A MEMS sensor package comprises a MEMS die that includes a substrate having a sensor formed thereon and a cap layer coupled to the substrate. The cap layer has a cavity overlying a substrate region at which the sensor resides. A port extends between the cavity and a side wall of the MEMS die and enables admittance of fluid into the cavity. Fabrication methodology entails providing a substrate structure having sensors formed thereon, providing a cap layer structure having inwardly extending cavities, and forming a channel between pairs of the cavities. The cap layer structure is coupled with the substrate structure and each channel is interposed between a pair of cavities. A singulation process produces a pair of sensor packages, each having a port formed by splitting the channel, where the port is exposed during singulation and extends between its respective cavity and side wall of the sensor package.

A MEMS device is formed by applying a lower polymer film to top surfaces of a common substrate containing a plurality of MEMS devices, and patterning the lower polymer film to form a headspace wall surrounding components of each MEMS device. Subsequently an upper polymer dry film is applied to top surfaces of the headspace walls and patterned to form headspace caps which isolate the components of each MEMS device. Subsequently, the MEMS devices are singulated to provide separate MEMS devices.

A packaged micro-electro-mechanical system (MEMS) device (100) comprises a circuitry chip (101) attached to the pad (110) of a substrate with leads (111), and a MEMS (150) vertically attached to the chip surface by a layer (140) of low modulus silicone compound. On the chip surface, the MEMS device is surrounded by a polyimide ring (130) with a surface phobic to silicone compounds. A dome-shaped glob (160) of cured low modulus silicone material covers the MEMS and the MEMS terminal bonding wire spans (180); the glob is restricted to the chip surface area inside the polyimide ring and has a surface non-adhesive to epoxy-based molding compounds. A package (190) of polymeric molding compound encapsulates the vertical assembly of the glob embedding the MEMS, the circuitry chip, and portions of the substrate; the molding compound is non-adhering to the glob surface yet adhering to all other surfaces.

A packing structure including: a cap secured to at least one first substrate and forming at least one cavity between the cap and the first substrate; a layer of at least one first material permeable to a gas, arranged in the cap and/or in the first substrate and/or at the interface between the cap and the first substrate, and forming at least one part of a wall of the cavity; a portion of at least one second material non-permeable to said gas, the thickness of which is higher than or equal to that of the layer of the first material, and surrounding at least one first part of the layer of the first material forming said part of the wall of the cavity; an aperture passing through the cap or the first substrate and opening onto or into said part of the layer of the first material.

A MEMS sensor package comprises a MEMS die that includes a substrate having a sensor formed thereon and a cap layer coupled to the substrate. The cap layer has a cavity overlying a substrate region at which the sensor resides. A port extends between the cavity and a side wall of the MEMS die and enables admittance of fluid into the cavity. Fabrication methodology entails providing a substrate structure having sensors formed thereon, providing a cap layer structure having inwardly extending cavities, and forming a channel between pairs of the cavities. The cap layer structure is coupled with the substrate structure and each channel is interposed between a pair of cavities. A singulation process produces a pair of sensor packages, each having a port formed by splitting the channel, where the port is exposed during singulation and extends between its respective cavity and side wall of the sensor package.

The cap wafer for a MEMS device includes multiple electrically isolated electrodes that can be bonded and electrically connected to separate electrical contacts on a MEMS device wafer. The electrically isolated electrodes can be used for any of a variety of functions, such as for apply a force to a movable MEMS structure on the MEMS device wafer (e.g., for driving resonance of the movable MEMS structure or for adjusting a resonance or sense mode of the movable MEMS structure) or for sensing motion of a movable MEMS structure on the MEMS device wafer. Since the electrodes are electrically isolated, different electrodes may be used for different functions.

Packaged MEMS devices are described. One such device includes a substrate having an active surface with an integrated circuit. Two substrate pads are formed on the substrate; one pad is a closed ring pad. The device also includes a cap wafer with two wafer pads. One of these wafer pads is also a closed ring pad. A hermetic seal ring is formed by a first bonding between the two ring pads. The device has a gap between the substrate and the cap wafer. This gap may be filled with a pressurized gas. An electrical connection is formed by a second bonding between one substrate pad and one wafer pad. An electrical contact is disposed over the cap wafer. The device also includes an insulation layer between the electrical contact and the cap wafer. Methods of producing the packaged MEMS devices are also described.

The present disclosure provides a semiconductor device. The semiconductor device includes a first device and a second device disposed adjacent to the first device; a conductive pillar disposed adjacent to the first device or the second device; a molding surrounding the first device, the second device and the conductive pillar; and a redistribution layer (RDL) over the first device, the second device, the molding and the conductive pillar, wherein the RDL electrically connects the first device to the second device and includes an opening penetrating the RDL and exposing a sensing area over the first device.

An electronic device includes a substrate, a functional element that is arranged on the substrate, a terminal that is arranged on the substrate and that is electrically connected to the functional element, and a bonding wire that is connected to the terminal. The terminal has an alloy portion that is alloyed to the bonding wire at a connection portion between the terminal and the bonding wire, and the thickness of the terminal is larger than the thickness of the alloy portion. Moreover, the terminal is formed of the same material (silicon) as the functional element.

An integrated circuit packaging structure comprises at least one Micro Electrical Mechanical Systems (MEMS) gyroscope die mounted directly on a multi-layer flexible substrate having at least one metal layer and wire-bonded to the flexible substrate and a lid or die coating protecting the MEMS die and wire bonds.