CN211206960U - Two-dimensional electrostatic scanning micro-mirror - Google Patents

Abstract

The utility model discloses a two-dimensional electrostatic scanning micro-mirror, which comprises an outer frame, an inner frame and a mirror surface, wherein the outer frame is provided with an outer frame isolation groove which divides the outer frame into an outer frame measuring part, an outer frame driving part and two outer frame connecting parts; an outer feedback comb tooth group is arranged between the outer frame measuring part and the inner frame, an outer driving comb tooth group is arranged between the outer frame driving part and the inner frame, a mirror surface isolation groove, a mirror surface feedback part for separating the mirror surface, a mirror surface driving part and a central part are machined on the mirror surface; an inner feedback comb tooth group and an inner drive comb tooth group are respectively processed between the mirror surface feedback part and the mirror surface drive part and the inner edge frame. Through setting up the isolation groove of isostructure at outline and mirror surface, separate outline and mirror surface for different functional units, set up inside and outside broach group into drive broach group and feedback broach group respectively, can realize the measurement to mirror surface at two direction deflection angles, can feed back the deflection angle of mirror surface in different directions in real time to improve the accuracy nature of mirror surface deflection angle control.

Description

Two-dimensional electrostatic scanning micro-mirror

Technical Field

The utility model belongs to the technical field of the micro-electro-mechanical system and specifically relates to a but two-dimensional electrostatic scanning micro mirror of real-time feedback angle based on MEMS processing technology preparation.

Background

The MEMS refers to a Micro-Electro-Mechanical System (Micro-Electro-Mechanical System), which is a revolutionary new technology developed on the basis of the Micro-electronics technology, and is a high-tech electromechanical device manufactured by combining technologies such as lithography, corrosion, thin film, silicon micromachining, and precision machining, and is a key technology related to the development of technology, economic prosperity, and national defense safety, in which, a scanning micromirror is a light reflection type device developed by applying the MEMS technology, and drives a mirror surface to deflect under the action of a Micro-driving force, so as to realize reflection scanning of a light beam in one-dimensional or two-dimensional directions, and has advantages of low cost, high reliability, miniaturization, and easy mass production, and the like, and has a huge application market in the fields of optical micromirror communication, laser projection, laser radar, three-dimensional imaging, and the like, when the mirror surface reflects light, the angle of mirror surface deflection needs to be monitored in real time, for an electrostatic micromirror, due to the effect of electrostatic force between combs, the comb causes a change of capacitance between the combs, that real-time monitoring of the angle of the mirror surface deflection is required, and the mirror surface deflection is performed by two-axis deflection signals, such as a two-axis vertical deflection, a two-scanning deflection signal, and a vertical deflection of a vertical deflection channel, which cannot be detected by applying a two-scanning mirror surface, and a two-vertical deflection-scanning mirror-axis-vertical deflection-scanning-vertical deflection-mirror-.

SUMMERY OF THE UTILITY MODEL

The applicant aims at the problem that the deflection angles of a two-dimensional scanning micro-mirror in two directions cannot be monitored in real time in the prior art, and provides a novel two-dimensional electrostatic scanning micro-mirror which can measure the capacitance change of an inner group of feedback comb teeth and an outer group of feedback comb teeth in real time, so that the deflection angles of the mirror surface in the two directions can be obtained, and the deflection state of the mirror surface can be accurately controlled.

The utility model discloses the technical scheme who adopts as follows:

a two-dimensional electrostatic scanning micro-mirror comprises an outer frame, an inner frame and a mirror surface, wherein the outer frame and the inner frame are connected through an outer torsion beam; an outer feedback comb tooth group is arranged between the outer frame measuring part and the inner frame, and an outer driving comb tooth group is arranged between the outer frame driving part and the inner frame.

As a further improvement of the above technical solution:

the mirror surface is processed with a mirror surface isolation groove which divides the mirror surface into a mirror surface feedback part, a mirror surface driving part and a central part; an inner feedback comb tooth group and an inner driving comb tooth group are respectively processed between the mirror surface feedback part and the inner edge frame and between the mirror surface driving part and the inner edge frame; the surface of the micromirror is provided with an insulating layer, an inner driving lead and an electrode as well as an inner feedback lead and an electrode are processed on the insulating layer, the electrode is positioned at the outer frame connecting part, and the tail ends of the inner driving lead and the lead of the electrode are communicated with the mirror surface driving part; the tail ends of the internal feedback lead and the lead of the electrode are communicated with the mirror feedback part.

