JP2010277664A - Optical disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To focus a light beam in the vicinity of a desired recording layer without being affected by interlayer stray light. <P>SOLUTION: An optical disk device 1 generates a focus error signal SFE based on a zeroth-order reflection light beam LR0. The optical disk device 1 receives first-order reflection light beams LR1A and LR1B in light receiving regions D2A and D2B of a light receiving part D disposed so as to avoid a stray light pattern W of an interlayer stray light beam LN and generates a pull-in signal PI1. An optical pickup 7 performs focus jump and focus control based on the focus error signal SFE and pull-in signal PI1. The optical disk device 1 generates the pull-in signal PI1 by eliminating the influence of stray light pattern W formed by interlayer stray light beam LN from a plurality of recording layers Y, and accurately performs focus jump and focus control. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an optical disc apparatus, and is suitable for application to an optical disc apparatus corresponding to an optical disc having a plurality of recording layers, for example.

  2. Description of the Related Art Conventionally, in an optical disc apparatus, a light beam is irradiated onto an optical disc, such as a CD (Compact Disc), a DVD (Digital Versatile Disc), and a Blu-ray Disc (registered trademark, hereinafter referred to as BD), and its reflection. A device that reproduces information by reading light is widely used.

  The optical disk apparatus focuses the light beam on the recording layer of the optical disk when the light beam is collected by an objective lens and information is reproduced from the optical disk.

  Further, in the case of reproducing information from an optical disc having a plurality of recording layers, the optical disc apparatus needs to focus on the destination recording layer when switching the recording layer for reproducing information.

  At this time, the optical disk apparatus receives the reflected light by providing a light receiving area of a predetermined shape on the photo detector, and based on the result of the light reception, the deviation amount in the focus direction between the focus position of the recording layer and the focus of the light beam is calculated. Calculate the focus error signal to represent.

  Then, the optical disc apparatus moves the focal point of the light beam to the vicinity of the recording layer to be moved by largely moving the objective lens based on the calculated focus error signal and performing a focus jump.

  As such a focus jump, there has been proposed a focus jump using a pull-in signal representing the amount of reflected light in addition to the focus error signal. (For example, refer to Patent Document 1).

Japanese Patent Laying-Open No. 2005-310275 (FIG. 9)

  By the way, as described above, the optical disc apparatus controls the optical disc having a plurality of recording layers so as to focus the light beam on the desired recording layer, and detects the reflected light.

  However, optical disks always reflect a light beam with a predetermined reflectivity in each recording layer regardless of which recording layer is a desired recording layer due to physical properties.

  For this reason, in the optical disc apparatus, a light beam reflected by another recording layer different from the desired recording layer (so-called interlayer stray light) may be irradiated to the light receiving region of the photodetector. At this time, the optical disk apparatus has a problem that an error occurs in the pull-in signal due to the interlayer stray light, and the focus jump may not be performed correctly.

  The present invention has been made in consideration of the above points, and an object of the present invention is to propose an optical disc apparatus capable of focusing a light beam in the vicinity of a desired recording layer without being affected by interlayer stray light.

  In order to solve such a problem, in the optical disk device, a light source that emits a light beam, an objective lens that focuses the light beam on a target recording layer among a plurality of recording layers provided on the optical disk, and an objective lens, A lens moving unit that moves in a focus direction that is in contact with and away from the target recording layer, a condensing lens that collects a reflected light beam that is reflected by the optical disk, and a plurality of lights that travel the reflected light beam in different directions. A light separation element that separates the light beam and a part of the light beam irradiated on the optical disk are disposed outside the irradiation range of the stray light pattern caused by the interlayer stray light that is reflected by another recording layer other than the target recording layer in the optical disk. The light receiving region generates the light receiving signal by receiving the reflected light beam separated by the light separation element, and the light receiving region. A signal processing unit that generates a pull-in signal that represents the amount of reflected light beam based on the received light signal, and the objective lens is moved in the focus direction via the lens moving unit based on the pull-in signal, and the focus of the objective lens is the target recording layer And a servo control unit to match the above.

  In this optical disc apparatus, the influence of interlayer stray light from a plurality of recording layers is eliminated, the ratio between the maximum value and the minimum value in the characteristic curve of the pull-in signal can be expanded, and each recording layer corresponding to each maximum value can be expanded. Identification accuracy can be increased.

  According to the present invention, the influence of interlayer stray light from a plurality of recording layers is eliminated, the ratio between the maximum value and the minimum value in the characteristic curve of the pull-in signal can be expanded, and each recording layer corresponding to each maximum value The identification accuracy can be improved. Thus, the present invention can realize an optical disc apparatus capable of focusing the light beam near the desired recording layer without being affected by interlayer stray light.

It is a basic diagram which shows the structure of an optical disk device. It is a basic diagram which shows the structure of an optical pick-up. It is an approximate line figure used for explanation of reflection of a light beam by a recording layer of an optical disc. It is a basic diagram which shows the structure of a hologram element. It is a basic diagram which shows the structure of a photodetector. It is a basic diagram which shows formation of a stray light pattern. It is a table | surface which shows the model of an optical disk and a hologram element. FIG. It is a basic diagram which shows the focus error signal and pull-in signal by recording layer Y0. It is a basic diagram which shows the focus error signal and pull-in signal by the recording layer Y1. It is a basic diagram which shows the focus error signal and pull-in signal by the recording layer Y2. It is a basic diagram which shows the focus error signal and pull-in signal by recording layer Y3. It is a basic diagram which shows the focus error signal and pull-in signal by a disc surface. It is a basic diagram with which it uses for description of the astigmatism method by the reflected light beam irradiated to the light-receiving part D1. It is a basic diagram which shows the focus error signal and pull-in signal by the recording layers Y0-Y3 and the disc surface. It is a basic diagram which shows the pull-in signal by the light reception signal S2. It is a basic diagram which shows a focus error signal and a pull-in signal at the time of correct | amending the spherical aberration of a recording layer Y0 focusing state. It is a basic diagram which shows a focus error signal and a pull-in signal at the time of correct | amending the spherical aberration of the recording layer Y1 focusing state. It is a basic diagram which shows a focus error signal and a pull-in signal at the time of correct | amending the spherical aberration of a recording layer Y2 focusing state. It is a basic diagram which shows a focus error signal and a pull-in signal at the time of correcting the spherical aberration of the recording layer Y3 focusing state. It is a basic diagram which shows a focus error signal and a pull-in signal in case spacer thickness is 25 micrometers. It is a basic diagram which shows a focus error signal and a pull-in signal in case spacer thickness is 22 micrometers. It is a basic diagram which shows a focus error signal and a pull-in signal in case spacer thickness is 20 micrometers. It is a basic diagram which shows a focus error signal and a pull-in signal in case spacer thickness is 18 micrometers. It is a basic diagram which shows a focus error signal and a pull-in signal in case spacer thickness is 16 micrometers. It is a basic diagram which shows the relationship between the spacer thickness and the ratio of the minimum value with respect to the maximum value of a pull-in signal.

Hereinafter, modes for carrying out the invention (hereinafter referred to as embodiments) will be described. The description will be given in the following order.
1. Embodiment 2. FIG. Other embodiments

<1. Embodiment>
[1-1. Configuration of optical disc apparatus]
As shown in FIG. 1, the optical disc apparatus 1 is configured with a central control unit 2 as a center, and can record information on the optical disc 100 and reproduce information from the optical disc 100.

  In the optical disc 100, spiral or concentric track grooves are formed in the recording layer, and information is recorded along the track grooves. Incidentally, the optical disc 100 has, for example, four recording layers Y0, Y1, Y2, and Y3 (hereinafter collectively referred to as recording layer Y), and there are various thicknesses between the recording layers Y. A spacer is provided.

  The overall control unit 2 includes a CPU (Central Processing Unit) (not shown), a ROM (Read Only Memory) in which various programs are stored, and a RAM (Random Access Memory) used as a work memory of the CPU. Yes.

  When reproducing information from the optical disc 100, the overall control unit 2 rotates the spindle motor 5 via the drive control unit 3 to rotate the optical disc 100 placed on the turntable 5T at a desired speed.

  Further, the overall control unit 2 drives the sled motor 6 via the drive control unit 3 so that the optical pickup 7 is largely moved along the movement axis in the tracking direction, that is, the direction toward the inner or outer peripheral side of the optical disc 100. It is made to move.

  The optical pickup 7 has a plurality of components such as an objective lens 8 and a biaxial actuator 9 attached thereto, and irradiates the optical disc 100 with a light beam based on the control of the overall control unit 2.

  Incidentally, when irradiating the optical disc 100 with a light beam, the overall control unit 2 selects the recording layer Y from which information is to be read out of the recording layers Y0 to Y3, that is, the recording layer Y on which the light beam is to be focused as the target recording layer YT. It is made to select as.

  The optical pickup 7 receives a reflected light beam obtained by reflecting the light beam by the optical disc 100, generates a light reception signal corresponding to the light reception result, and supplies the light reception signal to the signal processing unit 4.

