JP3017418B2 - Optical pickup device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to an optical pickup device of an optical information recording / reproducing device such as an optical disk drive device and an optical card device.

[0002]

2. Description of the Related Art An example of a conventional optical pickup device will be described with reference to FIG. Divergent light emitted from a semiconductor laser (LD) 1 as a laser light source is converted into substantially parallel light by a collimator lens 2, passes through a beam splitter 3, is deflected upward by a deflection prism 4, and is deflected upward by a λ / 4 plate 5. The light is condensed by the objective lens 6 and is irradiated onto the recording surface of the optical disc 7 as an optical information recording medium. Then, the reflected light A from the optical disk 7 is converted into substantially parallel light by the objective lens 6, the polarization direction is changed by the λ / 4 plate 5, reflected by the beam splitter 3 via the deflecting prism 4, and detected by the signal detection optical system. It is led into the system 8. The reflected light A from the optical disk 7 that has entered the signal detection optical system 8 is converged by the detection lens 9, a part of the light is transmitted by the beam splitter 10 and guided to the light receiving element 11, and a part of the light is reflected. The light is guided to the light receiving element 12.
The light receiving element 11 is divided into six light receiving surfaces a to f, and the light receiving element 12 is divided into three light receiving surfaces g, h, and i. Thereby, the information signal (the signal recorded on the recording surface)
Rf, focus error signal Fe (beam size method),
The track error signal Te can be obtained as Rf = a + b + c + d + e + f + g + h + i (1) Fe = (a + d + c + f + h)-(b + e + g + i) (2) Te = (a + b + c)-(d + e + f) (3)

FIG. 17 shows another conventional example relating to the signal detection optical system 8. As shown in FIG. The signal detection optical system 8 shown in FIG.
Then, the reflected light A condensed by the detection lens 9 is given astigmatism by the astigmatism generating lens 13 and guided to the light receiving element 14. The light receiving element 14 is divided into four light receiving surfaces a to d. Accordingly, the information signal Rf, the focus error signal Fe (astigmatism method), and the track error signal Te are as follows: Rf = a + b + c + d (4) Fe = (a + c)-(b + d) (5) Te = (a + d)- (B + c) (6)

In the signal detection optical system 8 shown in FIG. 17B, a part of the reflected light A condensed by the detection lens 9 is cut by the knife edge prism 15, and the uncut light is received by the light receiving element. The light that is guided to 16 and cut is guided to the light receiving element 17. The light receiving element 16 is divided into two light receiving surfaces a and b, and the light receiving element 17 is divided into two light receiving surfaces c and d. Accordingly, the information signal Rf, the focus error signal Fe (knife edge method), and the track error signal Te are as follows: Rf = a + b + c + d or c + d (7) Fe = ab (8) Te = cd ( 9) can be obtained as

Here, the principle of diffraction on the recording surface of the optical disk 7 will be described with reference to FIGS. FIG.
As shown in (a), the light spot P converged by the objective lens 6 is diffracted by a pit row of the optical disk 7 (in the case of a normal CD). FIG. 19A shows a ROM-type disk surface in which concavities and convexities are formed in advance (a concave portion is a pit portion, and a convex portion is a non-pit portion). Light reflected by the pit portion and the light reflected by the non-pit portion, respectively, causes a phase difference and causes interference. The phase difference is expressed as Δ = 2πnh / λ (where h: pit height, n: substrate reflectance, λ: laser wavelength). As shown in FIG. 19B, in the case of the phase-change recording method, light reflected by the mark portion 22a and the non-mark portion 22b causes a phase difference to cause interference.

The light (reflected light A) diffracted by the pit array of the optical disk 7 in this manner returns to the objective lens 6 having a numerical aperture NA, so that it is mainly a zero-order light 20a and a primary light as a higher-order component. The diffracted light 20b is taken in, and then guided to the light receiving elements 11, 12 (in the case of the optical system in FIG. 16). Interference between the zero-order light 20a and the first-order light 20b causes a change in the amount of light, thereby causing a pit (detected as an information signal; here, a phase pit due to unevenness, a mirror surface having a different reflectance). (Collectively referred to as dots). When the diffracted lights of the 0th-order light 20a and the 1st-order light 20b are guided to, for example, the light receiving elements 11 and 12 according to the above-described diffraction principle, the value of the information signal Rf is calculated as the total sum of the light amounts by the above equation (1). Obtainable.

[0007] The smaller the pit (shorter pit), the larger the diffraction angle θ, and if the pit is very short (shortest pit), the overlapping area between the zero-order light 20a and the first-order light 20b is reduced. Pits cannot be detected.
That is, the signal change of a short pit is more concentrated on the periphery of the detection light far field pattern (FFP) as the pit becomes smaller and the density is higher, whereas the signal change of a larger pit (long pit) is formed by a diffraction angle. θ is small and concentrated at the center of the detection light FFP.