And the outer frame measuring part and the outer frame driving part are respectively provided with a first electrode and a second electrode.

The inner driving lead and the lead of the electrode sequentially pass through the surfaces of the outer frame connecting part, the outer torsion beam, the inner frame, the inner torsion beam and the central part, and the tail ends of the inner driving lead and the lead of the electrode are communicated with the mirror surface driving part; the inner feedback wires and the wires of the electrodes pass through the surfaces of the outer frame connecting part, the outer torsion beam, the inner frame, the inner torsion beam and the central part, and the tail ends of the inner feedback wires and the wires of the electrodes are communicated with the mirror surface feedback part.

The outer frame connecting part, the inner frame, the mirror surface, the outer torsion beam and the inner torsion beam are covered with insulating layers.

A third electrode which is conducted with the silicon substrate of the micromirror is processed on the outer frame connecting part; the isolation groove on the mirror surface is arranged at the position, close to the comb teeth, of the edge of the mirror surface.

Four outer frame isolation grooves are processed on the outer frame; the mirror finishing is provided with two symmetrical mirror surface isolation grooves.

The outer frame isolation groove is positioned at the position of the static tooth on one side of the outer frame and divides one side of the outer frame into an outer frame measuring part and an outer frame driving part; the inboard quiet tooth of frame measuring part and the tooth that moves that interior frame corresponds constitute outer feedback broach group, and the inboard quiet tooth of frame drive division and the tooth that moves that interior frame corresponds constitute outer drive broach group.

The mirror surface isolation grooves are of two parallel linear structures.

The mirror surface is divided into a mirror surface driving part and a central part by the mirror surface isolating groove on one side of the mirror surface; the mirror surface isolation groove on the other side divides one side of the mirror surface into a mirror surface driving part and a mirror surface feedback part, movable teeth connected with the mirror surface driving part and static teeth corresponding to the inner frame form an inner driving comb tooth group, and movable teeth connected with the mirror surface feedback part and static teeth corresponding to the inner frame form an inner feedback comb tooth group; the internal driving lead and the part of the electrode on the mirror surface are T-shaped and are simultaneously communicated with the mirror surface driving parts on two sides of the mirror surface to provide driving signals.

The mirror surface isolation groove on at least one side is T-shaped.

The mirror surface isolation groove on at least one side is in a double-T shape.

The mirror surface isolation groove is of a broken line structure or a curve structure.

The mirror surface is square, round or oval; the outer torsion beam and the inner torsion beam are straight beams, folding beams or other connecting structures.

And the outer frame isolation groove and the mirror surface isolation groove are filled with insulating materials.

The utility model has the advantages as follows:

the utility model discloses a two-dimentional electrostatic scanning micro mirror is through setting up the not isolated slot of isostructure at outline and mirror surface, separates outline and mirror surface for different functional areas, then through the metal wire and the electrode of special shape, set up inside and outside broach respectively into drive broach group and feedback broach group, can realize the real-time measurement to the mirror surface at two orientation deflection angles, compare prior art can real-time feedback mirror surface at the not equidirectional deflection angle to improve the accuracy nature of mirror surface deflection angle control.

The utility model discloses all isolation tanks all are located outline and mirror surface, and need not to set up the isolation tank on constrictive torsion beam and interior frame, and the intussuseption of isolation tank packs insulating material and plays the effect of keeping apart, can be in the same place the effective fixed connection of different parts simultaneously, effectively reduces because introduce other insulating material and the stress and the rigidity problem that lead to, promotes the reliability of micro mirror.

Drawings

Fig. 1 is a schematic structural diagram of a first embodiment of the present invention.

Fig. 2 is a schematic structural view of the mirror portion in fig. 1.

Fig. 3 is a schematic structural diagram of a second embodiment of the present invention.

Fig. 4 is an enlarged view of a portion a as in fig. 3.

Fig. 5 is an enlarged view of the portion B as in fig. 3.