  The signal processing unit 4 generates a focus error signal, a tracking error signal, and a pull-in signal by performing predetermined arithmetic processing using the supplied light reception signal, and supplies them to the drive control unit 3.

  The servo control unit 3A of the drive control unit 3 generates a drive signal for driving the objective lens 8 based on the supplied focus error signal, tracking error signal, and pull-in signal. Supply to the actuator 9.

  The biaxial actuator 9 of the optical pickup 7 performs focus jump, focus control, tracking control, and the like of the objective lens 8 based on this drive signal, and adjusts the focal position of the light beam condensed by the objective lens 8. (Details will be described later).

  Further, the drive control unit 3 receives a notification of the target recording layer YT from the overall control unit 2, and performs focus control so that the light beam is focused on the target recording layer YT.

  The signal processing unit 4 can reproduce information recorded on the optical disc 100 by performing predetermined arithmetic processing, demodulation processing, decoding processing, and the like on the received light signal.

  Further, when recording information on the optical disc 100, the overall control unit 2 receives information to be recorded from an external device (not shown) and supplies the information to the signal processing unit 4. The signal processing unit 4 generates a recording signal by performing predetermined encoding processing, modulation processing, and the like on the information, and supplies the recording signal to the optical pickup 7.

  The optical pickup 7 forms a recording mark corresponding to the recording signal by making the light beam have an intensity for recording and modulating it in accordance with the recording signal. For example, when the optical disc 100 is a recording method similar to BD-RE (Blu-ray Disc-Rewritable), the recording mark is formed by locally changing the material forming the recording layer.

  In this way, the optical disc apparatus 1 can perform information reproduction processing and recording processing while irradiating the optical disc 100 with a light beam from the optical pickup 7 and performing focus control and tracking control based on the reflected light. ing.

[1-2. Configuration of optical pickup]
As shown in FIG. 2, the optical pickup 7 irradiates the optical disk 100 with a light beam L1 and receives a reflected light beam LR formed by reflecting the light beam L1 by the optical disk 100.

  The laser diode 11 can emit a light beam L1 made of blue-violet laser light having a wavelength of about 405 [nm] as divergent light under the control of the light source control unit 21. The mounting angle of the laser diode 11 is adjusted so that the light beam L1 becomes P-polarized light.

  In practice, the overall control unit 2 controls the light source control unit 21 to emit the light beam L1 from the laser diode 11 and make it incident on the collimator lens 12. The collimator lens 12 converts the light beam L1 from diverging light to parallel light and makes it incident on the polarization beam splitter 13.

  The polarization beam splitter 13 has a reflection / transmission surface 13S having different transmittance depending on the polarization direction of the light beam, and transmits the P-polarized light beam at a rate of approximately 100%, and also the S-polarized light beam. Is reflected at a rate of almost 100%.

  Actually, the polarization beam splitter 13 transmits the light beam L1 at a rate of approximately 100% by the reflection / transmission surface 13S and makes it incident on the spherical aberration correction unit 14.

  The spherical aberration correction unit 14 is made of, for example, a liquid crystal element, and changes the spherical aberration of the light beam L1 so as to be incident on the quarter-wave plate 15. The spherical aberration correction unit 14 can also adjust the degree of change of spherical aberration due to the liquid crystal element by the spherical aberration control unit 3AS of the servo control unit 3A.

  Actually, the spherical aberration correction unit 14 has a reverse characteristic to the spherical aberration generated when the light beam L1 is collected and reaches the target recording layer YT of the optical disc 100 based on the control of the overall control unit 2 and the spherical aberration control unit 3AS. The spherical aberration is given to the light beam L1 in advance. Thereby, the spherical aberration correction unit 14 can correct the spherical aberration when the light beam L1 reaches the target recording layer YT.

  The quarter-wave plate 15 is configured to be able to mutually convert the light beam between linearly polarized light and circularly polarized light. For example, the quarter wave plate 15 converts the light beam L1 composed of P-polarized light into left-handed circularly polarized light, and supplies the objective lens 8 Make it incident.

  The objective lens 8 condenses the light beam L1. Here, the overall control unit 2 adjusts the position of the objective lens 8 in the focus direction with the focus actuator 9F via the focus control unit 3AF.

  At this time, the light beam L1 is reflected by the target recording layer YT to become a reflected light beam LR and enters the objective lens 8. The reflected light beam LR becomes right circularly polarized light because the rotational direction of circularly polarized light is reversed when reflected.

  For example, when the recording layer Y0 is the target recording layer YT, as shown in FIG. 3, the light beam L1 is reflected by the recording layer Y0 to become a reflected light beam LR.

  Thereafter, the reflected light beam LR is converted from divergent light to parallel light by the objective lens 8, converted from right circularly polarized light to S polarized light (linearly polarized light) by the quarter wavelength plate 15, and further incident on the spherical aberration correction unit 14. Is done.

  The spherical aberration correction unit 14 corrects the spherical aberration that occurs between the time when the reflected light beam LR is reflected by the target recording layer YT and the time when the reflected light beam LR passes through the objective lens 8, and the reflected light beam LR is supplied to the polarization beam splitter 13. Make it incident.

  The polarization beam splitter 13 reflects the reflected light beam LR made of S-polarized light at the reflection / transmission surface 13 </ b> S and makes it incident on the condenser lens 16. The condenser lens 16 converts the reflected light beam LR into convergent light and makes it incident on the hologram element 17.

  The hologram element 17 diffracts the reflected light beam LR into at least zero order light and first order light due to the property as a diffractive element, and substantially straightens the reflected light beam LR0 composed of the 0th order light, and also the primary light. The reflected light beam LR1 is made to travel in a direction different from the 0th-order light and is incident on the cylindrical lens 18.

  Here, the hologram element 17 has a portion where the reflected light beam LR passes as shown in FIG. 4 (A) divided into a plurality of regions 17A to 17E, and is reflected for each region as shown in FIG. 4 (B). The diffraction direction of the light beam LR is set.

  The region 17A includes a portion of the reflected light beam LR1 that includes first-order diffracted light (that is, + 1st-order light or −1st-order light) diffracted by the track of the optical disc 100 and corresponds to the inner peripheral side portion of the optical disc 100. It is assumed that the reflected light beam LR1A. At this time, the region 17A diffracts the reflected light beam LR1A in a direction substantially along the traveling direction of the track (for convenience, this direction is hereinafter referred to as a longitudinal direction).

  The region 17B includes the first-order diffracted light (that is, −1st-order light or + 1st-order light) diffracted by the track of the optical disc 100 in the reflected light beam LR1, and reflects the portion corresponding to the outer peripheral side portion of the optical disc 100. It is assumed that the light beam LR1B. At this time, the region 17B diffracts the reflected light beam LR1B substantially vertically and slightly larger than the reflected light beam LR1A.

  The regions 17C1 and 17C2 contain almost no first-order diffracted light diffracted by the track of the optical disc 100 in the reflected light beam LR1, and the regions 17C1 and 17C2 exclude the central portion of the reflected light beam LR1. A portion corresponding to the peripheral portion is a reflected light beam LR1C. At this time, the regions 17C1 and 17C2 diffract the reflected light beam LR1C in a direction substantially perpendicular to the traveling direction of the track (for convenience, this direction is hereinafter referred to as a lateral direction).

  The regions 17D1 and 17D2 contain almost no first-order diffracted light diffracted by the track of the optical disc 100 in the reflected light beam LR1, and the outer periphery of the optical disc 100 is a region excluding the central portion of the reflected light beam LR1. A portion corresponding to the side portion is a reflected light beam LR1D. At this time, the regions 17D1 and 17D2 diffract the reflected light beam LR1D substantially in the lateral direction and slightly smaller than the reflected light beam LR1C.

  In the region 17E, the central portion of the reflected light beam LR1 is a reflected light beam LR1E. At this time, the region 17E diffracts the reflected light beam LR1E in an oblique direction that is substantially in the middle between the vertical direction and the horizontal direction, that is, in the lower left direction in the figure.

  Thus, the hologram element 17 changes the light amount when the push-pull component (that is, the focal point F1 of the light beam L1 is displaced toward the inner circumference side or the outer circumference side with respect to a desired track) in the reflected light beam LR1 composed of the primary light. The portions including the component) are reflected light beams LR1A and LR1B, which are diffracted in the vertical direction.

  The hologram element 17 includes almost no push-pull component in the reflected light beam LR1, and the front and rear portions in the traveling direction of the track are the reflected light beams LR1C and LR1D, which are diffracted in the lateral direction, respectively. Yes.

  Incidentally, since the so-called binary hologram is formed in each of the regions 17A to 17E, the hologram element 17 actually generates + 1st order light and −1st order light by the diffraction action. However, in the optical pickup 7, only one of the + 1st order light and the −1st order light is used as the first order diffracted light, and the other is not used.

  In this way, the hologram element 17 is configured to divide the reflected light beam LR1 into a plurality of reflected light beams LR1A to LR1E by diffracting the reflected light beam LR1 in a direction set for each region.

  The cylindrical lens 18 irradiates the photodetector 19 with astigmatism in the reflected light beam LR0 composed of 0th-order light.

