Two-degree-of-freedom actuator and MEMS device

文档序号:883640 发布日期:2021-03-19 浏览:6次 中文

阅读说明:本技术 二自由度的致动器和mems装置 (Two-degree-of-freedom actuator and MEMS device ) 是由 顾姗姗 陆发斌 梁吉德 于 2018-06-26 设计创作,主要内容包括:本发明涉及微机电系统MEMS装置。特别地,本发明提出了一种用于MEMS装置的致动器和包括这种致动器的MEMS装置。该致动器具有可连接到该MEMS装置的框架的多个边侧的第一端,并且具有,特别地,通过接头,可连接到该MEMS装置的台架的第二端。此外,该致动器的第二端被配置为当该致动器被驱动并且该第一端被连接时向上或向下弯曲。(The present invention relates to microelectromechanical systems (MEMS) devices. In particular, the present invention proposes an actuator for a MEMS device and a MEMS device comprising such an actuator. The actuator has a first end connectable to sides of a frame of the MEMS device and has a second end connectable to a stage of the MEMS device, in particular, by a joint. Further, the second end of the actuator is configured to bend upward or downward when the actuator is driven and the first end is connected.)

1. An actuator (100) for a micro-electromechanical system (MEMS) device (200), wherein,

the first end (101) of the actuator (100) is connected to sides of a frame (201) of the MEMS device (200),

a second end (102) of the actuator (100), a stage (202) connected to the MEMS device (200) by a joint (203), and

the second end (102) of the actuator (100) is configured to bend upwards or downwards when the actuator (100) is driven and the first end (101) is connected.

2. The actuator (100) of claim 1,

the first end (101) of the actuator (100) is connected to two adjacent sides of a frame (201) of the MEMS device (200).

3. The actuator (100) of claim 1 or 2,

the actuator (100) has an irregular trapezoidal shape.

4. The actuator (100) of any of claims 1 to 3, the actuator (100) being configured as

Piezoelectric, magnetic, thermal or electrostatic actuators.

5. A micro-electromechanical systems (MEMS) device (200), comprising:

a table frame (202),

a frame (201) surrounding the gantry (202), and

at least one actuator (100), the actuator (100) being in accordance with any one of claims 1 to 4,

wherein a first end (101) of the at least one actuator (100) is connected to a plurality of sides of the frame (201), a second end (102) of the at least one actuator (100) is connected to the stage (202) by a joint (203), and the second end (102) of the actuator (100) is configured to bend upwards or downwards when the actuator (100) is driven.

6. The MEMS device (200) of claim 5,

the first end (101) of the at least one actuator (100) is connected to two adjacent sides of the frame (201).

7. The MEMS device (200) according to claim 5 or 6, further comprising:

a rotating strut (300) disposed on top of the gantry (202), an

A mirror plate (301) disposed on top of the rotatable post (300).

8. The MEMS device (200) of claim 7,

the at least one actuator (100) is arranged at least partially, in particular at least at its second end (102), below the mirror plate (301).

9. The MEMS device (200) according to any one of claims 5 to 8,

the frame (201) is rectangular in shape,

the MEMS device (200) comprises four actuators (100), the actuators (100) being according to any of claims 1 to 4, and

the first end (101) of each actuator (100) is connected to a different pair of adjacent sides of the rectangular frame (201), and the second end (102) is connected to the gantry (202) by a different joint (203).

10. The MEMS device (200) of claim 9,

the four actuators (100) are symmetrically arranged around the gantry (202).

11. The MEMS device (200) according to claim 9 or 10,

non-adjacent actuators (100) are arranged on opposite sides of the gantry (202).

12. The MEMS device (200) of any of claims 9 to 11,

the joint (203) is a two degree of freedom, 2DOF, joint.

13. The MEMS device (200) according to any one of claims 9 to 12, the MEMS device (200) configured to:

all four actuators (100) are driven simultaneously, wherein two adjacent actuators (100) are driven to bend their second ends (102) upwards, while two other adjacent actuators (100) are driven to bend their second ends (102) downwards.

