surface 4c of the large-diameter DVD 4a. The PD 22 is arranged at a position where both can be received. However, in the present invention, the PD 22 may be disposed at a position where it can receive diffracted light of an arbitrary order reflected from the information recording surface of an optical disc of CD, DVD, or BD.

  In the present invention, as shown in FIG. 6, the PD 22 may be provided in correspondence with each type of optical disk accommodated in the apparatus main body 3. In FIG. 6, the same parts as those in the above-described embodiment are designated by the same reference numerals and the description thereof is omitted.

  In the example shown in FIG. 6, the PD 22 is provided corresponding to the large diameter CD 2a and receives the first-order diffracted light of the laser beam reflected by one surface 2c as the information recording surface of the large diameter CD 2a. PD22a, PD22b for PD22b that receives the first-order diffracted light of the laser beam that is provided corresponding to large-diameter DVD4a as PD22 and is reflected by one surface 4c as the information recording surface of the large-diameter DVD4a, and PD22 And a BD PD 22c that receives the first-order diffracted light of the laser light that is provided corresponding to the large diameter BD and reflected by the information recording surface of the large diameter BD.

  In the CD PD 22a, the angle θ1 formed by the line segment L of the line segment M1 connecting the CD PD 22a and the section K is 10 degrees, and the DVD PD 22b includes the DVD PD 22b and the section K. The angle θ2 formed by the connected line segment M2 and the line segment L is 23 degrees, and the BD PD 22c is formed by an angle θ3 formed by the line segment L connecting the BD PD 22c and the portion K with the line segment M3. Is arranged at a position of 70 degrees. As described above, in the example shown in FIG. 6, the PDs 22a, 22b, and 22c receive the diffracted light reflected from the information recording surface in different directions for each of the large diameter CD 2a, the large diameter DVD 4a, and the large diameter BD. A plurality of large diameter CDs 2a, large diameter DVDs, and large diameter BDs are provided.

  In this case, a plurality of PDs 22a, 22b, and 22c are provided corresponding to each of the large diameter CD 2a, the large diameter DVD 4a, and the large diameter BD accommodated in the device body 3, and the plurality of PDs 22a, 22b, and 22c are respectively corresponding large sizes. The diffracted light reflected by the information recording surfaces of the diameter CD2a, the large diameter DVD 4a and the large diameter BD is disposed at a position where it can be received. Therefore, even if the device can reproduce a plurality of types of CDs, DVDs, BDs, etc. by determining whether any of the plurality of PDs 22a, 22b, 22c has received the diffracted light described above. Thus, it is possible to reliably identify whether the CD, DVD, and BD accommodated in the device main body 3 are either the small-diameter optical disk or the large-diameter optical disk of the adapter 16. Further, in addition to being able to distinguish between a small-diameter optical disk with an adapter 16 and a large-diameter optical disk, μCOM identifies the PDs 22a, 22b, and 22c that have received diffracted light from among the plurality of PDs 22a, 22b, and 22c. It is also possible to identify the type of the large-diameter optical disk in the device body 3.

  According to the embodiment described above, the following player device 1 is obtained.

(Supplementary note) The adapter 16 is attached to the large diameter CD 2a and the large diameter DVD 4a, and the small diameter CD 2b and the small diameter DVD 4b smaller than the large diameter CD 2a and the large diameter DVD 4a, and the outer diameter is equal to the large diameter CD 2a and the large diameter DVD 4a. An apparatus main body 3 in which either one of the small-diameter CD 2b with the adapter 16 and the small-diameter DVD 4b is accommodated;
Both the adapter 16 of the small diameter CD 2b and the small diameter DVD 4b with the adapter 16 fixed to the apparatus main body 2 and accommodated in the apparatus main body 3, and one surface 2c, 4c of the large diameter CD 2a and the large diameter DVD 4a LD 21 provided at opposing positions and irradiating laser light toward them,
PD 22 that can receive the diffracted light of the laser beam that is aligned with the LD 21 and is irradiated from the LD 21 toward one surface 2c, 4c of the large-diameter CD 2a and the large-diameter DVD 4a;
A player apparatus 1 comprising:

  According to the supplementary note, the PD 22 that receives the diffracted light reflected by the one surface 2c, 4c as the information recording surface of the large diameter CD 2a of the laser light from the LD 21 and the large diameter DVD 4a is arranged side by side with the LD 21. Further, the LD 21 is used to irradiate the adapter 16 of the small diameter CD 2b with the adapter 16 and the small diameter DVD 4b with the adapter 16 in the apparatus main body 3 with a laser beam and as an information recording surface of the large diameter CD 2a and the large diameter DVD 4a of the apparatus main body 3. It arrange | positions in the position which irradiates a laser beam to one surface 2c, 4c.

