A technique for fabricating bumps on a substrate is disclosed. A substrate that includes a set of pads formed on a surface thereof is prepared. A bump base is formed on each pad of the substrate. Each bump base has a tip extending outwardly from the corresponding pad. A resist layer is patterned on the substrate to have a set of holes through the resist layer. Each hole is aligned with the corresponding pad and having space configured to surround the tip of the bump base formed on the corresponding pad. The set of the holes in the resist layer is filled with conductive material to form a set of bumps on the substrate. The resist layer is stripped from the substrate with leaving the set of the bumps.

A technique for fabricating bumps on a substrate is disclosed. A substrate that includes a set of pads formed on a surface thereof is prepared. A bump base is formed on each pad of the substrate. Each bump base has a tip extending outwardly from the corresponding pad. A resist layer is patterned on the substrate to have a set of holes through the resist layer. Each hole is aligned with the corresponding pad and having space configured to surround the tip of the bump base formed on the corresponding pad. The set of the holes in the resist layer is filled with conductive material to form a set of bumps on the substrate. The resist layer is stripped from the substrate with leaving the set of the bumps.

A technique for fabricating bumps on a substrate is disclosed. A substrate that includes a set of pads formed on a surface thereof is prepared. A bump base is formed on each pad of the substrate. Each bump base has a tip extending outwardly from the corresponding pad. A resist layer is patterned on the substrate to have a set of holes through the resist layer. Each hole is aligned with the corresponding pad and having space configured to surround the tip of the bump base formed on the corresponding pad. The set of the holes in the resist layer is filled with conductive material to form a set of bumps on the substrate. The resist layer is stripped from the substrate with leaving the set of the bumps.

An article of manufacture comprises: an integrated circuit having a contact; a conductive bump electrically coupled to the contact, the conductive bump having a profile with a wave pattern; a lead frame electrically coupled to the conductive bump; and an integrated circuit package mold, the integrated circuit package mold covering portions of the conductive bump and the lead frame.

Described examples provide integrated circuits and methods, including forming a conductive seed layer at least partially above a conductive feature of a wafer, forming a conductive structure on at least a portion of the conductive seed layer, performing a printing process that forms a polymer material on a side of the wafer proximate a side of the conductive structure, curing the deposited polymer material, and attaching a solder ball structure to a side of the conductive structure.

Described examples provide integrated circuits and methods, including forming a conductive seed layer at least partially above a conductive feature of a wafer, forming a conductive structure on at least a portion of the conductive seed layer, performing a printing process that forms a polymer material on a side of the wafer proximate a side of the conductive structure, curing the deposited polymer material, and attaching a solder ball structure to a side of the conductive structure.

A semiconductor device manufacturing method including: simultaneously forming a plurality of conductive bumps respectively on a plurality of formation sites by adjusting a forming factor in accordance with an environmental density associated with each formation site; wherein the plurality of conductive bumps including an inter-bump height uniformity smaller than a value, and the environmental density is determined by a number of neighboring formation sites around each formation site in a predetermined range.

A printed structure comprises a device comprising device electrical contacts disposed on a common side of the device and a substrate non-native to the device comprising substrate electrical contacts disposed on a surface of the substrate. At least one of the substrate electrical contacts has a rounded shape. The device electrical contacts are in physical and electrical contact with corresponding substrate electrical contacts. The substrate electrical contacts can comprise a polymer core coated with a patterned contact electrical conductor on a surface of the polymer core. A method of making polymer cores comprising patterning a polymer on the substrate and reflowing the patterned polymer to form one or more rounded shapes of the polymer and coating and then patterning the one or more rounded shapes with a conductive material.

A printed structure comprises a device comprising device electrical contacts disposed on a common side of the device and a substrate non-native to the device comprising substrate electrical contacts disposed on a surface of the substrate. At least one of the substrate electrical contacts has a rounded shape. The device electrical contacts are in physical and electrical contact with corresponding substrate electrical contacts. The substrate electrical contacts can comprise a polymer core coated with a patterned contact electrical conductor on a surface of the polymer core. A method of making polymer cores comprising patterning a polymer on the substrate and reflowing the patterned polymer to form one or more rounded shapes of the polymer and coating and then patterning the one or more rounded shapes with a conductive material.

A method for estimating a thickness related to multiple conductive structural elements of an object, the method includes estimating a height difference between an upper surface of a conductive structural element and an upper surface of a photoresists layer portion that surrounds the conductive structural element, to provide multiple height differences; estimating thicknesses of the multiple photoresists layer portions, based at least on the second part of the emitted radiation; and calculating thickness values related to the multiple conductive structural elements, wherein the calculating is based at least on the multiple height differences and on the estimated thickness of the multiple photoresists layer portions.