According to the present disclosure, a method of manufacturing a semiconductor device includes the steps of (a) preparing a lead frame including a switching element die pad, a control element die pad, and a third-side side rail portion, (b) mounting a switching element and a diode element on the switching element die pad and mounting a control element configured to control the switching element on the control element die pad, (c) sealing the switching element, the diode element, and the control element with a mold resin such that the power side terminal, the control side terminal, and a part of the third-side side rail portion protrude outward, and (d) forming a third-side side rail terminal by cutting the third-side side rail portion, the third-side side rail terminal extending from a part of the third-side side rail portion.

A high frequency device includes a semiconductor chip including a semiconductor substrate, and an amplifier provided on a front surface of the semiconductor substrate and amplifying a high frequency signal, a first reference potential layer provided above the semiconductor chip in an upper direction perpendicular to the front surface of the semiconductor substrate, and provided so as to overlap with the semiconductor chip in a plan view from above, and to which a reference potential is supplied, and a resonator provided between the semiconductor chip and the first reference potential layer in the upper direction perpendicular to the front surface of the semiconductor substrate, wherein a resonance frequency of the resonator is included in an operating frequency band of the amplifier, and an impedance of the resonator becomes minimal at the resonance frequency.

A semiconductor device includes: a package having a top surface and a bottom surface; a semiconductor element arranged in the package; and a base which is arranged in the package and on which the semiconductor element is mounted. A top surface of the base is exposed to the top surface of the package, and a bottom surface of the base is exposed to the bottom surface of the package.

An electronic package and method for manufacturing is provided. The package includes an electronic component having a terminal, a solidified molding compound encapsulating the electronic component, a lead including an inner and a mounting portion. The molding compound includes a first recess at or near a perimeter of a bottom surface of the mounting portion, exposing a portion of a bottom surface of the inner portion arranged near the mounting portion, and/or a second recess at the perimeter of the bottom surface of the mounting portion, the second recess exposing a portion of a side surface of the mounting portion extending between the top and the bottom surface of the mounting portion. The package provides more exposed lead space for a larger solder covering area using the first and/or second recess. Thus, solder strain accumulation is reduced or mitigated, and reliability of the electronic package can be enhanced.

This disclosure describes an electronic component with a package body which comprises a set of sidewalls and a bottom wall. One or more chip mounting elements extend into the space within the package from the inner surface of at least one sidewall, and at least one electronic chip is attached to the chip mounting elements. The electronic component also comprises one or more stiffening elements which extend inside the space within the package from the inner surface of one of the sidewalls to the outer surface of the bottom wall. These stiffening elements are separated from the one or more chip mounting elements inside the enclosed inner space.

A semiconductor package including a leadframe has a plurality of leads, and a semiconductor die including bond pads attached to the leadframe with the bond pads electrically coupled to the plurality of leads. The semiconductor die includes a substrate having a semiconductor surface including circuitry having nodes coupled to the bond pads. A mold compound encapsulates the semiconductor die. The mold compound is interdigitated having alternating extended mold regions over the plurality of leads and recessed mold regions in between adjacent ones of the plurality of leads.

Inner leads having die pads having upper surfaces to which semiconductor elements are mounted each have a stepped profile, and surfaces of portions of the inner leads are exposed from a sealing resin in plan view. Outer leads connected to the inner leads have first bends at side surfaces of the sealing resin to extend in a direction on a side of the upper surfaces of the die pads, so that a miniaturized semiconductor device can be obtained.

Implementations of semiconductor packages may include a substrate, a first die coupled on the substrate, and a lead frame coupled over the substrate. The lead frame may include a die attach pad. Implementations of semiconductor packages may also include a second die coupled on the die attach pad. The second die may overlap the first die.

A semiconductor device is provided, including a seal portion; an electronic element within the seal portion; first, second, and third lead terminals; first and second connecting elements; and first and second conductive bonding agents, one end of the first connecting element having a protrusion downward and electrically connected to a control electrode of the electronic element with the first conductive bonding agent, a first side surface extending from the one end to the other end of the first connecting element is parallel to an extending direction along which the one end of the second connecting element extends, a wall portion being disposed on a top surface of the one end of the second lead terminal, and the wall portion being in contact with the other end of the first connecting element.

An electronic device having a package structure with conductive leads, first and second dies in the package structure, as well as first and second conductive plates electrically coupled to the respective first and second dies and having respective first and second sides spaced apart from and directly facing one another with a portion of the package structure extending between the first side of the first conductive plate and the second side of the second conductive plate to form a capacitor. No other side of the first conductive plate directly faces a side of the second conductive plate, and no other side of the second conductive plate directly faces a side of the first conductive plate.