CN1581318A - Miniature optical pickup head module, and its manufacture method and view finding objective lens manufacturing method - Google Patents

Abstract

At least two pieces of fresnel zone plate are formed on a transparent basic plate. Then, a group of plane mirror of forming an acute angle with the base plate is prepared through special oblique exposure procedure by using thick film photoresistive. Metal layers are deposited plane located at outside of the said acute angle. One metal layer makes the plane mirror become reflector, and another metal layer makes another plane mirror become beam-splitter mirror being semitransparent and half reflective. A laser head is setup on another face of base plate opposite to fresnel zone plate; and an optical sensor is setup on another face of base plate opposite to another fresnel zone plate. The invention reduces assembling complexity and produces optical reading head in small size.

Description

Instructions micro-optical read head module and its manufacture method and viewing lens manufacture method thereof

Technical field

The invention relates to the manufacture method of a kind of micro-optical read head module and its manufacture method and viewing lens thereof, particularly about a kind of optically read head module that can read optical store medium matter.

Background technology

Optically read head module is the part of most critical in the CD-ROM drive, is responsible for producing small luminous point to read the stored data of CD (optical disk).For CD-ROM drive can be fast and reading of data continuously, CD must be done rotatablely moving at a high speed, and optically read head module also need cooperate the athleticism of CD to obtain data-signal on it.

Existing optically read head module is that laser head, optical sensor and small optical mirror slip are assembled in the housing, and the fixed angle of each element and relative position all need quite accurate, and Fig. 1 promptly is the synoptic diagram of an existing optically read head module 10.Send after the light source by first laser head 141 or second laser head 142, form a branch of directional light via collimating mirror (collimationlens) 11 after, by face mirror 12 directional light is reflexed to spectroscope (beam spliter) 13 again.Spectroscope 13 can be with the partial parallel photoconduction to CD 95, but will pass the track (scheming not shown) that viewing lens 16 just can focus on CD 95 earlier.Reflect different light signals via the pothole on the track, these light signals then can be by focusing to optical sensor 15 again after spectroscope 13 beam split.This first laser head 141 can send the non-boundling shape laser that wavelength is 780nm, is used to read the CD of CD form; And second laser head 142 can send the non-boundling shape laser that wavelength is 650nm, then is applicable to the CD that reads the DVD form.

Not only element is various but also assembling is complicated for existing optically read head module, also needs to take suitable space on the other hand and just can finish all light paths.To sum up say, press on the market a kind of have more conformability, integraty and cheaply processing procedure solve the existing problem of above-mentioned optically read head module.Fundamental purpose of the present invention provides a kind of micro-optical read head module and its manufacture method, it utilizes micro electronmechanical processing procedure that minute surface, condenser lens, laser head and the optical sensor of multiple angle are integrated on the transparency carrier, can significantly reduce the complicacy of assembling, and satisfy the requirement that the position is accurately aimed at.

Summary of the invention

Fundamental purpose of the present invention provides a kind of micro-optical read head module and its manufacture method, utilize micro electronmechanical processing procedure that minute surface, condenser lens, laser head and the optical sensor of multiple angle are integrated on the transparency carrier, can significantly reduce the complicacy of assembling, and satisfy the requirement that the position is accurately aimed at.

Second purpose of the present invention provides a kind of optically read cheaply head module, and the optical mirror slip of its use produces with manufacture of semiconductor, therefore can form several modules simultaneously on a transparency carrier.

The 3rd purpose of the present invention provides the small optically read head module of a kind of volume, because of all elements all are integrated on the transparency carrier with manufacture of semiconductor, so can be with whole volume microminiaturization.

