JP3386386B2 - Optical pickup device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pickup device, and more particularly to an optical pickup device used in an optical disc device for optically recording and reproducing information. recent years,
Optical disc devices are becoming thinner. Along with this, the optical pickup device is required to be thin.

The height dimension of the optical pickup device means the dimension from the lower end of the raising mirror to the label surface (upper surface) of the optical disk.

[0003]

2. Description of the Related Art FIG. 7 shows an example of a conventional optical pickup device 10 which is designed to be thin. In order to reduce the thickness of the optical pickup device 10, first, a light emitting unit 11 in which a semiconductor laser, a photodetector, a diffraction grating, and a hologram element (both not shown) having a deflecting and spectroscopic function are integrated. Secondly, it has a configuration including a finite system objective lens 12 in which the collimator lens can be omitted.

The three light beams 13 emitted from the light emitting unit 11 are reflected by a rising mirror 14 having a rising angle φ ₀ set to 45 degrees and vertically deflected, and are collected by an objective lens 12. Upon irradiation with light, three minute spots (not shown) are formed on the recording surface 15a of the optical disc 15. Reference numeral 17 is an object point, and 18 is an image point.

The light beam 13 is reflected by the recording surface 15a. The reflected light beam 16 returns to the light emitting unit 11 via the objective lens 12 and the raising mirror 14. Each light beam returned to the light emitting unit 11 is a light detector (not shown).
The focus error signal, the tracking error signal, and the reproduction signal are extracted.

An actuator (not shown) is driven by the focus error signal, the objective lens 12 is displaced in the Z direction (vertical direction), and the focus shift is corrected. An actuator (not shown) is driven by the tracking error signal, the objective lens 12 is displaced in the horizontal direction, and the tracking deviation is corrected. The optical pickup device 10 described above has a height dimension h ₀ .

Although the optical pickup device 10 is made thin by using the small-sized light emitting unit 11 and incorporating the finite system objective lens 12 as described above, it is not sufficient. FIG. 8 shows another conventional optical pickup device 20. In FIG. 8, parts corresponding to the parts shown in FIG. 7 are designated by the same reference numerals.

This optical pickup device 20 is disclosed in
-189932 or JP-A-5-120723
It has been disclosed in the report. This optical pickup device
The stand 20 has a rising angle φ of the rising mirror 14.₁'45 degrees
As a configuration that is set to a smaller angle (for example, 40 degrees)
is there. The rising angle φ of the rising mirror 14₁'From 45 degrees
Is also a small angle, the lower end of the light emitting unit 11
It is located above the lower end of the rising mirror 14 and has a light emitting unit.
The protrusion of the lower part of the hood 11 disappeared, and the startup
Height of Ra 14 a ₀'Is the corresponding dimension a in FIG.₀Yo
Becomes smaller. As a result, the optical pickup device 20
Height dimension h₀′ Is for the optical pickup device 10 of FIG.
Height dimension h₀The optical pickup device 20 is smaller and
7 is thinner than the device 10 of FIG.

The rising angle φ ₁ 'of the rising mirror 14 and the angle φ of the light beam deflected by the rising mirror 14
'Between the, phi _{2' 2} relationship of = 2 [phi ₁ '. 45
The light emitting unit 11 is arranged so that the light beam reflected by the rising mirror 14 which is tilted in a horizontal direction at a higher angle goes straight up.
Its optical axis 11a is provided in a direction of angle phi ₃ 'inclined downward with respect to the horizontal.

Reference numeral 21 denotes a lens holder, which is an objective lens 1
Surrounds 2 and supports this. The lens holder 21 is reflected by the raising mirror 14 to the lower end side,
It has an aperture stop 21a for narrowing the light beam incident on. The finite objective lens 12 has a convex upper surface 12a that is convex upward.
And a convex lower surface 12b that is convex downward.

Reference numeral 12c is the intersection of the optical axis 12d of the objective lens 12 and the convex upper surface 12a, that is, the top of the convex upper surface 12a. H ₁ is the height of the top portion 12c of the convex upper surface 12a. 12e is the intersection of the optical axis 12d of the objective lens 12 and the convex lower surface 12b, that is, the top of the convex lower surface 12b.

H ₂ is the height of the top portion 12e of the convex lower surface b. In the optical pickup device 20 of FIG. 8, the aperture stop 21a is located below the height H ₂ . The light emitting unit 11 is arranged at the height H ₃ . The upper end 11a of the light emitting unit 11 is located below the height H ₁ .

