Abstract: A micro electromechanical system (MEMS) spring element is disposed on a substrate, and includes a fixing portion and a moveable portion. The fixing portion is fixed on the substrate, and includes an insulating layer, a plurality of metal-fixing layers and a plurality of supporting-fixing layers. The insulating layer is disposed on the substrate. The metal-fixing layers are disposed above the insulating layer. The supporting-fixing layers are connected between the metal-fixing layers. The moveable portion has a first end and a second end. The first end is connected with the fixing portion, and the second end is suspended above the substrate. The moveable portion includes a plurality of metal layers and at least a supporting layer. The supporting layer is connected between the adjacent metal layers, and a hollow region is formed between the supporting layer and the adjacent metal layers.

Abstract: The present invention proposes a MEMS chip and a package method thereof. The package method comprises: making a capping wafer by: providing a first substrate and forming an etch stop layer on the first substrate; making a device wafer by: providing a second substrate and forming a MEMS device and a material layer surrounding the MEMS device on the second substrate; bonding the capping wafer and the device wafer; after bonding, etching the first substrate to form at least one via; etching the etch stop layer through the via; etch the material layer; and forming a sealing layer on the first substrate.

Abstract: A micro-electro mechanical system (MEMS) is disclosed, which comprises a substrate; at least one transistor formed on the substrate and electrically connected with a contact plug; at least one MEMS device; and a local interconnection line at the same level of the contact plug, through which the MEMS device is coupled to the transistor.

Abstract: The present invention discloses a 3D information generator for use in an interactive interface. The 3D information generator includes: a MEMS light beam generator having at least one light source for providing a dot light beam and a MEMS mirror for projecting a movable scanning light beam according to the dot light beam to an object; an image sensor for sensing an image of the object to generate a 2D image information; and a processor for generating a distance information by triangulation method according to a reflection result of the scanning light beam scanning on the object, wherein the distance information is combined with the 2D image information to generate a 3D information.

Abstract: An electronic device includes a housing, an optical touch module, and a detecting unit. The housing includes a first body and a second body, and an angle is formed between the first body and the second body. The optical touch module executes a positioning function by sensing signals. The detecting unit is configured to the optical touch module, and is used for detecting the angle. When the angle is smaller than a predetermined angle, the detecting unit instructs the optical touch module to pause executing the positioning function, so as to avoid false position determinations by the optical touch module.

Abstract: The present invention discloses a MEMS (Micro-Electro-Mechanical System, MEMS) accelerator with enhanced structural strength. The MEMS accelerator is located on a substrate, and it includes: multiple springs, wherein each spring includes: an anchor, fixed on the substrate; an extensible part, which has a fixed end fixed on the anchor, and a free end floating above the substrate; a proof mass, connected to the free ends of the springs; and multiple in-plane sense electrodes, wherein the extensible part is folded back and forth to form a substantially polygon shape as a whole, in which the fixed end is located within the middle one third length of one side of the substantially polygon shape, and the free end is located within the middle one third length of an opposite side of the substantially polygon shape.

Abstract: The present invention discloses a micro-electro-mechanical system (MEMS) device, comprising: a substrate with at least one opening; and a membrane supported on the substrate, the membrane including at least two thin segments and a thick segment connected together, wherein the two thin segments are not at the same level, and the thick segment is formed by a plurality of layers including at least two metal layers and a via layer, such that the membrane has a curve cross section.

Abstract: The present invention discloses a MEMS (Micro-Electro-Mechanical System) integrated chip with cross-area interconnection, comprising: a substrate; a MEMS device area on the substrate; a microelectronic device area on the substrate; a guard ring separating the MEMS device area and the microelectronic device area; and a conductive layer on the surface of the substrate below the guard ring, or a well in the substrate below the guard ring, as a cross-area interconnection electrically connecting the MEMS device area and the microelectronic device area.

Abstract: A light source is used for emitting an invisible light toward an object. The object reflects the invisible light and reflected light is formed, and a sensor is used for receiving the reflected light. A processor is coupled to the sensor for recording a time interval of the invisible light traveling from the light source to the object and reflected from the object to the sensor. Then, the processor estimates a measurement distance of the object according to the time interval, and adjusts an emission period of the light source, an exposure period of the sensor, intensity of the invisible light, and/or main sensing range of the sensor according to the measurement distance.