  Incidentally, the cylindrical lens 18 also has astigmatism with respect to the reflected light beams LR1A, LR1B, LR1C, LR1D, and LR1E, which are primary light, due to their optical properties. However, the reflected light beams LR1A to LR1E are preliminarily given aberrations that cancel out the astigmatism by the diffraction grating formed on the hologram element 17, and thus have no aberration when emitted from the cylindrical lens 18. It is made like that.

  As shown in FIG. 5, the photodetector 19 has a plurality of light receiving portions D1 to D4, and a plurality of light receiving regions are formed in the light receiving portions D1 to D4.

  The light receiving part D1 is divided into two in the vertical and horizontal directions around the reference point P corresponding to the optical axis of the reflected light beam LR0 composed of 0th order light, that is, the light receiving region D1A divided into four in a lattice shape. , D1B, D1C, and D1D receive the reflected light beam LR0. Incidentally, each of the light receiving regions D1A to D1D is formed in a substantially square shape having substantially the same size.

  The light receiving regions D1A, D1B, D1C, and D1D generate light receiving signals S1A, S1B, S1C, and S1D corresponding to the amounts of received light, and send them to the head amplifier 22 (FIG. 2).

  The light receiving part D2 is provided at a location separated from the reference point P in the vertical direction, and is arranged in the vertical direction, that is, along a virtual straight line VL1 extending from the reference point P in the vertical direction. And D2B are arranged. Incidentally, each of the light receiving regions D2A and D2B is formed in a substantially square shape having substantially the same size.

  The light receiving regions D2A and D2B receive the reflected light beams LR1A and LR1B, generate light reception signals S2A and S2B corresponding to the respective amounts of received light, and send them to the head amplifier 22 (FIG. 2). ing.

  Further, the light receiving unit D2 is provided with stray light receiving regions D2P and D2Q for detecting stray light (described in detail later) so as to be adjacent to the light receiving regions D2A and D2B, respectively, along the vertical direction. The stray light receiving areas D2P and D2Q also generate received light signals S2P and S2Q corresponding to the respective received light amounts and send them to the head amplifier 22 (FIG. 2).

  The light receiving unit D3 is provided at a location that is laterally separated from the reference point P, and the light receiving region D3C and the light receiving region D3C D3D is arranged with a predetermined interval. Incidentally, each of the light receiving regions D3C and D3D is formed in a substantially square shape having substantially the same size.

  As a result, the light detector 19 can reflect, for example, in the light receiving region D3C even when the reflected light beam LR moves due to various factors such as wavelength fluctuation of the light beam L1, temperature characteristics, defocusing, and the like. It is possible to prevent light from being applied to the other light receiving region D3D.

  The light receiving regions D3C and D3D receive the reflected light beams LR1C and LR1D, respectively, generate light reception signals S3C and S3D corresponding to the respective amounts of received light, and send them to the head amplifier 22 (FIG. 2). ing.

  Furthermore, stray light receiving areas D3R1 and D3R2 are provided adjacent to the light receiving area D3C in the light receiving section D3 so as to sandwich the light receiving area D3C from the vertical direction.

  Similarly, in the light receiving unit D3, stray light receiving regions D3S1 and D3S2 are provided adjacent to the light receiving region D3D so as to sandwich the light receiving region D3D from the vertical direction.

  The stray light receiving areas D3R1 and D3R2 generate stray light received signals S3R1 and S3R2 corresponding to the respective amounts of received light, and send them to the head amplifier 22 (FIG. 2).

  Similarly, the stray light receiving areas D3S1 and D3S2 generate stray light received signals S3S1 and S3S2 corresponding to the respective amounts of received light, and send them to the head amplifier 22 (FIG. 2).

  The light receiving unit D4 is provided at a location that is separated from the reference point P in an oblique direction (that is, a direction approximately in the middle of the vertical direction and the horizontal direction). The light receiving regions D4A, D4B, D4C divided into four in a lattice shape The reflected light beam LR1E is received by D4D. Incidentally, the division direction of each light receiving region in the light receiving unit D4 is formed at an angle of about 45 degrees with the division direction in the light receiving unit D1. The light receiving regions D4A to D4D are all formed in a substantially square shape having substantially the same size.

  The light receiving regions D4A, D4B, D4C, and D4D generate light receiving signals S4A, S4B, S4C, and S4D corresponding to the respective amounts of received light, and send them to the head amplifier 22 (FIG. 2).

  As described above, the photodetector 19 receives the reflected light beams LR0 and LR1A to LR1E by the light receiving areas of the light receiving portions D1 to D4, respectively, generates light reception signals corresponding to the respective amounts of received light, and supplies them to the head amplifier 22. It is made to supply.

  Incidentally, in the optical pickup 7, the reflected light beams LR1A, LR1B, LR1C, LR1D, and LR1E are substantially focused on the photodetector 19 by the design of the condenser lens 16 and the hologram element 17, for example. For this reason, the beam spots formed in each of the light receiving portions D2, D3, and D4 of the photodetector 19 are converged substantially in a dot shape.

[1-3. Irradiation of stray light and arrangement of light receiving area]
By the way, the optical disc 100 always reflects the light beam with a predetermined reflectance in the recording layers Y1 to Y3 and transmits the remainder, and reflects the light beam transmitted through the recording layer Y1 in the recording layer Y0. .

  For this reason, as shown in FIG. 3, even if the recording layer Y0 is selected as the target recording layer YT by the optical disc apparatus 1, for example, the light beam L1 is always reflected by the other recording layers Y1 to Y3. become. In this way, a light beam in which a part of the light beam L1 is reflected by the other recording layers Y1 to Y3 is referred to as an interlayer stray light beam LN.

  Incidentally, even though the disk surface 100A has a lower reflectance than the recording layers Y0 to Y3, the light beam is reflected to a slight extent.

  The interlayer stray light beam LN passes through the same optical path as the reflected light beam LR, is diffracted by the hologram element 17, and is finally irradiated to the photodetector 19.

  However, the interlayer stray light beam LN differs from the reflected light beam LR in the optical path length from when it is emitted as the light beam L1 from the objective lens 8 until it reaches the photodetector 19.

  In the optical pickup 7, the arrangement, optical characteristics, and the like of various optical components are determined so that the photodetector 19 becomes a confocal point of the target recording layer YT for the reflected light beam LR. For this reason, the interlayer stray light beam LN is split by the same splitting pattern as the reflected light beam LR, and is applied to the photodetector 19 in a defocused state, so-called defocused state.

  Furthermore, the optical disc 100 has a plurality of other recording layers Y1 to Y3 (in this case, three layers), and among the interlayer stray light beams LN, the light beam is reflected by any of the other recording layers Y1 to Y3. As a result, the defocused state on the photodetector 19 is different.

  For example, an interlayer stray light beam LN (hereinafter referred to as an interlayer stray light beam LN3) reflected by another recording layer Y3, that is, the recording layer Y farthest from the recording layer Y0 as the target recording layer YT is shown in FIG. ), A stray light pattern W3 that greatly spreads on the photodetector 19 is formed.

  In the stray light pattern W3, the stray light pattern W30 of the zero order light is formed by the hologram element 17, and the stray light patterns W3A and W3B are formed by the areas 17A and 17B of the primary light, and the areas 17C1, 17C2, 17D1 and 17D2 are formed. Thus, stray light patterns W3C1, W3C2, W3D1, and W3D2 are formed, respectively.

  Here, as shown in FIG. 6A, the light receiving units D2 and D3 of the photodetector 19 have the stray light pattern W3 with the largest irradiation range, the stray light pattern W30, the stray light patterns W3A and W3B, and the stray light pattern W3C1, W3C2, W3D1, and W3D2 are arranged so as not to be applied.

  On the other hand, an interlayer stray light beam LN (hereinafter referred to as an interlayer stray light beam LN1) reflected by another recording layer Y1, that is, the recording layer Y adjacent to the recording layer Y0 that is the target recording layer YT is shown in FIG. ), A stray light pattern W1 is formed on the photodetector 19 so as to be narrowed to a narrow range.

  This stray light pattern W1 corresponds to the stray light pattern W3. The hologram element 17 forms a zero-order stray light pattern W10, and the regions 17A and 17B of the primary light form stray light patterns W1A and W1B. The stray light patterns W1C1, W1C2, W1D1, and W1D2 are formed by the regions 17C1, 17C2, 17D1, and 17D2, respectively.

  As shown in FIG. 6 (B), the light receiving unit D2 of the photodetector 19 has the stray light patterns W1A and W1B formed by the regions 17A and 17B of the hologram element 17 in the case of the stray light pattern W1 with the smallest irradiation range. It is arranged so that it does not take.

  Here, the interval u1 between the stray light patterns W1A and W1B is the narrowest as shown in FIG. Therefore, in the photodetector 19, the light receiving areas D2A and D2B are arranged in the vertical direction without being arranged in the horizontal direction, and the horizontal widths of the light receiving areas D2A and D2B and the stray light receiving areas D2P and D2Q are made smaller than the interval u1. Has been made.