[0008]

A conventional example (for example, FIG. 16)
), The information signal Rf (see equation (1)) indicating the information of the pits recorded on the optical disk 7 is composed of the 0th-order light 20a and the 1st-order light 20b whose light amounts change according to the pit shape.
And a component of an overlapping area (see FIG. 18A) where
It is determined by the sum total of the entire light amount with the component of the 0th-order light 20a having a small change in the light amount and having a large noise component. However, by simply detecting the change in the entire light amount, as described above, the smaller the pits and the higher the density of the recording medium, the smaller the ratio of the component of the overlapping area to the component of the zero-order light 20a, and the noise component Because the ratio of
/ N will be reduced.

Here, taking a CD as an example of a recording medium, the shortest signal corresponding to the shortest pit is a 3T signal, and the longest signal corresponding to the longest pit is an 11T signal (T is the period of the basic clock). ). In this case, in order to read pits recorded at high density with good S / N, it is necessary to improve the resolution by increasing the signal amplitude of 3T or to improve the S / N by reducing noise of the 3T signal. . To improve the amplitude detected from the former shortest pit,
This cannot be realized unless the spot diameter of the light spot P for reading is reduced and the resolution of the spot itself is increased.
It is necessary to shorten the wavelength of the LD or increase the NA of the objective lens. However, at present, the wavelength of the LD is 635 nm, and the NA of the objective lens is about 0.6. As a method of reducing the noise of the latter 3T signal, the reflected light A
It is only necessary to remove the component of the zero-order light 20a, which becomes noise, but in the conventional signal detection method, as described above, the information signal Rf is obtained from the fluctuation of the entire amount of received light. Therefore, when a CD is recorded at a high density, noise cannot be reduced, S / N is reduced, and accurate signal detection cannot be performed.

In recent years, research and development called super-resolution has been made in order to perform high-density recording and reproduction, and an optical pickup device having a higher resolution than the conventional example shown in FIG. , Vol. 21, No. 5, May 1992,
See pages 342-345). The method using this super-resolution realizes a minute light spot exceeding the diffraction limit by changing the light intensity or phase near the center of the beam before focusing. Since the light spot forms a relatively strong side lobe, in the case of reproduction, the side lobe component is shielded using a slit, and only the main lobe component is cut out and received to obtain a reproduction signal. However, such a method of performing high-density recording using super-resolution has a disadvantage that light use efficiency is reduced because a light-shielding slit is used, and the spot diameter of the slit is as small as about 100 μm or less. In addition, the positional accuracy of the slit also becomes severe when miniaturization is considered.

A signal reproducing method using super-resolution uses a medium (super-resolution magneto-optical disk) (see Applied Physics, Vol. 61, No. 3, 1992, pp. 250-253). However, it is still in the research stage and lacks versatility.

[0012]

According to the first aspect of the present invention, the information signal reproducing means mainly overlaps the 0th-order light and the 1st-order light in the track direction (particularly, the light amount corresponding to the end of the pit). The first light area corresponding to the portion where the change is remarkable) and the remaining 0th-order light portion that hardly contains the primary light in the track direction (the portion where the light amount hardly changes even if there is pit unevenness). By detecting the difference between the signal obtained from the divided first light region and the signal obtained from the second light region, the pits are particularly shortest pits. In this case, based on the light amount of the light beam (first light area) where the signal detected corresponding to the shortest pit is concentrated, the light beam (second light area) where the signal corresponding to the shortest pit is hardly detected.
Can be subtracted, thereby making it possible to obtain an information signal by reducing only the noise component without reducing the signal amplitude of the shortest pit. In the first light area where the 0th-order light and the 1st-order light overlap each other, the change in the light amount is remarkable corresponding to the end of the pit. And the pit end position can be determined accurately.

According to the second aspect of the present invention, the first light area located at both ends of the light beam divided into three in the track direction of the reflected light by the information signal reproducing means, and the first light area at the both ends. The signal amplitude is reduced by dividing and detecting the second light area located in the center part between the two, and calculating the difference between the signal obtained from the first light area and the signal obtained from the second light area. The luminous flux corresponding to the noise component can be more effectively reduced without performing the above operation.

According to the third aspect of the present invention, the information signal reproducing means causes the first light region corresponding to the peripheral portion of the reflected light and the second light region corresponding to the central portion surrounded by the first light region. The light flux corresponding to the noise component is further reduced without lowering the signal amplitude by detecting by dividing into a region and a signal obtained from the first light region and a signal obtained from the second light region. It can be reduced effectively.

According to the invention described in claim 4, the information signal reproducing means includes a first light area in a peripheral portion of the reflected light divided in the track direction and a second light area corresponding to a portion other than the first light area. By detecting the light beam by dividing it into light regions and obtaining the difference between the signal obtained from the first light region and the signal obtained from the second light region, the light flux corresponding to the noise component is further reduced without reducing the signal amplitude. It can be reduced effectively.

According to the fifth aspect of the present invention, the reflected light from the optical information recording medium is divided into a plurality of areas in the track direction by the light beam dividing means, and the reflected lights divided into the plurality of areas are respectively transmitted to the light receiving means. By separately guiding the light beams, light can be received in a minute area near the converging point of each separated light beam, and the light receiving area can be reduced and the band can be improved.