Fig. 6 is a schematic structural view of an inner frame and a mirror surface of a third embodiment of the present invention.

Fig. 7 is a schematic structural diagram of the isolation trench of the present invention.

Fig. 8 is another schematic structural diagram of the isolation trench of the present invention.

Fig. 9A to 9D are schematic diagrams illustrating steps of manufacturing the scanning micromirror of the present invention.

In the figure: 1. an outer frame; 1-1, an outer frame measuring part; 1-2, an outer frame driving part; 1-3, an outer frame connecting part; 2. an inner frame; 3. a mirror surface; 3-1, mirror surface feedback part; 3-2, a mirror surface driving part; 3-3, a central portion; 4. an outer torsion beam; 5. an inner torsion beam; 6. an outer frame isolation groove; 7-1, feeding back the comb teeth group; 7-2, externally driving the comb tooth group; 8. a mirror surface isolation groove; 9-1, an internal feedback comb tooth group; 9-2, an internal driving comb tooth group; 10. a first electrode; 11. a second electrode; 12. a third electrode; 13. an inner drive lead and an electrode; 14. an internal feedback lead and an electrode; 21. photoresist; 22. an SOI silicon wafer; 23. an insulating material; 24. a metal.

Detailed Description

The following describes embodiments of the present invention with reference to the drawings.

The first embodiment is as follows:

as shown in fig. 1 and fig. 2, the two-dimensional electrostatic scanning micro-mirror of the present invention uses silicon material as a basic structure, and includes an outer frame 1, an inner frame 2 and a mirror surface 3, and the mirror surface 3 is square. The outer frame 1 and the inner frame 2 are connected together through two outer torsion beams 4, the inner frame 2 and the mirror surface 3 are connected together through two inner torsion beams 5, and the directions of the inner torsion beams 5 and the outer torsion beams 4 are vertical. The mirror surface 3 can be deflected with the inner torsion beam 5 as an axis, and the inner frame 2 and the mirror surface 3 can be deflected with the outer torsion beam 4 as an axis, thereby realizing deflection of the mirror surface 3 in two perpendicular directions.

Four outer frame isolation grooves 6 are processed on the outer frame 1, the outer frame isolation grooves 6 divide the outer frame 1 into an outer frame measuring part 1-1, an outer frame driving part 1-2 and an outer frame connecting part 1-3, and the three parts are electrically isolated and are not conducted with each other. An outer feedback comb tooth group 7-1 and an outer driving comb tooth group 7-2 are respectively arranged between the other two sides without the torsion beam between the outer frame 1 and the inner frame 2, wherein the static teeth of the outer feedback comb tooth group 7-1 are positioned at the inner side of the outer frame measuring part 1-1, the static teeth of the outer driving comb tooth group 7-2 are positioned at the inner side of the outer frame driving part 1-2, and one end of the outer torsion beam 4 is connected with the inner side of the outer frame connecting part 1-3. A first electrode 10 and a second electrode 11 are respectively processed on the outer frame measuring part 1-1 and the outer frame driving part 1-2 and are used for being connected with an external testing or driving device.

The mirror surface 3 is provided with two symmetrical mirror surface isolation grooves 8, preferably two parallel mirror surface isolation grooves 8, the mirror surface 3 is divided into a mirror surface feedback part 3-1, a mirror surface driving part 3-2 and a central part 3-3 which are isolated from each other, the outer edges of the mirror surface feedback part 3-1 and the mirror surface driving part 3-2 are respectively provided with movable teeth of an inner feedback comb tooth group 9-1 and an inner driving comb tooth group 9-2, and the inner side of the opposite inner edge frame 2 is provided with corresponding static teeth. The surfaces of the outer frame connecting part 1-3, the inner frame 2, the mirror surface 3, the outer torsion beam 4 and the inner torsion beam 5 are covered with insulating layers, inner driving wires and electrodes 13 and inner feedback wires and electrodes 14 are processed on the insulating layers, the electrodes are all positioned on the outer frame connecting part 1-3, the wires of the inner driving wires and the electrodes 13 sequentially pass through the surfaces of the outer frame connecting part 1-3, the outer torsion beam 4, the inner frame 2, the inner torsion beam 5 and the central part 3-3, and the tail ends of the inner driving wires and the electrodes are communicated with the mirror surface driving part 3-2 and are used for providing driving signals for the inner driving comb tooth group 9-2; and the inner feedback lead and the lead of the electrode 14 pass through the surfaces of the outer frame connecting part 1-3, the outer torsion beam 4, the inner frame 2, the inner torsion beam 5 and the central part 3-3, and the tail end of the inner feedback lead and the lead of the electrode is communicated with the mirror feedback part 3-1 to measure the capacitance of the inner feedback comb-tooth group 9-1. The outer frame connecting part 1-3 is also provided with a third electrode 12 which is conducted with the substrate silicon material and used for providing a driving signal for the comb teeth of the inner frame 2.