14. A method (500) for controlling a MEMS device (200) according to any of claims 9 to 13, the method (500) comprising:

pitching (501) a gantry (202) of the MEMS device (200) by driving a first pair of adjacent actuators (100) to bend their second ends (102) upward and driving a second pair of adjacent actuators (100) to bend their second ends (102) downward, or

Deflecting (502) a stage (202) of the MEMS device (200) by driving a third pair of adjacent actuators (100) to bend their second ends (102) upward and driving a fourth pair of adjacent actuators (100) to bend their second ends (102) downward.

15. The method (500) of claim 14,

the actuator (100) is driven piezoelectrically, magnetically, thermally and/or electrostatically.

Technical Field

The present invention relates to the field of Micro-Electro-Mechanical systems (MEMS) devices. In particular, the invention proposes an actuator for a MEMS device and a MEMS device comprising at least one such actuator. The invention also relates to a method for controlling a MEMS device by means of at least one such actuator. The actuator Of the present invention is specifically designed for a two-Degree-Of-Freedom (DOF) MEMS device. To this end, the actuator may be a bendable actuator, wherein when one end is fixed, the actuator may be piezoelectrically, magnetically, thermally or electrostatically driven to bend up or down at the other end.

Background

The structure of MEMS devices always strives for smaller pitches without affecting the performance of the MEMS device. In practice, however, in many cases there is a trade-off between smaller spacing and better performance. This is the case, for example, when designing actuators for MEMS devices. Whatever the drive principle for which such an actuator is suitable (e.g. electrostatic, piezoelectric, magnetic or thermal by using a comb structure), space is the most important factor for enabling large displacements of the actuator. Therefore, making the actuators smaller generally affects their (displacement) performance. This makes it very challenging for MEMS devices with the same performance to include smaller actuators.

For example, consider a MEMS device having a mirror array that includes a plurality of micro-mirrors driven by actuators. The micromirrors must have very small pitch (i.e., only slightly larger than the aperture size), but at the same time require large rotation angles. Although there are methods that can effectively arrange electrostatic comb actuators around a single micromirror, only rotation angles of ± 5 ° can be achieved. This is not sufficient because in some applications a higher fill factor (ratio of aperture size to pitch size) and in particular a larger rotation angle up to ± 15 ° are required.

Moreover, conventional actuators are only suitable for 1DOF motions. Thus, in a 2DOF MEMS device, such as one with a 2D movable micromirror, two different sets of actuators are required to achieve 2D motion. Actuating the micromirrors in such MEMS devices to rotate one set of actuators about one axis, while a second set of actuators responsible for rotation about a second axis must remain idle. Therefore, the use efficiency of the actuator is rather limited, which is contradictory to the purpose of minimizing the size of the device.

This disadvantage is solved, for example, by proposing to mount the mirror plate on top of the actuator. However, this can cause problems with stray light, as the incident beam will be reflected by the mirror plate and other device components (such as the actuator or device frame).

Furthermore, a MEMS device with a multilayer structure is proposed, which device comprises a semiconductor layer, an addressing layer, a hinge layer and a mirror layer. However, this device approach is only applicable to digital mirroring, which can have both "on" and "off" states. The MEMS device is not capable of analog motion with very high resolution and large range of motion.

Another proposed MEMS device includes a device mount, a rotary actuator, and a linkage. However, considerable space is required, especially for the actuator length. In this device, the actuator is disposed outside the rotor and the link so that the rotor operates as a second resolver. This leads to the problem of connecting a plurality of elements in series, making the device very fragile and flexible in construction, so that the torque from the actuator is transmitted to the gantry only very inefficiently.

Disclosure of Invention

In view of the above challenges and problems, the present invention is directed to improvements in actuators and MEMS devices. It is an object of the present invention to provide an actuator for a MEMS device and a MEMS device comprising such an actuator, wherein the space provided by the dimensions of the MEMS device is used more efficiently. Furthermore, by means of the actuator, it should be possible to achieve large displacements. In addition, the present invention is also directed to providing an actuator for a MEMS device more suitable for achieving 2DOF motion, i.e., for achieving 2 DOF.

The object of the invention is achieved by the solution presented in the appended independent claims. Advantageous implementations of the invention are further defined in the dependent claims.

