A display panel and device are provided. The display panel comprises a cover glass, a first light modulating layer is disposed on the cover glass, the first light modulating layer includes at least two first microstructures, the first microstructures are configured for increasing a scattering rate of a ambient light, and a second light modulating layer is disposed on the first light modulating layer, the second light modulating layer includes at least two first microstructures spaced from each other, the second microstructures are configured for increasing a transmittance of the ambient light.

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.

The present invention generally relates to an ovenized platform and a fabrication process thereof. Specifically, the invention relates to an ovenized hybrid Si/SiO.sub.2 platform compatible with typical CMOS and MEMS fabrication processes and methods of its manufacture. Embodiments of the invention may include support arms, CMOS circuitry, temperature sensors, IMUs, and/or heaters among other elements.

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.

Alignment features formed on a cover substrate allow for a second substrate to be bonded to the cover substrate while ensuring that the second substrate is not titled with respect to a plane defined by the alignment features. Die attachment material is patterned such that it deforms or flows underneath the second substrate while allowing corners of the second substrate to rest on landing areas that are elevated above the top surface of the cover substrate. Some of the landing areas may include additional features that are elevated above the landing areas to form notches which constrain the rotational position of the second in addition to its tilt.

A method of forming a monocrystalline nitinol film on a single crystal silicon wafer can comprise depositing a first seed layer of a first metal on the single crystal silicon wafer, the first seed layer growing epitaxially on the single crystal silicon wafer in response to the depositing the first seed layer of the first metal; and depositing the monocrystalline nitinol film on a final seed layer, the monocrystalline nitinol film growing epitaxially on the final seed layer in response to the depositing the monocrystalline nitinol film. The method can form a multilayer stack for a micro-electromechanical system MEMS device.

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.

MEMS packages, modules, and methods of fabrication are described. In an embodiment, a MEMS package includes a MEMS die and an IC die mounted on a front side of a surface mount substrate, and a molding compound encapsulating the IC die and the MEMS die on the front side of the surface mount substrate. In an embodiment, a landing pad arrangement on a back side of the surface mount substrate forms and anchor plane area for bonding the surface mount substrate to a module substrate that is not directly beneath the MEMS die.

Aspects of the disclosure provide a waterproof packaging technique for fabricating waterproof microphones in mobile devices. A device based on the waterproof packaging technique can include a microelectromechanical system (MEMS) device, a housing enclosing the MEMS device, and a liquid-resistant air inlet passive device (LRAPD) on the housing. The LRAPD can include at least one channel connecting an exterior of the housing with a chamber formed between the housing and the MEMS device. An inside surface of the channel can be coated with a liquid-repellant coating. In some examples, the liquid-repellant coating can be a self-assembled monolayer (SAM) coating.

Aspects of the disclosure provide a packaging technique for making a directional microphone which employs mechanical structures to cancel undesired background noise to realize the directional function instead of an extra sensor required in electronic noise-cancelling techniques, thus reducing footprint and cost of a directional microphone. A directional microphone based on this technique can include an acoustic sensor and a housing enclosing the acoustic sensor. The acoustic sensor can include a sensing diaphragm, a cavity below the sensing diaphragm, and a first substrate. The directional microphone device can further includes a channel with an inlet open at an edge of the first substrate and an outlet connected with the cavity. The housing can include a cover attached to a second substrate supporting the first substrate. The cover can include a first opening over the sensing diaphragm and a second opening at a side of the cover.