CN100343717C - Double-layer dielectric reflective space optical modulator with self-limiting micro-mechanical component - Google Patents

Double-layer dielectric reflective space optical modulator with self-limiting micro-mechanical component Download PDF

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CN100343717C
CN100343717C CNB2005100679297A CN200510067929A CN100343717C CN 100343717 C CN100343717 C CN 100343717C CN B2005100679297 A CNB2005100679297 A CN B2005100679297A CN 200510067929 A CN200510067929 A CN 200510067929A CN 100343717 C CN100343717 C CN 100343717C
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medium
light modulator
spatial light
deflecting element
micromirror
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CN1673800A (en
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A·G·休博斯
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Reflectivity Inc
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Reflectivity Inc
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Abstract

The present invention relates to a space optical modulator (12) which comprises an upper end optical lens medium (20) fixed above a lower end medium (34), and the lower end medium (34) comprises an addressing circuit. One or more electrostatic deflection elements (48) are suspended on the upper end medium (20) through a hinge (50). When the present invention is operated, a single electrostatic deflection element (48) is deflected selectively, which is helpful to modulate light (56) radiated to the upper end medium (20) spatially, and then, the light passes through the upper end medium (20) to be reflected back. A motion limiting pin (49) is fixed to the deflection element with reflection performance so as to make the electrostatic deflection element (48) not hit the lower end medium (34) suddenly. The motion limiting pin (49) pushes against the upper end medium (20), and thereby, a deflection angle of the electrostatic deflection element (48) with reflection performance is limited.

Description

The double-layer dielectric reflective space optical modulator that has self-limiting micro-mechanical component
The application is that the name of submitting on September 24th, 1998 is called: the dividing an application of the Chinese patent application 988142236 of " double-layer dielectric reflective space optical modulator that has self-limiting micro-mechanical component ".
Technical field
The present invention relates to spatial light modulator, especially have the spatial light modulator that is fixed on the addressable deflectable element of electronics on the optical transmission medium.
Background technology
Spatial light modulator (SLM) is with the transducer of spatial model modulation with a kind of light or the corresponding a branch of incident light of electricity input.Incident light can be modulated on phase place, intensity, polarization or direction.This modulation can have photomagnetism, photo or flexible various material by use and realize.SLM has many application, comprises display system, optical information processing, optical data storage and printing.
General technology for a SLM unit is that folder is used a liquid crystal material between two electrodes, and one of them electrode is transparent.By add a voltage between two electrodes, the direction of molecule changes in the liquid crystal layer, and this can change the optical property of layer, especially passes through the polarisation of light of this layer transmission.Therefore, the liquid crystal layer that combines with one or more polarizing filter devices can be used to form an amplitude modulaor (light valve).Yet this liquid crystal based on device is used SLM several disadvantages.At first, the mass part of light is absorbed in the polarizing filter device, has reduced the efficient of light.In addition, the contrast ratio that device is limited, (when the pixel intensity when device is opened is closed with device pixel intensity than), and reaction time very slow (a few microsecond) of widely used liquid crystal.Also have, liquid crystal is poor performance outside a temperature range that is rather narrow.Because these and other uses the SLM of the machinery of the structure deflection that moves to be studied always.
An early stage mechanical SLM who is designed to projection display system is described by Nathanson, and U.S. Patent number is U.S.Pat.No.3, and 746,911.The single pixel of SLM is as being addressed by a scanning beam in a direct-view cathode ray tube (CRT) commonly used.Electron beam is not to excite a phosphor, but gives the deflectable reflexive element charging that is arranged on the quartzy panel.The element that is recharged is because electrostatic force bends towards panel.Crooked and unbent element reflects directional light to different directions.Intercept with a cover Schlieren light hurdle (Schlieren stops) from the light of unbent element reflects, and be allowed to form an image at screen through projecting optical device from the light of the element reflects of bending.
Another addressing electron beam SLM is the Eidophor, E.Baumann is described in " Fisher broad screen projective system (Eidophor) " (E.Baumann, " The Fischer large-screen projection system (the Eidophor) " 20J.SMPTE 351 (1953)) on the 20th 351 pages of rolling up of the J.SMPTE of nineteen fifty-three.In this system, the active optical element is an oil reservoir, and this oil reservoir is periodically evoked ripples by electron beam so that incident light disperses.A disadvantage of Eidophor system is that oil reservoir is aggregated owing to continuous electronics bombs and the oil volatilization causes cathode life short.A disadvantage of these two systems is that they have used bulky and expensive vacuum tube.
A spatial light modulator, displaceable element wherein is addressed by the electronic circuit that is arranged on the silicon medium, described at " the micromachine optical modulator array of on silicon, making " (K.Peterson, " Micromechanical Light Modulator Array Fabricated on Silicon " 31Appl.Phys.Let.521 (1977)) that 31Appl.Phys.Let. the 31st rolls up on the 521st page (1977) by K.Peterson.This SLM is included in one 16 * 1 cantilever lens array on the silicon medium.These mirrors be make by silicon dioxide and a reflective metal layer arranged.Space under these mirrors is fallen silicon by a KOH etchant etching and is formed.These mirrors are deflected by electrostatic attraction: bias voltage is added between reflecting element and the medium and produces an electrostatic force.A similar spatial light modulator is a two-dimensional array, is described by Hartstein and Peterson, and U.S. Patent number is U.S.Pat.No.4,229,732.Though but the switching voltage of this SLM is lowered owing to only connecting the deflecting mirror element at place, an angle, efficient is very low owing to little optical activity district (as the part in whole device zone) for this device.In addition, the diffraction from addressing circuit has reduced the contrast of display rate.
Micromachine SLM based on silicon (wherein Zhuan Zhi major part is optically active) is digital mirror device (DMD), is U.S.Pat.No.5 by Texas Instruments development and by Harnbeck at U.S. Patent number, 216,537 and list of references in describe.Nearest invention comprises that one is suspended on first aluminum slice on the addressing electrode by torsion hinge.Second aluminum slice is based upon the first aluminum slice top and as a catoptron.Two-sided thin slice constructed of aluminium be required to provide one below the covering circuit and the approximate flat mirror surface of hinge means, in order to reach an acceptable contrast ratio, this is necessary.Make by thin slice by aluminium alloy----for total, and each all has independently optimized composition torsion hinge and special " debarkation point ".Aluminium can be piled up at low temperature, to avoid the CMOS addressing circuit below the infringement in manufacturing process.Yet the weak point of aluminium is fatiguability and easily plastic yield, and this can cause long-term reliability problems and unit " memory ", and clear position begins the inclined position that occupies to its most frequent quilt here.Another weak point of this DMD comprises: 1) in current design, big ripples (supporting pillar by mirror causes) are displayed on the mirror center, the efficient that this causes the incident scattering of light and reduces light.2) whole DMD structure is released by the plasma etching of a condensate sacrifice layer.This manufacturing process is problematic, is that it discharges effectively in order to make plasma etching (A), requires between the catoptron gap big, and (B) forms the pixel loss in dispose procedure, and this is enough not little on the micromirror structure of precision.Because the complicated structure and the difficulty of manufacturing process, the commercialization of DMD is carried out very slowly always.
Another SLM that makes on flat medium is that U.S. Patent number is U.S.Pat.No.5 by the grating valve (GLV) of descriptions such as Bloom, 311,360.As in patent 5,311, described in 360, but the deflection mechanical organ of GLV is reflexive flat post or band.Light is from band and dieletric reflection.If the band of reflection and the distance between the medium of reflection are half-wavelengths, from the light of two faces reflections can increase and the effect of installing as a mirror.If distance is a quarter-wave, directly will interfere devastatingly and this device will become light into the order of diffraction as a diffraction grating from the light of two surface reflections.Good approach is the ceramic layer with high mechanical quality, makes this device as LPCVD (low pressure chemical volatilization deposition) silicon nitride.
Even addressing circuit can not be placed under this film, a kind of intrinsic electromechanical bistable state also can be used as realization a kind of " passive " addressing scheme (Raj Apte, be used for the grating light valve that high-resolution shows, Stanford University's PhD dissertation, in June, 1994) (Raj Apte, Grating Light Valves for High Resolution Displays, StanfordUniversity Ph.D.thesis, June 1994).It is because mechanical force that deflection requires is linear roughly that bistable state exists, and electrostatic force is followed inverse square law.When applying a bias voltage, belt deflector.When band was deflected certain when a bit, thereby the mechanical force of storage no longer can be bitten medium by balance electrostatic force band suddenly.In order to make the position of band when returning to not deflection, voltage must be reduced under the voltage that fractures basically.This locking behavior allows driving circuit to be placed in outside the sheet or only at periphery, and addressing circuit needn't occupy the optical activity part of array.In the reality, this approach is difficult to realize: when band was contacted with medium, at this moment it was in a different gesture, and charge energy injects into insulating ceramics carrying material, thereby alteration switch voltage makes passive addressing impossible.The film nonuniformity of whole device is alteration switch voltage significantly also.Another problem about the GLV technology is a bonding: because the downside of the band of deflection contacts with the big surface of medium, band trends towards adhering on the medium.The film that comprises this structure can be roughened, but this causes undesired optical scattering, has reduced the contrast ratio of device.
The SLM based on catoptron of micromachine more has superiority because they only reflect incident light with an angle than the SLM based on diffraction, and this angle may be quite big.This simplifies this Design for optical system, and in this optical system, modulated light can pass the center of imaging len, keeps high-level efficiency simultaneously.This causes the still less not normal and reduction manufacturing cost of image.
Therefore, need one high contrast ratio, high efficiency, spatial light modulator are at a high speed arranged, this modulator is made easily, and its moving meter is made by reliable mechanical material.
Summary of the invention
Briefly, according to one embodiment of present invention, a spatial light modulator comprises an optical transmission medium and a circuit medium.One or more reflexive deflectable elements is fixed on the lower surface of optical transmission medium.This optical transmission medium is maintained at the top of circuit medium and spaced away, but this circuit medium comprises the addressing circuit that can optionally activate each reflectivity deflecting element.
In operation, single reflex components is deflected selectively and is used for the light that the optical transmission medium is incided in the modulation of ground, space, passes the optical transmission medium then and is reflected.
In one embodiment of the invention, spatial light modulator comprises a pel array.Each pixel comprises a single deflectable rigidity mirror and a torsion hinge, (this hinge is with the top of mirror attached to the optical transmission medium), and optical transmission medium.The optical transmission medium be placed in a silicon medium on, on the optical transmission medium, form an electrod-array.In one embodiment, in the optical transmission medium, form an aperture layer and arrive electrode or mirror supporting construction (hinge and stationary installation) to intercept light.Each mirror is by applying a bias voltage by optionally electrostatic deflection between its corresponding electrode of each mirror.