  In addition, in the case of this stray light pattern W1, the light receiving unit D3 of the photodetector 19 is arranged so that any of the stray light patterns W3C1, W3C2, W3D1, and W3D2 formed by the regions 17C1, 17C2, 17D1, and 17D2 of the hologram element 17 are not present. Has been.

  Here, the interval u2 between the stray light patterns W1C1 and W1C2 is the narrowest as shown in FIG. Therefore, in the photodetector 19, the light receiving areas D3C and D3D are arranged in the horizontal direction instead of being arranged in the vertical direction, the vertical width obtained by adding the stray light receiving areas D3R1 and D3R2 to the light receiving area D3C, and the stray light reception in the light receiving area D3D. The vertical width including the regions D3S1 and D3S2 is made smaller than the interval u2.

  In this manner, in each light receiving region of the photodetector 19, the stray light patterns W of various sizes are formed by the various interlayer stray light beams LN reflected by the other recording layers Y having different distances from the target recording layer YT. Even when the light is received, the light receiving portions D2 and D3 are arranged so that the stray light pattern is not applied.

[1-4. Focus control and tracking control]
The head amplifier 22 (FIG. 2) of the optical disc apparatus 1 amplifies the received light signals S1A, S1B, S1C and S1D, S2A and S2B, S3C and S3D, and S4A, S4B, S4C and S4D, respectively, and supplies them to the signal processing unit 4 To do.

  The head amplifier 22 also amplifies the stray light reception signals S2P and S2Q, and S3R and S3S, respectively, and supplies them to the signal processing unit 4.

  The signal processing unit 4 calculates the focus error signal SFE by the astigmatism method by performing the calculation according to the following equation (1) by the focus error signal calculation circuit 4F, and uses this as the focus control of the servo control unit 3A. Supply to unit 3AF.

  The focus error signal SFE represents the amount of deviation between the focal point F1 of the light beam L1 and the target recording layer YT on the optical disc 100.

  Further, the signal processing unit 4 calculates the pull-in signal PI1 as the light amount signal of the push-pull component by performing the calculation according to the following equation (2) by the pull-in signal calculation circuit 4P, and this is calculated by the servo controller 3A. Supply to the focus control unit 3AF.

  This pull-in signal PI1 corresponds to the amount of light of the reflected light beams LR1A and LR1B including a large amount of push-pull components of the reflected light beam LR1 that is primary light.

  The signal processing unit 4 uses either a phase difference method such as a DPD (Differential Phase Detection) method or a one-beam push-pull method for generating a tracking error signal.

  Specifically, the signal processing unit 4 uses a phase difference method when the optical disc 100 is a BD-ROM (Read Only Memory) in which a pit row is formed in advance in the recording layer Y according to the type of the optical disc 100. Use. The signal processing unit 4 uses a one-beam push-pull method when the optical disc 100 is BD-R (Recordable) or BD-RE (Rewritable).

  When the 1-beam push-pull method is used, the signal processing unit 4 calculates the tracking error signal STE by performing a calculation according to the following equation (3) by the tracking error signal calculation circuit 4T. Further, the signal processing unit 4 supplies the tracking error signal STE to the tracking control unit 3AT of the servo control unit 3A.

  This tracking error signal STE represents the amount of deviation between the focal point F1 of the light beam L1 and the desired track in the target recording layer YT on the optical disc 100.

  Incidentally, in the equation (3), the coefficient α represents a predetermined coefficient. In the term (S2A-S2B), the lens shift component (that is, the displacement of the objective lens 8 in the tracking direction) is added to the push-pull component (that is, the relative displacement between the focal point F1 of the light beam L1 and the desired track). It corresponds to the value made. Further, the term α × (S3C−S3D) corresponds to the value of the lens shift component.

  That is, in equation (3), the push-pull component is calculated by subtracting only the lens shift component from the value of the push-pull component to which the lens shift component is added.

  On the other hand, when using the phase difference method, the signal processing unit 4 generates a tracking error signal STE by performing arithmetic processing according to the following equation (4) based on the received light signals S1A, S1B, S1C, and S1D. This is supplied to the tracking control unit 3AT of the servo control unit 3A.

  Incidentally, in the equation (4), the operator φ represents the signal phase, and the phase difference is calculated as the whole equation.

  The focus control unit 3AF (FIG. 2) of the servo control unit 3A generates a focus drive signal SFD based on the focus error signal SFE and the pull-in signal PI1, and supplies this to the focus actuator 9F. The focus actuator 9F drives the objective lens 8 in the focus direction based on the focus drive signal SFD (hereinafter also referred to as focus control).

  Here, prior to the start of actual focus control, the optical disc apparatus 1 needs to perform a focus jump to move the focus F1 of the light beam L1 to the vicinity of the target recording layer YT (details will be described later).

  The optical disc apparatus 1 performs focus control repeatedly (that is, performs feedback control), thereby keeping the deviation amount of the focus F1 of the light beam L1 and the target recording layer YT in the focus direction within a predetermined range.

  The tracking control unit 3AT (FIG. 2) of the servo control unit 3A generates a tracking drive signal STD1 based on the tracking error signal STE and supplies it to the tracking actuator 9T. The tracking actuator 9T drives the objective lens 8 in the tracking direction based on the tracking drive signal STD1 (hereinafter referred to as tracking control).

  The optical disc apparatus 1 also repeatedly performs this tracking control (that is, performs feedback control), thereby setting the deviation amount in the tracking direction between the focal point F1 of the light beam L1 and a desired track in the target recording layer YT to an arbitrary target value. Converge.

  Thus, the optical disc apparatus 1 is adapted to adjust the focus F1 of the light beam L1 to a desired track in the target recording layer YT by performing focus control and tracking control.

  The optical disc apparatus 1 calculates the reproduction RF signal SRF by adding the received light signals S1A to S1D according to the following equation (5) in the reproduction signal calculation circuit 4R of the signal processing unit 4.

  The reproduction RF signal SRF corresponds to the total light amount of the reflected light beam LR0 composed of 0th order light and represents a signal recorded on the optical disc 100. Thereafter, the reproduction signal arithmetic circuit 4R reproduces information recorded on the optical disc 100 by performing predetermined demodulation processing, decoding processing, and the like on the reproduction RF signal SRF.

[1-5. Simulation of focus error signal and pull-in signal]
Hereinafter, the pull-in signal PI0 when the optical pickup 7 drives the objective lens 8 in the focus direction and moves the focus F1 of the light beam L1 so as to pass through the in-focus position of each recording layer Y (focus search is performed). A simulation result with the focus error signal SFE will be described.

  The recording layers Y0 to Y3 of the optical disc 100 used in this simulation have the cover layer thickness shown in FIG. The cover layer thickness indicates the distance from the disc surface 100A of the optical disc 100 shown in FIG.

  A spacer having a thickness shown in FIG. 7B is provided between the recording layers Y0 to Y3 of the optical disc 100.

  As shown in FIG. 7C, the 0th-order light quantity ratio of the regions 17A to 17E provided in the hologram element 17 is 74.9 [%]. The 0th-order light amount ratio indicates the ratio of the light amount of the reflected light beam LR0 that is the 0th-order light that travels straight through the hologram element 17 to the light amount of the reflected light beam LR incident on the hologram element 17.

  Further, as shown in FIG. 7D, the primary light quantity ratio by the regions 17A to 17E provided in the hologram element 17 is 10.2 [%]. The primary light quantity ratio indicates the ratio of the light quantity of the reflected light beam LR1 formed of the primary light diffracted by the hologram element 17 to the light quantity of the reflected light beam LR incident on the hologram element 17.

  As described above, in the optical disc device 1 according to the present embodiment, the pull-in signal calculation circuit 4P calculates the pull-in signal PI1 by performing the calculation according to the equation (2). On the other hand, in this simulation, the pull-in signal PI0 corresponding to the total light amount of the reflected light beam LR0 composed of 0th order light is calculated by adding the received light signals S1A to S1D according to the following equation (6).

  FIG. 8 shows the results of the received light signals S1A, S1B, S1C, and S1D generated by irradiating the light receiving unit D1 with the reflected light beam LR0, which is zero-order light that travels straight through the hologram element 17, out of the reflected light beam LR from the recording layer Y0. The characteristic curves of the focus error signal SFE and the pull-in signal PI0 are shown.

  Similarly, the focus error signal SFE and the pull-in signal PI0 by the reflected light beam LR0 that is the 0th-order light that travels straight through the hologram element 17 out of the reflected light beams LR from the recording layers Y1, Y2, and Y3 and the disk surface 100A are shown in FIG. 10, FIG. 11 and FIG.

  8 to 12, the horizontal axis indicates the in-focus position of the recording layer Y0 as 0 [μm], and the distance from the in-focus position to the focus direction is the defocus amount. The vertical axis is a relative value indicating the signal level.

  In the simulation shown in FIGS. 8 to 12, the optical disc apparatus 1 uses the recording layer Y0 as the target recording layer YT. At this time, the spherical aberration controller 3AS sets the spherical aberration corrector 14 so as to correct the spherical aberration when the focal point F1 of the light beam L1 is in the recording layer Y0 (in-focus state). Incidentally, the focus error signal SFE and the pull-in signal PI0 shown in FIGS. 8 to 12 are not affected by stray light from other layers.