For achieving the above object, the present invention discloses the manufacture method of a kind of micro-optical read head module and its manufacture method and viewing lens thereof, it is to form at least two fresnel's zone plates (Fresnel zone plate) on a transparent substrate, adopt the thick film photoresistance to form the one group of level crossing that is in sharp angle with substrate with the processing procedure that tiltedly exposes to the sun (inclined exposure process) again, the position of this group level crossing lays respectively at the top of this group fresnel's zone plate.The depositing metal layers respectively on the plane in the sharp angle outside of this group level crossing, wherein a metal level can make a level crossing become catoptron, and another metal level can make a level crossing become can partly to penetrate and the spectroscope of half reflection.There is a transparent polymeric material to be coated in the surface of this substrate, and should organizes level crossing and coat fully.At last form a condenser lens on the surface of this polymeric material again, its position is above optical sensor.Then a fresnel's zone plate is provided with a laser head with respect to another surface of this substrate therein, and another fresnel's zone plate is provided with an optical sensor with respect to another surface of this substrate.

This condenser lens is partly to cover light shield (3D shadow mask) by three-dimensional and produce the condenser lens of a plano-convex (plano-convex); Or utilize the hydrophilic and hydrophobic property and the temperature adjustment of photoresist, thereby on this transparent polymeric material, form condenser lens because of internal stress.

Description of drawings

The present invention will illustrate according to accompanying drawing, wherein:

Fig. 1 is the synoptic diagram of an existing optically read head module;

Fig. 2 (a)～(e) is the processing procedure synoptic diagram of micro-optical read head module of the present invention;

Fig. 3 is the synoptic diagram of optically read head module of the present invention;

Fig. 4 is with the synoptic diagram of layer metal deposition in the outer surface of level crossing;

Fig. 5 (a)～(c) is another processing procedure synoptic diagram of micro-optical read head module of the present invention;

Fig. 6 (a)～6 (c) is the synoptic diagram of the manufacture method of viewing lens of the present invention;

Fig. 7 (a)～7 (e) is the synoptic diagram of another manufacture method of viewing lens of the present invention.

Description of reference numerals

21,51 transparency carriers

22,52 fresnel's zone plates

23 thick film photoresist layers

241,541 first level crossings

242,542 second level crossings

251,551 the first metal layers

252,552 second metal levels

26,56 optical sensors

27,57 laser heads

30 optically read head modules

31 viewing lens

41 fixed mesas

42 containers

43 metal targets

58 polymeric materials

59 viewing lens

61 base materials

621,622,623 special teflon

63,63 ', 63 " polymeric materials

71 base materials

72,72 ' photoresist layer

73 light shields

74 hemispheres

75 plano-convex lenss, 75 ' curved mirror, 75 " plano-concave lenss

92 light shields

93 glycerine

94 exposure lights

95 CDs

Embodiment

Fig. 2 (a)～(e) is the processing procedure synoptic diagram of micro-optical read head module of the present invention.At first on transparency carrier 21, produce fresnel's zone plate 22, with as collimating mirror and focus on purposes.It is after transparency carrier 21 usefulness sulfuric acid mixing hydrogen peroxide are cleaned up, and last glimmer resistance of spin coating (spin-on) and exposure imaging go out the complementary graph (pattern) of fresnel's zone plate.With low cost and optical characteristics is good because of glass, this transparency carrier 21 more often uses glass.Again with the thick aluminium lamination of about 1500 on full wafer transparency carrier 21 evaporations, utilize aluminium to work as diffraction fringe in the fresnel's zone plate 22, again full wafer transparency carrier 21 bubbles are advanced to be equipped with in the solution of removing photoresistance agent afterwards, and fresnel's zone plate 22 is formed on the transparency carrier 21 via the processing procedure of peeling off (lift-off).