According to the sixth aspect of the present invention, by separating the reflected light from the optical information recording medium by the prism, it is possible to set the direction of separating the light flux relatively freely.

According to the seventh aspect of the present invention, by separating the reflected light from the optical information recording medium by the hologram, the direction of separating the light beam can be freely set, and the light beam separating function can be easily performed by using a single plate. Obtainable.

In the invention according to the eighth aspect, by separating light beams by a plurality of different light beam splitting regions, various signal detection methods (astigmatism) for obtaining a focus error signal and a track error signal in addition to an information signal. Aberration method, knife edge method, push-pull method, etc.) can be made by one element.

According to the ninth aspect of the present invention, the number of components can be reduced by guiding the plurality of reflected lights to the plurality of light receiving elements provided on the same substrate.

According to the tenth aspect of the present invention, since the laser light source and the light receiving element are arranged in the same housing, assembly adjustment can be facilitated.

[0022]

FIG. 1 shows a first embodiment of the present invention.
4 to 4 (corresponding to the first aspect of the present invention). The description of the same parts as those in the conventional example (see FIGS. 16 to 18) is omitted, and the same reference numerals are used for the same parts.

FIG. 2 shows the overall configuration of the optical pickup device. A collimating lens 2 and a beam splitter 3 are provided on an optical path of light emitted from the LD 1 toward the optical disc 7.
And a deflection prism 4 and an objective lens 6. The reflected light A from the optical disk 7 is reflected by the beam splitter 3
A detection lens 9 and a beam splitter 10 are arranged on an optical path in the signal detection optical system 8 reflected by the light. A light receiving element 21 for detecting an information signal is arranged on the optical path where the reflected light A is reflected by the beam splitter 10. Note that the reflected light A is
A light receiving element 23 for detecting a servo signal (focus error signal, track error signal) is disposed on the optical path through which the light passes.

The reflected light A, as shown in FIG.
It is composed of a secondary light 20a and ± primary light 20b (hereinafter the symbol ± is omitted). Of the reflected light A, two first light areas A ₁ (indicated by hatching areas) located at both ends in the track direction T mainly include the 0th-order light 20a and the 1st-order light 2a.
0b is an overlapping area. Second light area A ₂ of the central portion is almost included not the primary light 20b, mainly made from a portion of the 0 order light 20a.

As shown in FIG. 1B, the light receiving element 21 is divided into three in the track direction (jitter direction) T, and light receiving surfaces a, b, and c are formed. The light receiving surfaces a, b, and c are provided on the disk surface (recording surface) of the optical disk 7.
The reflected light A reflected from is guided. The light receiving surfaces a and b are
2 of the reflected light A located at both ends in the track direction T
One first light region A ₁ of receiving the receiving surface c may receive the second light region A ₂ located in the center portion of the reflected light A. An information signal reproducing unit is constituted by the light receiving element 21 having the light receiving surfaces a to c and a unit for reproducing the received signal.

In such a configuration, the light emitted from the LD 1 becomes substantially parallel light by the collimator lens 2, is condensed by the objective lens 6 via the beam splitter 3 and the deflection prism 4, and is converged on the recording surface of the optical disk 7. Irradiated. FIG. 1C shows a state on the disk surface (recording surface) of the optical disk 7. On the track 18 on the disk surface, a pit row (comprising pits 19 having different lengths) is formed in the track direction T. The reflected light A reflected and diffracted by the pit row includes a zero-order light 20a and a first-order light 2a.
0b, is reflected by the beam splitter 3, is converged by the detection lens 9 in the signal detection optical system 8, and is partially reflected by the beam splitter 10 and guided to the light receiving element 21. An information signal Rf is detected.

[0027] In this case, of the reflected light A consisting of 0-order light 20a and the first-order light 20b, the first light region A ₁ in the overlap region, the amount of light caused by interference between the zero-order light 20a and the primary light 20b Although a change appears, the size of the overlapping area changes according to the pit length in the track direction T. That is, as the pit length in the track direction T becomes shorter, the primary light 20
b almost disappears, and the 0th-order light 20a and the 1st-order light 2
0b becomes smaller. Therefore, of the reflected light A, the first light area A ₁ (overlap area corresponding to the recorded pit information) is an area where the light amount changes significantly according to the pit length, and the second light area A ₂ (noise area) (A region of the 0th-order light 20a corresponding to the above) is a region where the light amount hardly changes so much even if the pit shape changes.

Then, the reflected light A composed of the first light area A ₁ and the second light area A ₂ having the different light quantity changes as described above is divided into three light receiving surfaces a, 3 in the track direction T of the light receiving element 21.
It is led to b and c. At this time, the light receiving surface a, b at both ends guided most of the light flux of the first light region A ₁ is the light receiving surface c of the central portion most of the light flux of the second light region A ₂ is derived. Then, the information signal reproducing means, the light receiving surface a corresponding to the first optical region A ₁ of the reflected light A, the signal (X) detected by b, corresponding to the second optical region A ₂ of the reflected light A (= X−Y) from the signal (Y) detected by the light receiving surface c
, The information signal Rf recorded on the optical disk 7 can be reproduced. The information signal Rf reproduced at this time is obtained as follows: Rf = (a + b) -c (10) This makes it possible to perform signal detection by reducing only the noise component without reducing the signal amplitude.

