JP2004335034A - Portable electronic apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a portable electronic apparatus equipped with a large display viewable of the whole still picture data, video data or the like at a time without scrolling the whole data. <P>SOLUTION: The portable electronic apparatus is equipped with: an apparatus main body 11 in which a loading part 13 to load a disk cartridge 2 and whose principal plane part has a roughly similar size to the principal plane of the disk cartridge 2; an optical pickup 13b which is provided in the apparatus main body and reads the information recorded on the disk cartridge 2; a reproduction processing part 138 which performs the reproduction processing of the information signal read out from the cartridge 2 loaded in the loading part 13 with the optical pickup 13b; a display part 14 which is provided over roughly the entire area of the principal plane part of the equipment main body and which displays the visible data whose signal is processed in the reproduction processing part 138 according to the operation of the pickup 13b; and an operating part 15 which inputs an operatiing signal relevant to the reproducing operation to the cartridge 2 loaded in the loading part 13. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention is directed to a portable device that reproduces an information signal recorded on a recording medium mounted on a mounting portion of an apparatus main body having substantially the same size as a recording medium and displays visible data corresponding to the reproduced information signal on a display unit. Electronic devices.
[0002]
[Prior art]
2. Description of the Related Art As a portable electronic device, there is a portable recording / reproducing apparatus that records an information signal on a recording medium or reproduces the information signal recorded on the recording medium. For example, a portable recording / reproducing apparatus of a disk cartridge using an optical disk as a recording medium has an apparatus main body whose one main surface is substantially the same size as the main surface of the disk cartridge, and in which the disk cartridge is mounted. The mounting part to be mounted, the optical pickup that irradiates the optical disk with the light beam and detects the reflected light beam, the magnetic head that applies a magnetic field to the optical disk, and controls the whole according to the input operation signal etc. A circuit board or the like in which a control circuit or the like is installed is provided. The apparatus main body is provided on its surface with a small display unit, an operation unit for performing a reproduction start operation, and the like, and further, a remote control device, earphones, headphones, and the like are connected by wires.
[0003]
Usually, audio data such as music data and text data such as a title of the recorded audio data are recorded on the optical disk of this disk cartridge.
[0004]
This disk cartridge recording / reproducing device rotates the optical disk when the disk cartridge is mounted on the mounting part and the reproduction start operation is performed, irradiates the rotating optical disk with the light beam, and detects the reflected light beam reflected back. Then, the information signal recorded on the optical disk is read out, and after performing the reproducing process, an audible sound is emitted from an earphone, a headphone or the like. The display unit displays the title, reproduction time, track number, and the like of the audio data being reproduced. Since this display section exclusively displays a small amount of text data related to the audio data being reproduced, there is no need to provide a particularly large display section. Therefore, a small display unit such as an LCD (Liquid Crystal Display) is provided on a part of the main surface of the device main body in order to reduce the size and weight of the device main body.
[0005]
[Problems to be solved by the invention]
By the way, in addition to audio data and text data related to the audio data, still image data, video data, and the like can be recorded on the disc cartridge, and further, programs such as game software can be recorded. It is.
[0006]
However, still image data and video data cannot be displayed on a small display unit provided in a portable recording and reproducing apparatus. In order to view the entire image on a small display unit, it is necessary to scroll the image, which is troublesome.
[0007]
Further, the game software or the like is expressed in a manner that produces a visual or audiovisual effect, and the video or image is selected and determined by a user's operation from a range of video or image prepared in advance, As with still image data and video data, a small display unit cannot display the entire image at once. In a small-sized recording / reproducing apparatus having a display unit, it is difficult for a user to view the entire image at once, and it is also difficult to make a selection and determination according to the progress of the game using the operation unit.
[0008]
The present invention has been made in view of the above-described problems, and its purpose is to provide a large display unit in the device main body, without scrolling the entire still image data or video data, etc. An object of the present invention is to provide a novel portable electronic device having a playback function that can be viewed at a time.
[0009]
Another object of the present invention is to provide a portable electronic device that can be easily operated while viewing still image data, video data, and the like.
[0010]
Still another object of the present invention is to provide a portable electronic device capable of reproducing a plurality of types of recording media on which information signals are recorded in different recording formats.
[0011]
It is a further object of the present invention to provide a portable electronic device that permits reproduction of only a specific type of recording medium when a similar recording medium exists.
[0012]
It is another object of the present invention to provide a portable electronic device capable of recording an information signal on a recording medium.
[0013]
[Means for Solving the Problems]
In order to solve the above-described problems, a portable electronic device according to the present invention is provided with a mounting portion on which a recording medium is mounted, and a device main body having a main surface having substantially the same size as the main surface of the recording medium; A reproducing unit provided on the main body and reading an information signal recorded on a recording medium mounted on the mounting unit; and a signal processing unit performing a reproducing process of the information signal read from the recording medium mounted on the mounting unit by the reproducing unit. A display unit which is provided over substantially the entire area of the main surface of the device main body and which displays visible data signal-processed by the signal processing unit in accordance with the operation of the reproduction unit; And an operation unit for inputting an operation signal related to the operation, so that a still image or a video displayed on the display unit can be viewed, and further, an operation can be performed while viewing the video or the like displayed on the display unit. Easy operation of parts Unisuru.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a recording / reproducing apparatus to which a portable electronic device according to the present invention is applied will be described with reference to the drawings.
[0015]
As shown in FIG. 1, a recording / reproducing apparatus 10 to which the present invention is applied can rotate a read-only optical disk having a pit pattern corresponding to a recorded information signal and a magneto-optical disk capable of recording an information signal. Is a portable device that uses the first and second disk cartridges 1 and 2 stored in the first and second disk cartridges 1 and 2 as recording media, and includes still image data, video data, programs, and the like stored in the first and second disk cartridges 1 and 2. Is a device that reproduces the information signal of FIG. For example, the first disk cartridge 1 includes a read-only optical disk having a standard recording density in which audio data and the like are recorded and a magneto-optical disk having a standard recording density in which desired audio data is recorded by a user. Used for recording media. The first disk cartridge 1 further includes a magneto-optical disk capable of recording information signals at a higher density than a conventional magneto-optical disk identified by an identification unit provided on the cartridge body, as a recording medium. Can be On the other hand, the second disk cartridge 2 has an insertion end into the recording / reproducing apparatus 1 formed in a substantially arc shape, and the first disk cartridge 1 and the insertion end side into the recording / reproducing apparatus 1 have the same shape. I'm different. In the second disk cartridge 2, information signals are recorded in a pit pattern at a higher density than a conventional read-only optical disk used for the first disk cartridge 1, and not only audio data and text data but also game software And other programs, video data, and still image data. The shape of the second disk cartridge 2 is changed from that of the existing first disk cartridge 1 so that the user can easily visually identify the type of recording medium. Hereinafter, the recording medium used for the first and second disk cartridges 1 and 2 is also simply referred to as an optical disk.
[0016]
The recording / reproducing device 10 is a device on which two types of first and second disc cartridges 1 and 2 having different shapes as described above can be mounted. For example, by reproducing the first disc cartridge 1, Audio data and the like can be heard, and further, by playing the second disk cartridge 2 on which still image data, video data, game software, etc. are recorded, a video or a still image displayed on the display unit is viewed. Can enjoy the game.
[0017]
The recording / reproducing apparatus 10 will be described with reference to FIG. The recording / reproducing apparatus 10 has an apparatus main body 11 in which at least one main surface 11a is formed slightly larger than the main surfaces of the first and second disk cartridges 1 and 2 serving as recording media and has a substantially rectangular shape as a whole. The apparatus main body 11 is provided with an insertion / removal opening 12 through which the first and second disk cartridges 1 and 2 are inserted / removed. Inside the apparatus main body 11, the first and second disk cartridges 1 inserted through the insertion / removal opening 12 are provided. , 2 are mounted, the first and second disk cartridges 1, 2 inserted from the insertion opening 12 are held, and the held first and second disk cartridges 1, 2 are mounted on the mounting portion 13. A holder or the like to be mounted is provided.
[0018]
The mounting portion 13 is provided with a plurality of positioning protrusions for positioning the first and second disk cartridges 1 and 2 in the vertical and horizontal directions with respect to the mounting portion 13. The mounting section 13 serves as a recording / reproducing section for performing recording / reproducing of the first and second disk cartridges 1 and 2 positioned and held by the positioning projections, and serves as a recording / reproducing section of the mounted first and second disk cartridges 1 and 2. A disk rotation drive mechanism 13a for rotating the optical disk, an optical pickup 13b for irradiating the optical disk with a light beam and detecting a return light beam reflected by the optical disk, a magnetic head 13c for applying a magnetic field to the optical disk when recording an information signal, etc. Are arranged. The disk rotation drive mechanism 13a includes a spindle motor as a drive source, a disk table provided on a spindle of the spindle motor, and a magnetic table for magnetically attracting a clamping plate provided at the center of the optical disk. The optical pickup 13b detects a semiconductor laser serving as a light source, an objective lens for condensing a light beam emitted from the semiconductor laser on a signal recording surface of the optical disc, and a returning light beam reflected on the signal recording face of the optical disc. It has a photodetector and the like. The optical pickup is moved in the radial direction of the optical disk by a sled mechanism driven by a motor. A magnetic head 13c is attached to this optical pickup so as to face the objective lens with the optical disk interposed therebetween.
