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.

A semiconductor device includes a first region; a second region that is peripheral to the first region; a substrate having a first surface and a second surface arranged opposite to the first surface; a stress-sensitive sensor disposed in the first region at the first surface of the substrate; a back end of line (BEOL) stack disposed on the first surface of the semiconductor chip that extends laterally from the MEMS element, in the first region, into the second region; a first cavity formed in the BEOL stack that exposes the sensitive area of the stress-sensitive sensor, wherein the first cavity extends entirely through the BEOL stack over the first region thereby exposing a sensitive area of the stress-sensitive sensor; and at least one stress-decoupling trench laterally spaced from the stress-sensitive sensor and laterally spaced from the first cavity with a portion of the BEOL stack interposed between.

[Object] To provide an electronic device, a part mounting board, and an electronic apparatus that are capable of preventing warpage of a board from occurring. [Solving Means] An electronic device according to an embodiment of the present technology includes a first circuit board and a second circuit board. The first circuit board includes a first main surface, a second main surface, and a plurality of external terminals. The plurality of external terminals include a first terminal group located at an outermost periphery of the first main surface, and are arranged on the first main surface in a matrix pattern. The second circuit board includes a terminal surface facing the second main surface, and a plurality of connection terminals. The plurality of connection terminals include a second terminal group that is arranged on the terminal surface and faces at least a part of the first terminal group, and are electrically connected to the second main surface.

A method for manufacturing a MEMS unit for a micromechanical pressure sensor. The method includes the steps: providing a MEMS wafer including a silicon substrate and a first cavity formed therein, under a sensor membrane; applying a layered protective element on the MEMS water; and exposing a sensor core from the back side, a second cavity being formed between the sensor core and the surface of the silicon substrate, and the second cavity being formed with the aid of an etching process which is carried out with the aid of etching parameters changed in a defined manner; and removing the layered protective element.

A stress-isolated microelectromechanical systems (MEMS) device and a method of manufacture of the stress-isolated MEMS device are provided. MEMS devices may be sensitive to stress and may provide lower performance when subjected to stress. A stress-isolated MEMS device may be manufactured by etching a trench and/or a cavity in a first side of a substrate and subsequently forming a MEMS device on a surface of a platform opposite the first side of the substrate. Such a stress-isolated MEMS device may exhibit better performance than a MEMS device that is not stress-isolated. Moreover, manufacturing the MEMS device by first forming a trench and cavity on a backside of a wafer, before forming the MEMS device on a suspended platform, provides increased yield and allows for fabrication of smaller parts, in at least some embodiments.

A device having both an electronic assembly having an electronic component assembled on a first substrate, and also a body defining a cavity having a first end in fluid flow communication with a fluid, the electronic component extending inside the cavity and the first substrate including a portion in contact with a wall of the cavity. The coefficient of thermal expansion of the material of the first substrate is less than that of the electronic component, and the electronic component is assembled on the first substrate by a brazing type assembly method involving the application of heat. A method of making an electronic assembly. An assembly obtained by the method.

Expansion compensating structures are formed in redistribution layers of a wafer-level chip-scale integrated circuit package (WLCSP) or other IC package having a low-expansion substrate. The structures include micromechanical actuators designed and oriented to move solder bumps attached to them in the same direction and distance as a function of temperature as do pads to which they may be connected on a higher-expansion substrate such as a printed circuit board. Expansion compensated IC packages incorporating these expansion compensating structures are provided, as well as expansion compensated assemblies containing one or more of these IC packages. Methods of fabricating expansion compensated IC packages requiring minimal changes to existing commercial WLCSP fabrication processes are also provided. These devices and methods will result in assemblies having improved board-level reliability during thermal cycling, and allow the use of larger IC die sizes in WLCSP technology.

A MEMS device formed by a substrate, having a surface; a MEMS structure arranged on the surface; a first coating region having a first Young's modulus, surrounding the MEMS structure at the top and at the sides and in contact with the surface of the substrate; and a second coating region having a second Young's modulus, surrounding the first coating region at the top and at the sides and in contact with the surface of the substrate. The first Young's modulus is higher than the second Young's modulus.

An integrated device package is disclosed. The integrated device package can include a package housing that defines a cavity. The integrated device package can include an integrated device die that is disposed in the cavity. The integrated device die has a first surface includes a sensitive component. A second surface is free from a die attach material. The second surface is opposite the first surface. The integrated device die include a die cap that is bonded to the first surface. The integrated device package can also include a supporting structure that attaches the die cap to the package housing.

A sensor package comprising: a sensor, wherein the sensor comprises a sensing structure formed in a material layer and one or more further material layers arranged to seal the sensing structure to form a hermetically sealed sensor unit; a support structure; one or more springs flexibly fixing the hermetically sealed sensor unit to the support structure; wherein the one or more springs are formed in the same material layer as the sensing structure of the sensor unit; and one or more external package wall(s) encapsulating the sensor unit, the support structure, and the one or more springs, wherein the support structure is fixed to at least one of the package wall(s). The springs decouple mechanical stresses between the sensor unit and the external package wall(s) so as to reduce the long term drift of scale factor and bias.