The during operation of the two-dimensional electrostatic scanning micro-mirror of this embodiment, through second electrode 11, third electrode 12 and interior drive wire and electrode 13, be used for driven broach group to provide drive signal on outer frame 1, interior frame 2 and the mirror surface 3 respectively, under the effect of electrostatic force, interior frame 2 drives torsion beam 4 outside the mirror surface 3 and deflects for the axle, and torsion beam 5 is deflected in another direction for the axle within mirror surface 3 simultaneously. When the movable teeth and the static teeth of the driving comb tooth group are separated under the electrostatic acting force, the movable teeth and the static teeth of the corresponding feedback comb tooth group form a certain angle and have a certain capacitance value. At the moment, the rotating angle of the inner frame 2 and the mirror surface 3 in one direction can be obtained by testing the capacitance of the external feedback comb tooth group 7-1; meanwhile, the rotation angle of the mirror surface 3 in the other direction can be obtained by testing the capacitance of the internal feedback comb tooth group 9-1. Through the utility model discloses a structure, the angle that can effectual real-time measurement mirror surface 3 deflected in two directions of mutually perpendicular.

In order to realize above technological effect, the utility model discloses a set up a plurality of frames isolation tank 6 on outline 1, separate outline 1 for 4 parts that have different functions, realize the function of inside and outside drive and inside and outside electric capacity feedback simultaneously. Moreover, the mirror surface 3 is effectively divided into three areas through the mirror surface isolation grooves 8, and the functions of driving and capacitance feedback are simultaneously realized on the same mirror surface by matching with the special arrangement of a lead. The utility model discloses set up outline 1 and mirror surface 3 into a plurality of different functional areas, realized inside and outside simultaneous drive and electric capacity feedback, real-time measurement mirror surface 3's deflection angle.

Moreover, the utility model discloses an all isolation tanks are located outline 1 and mirror surface 3, and the isolation tank setting on the mirror surface 3 especially leans on broach one side at 3 edges of mirror surface, keeps away from the mirror surface center. Play the effect of keeping apart through insulating material in the isolation groove, be in the same place the effective fixed connection of different parts simultaneously, and need not to set up the isolation groove on narrow torsion beam and interior border 2, can effectively reduce because stress and the rigidity problem that introduces other insulating material and lead to promote the reliability of micro mirror.

Example two:

as shown in fig. 3, the outer frame 1 of the present embodiment is divided into an outer frame measuring part 1-1, an outer frame driving part 1-2, and an outer frame connecting part 1-3 by a plurality of outer frame separation grooves 6. Different from the first embodiment, as shown in fig. 5, an outer frame isolation groove 6 of the present embodiment is located at a position of a static tooth on one side of an outer frame 1, the outer frame isolation groove 6 divides one side of the outer frame 1 into an outer frame measuring part 1-1 and an outer frame driving part 1-2, wherein a part of the static tooth is connected to the inner side of the outer frame measuring part 1-1, and the part of the static tooth and a moving tooth corresponding to the inner frame 2 form an outer feedback comb tooth group 7-1; the inner side of the outer frame driving part 1-2 is connected with the other part of static teeth, the moving teeth corresponding to the inner frame 2 form an outer driving comb tooth group 7-2, and meanwhile, the comb tooth group below the whole micro mirror is also the outer driving comb tooth group 7-2.

