A semiconductor module includes: a dissipating metal plate including a recess provided on an upper surface; an insulating substrate provided on a bottom surface of the recess and including a circuit pattern; a semiconductor device provided on the insulating substrate and connected to the circuit pattern; a case bonded to a peripheral portion on the upper surface of the dissipating metal plate and surrounding the insulating substrate and the semiconductor device; a case electrode provided on the case; a wire connecting the semiconductor device and the case electrode; and a sealant provided in the case and sealing the insulating substrate, the semiconductor device, and the wire, wherein a sidewall of the recess has a taper.

Multi-die integrated circuit packages and methods of manufacturing the same are disclosed. An example integrated circuit package includes a first leadframe, a first die on a first side of the first leadframe, and a second die on a second side of the first leadframe opposite the first side. The example integrated circuit package further includes external second leadframe separate from the first leadframe.

Each of a plurality of terminals has a first portion and a second portion being a connection target for a semiconductor element. A manufacturing method of a housing includes a first step arranging, for a lower mold provided with a plurality of holes each of which is a target into which the first portion is inserted, a nest having a third portion covering at least one of the holes, a second step arranging, for the lower mold with the nest being arranged therein, the plurality of terminals by inserting the first portion into the hole not covered by the third portion, a third step arranging an upper mold on the lower mold with the nest and the plurality of terminals being arranged therein, and a fourth step, which is executed after the third step, obtaining the housing by performing resin molding using the lower mold and the upper mold.

A semiconductor package may include a semiconductor chip on a package substrate. The semiconductor package may include a plurality of conductive connections connecting the semiconductor chip to the package substrate may be disposed, a plurality of towers which are apart from one another and each include a plurality of memory chips may be disposed, wherein a lowermost memory chip of each of the plurality of towers overlaps the semiconductor chip from a top-down view. The semiconductor package further includes a plurality of adhesive layers be attached between the lowermost memory chip of each of the plurality of towers and the semiconductor chip.

A second semiconductor switching element is connected in series with a first semiconductor switching element, and is at least partially stacked on the first semiconductor switching element in the thickness direction. A first control element controls the first semiconductor switching element and the second semiconductor switching element, and performs an overcurrent protection operation with reference to a shunt voltage. The first control element is arranged outside the first semiconductor switching element and the second semiconductor switching element in the in-plane direction.

Techniques for providing vertical integrations of semiconductor chips, magnetic chips, and lead frames. The techniques can include fabricating an integrated circuit (IC) device as a multi-layer IC structure that includes, within a sealed protective enclosure, a first layer including at least one magnetic chip, a second layer including at least one semiconductor chip or die, and a lead frame. The techniques can further include vertically bonding the magnetic chip in the first layer onto the topside of the lead frame, and vertically bonding the semiconductor chip or die in the second layer on top of the magnetic chip to form a multi-layer IC structure.

The present application provides a method for preparing a semiconductor package The method includes bonding a bottom device die onto a package substrate; attaching a top device die onto the bottom device die; attaching an additional package substrate onto the top device die; establishing electrical connection between the additional package substrate and the top device die, between the additional package substrate and the package substrate, and between the top device die and the package substrate; and encapsulating the bottom device die, the top device die and the additional package substrate by an encapsulant.

A semiconductor device includes a semiconductor element circuit, a conductive support and a sealing resin. The conductive support includes a die pad, first terminals spaced in a first direction, second terminals spaced in the first direction and opposite to the first terminals in a second direction perpendicular to the first direction, and a support terminal connected to the die pad. The sealing resin encapsulates portions of the first and second terminals, a portion of the support terminal, the semiconductor element circuit and the die pad. The sealing resin has two first side surfaces spaced apart in the second direction and two second side surfaces spaced apart in the first direction. The first terminals and second terminals are exposed from the first side surfaces, while none of the elements of the conductive support is exposed from the second side surfaces.

A semiconductor device that is a surface mount-type device includes a nitride semiconductor chip including a silicon substrate having a first thermal expansion coefficient and an In.sub.xGa.sub.yAl.sub.1-x-yN layer in contact with a surface of the silicon substrate, where 0≤x≤1, 0≤y≤1, 0≤x+y≤1; and a die pad including Cu and having a second thermal expansion coefficient that is greater than the first thermal expansion coefficient. A thickness of the nitride semiconductor chip is at least 0.2 mm, length L of the nitride semiconductor chip is at least 3.12 mm, and thickness tm of the die pad and length L of the nitride semiconductor chip satisfy tm≥2.00×10.sup.−3×L.sup.2+0.173, tm being a thickness in mm and L being a length in mm.

A high frequency semiconductor amplifier according to the present disclosure includes: a transistor formed on a semiconductor substrate and including a gate electrode, a source electrode, and a drain electrode; a matching circuit for input-side fundamental wave matching of the transistor; a first inductor formed on the semiconductor substrate and having one end connected to the gate electrode of the transistor and the other end connected to the matching circuit; a capacitor formed on the semiconductor substrate and having one end being short-circuited; and a second inductor formed on the semiconductor substrate and having one end connected to the gate electrode of the transistor and the other end connected to the other end of the capacitor, wherein the second inductor resonates in series with the capacitor at second harmonic frequency, has a mutual inductance of subtractive polarity with the first inductor, and the first inductor and the second inductor form mutual inductive circuits for input-side second harmonic matching.