Fig. 2 (b) is the surface coated one thick film photoresist layer 23 that is provided with fresnel's zone plate 22 at transparency carrier 21, and this thick film photoresist layer 23 is better with the thick film photoresistance of selecting model SU-8 for use.In order to reduce the loss of laser, the thickness of thick film photoresist layer 23 of the present invention is better to reach about 1000 μ m.This thick film photoresist layer 23 also must could solidify through overbaking, and the upper surface after solidifying can be because of being heated factor out-of-flatnesses such as uneven and horizontal adjustment, so can be at upper surface spin coating one glycerine (glycerol) film, thick film photoresist layer 23 rough parts or hole are are all filled and led up, to reduce when exposing because the optics diffraction effect that surface irregularity was produced.Because of glycerine is a kind of transparent material, its viscosity and refractive index (as getting 1.6) are all considerably approaching with the thick film photoresist layer 23 of SU-8, and not can and SU-8 between any chemical action takes place, so be to be used for filling up the quite desirable material in gap (gap).Certain other transparent liquid also can replace glycerine and reach identical exposure effect, but the liquid refractive index requirement is preferable in 1.4～1.8 scopes.

Then light shield 92 and the transparency carrier 21 that is attached with thick film photoresist layer 23 are combined, and its conjunction is placed under the exposure light source, shown in Fig. 2 (c).And above-mentioned conjunction becomes certain specific angle with the incident direction of exposure light 94, this processing procedure that is different from existing vertical exposure, and we are referred to as tiltedly to expose to the sun processing procedure.Because of the refractive index of air is 1, the refractive index 1.53 of the light shield of making less than glass 92, so the refraction angle of exposure light 94 will be much smaller than incident angle.This incident angle is meant the angle between exposure light 94 and light shield 92 normals to a surface; Exposure light 94 is through light shield 92 surface modification light direct of travels, and direction after it changes and the angle between light shield 92 normals to a surface are the refraction angle.With respect to the refractive index of air, the refractive index of thick film photoresist layer is 1.67, so the birefringence angle of exposure light 94 and secondary incident angle are about equally.For the irradiation angle that exposes to the sun that can make thick film photoresist layer 23 has bigger range of choice, and be not subject to primary refraction angle, this conjunction can be buried and be dipped in the glycerine 93, so make the refraction angle of exposure light 94 in light shield 92 approximately equate with incident angle.

If the thick film photoresist layer of selecting for use 23 is negative photoresistance, light shield 92 can be removed the part that exposure light 94 covers in the step of removing photoresistance, therefore on transparency carrier 21, stay one group of first level crossing 241 and second level crossing 242 that tilts, and transparency carrier 21 is 19～90 degree with the angular range of this first level crossing 241, second level crossing 242 respectively, shown in Fig. 2 (d).This first level crossing 241 and second level crossing 242 be respectively by directly over the different fresnel's zone plates 22, and the different the first metal layer 251 and second metal levels 252 of deposition on the outer surface of sharp angle respectively.This first metal layer 251 can make first level crossing 241 become one and can partly penetrate and the spectroscope of half reflection, and second metal level 252 can make second level crossing 242 become a catoptron.

Arrive the reflected light that transparency carrier 21 backs produce a symmetrical angle for fear of exposure light 94, can be at surface coated one deck anti-reflecting layer of transparency carrier 21, as the photoresist of model C K6020L.This anti-reflecting layer can absorb any light from transparency carrier 21 surface reflections when tiltedly exposing to the sun.In addition, also can use polariscope to eliminate partial reflection light, as long as polariscope is placed the exposure light 94 preceding light waves that just can eliminate the particular amplitude direction, the surface that remaining exposure light 94 will be difficult for self-induced transparency substrate 21 produces reflection.

Then utilize individual layer self-assembly (Self-Assembly Monolayer; SAM) processing procedure is fixed in laser head 27 and optical sensor 26 lower surface of transparency carrier 21 respectively, shown in Fig. 2 (e).The position of laser head 27 be provided in a side of a fresnel's zone plate 22 wherein under, the position of optical sensor 26 then be located at another fresnel's zone plate 22 under.So-called individual layer self-assembly technology, the combination of utilizing bond power powerful between special metal and mercaptan to be produced exactly, for example: gold.Therefore, can form earlier the gold layer, and adhere to the mercaptan material at the ad-hoc location of the lower surface of transparency carrier 21 on the surface of laser head 27 and optical sensor 26.By gold and the two powerful bond power of mercaptan, make laser head 27 and optical sensor 26 can once adhere to correct position in large quantities and automatically.This technology is not only saved the action that repeats to assemble, and the automatic secured in alignment position of energy, is a kind of quite efficient method.