According to one embodiment of present invention, the process of making this spatial light modulator is provided.One sacrifice layer is deposited on the medium.Pass hole of sacrificial layer etching, this hole allows the layer of back is fixed on the optical transmission medium.A reflection horizon is deposited on this sacrifice layer, but and by medelling to limit one or more reflectivity deflecting elements.This reflection horizon links to each other with sacrifice layer by the hole.Sacrifice layer is removed so that reflex components is freely and can deflection.Addressing circuit and electrode are formed on the circuit medium.This medium is arranged in a line with the circuit medium and is combined so that reflex components can optionally be excited by addressing circuit and electrode.This two medium can be combined, connects as the epoxy material by the medium periphery.
According to one embodiment of present invention, process is included in the bias voltage that applies between deflectable element of reflectivity and the addressing circuit.This bias voltage can be changed in the device operating process.
Electronically addressing circuit on this silicon medium can be used the CMOS fabrication techniques of standard, and similar low-density storage array.
Because this two medium only combines after they are by single manufacturing, so the manufacturing process of each medium is unmatched.Owing in the manufacturing process of top medium, do not consider the compatibility of CMOS, so an advantage of the spatial light modulator of this locust is mechanically deflectable reflex components can be by only making by the selected material of the engineering properties of its high-quality, as silicon nitride, monox, unsetting silicon and many silicon of LPCVD-deposition.Because these films are deposited when high temperature, so they are common and the CMOS process is incompatible, because the latter uses aluminium to be coupled to each other, aluminium can melt when these higher temperature.
Another advantage of this spatial light modulator is after two media are joined together, and the part that moves can all be incapsulated.This provides a kind of packing method of high-quality and has made device high strength.
It is that it is not expensive and manufacturing is simple that spatial light modulator of the present invention also has an advantage.It is made up of two dielectric layers: the optical transmission medium that can use the CMOS fabrication techniques of standard, and the second optical transmission medium that comprises deflectable reflex components, this element is made simple.
Also have, another advantage of this spatial light modulator be photoresistance every aperture layer, and other planar optical device (as, chromatic filter, reflectivity enhancement layer, micro lens) can combine with the optical transmission medium.This can improve contrast ratio and increase effective light deflection angle, and reduces other Free Space Optics installation cost of native system level.
Also have, another advantage of this space optics modulator is that the limit movement structure can also be made by hard and long-life high-temperature material.Because their hardness and geometry, limit movement structure have a little contact region in operating process, this has greatly reduced the cohesive force between structure and medium.Also have, the medium that the limit movement structure is contacted with them is at same electromotive force, and this prevents to bond by welding and electric charge injection.These are problems that earlier version faced of DMD and GLV.
Also have, another advantage of this spatial light modulator is that the pyroprocessing of optical transmission medium allows the thin dielectric film of the high low-refraction that will replace to deposit on deflectable reflexive element, and this improves their reflectivity.
According to feature of the present invention, a kind of method of guide beam is provided, it comprises: the medium of the optical transmission with upper surface and lower surface is provided; But provide the deflecting element of the rigidity that is connected to dielectric surface, but wherein should comprise a first by deflecting element, one second portion and a reflecting surface, but and wherein should be designed to be positioned at not deflection state and deflection state by deflecting element, and when described first moved apart dielectric surface, described second portion was shifted to and can be touched dielectric surface at last; But should be positioned at undeflected state by deflecting element; Pass medium from a light emitted one light beam and arrive on the described reflecting surface, but with box lunch should deflecting element when the deflection state not this light beam be reflected at first direction and pass medium; But and will be somebody's turn to do the state that deflecting element is positioned at deflection, but with box lunch should deflecting element when the deflection state this light beam be reflected in second direction and pass medium.
After accompanying drawing below considering and the detailed description, the advantage of these and other is tangible with respect to those technology of prior art.
Description of drawings
Fig. 1 shows the top perspective at an angle of an embodiment of a spatial light modulator of the present invention.
Fig. 2 A-2F is presented at the bottom perspective view of the pixel of Fig. 1 in the several stages process of making.
A pixel of Fig. 3 A and 3B displayed map 1 is modulated the sectional view of a branch of light.
Fig. 4 shows the hysteresis phenomenon figure of deflection angle of mirror by applying bias voltage Fig. 1.
Fig. 5 shows for several different bias voltages, but acts on electricity and moment diagram machinery on the deflecting mirror.
Fig. 6 A is shown to the DRAM structure of the single addressing of SLM pixel of Fig. 1.
Fig. 6 B is shown to the SRAM structure of the single addressing of SLM pixel of Fig. 1.
Fig. 7 is presented at and gets the top view that escapement is placed in the intensive pel array.
Fig. 8 A-8H shows the backplan of the lens array with different hinge design.
Fig. 9 A-9D is presented at the manufacturing process that a pixel of hinge is arranged between mirror and the optical transmission medium (sub-hinge design).
Figure 10 A-10D shows the embodiment of sub-hinge design.
Figure 11 A-11C is presented at the manufacturing process that the pixel of mirror is arranged between hinge and the optical transmission medium (super hinge design).
Figure 12 shows the embodiment of a super hinge.
Figure 13 shows the top perspective view of amplification at an angle of an embodiment of spatial light modulator of the present invention.
Figure 14 shows the unit with sub-hinge with Figure 10 A of a similar structural unit array design.
Reference numeral in the accompanying drawing
10 micromachine spatial light modulators (SLM)
12 pixels
14 lower surfaces
16 upper surfaces
20 optical transmission media
22 aperture layers
24 protective seams
25 holes
26 sacrifice layers
28 mirror structural support layers
30 hinges
32 reflection horizon
34 circuit media
36 addressing circuits
38 passivation layers
42 hearth electrodes
43 contacts
44 get escapement
46 change layer
48 mirrors
49 motion banking pins
50 hinges
51 hinge support
54 fixed areas
56 light beams of introducing
The light beam of 58 outgoing
60 word lines
62 bit lines
64 light sources
66 imaging optical devices
68 transistors
70 first dielectric layers
72 second dielectric layers
74 voltage sources
78 optics projections
111 projections
Embodiment
Instructions relates to several figures that comprise reference numeral.Same reference number is represented similar or same parts in different figure.
In this manual, word " optical " is used with " light ".In instructions and claims, " optical " meaning is meant relevant with electromagnetic frequency, not only the frequency in the visible light field.As, one " optical transmission medium " is that the electromagnetic wave to a frequency of operation is transmissible medium, no matter this frequency is in the visible-range.
The top perspective view at the angle of an embodiment of a micromachine spatial light modulator 10 of the present invention (using " SLM " thereafter) is presented among Fig. 1.The enlarged drawing of the SLM10 of Fig. 1 is presented among Figure 13.SLM10 can comprise the pixel of any configuration and array size.Yet, for clarity, only four pixels 12 in one 2 * 2 mesh configuration, 12a, 12b and 12c show in the drawings.Pixel 12,12a, 12b and 12c have a pixel pitch, as, 12 microns." pixel pitch " is defined as the distance between the similar portions of adjacent picture elements.
The deflectable element of reflectivity (as, mirror 48,48a, 48b, 48c) (each is respectively corresponding to pixel 12,12a, and 12b 12c) is fixed on the lower surface 14 of an optical transmission medium 20 when inflection point not.Therefore, mirror 48,48a, 48b, the optical transmission medium 20 that 48c sees through among Fig. 1 is visible.For clarity, be positioned at mirror 48,48a, 48b, the photoresistance between 48c and the optical transmission medium 20 only dot so that show following hinge 50,50a, 50b and 50c every aperture layer 22.Spacing between adjacent mirror can be, as, 0.5 micron or less than 0.5 micron.
A process of making SLM10 is displayed in the bottom perspective view among Fig. 2 A-2F.For clarity, only the making of pixel 12 is described.Yet from this instructions, pixel 12a, 12b, other pixel among 12c and the SLM10 can be made simultaneously and be made in the mode identical with making pixel 12.
Optical transmission medium 20 is to be made by the material that can stand continuous treatment temperature.Visit optical transmission medium 20 can for, as, the quartzy thin slice of 4 inches 500 micron thickness.This quartzy thin slice is adopted widely, as, at the Hoya Corporation of No. 960, the Rincon Circle of the San Jose in the Jia Lifuniya state of the U.S., postcode is 95131 (HoyaCorporation U.S.A.at 960 Rincon Circle, San Jose, CA 95131.).
Shown in Fig. 2 A, photoresistance interlayer (as, the tungsten layer of one 50 nanometer thickness) is deposited and is formed photoresistance every aperture layer 22 by moulding.This aperture layer 22 is can keep stable opaque material (as, tungsten) to make in the continuous production phase by one.Tungsten can be by usefulness, as, well-known splash technology, deposition.The model of photoresistance is formed on aperture layer 22 with well-known photolithographic processing.Aperture layer is with a Drytek 100 plasma etching machine etchings then.Volume accounts for 50% SF 6Account for 50% C with volume 2ClF 5Potpourri by with 300sccm (to HF 6Be 150sccm, to C 2CLF 5Be 150sccm) ratio introduce in the reaction chamber of etching machine.The pressure that etching occurs in about 100mTorr down and the power supply on the etching machine be arranged on 500 watts and manifested (about 1 minute) up to optical transmission medium 20.After the etching, remaining photoresistance is taken with a general oxygen plasma to remove.Medelling described later can be operated similarly.
Shown in Fig. 2 B, an optical transmission protective seam 24 (as, about 94 nanometer thickness, weighing the silicon dioxide of 7% Doping Phosphorus) then is deposited and makes a passivation layer.The deflectable element of reflectivity (mirror 48) passes protective seam 24 and is connected on the optical transmission medium 20.Silicon dioxide layer of protection 24 can be deposited, as handling about 5 minutes by LPCVD under the pressure of about 400 ℃ and 250mTorr in the quartz ampoule of a Tylan smelting furnace.SiH 4, O 2, and PH 3By respectively with 28,115 and the speed of 7sccm be incorporated in the chamber.Then, the silicon dioxide of Doping Phosphorus 1100 ℃ in the environment of a steam by reflowing 20 minutes.
Sacrifice layer 26 (as, the thick unsetting silicon layer of about 0.6 μ m), (it is removed in the description of back at last) is deposited on the protective seam 24.Unsetting silicon layer can use LPCVD to handle and be deposited over, as, in the quartz ampoule of a Tylan smelting furnace.SLM10 was shown with 135 minutes under the pressure of about 670 ℃ and 220mTorr in quartz ampoule.SiH 4With H 2Bond by with the flow velocity of 246sccm (to SiH 4Be 146sccm and to H 2Be 100sccm) introduce.
