A package includes a base structure, which has an electrically isolating material and/or an electrically conductive contact structure, an electronic component, which is embedded in the base structure or is arranged on the base structure, a microelectromechanical system (MEMS) component, and a cover structure, which is mounted on the base structure for at least partially covering the MEMS component.

A capped micromachined device has a movable micromachined structure in a first hermetic chamber and one or more interconnections in a second hermetic chamber that is hermetically isolated from the first hermetic chamber, and a barrier layer on its cap where the cap faces the first hermetic chamber, such that the first hermetic chamber is isolated from outgassing from the cap.

A hermetically sealed component may comprise a glass substrate, a device with at least one electrical port associated with the glass substrate, and a glass cap. The glass cap may have at least one side wall. The glass cap may have a shaped void extending therethrough, from top surface of the glass cap to bottom surface of glass pillar. An electrically conductive plug may be disposed within the void, the plug configured to hermetically seal the void. The electrically conductive plug may be electrically coupled to the electrical port. The glass cap may be disposed on the glass substrate, with the at least one side wall disposed therebetween, to form a cavity encompassing the device. The side wall may contact the glass substrate and the glass cap to provide a hermetic seal, such that a first environment within the cavity is isolated from a second environment external to the cavity.

A resonance device that includes a MEMS substrate that includes a resonator, a top cover having a silicon oxide film on a surface thereof that faces the MEMS substrate, and a bonding part that bonds the MEMS substrate and the top cover to each other so as to seal a vibration space of the resonator. The silicon oxide film includes a through hole that is formed along at least part of the periphery of the vibration space when the top cover is viewed in a plan view and that penetrates to a surface of the top cover. The through hole includes a first metal layer.

A pressure sensor and a packaging method thereof. The pressure sensor comprises: a sensitive chip, which comprises a thin-wall part and a supporting part connected to the periphery of the thin-wall part, the supporting part being provided with an electrode; a sealing element, which is fitted over the sensitive chip and partially surrounds together with the sensitive chip to form a sealing cavity, the sealing element being provided with a through hole corresponding to the electrode; a conductive component, which is provided in the through hole in a sealed mode and electrically connected to the electrode, the conductive component and the sealing element being arranged in an insulating mode, and the conductive component comprising a filling part and a leading-out part embedded in the filling part.

Provided are an electrical interconnection structure, an electronic apparatus and manufacturing methods therefor, which can provide a reliable electrical interconnection structure between the MEMS apparatus and an external circuit while sealing and encapsulating the MEMS device. The electrical interconnection structure includes: a bonding metal; a first dielectric layer and a second dielectric layer. The first dielectric layer includes a first through hole penetrating the first dielectric layer and exposing the bonding metal. The first through hole is filled with a first conductive material electrically connected to the bonding metal. The second dielectric layer includes a second through hole. An orthographic projection of second conductive material in the second through hole covers an orthographic projection of first conductive material in the first through hole onto the plane of the base. The second through hole is filled with a second conductive material electrically connected to the first conductive material.

A microelectromechanical system (MEMS) device may include a MEMS structure over a first substrate. The MEMS structure comprises a movable element. Depositing a first conductive material over the first substrate and etching trenches in a second substrate. Filling the trenches with a second conductive material and depositing a third conductive material over the second conductive material and the second substrate. Bonding the first substrate and the second substrate and thinning a backside of the second substrate which exposes the second conductive material in the trenches.

A semiconductor device package includes a semiconductor device, a non-semiconductor substrate over the semiconductor device, and a first connection element extending from the semiconductor device to the non-semiconductor substrate and electrically connecting the semiconductor device to the non-semiconductor substrate.

A device including a first layer, a MEMS component and/or an ASIC component on the first layer, and a second layer having a cavity receiving the MEMS component and/or the ASIC component. The second layer has a feedthrough for transmission of at least one of an electrical signal, an electromagnetic signal, a fluid, and a force.

A component (B) comprising a carrier (TR), on which a functional structure (FS) is covered by a thin-layer covering (DSA) spanning across and resting on the carrier. On a planarization layer arranged above the thin-layer covering (DSA), a wiring level (M1, M2) is realized, which comprises structured conductor paths and which is connected via through-connections to the functional structure (FS).