The number of the driving teeth and the number of the feedback teeth can be reasonably distributed through the outer frame isolation groove 6 with the special structure. In actual design and manufacturing process, can set up the frame isolation slot 6 of suitable position according to the size of the required drive power of micro mirror to and the size of required feedback capacitance value, and then obtain the drive tooth and the feedback tooth of reasonable quantity, satisfy the demand in drive and feedback two aspects.

As shown in FIG. 4, the isolation groove on the mirror surface 3 in this embodiment is also different from the first embodiment, the mirror surface isolation groove 8 on the left side divides the mirror surface 3 into a mirror surface driving portion 3-2 and a central portion 3-3, and an inner driving comb teeth group 9-2 is arranged outside the mirror surface driving portion 3-2; the mirror surface isolation groove 8 on the right side is T-shaped, the right side of the mirror surface 3 is divided into an upper mirror surface driving part 3-2 and a lower mirror surface feedback part 3-1, the mirror surface driving part 3-2 is connected with partial comb teeth on the right side of the mirror surface 3, the partial comb teeth are used as moving teeth to form an inner driving comb tooth group 9-2 with static teeth corresponding to the inner frame 2, the mirror surface feedback part 3-1 is connected with other comb teeth, and the static teeth corresponding to the inner frame 2 form an inner feedback comb tooth group 9-1. The internal feedback lead and the electrode 14 are communicated with the mirror feedback part 3-1 as in the first embodiment and are used for detecting a capacitance signal; the internal driving lead and the part of the electrode 13 on the mirror surface 3 are T-shaped and are simultaneously communicated with the mirror surface driving parts 3-2 at the left side and the right side of the mirror surface for providing driving signals. Of course, the mirror surface isolation grooves 8 on both sides may be all set to be T-shaped structures, so as to divide the mirror surfaces on both sides into the upper mirror surface driving part 3-2 and the lower mirror surface feedback part 3-1, and match the feedback wires of the corresponding structures.

Through the mirror surface isolation groove 8 with the special structure, the number of the driving teeth and the feedback teeth can be effectively distributed, in the actual design and manufacturing process, the mirror surface isolation groove 8 with a proper shape can be arranged according to the size of required driving force and the size of required feedback capacitance, and the requirements of driving and feedback in two aspects are met.

Example three:

as shown in FIG. 6, the mirror surface isolation groove 8 on the left side of the mirror surface 3 in this embodiment is the same as that in the first embodiment, and divides the mirror surface 3 into the mirror surface driving section 3-2 and the center section 3-3. The mirror surface isolation groove 8 on the right side penetrates through the whole mirror surface, the right side comprises two branch isolation grooves which are of a double-T-shaped structure, the right side of the mirror surface 3 is divided into an upper part, a middle part and a lower part which are sequentially a mirror surface driving part 3-2 on the upper part, a mirror surface feedback part 3-1 on the middle part and a mirror surface driving part 3-2 on the lower part. The two mirror surface driving parts 3-2 are connected with partial comb teeth on the right side of the mirror surface 3, the partial comb teeth are used as moving teeth to form an inner driving comb tooth group 9-2 with static teeth corresponding to the inner frame 2, the mirror surface feedback part 3-1 is connected with middle comb teeth, and the static teeth corresponding to the inner frame 2 form an inner feedback comb tooth group 9-1. The internal feedback wire and the electrode 14 are connected to the mirror feedback part 3-1 for detecting the capacitance signal, as in the first embodiment. The inner driving lead and the electrode 13 are divided into two branches on the inner frame, and respectively enter the mirror surface 3 from the upper inner torsion beam 5 and the lower inner torsion beam 5 to form a plurality of contact ends which are all communicated with the plurality of mirror surface driving parts 3-2 on the mirror surface 3 and used for providing driving signals.

Of course, the mirror isolation groove 8 with a double T-shaped structure can divide the right mirror 3 into a mirror driving part 3-2 at the middle and mirror feedback parts 3-1 at the two ends. With the second embodiment, the mirror surface isolation groove 8 with the special structure can effectively distribute the number of the driving teeth and the feedback teeth, and in the actual design and manufacturing process, the mirror surface isolation groove 8 with a proper shape can be arranged according to the size of the required driving force and the size of the required feedback capacitance value, so that the requirements of the driving and the feedback are met.