[0013]

The optical pickup device 20 of FIG. 8 is made thinner than the optical pickup device 10 of FIG. 7. However, when considering an ultra-thin optical disc device built in a notebook computer expected in the near future, the optical pickup device 20 of FIG. 8 is not sufficiently thin.

Now, consider making the optical pickup device 20 thinner. The following two measures can be considered in order to reduce the thickness. To shift the position of the rising mirror 14 upward. To further reduce the rising angle φ ₁ 'of the rising mirror 14. When these two measures are taken, the optical pip-up device 20 of FIG. 8 becomes as shown in FIG. 9, for example.

As can be seen from FIG. 9, when the above measures are taken, the height dimension h ₀ ″ becomes small and the optical pickup device becomes thin. However, the focusing control operation lowers the objective lens downward. When it is displaced to a certain position, a part of the light beam is blocked by the lens holder, so-called eclipse occurs, and the reproduction of the optical disc becomes abnormal.

Therefore, it can be seen that the above measures alone do not work. Therefore, an object of the present invention is to provide an optical pickup device that solves the above problems.

[0017]

According to a first aspect of the invention, a light emitting element for emitting a light beam, a separation element for separating a light beam reflected by a recording medium, and a detection element for detecting the separated light beam. And a light emitting unit that is arranged so as to emit the light beam obliquely downward, and a rising angle is set to an angle smaller than 45 degrees, and reflects the light beam emitted from the light emitting unit. A rising mirror directed upward, a convex upper surface convex upward, and a convex lower surface convex downward, and collects the light beam reflected by the rising mirror on the recording medium. And an objective lens holder that surrounds the objective lens and supports the objective lens. In up device, down the opening
On the lower surface of the objective lens holder
And the lower surface of the objective lens holder on which the aperture stop is formed is closer to the convex upper surface side of the objective lens than the height of the top of the convex lower surface of the objective lens. The configuration is such that it is located in a biased position.

In the configuration in which the lower surface of the objective lens holder is arranged at a position offset to the convex upper surface side of the objective lens from the height of the apex of the convex lower surface of the objective lens, the raising mirror is moved closer to the objective lens side. It is possible. According to a second aspect of the invention, a light emitting element that emits a light beam, a separation element that separates the light beam reflected by the recording medium, and a detection element that detects the separated light beam are integrated. A light emitting unit arranged so as to emit obliquely downward,
A rising angle is set to an angle smaller than 45 degrees, and a rising mirror that reflects the light beam emitted from the light emitting unit and directs it upward, a convex upper surface that is convex upward and a convex surface that is convex downward. An objective lens having a lower surface for condensing the light beam reflected by the rising mirror on the recording medium, and an aperture stop for narrowing the light beam reflected by the rising mirror and incident on the objective lens. Is provided
In an optical pickup device having an objective lens holder surrounding the objective lens and supporting the objective lens,
The lower surface of the objective lens holder provided with the aperture stop is located at a position displaced from the height of the top of the convex lower surface of the objective lens to the convex upper surface side of the objective lens, and the light emitting unit. However, a part thereof protrudes above the height of the top of the convex upper surface of the objective lens within the operating range of the objective lens which is not affected by the variation amount of the recording medium when the recording medium is rotated. The objective lens holder is arranged at a height, and has a size and shape so that the objective lens holder does not enter the optical path of the light beam from the light emitting unit toward the raising mirror.

In the configuration in which the lower surface of the objective lens holder is arranged at a position displaced from the height of the top of the convex lower surface of the objective lens to the convex upper surface side of the objective lens, the raising mirror is located closer to the objective lens side. It is possible. The light emitting unit,
A part of it is arranged at a height protruding above the height of the top of the convex upper surface of the objective lens within the operating range of the objective lens which is not affected by the amount of fluctuation of the recording medium when the recording medium is rotated. Makes it possible to reduce the rising angle of the rising mirror while ensuring that the recording medium does not come into contact with the light emitting unit.

Further, the dimensional shape of the objective lens holder is determined so as not to enter the optical path of the light beam from the light emitting unit toward the rising mirror so that the light beam is prevented from being eclipsed. According to a third aspect of the present invention, the rising mirror has a wedge-shaped portion formed by cutting out in a substantially horizontal plane on the lower end side.

