The invention specifies an electronic component which has a first electrode (10), a second electrode (20), an active region (30), which is electrically coupled to the first electrode (10) and to the second electrode (20), and a housing (100), wherein the housing (100) contains carbon layers which are monoatomic at least in subregions.

A micro-electro-mechanical system (MEMS) microphone package is provided in the present disclosure. The MEMS microphone package includes a circuit board, an electromagnetic shielding cover mounted on the circuit board to define an accommodating space, electronic components received in the accommodating space and electrically connected to the circuit board, and a shielding ring covering a joint between the electromagnetic shielding cover and the circuit board. The shielding ring is configured for preventing electromagnetic waves from entering the accommodating space via the joint between the electromagnetic shielding cover and the circuit board.

The MEMS microphone includes a first circuit board; a second circuit board keeping a distance from the first circuit board; a frame located between the first circuit board and the second circuit board for forming a cavity cooperatively with the first circuit board and the second circuit board, the frame including a plated-through-hole; an ASIC chip located in the cavity; and an MEMS chip having a back cavity. The first circuit board is electrically connected with the second circuit board by the plated-through-hole. The frame includes a conductive layer and an insulating layer, and the conductive layer is located between an inner surface of the frame and the insulating layer.

A structure for preventing charge induced leakage of a semiconductor device includes a shield separated from a first interconnect by at least a first lateral spacing and separated from a second interconnect by at least a second lateral spacing. The first interconnect is connected to a first junction and the second interconnect is connected to a second junction. A shield bias is connected to the shield to terminate an electromagnetic field on the shield. The shield between the first and second lateral spacings has a minimum width to substantially prevent formation of a conductive channel between the first and second junctions. The shield may be formed over a portion of the first junction and over a portion of the second junction to substantially prevent formation of another conductive channel between the first and second junctions at a location that does not have the first and second lateral spacings.

A semiconductor device has a base substrate having a plurality of metal traces and a plurality of base vias. An opening is formed through the base substrate. At least one die is attached to the first surface of the substrate and positioned over the opening. A cover substrate has a plurality of metal traces. A cavity in the cover substrate forms side wall sections around the cavity. The cover substrate is attached to the base substrate so the at least one die is positioned in the interior of the cavity. Ground planes in the base substrate are coupled to ground planes in the cover substrate to form an RF shield around the at least one die.

A base plate with a first side having an elevated portion, a recessed portion laterally surrounding the elevated portion, and a vertical face extending from the recessed portion to the elevated portion is provided. At least a part of the vertical face is covered with a metal layer. A mold compound structure is formed on the first side with the metal layer disposed between the first side and the mold compound structure such that the mold compound structure includes an elevated portion laterally surrounding a recessed portion, and opposing edge faces that vertically extend from the recessed portion to the elevated portion. At least a part of the base plate is subsequently removed such that the recessed portion of the mold compound structure is uncovered from the base plate and such that the metal layer remains on at least one uncovered section of the mold compound structure.

Embodiments of the application provide a MEMS chip and an electrical packaging method for a MEMS chip. The MEMS chip includes a MEMS device layer, a first isolating layer located under the MEMS device layer, and a first conducting layer located under the first isolating layer. At the first isolating layer, there are a corresponding quantity of first conductive through holes in locations corresponding to conductive structures in a first region and in locations corresponding to electrodes in a second region. At the first conducting layer, there are M electrodes spaced apart from one another, and the M electrodes are respectively connected to M of the first conductive through holes. At the first conducting layer, electrodes in locations corresponding to at least some of the conductive structures in the first region are electrically connected in a one-to-one correspondence to electrodes in locations corresponding to at least some of the electrodes in the second region.

For a small sensor produced through a MEMS process, when an electrode pad, wiring, or a shield layer is formed in a final step, it is difficult to nondestructively investigate whether a structure for sensing a physical quantity has been processed satisfactorily. In the present invention, in a physical quantity sensor formed from an MEMS structure, in a structure in which a surface electrode having through wiring is formed on the surface of an electrode substrate and the periphery thereof is insulated, forming a shield layer comprising a metallic material on the surface of the electrode substrate in a planar view and providing a space for internal observation inside the shield layer makes it possible to check for internal defects.

In an embodiment a system includes a sensor including a base having a base electrode and a first membrane suspended above the base, wherein the first membrane has a first membrane electrode, wherein the first membrane is configured to deflect with respect to the base electrode in response to an environmental condition, and wherein the sensor is configured to measure a capacitance between the base electrode and the first membrane electrode. The system further includes a first device of the system configured to generate electrical interference signals, a first electrically conductive shield layer positioned between the sensor and the first device of the system, wherein the first electrically conductive shield layer defines a plurality of first apertures extending through the first electrically conductive shield layer and a dielectric material disposed in the plurality of first apertures.

The invention relates to antenna apparatus comprising: an antenna, a signal conductor and one or more RF MEMS switches, the antenna being conductively connected to the signal conductor, the MEMS switches and at least a portion of the signal conductor being supported by a crystalline MEMS substrate; and a capping substrate comprising a capping portion, wherein an enclosed volume is formed around the said MEMS switches between the capping portion and at least a portion of the crystalline MEMS substrate, and wherein the capping substrate comprises the said antenna.