Hole 25 is passed by anisotropic etching optionally and is sacrificed unsetting silicon layer 26 by medelling, as by using the SF 50% 6With 50% C 2CLF 5Modelling plasma etching under the environment of (referring to volume) passes sacrifice layer 26 up to the part of protective seam 24 and is appeared.Such etching can occur in the reaction chamber of Drytex 100 plasma etching machines.Gas componant by with 100sccm (to SF 6Be 50sccm, to C 2CLF 5Be 50sccm) ratio introduce, and pressure is 150mTorr.Main is, needs to pass in about 4.5 minutes this part that sacrifice layer 26 appears protective seam 24 under these conditions.
Mirror structural support layers 28 as a low stress nitride silicon layer that about 138nm is thick, is deposited and medelling formation mirror 48 and motion banking pin 49.Mirror 48 is thin slices of a substantially rigid.The low stress nitride silicon layer can be deposited, as, in the quartz ampoule of a Tylan smelting furnace, handled about 36 minutes by under the pressure of about 785 ℃ and 200mTorr, using LPCVD.Deposition takes place, as, by with SiCl 2H 2And NH 3Ratio with 165sccm and 32sccm is incorporated into quartz ampoule respectively.After the medelling light of deposition and photoresistance appeared, silicon nitride can be etched under 1200 watts voltage by the hexagonal electrode plasma etching machine with ATM8100.Etching gas, as, O 2And CHF 3, to be introduced in the reaction chamber with flow velocity 6sccm and 85sccm respectively, etching period is 17 minutes.Under these conditions, the optional ratio of polymerization silicon and silicon nitride is approximately 1: 6.
Shown in Fig. 2 C, hinge layer 30 (as, low stress nitride silicon layer that about 40nm is thick) is grown then and additionally limited torsion hinge 50 (top view of this pattern can be seen) by medelling in Fig. 8 A.At least the part of hinge 50 is passed hole 25 contact protection layers 24 to limit bearing 51 (Fig. 2 D-2F).Hinge 50 should " reversing " meaning be that hinge 50 is by applying torque vertically being twisted at hinge 50 by " reversing " operation.Therefore, the end that is fixed to the hinge 50 on the mirror 48 with respect to by 51 and 51 ends that supported by the deflection of angled ground.Hinge 50 can for, as, about 0.5 micron wide.
Handle with LPCVD for the thin layer of the low stress nitride silicon of hinge layer 30 and to be deposited in the quartz ampoule of Tylan smelting furnace.SiCl 2H 2And NH 3With flow velocity as, be respectively 165sccm and 32sccm, be introduced into quartz ampoule.As, deposition takes place, as, 785 ℃ of temperature, pressure 250mTorr was with 11 minutes.
As shown in Fig. 2 D, sacrifice layer 26 is partly removed with isotropic etch processes then.Etching process is isotropic so that the part of sacrifice layer 26 is removed from following mirror 48 and hinge 50.By after the etching partly, the sacrifice layer 26 below mirror 48 and hinge 50 is not removed at sacrifice layer 26.On the other hand, the pith of sacrifice layer 26 under mirror 48 and hinge 50 is owing to the protection of mirror 48 and hinge 50 still keeps.Therefore, after part is etched, continue supports mirror 48 and hinge 50 in the described below further making step of sacrifice layer 26 and prevent that unloaded particulate from posting and stay below mirror 48 and the hinge 50.It is in the reaction chamber of Drytex 100 plasma etching machines a plasma etch process to be handled by the mode that appears that a suitable isotropic etching is handled.About 100% SF 6Introduced in the reaction chamber by the flow velocity with about 50sccm, the voltage of putting etching machine is 375 watts.At room temperature (yet, plasma generation heat), under the pressure of about 150mTorr, etching took place about 100 seconds.In this process, silicon is about 6: 1 with the selection ratio of silicon nitride.
With reference to figure 2E, afterwards, the parallel surface of SLM10 (as, mirror structural support layers 28, hinge layer 30, and the part of protective seam 24) plate with a conduction and reflection horizon 32 (as, about thick aluminium lamination of 30nm), and this layer is optical reflectance.Some vertical planes (as, from the vertical plane of the nearest hinge 50 of mirror 48) also by plated film so that the reflection horizon on the mirror structural support layers 28 32 is electrically connected with reflection horizon 32 on the protective seam 24.For clarity, the part in the reflection horizon 32 on the hinge layer 30 and vertical plane be not shown in Fig. 2 E.A reflection horizon 32 like this can be deposited with as, with an angle evaporate aluminium downwards so that the parallel vectors at angle for from mirror 48 to motion banking pin 49.With this angle, the some place that contacts with protective seam 24 without any the motion banking pin 49 of metal (aluminium) on protective seam 24 exists, and does not allow metal deposit because of motion banking pin 49 these surfaces of shielding.Be pointed out that protective seam 24 because the partially-etched of sacrifice layer 26 described above appeared.Evaporation can take place, as, in the reaction chamber of e-gun thermal evaporation machine with the rate of sedimentation of per second one nanometer.
Getting escapement 44 (Fig. 1 to 13) is provided on the optical transmission medium.Getting escapement 44 is, as, form by Hoechst-Delanese AZ4330-RS photoresistance, with 5000rpm rotation in 30 seconds, use traditional lithography technique of taking pictures to be appeared and get escapement 44, in the time of 233 ℃, bake 1 hour then firmly to increase structural rigidity with formation with medelling.
Mirror 48a, 48b and 48c are all discharged from optical transmission medium 20, and except on hinge support 51 and 51, it is to use second isotropic etchant etched, as, a dichloride xenon etch processes, this can remove sacrifice layer 26 fully.This is etched under the pressure of about 4Torr and at room temperature continues about 20 minutes under about 100% a dichloride xenon environment.Under these conditions, the selectivity of this etch processes is more than 100: 1.
The circuit medium 34 that the optical transmission medium 20 that is fixed with lens array on it is easy to comprise addressing circuit 36 with one now (as, a semiconductor medium) combination, the sectional view as shown in Fig. 3 A.Get that escapement 44 (Fig. 1 and 13) combines with the circuit medium to keep optical transmission medium 20 and circuit medium 34 to be separated but nearest.
In one embodiment, the optical element on plane, as, two dielectric layers 70 and 72 (Fig. 2 F) of different refractive indexes are arranged, be deposited as mirror structural support layers 28.This lamination of dielectric layer can reflected light or the specific frequency range of elimination.As, the silicon dioxide layer (optical index is 1.46) that is deposited on the top of silicon nitride layer (optical index is 2.0) will improve reflectivity, as, silicon dioxide is that 96nm is thick if silicon nitride layer is for 68nm is thick, the reflectivity of the 32 pairs of many optical spectras in aluminium reflection horizon is 92% to 95% so.
After sacrifice layer 26 was etched away fully, optical transmission medium 20 combined with circuit medium 34.At first, medium 20 and 34 is optically arranged in a line and is together with each other, and can lump together with the epoxy glue around the edge that is dispersed in circuit medium 34.Because top medium 20 is optics transmissives, so just can realize at an easy rate being arranged in a straight line by model on the optical transmission medium 20 and a model on the circuit medium 34 are in line.By the epoxy of the dispersion around the edge of optical transmission medium 20 and circuit medium 34 under a clean environment, mirror 48 can be isolated with unloaded micron.
In Fig. 3 A, the bottom electrode 42 of unit 12 (as, thick aluminium bottom electrode of 500nm) is shown and passes contact 43 and be connected with addressing circuit 36.Many configurations are possible.In one embodiment, active bottom electrode 42 physically the position than the remainder of circuit component 36 and the position height at interconnective position.In the present embodiment, bottom electrode 42 interacts by the superincumbent mirror 48 of electrostatic force and suspension.
Operating among Fig. 3 A and Fig. 3 B of embodiment described above shows.In Fig. 3 A, mirror 48 is undeflected.In this undeflected state, the light beam on that introduce from light source 64, oblique SLM10 of being mapped to passes optical transmission medium 20 and is reflected by level crossing 48 and by aperture layer 22 partial reflections.Therefore the angle of the light beam 58 of output also tilts with optical transmission medium 20.The light beam of output can by, as, optics projection 78, receive.Aperture layer 22 is the technology that undesired diffusion light is removed from following hinge 50 with combining of optical transmission medium 20.
Unit 12 with a bias voltage is shown in Fig. 3 B, and this bias voltage is applied between mirror 48 and the bottom electrode Unit 42.Mirror 48 is deflected owing to electrostatic attraction.Because the design of hinge 50, the free end of mirror 48 is deflected to circuit medium 34.Be pointed out that hinge 50 can make all basically bendings in hinge 50 than applying of the more flexible such power of mirror 48.This can be much thin as to come to realize such as the mirror structural support layers 28 of the above by making hinge layer 30.The deflection of mirror 48 makes the light beam 58 of output enter in the imaging optical device 66 with a suitable angular deflection.
The motion of mirror 48 be subjected to be deposited on optical transmission medium 20 on the motion banking pin 49 that contacts of protective seam 24 limit (Fig. 3 B) so that mirror 48 does not contact with circuit medium 34.Because contact does not take place, so be electrically connected mirror 48,48a, 48b and 48c remain on same gesture point.Also have, can produce between bonding mirror 48 and the electrode 42 without any electric charge injection and welding.When in undeflected position, mirror 48 is separated with optical transmission medium 20, when being 2.8 microns as separation distance, motion banking pin 49 can stretch out from the hinge axis of hinge 50 (as, about 3.3 microns).
Whole electromechanical characteristic of modulator is further described in Fig. 4 and Fig. 5.In Fig. 4, the angle of deflection of the mirror 48 that drawn is to the curve of bias voltage and can be observed hysteresis phenomenon.When a bias voltage is applied between mirror 48 and the electrode 42 (Fig. 3 A and 3B), mirror 48 deflections (seeing the line 401 of Fig. 4) are when mirror 48 deflects past the voltage V that fractures Snap(as, about 6.8 volts) time, thereby the storage mechanical force of hinge 50 no longer can rupture (seeing 402 lines of Fig. 4) up to motion banking pin 49 contact optical transmission mediums 20 to the direction of the electrode 42 of circuit medium 34 by balance electrostatic force mirror 48.In order to make mirror 48 get back to its undeflected position (404 lines of Fig. 4), voltage must be reduced under the voltage that fractures (403 lines of Fig. 4), reaches V Release(as, about 5.6 volts).Therefore, mirror 48 is at voltage V ReleaseWith V AnapBetween will be an electromechanical bistable device.In other words, to fixing on V ReleaseWith V SnapBetween a specific voltage, according to the historical mirror 48 of mirror 48 deflections two kinds of possible angle of deflection are arranged.Therefore, mirror 48 deflections are just as a door bolt.Because the required mechanical force of deflection roughly is linear about angle of deflection, and the distance between anti-electrostatic force and mirror 48 and the electrode 42 is inversely proportional to, so these characteristics of bistability and door bolt exist.