The wedge-shaped configuration of the lower end side of the rising mirror eliminates the corner portion projecting downward when the rising mirror is tilted.

[0022]

1 shows an optical pickup device 30 according to a first embodiment of the present invention. In FIG. 1, the same components as those shown in FIG. 8 are designated by the same reference numerals, and the description thereof will be omitted. The optical pickup device 30 includes a light emitting unit (hologram unit) 11 and a finite objective lens 12
, A raising mirror 31, and an objective lens holder 32 having an aperture stop 32a.

The optical pickup device 30 has the following four means to avoid the problem of vignetting.
It has been made thinner. (1) First means: lower surface 32b of the objective lens holder 32
Is arranged at a position displaced upward from the height H ₂ . The aperture stop 32a is located at the same height as the lower surface 32b of the objective lens holder 32.

The thickness dimension u of the objective lens holder 32 is smaller than the thickness dimension u'of the objective lens holder 21 of FIG.
As a result, the aperture stop 32a (objective lens holder 32
Of the lower surface 32 b), the upper side than the height H _2, i.e. the height H ₂
Thus, the objective lens 12 is located on the convex upper surface 12a side at a position deviated by the dimension δ.

Here, how the gap between the raising mirror and the objective lens can be reduced by displacing the aperture stop 32a above the height H ₂ will be described. 1 and 8, the distance between the aperture stop 32a and the upper end 31a of the rising mirror 31 is d, and the objective lens 12 is
The distance between the lower top 12e of the lens and the aperture stop 32a is δ
(Δ ′), the thickness of the objective lens 12 is d _OBJ , the upper top portion 12c of the objective lens 12 and the upper end portion 31 of the rising mirror 31.
The distance to a is d _OM (d _OM ′).

In the optical pickup device 30 shown in FIG. 1, d _OM is d _OM = d _OBJ + d-δ (1) In the conventional optical pickup device 20 of FIG. 8, d _OM ′ is d _OM ′ = d _OBJ + δ ′ + d (2)

The difference between d _OM 'and d _OM is d _OM'- d _OM = δ' + δ (3). Therefore, according to the optical pickup device 30 of FIG. 1, as compared with the optical pickup device 20 of FIG. 8, the distance between the objective lens 12 and the raising mirror 31 is (δ ′ +
It can be narrowed by δ).

As a result, the optical pickup device 3
0 is thinner than the optical pickup device 20 of FIG. Since the aperture stop 32a is biased upward, the surface 12b of the objective lens 12 is projected downward from the lower surface 32b of the lens holder 32. But face 1
Since 2b has a curved surface that is convex downward, when the objective lens 12 moves downward during focus control operation,
The objective lens 12 does not collide with the rising mirror 31.

(2) Second means: The light emitting unit 11 is arranged so that its upper end 11a is located at a height protruding by a dimension t above the height H ₁ . A working distance WD for the focusing operation of the objective lens 12 is provided between the optical disk 15 and the upper top portion 12c of the objective lens 12. Further, the amount of variation ΔD in the height direction of the optical disc 15 due to surface wobbling or the like when the optical disc 15 is rotated is defined by the standard.

The protrusion size t is set so as to satisfy the condition of the following expression (4). 0 ≦ t ≦ WD−ΔD (4) Since the protrusion dimension t of the upper end 11a of the light emitting unit 11 above the height H ₁ is a value satisfying the above formula (4), the optical disk 15 is mounted on the light emitting unit 11. No contact occurs.

The arrangement height H ₄ of the light emitting unit 11 is the highest position, and is higher than the arrangement height H ₃ of the light emitting unit 11 in the conventional optical pickup device 20 shown in FIG. 8 by a dimension c. Therefore, the light emitting unit 11
Is the tilt angle φ ₃ of the optical axis 11a with respect to the horizontal.
8 is a posture inclined further downward than the posture shown in FIG. That is, the downward tilt angle φ _{3 with} respect to the horizontal of the optical axis 11 a is larger than the corresponding tilt angle φ ₃ ′ in FIG. 8.

