A semiconductor device includes: an insulated circuit substrate including a base plate, a resin layer on the base plate, and a circuit pattern on the resin layer; a semiconductor chip that is rectangular and is bonded to the circuit pattern such that a side edge of the semiconductor chip is spaced inwardly from an outer peripheral edge of the circuit pattern by a predetermined distance; a case on the resin layer and surrounds the circuit pattern and the semiconductor chip; and a sealing material that covers the insulated circuit substrate and semiconductor chip and is surrounded by the case. The predetermined distance and thickness of the circuit pattern are greater than or equal to 0.1 of a length of one side of the semiconductor chip. A peripheral region of the case and a peripheral region of the resin layer are connected to each other via an adhesive layer.

The invention provides improved techniques for bonding devices using copper-to-copper or other types of bonds. A substrate is cleaned to remove surface oxides and contaminants and then rinsed. The rinsed substrate is provided to coating unit where a protective coating is applied to the substrate. The protective coating may be applied by immersing the substrate in a bath or via chemical vapor deposition. In an aspect, the protective coating may be copper selective so that the protective coating is only applied to copper features of the substrate. The protective coating minimizes formation of oxides and other bond weakening forces that may form during bonding processes, such as bonding a copper wire to a copper bond pad of the substrate. In an aspect, an annealing process is used to cure the protective coating and remove small imperfections and other abnormalities in the protective coating prior to the bonding process.

An electronic device includes: an insulating substrate including an obverse surface facing a thickness direction; a wiring portion formed on the substrate obverse surface and made of a conductive material; a lead frame arranged on the substrate obverse surface; a first and a second semiconductor elements electrically connected to the lead frame; and a first control unit electrically connected to the wiring portion to operate the first semiconductor element as a first upper arm and operate the second semiconductor element as a first lower arm. The lead frame includes a first pad portion to which the first semiconductor element is joined and a second pad portion to which the second semiconductor element is joined. The first and second pad portions are spaced apart from the wiring portion and arranged in a first direction with a first separation region sandwiched therebetween, where the first direction is orthogonal to the thickness direction. The first control unit is spaced apart from the lead frame as viewed in the thickness direction, while overlapping with the first separation region as viewed in a second direction orthogonal to the thickness direction and the first direction.

An oscillator includes a resonator element provided with an excitation electrode, an oscillation circuit for oscillating the resonator element to generate an oscillation signal, a temperature sensor for generating a temperature signal for temperature compensation of the oscillation signal, a temperature control element for controlling temperature of the resonator element, and a container that houses the resonator element, the oscillation circuit, the temperature sensor, and the temperature control element, in which the temperature sensor and the temperature control element overlap the excitation electrode in plan view.

A semiconductor device includes a substrate, a conductive part formed on a front surface of the substrate, a semiconductor chip disposed on the front surface of the substrate, a control unit that controls the semiconductor chip, a sealing resin that covers the semiconductor chip, the control unit and the conductive part, and a first lead bonded to the conductive part and partially exposed from the sealing resin. The conductive part includes a first pad and a second pad disposed apart from each other. The first lead is bonded to the first pad and the second pad.

A power module includes a first end power semiconductor element and a second end power semiconductor element. A first sum is a sum of a path length between the gate electrode of the first end power semiconductor element and a first control terminal and a path length between the source electrode of the first end power semiconductor element and a first detection terminal. A second sum is a sum of a path length between the gate electrode of the second end power semiconductor element and the first control terminal and a path length between the source electrode of the second end power semiconductor element and the first detection terminal. The power module includes a first control layer connected to the gate electrode. The first control layer includes a first detour portion that detours the path to reduce a difference between the first sum and the second sum.

A semiconductor module, including a semiconductor chip, a sealed main body portion sealing the semiconductor chip and having a pair of attachment holes penetrating therethrough, a heat dissipation plate in contact with the sealed main body portion. The heat dissipation plate is positioned between the attachment holes in a plan view of the semiconductor module. The semiconductor module further includes a pair of rear surface supporting portions and/or a pair of front surface supporting portions protruding respectively from rear and front surfaces of the sealed main body portion. In the plan view, the heat dissipation plate is formed between the pair of attachment holes, which are in turn between the pair of rear surface supporting portions. The pair of front surface supporting portions are formed substantially between the pair of attachment holes in the plan view.

A bonding pad structure and a method of manufacturing a bonding pad structure are provided. The bonding pad structure includes a carrier, a first conductive layer disposed over the carrier, a second conductive layer disposed on the first conductive layer and contacting the first conductive layer, and a third conductive layer disposed on the second conductive layer and contacting the second conductive layer. The bonding pad structure also includes a first passivation layer disposed on the first conductive layer and contacting at least one of the first conductive layer or the second conductive layer. An upper surface of the third conductive layer facing away from the carrier is exposed from the first passivation layer.

A semiconductor device includes: a plurality of semiconductor elements connected in parallel; a rectifier element connected in anti-parallel to the plurality of semiconductor elements; a power terminal electrically connected to the plurality of semiconductor elements; and an electrical conductor electrically connected to the power terminal and the plurality of semiconductor elements and including a pad portion to which the plurality of semiconductor elements are bonded. The plurality of first semiconductor elements include a first element and a second element. The minimum conduction path of the first element to the power terminal is shorter than the minimum conduction path of the second element to the power terminal. The pad portion includes a first section to which the first element is bonded and a second section to which the second element is bonded. The rectifier element is located in the first section of the pad portion.

An amplifier circuit that includes an RF amplifier; an impedance matching network; a higher order harmonic termination circuit; a fundamental frequency matching circuit; and an integrated passive device (IPD) that includes a silicon carbide (SiC) substrate. The integrated passive device (IPD) includes one or more reactive components of the fundamental frequency matching circuit and one or more reactive components of the higher order harmonic termination circuit.