Again the combination of elements of finishing among a viewing lens 31 and Fig. 2 (e) is become an optically read head module 30 together at last, as shown in Figure 3.Send after the light source by laser head 27, form a branch of directional light via fresnel's zone plate 22 after, by second metal level 252 and second level crossing 242 directional light is reflexed to the first metal layer 251 and first level crossing 241 again.And the first metal layer 251 and first level crossing 241 can pass viewing lens 31 earlier with partial parallel light, and focus on the track (scheming not shown) of CD 95.This part focused light reflects different light signals via the pothole on the track, and these light signals then can be focused to optical sensor 26 by fresnel's zone plate 22 again by after the first metal layer 251 and 241 beam split of first level crossing.

Fig. 4 is with the synoptic diagram of layer metal deposition in the outer surface of level crossing.The present invention can utilize the processing procedure deposition the first metal layer 251 and second metal level 252 of evaporation or sputter, for example can earlier transparency carrier 21 be placed on the fixed mesa 41, and be stored in the interior metal targets 43 of container 42 with electron gun bombardment (bombard).The atom on these metal targets 43 surfaces can spin off, and is attached to the surface of second level crossing 242.The atom of metal targets 43 covered because of first level crossing 241 simultaneously, so can't deposit on it.Again, adjust first level crossing 241 and second level crossing 241 with respect to metal targets 43 to suitable angle, just the fresnel's zone plate 22 of inboard can be covered and prevent the deposition of metal targets 43.When needs evaporation or sputter the first metal layer 251, the surface of second metal level 252 to be covered to prevent repeated deposition equally.

In conjunction with Fig. 2 (a)～(d) and Fig. 5 (a)～(c) is the processing procedure synoptic diagram of another embodiment of micro-optical read head module of the present invention, and Fig. 5 (a)～(c) is the successive process synoptic diagram of hookup 2 (d).Cover the polymeric material 58 of layer of transparent on transparency carrier 51, this polymeric material 58 buries first level crossing 541 and second level crossing 542.And utilizing heating or light to expose to the sun according to polymeric material 58 is solidified, the first metal layer 551, second metal level 552 and fresnel's zone plate 52 also can be subjected to best protection simultaneously.

Fig. 5 (b) is upper surface formation one viewing lens that can focus on 59 at polymeric material 58, and this viewing lens 59 is the tops that are positioned at first level crossing 541.At last, utilize individual layer self-assembly technology respectively laser head 57 and optical sensor 56 to be fixed in the lower surface of transparency carrier 51, shown in Fig. 5 (c).The position of this optical sensor 56 is below viewing lens 59, and so the light source that sends of laser head 57 can see through first level crossing 541 and the first metal layer 551 beam split to optical sensor 56 and viewing lens 59.Certainly, at same transparency carrier 51 two laser heads 57 and two corresponding optical sensors 56 can be set respectively, wherein one group of laser head 57 and optical sensor 56 can read the CD of CD form, and another group then can read the CD of DVD form.In addition, in that a micro-actuator (scheming not shown) can be set below the viewing lens 59 and between the polymeric material 58, can change the focal position of viewing lens 59 by the action of micro-actuator, thereby reach the purpose of zoom.

Fig. 6 (a)～6 (c) is the synoptic diagram of the manufacture method of viewing lens.At first on a base material 61, form the special teflon 621,622 and 623 of ring-type of concentric, be coated with the polymeric material 63 of layer of transparent then.Utilize the hydrophobicity of special teflon to be higher than the characteristic of base material 61, polymeric material 63 suitably heated, owing to the effect of internal stress can make polymeric material 63 to the center of circle assemble the polymeric material 63 that forms an arch '.This polymeric material 63 ' can not remain on the surface of special teflon 621, but rest on water wettability base material 61 surfaces preferably, shown in Fig. 6 (b).Certainly,, will inwardly continue to gather and form the polymeric material 63 of hemisphere as the direction of arrow if improve the heating-up temperature of polymeric material again ", shown in Fig. 6 (c).The present invention can be focused to suitable position with the polymeric material heating according to needed curvature, and utilizes light to expose to the sun according to making the polymeric material full solidification of having assembled, so just can form a plano-convex lens as viewing lens.