The inclination of the light emitting unit 11 is as shown in FIG.
Since it is large, the rising mirror 31 is the light emitting unit 11 or not.
In order to reflect these laser beams and direct them directly above, start up
Angle φ ₁Is the rising angle φ in FIG.₁Be smaller than
It That is, φ₁<Φ₁’ This will bring up
The height dimension a of the mirror 31 is the corresponding dimension a in FIG.₀’
It gets smaller. That is, a <a₀’

As a result, the optical pickup device 30 of FIG. 1 is thinner than the optical pickup device 20 of FIG. Here, the above t is represented by the following equation. t (φ ₁ ) = (1 + cos2 φ ₁ ) · l (φ ₁ ) − (d _LD + 1l _OL ) · cos2 φ ₁ + h _LD · sin2 φ ₁ + d _OBJ (5) where

[0034]

[Equation 1]

L _OL : Distance between lower end of objective lens and object point d _CBJ : Thickness of objective lens d _LD : Object point in light emitting unit to thickness of unit bottom h _LD : Height of light emitting unit x 1/2 d: Distance from bottom of aperture stop to upper end of rising mirror δ: Distance from bottom of aperture stop to lower end of objective lens b: Margin with respect to beam diameter of rising mirror θ: Beam divergence angle

(3) Third means: The radius r of the objective lens holder 32 is determined so as to satisfy the following two conditions r ₀ <r, d ≦ S. Here, r ₀ is the radius of the objective lens, d is the distance from the aperture stop 32a to the upper end of the rising mirror 31, S is the aperture stop 32a, and the laser light traveling from the light emitting unit 11 to the rising mirror 31. It is the distance to the top edge.

S is a function of r,

[0038]

[Equation 2]

It is represented by Where θ is the light beam 13
The divergence angle l _OL of the (laser beam) is the distance along the optical path between the lower top 12e of the objective lens 12 and the object point 17. By arranging the light emitting unit 11 as in the second means, a situation where the laser beam emitted from the light emitting unit 11 and traveling toward the rising mirror 31 is eclipsed by the objective lens holder is likely to occur. However, by setting the radius r of the objective lens holder 32 as described above, even if the objective lens holder 32 is moved down by the maximum by the focus control, the light beam 13 may be eclipsed by the objective lens holder 32. Absent.

(4) Fourth Means: The lower end side of the rising mirror 31 has a wedge shape. The raising mirror 31 is shown in FIG.
A lower end portion 31b indicated by a chain double-dashed line is cut off by a substantially horizontal plane, and has a wedge-shaped portion 31c. The angle φ ₄ formed by the mirror surface 31d of the wedge-shaped portion 31c and the lower end surface 31e is equal to or smaller than the rising angle φ ₁ of the rising mirror 31. That is, φ ₄ is
φ ₄ ≤φ ₁ .

As a result, the height dimension a of the rising mirror 31 is smaller by Δh than the height dimension a'of the structure in which the lower end portion 31b of the rising mirror 31 is not cut off (that is, the conventional structure shown in FIG. 8). Become. Due to this, the optical pickup device 30 is thinner than the optical pickup device 20 of FIG.

Next, how thin the optical pickup device 30 of FIG. 1 which adopts the first to fourth means is compared with the conventional optical pickup device 20 shown in FIG. 8 will be described. . A comparison will be made in terms of numerical values using optical components that have been commonly and conventionally used.

In the optical pickup device 20 of FIG. 8, the working distance WD of the objective lens is 1.66 mm, the thickness of the objective lens is d _OBJ = 2.35 mm, and the distance from the lower end of the objective lens to the object point in the hologram unit is 19.111 mm. Divergence angle θ = 4.69 ° Moving the objective lens by focusing d = 1.0mm Distance from the lower end of the objective lens to the lens holder aperture stop δ '= 0.5mm Thickness of the raising mirror = 1.0mm Raising mirror The margin is 0.5mm for the beam diameter of the lens holder, and the outer diameter of the lens holder is φ7.4mm.

With the above settings, the minimum value of the raising angle φ ₁ 'of the raising mirror that the beam cannot be blocked by the lens holder when the objective lens is lowered to the lowest point by focusing is: φ ₁ ' _min = 40 .83 ° (8). In other words, this rising angle is the limit of sneaking of the rising mirror in the conventional configuration shown in FIG. However, this angle differs depending on the size of the objective lens. For example, if the size of the objective lens is larger than the above setting, the limit of the rising angle becomes large, and if the size of the objective lens is smaller than the above setting, the limit of the rising angle becomes smaller.