As described above, the zero-order light 20a and the first-order light 2a
The reflected light A and a 0b, the first optical region A ₁ is separated into the second optical region A ₂ detects the light-receiving element 21, the light beam (mainly peripheral portion, and the 0-order light 20a in the track direction T Primary light 20b
A first light area A ₁ ), which is an overlapped area with the first light area A ₁ ), and a light flux at the center (mainly the 0th-order light 20a that hardly contains the primary light 20b)
While the total light receiving amount of the signal is reduced by obtaining the light amount difference from the second light area A ₂ ) comprising the information signal without particularly reducing the signal amplitude of the signal detected corresponding to the shortest pit, Rf can be reproduced. Thereby, the noise (the noise of the LD 1, the noise of the light receiving element 21, the noise of the optical disk 7, etc.) included in the reflected light A can be reduced and the resolution can be increased. For these reasons, the S / N can be improved, and high-sensitivity signal reproduction can be performed even on a high-density recording medium.

Next, a second embodiment of the present invention will be described with reference to FIGS.
A description will be given based on FIG. 5 (corresponding to the inventions of claims 2, 3, and 4). The description of the same parts as those in the above-described embodiment is omitted, and the same reference numerals are used for the same parts.

As shown in FIG. 3, the light receiving element 21 is divided into three parts in the track direction T to form light receiving surfaces a and b at both ends. By being divided, the light receiving surfaces c and d at the center are obtained.
Are formed. Light receiving element 21 thus configured
Are arranged in the signal detection optical system 8 shown in FIG.
In this case, of the reflected light A from the optical disk 7, the first light area A ₁ (a light flux composed of the primary lights 20b at both ends where the signal corresponding to the shortest pit is concentrated) is guided to the light receiving surfaces a and b. Then, the second light area A ₂ (a light beam composed of the zero-order light 20a at the center where almost no signal corresponding to the shortest pit is detected) is guided to the light receiving surfaces c and d. The information signal Rf can be reproduced by obtaining the output difference between the signals obtained from the light receiving surfaces a and b and the light receiving surfaces c and d of the light receiving element 21 (information signal reproducing means). Also, the track error signal Te can be detected from the light receiving surfaces c and d. In this case, the information signal Rf and the track error signal Te can be obtained by the following formula: Rf = (a + b)-(c + d) (11) Te = cd (12)

Therefore, the reflected light A is transmitted to the light receiving element 2 as described above.
Of the three light beams that are led to 1, the light beam of the primary light 20b (first light area A ₁ ) at both ends and the light beam mainly of 0 at the central portion
By calculating the light amount difference from the light flux of the next light 20a (second light area A ₂ ), the noise included in the reflected light A is reduced without lowering the signal amplitude, and the S / N of the information signal Rf is reduced.
Can be improved. By arranging the light receiving element 23 in the signal detection optical system 8 of FIG. 2, the focus error signal Fe may be detected using a known signal detection method (astigmatism method, knife edge method, etc.). Good.

Next, a modified example will be described with reference to FIGS. First, as shown in FIG.
May be divided into a peripheral light receiving surface a and a central light receiving surface b (rectangular shape) surrounded by the light receiving surface a. This light receiving element 21 is arranged in the signal detection optical system 8 of FIG. In this case, of the reflected light A from the optical disc 7,
The first light area A ₁ (a light flux in the peripheral portion where the signal corresponding to the shortest pit is concentrated) is guided to the light receiving surface a in the peripheral portion, and the second light area A ₂ (the signal corresponding to the shortest pit is almost detected). The light beam at the central portion that is not processed is guided to the light receiving surface b. The information signal Rf can be reproduced with high sensitivity by reducing the noise by obtaining the light quantity difference between the signals obtained from the periphery and the center of the light receiving surfaces a and b of the light receiving element 21 (information signal reproducing means). ). In this case, the information signal Rf can be obtained by Rf = ab (13). Also, as shown in FIG. 4B, the light receiving surface b at the center is made elliptical, or the light receiving surfaces a and b divided in the track direction T as shown in FIG. The same effect can be obtained by configuring the light receiving element 21 by dividing the light receiving surface c (circle) into three. Note that the information signal Rf in FIG.
It is obtained in the same way as the equation.

As shown in FIGS. 5A and 5B, the light receiving element 21 is divided into light receiving surfaces a and b at the peripheral portion divided in the track direction T and light receiving surfaces at regions other than the peripheral portion. Face c
And may be configured separately. However, in the central part of the light receiving surfaces a and b, the light receiving surfaces a and b are formed so as to be curved in the track direction T in accordance with the distribution shape in which the 3T signal appears in a concentrated manner. The reason why the light receiving surfaces a and b are formed in a curved shape so as to detect only the peripheral luminous flux in the track direction T is that, as shown in FIG. This is because there is almost no 3T signal component at the end in the direction perpendicular to the track direction T.

