A method of generating a wire loop profile in connection with a semiconductor package is provided. The method includes the steps of: (a) providing package data related to the semiconductor package; and (b) creating a loop profile of a wire loop of the semiconductor package, the loop profile including a tolerance band along at least a portion of a length of the wire loop.

An isolation system, isolation device, and Integrated Circuit are disclosed. The isolation system is described to include an integrated circuit chip having a first capacitive plate, a second capacitive plate positioned with respect to the first capacitive plate to enable a capacitive coupling therebetween, an enhanced isolation layer positioned between the first capacitive the second capacitive plate that facilitates an electrical isolation between the first capacitive plate and the second capacitive plate, a first bonding wire that is in electrical communication with the second capacitive plate, and an isolation trench that at least partially circumscribes the first capacitive plate and is positioned between the first capacitive plate and the first bonding wire.

A method is disclosed for manufacturing a discrete package for housing at least one integrated circuit die with electromagnetic interference shielding. The method may utilize a lead frame with a central die paddle and outwardly extending leads. The die paddle may have a top surface and an opposing bottom surface. The method may also have at least one integrated circuit die with a top surface and an opposing bottom surface. The integrated circuit die may be attached to the top surface of the die paddle. At least one conductive material bond may be established between the lead frame and the integrated circuit die. A dielectric material over mold may encapsulate the integrated circuit die and lead frame. A second dielectric material over mold may encapsulate the integrated circuit die and the lead frame. Further, a conductive coating may encapsulate the top and side surfaces of the package.

The present disclosure relates to a solid-state imaging apparatus, a manufacturing method of the same and an electronic device which can make an apparatus size further smaller. A solid-state imaging apparatus includes: a laminate of a first structure in which a pixel array unit in which pixels that perform photoelectric conversion are two-dimensionally arranged is formed and a second structure in which an output circuit unit configured to output pixel signals output from the pixels to an outside of an apparatus is formed. The output circuit unit, a first through hole via which penetrates through a semiconductor substrate constituting part of the second structure, and an external terminal for signal output connected to the outside of the apparatus are disposed below the pixel array unit of the first structure. The present disclosure can be applied, for example, to a solid-state imaging apparatus or the like.

A solid-state imaging apparatus includes: a solid-state imaging device photoelectrically converting light taken by a lens; and a light shielding member shielding part of light incident on the solid-state imaging device from the lens, wherein an angle made between an edge surface of the light shielding member and an optical axis direction of the lens is larger than an incident angle of light to be incident on an edge portion of the light shielding member.

A semiconductor layer includes an opening, and in a joint surface between structures, a portion between a semiconductor layer and an opening in a direction in which the semiconductor layers are stacked together includes a plurality of conductor portions and an insulator portion located between the plurality of conductor portions in a direction orthogonal to the direction.

The semiconductor device according to the present invention includes: an n-type semiconductor substrate; a p-type anode layer provided in a front surface of the n-type semiconductor substrate; an anode electrode provided on the p-type anode layer; and a wire connected to the anode electrode, the p-type anode layer includes: a p.sup.+-type anode layer disposed to include a position right under a portion where the wire is connected; and a p.sup.-type anode layer disposed to exclude the position right under the portion where the wire is connected, and an impurity concentration of the p.sup.+-type anode layer is higher than an impurity concentration of the p.sup.-type anode layer.

A semiconductor apparatus includes a conductive member penetrating through a first semiconductor layer, a first insulator layer, and a third insulator layer, and connecting a first conductor layer with a second conductor layer. The conductive member has a first region containing copper, and a second region containing a material different from the copper is located at least between a first region and the first semiconductor layer, between the first region and the first insulator layer, and between the first region and the third insulator layer. A diffusion coefficient of the copper to a material is lower than a diffusion coefficient of the copper to the first semiconductor layer and a diffusion coefficient of the copper to the first insulator layer.

There is provided a semiconductor device including: a plurality of bumps on a first semiconductor substrate; and a lens material in a region other than the plurality of bumps on the first semiconductor substrate, wherein a distance between a side of a bump closest to the lens material and a side of the lens material closest to the bump is greater than twice a diameter of the bump closest to the lens material, and wherein the distance between the side of the bump closest to the lens material and the side of the lens material closest to the bump is greater a minimum pitch of the bumps.

Isolator structures for an integrated circuit with reduced effective parasitic capacitance. Disclosed embodiments include an isolator structure with parallel conductive elements forming a capacitor or inductive transformer, overlying a semiconductor structure including a well region of a first conductivity type formed within an tank region of a second conductivity type. The tank region is surrounded by doped regions and a buried doped layer of the first conductivity type, forming a plurality of diodes in series to the substrate. The junction capacitances of the series diodes have the effect of reducing the parasitic capacitance apparent at the isolator.