[0019]
When the optical disk housed in the cartridge is rotated by the disk rotation drive mechanism 13a, the light beam emitted from the semiconductor laser from the optical pickup 13b is condensed and irradiated by the objective lens. The optical pickup 13b reproduces an information signal recorded on the optical disk by detecting a return light beam reflected by a signal recording surface of the optical disk with a photodetector, and also detects a tracking error signal, a focus error signal, and an address. Extract signals and the like. At the time of reproducing the information signal, the magnetic head 13c is separated from the optical disc, and decodes the RF signal detected by the photodetector of the optical pickup 13b, thereby transmitting information signals such as still image data, video data, and programs. It reproduces and displays it on the display unit, and converts still image data, video data, audio signals related to programs, audio data, and the like into audible sounds and outputs them. When recording an information signal, the magnetic head 13c is brought close to the optical disk, and a magnetic field is applied in accordance with the information signal to be recorded in a region heated by the light beam.
[0020]
One main surface portion 11a of the apparatus main body 11 is formed to be substantially the same size as the main surfaces of the first and second disk cartridges 1 and 2 as described above, and the display portion 14 is provided in almost the entire area. Is provided. The display unit 14 is formed of, for example, an LCD (Liquid Crystal Display). The display unit 14 displays text data such as the title of the audio data being reproduced when reproducing the audio data recorded on the first and second disk cartridges 1 and 2, and further displays still image data and video data. At the time of reproduction, a still image or video being reproduced is displayed, and when a program is being executed, a still image or video related to the program being executed is displayed. In particular, when the game software is being executed, a video or an image selected and determined by a user operation from a video or an image prepared in advance in the game software is displayed.
[0021]
An operation unit 15 for operating the apparatus main body 11 is provided near the display unit 14, for example, below the display unit 14. The operation unit 15 includes a cross key 15a formed of a push button and a plurality of round buttons 15b. These keys 15a and 15b are used, for example, according to the progress of the game when playing game software. The character displayed on the display unit 14 is moved up, down, left and right, and the progress of the game is selected and determined. Further, the apparatus main body 11 is provided with a reproduction start button, a recording start button, a recording / reproduction stop button, a menu selection button, and the like on a side surface or the like, not shown.
[0022]
A remote control device 16 for remotely controlling the device main body 11 is electrically connected to the device main body 11 by a cable 17. The remote operation device 16 is provided with an operation unit 16a for performing basic operations of the device main body 11, and includes, for example, a reproduction start button, a recording start button, a recording / reproduction stop button, and the like. Further, a rotation operation unit is provided as the operation unit 16a, and an operation such as a track jump can be performed. In the recording / reproducing apparatus 1, for example, when playing game software, by using these operation sections 16 a provided on the remote operation apparatus 16, for example, an image displayed on the display section 14 of the apparatus main body 11 can be displayed. An operation signal can be input while watching. The remote control device 16 is provided with a small display unit 16b. The small display unit 16b is constituted by, for example, an LCD (Liquid Crystal Display), and displays, for example, basic information such as a title, a reproduction time, and a track number when audio data is reproduced. The remote control device 16 may transmit and receive data to and from the device main body 11 wirelessly without using the cable 17.
[0023]
An earphone 18 serving as an electroacoustic transducer for outputting audio data as audible sound is further connected to the remote control device 16b via a cable 19. The user can listen to the audio data being reproduced by attaching the earphone 18 to the pinna. Note that, instead of the earphone 18, a headphone or the like may be used as the electroacoustic element. Further, the earphone 18 may be connected to the apparatus main body 11 wirelessly without using the cable 19, or may be directly connected to the apparatus main body 11 by the cable 19.
[0024]
The first disk cartridge 1 used in the recording / reproducing apparatus 1 configured as described above will be described. As shown in FIG. 3, the first disk cartridge 1 has a substantially rectangular shape formed by connecting a pair of upper and lower halves. A read-only optical disk having a cartridge main body 1a in which information signals such as audio data are recorded in a pit pattern at a standard recording density in the cartridge main body 1a, or recording audio data and the like at a standard recording density; Rewritable magneto-optical disk, a rewritable magneto-optical disk 3a capable of recording audio data, still image data, video data, and the like at a higher density than this magneto-optical disk (hereinafter, also simply referred to as first optical disk 3a) ) Is rotatably stored. The first optical disc 3a is provided with a clamping plate 4 at the center thereof, and the clamping plate 4 is magnetically attracted to a disc table constituting a disc rotation driving mechanism of the recording / reproducing apparatus 10, whereby the disc table is magnetically attracted. It is mounted in a state where centering is achieved.
[0025]
The cartridge body 1a having a substantially rectangular shape has recording and reproducing openings 5a and 5b provided at a substantially central portion of one side edge from a substantially central portion to one side edge. The recording / reproducing openings 5a and 5b expose a part of the signal recording area of the optical disk 2a to the outside in the radial direction. A magnetic head 13c serving as a recording section of the recording / reproducing apparatus 10 enters from the recording / reproducing opening 5a on the upper half side, and an optical pickup 13b from the recording / reproducing opening 5b on the lower half side. enter in. The cartridge main body 1a is provided with a central opening 6 at the approximate center of the lower half side, with the clamping plate 4 facing the outside and allowing the disk table to enter. When a read-only optical disk is stored in the cartridge main body 1a, a magnetic head for recording an information signal is not required, so that the upper half side recording / reproducing opening 5a is not provided. .
[0026]
A shutter member 7 for opening and closing the recording / reproducing openings 5a and 5b is attached to one side edge of the cartridge body 1a so as to be movable along the one side edge 1b. The shutter member 7 opens the recording and reproducing openings 5a and 5b only when the shutter member 7 is inserted into the recording and reproducing device 10, and closes the recording and reproducing openings 5a and 5b when not in use. Foreign matter such as dust does not adhere to the first optical disk 3a in the main body 1a.
[0027]
The first disk cartridge 1 configured as described above is inserted into the insertion / removal opening 12 of the recording / reproducing apparatus 10 from the other side edge 1c orthogonal to the one side edge 1b of the cartridge body 1a to which the shutter member 7 is attached. You. When the first disk cartridge 1 is inserted into the insertion / removal opening 12 of the recording / reproducing apparatus 10, the shutter member 7 is moved to one side of the cartridge main body in the same direction as the insertion direction of the first disk cartridge 1 into the recording / reproducing apparatus 10. It moves along the edge 1b to open the recording / reproducing openings 5a and 5b so that recording / reproduction is possible.
[0028]
Further, as shown in FIG. 4, the second disk cartridge 2 is formed to have substantially the same size as the first disk cartridge 1, and serves as an insertion end of the cartridge main body 2a into the insertion opening 12 of the recording / reproducing apparatus 10. Both sides of the other side edge 2c are chamfered to form a substantially circular arc. In the second disk cartridge 2, the same members as those of the above-described first disk cartridge 1 are denoted by the same reference numerals, and the details are omitted. As described above, in the cartridge body 2a having the other side edge 2c formed in a substantially arc shape, information signals are recorded in a pit pattern at a higher density than a conventional read-only optical disk. A read-only optical disk 3b on which programs such as still image data, video data, and game software are recorded is rotatably stored. The second disk cartridge 2 is inserted into the insertion opening 12 of the recording / reproducing apparatus 10 with the other side edge 2c formed in a substantially arc shape orthogonal to the one side edge 2b to which the shutter member 7 is attached as an insertion end. You. Since the second disk cartridge 2 uses the read-only optical disk 3b, a recording / reproducing opening 5a for the magnetic head 13c required for recording an information signal is not provided. However, only the recording / reproducing opening 5b for the optical pickup 13b is provided on the lower half side. For example, when a recordable magneto-optical disc is used as the optical disc 3b, and game software is recorded on this magneto-optical disc, an information signal related to the game, for example, save data indicating the progress of the game is transmitted to the magneto-optical disc. In order to enable recording on the disk, a recording / reproducing opening 5a for the magnetic head 13c may be provided on the upper half side.
[0029]
Next, the details of the optical disk used for the first disk cartridge 1 and the second disk cartridge 2 will be described.
[0030]
The first optical disk 3a used in the first disk cartridge 1 described here is a magneto-optical disk, and is a light-transmitting synthetic resin substrate such as a polycarbonate resin having a diameter of about 64 mm and a thickness of 1.2 mm. The groove pattern is transferred by injection molding or the like, a magneto-optical recording layer is formed on the surface of the disk substrate that is the synthetic resin substrate on which the groove pattern is formed, and a reflective layer is formed on the magneto-optical recording layer. Further, a protective layer is formed on this reflective layer, and an information signal is reproduced by irradiating a light beam from the disk substrate side, and a light beam is radiated from the disk substrate side, and an external magnetic field is applied from the protective layer side. Is applied to record an information signal. The groove patterns of these magneto-optical disks are provided in accordance with the absolute address (ADIP: Address in Pregroove).
[0031]
The first disk cartridge 1 includes, as recording media, a conventional magneto-optical disk having a standard recording density, a high-density recording magneto-optical disk 1 having a higher density than the magneto-optical disk, and a magneto-optical disk. A magneto-optical disk 2 having a higher density than that of No. 1 is used. These three types of magneto-optical disks are housed in a first disk cartridge 1 having substantially the same shape. For example, the optical disks housed by an identification unit constituted by a concave portion provided in the vicinity of a corner portion of the cartridge body 1a. The recording / reproducing device 10 can determine the type of the magnetic disk.
[0032]
As shown in FIG. 5, these three types of magneto-optical disks are used in the optical pickup 13b with the wavelength of the light beam used being 780 nm, the numerical aperture (NA) of the objective lens used in the optical pickup 3b being 0.45. The components of the semiconductor laser and the objective lens can be shared, and a common optical pickup 13b can be used.