Abstract: The present invention discloses a MEMS (Micro-Electro-Mechanical System) integrated chip with cross-area interconnection, comprising: a substrate; a MEMS device area on the substrate; a microelectronic device area on the substrate; a guard ring separating the MEMS device area and the microelectronic device area; and a conductive layer on the surface of the substrate below the guard ring, or a well in the substrate below the guard ring, as a cross-area interconnection electrically connecting the MEMS device area and the microelectronic device area.

Abstract: The present invention discloses an MEMS sensor and a method for making the MEMS sensor. The MEMS sensor according to the present invention includes: a substrate including an opening; a suspended structure located above the opening; and an upper structure, a portion of which is at least partially separated from a portion of the suspended structure; wherein the suspended structure and the upper structure are separated from each other by a step including metal etch.

Abstract: According to the present invention, a micro-electro-mechanical system (MEMS) device comprises: a thin film structure including at least a metal layer and a protection layer deposited in any order; and a protrusion connected under the thin film structure. A preferred thin film structure includes at least a lower protection layer, a metal layer and an upper protection layer. The MEMS device for example is a capacitive MEMS acoustical sensor.

Abstract: The present invention discloses a MEMS lithography mask with improved tungsten deposition topography and a method for making the same. The MEMS lithography mask includes: a pattern including at least two sections forming a conjunction with each other, each of the at least two sections having a width not less than a minimum width, the conjunction having a center and a plurality of corners, wherein at least one of the corners is inwardly recessed to reduce a width of the conjunction, the sections being for defining trenches on a substrate to be filled with tungsten as apart of a MEMS device, whereby the lowest height of the tungsten surface is not lower than 80% of the trench height.

Abstract: According to the present invention, an in-plane sensor comprises: a fixed structure including a fixed finger and a fixed column connected to each other, the fixed finger having a supported end supported by the fixed column and a suspended end which is unsupported; and a movable structure including at least one mass body and an extending finger connected to each other; wherein the supported end of the fixed finger is closer to the mass body than the suspended end is.

Abstract: The present invention proposes a MEMS chip and a package method thereof. The package method comprises: making a capping wafer by: providing a first substrate and forming an etch stop layer on the first substrate; making a device wafer by: providing a second substrate and forming a MEMS device and a material layer surrounding the MEMS device on the second substrate; bonding the capping wafer and the device wafer; after bonding, etching the first substrate to form at least one via; etching the etch stop layer through the via; etch the material layer; and forming a sealing layer on the first substrate.

Abstract: According to the present invention, a micro-electro-mechanical system (MEMS) device comprises: a thin film structure including at least a metal layer and a protection layer deposited in any order; and a protrusion connected under the thin film structure. A preferred thin film structure includes at least a lower protection layer, a metal layer and an upper protection layer. The MEMS device for example is a capacitive MEMS acoustical sensor.

Abstract: The present invention proposes a MEMS chip and a package method thereof. The package method comprises; making a capping wafer by: providing a first substrate and forming an etch stop layer on the first substrate; making a device wafer by: providing a second substrate and forming a MEMS device and a material layer surrounding the MEMS device on the second substrate; bonding the capping wafer and the device wafer; after bonding, etching the first substrate to form at least one via; etching the etch stop layer through the via; etch the material layer; and forming a sealing layer on the first substrate.

Abstract: According to the present invention, an in-plane sensor comprises: a fixed structure including a fixed finger and a fixed column connected to each other, the fixed finger having a supported end supported by the fixed column and a suspended end which is unsupported; and a movable structure including at least one mass body and an extending finger connected to each other; wherein the supported end of the fixed finger is closer to the mass body than the suspended end is.

Abstract: The present invention discloses an MEMS sensor and a method for making the MEMS sensor. The MEMS sensor according to the present invention comprises: a substrate including an opening; a suspended structure located above the opening; and an upper structure, a portion of which is at least partially separated from a portion of the suspended structure; wherein the suspended structure and the upper structure are separated from each other by a step including metal etch.

Abstract: A 3-dimensional MEMS sensor, comprising: a first axis fixed electrode; a second axis fixed electrode; a third axis fixed electrode; a movable electrode frame including a first axis movable electrode, a second axis movable electrode, a third axis movable electrode, and a connection part connecting the movable electrodes, wherein the first axis movable electrode and the first axis fixed electrode form a first capacitor along the first axis, the second axis movable electrode and the second axis fixed electrode form a second capacitor along the second axis, and the third axis movable electrode and the third axis fixed electrode form a third capacitor along the third axis, the connection part including a center mass, wherein the center mass is at least connected with one of the first, second and third axis movable electrodes, and has an outer periphery and a first interconnecting segment connecting at least two adjacent sides of the outer periphery; at least one spring connecting with the movable electrode frame;