This door bolt behavior allows driving circuit to be placed in outside the sheet or only at periphery, the behavior uses passive addressing rather than has a memory cell driving each electrode.As, each electrode 42 at each given row when each mirror 48 at each given row is electrically connected is electrically connected.In address period, because each pixel and the pixel that is addressed be not at same row and column, so the voltage that is applied is at V ReleaseWith V SnapBetween medium voltage (as 6.2 volts).Therefore, online 403 for these pixels if mirror 48 is deflected, so the deflection of mirror 48 represent a binary states (as a, binary one), online 401 if mirror 48 is deflected, so the deflection of mirror 48 represent another binary states (as a, binary zero).Talk about with another sentence, this medium voltage does not determine the state of mirror 48 deflections uniquely.
If a "on" position (or off-position) can be programmed at the pixel that is addressed, electrode 42 voltages that the pixel that is addressed so is capable are changed to increase the bias voltage that (or reducing to close) applied.Mirror 48 voltages of the pixel row that are addressed also are changed to increase the bias voltage that (or reducing to close) applied.For by chance with the pixel that is addressed at the pixel that is not addressed with delegation or same row, the bias voltage that is applied increases (or reducing to close), but still at V ReleaseWith V SnapBetween.Therefore, binary states is not because the pixel that is not addressed is changing with delegation or same row with the pixel that is addressed by chance.Yet for the pixel that is addressed, the voltage of electrode 42 and mirror 48 is changed to increase the bias voltage that (or reducing to close) applied always.V is compared in this increase Snap(or V is compared in this minimizing greatly RelenseLittle of to close the pixel that is addressed), thus the state that the pixel that is addressed is in out (or being in closing state).For addressing and programming, each row and column is only needed a driving circuit.Therefore, driving circuit can be placed along the periphery of device or be placed outside the sheet.
Even the whole active addressing of a driving circuit (as a transistor in the DRAM configuration) being arranged for each electrode 42 wherein, connection mirror in groups can increase addressing efficient.This can by or realize in connection with the lens array periphery, perhaps by the sedimentary column that mirror is connected to this circuit medium being realized at location of pixels.Because electrostatic force only depends on the reflection horizon 32 of conduction and the whole voltage between the bottom electrode 42, thus one be applied to a mirror group (by reflection horizon 32) thus the negative pressure operating voltage that reduced respective electrode reduced the voltage request of SLM10.This is desirable, as, for keep operating voltage under 5V because the 5V switching capability is a standard for semi-conductor industry.In addition, depart from the required amount of charge of each electrode of the pixel that is addressed and be placed in the little of a embodiment on the substrate than all mirrors.Therefore it is fast relatively giving the pixel required time of programming that is addressed.
In Fig. 5, thereby we have drawn and have worked as the bias voltage that is applied when being increased mirror 48 and tilting, mechanical and electric torque and the relation curve between the angle of deflection.As shown in Figure 5, the machinery by hinge 50 stores the caused machine torque τ of power MechnicalWith respect to angle of deflection roughly is linear.On the other hand, each electric torque (τ that causes by the electrostatic force between mirror 48 and the electrode 42 Electrical) curve defer to the inverse ratio square law and along with the increase of angle of deflection sharply increase (when mirror 48-when the electric capacity of electrode 42 structures is increased).At low bias voltage place, as by bottom curve (V=V a) illustrated, an equilibrium point α is arranged EIf mirror 48 is tilted than equilibrium point α EMany a little (or few) some, the mechanical force in the sensing (or pointing to electrostatic force down) thus play a major role mirror 48 upwards (or downward) deflection return equilibrium point α EBy changing the "on" position bias voltage between mirror 48 and the electrode 42, can control the inclination of mirror 48.
If the bias voltage between mirror 48 and the electrode 42 surpass a key value (as shown in the intermediate curve, V=V here b), equilibrium point α ENo longer exist, mirror 48 is to circuit medium 34 fracture (seeing 402 lines among Fig. 4).If mechanical force moment and angle are linear, when mirror 48 about deflections to the circuit medium midway the time, generation fractures.If there is not brake in position, the behavior of fractureing will continue to contact with electrode 42 until mirror 48 so.Because bonding may since welding take place, so for fear of the pattern of this operation, this is desirable.When these surfaces that come in contact are in different electromotive forces at first or when large tracts of land surface of contact and extensible material such as metal were had an effect, welding was possible especially.
Motion banking pin 49 recited above is made by hard material such as silicon nitride.These hard materials have the quite long life-span than metal construction.Motion banking pin 49 also has a limited contact region with optical transmission medium 20, and therefore reduces cohesive force.By keeping motion banking pin 49 the same gesture to be arranged, cause that the electric potential difference of welding also may be avoided with the reflection horizon 32 that they are contacted.Can be thereby the motion banking pin 49 that fractures contacts with physics between the optical transmission medium 20 by keeping V<V bAvoided fully.
If SLM10 is operated at the voltage that surpasses snap point, it can with or active addressing (as, transistor driving electrode 42 in a separation of each pixel position), perhaps use passive addressing (as, to each row or column driving circuit only) with, by surveying the electromechanical bistability of mentioning for a long time, be operated with digital mode.If SLM10 is than V SnapBig is voltage-operated, and 403 deflections along the line can be represented a binary states and another binary states is represented in all other deflections.
If the voltage of SLM10 under snap point is operated, it can be operated with simulated mode with active addressing.As, for different angle of deflection, if power supply 64 from many positions divergent-ray, the varying strength of light can be reflected to imaging optical device 66.The use of high-quality mechanical material recited above can produce blunt good consistance on the pixel array, and makes the simulated operation practicality.Afterwards, mirror 48 deflections will be directly proportional with the electric charge in each corresponding electrode place storage.Operation helps preventing Mechanical Contact during operation under snap point, eliminates possible adhesion problem.
Operation surpasses the voltage condition that fractures for mirror, along with, the voltage that changes as the function of time is possible.In active address phase, addressing is placed in, and for those electrodes, based on the required level of the mirror deflection of electrostatic force, at those electrode places, mirror deflection is required.After mirror deflection in question, remain on that to be deflected the required voltage of the real deflection of the required voltage ratio in position little.This is because little in being deflected process of the mirror of deflection and the gap ratio mirror between the addressing electrode.Therefore, this stage after active address phase, (as, said " maintenance stage ") the addressing voltage position may be reduced from initial position and do not influenced the state of mirror basically.The benefit that a maintenance stage is arranged be undeflected mirror now also than being subject to less electrostatic attraction gravitational attraction in the past, so they reach and zero-nearer position of inflection point.This has improved the mirror of deflection and the optical contrast rate between the undeflected mirror.
The electronics of a storage array portion of addressing circuit 36 is patterned among Fig. 6 A and Fig. 6 B and shows.If active addressing is used, be embodied in the position that addressing scheme in the circuit of Fig. 6 A can be used to individually determine each pixel of SLM10 so.Medium 20 and 34 does not show in Fig. 6 A that mirror 48 and bottom electrode 42 are symbolically drawn.This scheme is the same with the scheme that is used as DRAM (dynamic random receives storage).Each pixel 12,12a, 12b and 12c be respectively by nmos pass transistor 68,68a, and 68b and 68c drive.As, if pixel 12 is addressed, electrode 42 is recharged with that.The state of the respective column of pixel (comprising pixel 12 and 12c) is determined by the mirror deflection wanted is controlled corresponding bit line 62 when the suitable bias voltage.Depart from relevantly with mirror 48, this departs from and is connected to a general voltage, as base stage.Corresponding then word line 60 by pulse height-low-Gao (as, nmos pass transistor 68 is opened temporarily) and magnitude of voltage stored and be the electric charge between hearth electrode 42 and the mirror 48.An additional capacitors can be stored to overcome leakage to guarantee enough electric charges with mirror-parallel placement of electrode combination.
Another embodiment uses a SRAM (take a stand and receive memory at random) type unit to drive exciting electrode (Fig. 6 B).As, on behalf of the voltage of a binary states one, pixel 12 be addressed by apply one on corresponding bit line 62.Voltage is enough to electrode 42 charging and deflecting mirrors 48.Represent the voltage of a binary states zero to be displayed on another corresponding bit line 62 (bar).Corresponding word line 60 is selected by applying a voltage that is enough to open transistor 69a and 69b.The input of inverter 69C with represent a binary states zero from the output of inverter 68D.Represent a binary states one from the output of inverter 69C and the input of inverter 68D.When transistor 69A opened, electrode 42 was recharged by bit line 62.
Because mirror 48 zones can be quite big (12 * 12 microns=144 square microns) according to semi-conductive ratio, thus more complicated circuit can be fabricated on each exciting electrode below.Possible circuit includes, but are not limited to, and the storage impact damper is with in each pixel waiting time sequence Pixel Information; Electronic circuit is to compensate the inconsistent of possible mirror/electrode separation by the voltage levvl drive electrode in variation.
Suitably select size ( medium 20 and 34 spacing 1 to 5 μ m, hinge thickness is 0.03 to 0.3 μ m) and material (silicon nitride), a SLM10 can be manufactured with an only operating voltage of several volts.The angle rotation coefficient of hinge 50 can be, as, about 3.3 * 10 -14The every degrees of rotation of Newton meter.As discussed above, the voltage in the position that addressing circuit must move can be made for negative (or just) by the gesture that keeps mirror 48 even is lower, with reference to circuit base stage (bias voltage).As, at the negative bias state, this can produce the effect that the hysteresis phenomenon curve is moved to the left, so that the exciting electrode array can be moved and cause mirror deflection in as the low voltage range of 0-5V.For a given voltage, this causes having a bigger difference on deflection angle.Maximum negative bias is-V ReleaseNegative pressure can be applied on the mirror 48 to be passed through, and as, the switch 76 that closes on mirror 48 and the power supply 74 that is designed to apply a negative pressure is complementary.(seeing the pixel 12 of Fig. 6 A).
According to the planarity and the bending resistance of medium 20 and 34, getting escapement 44 self may need to be embedded in the lens array.Fig. 7 has shown that has a rational adjacent lens array of getting escapement in the centre.Lens array comprises 56 mirrors 48,48 aTo 48 z, 48 AaTo 48 Az, 48 Ba, 48 BbWith 48 BcFor clarity, optical transmission medium 20 and circuit medium 34 be not illustrated and each mirror 48 by a square representative.Get escapement 44 and be positioned at mirror 48aa, 48ab, among 48ai and the 48aj, each mirror has with the corresponding limit of getting escapement shown in Fig. 7 a total limit is arranged.