Then, of the reflected light A from the optical disk 7, the first light area A ₁ (a light flux in a peripheral portion where a signal corresponding to the shortest pit is concentrated) is a light receiving surface a, which is located in the peripheral portion.
b, and the second light area A ₂ (the light beam at the center where almost no signal corresponding to the shortest pit is detected) is guided to the light receiving surface c located at the center. Thus, by obtaining the light amount difference between the signals obtained from the peripheral portion of the light receiving element 21 and the other portion, it is possible to reduce noise and reproduce the information signal Rf with high sensitivity (information signal reproducing means).
The information signal Rf can be obtained in the same manner as in the equation (10).

Next, a third embodiment of the present invention will be described with reference to FIGS.
This will be described with reference to FIG. 8 (corresponding to the inventions of claims 5, 6, and 7). The description of the same parts as those in the above-described embodiments is omitted, and the same parts are denoted by the same reference numerals.

As shown in FIG. 6, a prism 24 as a light beam splitting means is arranged on the optical path where the reflected light A from the optical disk 7 is reflected by the beam splitter 10. FIG. 7A shows the shape of the prism 24, which is divided into three regions 24a, 24b and 24c. The upper and lower regions 24a and 24b are reflected light A
Is sized first light region A ₁ of the light beam (primary beam 20b) is guided is, central region 24c is first light region A ₁ other than the second light region A ₂ of the light flux of the reflected light A (0-order It is sized to guide light 20a). Such a prism 24 is arranged in the optical path such that the regions 24a, 24b, 24c are divided in the track direction T. Further, the three light beams 2 separated by the prism 24
Light-receiving element 21 as light-receiving means having light-receiving surfaces a, b, and c for individually detecting 5a, 25b, and 25c.
Is provided. Here, each of the light receiving surfaces a, b, and c of the light receiving element 21 is disposed near a converging point of each of the light beams 25a, 25b, and 25c. The light receiving means may be constituted by using a plurality of light receiving elements instead of using one light receiving element 21 having light receiving surfaces a, b, and c.

With the prism 24 and the light receiving element 21 configured as described above arranged in the optical path, the optical disk 7
Is reflected by the prism 24. At this time, of the reflected light A, the upper first light area A ₁ (a peripheral light flux where the signal corresponding to the shortest pit is concentrated) is guided to the area 24a above the prism 24, and The light region A ₁ is guided to a region 24 _b below the prism 24, and the central second light region A ₂ (a central light beam where a signal corresponding to the shortest pit is hardly detected) is guided to a central region 24 c of the prism 24. I will As a result, the reflected light A that has passed through the prism 24 is, as shown in FIG.
The light is divided into a total of three light beams 25a and 25b (first light region A ₁ ) and a central light beam 25c (second light region A ₂ ). These three light beams 25a, 25b, and 25c are separately detected by the light receiving element 21 having the three divided light receiving surfaces a, b, and c. That is, by guiding the light beam 25a to the light receiving surface a, guiding the light beam 25b to the light receiving surface b, and guiding the light beam 25c to the light receiving surface c, the information signal Rf can be obtained in the same manner as in Expression (10) (information signal Reproduction means). As a result, noise can be reduced and the information signal Rf can be reproduced with high sensitivity. Here, each light beam 25a,
Since the light receiving surfaces 25b and 25c are received on the respective light receiving surfaces a, b and c of the light receiving element 21 in the vicinity of the converging point, the light receiving area can be reduced, and thereby the band can be improved.

As shown in FIG. 8, a hologram 26 may be used instead of the prism 24 as the light beam dividing means. The hologram 26 is composed of upper and lower regions 26a and 26b where a grating is formed, and a central region 26c where no grating exists. In this case, the upper and lower regions 26a, 26b are formed to a size that the light flux of the first light region A ₁ of the reflected light A is guided to a central region 26c is first other than the first optical region A ₁ of the reflected light A It is formed in such a size that the light flux of the _two- light area A2 is guided. Then, such a hologram 26 is placed in the regions 26a, 26a.
b and 26c are arranged in the optical path so as to be divided with respect to the track direction T, and the reflected light A is made incident thereon, so that three light beams 25a and 25
5b and 25c can be detected separately, whereby the noise can be reduced and the information signal Rf can be reproduced with high sensitivity. Also in this case, the information signal Rf can be obtained in the same manner as in the equation (10).

Next, a fourth embodiment of the present invention will be described with reference to FIGS.
This will be described with reference to FIG. 12 (corresponding to the inventions of claims 8 and 9). The description of the same parts as those in the above-described embodiments is omitted, and the same parts are denoted by the same reference numerals.

In the signal detection optical system 8 shown in FIG. 9, a prism 27 as a light beam splitting means and a light receiving element 28 for receiving a plurality of light beams separated by the prism 27 are provided. As shown in FIG. 10, the prism 27 is divided into a plurality of different regions 27a to 27e (light beam division regions). Here, the “different region” means that the refraction direction of the incident light beam is different. Then, the reflected light A from the optical disk 7 is incident on the prism 27 configured as described above, so that the areas 27a to 27e
Light beams 29a to 29e are respectively generated corresponding to the light receiving surfaces 28a to 29e.
8a to 28e (however, 28d and 28e are not shown).