  Here, the astigmatism method described above will be described together with the signal waveform of the focus error signal SFE, taking as an example the case where the focus F1 of the light beam L1 is focused on the recording layer Y0.

  When the focal point F1 of the light beam L1 is in the in-focus state of the recording layer Y0, the reflected light beam LR0 is evenly applied to the light receiving regions D1A, D1B, D1C, and D1D as shown in FIG. For this reason, the value of the focus error signal SFE is 0 level from the equation (1). Therefore, the focus error signal SFE has a signal level of a defocus amount of 0 [μm] shown in FIG.

  On the other hand, when the objective lens 8 comes close to the recording layer Y0 from the focused state of the recording layer Y0, as shown in FIG. 13A, the reflected light beam LR0 irradiates the light receiving areas D1A and D1C as compared with FIG. The area to be irradiated is reduced, and the area irradiated to the light receiving regions D1B and D1D is increased. For this reason, the value of the focus error signal SFE is negative from the equation (1). Accordingly, the focus error signal SFE has a signal level in the range of 0 to about −5 [μm] of the defocus amount shown in FIG. 8 in the simulation result.

  On the other hand, when the objective lens 8 is separated from the recording layer Y0 from the in-focus state of the recording layer Y0, as shown in FIG. 13C, the reflected light beam LR0 enters the light receiving regions D1A and D1C as compared with FIG. 13B. The irradiated area increases, and the area irradiated to the light receiving regions D1B and D1D decreases. For this reason, the value of the focus error signal SFE is positive from the equation (1). Accordingly, the focus error signal SFE has a signal level of 0 to about 5 [μm] of the defocus amount shown in FIG. 8 in the simulation result.

  Thus, the focus error signal SFE indicates a signal proportional to the defocus amount from the focus F1 of the light beam L1 to the focus position of the target recording layer YT from the focus position to a certain defocus amount. Thus, the focus error signal SFE draws a substantially S-shaped curve when the focal point F1 of the light beam L1 passes through the target recording layer YT. Hereinafter, the point where the substantially S-shaped curve of the focus error signal SFE intersects with the 0 level is also referred to as a zero cross point.

  Similarly, with respect to the recording layers Y1, Y2, Y3 and the disc surface 100A, the zero cross point of the focus error signal SFE is the in-focus position of each recording layer Y and the disc surface 100A as shown in FIGS.

  As described above, the optical disc apparatus 1 calculates the focus error signal SFE by the astigmatism method.

  By the way, in this simulation, the optical disc apparatus 1 sets the recording layer Y0 as the target recording layer YT. At this time, the spherical aberration controller 3AS sets the spherical aberration corrector 14 so as to correct the spherical aberration in the focused state of the recording layer Y0.

  For this reason, the spherical aberration correction unit 14 cannot correct the spherical aberration as the focal point F1 of the light beam L1 moves away from the recording layer Y0, and the focused spot of the light beam L1 irradiated on the recording layer Y of the optical disc 100 is changed. It will deteriorate extremely. As a result, as shown in FIGS. 9 to 12, the detected amplitude of the focus error signal SFE becomes smaller than that in FIG.

  Further, as shown in the equation (6), the pull-in signal PI0 has a signal level corresponding to the light amount of the reflected light beam LR0.

  Therefore, the signal level of the pull-in signal PI0 increases when the focal point F1 of the light beam L1 comes close to a layer having a predetermined reflectance such as the recording layer Y or the disk surface 100A. As a result, as shown in FIGS. 8 to 12, the pull-in signal PI0 has its maximum value near the zero cross point of the focus error signal SFE.

  As described above, the pull-in signal PI0 has its maximum value in the vicinity of the in-focus position of the recording layer Y and the disc surface 100A. Therefore, the optical disc apparatus 1 can determine the approximate position of the recording layer Y from the maximum value of the pull-in signal PI0. Thereby, the optical disc apparatus 1 can use the pull-in signal PI0 when performing the focus jump.

[1-6. Focus jump and focus control based on simulation results]
When the focus error signal SFE and the pull-in signal PI0 in FIGS. 8 to 12 are added, the focus error signal SFE and the pull-in signal PI0 shown in FIG. 14 are obtained.

  In the pull-in signal PI0, five local maximum values appear in the vicinity of the in-focus positions of the recording layers Y0 to Y3 and the disc surface 100A. In the focus error signal SFE, in the in-focus positions of the recording layers Y0 to Y3 and the disc surface 100A. Five zero-cross points appear. In the pull-in signal PI0, three local minimum values appear between the local maximum values in the vicinity of the in-focus positions of the recording layers Y0 to Y3 and the local maximum values of the adjacent recording layers Y.

  As described above, in this simulation, the optical disc apparatus 1 uses the recording layer Y0 as the target recording layer YT, and the spherical aberration control unit 3AS uses the spherical aberration correction unit 14 to correct the spherical aberration in the focused state of the recording layer Y0. It is set.

  FIG. 14 is a sum of the focus error signal SFE and the pull-in signal PI0 on the recording layers Y0 to Y3 and the disc surface 100A when the spherical aberration in the focused state of the recording layer Y0 is corrected. The influence of the interlayer stray light beam LN reflected by the layer Y appears.

  Incidentally, as described above, the focus error signal SFE is calculated by calculation according to the equation (1). For this reason, as shown in FIG. 6, even if the stray light pattern W is applied to each of the light receiving regions D1A, D1B, D1C, and D1D, the focus error signal SFE is expressed by the light receiving signals S1A, S1B, S1C, and S1D according to the equation (1). The influence of the stray light contained in is canceled.

  Here, based on the focus error signal SFE and the pull-in signal PI0 shown in FIG. 14, focus jump and focus control from the recording layer Y0 to the recording layer Y1 performed by the optical disc apparatus 1 will be described.

  When performing a focus jump from the recording layer Y0 to the recording layer Y1, the focus control unit 3AF supplies a kick pulse as a focus drive signal SFD to the focus actuator 9F to move the objective lens 8 greatly in the direction of the recording layer Y1. As a result, the focus control unit 3AF moves the focus F1 of the light beam L1 from the focus position of the recording layer Y0 that is currently focused to the focus position direction of the next recording layer Y1.

  The focus control unit 3AF measures the change rate of the pull-in signal PI0 while largely moving the objective lens 8 by the focus jump.

  Subsequently, based on the change rate, the focus control unit 3AF further supplies a kick pulse to the focus actuator 9F, or supplies a brake pulse as the focus drive signal SFD to the focus actuator 9F to stop the movement of the objective lens 8 Make a decision.

  Specifically, the focus control unit 3AF determines that the focal point F1 of the light beam L1 is between the recording layer Y0 and the recording layer Y1 when the signal level of the pull-in signal changes so as to increase after decreasing. Further, a kick pulse is supplied to the focus actuator 9F.

  For this reason, in the pull-in signal PI0, the larger the change rate (that is, the differential amount) near the minimum value between the maximum value due to the currently focused recording layer Y and the maximum value due to the next target recording layer YT, the larger the optical disc. The apparatus 1 can perform a focus jump with high accuracy.

  Here, the ratio of the minimum value appearing between the recording layer Y adjacent to the target recording layer YT and the maximum value appearing in the vicinity of the in-focus position of the target recording layer YT in the pull-in signal PI0 is defined as a minimum value ratio MR. In the pull-in signal PI0, the lower the minimum value ratio MR, the greater the rate of change near the minimum value.

  When the focus F1 of the light beam L1 is positioned in the vicinity of the in-focus position of the recording layer Y1 due to the focus jump, the focus control unit 3AF performs focus control to finely move the objective lens 8, and the focus F1 of the light beam L1 is moved to the recording layer Y1. Focus on.

  At this time, the focus control unit 3AF determines that the zero cross point of the focus error signal SFE is focused on the recording layer Y1 in a state where the signal level of the pull-in signal PI0 is equal to or higher than a predetermined threshold (eg, 320 level).

  The focus control unit 3AF determines that the focus F1 of the light beam L1 is not in the vicinity of the in-focus position of the recording layer Y1 when the signal level of the pull-in signal PI0 is less than a predetermined threshold (eg, 320 level).

  Therefore, in order for the focus control unit 3AF to use for the focus jump and focus control, the pull-in signal PI0 needs to be greater than or equal to a predetermined threshold value at the maximum value and less than the predetermined threshold value at the minimum value. Incidentally, when the difference in signal level between the maximum value appearing in the vicinity of the in-focus position of the predetermined recording layer Y in the pull-in signal and the minimum value appearing between the recording layer Y adjacent to the recording layer Y is large, the minimum value ratio MR is low.

  Thus, the optical disc apparatus 1 performs focus jump and focus control based on the focus error signal SFE while using the pull-in signal PI0 as an auxiliary signal.

  By the way, FIG. 14 is the sum of the focus error signal SFE and the pull-in signal PI0 in FIGS. 8 to 12, so that the influence of the interlayer stray light beam LN reflected by the other recording layer Y appears. Yes.