[0033]
A magneto-optical disk having a standard recording density is compressed by ATRAC (Advanced Transform Acoustic Coding) or the like, and is subjected to error correction coding by ACIRC (Advanced Cross Interleaved Reed-Solomon Code) or the like, and EFM (Eighth to Metto to Futto). Has a recording capacity capable of recording audio data or the like modulated by the above for 74 minutes or 80 minutes. Specifically, a magneto-optical disk capable of recording 74 minutes of data has a recording capacity of about 160 MB, and a magneto-optical disk capable of recording 80 minutes of data has a recording capacity of about 180 MB. . A magneto-optical disk having a standard recording density realizes the above-mentioned recording capacity by setting the bit length to 0.6 μm, the shortest mark length to 0.85 μm, and the track pitch to 1.6 μm or 1.5 μm. ing. In the case of a magneto-optical disk having a standard recording density, the data transfer speed is 2.8 Mbps ／ 2.4 m / s.
[0034]
The high-density recording magneto-optical disk 1 is subjected to an error correction encoding process using an RS-LDC (Reed Solomon-Long Distance Code) with a BIS (Burst Indicator Subcode) having a higher correction capability, and is adapted to high-density recording. RLL (1-7) PP modulation method (RLL: Run Length Limited, PP: Parity reserve / Prohibit rmtr (repeat minimum transmission run length)) can record audio data or the like that can be recorded for 74 minutes or 80 minutes. Having. Specifically, a magneto-optical disk capable of recording 74 minutes of data has a recording capacity of about 284 MB, and a magneto-optical disk capable of recording 80 minutes of data has a recording capacity of about 308 MB. . The magneto-optical disk 1 for high-density recording achieves the above-mentioned recording capacity by setting the bit length to 0.44 μm, the shortest mark length to 0.58 μm, and the track pitch to 1.6 μm or 1.5 μm. I have. In the magneto-optical disk 1 for high-density recording, the data transfer speed is 4.37 Mbps＠2.4 m / s.
[0035]
Further, the magneto-optical disc 2 on which information signals are recorded at a higher density than the magneto-optical disc 1 for high-density recording is subjected to an error correction encoding process using a BIS-equipped RS-LDC or the like, which has a higher correction capability, and is recorded at a higher density Approximately 1 GB of data modulated by the RLL (1-7) PP modulation method or the like conforming to the standard can be recorded. The magneto-optical disk 2 for high-density recording achieves the above-mentioned recording capacity by setting the bit length to 0.16 μm, the shortest mark length to 0.21 μm, and the track pitch to 1.25 μm. The data transfer speed of the magneto-optical disk 2 for high-density recording is 9.83 Mbps＠1.98 m / s.
[0036]
The magneto-optical disk of standard recording density and the magneto-optical disk 1 of high-density recording are rotated at a CLV (Constant Linear Velocity) by a disk rotation driving mechanism. , ZCAV (Zone Constant Angular Velocity). Data is recorded on the magneto-optical disk 2 of high-density recording by a domain wall displacement type super-resolution reproduction method, so-called DWDD (Domain Wall Displacement Detection). Regarding any of the magneto-optical disks, any of CLV, ZCAV, CAV (Constant Angular Velocity), and ZCLV (Zone Constant Linear Velocity) can be adopted as the rotation method.
[0037]
Next, the optical disk 3b used for the second disk cartridge 2 will be described. The optical disk 3b is basically a read-only optical disk, and a pit pattern corresponding to data to be recorded on a light-transmitting synthetic resin substrate such as a polycarbonate resin is transferred by injection molding or the like. The information signal is reproduced by irradiating a light beam from one surface side.
[0038]
Specifically, as shown in FIG. 6, the optical disk 3b has a diameter of 64 mm and is formed in the same size as the above-described first optical disk 3a. It has become. The first optical disk 3a has specifications similar to those of a DVD (Digital Versatile Disc). That is, in the optical disc 3b, the wavelength of the light beam to be used is 650 nm, the numerical aperture (NA) of the objective lens used in the optical pickup 13b is 0.6, which is the same as the optical system of the DVD optical pickup.
[0039]
The recording area of the optical disc 3b is 16 to 30.5 mm. The optical disc 3b has one recording layer and two recording layers. The recording capacity of the one-layer optical disc is 1 GB, and the recording capacity of the two-layer optical disc is 2 GB. The track pitch is 0.74 μm, the linear density is 0.29 μm / bit, and the shortest mark length is 0.44 μm. The modulation method is EFMplus (8-16 modulation), and the error correction method is a Reed-Solomon Product Code (RS-PC). That is, in the optical disk 3b, other portions except for the disk diameter are determined to be substantially the same as the DVD.
[0040]
The first optical disc 3a includes video data compressed by MPEG (Moving Picture Coding Experts Group / Moving Picture Experts Group) 4 or the like, ATRAC3, ATRAC3pulss, PCM audio data, and program software such as game software. Be recorded.
[0041]
In this optical disk 3, the depth of the pit pattern is set to １ ／ λ to ６λ of the wavelength of the light beam to be used, so that the tracking error signal can be detected by the push-pull method. This is the same as the case of a read-only optical disk in which an information signal is recorded in a pit pattern which is one of the optical disks 3a of the disk cartridge 1.
[0042]
The optical disk 3b is formed by bonding two disk substrates. Specifically, as shown in FIG. 7, the optical disc 3b is formed by laminating a first substrate 31 and a second substrate 32 having optical transparency through an adhesive layer 33, and the recording layer is In the case of a single layer, a pit pattern corresponding to an information signal to be recorded on the surface of the first substrate 31 facing the second substrate 32 is transferred by injection molding or the like. A pit pattern corresponding to the information signal to be recorded on the surfaces of the first and second substrates 32 facing each other is transferred by injection molding or the like.
[0043]
Then, on the first substrate 31, a reflective film 31a is formed on the surface on which the pit pattern is formed. When a pit pattern is also formed on the second substrate 32, a reflection film 32a is formed on the surface on which the pit pattern is formed. The adhesive layer 33 has an optical structure such that the pit pattern of the first substrate 31 serving as the first recording layer and the pit pattern of the second substrate 32 serving as the second recording layer are not located within the depth of focus of the light beam. It is formed to a thickness that can be separated. Here, the reflection film 31a formed on the pit pattern of the first substrate 31 on the side of the light beam irradiation surface also irradiates the light beam to the pit pattern of the second substrate 32 as the second recording layer. Therefore, it has a predetermined light transmittance. The optical disc 3b on which the two substrates 31, 32 are bonded by the adhesive layer 33 serving as an intermediate layer is a recording medium for single-sided reading, and is irradiated with a light beam from the first substrate 31 side. The information signal recorded on the first substrate 31 by the pit pattern is read out by being focused on the pit pattern of the substrate 31 and reflected by the reflection film 31a and detecting this by the optical pickup 13b. The pit pattern of the second substrate 32 is read out by focusing the light beam transmitted through the first substrate 31 and the reflection film 31a on the pit pattern of the second substrate 32 by the objective lens 34 and reflecting the light beam by the reflection film 32a. This is performed by detecting the light beam transmitted through the reflection layer 31a and the first substrate 31 by the optical pickup 13b.
[0044]
The optical disk 3b is formed so as to have substantially the same thickness as the first optical disk 3a for compatibility with the above-mentioned first optical disk 3a. That is, since the thickness of the first optical disc 3a is approximately 1.2 mm, the optical disc 3b has the thickness t1 of the first substrate and the thickness t2 of the second substrate 32 of 0.5 ± 0. 0.02 mm, and the thickness of the adhesive layer 33 is 0.05 ± 0.01 mm. That is, in the optical disk 3b, the thickness of the first substrate 31 and the thickness of the second substrate 32 are set to 0.5 mm, and the entire thickness including the adhesive layer 33 is set to approximately 1.05 mm, and the thickness is reduced to 1.2 mm. I'm trying to get closer.
[0045]
The permissible range of the surface deviation of the optical disk 3b is ± 150 μm for the AC component and ± 200 μm including the DC component.
[0046]
The conventional DVD is formed by bonding two substrates having a thickness of 0.6 mm together. In the optical disk 3b, the first substrate 31 and the second substrate 32 have a thickness of 0.5 mm. The size of the optical pickup 13b is reduced. As shown in FIG. 8A, a conventional magneto-optical disk, which is one of the first optical disks 3a used in the first disk cartridge 1, has a total thickness t3 of 1. 2 mm. The wavelength of the light beam B1 used for the magneto-optical disk at this standard recording density is 780 nm as described above, and the numerical aperture of the objective lens 34 is 0.45. At this time, the depth of focus D1 when not passing through a standard recording density magneto-optical disk is 1.62 mm, and the working distance WD1, which is the distance between the objective lens 34 and the optical disk 3b, is 0.85 mm. .
[0047]
As shown in FIG. 8B, an optical disk 3b used in the second disk cartridge 2 has a thickness t2, t3 of each of the first substrate 31 and the second substrate 32 of 0.6 mm. is there. The optical pickup 13b used here emits a light source B1 having a wavelength of 780 nm corresponding to a standard magneto-optical disk and a light beam B2 having a wavelength of 650 nm corresponding to an optical disk 3b for high-density recording. A light source and an objective lens 34 having an aperture diaphragm hologram are further provided. The optical pickup 13b emits a light beam B1 having a wavelength of 780 nm when performing recording / reproduction on an optical disk having a standard recording density, and sets the numerical aperture of the objective lens 34 to 0.45 to thereby obtain a standard recording density. To the magneto-optical disk. When reproducing the optical disk 3b of high-density recording, the optical pickup 13b emits a light beam B2 having a wavelength of 650 nm, irradiates the optical disk 3b with a numerical aperture of the objective lens 34 of 0.6. In this case, the spots of the ± primary light are prevented from forming conjugate points on the front and back surfaces of the optical disc 3b in order to reliably detect a tracking error signal, a focus error signal, and the like. In FIG. 8B, the interval between the spots of the 0th order light and the ± 1st order light is 0.39 mm. When reproducing the optical disk 3b, the position of the objective lens 34 is separated from the optical disk 3b by a distance C1 (0.14 mm) from the reference line L indicating the position of the objective lens 34 in FIG. WD2 is 0.99 mm, which is farther from the optical disc 3b than in the case of FIG. Accordingly, the optical pickup corresponding to both the optical disk having the standard recording density shown in FIG. 8A and the optical disk 3b shown in FIG. 8B has a moving amount of the objective lens 34 in the optical axis direction. Must be increased, and it is difficult to reduce the size.