In summary, the present invention proposes an actuator for a MEMS device that can bend and constrain at multiple sides of the frame of the MEMS device and thus enable motion of the MEMS device in more than 1 DOF. The outer edge of the actuator is in particular fixed to at least two sides of the frame, the inner edge of which is connected to the gantry of the MEMS device.

A first aspect of the invention provides an actuator for a MEMS device, wherein a first end of the actuator is connectable to a plurality of sides of a frame of the MEMS device, a second end of the actuator is connectable, in particular by a joint, to a stage of the MEMS device, and the second end of the actuator is configured to bend upwards or downwards when the actuator is driven and the first end is connected.

The possibility of actuators being able to be attached at multiple sides of the frame is particularly advantageous for 2DOF MEMS devices. Furthermore, the ability to bend up or down enables smaller MEMS devices, as the actuator may be disposed, for example, partially under the stage of the MEMS device. Thus, the actuator may more efficiently utilize space in the MEMS device.

In an implementation of the first aspect, the first end of the actuator may be connected to two adjacent sides of the frame of the MEMS device.

In a further implementation form of the first aspect, the actuator has an irregular trapezoidal shape.

This shape allows the actuator to be connectable to at least two sides of the frame, while allowing better utilization of space in the MEMS device.

In a further implementation form of the first aspect, the actuator is configured as a piezoelectric, magnetic, thermal or electrostatic actuator.

A second aspect of the invention provides a MEMS device comprising: a gantry, a frame surrounding the gantry, and at least one actuator, in particular an actuator according to the first aspect or any implementation thereof, wherein a first end of the at least one actuator is connected to a plurality of sides of the frame, a second end of the at least one actuator is connected to the gantry by a joint, and the second end of the actuator is configured to bend upwards or downwards when the actuator is driven.

The connection of the two sides of the frame enables the actuator to provide different movements to the stage, in particular together with other actuators of the MEMS device, thereby enabling better space usage for a 2DOF MEMS device.

In an implementation of the second aspect, the first end of the at least one actuator is connected to two adjacent sides of the frame.

Thus, the actuators may be driven to provide different types of motion to the gantry, such as pitch and yaw.

In a further implementation of the second aspect, the MEMS device further comprises: a rotatable post disposed on top of the stage, and a mirror plate disposed on top of the rotatable post.

In a further implementation of the second aspect, the at least one actuator is arranged at least partially, in particular at least at its second end, below the mirror plate.

Accordingly, the MEMS device can be constructed more compactly, and/or the space given by the size of the MEMS device can be effectively utilized.

In a further implementation form of the second aspect, the frame is rectangular, the MEMS device comprises four actuators, in particular according to the first aspect or any one of its implementation forms, and each actuator has a first end connected to a different pair of adjacent sides of the rectangular frame and a second end connected to the gantry by a different joint.

In a further implementation of the second aspect, the four actuators are arranged symmetrically around the gantry.

In a further implementation of the second aspect, non-adjacent actuators are arranged on opposite sides of the gantry.

In a further implementation of the second aspect, the joint is a 2DOF joint.

In a further implementation of the second aspect, the MEMS device is configured to: all four actuators are driven simultaneously, in particular two adjacent actuators are driven to bend their second ends upwards, while two other adjacent actuators are driven to bend their second ends downwards.

This allows pairs of actuators to be driven to effect pitch and/or yaw of the gantry.

A third aspect of the invention provides a method for controlling a MEMS device according to the second aspect or any of its implementations, the method comprising: the stage of the MEMS device is tilted by driving a first pair of adjacent actuators to bend their second ends upward and a second pair of adjacent actuators to bend their second ends downward, or by driving a third pair of adjacent actuators to bend their second ends upward and a fourth pair of adjacent actuators to bend their second ends downward.

In an implementation form of the third aspect, the actuator is driven piezoelectrically, magnetically, thermally and/or electrostatically.

It has to be noted that all devices, elements, units and means described in the present application may be implemented in software or hardware elements or any kind of combination thereof. All steps performed by the various entities described in the present application, as well as the functions described as being performed by the various entities, are intended to mean that the respective entity is adapted to, or used to, perform the respective steps and functions. Even though in the following description of certain embodiments certain functions or steps performed by an external entity are not reflected in the description of certain detailed elements of the entity performing the certain steps or functions, it should be clear to a person skilled in the art that these methods and functions can be implemented in individual software or hardware elements or any kind of combination thereof.

