The present invention disclosed a micro acoustic collector with a lateral cavity, comprising: a base metal layer; a movable film, an annular side wall; a lateral metal layer. The movable film faces towards the base metal layer to form a hollow space. The lateral metal layer is formed at a side of the movable film and around the movable film, fixed by the annular side wall and spaced apart from peripheral of the movable film by a distance, and the lateral metal layer faces towards the base metal layer to form a lateral cavity to assist an acoustic collection.

Provided herein is a method including forming a cavity in a first side of a first silicon wafer. An oxide layer is formed on the first side and in the cavity. The first side of the first silicon wafer is bonded to a first side of a second silicon wafer, and a gap control structure is deposited on a second side of the second silicon wafer. A MEMS structure is formed in the second silicon wafer. The second side of the second silicon wafer is eutecticly bonded to the third silicon wafer, and the eutectic bonding includes pressing the second silicon wafer to the third silicon wafer.

An electrooptical device includes a first metal layer disposed spaced apart from a first surface of a substrate and including a mirror, which modulates light, and a mirror support post, which has a tubular shape and protrudes from the mirror toward the substrate. The first metal layer is formed by forming a metal layer on a surface of a sacrificial layer having an opening, patterning the metal layer, and removing the sacrificial layer. Thus, the mirror support post is formed so as to extend over the inner wall of the opening. Here, the mirror support post has a thickness of not less than 1.5 times the length of the mirror support post.

Three-dimensional micro devices usable as electromagnetic and magnetomechanical energy converters, as micromagnetic motors or generators, and methods for their production. The three-dimensional micro devices exhibit high efficiency even at dimensions on the microscale and below, and the method for production, as well as mass production, is simple and economical. Moreover, the three-dimensional micro devices at least include one three-dimensional device produced using roll-up technology. This three-dimensional device includes all functional and structural components for full functionality. At least one functional or structural component is an element that is at least partially freely movable at least partially within a surrounding element and is arranged such that it can be rotated at least around one of its axes.

A micromechanical pressure sensor device including a semiconductor base substrate of a first doping type on which an intermediate layer of the first doping type is situated, a cavity sealed by a sealing layer of a second doping type and including a reference pressure, a first grating of the second doping type, suspended inside the cavity on a buried connection region of the second doping type, the buried connection region laterally extending away from the cavity into the semiconductor base material, a second grating of the second doping type, situated on a side of the diaphragm region pointing to the cavity and suspended on the diaphragm region, the first grating and the second grating being electrically insulated from each other and forming a capacitance, a first connection electrically connected to the first grating via the buried connection region, and a second connection electrically connected to the second grating.

A digital micromirror device comprises an array of micromirror pixels, the array comprising a first micromirror pixel and a second micromirror pixel. The first micromirror pixel comprises a hinge, where the hinge is configured to tilt toward a first raised address electrode and toward a second raised address electrode. The first micromirror pixel also comprises a first micromirror coupled to the hinge, where the first micromirror has a sculpted edge. The second micromirror pixel comprises a second micromirror, where a first gap between a first point on the sculpted edge and a nearest point to the first point on the second micromirror is larger than a second gap between a second point on the sculpted edge and a nearest point to the second point on the second micromirror.

A microphone device includes a substrate having a first surface, a wall disposed on the first surface, a microelectromechanical systems (MEMS) transducer, and an integrated circuit. Both the MEMS transducer and the integrated circuit are mounted on the first surface of the wall. The wall separates the MEMS transducer from the integrated circuit and acoustically isolates the MEMS transducer from the integrated circuit. The microphone device additionally includes a first set of wires extending through the wall and electrically connecting the MEMS transducer to the integrated circuit. The microphone device further includes a second set of wires electrically connecting the integrated circuit to a conductor on the substrate.

A microelectromechanical (MEMS) resonator includes a spring-mass system having a first weight portion (M1), a second weight portion (M2), and a central spring portion (SP) in between the weight portions.

A MEMS sensor includes a proof mass that is suspended over a substrate. A sense electrode is located on a top surface of the substrate parallel to the proof mass, and forms a capacitor with the proof mass. The sense electrodes have a plurality of slots that provide improved performance for the MEMS sensor. A measured value sensed by the MEMS sensor is determined based on the movement of the proof mass relative to the slotted sense electrode.

This MEMS beam structure that elastically supports a movable section displaced in a first direction includes: a first beam section and a second beam section extending in a second direction orthogonal to the first direction; and a linking section that connects the tip of the first beam section and the tip of the second beam section that is connected to the movable section, wherein the first beam section and the second beam section each have a shape as a beam of uniform strength, and the beam section root of the second beam section is displaced relatively in the first direction with respect to the beam section root of the first beam section according to the displacement of the movable section in the first direction.