Thus, for example, the light beam 29d transmitted through the region 27d or the light beam 29e transmitted through the region 27e is
By receiving light on the divided light receiving surface d or e, the focus error signal Fe can be detected using the knife edge method. Further, for example, the track error signal Te can be detected by receiving the light beams 29b and 29c refracted by the regions 27b and 27c on the light receiving surfaces b and c and obtaining a difference signal. The information signal Rf is
Of the reflected light A received on the light receiving surfaces a to e (a at the center and b to e at the periphery), the signal obtained from the light flux at the periphery (first light area A ₁ ) and the light flux at the center ( It can be detected by taking the difference from the signal obtained from the second light area A ₂ ). The various signals Fe, Te, and Rf are as follows: Fe = d ₁ -d ₂ or e ₁ -e ₂ (14) Te = bc (15) Rf = (d + e) -a or (b + c + d + e) -a (16) However, d ₁ and d ₂ can be obtained by dividing the light receiving surface d into two divided surfaces e ₁ and e ₂ of the light receiving surface e.

As shown in FIG. 11, a hologram 30 may be used instead of the prism 27 as the light beam splitting means. The hologram 30 is divided into a plurality of different regions 30a to 30d (light beam division regions). A grating is formed in the regions 30a, 30b, 30c. Here, the “different region” means that the incident light beams have different diffraction directions. By causing the reflected light A to enter the hologram 30 configured as described above, for example, the focus error signal Fe is detected by the knife edge method using the light beam diffracted in the region 30a, and the light beam diffracted in the regions 30b and 30c. , A track error signal Te is detected, and a light flux at the peripheral portion (first light area A ₁ ) and a light flux at the central portion (second light area A) of the reflected light A are detected.
_The information signal Rf can be detected from the difference from ₂ ). In this case, for example, the light receiving element 28
Is divided into the light receiving surfaces a to d corresponding to the regions 30a to 30d, the information signal Rf can be obtained by Rf = d- (a + b + c) (17).

Further, as shown in FIG.
A plurality of luminous fluxes separated by 0 may be separately guided to the respective light receiving surfaces a ₁ , a _{2 to} d of the four light receiving elements 32 a to 32 d integrally mounted on the same substrate 31. The various signals Fe, Te, and Rf can be obtained by Fe = a ₁ −a ₂ (18) Te = bc (19) Rf = (a ₁ + a ₂ + b + c) −d (20) Thus, the light receiving element 32a
The assembly adjustment can be facilitated by integrally providing the substrates 32 to 32d on the substrate 31.

Next, a fifth embodiment of the present invention will be described with reference to FIG.
15 to FIG. 15 (corresponding to the invention of claim 10). The description of the same parts as those in the above-described embodiments is omitted, and the same parts are denoted by the same reference numerals.

As shown in FIG. 13, an LD-
In the PD unit 33, the LD 1 and the four light receiving elements 3
4a to 34d are provided. FIG. 14 shows an LD-PD
FIG. 3 shows a front view of the unit 33. LD in the center
1, light receiving elements 34a to 34d are arranged therearound.

The light emitted from the LD 1 of the LD-PD unit 33 configured as described above is reflected by the mirror 35 and travels to the outside of the unit. And let P
(A function of diffracting polarized light). The emitted light passes through the polarization hologram 36, changes its traveling direction by the deflecting prism 4, is condensed by the objective lens 6 via the λ / 4 plate 5, and is irradiated on the optical disk 7. The reflected light A from the optical disk 7 follows the reverse optical path, passes through the λ / 4 plate 5 again, and is changed to linearly polarized light having a polarization direction different from that of the emitted light by 90 °. Then, the light travels along an optical path different from the emission optical path, and is guided to the light receiving elements 34 a to 34 d in the LD-PD unit 33. Thereby, for example, various signals Rf, Fe, and Te can be detected based on the same principle as in the configuration of FIG. Thus, by arranging the LD 1 and the four light receiving elements 34a to 34d close to each other using the LD-PD unit 33, the input / output optical path is simplified in substantially one direction, and the optical system space is reduced. be able to.

The apparatus shown in FIG. 15 is an example in which the collimating lens 2 and the deflecting prism 4 of the apparatus shown in FIG. 13 are omitted, and each element is integrally mounted. As a result, the number of components can be reduced, and the size of the apparatus can be further reduced.

The optical information recording medium having pits is not limited to an optical information recording medium such as an optical disk (CD) in which a step (concavity and convexity) is formed in the thickness direction of the disk with respect to the peripheral portion. A disc having a different reflectance from the peripheral portion, such as a variable disc, may be used.