Fig. 7 (a)～7 (e) is the synoptic diagram of another manufacture method of viewing lens.The present invention forms translucent hemisphere 74 polymkeric substance earlier on the light shield 73 of glass material, and utilizes exposure light 94 on hemisphere 74 surfaces different penetrabilitys to be arranged, and therefore makes the photoresist layer 72 on the base material 71 be subjected to different exposure doses.This photoresist layer 72 is positive photoresistances, so Bao Guang part can be removed fully, only stays a hemispherical plano-convex lens 75.Certainly, if with the irradiating angle of exposure light 94 change into non-perpendicular to light shield 73 ' direction, and cover light shield 73 ' the go up whole patterns of right-hand part of three-dimensional hemisphere 74 with metal level, adopt on the base material 71 simultaneously the photoresist layer 72 of negative photoresistance ', then the exposure after can obtain an asymmetrical curved mirror 75 ', shown in Fig. 7 (c)～7 (d).If with this photoresist layer 72 ' be located at base material 71 belows, exposure light 94 refracts to photoresist layer 72 ' to expose from substrate 71, treat that then the part of not exposing is fully removed after, just can form a plano-concave lens 75 ", shown in Fig. 7 (e).

Technology contents of the present invention and technical characterstic disclose as above, yet the personage who is familiar with this technology still may be based on teaching of the present invention and announcement and done all replacement and modifications that does not deviate from spirit of the present invention.Therefore, protection scope of the present invention should be not limited to the content that embodiment discloses, and should comprise various do not deviate from replacement of the present invention and modifications, and is contained by the claim of present patent application.

Claims (24)

1. micro-optical read head module comprises:

One transparency carrier has first surface and second surface;

At least two fresnel's zone plates are located at the first surface of this transparency carrier;

First level crossing is bonded with each other with a sharp angle with the first surface of this transparency carrier, and is arranged in the top of these at least two fresnel's zone plates;

The first metal layer is located at the another side of this first level crossing with respect to this sharp angle, is used for partly penetrating and half reflection light;

Second level crossing is bonded with each other with a sharp angle with the first surface of this transparency carrier, and is arranged in the top of these at least two fresnel's zone plates;

Second metal level is located at the another side of this second level crossing with respect to this sharp angle, is used for reflection ray;

One laser head is located on the second surface of this transparency carrier the position with respect to this second level crossing;

One optical sensor is located on the second surface of this transparency carrier the position with respect to this first level crossing.

2. micro-optical read head module as claimed in claim 1 is characterized in that comprising a viewing lens in addition, is located at the top of described the first metal layer.

3. micro-optical read head module as claimed in claim 1 is characterized in that comprising in addition: one is used to coat the polymeric material of this first level crossing and second level crossing; And be located on the surface of this polymeric material a viewing lens with respect to the position of this optical sensor.

4. micro-optical read head module as claimed in claim 1 is characterized in that comprising in addition the anti-reflecting layer of the first surface of being located at this transparency carrier.

5. micro-optical read head module as claimed in claim 1 is characterized in that described fresnel's zone plate is as collimating mirror and focuses on usefulness.

6. micro-optical read head module as claimed in claim 1 is characterized in that comprising in addition a micro-actuator that combines with this viewing lens, and it can change the focal position of this viewing lens.

7. the manufacture method of a micro-optical read head module comprises the following step:

One transparency carrier is provided;

Surface at this transparency carrier forms one group of fresnel's zone plate;

Coating one thick film photoresist layer on this transparency carrier and this fresnel's zone plate;

One light shield is placed the surface of this thick film photoresist layer, and to expose non-perpendicular to the mode of exposure light and to develop;

Carry out removing photoresistance, thereby produce first level crossing and second level crossing that tilts to be located at this transparency carrier;

Can partly penetrate and the metal level of half reflection light at surface deposition one deck of this first level crossing;

But metal level at surface deposition one deck reflection ray of this second level crossing.