[0048]
The optical pickup 13b shown in FIG. 8C has only a light source that emits a light beam B1 having a wavelength of 780 nm corresponding to a standard magneto-optical disk, and has a wavelength of 650 nm corresponding to a high-density recording optical disk 3b. There is no light source for emitting the light beam B2. The optical pickup 13b includes an objective lens 34 having an aperture stop hologram. The optical pickup 13b emits a light beam B1 having a wavelength of 780 nm when performing recording and reproduction on an optical disk having a standard recording density, and sets the numerical aperture of the objective lens 34 to 0.45 to thereby form a light beam having a standard recording density. Irradiate the magnetic disk. The optical pickup 13b also emits a light beam B1 having a wavelength of 780 nm, sets the numerical aperture of the objective lens to 0.6, and irradiates the optical disk 3b when reproducing the high-density recorded optical disk 3b. .
[0049]
When reproducing the optical disk 3b, the position of the objective lens 34 is separated from the optical disk 3b by a distance C2 (0.39 mm) from the reference line L indicating the position of the objective lens 34 in FIG. The WD3 is 1.24 mm, which is farther from the optical disc 3b than in the case of FIGS. 8A and 8B. Therefore, an optical pickup corresponding to both the optical magnetic disk having the standard recording density shown in FIG. 8A and the optical disk 3b shown in FIG. 8C has a higher objective than the example shown in FIG. It is necessary to increase the amount of movement of the lens 34 in the optical axis direction, which makes it difficult to reduce the size.
[0050]
A light source that emits a light beam B1 having a wavelength of 780 nm corresponding to the standard magneto-optical disk shown in FIG. 8B and a light source that emits a light beam B2 having a wavelength of 650 nm corresponding to the high-density recording optical disk 3b; Further, the optical pickup 13b including the objective lens 34 having the aperture stop hologram includes a light source that emits a light beam B1 having a wavelength of 780 nm corresponding to the standard magneto-optical disk shown in FIG. Compared with the optical pickup 13b having the objective lens 34 having the aperture hologram, the amount of movement of the objective lens 34 in the optical axis direction can be reduced, but the standard recording density shown in FIG. The moving amount of the objective lens 34 in the optical axis direction is larger than that of the optical pickup 13b used for the magneto-optical disk.
[0051]
Therefore, in FIG. 8D, the thicknesses t1 and t2 of the first substrate 31 and the second substrate 32 constituting the optical disc 3b are set to approximately 0.5 mm as described above, and are shown in FIG. A light source that emits a light beam B1 having a wavelength of 780 nm corresponding to a standard magneto-optical disk, a light source that emits a light beam B2 having a wavelength of 650 nm corresponding to an optical disk 3b of high density recording, and an aperture stop hologram. The optical pickup 13b having the objective lens 34 is used. Then, when reproducing the optical disk 3b, the position of the objective lens 34 is separated from the optical disk 3b by a distance C3 (0.04 mm) from the reference line L indicating the position of the objective lens 34 in FIG. Therefore, the working distance WD4 can be set to 0.89 mm, the moving amount of the objective lens 34 in the optical axis direction is made smaller than in the case of FIG. 8B, and the size of the optical pickup 13b is reduced. Can be. In addition, if the thickness t1 of the first substrate 31 on the objective lens 34 side is 0.5 mm, the thickness t2 of the second substrate 32 is 0.6 mm. Good.
[0052]
The first optical disk 3a used for the first disk cartridge 1 has a thickness of approximately 1.2 mm, and the optical disk 3b used for the second disk cartridge 2 has a thickness of approximately 1.05 mm. Yes, different in thickness. When the disk rotation drive mechanism 13a of the recording / reproducing apparatus 10 is shared by the two first and second disk cartridges 1 and 2, the rotating position of the rotating first and second optical disks 3a and 3b in the height direction is determined. Must be the same.
[0053]
Here, FIG. 9A is a cross-sectional view of a main part of the first disk cartridge 1. The first optical disk 3a has a center hole 43a at the center thereof, which is engaged with a centering portion 42 protruding from the center of a disk table 41 constituting the disk rotation driving mechanism 13a. Is a reference surface 45a supported by a disk support portion 44 provided around the centering portion 42.
[0054]
FIG. 9B is a sectional view of a main part of the second disk cartridge 2. As shown in FIG. 9B, since the optical disk 3b is formed thinner than the first optical disk 3a, the position when the optical disk 3b is mounted on the disk table 41 is higher than when the first optical disk 3a is mounted. Will also be lower. Therefore, in the optical disc 3b, the periphery of the center hole 43b in which the centering portion 42 is engaged is formed particularly thick, and the height of the reference surfaces 45a and 45b is made equal to that of the first optical disc 3a, and the rotation in the height direction is performed. The position is the same. That is, the entire optical disc 3b is formed by bonding the first substrate 31 and the second substrate 32 each having a thickness of 0.5 mm via the adhesive layer 33 having a thickness of 0.5 mm to 1.05 mm. 2 mm thinner than the first optical disc 3a. Therefore, each of the substrates 31 and 32 of the optical disk 3b is formed thick so that the thickness around the center hole 43b is 1.2 mm, which is the same as that of the first optical disk 3a. Thus, when the center hole 43b is engaged with the centering portion 42 of the disk table 41, the clamping plate 4 is magnetically attracted, and the reference surface 45b is supported by the disk support portion 44, the first optical disk 3a Is supported by the disk table 41 at the same height.
[0055]
Further, as shown in FIGS. 9 (A) and 9 (B), the first and second optical discs 3a, 3b rotatably housed in the cartridge main bodies 1a, 2a are used to suppress rattling. Disc holding portions 46a, 46b, 47a, 47b are provided. The disc holding portions 46a, 46b provided on the inner surfaces of the upper halves constituting the cartridge main bodies 1a, 2a are rotatably supported by the disc table 41 at the same height as the first and second optical discs 3a, 3b. The first and second optical disks 3a and 3b are formed at the same height at positions corresponding to the inner-side non-signal recording areas. The disc holding portions 47a and 47b provided on the inner surfaces of the lower halves constituting the cartridge main bodies 1a and 2a have the first and second optical discs because the optical disc 3b is formed thinner than the first optical disc 3a. The disc pressing portion 47b of the cartridge main body 2a is formed higher than the disc pressing portion 47a of the cartridge main body 1a at a position corresponding to the inner peripheral non-signal recording area of 3a, 3b. In the cartridge main body 2a, the lower half side disk pressing portion 47b is made higher as the optical disk 3b becomes thinner, thereby suppressing the play of the optical disk 3b when not in use.
[0056]
The cartridge main bodies 1 a and 2 a are provided with a plurality of positioning projections 48 for positioning the cartridge main body 1 a in the mounting section 13 in the vertical and horizontal directions when mounted on the mounting section 13.
[0057]
Here, the circuit configuration of the recording / reproducing apparatus 10 for recording / reproducing the first and second disk cartridges 1 and 2 as described above will be described. As shown in FIG. And a recording / reproducing section 102 for recording / reproducing the first and second disk cartridges 1 and 2. The system control section 101 and the recording / reproducing section 102 are independent integrated circuits. It is composed of circuit chips.
[0058]
The system control unit 101 includes an input / output interface (hereinafter, simply referred to as an input / output I / F) 111 connected to an external device, an audio processor 112 for converting audio data into audible sound, and an audio processor. A RAM (Random Access Memory) 113 to which data to be processed in 112 is temporarily loaded is connected to each other by a first bus 114 such as an SSBUS (Slow System Bus). The input / output I / F 111 is connected to an operation device such as a keyboard and a joystick externally connected to the operation unit 15, and is further connected to an IC card for storing game save data and the like. The audio processor 112 is connected to an electroacoustic transducer such as the earphone 18 described above. The first bus 114 is connected to the recording / reproducing unit 102 for recording / reproducing the first and second disk cartridges 1 and 2.
[0059]
In addition, the system control unit 101 includes a main CPU (Central Processing Unit) 115 that controls the entire operation and a work RAM 116 into which data processed by the main CPU 115 is temporarily loaded, such as a local bus (Local Bus). It is connected by two buses 117. The first bus 114 and the second bus 117 are connected by a bridge circuit 119.
[0060]
Further, the system control unit 101 includes an MPEG decoder 119 for decoding the compressed video data recorded on the optical disc 3b of the second disc cartridge 2, and a USB interface for connecting an external device with a USB (Universal Serial Bus). (Hereinafter, simply referred to as a USB I / F) 120 for connection to a GPU (Graphics Processing Unit) that controls display of video data and the like displayed on the display unit 14 provided on one main surface 11a of the apparatus main body 11. (Hereinafter simply referred to as GPU I / F) 121 is connected by a third bus 122 such as an AHB (Advanced High-Performance Bus). The second bus 117 and the third bus 122 are connected by a bridge circuit 123. The MPEG decoder 119 decodes MPEG4 compressed video data from the optical disk 3b of the second disk cartridge 2. The GPU I / F 121 is connected to a GPU 124, and the GPU 124 is connected to a graphical RAM 125 into which display data is temporarily loaded. The display data processed by the GPU 124 is displayed on the display unit 14 configured by an LCD driven by the LCD driver 125.