Fig. 8 A has shown the pixel 12 of a SLM10 who passes through to form with reference to the described process of Fig. 2 A-2D and the top view of 12a.Mirror 48 and 48a wind the axle rotation that is limited by thin hinge 50 and 50a.The motion of mirror 48 and 48a is limited by motion banking pin 49 and 49a, and it moves forward runs into fixed mirror 48 and 48a optical transmission medium 20 (seeing Fig. 3 B) thereon at last.In one embodiment, the diagonal line representative comprises a quite thick silicon nitride layer of comparing with thin hinge.The dirigibility while in remaining on hinge 50 and 50a, this reinforcing mechanically makes mirror 48 and 48a hardening.Similarly reinforce and see Fig. 8 B-8E.
In the design of the mirror 48 of the optical active element that forms SLM10, also exist many possible variations.Fig. 8 A-8D shows some variations, in these change, and motion banking pin 49 and mirror 48 basic coplanes.Shown that at Fig. 8 B two motion banking pins 49 are arranged 8BAn embodiment.In Fig. 8 C, hinge 50 8CDirectly linked motion banking pin 49 8COn.Fig. 8 C and 8D are similarly, except Fig. 8 D only shows a motion banking pin 49 8DFig. 8 E shows adjacent support 51 8EThe pixel 12 of Fig. 8 E 8EIf basic just not motion banking pin and SLM10 only at V SnapUnder operate then pixel 12 8EBe the most useful.
In the embodiment shown in Fig. 8 F and the 8G, hinge 50 8FWith 50 8GBy flexing rather than by rotating operation." Flexure " meaning is meant hinge 50 8FWith 50 8GEnd be fixed and mirror 48 8FWith 48 8GAngular deflection make hinge 50 8FWith 50 8GAt hinge 50 8FWith 50 8GThe middle part angular deflection, thereby make hinge 50 8FWith 50 8GAlong hinge 50 8FWith 50 8GExtending longitudinally.The hinge 50 of Fig. 8 F and Fig. 8 G 8FWith 50 8G Hinge support 51 is arranged 8FWith 51 8G, hinge support 51 8FWith 51 8GConnect hinge 50 8FWith 50 8GDown to optical transmission medium 20 (Fig. 1,2A, 2B, 2C, 2D, 2E, 2F, 3A, 3B, 9A, 9B, 9C, 9D, 10A, 10B, 10C, 11A, 11B, 11C, 12 and 13).So hinge 50 8FWith 50 8GLongitudinally crooked rather than to reverse ground crooked.At hinge 50 8FWith 50 8GThis embodiment in, mechanical recovery force will be according to faster the increasing of ratio linearity of deflection, as the strain in the initial pulling force.The hinge 50 that has this specific character 8FWith 50 8GWhen mirror 48 is operated with analog form may be useful, because the angle that fractures (thereby V Snap) will be increased.In Fig. 8 H, hinge 50 8HBe a cantilever design, and pass through flexing and non-twist operation.
Second manufacturing process of producing micromachine SLM10 of the present invention is illustrated explanation in Fig. 9 A-9D and Figure 10 A.This processing uses many silicon nitride layers to reach one than having a mirror type structure of higher aperture ratio with the processing that is outline among Fig. 2 A-2F.This part ground is because mirror light hurdle 49 10A(Figure 10 A) and mirror 48 10A(Figure 10 A) is positioned at different planes.Optical transmission medium 20 is by making as the quartzy this material that can stand continuous treatment temperature.In this process, intercept the aperture layer 22 of light and the deposition of protective seam 24, as Fig. 1, shown in 2A and the 2C, skipped always but may be increased as the first step of handling.
Sacrifice layer 26 10A(as, about 0.5 micron thickness, the unsetting silicon layer that LPCVD grows up) be deposited.In the hole 25 10APassed after the optical transmission dielectric layer 20 that arrives as shown in Fig. 9 A by medelling, motion braking layer (as, the low stress nitride silicon layer that the LPCVD of a thick 150nm grows up) is deposited and is had with formation by medelling the motion banking pin 49 of a sharp-pointed contact point 90 10A
Next step, hinge layer (as, the low stress nitride silicon layer of a thick 40nm) is grown to be limited the torsion hinge 50 shown in Fig. 9 B by moulding then 10A Second sacrifice layer 27 be deposited (as, about 0.5 micron thickness, the unsetting silicon layer that LPCVD grows up), and by moulding so that hole 25c arrives hinge 50 downwards 10A(Fig. 9 C).This second sacrifice layer 27 10ACan think the film deposition of back and obtain a plane with chemically mechanical polishing (CMP) the technology polishing usually by quilt.Because continuous sedimentary deposit comprises mirror structural support layers 28 10ASo, mirror structural support layers 28 10AThereby the characteristic that improves the plane had the reflection homogeneity of improvement and the system contrast and the brightness of improvement.At last, silicon nitride mirror structural support layers 28 that about 138nm is thick 10ABe deposited and by moulding to form the mirror thin slice of substantially rigid.
Next step, sacrifice layer 26 10AWith 27 by with one isotropic (as, dichloride xenon-133 gas etching; 100%SF with reference to the front 6Cement Composite Treated by Plasma also can be used) etch processes partly removes, and total is coated with as, an extremely thin aluminium lamination (the 30nm) (reflection horizon 32 of Figure 10 A 10A), this layer not only had high reflectivity and but also helped recited above those mirrors to be electrically connected.
At last, those mirrors all discharge with second isotropic etch processes (as, chlorination xenon-133 gas etching), remove sacrifice layer 26 fully 10AThose mirrors easily combine with the circuit medium 34 that comprises addressing circuit now, use as, same Technical Reference Fig. 2 and Fig. 3 described above.Therefore, a sub-hinge arrangement is made, and one may be transparent hinge 50 in this sub-hinge 10ABe deposited between optical transmission medium 20 and the mirror 48.
The synoptic diagram of the sub-hinge arrangement that Figure 10 A-10C makes of above-mentioned processing.For the sake of clarity, 10 of SLM 10A-10DBe rotated 90 ° so that hinge 50 10A-10DCan be seen.Figure 10 A shows one and has a torsion hinge 50 10AReach a motion banking pin 49 placed in the middle 10AUnit 12 10A, this device is shown to conform with the ratio of the similar structures cellular array among Figure 14.Figure 10 B has shown to have two light hurdles 49 10BSynoptic diagram.Figure 10 C has shown two banding pattern hinges 49 of use 10CA device, this device also provides the function of " motion banking pin " in two ways inherently.When mirror 48 10CDuring deflection, can be the hinge 50 of straight line in undeflected position 10CBecause by mirror 48 10CThe torque that applies and present a S shape.When mirror 48 10CAngular deflection when increasing, hinge 50 10CExtend and bending.Therefore, mirror 48 10CMechanical recovery force with than increasing with the linear bigger speed of angular deflection.This nonlinear amount is a kind of mode, and hinge 50 in this way 10CFunction provide the functional of " motion banking pin " even when not having contact optical transmission medium 20.Functional second mode that obtains " motion banking pin " with this structure is by at mirror 48 10CWith hinge 50 10CBetween the contact.
Figure 10 D has also shown another synoptic diagram of a torsion hinge device, and for this device, the step of sedimentary movement braking layer is removed, because it does not utilize the motion banking pin of being made respectively.In the synoptic diagram of Figure 10 D, contact 51 10DPass the hole in first sacrifice layer and form.Door assembly with hinge and glass in right hand and left 50 10DOn first sacrifice layer, be formed.Second sacrifice layer is formed on hinge 50 10DReach on first sacrifice layer and also have one and appear hinge 50 10DA hole of core.Contact 51 αPass this hole and mirror 48 10DAn individual layer and form and motion banking pin 49 10DBe deposited over the top of second sacrifice layer.Latter two sacrifice layer be removed so that mirror 48 10DAnd motion banking pin 49 10DFree.
The 3rd manufacturing process of making micromachine spatial light modulator of the present invention (SLM) shows with sectional view in Figure 11 A-11C and Figure 12.This process has also used multilayer silicon nitride to obtain may have the mirror type structure of higher aperture than (mark in optical activity district) than the process that Fig. 2 was outline.Optical transmission medium 20 is by making as the quartzy this material that can stand continuous treatment temperature.In this process, the deposition of resistance light aperture layer 22 and protective seam 24 is ignored from this process, but can be increased the first step as this process.
At first, shown in Figure 11 A, optical transmission medium 20 by medelling and etching so that small lugs 111 is formed contact point.The unsetting sacrificial silicon layer 26 of the LPCVD growth that next, one 0.5 μ m is thick 12Be deposited, this layer is removed at last.Follow the silicon nitride mirror structural support layers 28 of a thick 138nm 12Be deposited, this layer is by the mirror thin slice 28 of medelling with the formation substantially rigid 12(Figure 11 B).Afterwards, second sacrifice layer 27 12Be deposited, and by medelling so that hole 29 βArrive mirror thin slice 28, hole 29 downwards 12Arrive projection 111 downwards.Low stress nitride silicon hinge layer 29 that about 40nm is thick then 12Grown and by medelling to limit the torsion hinge shown in Figure 11 C.
Secondly, sacrifice layer 26 12And 27 12(also can use 100%SF with having 100: 1 6Cement Composite Treated by Plasma) above etching selectivity the isotropic etch processes of dichloride xenon and partly removed, and total is coated with an extremely thin aluminium lamination (30nm), and this aluminium lamination not only has high reflectivity but also helps mirror to be electrically connected.Last mirror is discharged fully with the second chlorination xenon etch processes, removes sacrifice layer 26 fully 12Now mirror is easy to combine with a semiconductor medium that comprises addressing circuit, uses the identical medium combination technology described in Fig. 2 and Fig. 3 in front.
Figure 12 has shown a synoptic diagram of the structure of using the said process making.Support 51 12By passing hole 29 12Silicon nitride hinge layer deposition and form.Hinge 50 12Form hinge layer 29 12 Mirror 48 12It is the mirror thin slice 28 shown in Figure 11 B 12This mirror is by supporting 51 βBe fixed to hinge 50 12On.Owing to support 51 12, mirror 48 12When inflection point not, separate with optical transmission medium 20.