Example four:

in the first to third embodiments, the mirror isolation grooves 8 are all linear structures. In this embodiment, as shown in fig. 7, the mirror surface isolation groove 8 has a polygonal line structure. As shown in fig. 8, the mirror isolation trench 8 has a curved structure. Through the 8 structures of mirror surface isolation groove of complicacy, can increase the area of contact of filling material and matrix material in the isolation groove, promote the whole reliability of mirror surface structure.

Example five:

in this embodiment, the mirror surface 3 can be made into a circular or elliptical geometric shape according to actual requirements.

The inner and outer torsion beams can be processed into straight beams, folding beams or other structures.

Example six:

fig. 9 is a schematic diagram of a simple flow path for manufacturing the micromirror of the present invention, which is only used to simply explain the manufacturing process of the partial isolation groove and the metal wire and the electrode of the present invention, but not to limit the structure of the micromirror of the present invention.

Step 1: as shown in fig. 9A, a photoresist 21 is coated on an SOI silicon wafer 22, and a desired isolation trench is etched by photolithography, etching, or the like.

Step 2: as shown in fig. 9B, an insulating material 23 is deposited on the front surface of the SOI silicon wafer 22 to fill the isolation trenches, and then the micromirror surface is planarized by a chemical mechanical polishing process, so that a layer of the insulating material 23 still remains on the silicon wafer surface.

The insulating material 23 filling the isolation trenches is SiN, SiO2, or other semiconducting insulating material.

And step 3: as shown in fig. 9C, a contact hole is etched on the insulating material 23 by photolithography and etching processes on the front surface of the SOI silicon wafer 22; metal 24 is then deposited and etched to form the metal electrodes and conductive lines in the specified pattern, forming the mirror surfaces, metal electrodes and conductive lines.

The metal 24 is made of conductive materials such as gold, copper, aluminum, silver and the like.

And 4, step 4: as shown in fig. 9D, structures such as comb teeth, inner and outer frames, and mirror surfaces are fabricated by front and back photolithography and etching. As shown in the mirror cross-sectional view, it can be seen that the mirror isolation groove 8 composed of the insulating material 23 partitions the mirror 3 into the mirror feedback section 3-1, the mirror driving section 3-2 and the center section 3-3 which are isolated from each other.

The above description is illustrative of the present invention and is not intended to limit the present invention, and the present invention may be modified in any manner without departing from the spirit of the present invention.

Claims (15)

1. The utility model provides a two-dimentional electrostatic scanning micro mirror, includes outline (1), interior frame (2) and mirror surface (3), and outline (1) and interior frame (2) are connected through outer torsion beam (4), and interior frame (2) and mirror surface (3) are connected through interior torsion beam (5), the direction mutually perpendicular of interior torsion beam (5) and outer torsion beam (4), its characterized in that: an outer frame isolation groove (6) is processed on the outer frame (1) to divide the outer frame (1) into an outer frame measuring part (1-1), an outer frame driving part (1-2) and two outer frame connecting parts (1-3); an external feedback comb tooth group (7-1) is arranged between the outer frame measuring part (1-1) and the inner frame (2), and an external driving comb tooth group (7-2) is arranged between the outer frame driving part (1-2) and the inner frame (2).

2. The two-dimensional electrostatic scanning micro-mirror of claim 1, wherein: the mirror surface (3) is processed with a mirror surface isolation groove (8) to divide the mirror surface (3) into a mirror surface feedback part (3-1), a mirror surface driving part (3-2) and a central part (3-3); an inner feedback comb tooth group (9-1) and an inner driving comb tooth group (9-2) are respectively processed between the mirror feedback part (3-1) and the mirror driving part (3-2) and the inner frame (2); the surface of the micro mirror is provided with an insulating layer, an inner driving lead and electrode (13) and an inner feedback lead and electrode (14) are processed on the insulating layer, the electrode is positioned on the outer frame connecting part (1-3), and the tail ends of the inner driving lead and the lead of the electrode (13) are communicated with the mirror surface driving part (3-2); the tail ends of the internal feedback lead and the electrode (14) are communicated with the mirror feedback part (3-1).