Drawings

The above aspects and implementations of the invention are explained in the following description of specific embodiments with reference to the drawings, in which:

FIG. 1 illustrates an actuator according to an embodiment of the present invention.

FIG. 2 illustrates a MEMS device in accordance with an embodiment of the invention.

FIG. 3 illustrates a MEMS device in accordance with an embodiment of the invention.

FIG. 4 illustrates an actuator and other components of a MEMS device in accordance with an embodiment of the present invention.

Fig. 5 shows a method according to an embodiment of the invention.

Detailed Description

FIG. 1 illustrates an actuator 100 for a MEMS device 200 (see FIG. 2) according to an embodiment of the present invention. The actuator 100 is particularly configured to implement a 2DOF MEMS device.

The actuator 100 has two opposing ends 101 and 102. The first end 101 may be connected to a plurality of sides of the frame 201 of the MEMS device 200, in particular to two adjacent sides of the rectangular frame 201 of the MEMS device. Thus, the actuator 100, and in particular the first end 101 thereof, is provided with a determined shape to allow such a connection. For example, the actuator 100 may have an irregular trapezoidal shape as shown in fig. 1.

Second end 102 is connectable to a stage 202 of MEMS device 200, particularly via a joint 203. The second end 102 of the actuator 100 is configured to bend upwards or downwards when the actuator 100 is driven and when the first end 101 is particularly connected to the frame 201. In particular, the actuator 100 may be driven piezoelectrically, magnetically, thermally, and/or electrostatically.

FIG. 2 illustrates, in top view, a MEMS device 200 in accordance with an embodiment of the invention. The MEMS device 200 includes at least one actuator 100, such as shown in fig. 1. Illustratively, FIG. 2 shows a MEMS device 200 that includes four actuators 100 (labeled A, B, C and D), each actuator 100 being as shown in FIG. 1.

In addition to the at least one actuator 100, the MEMS device 200 includes a stage 202 and a frame 201 surrounding the stage 202. The first end 101 of each actuator 100 is connected to a plurality of sides of the frame 201, in particular to two adjacent sides of the rectangular frame 201, as shown in fig. 2. The second end 102 of each actuator 100 is connected to the stage 202 by a joint 203 of the MEMS device 200. The second end 102 of each actuator 100 may bend upward or downward when the actuator 100 is driven. This moves the stage 202 accordingly.

As shown in fig. 2, the actuators 100 may be symmetrically arranged around the gantry 202. Further, each joint 203 may be a 2DOF joint. By driving two adjacently disposed actuators 100 (e.g., a and B) to bend upward and two other adjacently actuators (e.g., C and D) to bend downward in the MEMS device 200, pitch and/or yaw of the gantry 202 can be achieved. Thus, the stage 202 can move in accordance with 2 DOF.

FIG. 3 illustrates, in side view, a MEMS device 200 in accordance with an embodiment of the present invention. The MEMS device 200 of FIG. 3 is based on the MEMS device 200 shown in FIG. 2. Accordingly, like elements are given like reference numerals and perform like functions. Fig. 3 shows in particular in (a) the MEMS device 200 when no actuator 100 is driven and in (b) the MEMS device 200 when two opposing actuators 100 are driven relative to each other.

Fig. 3 illustrates a specific 1D micromirror device. Thus, the rotatable support 300 is mounted in the center of the gantry 202 of the MEMS device 200, in particular on top of the gantry 202. The posts 300 support the mirror plate 301 at their upper ends, i.e. the mirror plate 301 is disposed on top of the rotatable posts 301. Two bendable actuators 100 (out of four) are shown in fig. 3, these actuators 100 being fixed at their outer (first) ends 101, respectively, to a frame 201 of a MEMS device 200. Further, their inner (second) ends 102 are connected to the gantry 200 by using joints 203.