  That is, the light receiving unit D1 (FIG. 6) is irradiated with the reflected light beam LR0 that is zero-order light that travels straight without being diffracted by the hologram element 17. At the same time, the 0th-order light of the interlayer stray light beam LN that has traveled straight without being diffracted by the hologram element 17 in the interlayer stray light beam LN is also irradiated to the light receiving portion D1.

  Since the interlayer stray light beam LN travels the same path as the reflected light beam LR, the 0th-order light obtained by the interlayer stray light beam LN traveling straight through the hologram element 17 is the same light receiving unit as the reflected light beam LR0 that is the 0th-order light of the reflected light beam LR. D1 is irradiated.

  In the optical pickup 7 according to the present embodiment, it is difficult to avoid such irradiation of the zero-order light of the interlayer stray light beam LN to the light receiving part D1. Further, as the layer interval, which is the interval between the recording layer Y reflected by the interlayer stray light beam LN and the target recording layer YT, is narrower, the light amount of the stray light interlayer beam LN irradiated to the light receiving unit D1 as shown in FIG. Therefore, the influence of the interlayer stray light beam LN appears in the pull-in signal PI0.

  For this reason, a part of the peak waveform of each recording layer Y of the pull-in signal PI0 overlaps a part of the peak waveform in the adjacent recording layer Y. In particular, since the spacer thickness between the recording layer Y2 and the recording layer Y3 is as narrow as 12 [μm] (FIG. 7), it is difficult to determine the position of the maximum value for the recording layer Y2 and the recording layer Y3.

  That is, as described above, when the threshold value of the pull-in signal PI0 used as the auxiliary signal of the focus error signal SFE when performing focus control is set to 320 levels, between the recording layer Y2 and the recording layer Y3, The signal level of the pull-in signal PI0 always exceeds the threshold value, and the signal cannot be used as a criterion for performing focus control.

  As described above, since the signal level of the minimum value of the pull-in signal PI0 is not sufficiently small with respect to the maximum value, the optical disc apparatus 1 cannot determine the position of the maximum value of the pull-in signal PI0, and determines the approximate position of the recording layer Y. It becomes difficult to do.

  Further, since the signal level of the minimum value of the pull-in signal PI0 is not sufficiently small with respect to the maximum value, the change rate of the minimum value adjacent to the maximum value is also reduced. This makes it difficult for the optical disc apparatus 1 to determine whether or not the focal point F1 of the light beam L1 is between the recording layer Y and the adjacent recording layer Y.

  This makes it difficult for the optical disc apparatus 1 to use the pull-in signal PI0 as an auxiliary signal for focus jump and focus control.

[1-7. Focus jump and focus control according to this embodiment]
The above is a sum signal obtained by adding the received light signals S1A, S1B, S1C, and S1D generated by irradiating the light receiving regions D1A, D1B, D1C, and D1D of the light receiving unit D1 with the reflected light beam LR0 that is zero-order light. The pull-in signal PI0 as described above has been described.

  Next, FIG. 15 shows a pull-in signal PI1 as a sum signal obtained by adding the light reception signals S2A and S2B in the present embodiment. The light receiving signals S2A and S2B are signals generated by irradiating the light receiving regions D2A and D2B with the reflected light beams LR1A and LR1B including the push-pull component of the reflected light beam LR1 that is primary light.

  In the pull-in signal PI1 shown in FIG. 15, the optical disc apparatus 1 uses the recording layer Y0 as the target recording layer YT as in FIG. 14, and the spherical aberration control unit 3AS determines the spherical aberration in the focused state of the recording layer Y0. The spherical aberration correction unit 14 is set to correct.

  As shown in FIG. 6, the light receiving regions D2A and D2B are arranged at positions where the 0th-order light in which the interlayer stray light beam LN travels straight through the hologram element 17 is not irradiated. For this reason, the light reception signals S2A and S2B are signals that avoid the influence of the zero-order light of the interlayer stray light beam LN.

  In addition, the light receiving areas D2A and D2B are arranged so that the stray light patterns W1A and W1B from the adjacent recording layer Y where the irradiation range is minimized are not applied. Therefore, the light reception signals S2A and S2B are signals that avoid the influence of the stray light patterns W1A and W1B.

  Since the reflected light beams LR1A and LR1B are based on the reflected light beam LR similarly to the reflected light beam LR0, the pull-in signal PI1 of the light reception signals S2A and S2B by the reflected light beams LR1A and LR1B is as shown in FIG. The maximum value appears with the same defocus amount as the pull-in signal PI0 for the recording layer Y0.

  As shown in FIG. 15, the pull-in signal PI1 is smaller than the pull-in signal PI0, and the minimum value between the recording layer Y adjacent to the recording layer Y and the maximum value near the in-focus position of the predetermined recording layer Y. And the signal level difference is much larger, and the minimum value ratio MR is kept low.

  In particular, even between the recording layer Y2 and the recording layer Y3 where the spacer thickness is small, the pull-in signal PI1 has a signal level that has fallen to a minimum value of about 12 levels. Compared to the maximum value of about 17 levels adjacent to the minimum value, The minimum value ratio MR is sufficiently suppressed.

  If the threshold level of the pull-in signal PI1 used as an auxiliary signal for the focus error signal SFE when performing focus control is set to 14 levels, the minimum value between the recording layer Y2 and the recording layer Y3 is less than the threshold value. ing.

  Since the minimum value ratio MR is kept low, the pull-in signal PI1 has a much larger change rate near the minimum value than the pull-in signal PI0 shown in FIG.

  Incidentally, as shown in FIG. 7, the hologram element 17 has a zero-order light amount ratio of 74.9 [%] and a primary light amount ratio of 10.2 [%]. Therefore, the amount of light received by the light receiving regions D2A and D2B is smaller than the amount of light received by the light receiving regions D1A, D1B, D1C, and D1D of the light receiving unit D1. As a result, the pull-in signal PI1 has a lower signal level than the pull-in signal PI0.

  On the other hand, the optical disk apparatus 1 can obtain a sufficient signal level of the pull-in signal PI1 by adjusting the diffraction efficiency in each region of the hologram element 17 and increasing the amplification factor of the received light signal by the head amplifier 22.

  FIG. 16 shows a focus error signal SFE and a pull-in signal when the target recording layer YT is the recording layer Y0 and the spherical aberration correction unit 14 is set by the spherical aberration control unit 3AS to correct the spherical aberration in the focused state of the recording layer Y0. The simulation result of PI0 (FIG. 14) and the pull-in signal PI1 (FIG. 15) are shown.

  17 to 19, the target recording layer YT is set as the recording layers Y1 to Y3, respectively, and the spherical aberration correction unit 14 is set so that the spherical aberration control unit 3AS corrects the spherical aberration in the focused state of each recording layer Y1 to Y3. The simulation results of the focus error signal SFE and the pull-in signal PI0 and the pull-in signal PI1 are shown.

  Here, the defocus amount on the horizontal axis is the focus position of the target recording layer YT being 0 [μm], the left vertical axis is the relative value of the signal level by the pull-in signal PI0, and the right vertical axis is by the pull-in signal PI1. Indicates the relative value of the signal level.

  As shown in FIGS. 16 to 19, even if the spherical aberration correction unit 14 is set so as to correct the spherical aberration when focusing on which recording layer Y, the pull-in signal PI0 is between the maximum values. As a result, the signal level gradually changes, the signal level difference between the minimum values for each maximum value is small, and the minimum value ratio MR is high. In other words, it can be said that the pull-in signal PI0 is in a state where it is difficult to separate the local maximum values.

  On the other hand, the pull-in signal PI1 has a sufficiently large signal level difference between the maximum value and the minimum value adjacent to each other, regardless of which recording layer Y is set for spherical aberration correction. The ratio MR is kept low. Therefore, it can be seen that the maximum value of each recording layer Y is separated from the pull-in signal PI1.

  As a result, the optical disc apparatus 1 can accurately determine the approximate position of the recording layer Y, and whether or not the focal point F1 of the light beam L1 is between the recording layer Y and the adjacent recording layer Y is also accurate. Judgment can be made. Thus, the optical disc apparatus 1 can use the pull-in signal PI1 as an auxiliary signal for the focus error signal SFE.

[1-8. Simulation of spacer thickness]
As described above, the pull-in signal PI0 is affected by the interlayer stray light beam LN as the layer interval of the optical disc 100 becomes narrower, and the minimum value thereof cannot be lowered, and the maximum value and the maximum value are connected.

  A simulation of the focus error signal SFE, the pull-in signal PI0, and the pull-in signal PI1 when the layer interval is changed will be described.

  Specifically, consider an optical disc 100 having two recording layers Y, a recording layer Y0 and a recording layer Y1, each having the same reflectivity. Here, for example, if the recording layer Y0 has been recorded and the recording layer Y1 has not been recorded, the difference in reflectance between the recording layer Y0 and the recording layer Y1 is about 50%.

  At this time, the reflectivity changes by 50 [%] only by the difference between recorded and unrecorded recording layer Y. Therefore, if the minimum value ratio MR of the pull-in signal is not less than 50 [%], reflection due to recorded and unrecorded The change in the light amount of the light beam exceeds the change in the light amount of the reflected light beam due to the maximum value and the minimum value of the pull-in signal.

