The present disclosure provides a terminal assembly structure of a MEMS microphone, including a signal let out board disposed at a terminal and a silicon microphone disposed on the signal let out board. The silicon microphone includes a housing, a substrate forming an accommodation space with the housing, an MEMS chip and a waterproof member. The substrate is configured with a sound inlet connected to the outside. The waterproof member is sandwiched between the MEMS chip and the substrate. A position where the signal let out board corresponds to the silicon microphone is configured with an accommodation hole. The housing is accommodated in the accommodation hole. The substrate abuts a surface of the signal let out board and covers the accommodation hole. A surface of the substrate where the housing is assembled, is provided with at least one pad electrically connected with the signal let out board.

A semiconductor device includes semiconductor elements arranged in a first direction, an arm connection portion disposed between the semiconductor elements in the first direction, first and second power supply terminals disposed on the same side in the first direction, first and second substrates interposing the semiconductor elements therebetween, and a sealing body. The second substrate includes an insulating base member, a front-face metal body and a back-face metal body. The front-face metal body includes a second power supply wiring and a second relay wiring. The second power supply wiring includes a base portion on which the second element is arranged, and a pair of extending portions extending from the base portion in the first direction. The second relay wiring is disposed between the extending portions in a second direction, so that the second relay wiring and the base portion satisfy a relationship of L1<L2<L3.

A semiconductor device includes: a semiconductor element having main electrodes on opposite faces in a plate thickness direction; a substrate having an insulating base member, a front-face metal body disposed on a front face of the insulating base member and electrically connected to one of the main electrodes of the semiconductor element, and a back-face metal body disposed on a back face of the insulating base member; a bonding member; and a metal member connected to the front-face metal body through the bonding member. The metal member has an opposing face opposing an upper face of the front-face metal body and a receiving portion disposed adjacent to the opposing face to provide a receiving space to receive the bonding member therein. The bonding member is received in the receiving space in a state where the opposing face is in contact with the upper face of the front-face metal body.

A semiconductor device includes a semiconductor element, a substrate, a bonding member and a sealing body sealing the semiconductor element, the substrate and the bonding member. The substrate has front-face and back-face metal bodies on opposite faces of an insulating base member. The front-face metal body is electrically connected to a main electrode of the semiconductor element. The bonding member connects the front-face metal body and the main electrode. The front-face metal body includes a base material and a plating film disposed on faces of the base material. The plating film is disposed at an upper face and a side face of the front-face metal body. The front-face metal body includes a roughened portion at the upper face and the side face, and a non-roughened portion at an area of the upper face excluding the roughened portion and including an arrangement region of the bonding member.

An electronic device package includes a frame, an electronic device mounted to the frame, surface-mount leads, and a gel at least partially filling a cavity between the electronic device and the frame. The electronic device includes electronic circuitry provided on an electronic device substrate, and the surface-mount leads are electrically connected to the electronic circuitry and extend laterally and outwardly from an outer perimeter of the frame. The gel in the cavity covers the electronic circuitry.

A semiconductor device includes a semiconductor element having main electrode on opposite faces in a plate thickness direction, a substrate, and a sealing body. The substrate has an insulating base member, a front-face metal body, and a back-face metal body having an exposed face exposed from the sealing body. A laminate of the insulating base member and the back-face metal body has a side face connecting between a front face of the insulating base member and the exposed face of the back-face metal body. The side face includes a first inclined portion in a predetermined range from the front face and a second inclined portion in a predetermined range from the exposed face. In a plan view of the substrate viewed along the plate thickness direction, a length of the second inclination portion is shorter than a length of the first inclination portion.

A semiconductor device includes a semiconductor element, a wiring member, a sintered member between a first main electrode of the semiconductor element and the wiring member, and a sealing body. The wiring member includes a base material, a metal film on a face of the base material, and an uneven oxide film. The uneven oxide film includes a thick film portion and a thin film portion. An opposing face of the wiring member opposing the semiconductor element includes a mounting portion to which the first main electrode is bonded, an outer peripheral portion formed with the thick film portion and surrounding the semiconductor element, and an intermediate portion formed with the thin film portion between the mounting portion and the outer peripheral portion. The sintered member overlaps with the mounting portion and the intermediate portion in the plan view, and is in contact with the thin film portion.

A circuit package with improved thermal management is disclosed. In one aspect, a ceramic insert is provided within a package having heat-producing circuitry thereon. The ceramic insert replaces traditional laminate inserts and provides a better thermal path to remove heat from leads and/or traces within the package. More particularly, the ceramic insert more readily transfers and/or dissipates heat that might otherwise accumulate at an output port where a solder junction may be made to couple the output port to external elements.

A semiconductor package may include a substrate including a connection circuit, a redistribution structure, and a chip structure on the redistribution structure. The redistribution structure may include a rear redistribution layer electrically connected to the connection circuit, a first semiconductor chip between rear and front redistribution portions and electrically connection to a front redistribution layer of the front redistribution portion, a first molded portion covering at least a portion of the first semiconductor chip, and a first through-via passing through the first molded portion and electrically connecting the front and the rear redistribution layers. The chip structure may include a wiring portion having a wiring layer electrically connected to the front redistribution layer, second and third semiconductor chips on the wiring portion and electrically connected to the wiring layer, and a second molded portion covering at least a portion of each of the second and third semiconductor chips.

A fingerprint sensing chip packaging method and package are provided. The method includes: providing a cover plate, providing a fingerprint sensing chip, where a fingerprint sensing region and contact pads at periphery of the region are arranged on a front surface of the chip, electrically connecting the contact pads to a back surface of the chip, forming a first conductive structure electrically connected to the contact pads on the back surface of the chip, laminating the front surface of the chip with a back surface of the cover plate, providing a flexible printed circuit, where a second conductive structure is arranged on a back surface of the circuit and an opening is arranged in the circuit, laminating a front surface of the circuit with the back surface of the cover plate, and electrically connecting the first conductive structure to the second conductive structure.