Disclosed embodiments relate to a semiconductor device. A semiconductor device is fabricated by attachment of a first chip to a first surface of a pad of a leadframe. Each of one or more terminals of the first chip is connected to a respective lead of the leadframe. The first chip and the first surface of the pad are then encapsulated in a packaging material, while leaving an opposite second surface of the pad exposed. A second chip is attached to a recessed portion of the second surface of the pad so that at least one terminal of the second chip is substantially coplanar with an un-recessed portion of the second surface. In one embodiment, a third chip is also attached to the recessed portion of the second surface so that at least one terminal of the third chip is substantially coplanar with the un-recessed portion of the second surface.

In one embodiment, a magneto-resistive chip package includes a circuit board; a shielding body including a shielding base part positioned on the circuit board and a shielding intermediate part extending from one side of the shielding base part; a magneto-resistive chip positioned on the shielding base part and including a magneto-resistive cell array; an internal connection part electrically connecting the magneto-resistive chip to the circuit board; an encapsulation part encapsulating the magneto-resistive chip on the circuit board, and having an upper surface that is higher than an upper surface of the magneto-resistive chip; and a shielding cover positioned on the shielding intermediate part, and on the encapsulation part.

Semiconductor light-emitting device, includes: substrate having base and conductive part; first to third semiconductor light-emitting elements; first to third wires connected to the first to third semiconductor light-emitting elements respectively; and light-transmitting resin part covering the first to the third semiconductor light-emitting elements, wherein the base has main and rear surfaces facing opposite sides in thickness direction of the base, wherein the conductive part includes main surface part on the main surface, wherein the main surface part includes main surface first part where the first and second semiconductor light-emitting elements are mounted, wherein the main surface first part reaches both ends of the main surface in first direction perpendicular to the thickness direction, and wherein the main surface first part is separated from both the main surface part where the third semiconductor light-emitting element is mounted and the main surface part where the first, second, and third wires are connected.

A semiconductor device includes leads, a switching element, a control element that controls the switching element, and a resin member covering the switching element, the control element and parts of the respective leads. The leads include a drain lead connected to a drain electrode of the switching element, a source lead connected to a source electrode of the switching element, and at least one control lead connected to the control element. The resin member includes a drain exposed portion at which the drain lead is exposed, a source exposed portion at which the source lead is exposed, and a control exposed portion at which the control lead is exposed. The distance in a first direction between the drain exposed portion and the source exposed portion is larger than the distance in the first direction between the control exposed portion and the source exposed portion.

A semiconductor device has a substrate and a first electrical component including a sensing region disposed over the substrate. The sensing region can be responsive to external stimuli, such as pressure. A cover lid is disposed over the first electrical component and extending to the substrate with an opening in the cover lid aligned over the sensing region. A gel material is disposed within the opening of the cover lid to seal the sensing region with respect to an environment condition, such as liquid. A bond wire is coupled between the first electrical component and substrate. An adhesive layer is disposed around a perimeter of the sensing area and the cover lid is bonded to the adhesive layer. A second electrical component is disposed on the substrate and the first electrical component is disposed on the second electrical component.

A multiple-path amplifier (e.g., a Doherty amplifier) includes a first transistor (e.g., a main amplifier FET), a second transistor (e.g., a peaking amplifier FET), a combining node, and a shunt-inductance circuit. The first and second amplifiers and the combining node structure are integrally-formed with a semiconductor die, and the shunt-inductance circuit is integrated with the die. Outputs of the first and second transistors are electrically coupled to the combining node structure. The shunt-inductance circuit is electrically coupled between the combining node structure and a ground reference node. The shunt-inductance circuit includes a shunt inductance (e.g., including wirebond(s) and/or spiral inductor(s)) that is integrated with the semiconductor die. The multiple-path amplifier also may include an integrated phase shifter/impedance inverter coupled between the outputs of the first and second transistors, and which is configured to impart a 90-degree phase delay between intrinsic drains of the first and second transistors.

An electronic package structure and a chip thereof are provided. The electronic package structure includes a substrate, a chip, a plurality of signal wires, and a core ground wire. The chip disposed on and electrically connected to the substrate has a core wiring region and an input and output pad region located at a top surface thereof. The input and output pad region is located between the core wiring region and an edge of the chip. The chip includes a plurality of signal pads in the input and output region and a core ground pad adjacent to one of the signal pads. The core ground pad located in the core wiring region. The signal wires are respectively connected to the signal pads. The core ground wire connected to the core ground pad is adjacent to and shields one of the signal wires.

A display device includes: an array substrate including a display area, of an image, including a plurality of pixels arranged in an array; a first circuit that is disposed at the array substrate to face an end of the display area, and controls drive of the plurality of pixels; and a second circuit that controls drive of the first circuit. The first circuit includes a plurality of first terminals arranged on the array substrate. The first circuit includes a plurality of second terminals each connected by at least one wire bond to a corresponding one of a plurality of terminals included in the second circuit.

A multi-level leadframe including three bonding levels and one exposed level. Each of the three bonding levels and the one exposed level is positioned in a different horizontal plane, with each bonding level providing a bonding site vertically positioned relative to the horizontal plane of the exposed level, with each bonding site coupled to a package lead at the exposed level. Bonding sites located at first and second bonding levels can be located in a common, outer row, along a common, vertical plane, and bonding sites located at a third bonding level can be located in a separate, inner row, along a separate vertical plane. A third level bonding site can be coupled to a first level bonding site with a multiple level electrical lead conductor that vertically spans a second bonding level. A two-step etch process from a single sheet conductor is provided to manufacture the multi-level leadframe.

A semiconductor device including a main board; a first board provided on the main board; first and second semiconductor elements provided on the first board; a first positive terminal provided on the first board; a first negative terminal provided on the first board; a first output terminal provided on the first board; a second board provided on the main board; third and fourth semiconductor elements provided on the second board; a second positive terminal provided on the second board; a second negative terminal provided on the second board; a second output terminal provided on the second board; a first terminal plate connecting the first positive terminal and the second positive terminal, a second terminal plate connecting the first negative terminal and the second negative terminal, and a third terminal plate connecting the first output terminal and the second output terminal.