An electronic device includes a package including an opening, and a cavity communicating with the opening, a pressure sensor element disposed in the cavity, and a waterproof unit is disposed in the package so as to cover the opening, in which the waterproof unit includes a through hole that is a separate body from the package, blocks passing of liquid, and permits passing of gas from an outside of the package into an inside of the cavity.

A flip chip pressure sensor assembly. The flip chip pressure sensor assembly comprises a substrate; a pressure sensor die comprising a sensing diaphragm, the die having a top side and a bottom side that is reverse to the top side, where the top side of the die is electrically connected to the substrate by flip chip mounting technology; a cover defining an aperture disposed over the pressure sensor die, where the aperture defined by the cover aligns with the sensing diaphragm to provide a path for pressure to be transmitted through the aperture to the bottom side of the sensing diaphragm; and a gel disk disposed within the aperture in intimate contact with a bottom side of the sensing diaphragm, where the gel disk is domed above an outer shoulder of a rim defined by the cover.

Provided is a pressure sensor including a substrate having a cavity therein, a partition wall disposed in the substrate to surround the cavity, a substrate insulation layer disposed on the top surface of the substrate to cover the cavity, a sensing unit disposed on the substrate insulation layer, and an encapsulation layer disposed on the substrate insulation layer to cover the sensing unit. The cavity may extend from a top surface toward a bottom surface of the substrate, the partition wall may have an inner sidewall exposed by the cavity, and at least a portion of the sensing unit may overlap the cavity when viewed in a plan view.

A packaged pressure sensor, comprising: a MEMS pressure-sensor chip; and an encapsulating layer of elastomeric material, in particular PDMS, which extends over the MEMS pressure-sensor chip and forms a means for transferring a force, applied on a surface thereof, towards the MEMS pressure-sensor chip.

When a main body of a sensor chip (1) is in a grounded state, a shield layer (71) constituting a shield electrode formed on a circuit layer (72) is grounded through a resistor (46).

A double diaphragm type pressure sensor includes a metal container having a concave portion; a pressure sensor unit mounted on a bottom of the container; a metal diaphragm airtightly bonded to an opening portion of the concave portion of the container; a pressure transmission medium filling a space formed by the metal diaphragm and the concave portion of the container; and a metal terminal penetrating the bottom of the container and being electrically insulated from the container.

A pressure sensor has a substrate having a diaphragm, a cavity portion that is positioned on one side of the diaphragm, and a ceiling portion that is disposed opposite to the diaphragm via the cavity portion, and unevenness is formed on a surface of the substrate facing the cavity portion. In addition, the unevenness has a plurality of recessed portions.

The invention provides a combo MEMS device. The combo MEMS device includes a substrate, a device layer, a cap, and at least two sensor units. The device layer is on the substrate. The cap is on the device layer. At least two sensor units which are adjacent to each other are both formed by the substrate, the device layer, and the cap. The first sensor unit includes a sealed space, and the second sensor unit includes a membrane and a semi-sealed space. The membrane is formed by reducing a thickness of a portion of the device layer. The semi-sealed space is formed between the substrate and the device layer or between the device layer and the cap, to receive an external pressure through an external pressure communication opening. The external pressure communication opening is formed between the substrate and the device layer, or between the device layer and the cap, or between the substrate and the cap.

An integrated device package is disclosed. The integrated device package can include a packaging structure defining a cavity. An integrated device die can be disposed at least partially within the cavity. A gel can be disposed within the cavity surrounding the integrated device. A portion of the gel can be disposed between a lower surface of the integrated device die and an upper surface of the packaging structure within the cavity.

Systems and methods for an internally switched multiple range transducer are provided. In one embodiment, a method comprises receiving, at a first sensor, a pressure, wherein the first sensor is associated with a first pressure range; measuring, at the first sensor, the pressure to generate a first pressure signal; in response to determining that the first pressure signal is not associated with the first pressure range, activating a second sensor, wherein the second sensor is associated with a second pressure range that is different from the first pressure range; and measuring, at the second sensor, the pressure to generate a second pressure signal.