[0050]

According to the first aspect of the present invention, of the reflected light including the zero-order light and the primary light from the optical information recording medium, the primary light mainly in the track direction is used by using the information signal reproducing means. A first light area that appears (particularly, a light flux in a portion where a signal corresponding to the shortest pit is concentrated, that is, an area in which a change in the amount of light is remarkable according to a change in the shape of the end of the pit) and the primary light in the track direction are The light beam is divided into a second light region composed of 0th-order light that is hardly included (a light beam in a portion where a signal corresponding to the shortest pit is hardly detected, that is, a region where the light amount does not substantially change even if the pit shape changes). Since the information signal is reproduced by subtracting the signal obtained by the second light region from the signal obtained by the first light region, only the noise component can be reduced without lowering the signal amplitude. More, it is possible to greatly improve the S / N, it is possible to improve the signal detection accuracy even for high-density recording medium. In addition, signal detection is performed based on a difference between a first light area in which the 0th-order light and the 1st-order light in which the light amount changes significantly corresponding to the pit end and a second light area mainly including the 0th-order light. For this reason, the pit end position can be accurately obtained by increasing the resolution as compared with the conventional method of detecting an information signal based on the total amount of received light, thereby always obtaining an accurate signal. Further, since the information signal can be easily obtained by the difference between the light amount of the first light region and the light amount of the second light region, an inexpensive device with a simple circuit configuration can be provided.

According to a second aspect of the present invention, there is provided an information signal reproducing means, wherein the first light areas of the reflected light from the optical information recording medium are located at both ends of a light beam divided into three in the track direction, and It is divided into a second light region located at the center between the first light regions, and a difference between a signal from the first light region and a signal from the second light region is obtained to reproduce an information signal. Therefore, in addition to the effect of the first aspect of the present invention, only the noise component can be more effectively reduced without lowering the signal amplitude, whereby the S / N can be significantly improved. .

According to a third aspect of the present invention, a first light area corresponding to a peripheral part and a central part surrounded by the first light area are included in reflected light from an optical information recording medium using an information signal reproducing means. 2. The information signal is reproduced by dividing the signal into a second light area corresponding to the second light area and calculating a difference between a signal from the first light area and a signal from the second light area. In addition, only the noise component can be more effectively reduced without lowering the signal amplitude.
/ N can be significantly improved.

According to a fourth aspect of the present invention, the first light area of the peripheral portion divided in the track direction of the reflected light from the optical information recording medium and the first The information signal is reproduced by dividing into a second light region other than the light region and obtaining a difference between a signal from the first light region and a signal from the second light region. In addition to the effects, it is possible to more effectively reduce only the noise component without lowering the signal amplitude, thereby significantly improving the S / N.

According to a fifth aspect of the present invention, the reflected light from the optical information recording medium is divided into a plurality of areas in the track direction by the light beam dividing means, and the reflected lights divided into the plurality of areas are individually separated by the light receiving means. Since each light beam is received in the vicinity of the converging point, the light receiving area can be reduced, thereby providing a device capable of improving the bandwidth and performing high-speed reading with high resolution. .

According to the sixth aspect of the present invention, since the prism is used as the light beam splitting means, the direction of splitting the light beam can be set relatively freely, thereby increasing the degree of freedom in design such as the setting position of the light receiving element. Can be.

According to the seventh aspect of the present invention, since a hologram is used as the light beam splitting means, the light beam separating function can be obtained with a simple structure. Can be obtained. In addition, since the direction in which the light beam is separated can be freely set, the degree of freedom in design such as the setting position of the light receiving element can be increased.

According to the eighth aspect of the present invention, since a plurality of different light beam dividing areas are formed in the light beam dividing means, various signals (information signal, focus error signal, track error signal) are formed.
Can be detected by one element, thereby reducing the number of components by sharing components and providing a small-sized and low-cost device.

According to the ninth aspect of the present invention, since a plurality of light receiving elements for separately receiving the reflected light from the optical information recording medium are formed on the same substrate, the production and the assembly adjustment are facilitated. It is possible to provide an even smaller device at low cost.

According to the tenth aspect of the present invention, since the laser light source and the light receiving element are integrally provided in the same housing, the number of parts can be greatly reduced, and assembly adjustment can be performed more easily. Thus, a small and highly reliable device can be provided.

[Brief description of the drawings]

FIG. 1 shows a first embodiment of the present invention,
(A) is a front view showing light reflected from the optical disc, (b)
FIG. 3 is a front view showing a state in which the reflected light is received on a three-divided light receiving surface of the light receiving element, and FIG. 3C is a plan view showing a state on the optical disk surface on which pits of various shapes are formed.

FIG. 2 is a configuration diagram illustrating an overall configuration of an optical pickup device.

FIG. 3 shows a second embodiment of the present invention,
It is a front view showing signs that reflected light is divided and received in the track direction.

4A and 4B are views showing a state in which reflected light is divided into a peripheral portion and a central portion to receive light, wherein FIG. 4A is a front view when a light receiving surface of the central portion is rectangular, and FIG. (C) is a front view when the light receiving surface at the center is a circle.

5A and 5B are diagrams showing a state in which reflected light is divided and received in a track direction, in which FIG. 5A is a front view in the case where a part of a dividing boundary line is formed in an elliptical shape, and FIG. It is a front view when a part of division | segmentation boundary line is making a circular shape.

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

7A is a front view of a prism, and FIG. 7B is a side view thereof.