[0061]
Next, a circuit configuration of the recording / reproducing unit 102 included in the recording / reproducing apparatus 10 will be described with reference to FIG. The recording / reproducing unit 102 includes a disk table 41 on which first and second optical disks 3a and 3b of the first and second disk cartridges 1 and 2 are mounted on a spindle, and the first and second optical disks 3a and 3b. 3b, a spindle motor 131 serving as a rotation drive source, a function generator 132 for detecting rotation speeds of the first and second optical discs 3a and 3b to be rotated, and a light beam for the first and second rotating optical discs 3a and 3b. An optical pickup 13b for irradiating a beam and detecting a reflected light beam reflected therefrom, and a magnetic head 13c for applying a magnetic field corresponding to recording data to the first and second optical disks 3a and 3b when recording an information signal. A sled mechanism 133 for moving the optical pickup 13b in the radial direction of the first and second optical disks 3a and 3b; Includes a laser driver 134 for driving a semiconductor laser which emits a built-in light beam in the optical pickup 13b, and an RF amplifier 135 to the detected light beam by the photodetector of the optical pickup 13b photoelectrically converted and amplified.
[0062]
The recording / reproducing section 102 is used as a reproducing system for a rewritable magneto-optical disc having a standard recording density, which is one of the first optical discs 3a housed in the first disc cartridge 1, or an optical disc dedicated for reproduction. A first reproduction processing unit 136 for reproducing the recorded information signal and a high-density magneto-optical disk 1 or 2 which is a first optical disk 3a housed in the first disk cartridge 1 are recorded. A second reproduction processing unit 137 for reproducing information signals; a third reproduction processing unit 138 for reproducing information signals recorded on the reproduction-only optical disk 3b stored in the second disk cartridge 2; , A first playback processing unit 136, a second playback processing unit 137, and a playback selector 139 that can selectively output playback data strings of the third playback processing unit 138.
[0063]
Further, the recording / reproducing unit 102 serves as a recording system when recording an information signal on a magneto-optical disk having a standard recording density, which is one of the first optical disks 3a housed in the first disk cartridge 1. When recording information signals on the first recording processing unit 140 that performs recording processing on the optical disk 1 and the high-density recording magneto-optical disks 1 and 2 that are the first optical disk 3a housed in the first disk cartridge 1 A second recording processing unit 141 that performs recording processing on recording data, a recording selector 142 that switches the output from the first recording processing unit 140 and the second recording processing unit 142, and a magnetic device that drives the magnetic head 13c And a head driver 143.
[0064]
Further, the recording / reproducing unit 102 stores an ADIP demodulation unit 144 for demodulating an ADIP address signal, a servo circuit 145 for performing focusing servo control, tracking servo control, and the like of the objective lens 34, and temporarily stores data to be recorded and reproduced. It includes a data buffer 146, a copyright protection circuit 147 for protecting the copyright of information signals recorded on the first and second optical disks 3a and 3b, and a system controller 148 for controlling the entire operation. .
[0065]
In the spindle motor 131, a disk table 41 constituting the disk rotation drive mechanism 13a is integrally attached to a spindle of the spindle motor 131, and the first and second optical disks 3a, 3a, which are mounted in a state where centering is achieved by the disk table. 3b is rotated at CLV or ZCAV as described above. Specifically, the spindle motor 131 rotates the CLV of a magneto-optical disk having a standard recording density and a read-only optical disk 3b for high-density recording, which are one of the first optical disks 3a, and is a first optical disk 3a. The magneto-optical disks 1 and 2 for high-density recording are rotated at ZCAV. The rotation speeds of the first and second optical disks 3a and 3b are detected by the function generator 132.
[0066]
The optical pickup 13b is provided at a position facing the recording surfaces of the first and second optical disks 3a and 3b. The optical pickup 13b has a semiconductor laser 151 for irradiating a recording surface of the first and second optical disks 3a, 3b with a light beam as a laser beam during recording and reproduction. The semiconductor laser 151 outputs a high-level light beam for heating a recording track to the Curie temperature during recording, and a relatively low-level light beam for detecting data from reflected light by the magnetic Kerr effect during reproduction. Is output. The output level of the semiconductor laser 151 is controlled by the laser driver 134. The optical pickup 13b has an optical system such as a polarizing beam splitter 152 and an objective lens 34 for irradiating the first and second optical disks 3a and 3b with a light beam and detecting reflected light. The optical pickup 13b has a photodetector 153 for detecting the amount of reflected light from the first and second optical disks 3a and 3b.
[0067]
The optical pickup 13b has two directions: a direction perpendicular to the recording tracks of the first and second optical disks 3a and 3b, and a direction approaching or separating from the first and second optical disks 3a and 3b. A biaxial actuator 154 serving as an objective lens driving mechanism for movably holding the objective lens 34 is provided. The optical pickup 13b moves the position of the light beam spot in the same direction by moving the objective lens 43 in a direction orthogonal to the recording tracks of the first and second optical disks 3a and 3b by the biaxial actuator 154. And performs tracking control. Further, the optical pickup 13b moves the objective lens 43 in a direction approaching or moving away from the first and second optical discs 3a and 3b by the biaxial actuator 154, so that the focus positions of the light beams are shifted to the first and second optical discs. Focusing control is performed to move the focus position of the light beam away from or closer to the recording surfaces of the two optical disks 3a and 3b and to match the focal positions of the light beams with the recording surfaces of the first and second optical disks 3a and 3b.
[0068]
The magnetic head 13c is provided at a position facing the objective lens 34 of the optical pickup 13b with the first and second optical disks 3a and 3b interposed therebetween. The magnetic head 13c applies a magnetic field modulated by recording data to the first optical disc 3a during recording. That is, the first optical disk 3a used for the first disk cartridge 1 is a magneto-optical disk. When recording an information signal on this magneto-optical disk, the first optical disk 3a comes close to the magneto-optical disk, and A corresponding magnetic field is applied to the magneto-optical disk. Note that the optical disk 3b used for the second disk cartridge 2 is a read-only optical disk on which an information signal is recorded in a pit pattern, so that the magnetic head 13b is not used. Also, it is not used at the time of reproducing the magneto-optical disk constituting the first optical disk 3a of the first disk cartridge 1. Therefore, when not in use, the magnetic head 13c is moved to a position separated from the first and second optical disks 3a and 3b by a lifting mechanism of the magnetic head 13c (not shown).
[0069]
When recording data, the optical pickup 13b and the magnetic head 13c emit a high-level light beam to heat the recording track to the Curie temperature, and apply a magnetic field modulated according to the recording data to the first optical disk 3a. Is applied to a magneto-optical disk to change the light reflection characteristics of the magneto-optical disk, thereby recording data. When reproducing data, the optical pickup 13b irradiates a target track with a low-level light beam that does not heat the Curie temperature, and detects characteristics changed by the magnetic Kerr effect from the reflected light of the irradiated light beam. Thus, the data is reproduced. The thread mechanism 133 moves both the optical pickup 13b and the magnetic head 13c in the disk radial direction. By moving the optical pickup 13b and the magnetic head 13c in the radial direction of the first and second optical disks 3a and 3b, the thread mechanism 133 performs recording or reproduction within the field of view of the objective lens 34 in the optical pickup 13b. Position the track to be performed.
[0070]
The laser driver 134 drives the semiconductor laser 151, controls the output by APC (Automatic Laser Power Control) or the like, switches the output level between recording and reproduction of the first and second optical disks 3a and 3b, and The semiconductor laser 151 stably emits a light beam having a predetermined output.
[0071]
A photocurrent signal according to the reflected light from the first and second optical disks 3a and 3b detected by the photodetector 153 of the optical pickup 13b is input to the RF amplifier 135. The RF amplifier 135 performs current-voltage conversion, amplification processing, matrix calculation processing, and the like on the input photocurrent signal, and performs a reproduction signal (RF signal), a tracking error signal (TE signal), and a focus error signal (FE). Signal), an address signal (ADIP signal) and a visual field signal, and output these signals.
[0072]
The RF signal is a signal indicating data recorded on the first and second optical disks 3a and 3b. The RF signal of the first optical disk 3a on which the magneto-optical recording has been performed is generated based on the difference in the amount of light before and after the light beam in the recording direction in the spot. An information signal in which data is recorded in a pit pattern is generated based on a light amount difference based on the presence or absence of a pit.
[0073]
The TE signal is a signal indicating the amount of positional deviation of the position of the spot of the light beam from the recording track in a direction orthogonal to the recording track. The TE signals of the first and second optical disks 3a and 3b on which recording tracks are formed by grooves, lands, or pit patterns are generated by calculating the difference in light amount between the edge components of the recording tracks. For example, the TE signal is generated by a push-pull method.
[0074]
The FE signal is a signal indicating the amount of displacement between the disk recording surface and the focal position of the light beam. The FE signal is generated by, for example, a method called astigmatism method. When the FE signal is generated by the astigmatism method, a lens that causes astigmatism is provided in the optical system of the optical pickup 13b. When such a lens is provided, when the light beam is reflected at a position other than the focal position, the spot shape becomes an ellipse instead of a perfect circle. Further, the major axis of the ellipse is shifted by 90 ° between the case where the light beam is reflected before the focal position and the case where the light beam is reflected after the focal position. Therefore, when the FE signal is generated by the astigmatism method, the spot of the light beam may be divided into four parts in the upper, lower, left, and right directions, and the diagonal light amount difference may be detected.