8. the manufacture method of micro-optical read head module as claimed in claim 7 is characterized in that comprising in addition another surperficial step of a laser head and an optical sensor being located at this transparency carrier.

9. the manufacture method of micro-optical read head module as claimed in claim 8, it is characterized in that described laser head and optical sensor are to utilize individual layer self-assembly processing procedure to combine with this transparency carrier, this self-assembly processing procedure is to utilize bond power powerful between special metal and the mercaptan and produce combination.

10. the manufacture method of micro-optical read head module as claimed in claim 7 is characterized in that comprising in addition the step of an anti-reflecting layer being coated this transparency carrier.

11. the manufacture method of micro-optical read head module as claimed in claim 7 is characterized in that being included in addition before the exposure this light shield and this thick film photoresist layer soaked and is embedded in the interior step of the refractive index liquid close with this thick film photoresist layer.

12. the manufacture method of micro-optical read head module as claimed in claim 11 is characterized in that described liquid refractive index is in 1.4 to 1.8 scope.

13. the manufacture method of micro-optical read head module as claimed in claim 11 is characterized in that described liquid is glycerine.

14. the manufacture method of micro-optical read head module as claimed in claim 7 is characterized in that described transparency carrier is the 19-90 degree with the angular range of this first level crossing, this second level crossing respectively.

15. the manufacture method of micro-optical read head module as claimed in claim 7 is characterized in that comprising in addition the step of utilizing a polariscope to remove particular light ray.

16. the manufacture method of micro-optical read head module as claimed in claim 7 is characterized in that wrapping in addition the following step:

Utilize a transparent polymeric material to coat this first level crossing and the two or two level crossing;

Form a viewing lens on the surface of this polymeric material;

One laser head and an optical sensor are located at another surface of this transparency carrier.

17. the manufacture method of micro-optical read head module as claimed in claim 7 is characterized in that comprising in addition the step of filling up the surface pore of this thick film photoresist layer with an oil film.

18. the manufacture method of the viewing lens of a micro-optical read head module comprises the following step:

One transparent base material is provided;

Surface at this base material forms the ring-type figure with concentric with the material that hydrophobicity is different from this base material;

On this base material and this ring-type figure, cover one deck polymeric material;

The control heating-up temperature makes this polymeric material gather to the center of circle;

Make this polymeric material solidifying and setting.

19. the manufacture method of the viewing lens of micro-optical read head module as claimed in claim 18 is characterized in that described ring-type figure is to select for use special teflon to make.

20. the manufacture method of the viewing lens of micro-optical read head module as claimed in claim 18 is characterized in that described polymeric material is one can be subjected to the photoresist of photocuring.

21. the manufacture method of the viewing lens of micro-optical read head module as claimed in claim 18, it is characterized in that utilizing surface hydrophobic or hydrophilic difference and change the radius-of-curvature of this viewing lens, thereby and the temperature of this base material of control heating change the focal length of this viewing lens.

22. the manufacture method of the viewing lens of a micro-optical read head module is characterized in that comprising the following step:

One transparent base material is provided;

Provide a surface to have the light shield of three-dimensional semi-transparent spherical;

On this base material, cover one deck photoresistance;

This light shield is placed this base material top and expose;

On this base material, produce photoresistance figure corresponding to this semi-transparent spherical.

23. the manufacture method of the viewing lens of micro-optical read head module as claimed in claim 22 is characterized in that described photoresist layer accepts the photograph that exposes to the sun of exposure light with non-perpendicular angle.

24. the manufacture method of the viewing lens of micro-optical read head module as claimed in claim 22, the semi-transparent spherical that it is characterized in that described light shield is formed by a photo curable polymeric material.

Images