A semiconductor device includes a semiconductor element, a conductive layer, terminals, and a sealing resin. The conductive layer, containing metal particles, is in contact with the reverse surface and the side surface of the semiconductor element. The terminals are spaced apart from and electrically connected to the semiconductor element. The sealing resin covers the semiconductor element. The conductive layer has an edge located outside of the semiconductor element as viewed in plan. Each terminal includes a top surface, a bottom surface, an inner side surface held in contact with the sealing resin, and the terminal is formed with a dent portion recessed from the bottom surface and the inner side surface. The conductive layer and the bottom surface of each terminal are exposed from a bottom surface of the sealing resin.

A light emitting device includes a semiconductor chip including a p-type semiconductor layer and an n-type semiconductor layer, the semiconductor chip being adapted to emit light between the p-type semiconductor layer and the n-type semiconductor layer; a p-side pad electrode disposed on an upper surface side of the semiconductor chip and over the p-type semiconductor layer; an n-side pad electrode disposed on an upper surface side of the semiconductor chip and over the n-type semiconductor layer; a resin layer disposed to cover the upper surface of the semiconductor chip; a p-side connection electrode and an n-side connection electrode disposed at an outer surface of the resin layer and positioned on the upper surface side of the semiconductor chip; and a metal wire disposed in the resin. The metal wire is adapted to make connection at least one of between the p-side pad electrode and the p-side connection electrode, and between the n-side pad electrode and the n-side connection electrode.

The present disclosure provides a semiconductor device. The semiconductor device includes a semiconductor element, a plurality of terminals, and a sealing resin. The semiconductor element has a front surface and a back surface. The front surface and the back surface face in opposite directions to each other in a thickness direction of the semiconductor element. The plurality of terminals are disposed at a distance from the semiconductor element and are electrically connected to the front surface. The sealing resin has a first surface facing in a same direction as the direction in which the front surface faces. Each of the plurality of terminals has a main surface exposed from the first surface.

The teachings of the present disclosure may be applied to the manufacture and design of capacitors. In some embodiments of these teachings, a capacitor may be formed on a heavily doped substrate. For example, a method for manufacturing a capacitor may include: depositing an oxide layer on a first side of a heavily doped substrate; depositing a first metal layer on the oxide layer; and depositing a second metal layer on a second side of the heavily doped substrate.

In a semiconductor module, first and second semiconductor chips each include a transistor and a temperature-detecting diode connected between first and second control pads. The first control pad of the first semiconductor chip is connected to a first control terminal, the second control pad of the first semiconductor chip and the first control pad of the second semiconductor chip are connected to a second control terminal, and the second control pad of the second semiconductor chip is connected to a third control terminal.

A package structure includes a first carrier plate, a second carrier plate, a pin group and an encapsulant member. A power component is disposed on a first top surface of the first carrier plate. The second carrier plate is disposed on the first top surface of the first carrier plate. A driving circuit is disposed on a second top surface of the second carrier plate for driving the power component. An opening runs through the second carrier plate, and the power component is accommodated within the opening. The pin group is assembled on the first carrier plate and/or the second carrier plate. The encapsulant member encapsulates the first carrier plate, the second carrier plate, a part of the first pin group and a part of the second pin group, so that the first pin group and the second pin group are partially exposed outside the encapsulant member.

A measuring device includes two sensor chips that measure a flow rate of a fluid flowing through a pipe, electrode pads extending from a temperature measuring section and from a heater, respectively, toward peripheries of the two sensor chips, and wires that are electrically connected to the electrode pads and via which a measurement signal that is output from the temperature measuring section or the heater is transmitted to outside of the sensor chips. Each of the electrode pads includes a straight portion that extends linearly from the temperature measuring section or the heater and a wide portion that is formed at a leading end of each of the electrode pads and is wider than the straight portion, and an entire surface area of the wide portion is set as a wire-bonding-allowed region, to which one of the wires is to be bonded.

Embodiments of the present application provide the chip packaging structure, the chip module and the electronic terminal. In the chip packaging structure, the chip is accommodated in the trench of the substrate to decrease the thickness and volume of the chip packaging structure; and the plastic package is provided on the surface of the substrate on which the chip is disposed to plastically package the chip, which not only ensures the structural strength of the chip packaging structure, but also reduces the warpage that may be caused due to the decrease of the thickness of the chip packaging structure as much as possible. In addition, the surface of the plastic package is treated to be a flat surface, such that the chip module has good flatness and the adaptability of the chip module is improved.

The present disclosure relates to an air-cavity package, which includes a substrate, a base, and a semiconductor die. The substrate includes a substrate body, thermal vias extending through the substrate body, and a metal trace on a bottom side of the substrate body and separate from the thermal vias. The base includes a base body, a perimeter wall extending about a perimeter of the base body, and a signal via structure. Herein, the bottom side of the substrate body resides on the perimeter wall to form a cavity, and the signal via structure extends through the perimeter wall and is electrically coupled to the metal trace. The semiconductor die is mounted on the bottom side of the substrate body, exposed to the cavity, and electrically coupled to the metal trace. The thermal vias conduct heat generated from the semiconductor die toward a top side of the substrate body.

An integrated circuit package is provided. The integrated circuit package comprises a first and second guard bond wire. The first guard bond wire has a first and second end coupled to ground. The second guard bond wire has a first and second end coupled to ground. The integrated circuit package further comprises a die. The die is mounted between the first and second guard bond wires such that the first and second guard bond wires distort a magnetic field between at least an input terminal and an output terminal of the die.