Three main advantages are achieved by using this structure. First, even if the actuator 100 is provided with enough space (i.e., length) to achieve sufficient displacement of the stage 202, the ratio of the mirror plate 301 to the overall device size is relatively large. This displacement is shown in FIG. 3(b), where one actuator 100 is driven to bend upwards (to the left) and one actuator is driven to bend downwards (to the right), which results in the tilt of the stage 202, posts 300, and mirror plate 301. This is possible because the actuator 100 is partially hidden under the mirror plate 301. In other words, the actuators 100 are each arranged at least partially, in particular at least at their second ends 102, below the mirror plate 301. Second, the torque transmitted by the actuator 100 is applied to the joints 203 near the center of mass of the mirror plate 301 and the posts 300, so that it can be amplified using levers. Third, the incident light beam will not be reflected too much by the actuator 100, because the incident light will be mainly reflected by the surface of the mirror plate 301 due to the partial arrangement of the actuator 100 below the mirror plate 301.

Fig. 4 shows in (a) a top view of the MEMS device 200 shown in fig. 3 and in (b) a perspective side view of some components of the MEMS device 200. Fig. 4 specifically illustrates how the present invention is implemented to further optimize space utilization of the MEMS device 200 and achieve the 2DOF objective.

The actuator 100 shown in fig. 4(a) is constrained at its first end 101 to multiple sides of the frame 201, which is advantageous for 2 DOF. Actuators constrained to only one side of the frame 201 are only available for 1 DOF. Thus, such actuators are not suitable for pitch and yaw of the gantry 202. In a MEMS device with four such actuators, two actuators must always remain idle, while the other two actuators are used.

However, the MEMS device 200 shown in fig. 4 employs the actuator 100 fixed to both side sides of the frame 201, particularly the actuator 100 of an irregular trapezoidal shape. In this manner, in particular, in a MEMS device 200 having four actuators 100 as shown, all actuators 100 can be applied to pitch and yaw. For example, in FIG. 4, when the actuators 100 labeled A and B are driven upward while the actuators 100 labeled C and D are driven downward, the gantry 202 will tilt. When the actuators 100 labeled a and D are driven upward while the actuators 100 labeled B and C are driven downward, the gantry 202 will deflect. Thus, the actuators 100 are all 2DoF suitable.

The actuator 100 may be driven by, for example, piezoelectric, magnetic, thermal, or electrostatic principles. The example of the MEMS device 200 shown in fig. 4 is specific to the piezoelectric actuator 100. Furthermore, the joint 203 may be in particular a meandering joint, which may be made very elongated. Such an elongated meandering joint 203 helps to attenuate geometric non-linearities while the MEMS device 200 achieves large displacements of the gantry 202.

Fig. 4 shows in (b) the "horizontal plane" at which the rotatable post 301 may pierce the actuator 100 at both ends. The long tail of post 300 under actuator 100 can be used as a counterweight to avoid initial tilt when MEMS device 200 is mounted horizontally, where no tilt means the normal vector on mirror plate 301 is parallel to gravity.

Fig. 5 illustrates a method 500 according to an embodiment of the invention. The method 500 is used to control a MEMS device 200, for example, as shown in fig. 2-4, in which four actuators 100 are symmetrically arranged about a gantry 202. The MEMS device 200 may include a controller, such as a processor or other processing circuitry, to control the MEMS device 200 by implementing the method 500.

For pitching 501 the stage 202 of the MEMS device 200, the method 500 includes driving a first pair of adjacent actuators 100 to bend their second ends 102 upward and driving a second pair of adjacent actuators 100 to bend their second ends 102 downward. For deflecting 502 the stage 202 of the MEMS device 200, the method 500 includes driving a third pair of adjacent actuators 100 to bend their second ends 102 upward and driving a fourth pair of adjacent actuators 100 to bend their second ends 102 downward.

The invention has been described in connection with various embodiments by way of example and implementation. However, other variations will be understood and effected by those skilled in the art and practicing the claimed invention, from a study of the drawings, the disclosure, and the independent claims. In the claims as well as in the description, the word "comprising" does not exclude other elements or steps, and the indefinite article "a" or "an" does not exclude a plurality. A single element or other unit may fulfill the functions of several entities or items recited in the claims. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.

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