3. The two-dimensional electrostatic scanning micro-mirror of claim 1, wherein: the outer frame measuring part (1-1) and the outer frame driving part (1-2) are respectively provided with a first electrode (10) and a second electrode (11).

4. The two-dimensional electrostatic scanning micro-mirror of claim 2, wherein: the inner driving lead and the lead of the electrode (13) sequentially pass through the surfaces of the outer frame connecting part (1-3), the outer torsion beam (4), the inner frame (2), the inner torsion beam (5) and the central part (3-3), and the tail end of the inner driving lead is communicated with the mirror surface driving part (3-2); the inner feedback wires and the wires of the electrodes (14) pass through the surfaces of the outer frame connecting parts (1-3), the outer torsion beam (4), the inner frame (2), the inner torsion beam (5) and the central part (3-3), and the tail ends of the inner feedback wires and the wires of the electrodes are communicated with the mirror feedback part (3-1).

5. The two-dimensional electrostatic scanning micro-mirror of claim 2, wherein: the surface of the outer frame connecting part (1-3), the inner frame (2), the mirror surface (3), the outer torsion beam (4) and the inner torsion beam (5) is covered with an insulating layer.

6. The two-dimensional electrostatic scanning micro-mirror of claim 2, wherein: a third electrode (12) which is conducted with the silicon substrate of the micromirror is processed on the outer frame connecting part (1-3); the isolation grooves on the mirror surface (3) are arranged at the position, close to the comb teeth, of the edge of the mirror surface (3).

7. The two-dimensional electrostatic scanning micro-mirror of claim 2, wherein: four outer frame isolation grooves (6) are processed on the outer frame (1); the mirror surface (3) is provided with two symmetrical mirror surface isolation grooves (8).

8. The two-dimensional electrostatic scanning micromirror of claim 1 or 2, wherein: the outer frame isolation groove (6) is positioned at the position of the static teeth on one side of the outer frame (1) and divides one side of the outer frame (1) into an outer frame measuring part (1-1) and an outer frame driving part (1-2); static teeth on the inner side of the outer frame measuring part (1-1) and moving teeth corresponding to the inner frame (2) form an outer feedback comb tooth group (7-1), and static teeth on the inner side of the outer frame driving part (1-2) and moving teeth corresponding to the inner frame (2) form an outer driving comb tooth group (7-2).

9. The two-dimensional electrostatic scanning micro-mirror of claim 2, wherein: the mirror surface isolation grooves (8) are of two parallel linear structures.

10. The two-dimensional electrostatic scanning micro-mirror of claim 2, wherein: the mirror surface isolation groove (8) on one side of the mirror surface (3) divides the mirror surface (3) into a mirror surface driving part (3-2) and a central part (3-3); a mirror surface isolation groove (8) on the other side divides one side of the mirror surface (3) into a mirror surface driving part (3-2) and a mirror surface feedback part (3-1), movable teeth connected with the mirror surface driving part (3-2) and static teeth corresponding to the inner frame (2) form an inner driving comb tooth group (9-2), and movable teeth connected with the mirror surface feedback part (3-1) and static teeth corresponding to the inner frame (2) form an inner feedback comb tooth group (9-1); the internal driving lead and the part of the electrode (13) on the mirror surface (3) are T-shaped and are simultaneously communicated with the mirror surface driving parts (3-2) at two sides of the mirror surface (3) to provide driving signals.

11. The two-dimensional electrostatic scanning micro-mirror of claim 10, wherein: the mirror surface isolation groove (8) on at least one side is T-shaped.

12. The two-dimensional electrostatic scanning micro-mirror of claim 10, wherein: the mirror surface isolation groove (8) on at least one side is in a double-T shape.

13. The two-dimensional electrostatic scanning micro-mirror of claim 2, wherein: the mirror surface isolation groove (8) is of a broken line structure or a curve structure.

14. The two-dimensional electrostatic scanning micro-mirror of claim 1, wherein: the mirror surface (3) is square, circular or elliptical; the outer torsion beam (4) and the inner torsion beam (5) are straight beams or folding beams.

15. The two-dimensional electrostatic scanning micro-mirror of claim 2, wherein: and the outer frame isolation groove (6) and the mirror surface isolation groove (8) are filled with insulating materials.

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