[0075]
The ADIP signal is a signal indicating the physical address of the track being recorded or reproduced. Address information is modulated on the wobble component of the recording track on the first optical disc 3a. Therefore, the ADIP signal is generated based on the signal component (push-pull signal) of the fluctuation of the spot of the light beam in the disk radial direction.
[0076]
The visual field signal is a signal indicating how much the position of the objective lens 34 deviates from the center position of the visual field. The center position of the field of view is the position of the objective lens 34 when the two-axis actuator 154 is not driven. The displacement of the objective lens 34 in the direction orthogonal to the recording track occurs while the tracking servo control is being performed, and further appears in the low frequency component of the push-pull signal. Therefore, the view signal is generated by performing low-pass filtering on the push-pull signal.
[0077]
The first reproduction processing section 136 is a part of the first optical disk 3a housed in the first disk cartridge 1 and is a standard recording density magneto-optical disk or a read-only optical disk. Perform playback processing. More specifically, the first reproduction processing unit 136 plays a part in reproducing a standard recording density magneto-optical disk or a read-only optical disk which is one of the first optical disks 3a stored in the first disk cartridge 1. The RF signal output from the RF amplifier 135 is input. The first reproduction processing unit 136 has a comparator 136a, a PLL circuit 136b, an EFM demodulation circuit 136c, and an ACIRC decode circuit 136d. The input RF signal is clock-regenerated and binarized by a comparator 136a and a PLL circuit 136b, and then EFM demodulated by an EFM demodulation circuit 136c. The data sequence of the reproduced signal subjected to the EFM demodulation is subjected to an error correction process and a deinterleave process by an ACIRC decoding circuit 136d.
[0078]
The second reproduction processing unit 137 operates at the time of reproducing the high-density recorded magneto-optical disks 1 and 2 of the first optical disk 3a used for the first disk cartridge 1. The second reproduction processing unit 137 receives the RF signal output from the RF amplifier 135 when reproducing the high-density recorded magneto-optical disks 1 and 2. The second reproduction processing unit 137 includes an A / D converter 137a, an equalizer 137b, a PLL circuit 137c, a Viterbi decoding circuit 137d, a 1-7PP demodulation circuit 137e, and an RS-LDC decoding circuit 137f. I have. The input RF signal is clock-regenerated and binarized by an A / D converter 137a, an equalizer 137b, and a PLL circuit 137c, and then Viterbi-decoded by a Viterbi decoding circuit 137d. The data sequence of the Viterbi-decoded reproduced signal is subjected to RLL (1-7) demodulation by a 1-7PP demodulation circuit 137e, and error correction and deinterleave processing by an RS-LDC decoding circuit 137f.
[0079]
The third reproduction processing unit 138 performs a reproduction process of the information signal recorded on the optical disk 3b stored in the second disk cartridge 2. Specifically, the third reproduction processing unit 138 includes a comparator 138a, a PLL circuit 138b, an EFMplus demodulation circuit 138c, and an RS-PC decoding circuit 138d. After the input RF signal is clock-regenerated and binarized by the comparator 138a and the PLL circuit 138b, the EFMplus demodulation circuit 138c demodulates the 16-bit data sequence into an 8-bit data sequence. The data sequence of the reproduced signal demodulated by EFMplus is subjected to error correction processing and deinterleaving processing by the RS-PC decoding circuit 138d.
[0080]
The reproduction selector 139 selectively connects the first reproduction processing unit 136, the second reproduction processing unit 137, and the third reproduction processing unit 138 to the data buffer 146. Specifically, the reproduction selector 139 is connected to the ACIRC decoding circuit 136d when reproducing a standard recording density magneto-optical disk, which is one of the first optical disks 3a housed in the first disk cartridge 1. Terminal 139a connected to the terminal 139d connected to the data buffer 146. When reproducing the high-density magneto-optical disks 1 and 2 of the first optical disk 3a used for the first disk cartridge 1, the reproduction selector 139 is connected to the terminal 139b connected to the RS-LDC decoding circuit 137f. The terminal 139d connected to the data buffer 146 is connected. Further, the reproduction selector 139 connects the terminal 139c connected to the RS-PC decoding circuit 138d and the terminal 139d connected to the data buffer 146 when reproducing the optical disk 3b stored in the second disk cartridge 2. I do.
[0081]
The first recording processing unit 140 outputs an output signal from the data buffer 146 when recording an information signal on a magneto-optical disk having a standard recording density, which is one of the first optical disks 3 a housed in the first disk cartridge 1. A recording data string to be input is input. The first recording processing unit 140 has an ACIRC encoding circuit 140a and an EFM modulation circuit 140b. The input recording data sequence is subjected to interlib processing and an error correction code by an ACIRC encoding circuit 140a, and is subjected to EFM modulation by an EFM modulation circuit 140b.
[0082]
When recording an information signal on the high-density magneto-optical disks 1 and 2 of the first optical disk 3 a used for the first disk cartridge 1, the second recording processing unit 141 outputs the recording data output from the data buffer 146. A column is entered. The second recording processing unit 141 has an RS-LDC encoding circuit 141a and a 1-7PP modulation circuit 141b. The input recording data sequence is subjected to interleaving and convolutional encoding by the RS-LDC encoding circuit 141a, and is subjected to RLL (1-7) modulation by the 1-7PP modulation circuit 141b.
[0083]
The recording selector 142 switches the output from the first recording processing unit 140 and the second recording processing unit 142 to the magnetic head driver 143. Specifically, when recording an information signal on a magneto-optical disk having a standard recording density, which is one of the first optical disks 3a housed in the first disk cartridge 1, the recording selector 142 controls the EFM modulation circuit 140b. The connected terminal 142a and the terminal 142c connected to the magnetic head driver 143 are connected. When recording information signals on the high-density magneto-optical disks 1 and 2 of the first optical disk 3a used for the first disk cartridge 1, the recording selector 142 is connected to a terminal connected to the 1-7PP modulation circuit 141b. 142b and the terminal 142c connected to the magnetic head driver 143 are connected.
[0084]
The magnetic head driver 143 drives the magnetic head 13c according to the input recording data, and causes the magnetic head 13c to apply a magnetic field modulated according to the recording data to the disk D.
[0085]
The ADIP demodulation unit 144 receives the ADIP signal output from the RF amplifier 135. ADIP demodulation section 144 performs band limitation on the ADIP signal with a band-pass filter to extract a wobble component, and then performs FM demodulation and biphase demodulation to demodulate the ADIP address signal. The ADIP demodulator 144 decodes the absolute addresses of the recording tracks of the first and second optical discs 3a and 3b from the demodulated ADIP address signals when recording or reproducing the first and second optical discs 3a and 3b. The decoded absolute address is supplied to the system controller 148.
[0086]
The servo circuit 145 drives the biaxial actuator 154 based on the focus error signal (FE signal) output from the RF amplifier 135 to move the focal position of the light beam closer to the first and second optical disks 3a and 3b. Focusing servo control for moving in the direction of separation is performed. Specifically, the servo circuit 145 drives the two-axis actuator 154 by forming a servo loop in which negative feedback is formed so that the FE signal becomes 0. Further, the servo circuit 145 drives the biaxial actuator 154 based on the tracking error signal (TE signal) output from the RF amplifier 135 to record the irradiation position of the light beam on the first and second optical disks 3a and 3b. A tracking servo control for moving in a direction perpendicular to the track is performed. Specifically, the servo circuit 145 drives a two-axis actuator 154 by forming a servo loop in which negative feedback is formed so that the TE signal becomes 0.
[0087]
The servo circuit 145 targets the first and second optical disks 3a and 3b based on the target rotation speed calculated from the address information of the track being recorded or reproduced and the rotation speed detected by the function generator 132. The spindle motor 131 is driven so as to reach the rotation speed.
[0088]
The servo circuit 145 drives the sled mechanism 133 based on a sled drive instruction given from the system controller 148, and moves the optical pickup 13b and the magnetic head 13c in a predetermined direction.
[0089]
The data buffer 146 stores data exchanged with a host device such as a computer connected to the recording / reproducing device 10. The data buffer 146 stores data reproduced from the first and second optical disks 3a and 3b, data to be recorded on the first and second optical disks 3a and 3b, and various control data.
[0090]
The copyright protection circuit 147 protects the copyright from the RF signal generated by the RF amplifier 135 when copying information signals recorded on the first and second optical disks 3a and 3b onto another recording medium. Information is extracted, and copying or the like is permitted or prohibited based on the extracted copyright protection information. The copyright protection circuit 147 extracts a copyright protection code such as SCMS (Serial Copy Management System) and CGMS (Copy Generation Management System), and permits or prohibits copying based on the extracted code. Further, the copyright protection circuit 147 decodes the data to be reproduced when the data to be reproduced is protected by CSS (Content Scrambling System), DTCP (Digital Transmission Content Protection), or the like. Further, the copyright protection circuit 147 extracts a regional code or the like, and permits or prohibits reproduction or the like based on the extracted code.
[0091]
The system controller 148 controls the entire recording / reproducing unit 102. The system controller 148 controls switching of the power of the light beam of the semiconductor laser 151 between recording and reproduction, for example, and switches between using a reproduction-related circuit and a recording-related circuit. . Further, the system controller 148 controls switching of the reproduction selector 139 and the recording selector 142 in accordance with the type of the optical disc. Further, the system controller 148 monitors the visual field signal and controls the driving of the sled mechanism 133.
