The semiconductor device includes: a heat spreader; a plurality of semiconductor elements; and one or a plurality of temperature detection elements. If a line segment connecting centers of two respective adjacent ones of the semiconductor elements is defined as X, a straight line that passes through one of the centers of the two adjacent semiconductor elements and that is perpendicular to X and parallel to the one-side surface of the heat spreader is defined as Y1, and a straight line that passes through another one of the centers of the two adjacent semiconductor elements and that is perpendicular to X and parallel to the one-side surface of the heat spreader is defined as Y2, at least a part of the temperature detection element is located in an arrangement region interposed between Y1 and Y2, as seen in a direction perpendicular to the one-side surface of the heat spreader.

A power module, including: a first conductor, disposed at a first reference plane; a second conductor, disposed at a second reference plane, wherein projections of the first and second conductors on the first reference plane have a first overlap area; a third conductor, disposed at a third reference plane; a plurality of first switches and a plurality of second switches, wherein at least one of the first switches and at least one of the second switches that are located on a left side are alternatively disposed, at least one of the first switches and at least one of the second switches that are located on a right side are alternately disposed, and the left side and the right side of the first overlap area are oppositely disposed. Heat sources of the power module are evenly distributed and its parasitic inductance is low.

In one example, an electronic assembly comprises a first semiconductor device and a second semiconductor device. Each of the first semiconductor device and the second semiconductor devices comprises a substrate comprising a top surface and a conductive structure, an electronic component over the top surface of the substrate, a dielectric material over the top surface of the substrate and contacting a side of the electronic component, a substrate tab at an end of substrate and not covered by the dielectric material, wherein the conductive structure of the substrate is exposed at the substrate tab, and an interconnect electrically coupled to the conductive structure at the substrate tab of the first semiconductor device and the conductive structure at the substrate tab of the second semiconductor device.

Other examples and related methods are also disclosed herein.

There is provided a semiconductor module including: a base for semiconductor cooling; a stacked substrate provided above the base; a semiconductor chip provided above the stacked substrate; a coating layer provided on an upper surface of the semiconductor chip; and a sealing resin for sealing the semiconductor chip, in which the base is in contact with the sealing resin.

An intelligent power module (IPM) comprises a first, second, third and fourth die supporting elements, a first group of insulated gate bipolar transistors (IGBTs), a second group of IGBTs, a first group of super-junction metal-oxide-semiconductor field-effect transistors (MOSFETs), a second group of super-junction MOSFETs, a fifth die supporting element, a low voltage IC, a high voltage IC, and a molding encapsulation. The low and high voltage ICs are attached to the fifth die supporting element. The molding encapsulation encloses the first, second, third and fourth die supporting elements, the first group of IGBTs, the second group of IGBTs, the first group of super-junction MOSFETs, the second group of super-junction MOSFETs, the fifth die supporting element, the low voltage IC, the high voltage IC.

A semiconductor device includes a region of semiconductor material having a first side and a second side opposite to the first side. Active device structures are adjacent to the first side, the active device structures comprising source regions and gate electrodes. A first gate conductor is at the first side electrically connected to the gate electrodes, a drain region is at the second side, a second gate conductor is at the second side, and through-semiconductor vias extending from the first side towards the side and electrically connecting the first gate electrode to the second gate electrode. A source electrode is at the first side electrically connected to the source regions, and a drain electrode is at the second side electrically connected to the drain region. The through-semiconductor vias are electrically isolated from the source regions and the drain region. The structure provides a gate/drain up with a source-down configuration.

A semiconductor device includes: a plurality of semiconductor chips each including a first main electrode on a top surfaces and including a second main electrode and a control electrode on a bottom surface; a first common main electrode connected to the first main electrodes; a printed board including a control wiring part and a main wiring part provided on a bottom surface of an insulating layer, and a common control electrode and a second common main electrode provided on a top surface of the insulating layer and electrically connected to the control wiring part and the main wiring part; projection electrodes bonding the control electrodes to the control wiring part; projection electrodes bonding the second main electrodes to the main wiring part; and a sealing member sealing the semiconductor chips and exposing the first common main electrode, the common control electrode, and the second common main electrode.

A semiconductor device includes a semiconductor element (30), an input lead, and first drive leads (60) connecting a source electrode of the semiconductor element (30) to the input lead. The first drive leads (60) are formed of a thin metal plate that is belt-shaped as viewed in a thickness-wise direction (Z). The first drive leads (60) include at least a metal plate (60A) connected to the semiconductor element (60) and a metal plate (60B) stacked on the metal plate (60A). The metal plate (60A) includes a first connector (61A) connected to the semiconductor element (30). The metal plate (60B) includes a first connector (61B) connected to the first connector (61A). The first connectors (61A, 61B) are stacked in the thickness-wise direction (Z).

A semiconductor device includes a region of semiconductor material having a first side and a second side opposite to the first side. Active device structures are adjacent to the first side, the active device structures comprising source regions and gate electrodes. A first gate conductor is at the first side electrically connected to the gate electrodes, a drain region is at the second side, a second gate conductor is at the second side, and through-semiconductor vias extending from the first side towards the side and electrically connecting the first gate electrode to the second gate electrode. A source electrode is at the first side electrically connected to the source regions, and a drain electrode is at the second side electrically connected to the drain region. The through-semiconductor vias are electrically isolated from the source regions and the drain region. The structure provides a gate/drain up with a source-down configuration.

A semiconductor device includes: a substrate; a semiconductor element that disposed on the upper surface of the substrate; a sealing portion that seals the substrate and the semiconductor element; a first lead frame that has one end in contact with a upper surface of the first conductive layer at an end extending in the side direction of the upper surface of the substrate in the sealing portion, and has the other end exposed from the sealing portion; a first conductive bonding material that bonds between the upper surface of the first conductive layer and the lower surface side of the one end portion of the first lead frame at the end portion of the substrate, and has electrical conductivity.