This heat sink integrated insulating circuit substrate includes: a heat sink including a top plate part and a cooling fin; an insulating resin layer formed on the top plate part of the heat sink; and a circuit layer made of metal pieces arranged on a surface of the insulating resin layer opposite to the heat sink, wherein, when a maximum length of the top plate part is defined as L, an amount of warpage of the top plate part is defined as Z, and deformation of protruding toward a bonding surface side of the top plate part of the heat sink is defined as a positive amount of warpage, and a curvature of the heat sink is defined as C=|(8×Z)/L.sup.2|, a ratio P/C.sub.max between a maximum curvature C.sub.max(l/m) of the heat sink during heating from 25° C. to 300° C. and peel strength P (N/cm) of the insulating resin layer satisfies P/C.sub.max>60.

The invention relates to a device having: —a circuit carrier board (3) and—a conductor element (2), which is designed to transfer an electric current from and/or to the circuit carrier board (3), characterized by: —an electrically conductive, elastically deformable, contoured, plate-like connection element (1), which connects the circuit carrier plate (3) to the conductor element (2) and is designed to create a local, dynamic resilience, as a result of which a force transmission (F) from the conductor element (2) to the circuit carrier plate (3) can be reduced, and—a plate thickness of the connection element (1) of at least 2 cm. The invention also relates to a power converter (4) and an aircraft (6) having such a device.

An electronic device including a connection element is provided. The connection element includes a first insulation layer and a second insulation layer. The first insulation layer has a first opening. A sidewall of the first insulation layer at the first opening has roughness different from roughness of a top surface of the first insulation layer. The second insulation layer is disposed on the first insulation layer, and the second insulation layer has a second opening. The sidewall of the first insulation layer at the first opening is exposed by the second opening. A method of fabricating an electronic device is also provided.

The present disclosure provides a circuit board arrangement comprising a main board comprising at least one longitudinal cutout, at least one reinforcing plate arranged in the at least one longitudinal cutout and mechanically coupled to the main board, wherein the plane of main extension of the main board is arranged perpendicular to the plane of main extension of the at least one reinforcing plate. Further, the present disclosure provides a differential probe circuit and a respective method.

A circuit board having multiple degrees of freedom, comprises a flat board and a conductive and flexible unit disposed on the flat board. The conductive and flexible unit comprises: an inner support plate, an outer support plate, and at least one flexible connector; a hollow portion is provided on the outer support plate; the inner support plate and the flexible connector are disposed in the hollow portion; the inner and the outer support plates are connected by the flexible connector; the flexible connector comprises an outer connecting portion, an inner connecting portion corresponding to the outer connecting portion, and an extension located between the outer connecting portion and the inner connecting portion. The circuit board has a simple and compact structure; the production efficiency is high; costs are low; a multi-axis flexible anti-shaking effect can be achieved without folding a flexible structure; the resilience performance is good.

A metal-clad laminate includes: an insulating layer; and a metal layer stacked on the insulating layer. The insulating layer includes: a first layer; and a second layer interposed between the first layer and the metal layer. The first layer contains a cured product of a first resin composition containing composite particles. The second layer contains a cured product of a second resin composition. The first resin composition contains composite particles, each having a core containing a fluororesin and a shell containing a silicon oxide that coats the core at least partially. The second resin composition may or may not contain composite particles. When the second resin composition contains the composite particles, a ratio of the composite particles in the second resin composition to solid content of the second resin composition is lower than a ratio of the composite particles in the first resin composition to solid content of the first resin composition.

A semiconductor device, a circuit board structure and a manufacturing forming thereof are provided. A circuit board structure includes a core layer, a first build-up layer and a second build-up layer. The first build-up layer and the second build-up layer are disposed on opposite sides of the core layer. The circuit board structure has a plurality of stress releasing trenches extending into the first build-up layer and the second build-up layer.

A circuit board according to an embodiments includes an insulating portion comprising a plurality of insulating layers, wherein the insulating portion includes: a first insulating portion; a second insulating portion disposed on the first insulating portion and having a coefficient of thermal expansion corresponding to the first insulating portion; and a third insulating portion disposed under the first insulating portion and having a coefficient of thermal expansion corresponding to the first insulating portion; wherein the first insulating portion includes a prepreg including glass fibers, and wherein the second and third insulating portions include a resin coated copper (RCC) with a coefficient of thermal expansion in the range of 10 to 65 (10.sup.−6 m/m.Math.k).

An electronic component of the present disclosure includes: an electronic component body; an electrode on a surface of the electronic component body; and a cover layer having insulating properties on at least a portion of a perimeter of the electrode and extending across a boundary between the perimeter of the electrode and the surface of the electronic component body, wherein in a plan view of the electronic component body seen from a side where the electrode is disposed, the electrode includes corners each provided by two segments defining a portion of the perimeter of the electrode, and a thickness of at least a portion of the cover layer on at least one of the corners is greater than a thickness of the other portions of the cover layer on portions other than the corners.

This application provides a stiffener ring and a surface packaging assembly. The stiffener ring is configured to correct warpage of a substrate of the surface packaging assembly. The stiffener ring includes an annular stiffener ring body and an adjustment block that is disposed at a same layer as the stiffener ring body and that is fastened to at least one corner of the stiffener ring body.

A coefficient of thermal expansion of the adjustment block is less than a coefficient of thermal expansion of the stiffener ring body. Coordination between the adjustment block and the stiffener ring body alleviates an “M-shape” overpressure phenomenon of a warpage deformation caused by the stiffener ring to the substrate at a high temperature, reduces warpage of the substrate, and improves flatness of the surface packaging assembly.