A semiconductor chip includes a substrate including a circuit area having a rectangular shape and a peripheral area surrounding the circuit area, a key area being overlapping a part of the circuit area and a part of the peripheral area, a plurality of drive circuit cells in the circuit area, and a conductive reference line on the peripheral area and extending in a first direction parallel to a first edge among four edges of the rectangular shape of the circuit area.

The present invention relates to a camera module in which a thin camera module can be realized at a low cost and an electronic device. The camera module includes a lens unit that stores a lens that condenses light on a light receiving surface of an image sensor; a rigid substrate on which the image sensor is disposed; and a flexible substrate electrically connected with the rigid substrate, wherein in the case where the light receiving surface of the image sensor locates at the top, the lens unit, the flexible substrate, and the rigid substrate are disposed in this order from the top.

A multi-row wiring member for semiconductor device configured of a plurality of wiring members arrayed in a matrix includes a resin layer, a first plating layer forming internal terminals, a plating layer forming wiring portions and a second plating layer forming external terminals. The first plating layer is formed in the resin layer with lower faces thereof uncovered in the bottom surface of the resin layer. The plating layer forming wiring portions is formed on the first plating layer in the resin layer. The second plating layer is formed on partial areas within areas of the plating layer forming wiring portions, with upper faces thereof being uncovered on a top-surface side of the resin layer. On a bottom-surface side of the resin layer, a resin frame is integrally formed with the resin layer at the margin around an aggregate of individual wiring members for semiconductor devices arrayed in a matrix.

Methods of forming a semiconductor package. Implementations include providing a leadframe, coupling a semiconductor die or an electronic component to the leadframe, and encapsulating at least a portion of the semiconductor die or the electronic component using a mold compound leaving two or more leads of the leadframe exposed. The method may also include coating the two or more leads of the leadframe with an electrically conductive layer. The method may include fully electrically and physically singulating one or more tie bars between two or more leads of the leadframe, a lead of the two or more leads and a leadframe flag, or any combination thereof. The method may also include singulating the leadframe to form one or more semiconductor packages.

The present disclosure provides a semiconductor structure including a substrate, a first die vertically over the substrate, a second die vertically over the substrate and laterally separated from the first die with a gap, and an insulation material in the gap. The substrate is at least partially overlapped with the gap when viewed from a top view perspective, and a Young's modulus of the substrate is higher than that of the insulation material.

A semiconductor module, comprises a substrate plate; a semiconductor switch chip and a diode chip attached to a collector conductor on the substrate plate, wherein the diode chip is electrically connected antiparallel to the semiconductor switch chip; wherein the semiconductor switch chip is electrically connected via bond wires to an emitter conductor on the substrate plate providing a first emitter current path, which emitter conductor is arranged oppositely to the semiconductor switch chip with respect to the diode chip; wherein a gate electrode of the semiconductor switch chip is electrically connected via a bond wire to a gate conductor on the substrate plate providing a gate current path, which gate conductor is arranged oppositely to the semiconductor switch chip with respect to the diode chip; and wherein a protruding area of the emitter conductor runs besides the diode chip towards the first semiconductor switch chip and the first semiconductor switch chip is directly connected via a bond wire with the protruding area providing an additional emitter current path running at least partially along the gate current path. The semiconductor switch chip is a first semiconductor switch chip and the diode chip is a first diode chip, which are arranged in a first row. The semiconductor module comprises further a second row of a second semiconductor switch chip and a second diode chip attached to the collector conductor, wherein the diode chip of each row is electrically connected antiparallel to the semiconductor switch chip of the same row and the first and second rows are electrically connected in parallel. The first semiconductor switch chip is arranged besides the second diode chip and the second semiconductor chip is arranged besides the first diode chip.

A multi-row wiring member for semiconductor device configured of a plurality of wiring members arrayed in a matrix includes a resin layer, a first plating layer forming internal terminals, a plating layer forming wiring portions and a second plating layer forming external terminals. The first plating layer is formed in the resin layer with lower faces thereof uncovered in the bottom surface of the resin layer. The plating layer forming wiring portions is formed on the first plating layer in the resin layer. The second plating layer is formed on partial areas within areas of the plating layer forming wiring portions, with upper faces thereof being uncovered on a top-surface side of the resin layer. On a bottom-surface side of the resin layer, a resin frame is integrally formed with the resin layer at the margin around an aggregate of individual wiring members for semiconductor devices arrayed in a matrix.

Methods and apparatus for a signal isolator having enhanced creepage characteristics. In embodiments, an isolator includes a leadframe having first and second die paddles each having opposed first and second surfaces, a first die supported by the first surface of the first die paddle, and a second die supported by the first surface of the second die paddle. The first and second die paddles are configured enhanced creepage characteristics.

Aspects of the disclosure include a 1.5 sided cooled power module for enhanced cooling and gate connections. An exemplary cooled power module can include an upside direct bond copper (DBC) having a first top copper layer, a first bottom copper layer, and a first dielectric layer between the first top copper layer and the first bottom copper layer. A downside DBC includes a second top copper layer, a second bottom copper layer, and a second dielectric layer between the second top copper layer and the second bottom copper layer. One or more dies are positioned between the upside DBC and the downside DBC. The upside DBC is sized such that a portion of an uppermost surface of the one or more dies remains exposed. Bond wires are placed on the exposed portion of the one or more dies and terminated on the first top copper layer of the upside DBC.

An object is to provide a technique that suppresses peeling of a sealing resin that seals a semiconductor element by a simple method. A semiconductor device includes an insulating substrate provided with a front surface metal pattern a front surface thereof, a semiconductor element mounted on the front surface metal pattern, a wiring wire connected to the front surface electrode of the semiconductor element, a sealing resin that seals the insulating substrate and the semiconductor element, and at least one metal wire arranged around the semiconductor elements on and along the front surface metal pattern. The distance between the semiconductor element and the at least one metal wire is greater than the thickness of the semiconductor element.