But a single Fang Jing is not only possible reflection deflecting element 48; Other design, as four-leaf clover shape or be possible like the design of grating type.As, the membranaceous mirror that delegation unifies deflection can form disposable diffraction grating.The deflectable element of reflectivity is that a film that scribbles metal also is feasible.The part of element is from removing than low medium rather than shifting to it but the design of deflecting element also can be made.Mirror element also can be designed court more than a direction deflection, as, have more than a controllable degree of freedom.
If modulator is operated to the deflectable element of reflectivity contact circuit medium when being excited, the device embodiment as shown in Fig. 8 E will take place, and another structure can be added to the circuit medium.As, in a lens device, outstanding projection can be made to reduce the whole surface of real contact.The mirror that projection preferably welds when avoiding contacting is in same electromotive force.In addition, the hyaline layer of a conduction as indium oxide antimony, can be deposited over before the protective seam 24.The bias voltage that is applied between conduction hyaline layer and the mirror can be moved mirror the top of medium 20 on one's own initiative and make them return to closed condition.
There are many diverse ways to make the circuit of addressing function.DRAM recited above, SRAM and passive addressing scheme, and well-known door bolt device can have addressing function in the prior art.The circuit medium can be transparent, as quartz.In this case, transistor can be by making with many silicon that quartzy silicon can be compared.
In one embodiment, aperture layer 22 can also be modified to comprise the optical mode of arbitrary binary.In addition, the end face 16 of optical transmission medium 20 or in the bottom surface 14 places, the optics on other plane can be combined into one with optical transmission medium 20.Some structures in many possible structures comprise the chromatic filter of being made up of an one deck or a lamination, micro lens and have the characteristic of color diffusion or diffraction.As " the plane combination of the optics of free space " at Jahns and Huang, " applied optics ", 28 volumes, the 9th phase, on May 1st, 1989 (PlanarIntegration of Free-Space Optical Components " Applied Optics; vol.28, No.9,1May 1989.).The cost that this optical function is attached to ability on the optical transmission medium and can increases practical contrast ratio and the Free Space Optics device by reducing the native system level reduces cost.In some embodiments of the invention, mirror thin slice itself can be in conjunction with the optical function except that simple reflectivity.As, mirror can be made up of to increase the reflectivity of filtration capacity or raising and comparable some wavelength of other parts a plurality of quite transparent layers.This is useful, as, as the colour deficient of balance optical system, as the spectrum of illuminating lamp, a kind of method.
There are many manufacturing process to be modified.Replace to use an epoxy that two media are combined, other material can be used as molten metal when the accessible treatment temperature or thermoplast.In arbitrary scheme, that keeps that dielectric layer is separated from each other gets escapement and can be established at each layer.It is static that the very important method that is pointed out that deflection also not necessarily is limited: wherein can the selecting with exciting also of piezoelectricity of heat.At each pixel, also have of the electrical connection of a top to the medium of bottom, at this each pixel place, the element of forming each pixel can maintain their electromotive force place.In manufacturing process, for the optical activity district that makes mirror Horizon as far as possible, chemically mechanical polishing (CMP) can be added at several stages, after on the top of the aperture layer that is deposited over medelling at protective seam, after the mirror layer is deposited.
For micro-mechanical component, many materials can be used as alternative: a kind of ceramic making mirror that may be to use another kind of model, and perhaps even fully use a kind of metal (as an aluminium alloy) to make mirror.Material for sacrifice layer also has many possibilities, as, silicon dioxide.Silicon can also be used as grid material and make grid material without tungsten.This will make this process and the silicon nitride depositing device that is used for making the CMOS chip product more mate.Grid and relevant protective seam can also be removed fully.Yet for deflectable element (as mirror), another combination of material will be silicon (as, the polysilicon of LPCVD), be silicon dioxide (as, LPCVD growth) for sacrifice layer.Silicon dioxide can fall with containing hydrofluoric acid etching, and can finish dried to impel NAG mirror release with well-known key point drying (critical-point-drying) technology.Get escapement and also can make, comprise various organism, oxide or metal by wide variety of materials.
In a word, SLM10 of the present invention is a device that can represent many desirable properties, comprises high-resolution, high optical efficiency, high contrast ratio or depth of modulation, and high mechanical reliability.SLM10 can use in a lot of fields, comprises projection display system.The design of the novelty of the low switch voltage of SLM10 makes the cmos circuit of standard be used as the addressing parts.Available standard procedure is fabricated on the medium of a separation in silicon CMOS making apparatus but deflecting element itself also can use.Two media can or not be that very accurate equipment is made with coarse relatively device.SLM10 is made these factors easily and the charge is small.
Though above the present invention describes with certain embodiments always,, can expect in advance that modification of carrying out and change will belong to technical field of the present invention undoubtedly significantly therefrom.Therefore, want to be pointed out that following claim will be comprised all such modifications and change by explanation, these all modifications and change all drop on connotation of the present invention with within the scope.

Claims (161)

1. spatial light modulator, its section comprises from top to bottom:
The optical transmission medium;
First gap under the described optical transmission medium;
But the deflecting element under described first gap;
But second gap under the described deflecting element; And
Hinge under described second gap.
2. spatial light modulator as claimed in claim 1, wherein said hinge comprises flexible part, but described flexible part is blocked by described deflecting element when looking via described optical transmission medium.
3. spatial light modulator as claimed in claim 1, but wherein said optical transmission medium and described deflecting element all have end face and bottom surface, but and wherein said hinge be connected to the bottom surface of described optical transmission medium and described deflecting element.
4. spatial light modulator as claimed in claim 1, further comprise the circuit medium, described circuit medium is positioned under the described optical transmission medium and with interval separating, and wherein said circuit medium comprises electrode, attracts but be used for forming between described deflecting element and described circuit medium.
5. spatial light modulator as claimed in claim 4, but but wherein said hinge extends through described deflecting element between described electrode and described deflecting element, but but and be connected core with described deflecting element towards described deflecting element.
6. spatial light modulator as claimed in claim 1, but wherein said deflecting element comprises conducting stratum.
7. spatial light modulator as claimed in claim 1, wherein said hinge is a torsion hinge.
8. spatial light modulator comprises:
The optical transmission medium, but it has position deflecting element thereon, but described deflecting element comprises hinge, but described hinge is positioned at a side of described deflecting element, and this side is relative with a side of described optical transmission medium.
9. spatial light modulator as claimed in claim 8, wherein said hinge comprises flexible part, when looking via described optical transmission medium, but described flexible part is blocked by described deflecting element.
10. spatial light modulator as claimed in claim 8, wherein said hinge is connected with described optical transmission medium via the binding post of extension from the bottom surface of described optical transmission medium.
11. spatial light modulator as claimed in claim 8, but be provided with the gap between wherein said hinge and the described deflecting element.
12. spatial light modulator as claimed in claim 11, further comprise, the circuit medium, described circuit medium is positioned under the described optical transmission medium and with interval separating, wherein said circuit medium comprises electrode, but described electrode is used for forming attraction between described deflecting element and described circuit medium.
13. spatial light modulator as claimed in claim 8, but wherein said deflecting element comprises reflection horizon and conductive electrode layer, and described electrode layer separates at interval with described reflection horizon.
14. spatial light modulator as claimed in claim 13, but wherein said deflecting element is substantially rectangle or square, but and wherein said hinge along the described deflecting element of diagonal line extend through.
15. spatial light modulator as claimed in claim 14, but wherein said deflecting element comprises aluminium.
16. a spatial light modulator, it comprises:
The optical transmission medium, but it has position deflecting element thereon, but described deflecting element comprises first and second portion, but so that in the reflection process of described deflecting element, described second portion is shifted to described optical transmission medium, and described first moves apart described optical transmission medium.
17. spatial light modulator as claimed in claim 16, wherein hinge comprises flexible part, but described flexible part is blocked by described deflecting element when looking via described optical transmission medium.
18. spatial light modulator as claimed in claim 16, wherein hinge is connected with described optical transmission medium via the binding post of extension from the bottom surface of described optical transmission medium.
19. spatial light modulator as claimed in claim 16, but wherein between hinge and described deflecting element, be provided with the gap.
20. spatial light modulator as claimed in claim 16, further comprise, the circuit medium, described circuit medium is positioned under the described optical transmission medium and with interval separating, wherein said circuit medium comprises electrode, but described be used between described deflecting element and described circuit medium forming attract.
21. spatial light modulator as claimed in claim 20, but wherein said deflecting element comprises reflection horizon and conductive electrode layer, and described electrode layer separates at interval with described reflection horizon.
22. spatial light modulator as claimed in claim 21, but wherein said deflecting element is substantially rectangle or square, but and wherein hinge along the described deflecting element of diagonal line extend through.
23. spatial light modulator as claimed in claim 22, but wherein said deflecting element comprises aluminium.
24. a spatial light modulator, it comprises:
The optical transmission medium, but it is fixed at least one deflecting element on its bottom surface by corresponding at least one torsion hinge, but described deflecting element has smooth end face and bottom surface and one or more edges therebetween, but but is connected to the core of described at least one torsion hinge of described deflecting element towards the described bottom surface of described deflecting element.
25. spatial light modulator as claimed in claim 24, wherein said hinge comprises flexible part, but described flexible part is blocked by described deflecting element when looking via described optical transmission medium.
26. spatial light modulator as claimed in claim 24, but wherein said optical transmission medium and described deflecting element all have end face and bottom surface, but and wherein said hinge be connected to the bottom surface of described optical transmission medium and described deflecting element.
27. spatial light modulator as claimed in claim 24, comprise that further circuit medium, described circuit medium are positioned under the described optical transmission medium and with interval separating, wherein said circuit medium comprises electrode, attracts but be used for forming between described deflecting element and described circuit medium.
28. spatial light modulator as claimed in claim 27, but but wherein said hinge extends through described deflecting element between described electrode and described deflecting element, but but and be connected core with described deflecting element towards described deflecting element.
29. spatial light modulator as claimed in claim 26, but wherein said deflecting element comprises conducting stratum.
30. spatial light modulator as claimed in claim 29, wherein said hinge is a torsion hinge.
31. a spatial light modulator, it comprises:
First medium is connected to second medium and has the gap between the two;
But described first medium is the optical transmission medium that has a plurality of deflecting elements on it;
Described second medium has cmos circuit and electrode on it, but is used to make the described deflecting element on described first medium to deflect.
32. spatial light modulator as claimed in claim 31, wherein said medium comprises the electrode that approaches corresponding polarizer most and be provided with, but it is used for the described deflecting element of deflection.
33. as spatial light modulator as described in the claim 32, wherein said medium is the silicon medium.
34. spatial light modulator as claimed in claim 31, but wherein said deflecting element is the micromirror that comprises reflection layer.
35. spatial light modulator as claimed in claim 31, wherein hinge is a torsion hinge.
