Abstract: A circuit package may include an upper surface of first conductive elements and second conductive elements. The first conductive elements may receive input/output signals from respective conductive elements of an integrated circuit die, and the second conductive elements may receive a first plurality of the input/output signals from respective ones of the first conductive elements. A lower surface of the package may include third conductive elements, the third conductive elements to receive a second plurality of the input/output signals from respective other ones of the first conductive elements.

Abstract: A circuit package may include an upper surface of first conductive elements and second conductive elements. The first conductive elements may receive input/output signals from respective conductive elements of an integrated circuit die, and the second conductive elements may receive a first plurality of the input/output signals from respective ones of the first conductive elements. A lower surface of the package may include third conductive elements, the third conductive elements to receive a second plurality of the input/output signals from respective other ones of the first conductive elements.

Abstract: Adhesive material is applied to a surface of a metallic core layer. The adhesive material is removed from a conductive region of the metallic core layer. A metallic contact is provided over the conductive region of the metallic core layer. The metallic core layer is laminated to an imprinted buildup layer, the buildup layer having a dielectric region and a conductive region, wherein a nonconductive region of the metallic core layer is bonded to the dielectric region of the buildup layer and the conductive region of the metallic core layer is bonded to the conductive region of the imprinted-buildup layer.

Abstract: Numerous embodiments of a method and apparatus for forming an imprinting tool are disclosed. In one embodiment, a method of forming an imprinting tool comprises forming a first mold by use of one or more printing processes, forming a second mold from the first mold, and forming an imprinting tool from the second mold, where the imprinting tool is formed at least in part by metalizing at least a portion of the second mold.

Abstract: To decrease the complexity, time, and cost of fabricating an electronics package, and to potentially increase the quality and decrease the size thereof, the package includes at least one electronic component mounted on a substrate formed through imprinting. In an embodiment, the substrate may comprise conductive traces, vias, and patterns of lands on one or more layers. Conductor features of different geometries may be formed by imprinting them simultaneously on one or both surfaces of an imprintable tape. Fabrication apparatus and methods, as well as application of the imprinted package to an electronic assembly, are also described.

Abstract: To decrease the complexity, time, and cost of fabricating an electronics package, and to potentially increase the quality and decrease the size thereof, the package includes at least one electronic component mounted on an imprinted substrate. In an embodiment, the substrate may comprise conductive traces, vias, and patterns of lands on one or more layers. Such features may be formed by imprinting in one operation rather than sequentially. Conductor features, such as trenches, holes, and planes, may be formed of different sizes simultaneously. Methods of fabrication, as well as application of the imprinted package to an electronic assembly, are also described.

Abstract: Adhesive material is applied to a surface of a metallic core layer. The adhesive material is removed from a conductive region of the metallic core layer. A metallic contact is provided over the conductive region of the metallic core layer. The metallic core layer is laminated to an imprinted buildup layer, the buildup layer having a dielectric region and a conductive region, wherein a nonconductive region of the metallic core layer is bonded to the dielectric region of the buildup layer and the conductive region of the metallic core layer is bonded to the conductive region of the imprinted-buildup layer.

Abstract: A capacitor (FIGS. 6-9) includes one or more extended surface lands (604, 704, 804, 904, FIGS. 6-9). In one embodiment, each extended surface land is a land on a top or bottom surface of the capacitor, having a land length that is equal to at least 30% of the width (614, FIG. 6) of the capacitor or 20% of the length (914, FIG. 9) of the capacitor. When embedded within an integrated circuit package (1102, FIG. 11), two or more vias (1112) can be electrically connected to the extended surface lands (1108).

Abstract: A thin film capacitor provides an interposer substrate between an integrated circuit die and an organic substrate. The interposer substrate includes a first conductive layer deposited on a base substrate layer. A portion of the first conductive layer provides a first electrode region serving as a first plate of the capacitor. Portions of a second conductive layer forming a second electrode region serving as a second plate of the capacitor. A dielectric layer is disposed between the first and second conductive layers to provide for capacitive regions between the first electrode region and the second electrode region. The base substrate layer and die may be based on similar semiconductor materials, such as Silicon or Gallium Arsenide, to provide an improved coefficient of thermal expansion match.

Abstract: A capacitor (FIGS. 6-9) includes one or more extended surface lands (604, 704, 804, 904, FIGS. 6-9). In one embodiment, each extended surface land is a land on a top or bottom surface of the capacitor, having a land length that is equal to at least 30% of the width (614, FIG. 6) of the capacitor or 20% of the length (914, FIG. 9) of the capacitor. When embedded within an integrated circuit package (1102, FIG. 11), two or more vias (1112) can be electrically connected to the extended surface lands (1108).

Abstract: An electronic package (302, FIG. 3) includes one or more capacitors (308) embedded within one or more layers (310) of the package. The embedded capacitors are discrete devices, such as integrated circuit capacitors (FIGS. 17-18) or ceramic capacitors. During the package build-up process, the capacitors are mounted (410, FIG. 4) to a package layer, and a non-conductive layer is applied (412) over the capacitors. When the build-up process is completed, the capacitor's terminals (604, 608, FIG. 6) are electrically connected to the top surface of the package. The embedded capacitor structure can be used in an integrated circuit package (1904, FIG. 19), an interposer (1906), and/or a printed circuit board (1908).

Abstract: To accommodate the operational and structural requirements of high performance integrated circuits, an integrated circuit package includes conductive trenches that are formed within a substrate. The trenches provide increased current carrying capacity, lower inductance, higher capacitance, and single and/or dual reference planes for signal conductors. Trench structures can be provided at various locations within the substrate, such as adjacent to signal conductors and embedded capacitors, as well as on the substrate periphery to couple the package to a socket. Trenches can be formed by routing, drilling, imprinting, and/or microperforation. Methods of fabrication, as well as application of the package to an electronic assembly and to an electronic system, are also described.