  In this case, whether the optical disc apparatus 1 has changed the pull-in signal due to the movement of the focal point F1 with respect to the recording layer Y, or has the reflectance changed due to the difference between recorded and unrecorded and the amount of reflected light beam has changed? Cannot be judged.

  For this reason, the minimum value ratio MR of the pull-in signal needs to be less than 50 [%], and it is desirable that the minimum value ratio MR is low even if the layer interval between two recording layers, that is, the spacer thickness is narrowed.

  20 to 24 show simulation results of the focus error signal SFE, the pull-in signal PI0, and the pull-in signal PI1 in the optical disc 100 having the two recording layers Y of the recording layer Y0 and the recording layer Y1.

  20 to 24, the thickness of the spacer between the recording layer Y0 and the recording layer Y1 is 25, 22, 20, 18, and 16 [μm], respectively.

  FIG. 25 shows the minimum value ratio MR of each of the pull-in signal PI0 and the pull-in signal PI1 according to the spacer thickness, which summarizes the simulation results shown in FIGS. Incidentally, as shown in FIGS. 20 to 24, two local maximum values of the pull-in signal appear, and the ratio of the local minimum value to the average value of the signal levels of these local maximum values is defined as the local minimum ratio MR.

  From FIG. 25, in both the pull-in signal PI0 and the pull-in signal PI1, the minimum value ratio MR gradually increases as the spacer thickness decreases. The pull-in signal PI0 has a minimum value ratio MR of 50 [%] or more when the spacer thickness is 21 [μm] or less.

  For this reason, when the pull-in signal PI0 is used, the optical disc apparatus 1 cannot determine the position of the maximum value of the pull-in signal PI0 when the spacer thickness is 21 [μm] or less, and it is difficult to determine the approximate position of the recording layer Y. .

  As a result, the optical disk apparatus 1 cannot use the pull-in signal PI0 as an auxiliary signal for focus jump and focus control when the spacer thickness is 21 [μm] or less.

  On the other hand, the pull-in signal PI1 has a minimum value ratio MR of about 0 [%] when the spacer thickness is 21 [μm]. Even when the spacer thickness is further reduced to 16 [μm], the minimum value ratio MR is suppressed to about 10 [%].

  Incidentally, the spacer thickness of the optical disk in a general two-layer BD is about 25 [μm]. When the spacer thickness is 25 [μm], the minimum value ratio MR is about 40 [%] in the pull-in signal PI0, which is close to 50 [%], but in the pull-in signal PI1, the minimum value ratio MR is about 0 [%]. %].

  For this reason, the optical disc 100 according to the present embodiment does not have the four recording layers Y and uses the pull-in signal PI1 rather than the pull-in signal PI0 even for the optical disc having the two recording layers. However, the optical disc apparatus 1 can perform focus jump and focus control more stably.

  Thus, the pull-in signal PI1 has a minimum value ratio MR that is kept low even when the spacer thickness is narrower than the pull-in signal PI0. Accordingly, the optical disc apparatus 1 can perform focus jump and focus control more stably by using the pull-in signal PI1.

[1-9. Operation and effect]
In the above configuration, the optical pickup 7 of the optical disc apparatus 1 irradiates the optical disc 100 with the light beam L1 and causes the reflected light beam LR and the interlayer stray light beam LN reflected by the optical disc 100 to enter the hologram element 17.

  The hologram element 17 causes the reflected light beam LR0 composed of zero-order light and the zero-order light of the interlayer stray light beam LN to travel substantially straight and reflects the primary light for each of the regions 17A to 17E (FIG. 4A). The light beam LR1 and the primary light of the interlayer stray light beam LN are diffracted.

  At this time, the hologram element 17 diffracts the reflected light beams LR1A and LR1B in the vertical direction, diffracts the reflected light beams LR1C and LR1D, respectively, and further diffracts the reflected light beam LR1E in an oblique direction.

  In response to this, the photodetector 19 receives the 0th order light of the reflected light beam LR0 and the interlayer stray light beam LN by the light receiving regions D1A to D1D of the light receiving unit D1, and generates light receiving signals S1A to S1D.

  Based on the received light signals S1A to S1D amplified by the head amplifier 22, the signal processing unit 4 calculates the focus error signal SFE according to the equation (1) by the focus error signal calculation circuit 4F.

  The photodetector 19 receives the reflected light beams LR1A and LR1B by the light receiving regions D2A and D2B of the light receiving unit D2 arranged so as to avoid the stray light pattern W of the primary light of the interlayer stray light beam LN, and receives the received light signals S2A and S2A. S2B is generated.

  The servo control unit 3A performs focus jump and focus control by generating a focus drive signal SFD based on the focus error signal SFE and the pull-in signal PI1 by the focus control unit 3AF and supplying the focus drive signal SFD to the focus actuator 9F.

  Based on the received light signals S2A and S2B amplified by the head amplifier 22, the signal processing unit 4 calculates the pull-in signal PI1 by the pull-in signal arithmetic circuit 4P according to the equation (2).

  Therefore, the pull-in signal calculation circuit 4P can calculate the pull-in signal PI1 avoiding the influence of the interlayer stray light beam LN.

  Accordingly, the optical disc apparatus 1 can obtain the pull-in signal PI1 in which the minimum value ratio MR is suppressed to be lower than that of the pull-in signal PI0 affected by the interlayer stray light beam LN.

  Further, since the minimum value ratio MR is kept low, the optical disc apparatus 1 has a rate of change near the minimum value between the maximum value due to the recording layer Y and the maximum value due to the adjacent recording layer Y compared to the pull-in signal PI0. Large pull-in signal PI1 can be obtained.

  Therefore, the optical disc apparatus 1 can determine the position where the pull-in signal PI1 takes the maximum value as the approximate position of the recording layer Y.

  Thus, the optical disc apparatus 1 can perform the focus jump with high accuracy even when the layer interval of the optical disc 100 is narrowed.

  According to the above configuration, the optical disc apparatus 1 generates the focus error signal SFE based on the reflected light beam LR0 that is zero-order light. The optical disc apparatus 1 receives the reflected light beams LR1A and LR1B of the primary light by the light receiving regions D2A and D2B of the light receiving unit D2 arranged so as to avoid the stray light pattern W of the interlayer stray light beam LN, respectively, and pull-in signal PI1. Is generated. Subsequently, the optical pickup 7 performs focus jump and focus control based on the focus error signal SFE and the pull-in signal PI1. As a result, the optical disc apparatus 1 can generate the pull-in signal PI1 excluding the influence of the stray light pattern W formed by the interlayer stray light beams LN from the plurality of recording layers Y, and can perform focus jump and focus control with high accuracy. .

<2. Other embodiments>
In the above-described embodiment, the case where the sum signal obtained by adding the light reception signals S2A and S2B is used as the pull-in signal PI1 has been described.

  However, the present invention is not limited to this, and only one of the light reception signals S2A or S2B may be used as the pull-in signal PI1. However, since the signal level is higher when only the received light signals S2A and S2B are added, focus jump and focus control can be performed with higher accuracy than when only one of the received light signals is used.

  In the above-described embodiment, the light reception signal by the light reception regions D2A and D2B irradiated with the reflected light beams LR1A and LR1B including a large amount of push-pull components in the reflected light beam LR1 composed of the primary light is used as the pull-in signal PI1. Said about the case.

  However, the present invention is not limited to this, and a light reception signal from the light reception regions D3C and D3D irradiated with the reflected light beams LR1C and LR1D including a large amount of the lens shift component of the reflected light beam LR1 may be used as the pull-in signal PI1.

  However, as in the configuration of the hologram element 17 shown in FIG. 4, the area obtained by adding the regions 17A and 17B for diffracting the reflected light beams LR1A and LR1B has a region 17C for diffracting the reflected light beams LR1C and LR1D. The area is larger than the sum of 17C2 and 17D1 and 17D2.

  For this reason, the light quantity irradiated to the light receiving areas D2A and D2B is larger than the light quantity irradiated to the light receiving areas D3C and D3D. As a result, the signal level of the light reception signal also increases, and the focus jump and focus control can be performed with higher accuracy than when the light reception signals S3C and S3D are used, compared to the case where the light reception signals S2A and S2B are used.

  Also, when using the light reception signals from the light reception areas D3C and D3D, only the one light reception signal of the light reception signals S3C or S3D may be used as the pull-in signal PI1 as in the light reception areas D2A and D2B. However, since the signal level is higher when only the received light signals S3C and S3D are added, focus jump and focus control can be performed with higher accuracy than when only one received light signal is used.

  The pull-in signal PI1 may be obtained by adding the light reception signals from the light reception regions D3C and D3D to the light reception signals from the light reception regions D2A and D2B.

  In this case, since the signal level is higher than in the case of only the light receiving signals from the light receiving areas D2A and D2B, the optical disc apparatus 1 can perform focus jump and focus control with high accuracy.

  Furthermore, in the above-described embodiment, the case where the light receiving part D2 is provided at a place spaced apart from the reference point P of the photodetector 19 in the vertical direction and the light receiving part D3 is provided at a place spaced apart from the reference point P in the horizontal direction will be described. It was.