  For this reason, since there are no fine pits formed on one surface 2c, 4c, 2d, 4d of the CD 2a, 2b and the DVD 4a, 4b on the surface of the adapter 16, the small diameter CD 2b with the adapter 16 and the adapter 16 are attached. When the small-diameter DVD 4b is accommodated in the device body 3, the PD 22 cannot receive the laser light reflected by the surface of the adapter 16. Further, when the large diameter CD 2a and the large diameter DVD 4a are accommodated in the apparatus main body 3, the diffracted light of the laser light reflected by the one surface 2c, 4c of the large diameter CD 2a and the large diameter DVD 4a of the laser light from the LD 21 is changed. The PD 22 can reliably receive light. Therefore, depending on whether or not the PD 22 has received the diffracted light described above, the optical disk accommodated in the apparatus main body 3 is divided into the small diameter CD 2b with the adapter 16, the small diameter DVD 4b with the adapter 16, the large diameter CD 2a, and the large diameter DVD 4a. Can be reliably identified.

  In addition, the Example mentioned above only showed the typical form of this invention, and this invention is not limited to an Example. That is, various modifications can be made without departing from the scope of the present invention.

It is a perspective view of the player apparatus concerning one Example of this invention. FIG. 2 is a perspective view showing a chassis main body, a clamp reproduction unit, and the like of the player device shown in FIG. 1. (A) is sectional drawing which follows the IIIA-IIIA line in FIG. 2, (a) is sectional drawing which follows the IIIB-IIIB line in FIG. FIG. 2 is a cross-sectional view schematically illustrating a determination unit, a large diameter CD, a large diameter DVD, and the like of the player device illustrated in FIG. 1. FIG. 2 is a cross-sectional view schematically illustrating a determination unit, a small-diameter CD with an adapter, a small-diameter DVD with an adapter, and the like of the player device illustrated in FIG. 1. FIG. 8 is a cross-sectional view schematically showing a determination unit, a large-diameter optical disc, and the like in a modified example of the player device shown in FIG. 1.

Explanation of symbols

1 Player device (optical disk device)
2a Large diameter CD (large diameter optical disc)
2b Small-diameter CD (small-diameter optical disc)
2c, 2d One surface (information recording surface)
3 Equipment body 4a Large diameter DVD (large diameter optical disk)
4b Small-diameter DVD (small-diameter optical disc)
4c, 4d One surface (information recording surface)
16 Adapter 21 LD (Light Emitting Element)
22 PD (light receiving element)
22a PD for CD
22b PD for DVD
22c PD for BD

Claims (3)

An apparatus main body that accommodates one of a large-diameter optical disk and a small-diameter optical disk with an adapter having an outer diameter equal to the large-diameter optical disk, with an adapter attached to an optical disk smaller in diameter than the large-diameter optical disk; ,
A small-diameter optical disk adapter with an adapter that is fixed to the apparatus main body and accommodated in the apparatus main body is provided at a position facing both the adapter and the information recording surface of the large-diameter optical disk. A light emitting element that emits laser light;
A light receiving element that can receive the diffracted light of the laser beam that is aligned with the light emitting element and is irradiated from the light emitting element toward the information recording surface of the large-diameter optical disc,
An optical disc apparatus comprising:   A plurality of the light receiving elements are provided corresponding to the types of the large-diameter optical discs so as to receive diffracted light reflected from the information recording surface in different directions for the types of the large-diameter optical discs. The optical disc apparatus according to claim 1.   2. The optical disc apparatus according to claim 1, wherein one of the light receiving elements is disposed at a position capable of receiving different orders of diffracted light from the different types of large-diameter optical discs.

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