[0092]
Next, the overall operation of the recording / reproducing apparatus 10 configured as described above will be described. As shown in FIG. 2, the first disk cartridge 1 using the first optical disk 3a as a recording medium or the second disk cartridge 2 using the second optical disk 3b as a recording medium is provided on the other side of the cartridge main bodies 1a and 2a. With the edges 1 c and 2 c as insertion ends, the device is inserted through the insertion opening 12 of the apparatus main body 11. When the first and second disk cartridges 1 and 2 are inserted through the insertion / removal opening 12 of the apparatus main body 11, they are held by a holder built in the apparatus main body 11 and provided on a base built in the apparatus main body 11. The mounting portion 13 is mounted. At this time, the first and second disk cartridges 1 and 2 are positioned with respect to the mounting portion 13 by the positioning projections provided on the mounting portion 13 engaging with the positioning recesses provided on the cartridge main bodies 1a and 2a. It is mounted in a state where it is positioned vertically and horizontally. When the shutter member 7 of the first and second disk cartridges 1 and 2 is mounted on the mounting portion 13, the shutter member 7 slides along one side edge of the cartridge main bodies 1a and 2a, and the recording and reproducing opening 5a is formed. , 5b are opened, and the first and second optical disks 3a, 3b accommodated in the cartridge main bodies 1a, 2a are exposed to the outside so that recording or reproduction is possible.
[0093]
When the first and second disk cartridges 1 and 2 are mounted on the mounting portion 13, the disk table 41 constituting the disk rotation drive mechanism 13a enters through the central opening 6 provided in the cartridge main bodies 1a and 2a. Then, as shown in FIGS. 9A and 9B, the clamping plate 4 is magnetically attracted. Thus, the first and second optical disks 3a and 3b are centered by the centering unit 42 of the disk table 41 and are in a rotatable state. Here, as shown in FIGS. 9A and 9B, the second optical disc 3b is thinner than the first optical disc 3a as a whole, but the center hole 43b is surrounded by the center hole of the first optical disc 3a. It is formed to the same thickness as the periphery of 43a. Therefore, the disk table 41 can rotatably hold the first and second optical disks 3a and 3b at substantially the same height.
[0094]
When the first and second disk cartridges 1 and 2 are mounted, the recording / reproducing device 10 detects the first and second disk cartridges 1 by using a detection switch such as a pressing switch provided on the mounting unit 13. , 2 and the type of the first optical disk 3a stored in the first disk cartridge 1. The first disk cartridge 1 is formed in a substantially rectangular shape as a whole, and the second disk cartridge 2 is formed in a substantially arcuate shape on the other side edge 2c serving as an insertion end into the recording / reproducing device 10, Both have different shapes. The mounting unit 13 is provided with detection switches for the first and second disk cartridges 1 and 2 at positions corresponding to the other side edges 1c and 2c of the first and second disk cartridges 1 and 2, for example, the first and second disk cartridges 1 and 2. By pressing the disk cartridge 1 only, two types of disk cartridges can be identified. Further, the first disk cartridge 1 stores a plurality of types of magneto-optical disks having different recording densities as described above. The recording / reproducing apparatus 10 detects the presence or absence of one or a plurality of identification recesses provided in the cartridge main body 1a according to the type of the first optical disk 3a. The type can be identified. Then, the detection result detected by the detection switch is input to the system controller 148 shown in FIG.
[0095]
Next, the recording operation of the first disk cartridge 1 on the first optical disk 3a will be described. The source of the recording data is input from, for example, an information processing device such as a personal computer or a compact disk player connected to the USB I / F 120 or the input / output I / F 111 shown in FIG. As shown in FIG. 11, the recording / reproducing unit 102 turns off the reproducing selector 139 and switches the recording selector 142 between the first recording processing unit 140 and the second recording processing unit 141 according to the type of the first optical disc 3a. One of them is connected to the magnetic head driver 143.
[0096]
Then, the recording data input from the USB I / F 120 or the input / output I / F 111 is input to the data buffer 146 shown in FIG. 11, and the first recording processing unit 140 or the second recording processing unit 140 is used in accordance with the type of the first optical disc 3a. Is input to any of the recording processing units 141. When the type of the first optical disk 3a is a magneto-optical disk having a standard recording density, the recording data is input to the first recording processing unit 140, and the first recording processing unit 140 performs interlib processing by the ACIRC encoding circuit 140a. An error correction code is added, EFM modulation is performed by an EFM modulation circuit 140b, and input to the magnetic head 13c via a recording selector 142 that connects the EFM modulation circuit 140b and the magnetic head driver 143. In the case of the magneto-optical disks 1 and 2 of high-density recording, the recording data is subjected to interleaving and convolutional encoding by an RS-LDC encoding circuit 141a, and RLL (1-7) modulation by a 1-7PP modulation circuit 141b. Then, it is input to the magnetic head 13c via the recording selector 142 which connects the 1-7PP modulation circuit 141b and the magnetic head driver 143.
[0097]
On the other hand, when the first optical disk 3a mounted on the disk table 41 is a magneto-optical disk with a standard recording density or the magneto-optical disk 1 with a high-density recording, the spindle motor 131 constituting the disk rotation drive mechanism 13a is used. , CLV, and when it is a magneto-optical disk 2 for high-density recording, it rotates at ZCAV. Then, the optical pickup 13a emits a recording-level light beam from the semiconductor laser 151, irradiates the first optical disk 3a, and locally heats the Curie temperature. A magnetic field corresponding to the recording data is applied to the first optical disk 3a at a location heated to the Curie temperature by the magnetic head 13c in a state close to the first optical disk 3a, and an information signal is recorded. In particular, the magneto-optical disk 2 on which information signals are recorded at the highest density records information signals in DWDD during recording.
[0098]
At the time of recording on the first optical disc 3a, the servo circuit 145 forms a servo loop in which negative feedback is formed so that the FE signal input from the RF amplifier 135 becomes 0, and drives the two-axis actuator 154. . Further, the servo circuit 145 drives the biaxial actuator 154 based on the tracking error signal (TE signal) input from the RF amplifier 135, and shifts the irradiation position of the light beam in a direction orthogonal to the recording track of the first optical disc 3a. To perform tracking servo control for moving to.
[0099]
Next, the reproducing operation of the first and second disk cartridges 1 and 2 will be described. The system controller 148 detects the type of the disk cartridge and the type of the first optical disk 3a of the first disk cartridge 1 in response to an input from a detection switch provided in the mounting unit 13, and performs recording based on the detection result. The selector 142 is turned off, and the reproduction selector 139 is turned on by the first reproduction processing unit 136, the second reproduction processing unit 137, and the third reproduction processing unit 138 according to the type of the disk cartridge and the type of the first optical disk 3a. One of them is connected to the data buffer 146.
[0100]
When playing back the first optical disk 3a stored in the first disk cartridge 1, when the track number or the like is designated by the operation unit 15 or the operation unit 16a of the remote operation device 16, the optical pickup 13b is moved to the designated position. The first optical disk 3a is moved in the radial direction by the thread mechanism 133 to the recording track. Then, the optical pickup 13b irradiates the first optical disc 3a with a light beam of a reproduction level from the semiconductor laser 151, detects the reflected light beam returned by the light detection unit 153, and performs focus servo control and tracking servo control. Do.
[0101]
When reproducing a magneto-optical disk having a standard recording density, which is one of the first optical disks 3a housed in the first disk cartridge 1, the RF signal generated by the RF amplifier 135 includes a comparator 136a and a PLL circuit 136b. After the clock is reproduced and binarized, the EFM demodulation circuit 136c performs EFM demodulation. The data sequence of the reproduced signal subjected to the EFM demodulation is subjected to error correction processing and deinterleaving processing by the ACIRC decoding circuit 136d, and is output to the data buffer 146 via the reproduction selector 139 connecting the ACIRC decoding circuit 136d and the data buffer 146. Is done.
[0102]
When reproducing the high-density magneto-optical disks 1 and 2 of the first optical disk 3a used for the first disk cartridge 1, the RF signal generated by the RF amplifier 135 is converted into an A / D converter 137a and an equalizer 137b. Then, after the clock is reproduced and binarized by the PLL circuit 137c, it is Viterbi decoded by the Viterbi decoding circuit 137d. The data sequence of the Viterbi-decoded reproduced signal is subjected to RLL (1-7) demodulation by a 1-7PP demodulation circuit 137e, error correction and deinterleaving by an RS-LDC decoding circuit 137f, and an RS-LDC decoding circuit 137f. The data is output to the data buffer 146 via the reproduction selector 139 connecting the data buffer 146 and the data buffer 146.
[0103]
When the reproduction data output from the data buffer 146 is audio data such as audio data, for example, the data compressed by the audio processor 112 or the like shown in FIG. Be sounded. Further, the image data and the text data are displayed on the display unit 14 provided on the apparatus main body 11 and the small display unit 16b provided on the remote operation device 16.
[0104]
When playing back the second optical disk 3b stored in the second disk cartridge 2, the track number is input from the operation unit 15 or the operation unit 15 of the remote operation device 16, and is connected to the input / output I / F 111. When save data or the like, which is game progress data, is input from the IC card, the optical pickup 13b is moved in the radial direction of the first optical disc 3a by the thread mechanism 133 to a designated recording track. Then, the optical pickup 13b irradiates the first optical disc 3a with a light beam of a reproduction level from the semiconductor laser 151, detects the reflected light beam returned by the light detection unit 153, and performs focus servo control and tracking servo control. Do.