  However, the present invention is not limited to this, and the photodetector 19 may be provided with various light receiving areas. In this case, the photodetector 19 avoids the irradiation of stray light by the central portion by removing the central portion of the reflected light beam LR1, and receives light outside the irradiation range of stray light caused by other portions of the reflected light beam LR1. An area may be arranged.

  In short, the optical disc apparatus 1 uses, as a pull-in signal, a light reception signal obtained by an arbitrary number of light receiving regions having various shapes and sizes arranged at various positions so that the stray light pattern W by the interlayer stray light beam LN is not irradiated. Use it.

  Further, in the above-described embodiment, the case where the reflected light beam LR is diffracted by the hologram element 17 has been described.

  However, the present invention is not limited to this, and various optical elements capable of separating a light beam may be used. In this case, it is only necessary to irradiate the predetermined light receiving region in the photodetector 19 with the reflected light beam LR and avoid irradiation with the interlayer stray light beam LN.

  Further, in the above-described embodiment, the case where the light receiving portions D2 and D3 in the detector 19 are arranged so as to avoid the irradiation of the interlayer stray light beam LN has been described.

  However, the present invention is not limited to this, and the light receiving portions D2 and D3 in the photodetector 19 may be irradiated as long as the interlayer stray light beam LN is up to a certain extent. In this case, for example, in the pull-in signal obtained by performing the focus search for all the recording layers of the optical disc, if the minimum value ratio MR of the maximum value in all the recording layers to the adjacent minimum value is less than 50 [%]. good.

  Further, in the above-described embodiment, the case where the light receiving portions D2 and D3 are not irradiated with the stray light pattern W of the interlayer stray light beam LN has been described.

  However, the present invention is not limited to this. For example, even if a lens shift of the objective lens 8 occurs and the interlayer stray light beam LN moves along with this, the stray light pattern W of the interlayer stray light beam LN is irradiated on the light receiving unit D2 or D3. good.

  In this case, for example, when the light receiving area D2A is irradiated with the stray light pattern W1B, the stray light receiving area D2P is also irradiated with the stray light pattern W1B. Therefore, the light receiving area D2A is received using the light receiving signal S2P by the stray light receiving area D2P. What is necessary is just to cancel the influence of the irradiated stray light pattern W1B.

  Further, in the above-described embodiment, the case where the focus error signal calculation circuit 4F calculates the focus error signal SFE by the astigmatism method has been described.

  However, the present invention is not limited to this, and various focus error signal calculation methods such as an SSD (Spot Size Detection) method may be used. In that case, a photodetector corresponding to various focus error signal calculation methods may be used.

  Further, in the above-described embodiment, the case where focus jump and focus control are performed on the optical disc 100 having the four recording layers Y has been described.

  However, the present invention is not limited to this, and may be applied to the case where an optical disc having an arbitrary number of recording layers Y is used. In this case, the effect of the present invention becomes more remarkable as the number of recording layers Y increases and the spacer thickness between the recording layers Y decreases.

  Furthermore, in the above-described embodiment, the laser diode 11 as the light source, the objective lens 8 as the objective lens, the biaxial actuator 9 as the lens moving unit, the condenser lens 16 as the condenser lens, and the light separation The case where the optical pickup 7 as the optical pickup is configured by the hologram element 17 as the element and the photodetector 19 as the photodetector has been described.

  However, the present invention is not limited to this, and an optical pickup is configured by a light source having various other circuit configurations, an objective lens, a lens moving unit, a condenser lens, a light separation element, and a photodetector. May be.

  Furthermore, in the above-described embodiment, the laser diode 11 as the light source, the objective lens 8 as the objective lens, the biaxial actuator 9 as the lens moving unit, the condenser lens 16 as the condenser lens, and the light separation An optical disk device 1 as an optical disk device is configured by a hologram element 17 as an element, a photodetector 19 as a photodetector, a signal processing unit 4 as a signal processing unit, and a servo control unit 3A as a servo control unit. Said about the case.

  However, the present invention is not limited to this, and a light source having various other circuit configurations, an objective lens, a lens moving unit, a condenser lens, a light separation element, a photodetector, a signal processing unit, and servo control. The optical disk apparatus may be configured by the unit.

  The present invention can also be used in an optical disc apparatus that records information such as video, audio or various data on an optical disc and reproduces the information from the optical disc.

  DESCRIPTION OF SYMBOLS 1 ... Optical disk apparatus, 2 ... General control part, 3 ... Drive control part, 3A ... Servo control part, 3AT ... Tracking control part, 3AF ... Focus control part, 3AS ... Spherical aberration control part, 4 ...... Signal processing unit, 4T. Tracking error signal arithmetic circuit, 4F. Focus error signal arithmetic circuit, 4P .. Pull-in signal arithmetic circuit, 4R .. Playback signal arithmetic circuit, 5 ... Spindle motor, 6 ... Thread Motor, 7 ... Optical pickup, 8 ... Objective lens, 9 ... Biaxial actuator, 9T ... Tracking actuator, 9F ... Focus actuator, 11 ... Laser diode, 12 ... Collimator lens, 13 ... Polarized beam Splitter, 14 ... spherical aberration correction unit, 15 ... 1/4 wavelength plate, 16 ... condensing lens, 17 ... hologram element , 17A, 17B, 17C1, 17C2, 17D1, 17D2, 17E... Region, 18 ... cylindrical lens, 19 ... photodetector, 21 ... light source controller, 22 ... head amplifier, 100 ... optical disc, L ... Recording layer YT ... Target recording layer, 100A ... Disk surface, D1, D2, D3, D4 ... Light-receiving area group, D1A, D1B, D1C, D1D, D2A, D2B, D3C, D3D ... Light-receiving area, S1A, S1B, S1C, S1D, S2A, S2B, S3C, S3D... Light receiving signal, L1... Light beam, LR... Reflected light beam, LN ... Interlayer stray light beam, W. Error signal, SFE: Focus error signal, PI0, PI1 ... Pull-in signal.

Claims (5)

A light source that emits a light beam;
An objective lens that focuses the light beam on a target recording layer among a plurality of recording layers provided on an optical disc;
A lens moving unit that moves the objective lens in a focus direction that is in contact with and away from the target recording layer;
A condensing lens for condensing a reflected light beam formed by reflecting the light beam by the optical disc;
A light separating element for separating the reflected light beam into a plurality of light beams traveling in different directions;
By a light receiving region arranged outside the irradiation range of the stray light pattern caused by the interlayer stray light that is reflected by the recording layer other than the target recording layer in the optical disc, a part of the light beam irradiated on the optical disc, A photodetector that receives the reflected light beam separated by the light separation element and generates a light reception signal;
A signal processing unit that generates a pull-in signal representing the amount of the reflected light beam based on the light reception signal generated by the light receiving region;
And a servo control unit that moves the objective lens in the focus direction via the lens moving unit based on the pull-in signal, and adjusts the focus of the objective lens to the target recording layer. The light detector is separated by the light separation element, and a push-pull component of the light beam whose light amount fluctuates when the focal point of the light beam is displaced to the inner or outer peripheral side with respect to a desired track of the optical disc. Is received by a light receiving region arranged outside the irradiation range of the stray light pattern caused by the interlayer stray light, and the light reception signal is generated,
The optical disc apparatus according to claim 1, wherein the signal processing unit generates a pull-in signal representing a light amount of the reflected light beam based on a light reception signal of the push-pull component. The light detector is separated by the light separation element, and a push-pull component of the light beam whose light amount fluctuates when the focal point of the light beam is displaced to the inner or outer peripheral side with respect to a desired track of the optical disc. And a light receiving area separated from the stray light pattern caused by the interlayer stray light, the lens shift component of the light beam separated by the light separation element and representing the displacement of the objective lens with respect to the tracking direction of the optical disc. Receive the light and generate the light reception signal,
The optical disc apparatus according to claim 2, wherein the signal processing unit generates a pull-in signal representing a light amount of the reflected light beam based on the light reception signals of the push-pull component and the lens shift component. The light detector is separated by the light separation element, and the lens shift component of the light beam representing the displacement of the objective lens with respect to the tracking direction of the optical disk is disposed outside the irradiation range of the stray light pattern caused by the interlayer stray light. Received by the received light receiving region to generate the light reception signal,
The optical disc apparatus according to claim 1, wherein the signal processing unit generates a pull-in signal representing a light amount of the reflected light beam based on a light reception signal of the lens shift component. The photodetector detects a reflected light beam in which a shape of a beam spot formed in a light receiving region arranged at a predetermined position changes when a focal point of the objective lens with respect to the focus direction is shifted with respect to the target recording layer. , Receive light by the light receiving region and generate a light reception signal,
The signal processing unit generates a focus error signal representing a focus shift amount of the objective lens with respect to the target recording layer with respect to the focus direction based on a light reception signal generated by the light reception region;
The servo control unit moves the objective lens in the focus direction via the lens moving unit based on the focus error signal and the pull-in signal, and focuses the objective lens on the target recording layer. An optical disk device according to the above.

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