A low-profile packaging structure for a microelectromechanical-system (MEMS) resonator system includes an electrical lead having internal and external electrical contact surfaces at respective first and second heights within a cross-sectional profile of the packaging structure and a die-mounting surface at an intermediate height between the first and second heights. A resonator-control chip is mounted to the die-mounting surface of the electrical lead such that at least a portion of the resonator-control chip is disposed between the first and second heights and wire-bonded to the internal electrical contact surface of the electrical lead. A MEMS resonator chip is mounted to the resonator-control chip in a stacked die configuration and the MEMS resonator chip, resonator-control chip and internal electrical contact and die-mounting surfaces of the electrical lead are enclosed within a package enclosure that exposes the external electrical contact surface of the electrical lead at an external surface of the packaging structure.

A semiconductor device has a first semiconductor die and a modular interconnect structure adjacent to the first semiconductor die. An encapsulant is deposited over the first semiconductor die and modular interconnect structure as a reconstituted panel. An interconnect structure is formed over the first semiconductor die and modular interconnect structure. An active area of the first semiconductor die remains devoid of the interconnect structure. A second semiconductor die is mounted over the first semiconductor die with an active surface of the second semiconductor die oriented toward an active surface of the first semiconductor die. The reconstituted panel is singulated before or after mounting the second semiconductor die. The first or second semiconductor die includes a microelectromechanical system (MEMS). The second semiconductor die includes an encapsulant and an interconnect structure formed over the second semiconductor die. Alternatively, the second semiconductor die is mounted to an interposer disposed over the interconnect structure.

Substrate is produced by using a MEMS technique to form multiple diaphragms in a substrate by forming piezoelectric material layer on one surface of the substrate and thereafter by forming openings in the substrate from the other surface of the substrate; substrate and substrate on which signal detection circuit is formed are aligned to each other using at least one of multiple diaphragms as alignment diaphragm; and substrate and substrate are bonded together.

Disclosed herein are microelectronic assemblies including microelectronic components coupled by direct bonding, and related structures and techniques. In some embodiments, a microelectronic assembly may include a first microelectronic component including a first guard ring extending through at least a portion of a thickness of and along a perimeter; a second microelectronic component including a second guard ring extending through at least a portion of a thickness of and along a perimeter, where the first and second microelectronic components are coupled by direct bonding; and a seal ring formed by coupling the first guard ring to the second guard ring. In some embodiments, a microelectronic assembly may include a microelectronic component coupled to an interposer that includes a first liner material at a first surface; a second liner material at an opposing second surface; and a perimeter wall through the interposer and connected to the first and second liner materials.

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.

In one example, an electronic device includes a semiconductor sensor device having a cavity extending partially inward from one surface to provide a diaphragm adjacent an opposite surface. A barrier is disposed adjacent to the one surface and extends across the cavity, the barrier has membrane with a barrier body and first barrier strands bounded by the barrier body to define first through-holes. The electronic device further comprises one or more of a protrusion pattern disposed adjacent to the barrier structure, which can include a plurality of protrusion portions separated by a plurality of recess portions; one or more conformal membrane layers disposed over the first barrier strands; or second barrier strands disposed on and at least partially overlapping the first barrier strands. The second barrier strands define second through-holes laterally offset from the first through-holes. Other examples and related methods are also disclosed herein.

Microelectromechanical (MEMS) devices and associated methods are disclosed. Piezoelectric MEMS transducers (PMUTs) suitable for integration with complementary metal oxide semiconductor (CMOS) integrated circuit (IC), as well as PMUT arrays having high fill factor for fingerprint sensing, are described.

A semiconductor sensor, comprising a gas-sensing device and an integrated circuit is provided. The gas-sensing device includes a substrate having a sensing area and an interconnection area in the vicinity of the sensing area, an inter-metal dielectric (IMD) layer formed above the substrate in the sensing area and in the interconnection area, and an interconnect structure formed in the interconnection area; further includes a sensing electrode, a second TiO.sub.2-patterned portion, and a second Pt-patterned portion on the second TiO.sub.2-patterned portion in the sensing area. The interconnect structure includes a tungsten layer buried in the IMD layer, wherein part of a top surface of the tungsten layer is exposed by at least a via. The interconnect structure further includes a platinum layer formed in said at least the via, a TiO.sub.2 layer formed on the IMD layer, a first TiO.sub.2-patterned portion and a first Pt-patterned portion.

An adaptive MEMS device includes a MEMS microphone and integrated circuitry, wherein the integrated circuitry is electrically connected to the MEMS microphone. The integrated circuitry reads out an output signal from the MEMS microphone and provides the output signal or a rendered output signal, via a first integrated interface, to an external processing device. Additionally, the integrated circuitry determines, at run-time, diagnostic data on the current condition of the MEMS device and provides, at run-time, the diagnostic data, via a second integrated interface, to the external processing device.

A microelectromechanical system (MEMS) semiconductor device has a first and second semiconductor die. A first semiconductor die is embedded within an encapsulant together with a modular interconnect unit. Alternatively, the first semiconductor die is embedded within a substrate. A second semiconductor die, such as a MEMS die, is disposed over the first semiconductor die and electrically connected to the first semiconductor die through an interconnect structure. In another embodiment, the first semiconductor die is flip chip mounted to the substrate, and the second semiconductor die is wire bonded to the substrate adjacent to the first semiconductor die. In another embodiment, first and second semiconductor die are embedded in an encapsulant and are electrically connected through a build-up interconnect structure. A lid is disposed over the semiconductor die. In a MEMS microphone embodiment, the lid, substrate, or interconnect structure includes an opening over a surface of the MEMS die.