On the other hand, if the same objective lens as described above is used in the optical pickup device 30 of FIG. 1, the working distance WD of the objective lens is 1.66 mm and the thickness of the objective lens is d _OBJ = 2.35 mm. Distance between object points in hologram unit = 19.111mm Divergence angle of laser beam θ = 4.69 ° Movement of objective lens by focusing d = 1.0mm Distance from lower end of objective lens to lens holder aperture stop δ = 0.1mm The thickness of the raising mirror = 1.0 mm, the margin for the beam diameter of the raising mirror = 0.5 mm, the outer diameter of the lens holder = 6.4 mm.

When the minimum value of the rising mirror angle φ _{1 at which} the beam cannot be deflected by the lens holder when the objective lens is lowered to the lowest point by focusing, φ _{1 min} = 40.66 ° (9) Become. That is, the rising angle can be further reduced by 0.17 ° as compared with the conventional one.

Here, when the height from the label surface (top surface) of the disc to the bottom of the raising mirror is calculated, the height dimension h ₀ 'of the conventional optical pickup device 20 shown in FIG. 8 is calculated.
Is h ₀ ′ = 9.61 mm (10), while in the optical pickup device 30 of the present embodiment, the height dimension h is h = 7.92 mm ( 11), which is 1.69 mm thinner than the conventional one.

Next, another embodiment of the present invention will be described with reference to FIG.
A brief description will be given with reference to FIGS. In each figure, parts corresponding to the parts shown in FIG. 1 are designated by the same reference numerals. Figure 2
Is an optical pickup device 30 according to the second embodiment of the present invention.
A is shown. This optical pickup device 30A is the same as the first
Among the fourth to fourth means, it has a structure having only the first means.

This optical pickup device 30A has a height dimension h ₂ and is thinner than the optical pickup device 20 of FIG. FIG. 3 shows an optical pickup device 30B according to the third embodiment of the present invention. This optical pickup device 30B
Is a first means and a fourth means among the above first to fourth means.
It has a structure that adopts the above means.

This optical pickup device 30B has a height dimension of h ₃ and is thinner than the optical pickup device 20 of FIG. FIG. 4 shows an optical pickup device 30C according to the fourth embodiment of the present invention. This optical pickup device 30
C has a structure in which only the second means and the third means are adopted from the first to fourth means.

This optical pickup device 30C has a height dimension of h ₄ and is thinner than the optical pickup device 20 of FIG. FIG. 5 shows an optical pickup device 30D according to the fifth embodiment of the present invention. This optical pickup device 30
D has a structure that adopts the second means, the third means, and the fourth means of the first to fourth means.

This optical pickup device 30D has a height dimension of h ₅ and is thinner than the optical pickup device 20 of FIG. FIG. 6 shows an optical pickup device 30E according to a sixth embodiment of the present invention. This optical pickup device 30
E has a structure that adopts the first, second, and third means of the first to fourth means.

This optical pickup device 30E has a height dimension of h ₆ and is thinner than the optical pickup device 20 of FIG.

[0054]

As described above, according to the first aspect of the present invention, the bottom surface of the objective lens holder provided with the aperture stop is positioned higher than the height of the top of the convex lower surface of the objective lens. Since it is configured to be located at a biased position on the convex upper surface side, it can be brought closer to the raising mirror objective lens, which makes the height size smaller than the conventional one, It is possible to realize an optical pickup device that is thinner than that of.

According to the second aspect of the invention, the aperture stop is provided.
The bottom surface of the aperture stop of the objective lens holder is located at a position displaced from the height of the top of the convex lower surface of the objective lens to the convex upper surface side of the objective lens, and the light emitting unit is Is located at a height protruding above the height of the apex of the convex upper surface of the objective lens within the operating range of the objective lens that is not affected by the fluctuation amount of the recording medium when the recording medium is rotated. Since the objective lens holder has a size and shape that does not enter the optical path of the light beam from the light emitting unit toward the raising mirror, the bottom surface of the objective lens holder is the objective lens holder. By arranging at a position deviated to the convex upper surface side of the objective lens from the height of the apex of the convex lower surface of the convex lens, the raising mirror can be moved closer to the objective lens side, and the light emitting unit Part of the lens is placed at a height protruding above the height of the top of the convex upper surface of the objective lens within the operating range of the objective lens that is not affected by the variation of the recording medium when the recording medium rotates. With the structure provided, it is possible to make sure that the recording medium does not come into contact with the light emitting unit, and the rising angle of the rising mirror can be made small, so that the optical pickup device is thinner than the invention according to claim 1. Can be converted. In addition, the size and shape of the objective lens holder are determined so as not to enter the optical path of the light beam traveling from the light emitting unit to the rising mirror, whereby it is possible to ensure that the light beam is not eclipsed.