36. spatial light modulator as claimed in claim 32, but wherein the deflection thin slice comprises silicon nitride.
37. spatial light modulator as claimed in claim 31, wherein the distance between the neighbouring element is smaller or equal to 0.5 micron.
38. spatial light modulator as claimed in claim 31, the distance between wherein said first and second media are 1 to 5 micron.
39. spatial light modulator as claimed in claim 31, wherein said medium use the bonding agent that comprises stupalith to connect together and have the escapement of getting between the two, wherein said stupalith is silicon dioxide or nitrogen oxide.
40. spatial light modulator as claimed in claim 31, but wherein get the outside that escapement is positioned at described a plurality of deflecting elements.
41. a spatial light modulator, it comprises:
First medium and second medium, described first medium are connected with described second medium and have the gap between the two;
But described first medium is the optical transmission medium that has a plurality of deflecting elements on it;
Described second medium has circuit and aluminium electrode on it, but is used to make the described deflecting element on described first medium to deflect.
42. spatial light modulator as claimed in claim 41, but wherein said medium comprises the electrode that approaches corresponding deflecting element placement most, but be used for the described deflecting element of deflection.
43. spatial light modulator as claimed in claim 41, but wherein said deflecting element is the micromirror that comprises reflection layer.
44. spatial light modulator as claimed in claim 41, wherein hinge is a torsion hinge.
45. spatial light modulator as claimed in claim 41, but wherein the deflection thin slice comprises silicon nitride.
46. spatial light modulator as claimed in claim 41, wherein the distance between the neighbouring element is smaller or equal to 0.5 micron.
47. spatial light modulator as claimed in claim 41, the distance between wherein said first and second media are 1 to 5 micron.
48. spatial light modulator as claimed in claim 41, wherein said medium use the bonding agent that comprises stupalith to connect together and have the escapement of getting between the two, wherein said stupalith is silicon dioxide or nitrogen oxide.
49. spatial light modulator as claimed in claim 41, but wherein get the outside that escapement is positioned at described a plurality of deflecting elements.
50. a spatial light modulator, it comprises:
First medium and second medium, described first medium are connected with described second medium and have the gap between the two;
But described first medium is the optical transmission medium that has a plurality of deflecting elements on it;
Described second medium is the silicon medium with electrode, but is used to make the described deflecting element on described first medium to deflect.
51. spatial light modulator as claimed in claim 50, but wherein said silicon medium comprises the electrode that approaches corresponding deflecting element placement most, but be used for the described deflecting element of deflection.
52. spatial light modulator as claimed in claim 51, but wherein said deflecting element is the micromirror that comprises reflection layer.
53. spatial light modulator as claimed in claim 52, wherein hinge is a torsion hinge.
54. spatial light modulator as claimed in claim 53, but wherein the deflection thin slice comprises silicon nitride.
55. spatial light modulator as claimed in claim 52, wherein the distance between the neighbouring element is smaller or equal to 0.5 micron.
56. spatial light modulator as claimed in claim 52, the distance between wherein said first and second media are 1 to 5 micron.
57. spatial light modulator as claimed in claim 53, wherein said medium use the bonding agent that comprises stupalith to connect together and have the escapement of getting between the two, wherein said stupalith is silicon dioxide or nitrogen oxide.
58. spatial light modulator as claimed in claim 53, but wherein get the outside that escapement is positioned at described a plurality of deflecting elements.
59. spatial light modulator as claimed in claim 50 has circuit on wherein said second medium, the distance of described first medium of described spread of electrodes is nearer apart from the distance of described first medium than described circuit.
60. spatial light modulator as claimed in claim 59, but wherein said silicon medium comprises the electrode that approaches corresponding deflecting element placement most, but be used for the described deflecting element of deflection.
61. spatial light modulator as claimed in claim 59, but wherein said deflecting element is the micromirror that comprises reflection layer.
62. spatial light modulator as claimed in claim 59, wherein hinge is a torsion hinge.
63. spatial light modulator as claimed in claim 59, but wherein deflection film comprises silicon nitride.
64. spatial light modulator as claimed in claim 59, wherein the distance between the neighbouring element is smaller or equal to 0.5 micron.
65. spatial light modulator as claimed in claim 59, the distance between wherein said first and second media are 1 to 5 micron.
66. spatial light modulator as claimed in claim 59, wherein said medium use the bonding agent that comprises stupalith to connect together and have the escapement of getting between the two, wherein said stupalith is silicon dioxide or nitrogen oxide.
67. spatial light modulator as claimed in claim 59, but wherein get the outside that escapement is positioned at described a plurality of deflecting elements.
68. a spatial light modulator, it comprises:
Medium, its transmissive visible light;
The silicon medium;
The described medium of wherein said silicon medium and transmissive visible light connects together and gets escapement between the two to form the gap between these media; And
But a plurality of deflecting elements that are sealed in the described gap, but and the wherein said escapement of getting be positioned at within the occupied zone of described a plurality of deflecting elements.
69. as the described spatial light modulator of claim 68, but wherein said silicon medium comprises the electrode that approaches corresponding deflecting element placement most, but is used for the described deflecting element of deflection.
70. as the described spatial light modulator of claim 69, but wherein said deflecting element is the micromirror that comprises reflection layer.
71. as the described spatial light modulator of claim 68, wherein hinge is a torsion hinge.
72. as the described spatial light modulator of claim 71, but wherein the deflection thin slice comprises silicon nitride.
73. as the described spatial light modulator of claim 71, wherein the distance between the neighbouring element is smaller or equal to 0.5 micron.
74. as the described spatial light modulator of claim 71, the distance between wherein said first and second media is 1 to 5 micron.
75. as the described spatial light modulator of claim 71, wherein said medium uses the bonding agent that comprises stupalith to connect together and has the escapement of getting between the two, wherein said stupalith is silicon dioxide or nitrogen oxide.
76., but wherein saidly get the outside that escapement is positioned at described a plurality of deflecting elements as the described spatial light modulator of claim 75.
77. a spatial light modulator, it comprises:
First medium, the escapement of getting that it has a plurality of micromirror and is positioned at described a plurality of micromirror; And
Second medium, it has the array of electrode and circuit, wherein said first and second media connect together and described first and second media between get escapement.
78. as the described spatial light modulator of claim 77, but wherein said medium comprises the electrode that approaches corresponding deflecting element placement most, but is used for the described deflecting element of deflection.
79. as the described spatial light modulator of claim 78, wherein said medium is the silicon medium.
80. as the described spatial light modulator of claim 77, but wherein said deflecting element is the micromirror that comprises reflection layer.
81. as the described spatial light modulator of claim 80, wherein hinge is a torsion hinge.
82. as the described spatial light modulator of claim 81, but wherein the deflection thin slice comprises silicon nitride.
83. as the described spatial light modulator of claim 81, wherein the distance between the neighbouring element is smaller or equal to 0.5 micron.
84. as the described spatial light modulator of claim 82, the distance between wherein said first and second media is 1 to 5 micron.
85. as the described spatial light modulator of claim 82, wherein said medium uses the bonding agent that comprises stupalith to connect together and has the escapement of getting between the two, wherein said stupalith is silicon dioxide or nitrogen oxide.
86., but wherein saidly get the outside that escapement is positioned at described a plurality of deflecting elements as the described spatial light modulator of claim 85.
87. a spatial light modulator, it comprises:
First medium;
Second medium, wherein said first connects together and gets escapement between the two to form the gap between described medium with described second medium;
Be positioned at a plurality of micromirror in described gap, each micromirror further comprises:
Eyeglass, it further comprises:
First and second parts, wherein described second portion moves apart described first medium when described first shifts to described first medium;
Hinge, it is arranged in a plane different with plane, described mirror thin slice place;
Wherein said mirror thin slice is fixed to described hinge, so that described mirror thin slice can be rotated operation; And
But the wherein said escapement of getting is positioned at within the occupied zone of described a plurality of deflecting elements.
88. as the described spatial light modulator of claim 87, but wherein said medium comprises the electrode that approaches corresponding deflecting element setting most, but is used for the described deflecting element of deflection.
89. as the described spatial light modulator of claim 88, wherein said medium is the silicon medium.
90. as the described spatial light modulator of claim 87, but wherein said deflecting element is the micromirror that comprises reflection layer.
91. as the described spatial light modulator of claim 87, wherein said hinge is a torsion hinge.
92. as the described spatial light modulator of claim 91, but wherein the deflection thin slice comprises silicon nitride.
93. as the described spatial light modulator of claim 91, wherein the distance between the neighbouring element is smaller or equal to 0.5 micron.
94. as the described spatial light modulator of claim 91, the distance between wherein said first and second media is 1 to 5 micron.
95. as the described spatial light modulator of claim 91, wherein said medium uses the bonding agent that comprises stupalith to connect together and has the escapement of getting between the two, wherein said stupalith is silicon dioxide or nitrogen oxide.
96. as the described spatial light modulator of claim 95, the wherein said escapement of getting is positioned at described a plurality of outside of changeing element.
97. a spatial light modulator, it comprises:
First medium, it is the semiconductor medium with electrode and gate array;
Second medium, but it has the deflecting element array; And
But wherein said electrode is related with described deflecting element, but is used for the described deflecting element of deflection.
98. as the described spatial light modulator of claim 97, wherein said first and second media connect together with formation space between the two, but described deflecting element is sealed in the described space.
99. as the described spatial light modulator of claim 97, the distance between the wherein said medium is from 1 to 5 micron.
100. as the described spatial light modulator of claim 98, wherein said medium uses bonding agent to connect together and has the escapement of getting between the two.
101. as the described spatial light modulator of claim 100, the wherein said escapement of getting is positioned at described a plurality of outside of changeing element.
102. as the described spatial light modulator of claim 100, but wherein said deflecting element comprises it being the stupalith of silicon dioxide or nitrogen oxide.
103. as the described spatial light modulator of claim 100, wherein each mirror thin slice all is fixed on the torsion hinge, so that described mirror thin slice can be rotated operation.
104. a projector, it comprises:
Light source, it provides illumination light;
As the described spatial light modulator of claim 94, it is used to regulate described illumination light; And
Display-object, described adjusting transmittance on it to produce desired image.
105. a spatial light modulator device, it comprises:
First medium, it has the array of circuit and electrode;
But the array of deflecting element, it is made on second medium, and described second medium is a semiconductor medium; And
Coupling between wherein said first and second media are mutual, but so that described deflecting element can be by described electrode drive.
106. as the described spatial light modulator device of claim 105, further comprise, but be positioned at the escapement of getting within described a plurality of deflecting element.
107. as the described spatial light modulator device of claim 105, wherein said first and second media connect together and described first and second media between the described escapement of getting is arranged.