FIG. 8A is a front view of a hologram, and FIG. 8B is a side view thereof.

FIG. 9 is a configuration diagram illustrating an overall configuration of an optical pickup device according to a fourth embodiment of the present invention.

FIG. 10A is a perspective view of a prism having a plurality of different light beam splitting regions, and FIG. 10B is a front view thereof.

FIG. 11 is a front view of a hologram having a plurality of different light beam division regions.

FIG. 12 is a front view when a plurality of light receiving elements are mounted on the same substrate.

FIG. 13 is a configuration diagram illustrating an overall configuration of an optical pickup device according to a fifth embodiment of the present invention.

FIG. 14 is a front view when a laser light source and a light receiving element are integrally mounted in a housing.

FIG. 15 is a configuration diagram showing a modified example of FIG.

FIG. 16 is a configuration diagram showing a conventional optical pickup device.

17A is a configuration diagram showing an optical system when signal detection is performed by the astigmatism method, and FIG. 17B is a configuration diagram showing an optical system when signal detection is performed by the knife edge method.

18A is an explanatory diagram illustrating the principle of diffraction on the optical disk surface, and FIG. 18B is an explanatory diagram illustrating light intensity distributions corresponding to 0-order light and primary light constituting reflected light.

FIGS. 19A and 19B are side views showing the principle of diffraction caused by phase pits, and FIG. 19B is a side view showing the principle of diffraction caused by a phase change optical disk.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Laser light source 6 Objective lens 7 Optical information recording medium 18 Track 19 Pit 20a 0th-order light 20b Primary light 21 Light-receiving means (light-receiving element) 24 Beam splitting means (prism) 26 Beam splitting means (hologram) 27 Beam splitting means (prism) 27a-27e Light beam splitting area 30 Light beam splitting means (hologram) 30a-30d Light beam splitting area 31 Substrate 32a-32d Light receiving element 33 Housing 34a-34d Light receiving element

────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-8-315401 (JP, A) JP-A-5-128575 (JP, A) JP-A-5-298721 (JP, A) JP-A-5-298721 120726 (JP, A) (58) Field surveyed (Int. Cl. ⁷ , DB name) G11B ^7/ 12-7/22 G11B 7/09

Claims (10)

(57) [Claims] 1. A laser beam emitted from a laser light source is condensed by an objective lens and irradiates pits formed on a predetermined track of an optical information recording medium, and reflected light from the optical information recording medium is detected. In the optical pickup device that reproduces the recorded information, the reflected light including the zero-order light and the primary light from the optical information recording medium mainly includes the zero-order light and the primary light in the track direction. An information signal is reproduced from a difference between a first light area corresponding to a part where light overlaps and a second light area corresponding to a part of the zero-order light which hardly contains the primary light in the track direction. An optical pickup device comprising information signal reproducing means. 2. A laser beam emitted from a laser light source is condensed by an objective lens and irradiates pits formed on a predetermined track of an optical information recording medium, and reflected light from the optical information recording medium is detected. An optical pickup device for reproducing information recorded by the optical information recording medium, a first light area located at both ends of a light beam divided into three in a track direction in reflected light from the optical information recording medium; An information signal reproducing means for reproducing an information signal from a difference from a second light area located at a central portion between the first light areas. 3. A laser beam emitted from a laser light source is condensed by an objective lens and irradiates pits formed on a predetermined track of an optical information recording medium to detect reflected light from the optical information recording medium. In the optical pickup device for reproducing the information recorded by the above, in the reflected light from the optical information recording medium, the first light region of the peripheral portion, the second light of the central portion surrounded by the first light region An optical pickup device comprising an information signal reproducing means for reproducing an information signal from a difference from an optical area. 4. A laser beam emitted from a laser light source is condensed by an objective lens and irradiates pits formed on a predetermined track of an optical information recording medium, and reflected light from the optical information recording medium is detected. An optical pickup device for reproducing information recorded by the optical information recording medium, a first light area of the reflected light from the optical information recording medium, the first light area being located at a peripheral portion of a light beam divided in a track direction; An optical pickup device provided with an information signal reproducing means for reproducing an information signal from a difference from a second optical region other than the region. 5. An information signal reproducing means for dividing a reflected light from an optical information recording medium into a plurality of areas in a track direction, and separately receiving the reflected light divided into the plurality of areas. 5. The optical pickup device according to claim 1, further comprising a light receiving unit. 6. The optical pickup device according to claim 5, wherein the light beam splitting means comprises a prism. 7. The optical pickup device according to claim 5, wherein the light beam splitting means comprises a hologram. 8. The optical pickup device according to claim 5, wherein the light beam splitting means has a plurality of different light beam splitting regions. 9. The method according to claim 1, wherein a plurality of light receiving elements for separately receiving the reflected light from the optical information recording medium are provided, and the plurality of light receiving elements are mounted on the same substrate. Optical pickup device according to any one of claims 1, 3, 4, 5, 6, 7 and 8. 10. The optical pickup device according to claim 8, wherein the laser light source and the light receiving element are provided integrally in the same housing.