According to the third aspect of the present invention, since the raising mirror has a wedge-shaped portion which is cut off substantially in the horizontal plane on the lower end side, the raising mirror has a lower portion than the lower end of the mirror surface. The portion protruding downward can be eliminated, and the height dimension of the optical pickup device can be reduced accordingly, and the thickness of the optical pickup device can be reduced.

[Brief description of drawings]

FIG. 1 is a diagram showing an optical pickup device according to a first embodiment of the present invention.

FIG. 2 is a diagram showing an optical pickup device according to a second embodiment of the present invention.

FIG. 3 is a diagram showing an optical pickup device according to a third embodiment of the present invention.

FIG. 4 is a diagram showing an optical pickup device according to a fourth embodiment of the present invention.

FIG. 5 is a diagram showing an optical pickup device according to a fifth embodiment of the present invention.

FIG. 6 is a diagram showing an optical pickup device according to a sixth embodiment of the present invention.

FIG. 7 is a diagram showing an example of a conventional optical pickup device.

FIG. 8 is a diagram showing another conventional optical pickup device.

FIG. 9 is a diagram for explaining a problem to be solved by the present invention.

[Explanation of symbols]

11 Light emitting unit 12 Finite objective lens 12a convex upper surface 12b convex lower surface 12c top 12d optical axis 13 light beam 14 Start-up mirror 15 Optical disc 15a recording surface 16 reflected light beam 17 points 18 image points 30,30A-30E Optical pickup device 31 Start-up mirror 31a upper end 31c Wedge shape part 31d Mirror surface 31e Lower end surface 32, 32A, 32B Objective lens holder 32a, 32Aa, 32Ba Aperture stop 32b lower surface

─────────────────────────────────────────────────── ─── Continuation of front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) G11B 7/135

Claims (3)

(57) [Claims] 1. A light emitting element for emitting a light beam, a separation element for separating a light beam reflected by a recording medium, and a detection element for detecting the separated light beam are integrated.
A light-emitting unit arranged so as to emit a light beam obliquely downward, and a start-up mirror which has a rising angle set to an angle smaller than 45 degrees and which reflects the light beam emitted from the light-emitting unit and directs it upward. An objective lens that has a convex upper surface that is convex upward and a convex lower surface that is convex downward, and that condenses the light beam reflected by the raising mirror onto the recording medium; In an optical pickup device having an aperture stop that narrows a light beam reflected by a raising mirror and incident on the objective lens, and an objective lens holder that surrounds the objective lens and supports the objective lens, the aperture stop is The objective lens is attached to the lower surface of the objective lens holder.
It is formed integrally with the lens holder, and the aperture stop is
An optical pickup characterized in that the lower surface of the formed objective lens holder is located at a position displaced to the convex upper surface side of the objective lens from the height of the top of the convex lower surface of the objective lens. apparatus. 2. A light emitting element that emits a light beam, a separation element that separates the light beam reflected by the recording medium, and a detection element that detects the separated light beam are integrated.
A light-emitting unit arranged so as to emit a light beam obliquely downward, and a start-up mirror which has a rising angle set to an angle smaller than 45 degrees and which reflects the light beam emitted from the light-emitting unit and directs it upward. An objective lens that has a convex upper surface that is convex upward and a convex lower surface that is convex downward, and that condenses the light beam reflected by the raising mirror onto the recording medium; An optical pickup device is provided with an aperture stop for narrowing a light beam reflected by a raising mirror and incident on the objective lens, and an optical pickup device having an objective lens holder that surrounds the objective lens and supports the objective lens. The lower surface of the objective lens holder provided, from the height of the top of the convex lower surface of the objective lens, on the convex upper surface side of the objective lens, is located at a position biased, A part of the light emitting unit is located above the height of the apex of the convex upper surface of the objective lens within the operation range of the objective lens which is not affected by the variation amount of the recording medium when the recording medium is rotated. The objective lens holder is arranged at such a height that it does not enter the optical path of the light beam from the light emitting unit toward the raising mirror. Pickup device. 3. The optical pickup device according to claim 1, wherein the raising mirror has a wedge-shaped portion formed by cutting out in a substantially horizontal plane on the lower end side.