[0105]
Then, the RF signal generated by the RF amplifier 135 is clock-reproduced and binarized by the comparator 138a and the PLL circuit 138b, and then the EFMplus demodulation circuit 138c demodulates the 16-bit data sequence into an 8-bit data sequence. You. The data sequence of the reproduced signal demodulated by EFMplus is subjected to error correction processing and deinterleave processing by an RS-PC decoding circuit 138d, and is passed through a reproduction selector 139 connecting the RS-PC decoding circuit 138d and a data buffer 146. The data is output to the data buffer 146.
[0106]
The reproduction data output from the data buffer 146 is, for example, video data, image data, audio data, and the like constituting game software, and is output to the MPEG decoder 119. After the reproduced data is decoded by the MPEG decoder 119, the video data and the image data are subjected to image processing by the GPU 124 and the graphical RAM 125 via the GPU I / F 121, and are provided in the apparatus main body 11. It is displayed on the large display unit 14. The sound data is emitted from an electroacoustic transducer such as the earphone 18 via the sound processor 112 shown in FIG.
[0107]
As shown in FIG. 1, when playing the game software recorded on the second disk cartridge 2, the user grips the apparatus main body 11 with his / her hand and displays the image displayed on the large display unit 14. The character displayed on the display unit 14 using the ten o'clock key 15a or the round button 15b constituting the operation unit 15 provided near the display unit 14 of the apparatus main body 11 while watching the audio data with the earphone 18 while watching. Can be moved up, down, left and right, and the progress of the game can be selected and determined. The game operation may be performed using the operation unit 16a of the remote operation device 16 in addition to the operation unit 15.
[0108]
In the recording / reproducing apparatus 10 configured as described above, a large display section 14 is provided on one main surface section 11a of the apparatus main body 11, and images and videos can be displayed on the display section 14. It can be performed. That is, in the conventional portable recording / reproducing apparatus, only a small display section for displaying text data is provided on one main surface section 11a of the apparatus main body. Although the entire image could not be displayed at once, the recording / reproducing apparatus 10 can display the entire video and image at once by providing the large display unit 14, and the user can use the recording / reproducing unit 10. , While enjoying the content data such as game software recorded on the disk cartridge. When the game is stopped halfway, the recording / reproducing device 10 generates save data or the like which is progress data of the game, and saves the generated save data or the like on an IC card connected to the input / output I / F 111. it can.
[0109]
The recording / reproducing apparatus 10 includes a plurality of reproduction processing units 136, 137, and 138, and thus can reproduce optical disks having different specifications. For example, the recording / reproducing apparatus 10 can also reproduce a new recording medium such as the second optical disk 3b in addition to an optical disk of an existing specification.
[0110]
In the above example, the second optical disk 3b for recording the game software and the like used for the second disk cartridge 2 has been described as a read-only optical disk with a pit pattern. A recording area may be provided in a part. In this case, for example, a groove is provided on a part of the inner circumference side or the outer circumference side of the second optical disc 3b so that phase change recording or the like can be performed, and the semiconductor laser 151 has a high output light capable of phase change recording. What is necessary is just to emit a beam. The recording / reproducing unit 102 is provided with a third recording processing unit in parallel with the first recording processing unit 141 and the second recording processing unit 142. The third recording processing unit is provided with an RS-PC encoder connected to the data buffer 146 and an EFMplus modulation circuit connected to the RS-PC encoding circuit. What is necessary is just to connect to the magnetic head driver 143.
[0111]
Further, in the recording / reproducing apparatus 10 described above, an example has been described in which both the first disk cartridge 1 and the second disk cartridge 2 can be mounted on the mounting section 13. However, the present invention is not limited to this. The apparatus may be configured such that only the second disk cartridge 2 using the second optical disk 3b for recording content data having video data as a recording medium can be mounted. As shown in FIG. 12, the second disk cartridge 2 has the other side edge 2c, which is the insertion end into the recording / reproducing device 10, formed in a substantially arc shape. In view of this, the mounting section 13 of the recording / reproducing apparatus 10 may be provided with a regulating section 160 corresponding to the shape of the other side edge 2c of the second disk cartridge 2 so as to protrude. Thus, for example, when the first disk cartridge 1 having a substantially rectangular shape as a whole is inserted through the insertion / removal opening 12 of the recording / reproducing apparatus 10 with the other side edge 1c as an insertion end, the regulating section 160 becomes an insertion end to the recording / reproducing apparatus 10. Since it comes into contact with the other side edge 1c and is not mounted on the mounting portion 13, the user can easily recognize that the first disk cartridge 1 is an unusable recording medium.
[0112]
As described above, when the recording / reproducing device 10 is exclusively used for the second disk cartridge 2, the first reproduction processing unit 136, the second reproduction processing unit 137, and the second reproduction processing unit 136 related to the first disk cartridge 1 are used. There is no need to provide the first recording processing unit 141 and the second recording processing unit 142, and the recording / reproducing unit 102 only needs to include the third reproduction processing unit 138 and the above-described third recording processing unit.
[0113]
In the above example, the optical disk 3a of the first disk cartridge 1 is a read-only optical disk on which audio data and the like are recorded, a magneto-optical disk on which audio data desired by a user is recorded, and a conventional optical disk. A magneto-optical disk capable of recording information signals at a higher density than the magnetic disk was used, and the information signal was recorded at a higher density than the conventional read-only optical disk as a pit pattern as the optical disk 3b of the second disk cartridge 2. Although an example using a read-only optical disk has been described, the types of the optical disks 3a and 3b include a rewritable optical disk using a phase change material for a recording layer and a write-once optical disk using an organic dye for a recording layer. Is also good. Further, the recording medium may be an optical disk alone, a tape cartridge, an IC card, or the like, in addition to the disk cartridge.
[0114]
【The invention's effect】
According to the present invention, in a small portable electric device in which the size of one main surface of the device main body is substantially the same as the recording medium, the display unit is provided over almost the entire area of the main surface of the device main body. In addition, the entire still image data, video data, and the like can be viewed at once without scrolling or the like.
[Brief description of the drawings]
FIG. 1 is a perspective view illustrating a use state of a portable recording / reproducing apparatus to which the present invention is applied.
FIG. 2 is a perspective view of the portable recording / reproducing apparatus.
FIG. 3 is a perspective view of a first disk cartridge used in the portable recording / reproducing apparatus.
FIG. 4 is a perspective view of a second disk cartridge used in the portable recording / reproducing apparatus.
FIG. 5 is a diagram illustrating specifications of an optical disk used for the first disk cartridge shown in FIG.
FIG. 6 is a diagram illustrating the specifications of an optical disk used in the second disk cartridge shown in FIG.
FIG. 7 is a cross-sectional view of a main part of an optical disk formed by bonding two substrates.
FIGS. 8A to 8D are diagrams illustrating the relationship between an optical disc and an optical pickup.
9A is a cross-sectional view of a main part of a first disk cartridge, and FIG. 9B is a cross-sectional view of a main part of a second disk cartridge.
FIG. 10 is a block diagram illustrating an overall configuration of a recording / reproducing apparatus to which the present invention has been applied.
FIG. 11 is a block diagram illustrating a recording / reproducing unit that performs recording / reproduction on first and second disk cartridges.
FIG. 12 is a perspective view illustrating a mounting portion that allows only a second disk cartridge to be mounted.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 1st disk cartridge, 2nd disk cartridge, 3a 1st optical disk, 3b 2nd optical disk, 10 recording / reproducing apparatus, 11 apparatus main body, 11a main surface part, 12 slot, 13 mounting part, 13a disk rotation Drive mechanism, 13b optical pickup, 13c magnetic head, 14 display unit, 15 operation unit, 16 remote control device, 18 earphone, 31 first substrate, 32 second substrate, 33 adhesive layer, 34 objective lens, 41 disk table , 42 centering part, 43a, 43b center hole, 44 disk support part, 45a, 45b reference plane, 46a, 46b disk holding part, 47a, 47b disk holding part

Claims (9)

A mounting section on which the recording medium is mounted is provided, and a main surface portion of the device main body having substantially the same size as the main surface portion of the recording medium;
A reproducing unit that is provided in the device main body and reads out an information signal recorded on a recording medium mounted on the mounting unit;
A signal processing unit that performs a reproduction process of an information signal read from a recording medium mounted on the mounting unit in the reproduction unit;
A display unit that is provided over substantially the entire area of the main surface of the device main body and displays visible data that has been signal-processed by the signal processing unit in accordance with the operation of the playback unit;
A portable electronic device comprising: an operation unit configured to input an operation signal related to a reproduction operation for a recording medium mounted on the mounting unit. 2. The portable electronic device according to claim 1, wherein the recording medium is a disk cartridge, and the main body of the device main body is formed to have substantially the same size as the main surface of the disk cartridge. The portable electronic device according to claim 1, wherein the operation unit is provided on a main surface of a device main body provided with the display unit. The portable electronic device according to claim 1, wherein the operation unit is provided in a remote operation device connected to the device main body by wire or wirelessly. The portable electronic device according to claim 1, further comprising an electroacoustic transducer that emits the audio data signal-processed by the signal processing unit, to the device body. The portable electronic device according to claim 1, wherein the signal processing unit performs signal processing on information signals in a plurality of recording formats. The portable electronic device according to claim 1, further comprising a recording unit that records an information signal on a recording medium mounted on the mounting unit. 2. The portable electronic device according to claim 1, wherein a plurality of types of recording media having different external shapes can be mounted on the mounting portion. 2. The portable electronic device according to claim 1, wherein the mounting portion is provided with a restricting portion that permits mounting only on a recording medium having a predetermined outer shape.

Images