108. as the described spatial light modulator device of claim 105, the distance between the wherein said medium is 1 to 5 micron.
109. a two medium apparatus, it comprises:
First and second media are formed with the gap therebetween; And
But be arranged in the deflecting element array in described gap, when being in its ON state, incident light is reflexed on the display-object to produce desired image.
110. as the described device of claim 109, further comprise, but electrod-array is to drive described deflecting element.
111. as the described device of claim 109, wherein said first and second media are with comprising that the adhesives of epoxy resin connects together.
112. as the described device of claim 109, wherein said first and second media connect together and described gap in get escapement.
113. as the described device of claim 112, wherein said getting around the described parameter that escapement is positioned at described medium.
114. as the described device of claim 109, the distance between the wherein said medium is 1 to 5 micron.
115., wherein in described first medium, further comprise: insulation course as the described device of claim 112.
116. as the described device of claim 112, but but wherein said deflecting element is the deflecting reflection micromirror, each all is fixed on the torsion hinge, so that described micromirror can be rotated operation with respect to described medium.
117. a spatial light modulator device, it comprises:
But deflecting element array;
The silicon medium; And
But wherein said deflecting element is fixed on described silicon medium top by another medium rather than described silicon medium, but so that described deflecting element can reflect incident light to produce desired image.
118. as the described spatial light modulator device of claim 117, wherein two media connect together with adhesives.
119. as the described spatial light modulator device of claim 117, wherein two media connect together and get escapement between the two.
120. as the described spatial light modulator device of claim 119, the wherein said escapement of getting is positioned within the described micromirror.
121. a spatial light modulator device, it comprises:
But the deflecting reflection element arrays, it is fixed to and reflects incident light on first medium to produce image, and the distance between the adjacent elements in the wherein said array is smaller or equal to 0.5 micron.
122., further comprise second medium as the described device of claim 121; And the gap between described first and second media, but wherein said deflecting element is sealed in the described gap.
123. as the described device of claim 122, further comprise, but approach electrode and the gate array that described deflecting reflection element is provided with most, but be used for the described deflecting reflection element of static driven.
124. as the described device of claim 122, the wherein said first medium light-transmissive; And described second medium is the semiconductor medium that has described electrode and gate array on it.
125. as the described device of claim 122, but but wherein said deflecting element is the microelectron-mechanical deflecting element.
126. as the described device of claim 122, the distance between wherein said first and second media is 1 to 5 micron.
127. as the described device of claim 122, wherein two media connect together with bonding agent.
128., but wherein get the outside that escapement is positioned at described a plurality of deflecting elements as the described device of claim 122.
129. as the described device of claim 122, but wherein said deflecting element comprises stupalith, described stupalith is silicon dioxide or nitrogen oxide.
130. as the described device of claim 122, wherein each mirror thin slice all is fixed on the hinge, so that the rotatable operation of described mirror thin slice.
131. as the described device of claim 130, wherein said hinge is a torsion hinge.
132. a projector, it comprises:
Light source, it provides illumination light;
Spatial light modulator as claimed in claim 1, it is used to regulate described illumination light; And
Display-object, the transmittance that is conditioned on it to produce desired image.
133. regulate illumination light to produce the method for desired image for one kind, this method comprises:
Provide the reflection micromirror that is fixed on first medium array, so that described micromirror can be by opening the ON state and closing and rotate between the OFF state and can switch;
Each micromirror is related with electrode, so that between described micromirror and associated described electrode, set up electrostatic field;
Described illuminated light guide is guided on the described micromirror;
Described micromirror is applied voltage, so that all micromirror all have same potential; And
Coming the described micromirror of deflection by the described electrostatic field that changes between described micromirror and the described electrode between described ON and OFF state.
134. as the described method of claim 133, wherein the step of the described micromirror of deflection further comprises:
Described micromirror is deflected into described ON state so that described illumination light is reflexed on the display-object; And
Described micromirror is deflected into described OFF state leave described display-object to reflect described illumination light.
135. as the described method of claim 133, wherein each micromirror is fixed on the hinge, like this, described micromirror can be rotated operation.
136. as the described method of claim 133, wherein hinge is a torsion hinge.
137. as the described method of claim 133, wherein the step that described illuminated light guide is guided on the described micromirror further comprises: described illuminated light guide is guided on the reflecting surface of described micromirror.
138. as the described method of claim 133, wherein reflecting surface comprises aluminium lamination.
139. a spatial light modulator device, it comprises:
But the deflecting reflection element arrays, it is fixed on the silicon medium but directly is not connected with it, and described silicon medium has electrode and gate array, but is used for the deflection deflecting element.
140., get escapement but wherein said deflecting element is connected to be provided with between described silicon medium and described silicon medium and the described optical transmission medium by the optical transmission medium as the described device of claim 139.
141. as the described device of claim 139, wherein two media connect together, and form the gap, but described deflecting element are in described gap.
142. as the described device of claim 139, but wherein said deflecting element is a micromirror, described micromirror is fixed on the hinge, so that described micromirror can be rotated with respect to described silicon medium.
143. a spatial light modulator device, it comprises:
But deflecting reflection micromirror array, it is made on the optical transmission medium;
Electrod-array, but it is related with deflecting element, is used for element is carried out deflection, but wherein each deflecting element is related with electrode and by described electrode deflection; And
Wherein each micromirror is fixed to and is on the hinge of the described micromirror coplane under the non-deflection state, so that described micromirror can be rotated with respect to described optical transmission medium.
144. as the described device of claim 143, wherein said hinge is a torsion hinge.
145. as the described device of claim 143, wherein said optical transmission medium connects together with the silicon medium, and is gapped between the two, but described deflecting element is in described gap.
146. as the described device of claim 143, wherein said each micromirror can be carried out the conversion of ON and OFF state in operation.
147. a spatial light modulator device, it comprises:
But deflecting reflection micromirror array, it is fixed on the medium, wherein each micromirror is fixed on the deformable hinge in the independent plane that is placed on described micromirror, so that described micromirror can be rotated to ON state and OFF state, wherein said OFF state is the state parallel with described medium.
148. as the described device of claim 147, wherein said hinge is a torsion hinge.
149. as the described device of claim 147, wherein said hinge is placed between described micromirror and the medium, is connected with described micromirror on the described medium.
150., further comprise as the described device of claim 147:
Electrode and gate array, but it is approached the placement of deflection micromirror most, is used for the described micromirror of deflection.
151. as the described device of claim 147, the described medium that wherein is fixed with described micromirror on it is the optical transmission medium.
152. as the described device of claim 147, wherein electrode and circuit are formed on the silicon medium that is connected to described optical transmission medium.
153. regulate illumination light to produce the method for desired image for one kind, this method comprises:
But the array of the deflecting reflection micromirror with a group pattern edge is provided, and wherein each micromirror can be rotated to ON state and OFF state;
With described illumination light along the direction guiding of the described edge-perpendicular of its projection on described micromirror array and described micromirror array on described micromirror;
Described micromirror with described micromirror array deflects into described ON state and described OFF state respectively; And
Will be from the indirect illumination transmittance that is in the described micromirror under the described ON state to display-object; And reflection is left display-object from the indirect illumination light that is in the described micromirror under the described OFF state.
154. as the described method of claim 153, wherein the step of the described micromirror of deflection further comprises respectively:
Described micromirror is related with electrode; And
Between described micromirror and the described electrode related, set up electrostatic field with it.
155., further comprise as the described method of claim 154:
The described micromirror that keeps described micromirror array is under an electromotive force.
156. a spatial light modulator device, it comprises:
But deflecting reflection micromirror array, its each all be fixed on the deformable hinge;
The array of electrode and circuit, it is positioned on the silicon medium, and described silicon medium is placed on the most approaching described micromirror place, is used for the described micromirror of deflection, and wherein each micromirror is related with electrode and by described electrode deflection; And
Wherein said hinge is placed between described micromirror and the described electrode related with it.
157. as the described device of claim 156, wherein said micromirror is formed on the optical transmission medium.
158. a spatial light modulator device, it comprises:
Medium, its transmissive visible light;
Silicon medium, the described medium of wherein said silicon medium and transmissive visible light connect together and the escapement of getting between the two forms the gap between medium;
But a plurality of deflecting elements, it is sealed in the described gap; And
The photoresistance barrier film, it is positioned on the selection area of described optical transmission medium.
159. as the described device of claim 158, wherein said photoresistance barrier film is placed on around the parameter of described optical transmission medium.
160. a method of making micromirror device, described method comprises:
Deposit one or more sacrifice layers, it is the amorphous silicon layer on the medium;
Form hinge and micromirror on the sacrifice layer that is deposited, so that after removing described sacrifice layer, described micromirror is fixed on the described hinge; And
Use comprises xenon difluoride XeF 2The etchant of gas phase remove described sacrifice layer.
161. as the described method of claim 160, wherein said etchant comprises diluents, described diluents comprises inert gas.
CNB2005100679297A 1998-09-24 1998-09-24 Double-layer dielectric reflective space optical modulator with self-limiting micro-mechanical component Expired - Fee Related CN100343717C (en)

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* Cited by examiner, † Cited by third party
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Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4229732A (en) * 1978-12-11 1980-10-21 International Business Machines Corporation Micromechanical display logic and array
US4383255A (en) * 1980-03-11 1983-05-10 Centre Electronique Horloger S.A. Miniature display device
US5579149A (en) * 1993-09-13 1996-11-26 Csem Centre Suisse D'electronique Et De Microtechnique Sa Miniature network of light obturators
US5768009A (en) * 1997-04-18 1998-06-16 E-Beam Light valve target comprising electrostatically-repelled micro-mirrors
US5784190A (en) * 1995-04-27 1998-07-21 John M. Baker Electro-micro-mechanical shutters on transparent substrates
US5808780A (en) * 1997-06-09 1998-09-15 Texas Instruments Incorporated Non-contacting micromechanical optical switch

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4229732A (en) * 1978-12-11 1980-10-21 International Business Machines Corporation Micromechanical display logic and array
US4383255A (en) * 1980-03-11 1983-05-10 Centre Electronique Horloger S.A. Miniature display device
US5579149A (en) * 1993-09-13 1996-11-26 Csem Centre Suisse D'electronique Et De Microtechnique Sa Miniature network of light obturators
US5784190A (en) * 1995-04-27 1998-07-21 John M. Baker Electro-micro-mechanical shutters on transparent substrates
US5768009A (en) * 1997-04-18 1998-06-16 E-Beam Light valve target comprising electrostatically-repelled micro-mirrors
US5808780A (en) * 1997-06-09 1998-09-15 Texas Instruments Incorporated Non-contacting micromechanical optical switch

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