Abstract: A configurable antenna for a software defined radio including a first antenna unit having a first antenna element for receiving a first electromagnetic signal in a first frequency band wherein the first frequency band corresponds to a first mode of operation of a software defined radio, an interface unit having a first connector to couple the first electromagnetic signal from the first antenna unit and a second connector to couple the first electromagnetic signal to the software defined radio, an enclosure configured to receive the interface unit within an internal cavity, and a retention bracket configured to mechanically retain the interface unit within the enclosure, the retention bracket having at least one hole for allowing the first connector to conductively contact the antenna unit.

Abstract: A method for a low profile multi-IC chip package for high-speed applications comprises a connector for electrically connecting the equivalent outer leads of a set of stacked primary semiconductor packages. In one embodiment, the connector comprises a two-part sheet of flexible insulative polymer with buses formed on one side. In another embodiment, the connector comprises multiple buses formed from conductive polymer. In further embodiments, the primary packages are stacked within a cage and have their outer leads in unattached contact with buses within the cage or, alternatively, are directly fixed to leads or pads on the host circuit board.

Abstract: A stacked multiple offset chip device is formed of two or more dice of similar dimensions and bond pad arrangement, in which bond pads are located in fields along less than three edges of the active surface of each die. A first die is attached to a substrate and subsequent die or dice are attached in a vertical sequence atop the first die, each in an offset configuration from the next lower die to expose the bond pads thereof for conductive bonding to metallization of the substrate. The multiple chip device permits a plurality of dice to be stacked in a maximum density low profile device. A particularly useful application is the formation of stacked mass storage flash memory package.

Abstract: A multi-part lead frame semiconductor device assembly is disclosed including a die bonded to a die paddle. A second lead frame including leads is superimposed and bonded onto the first lead frame. Also disclosed is a method for fabricating the multi-part lead frame semiconductor device assembly which utilizes equipment designed for single lead frame processing. If desired, the materials for the multi-part lead frame may be dissimilar.

Abstract: A multi-part lead frame semiconductor device assembly is disclosed including a die bonded to a die paddle. A second lead frame including leads is superimposed and bonded onto the first lead frame. Also disclosed is a method for fabricating the multi-part lead frame semiconductor device assembly which utilizes equipment designed for single lead frame processing. If desired, the materials for the multi-part lead frame may be dissimilar.

Abstract: A ball grid array (BGA) package that includes a central cavity for receiving a semiconductor die therein is disclosed. The die rests on a base laminate, the die side of which includes traces therein extending into the cavity, which is framed at least by an anisotropically conductive adhesive layer. Bond pads on the die are electrically connected, to the traces. The traces are, in turn, electrically connected through conductive vias to conductive element sites on the opposite side of the base laminate through a dielectric layer, the conductive element sites carrying solder balls or other discrete conductive bonding elements for connection to higher-level packaging. A ground plane, may extend over the adhesive layer and frame the cavity, or also extend over the cavity to provide an enclosure for the die. In the former case, an encapsulant is applied over the die and electrical connections to the traces.

Abstract: A multi-part lead frame semiconductor device assembly is disclosed including a die bonded to a die paddle. A second lead frame, including leads, is superimposed and bonded onto the first lead frame. Also disclosed is a method for fabricating the multi-part lead frame semiconductor device assembly which utilizes equipment designed for single lead frame processing. If desired, the materials for the multi-part lead frame may be dissimilar.

Abstract: A LOC die assembly and method is disclosed including a die dielectrically adhered to the underside of a lead frame. The lead frame has stress relief slots formed in the undersides of the lead elements proximate the adhesive to accommodate filler particles lodged between the leads and the active surface of the die during transfer molding of a plastic encapsulant. The increased space created by the slots and flexure in the leads about the slots reduces point stresses on the active surface of the die by the filler particles. The increased flexure in the leads about the slots further enhances the locking of the leads in position with respect to the die.

Abstract: An inventive integrated circuit package includes a package body, such as a transfer molded plastic or preformed ceramic package body, having an integrated circuit die positioned therein. A lead frame, such as a peripheral lead, Leads-Over-Chip (LOC), or Leads-Under-Chip (LUC) lead frame, includes a plurality of leads with portions enclosed within the package body that electrically connect to the integrated circuit die. A heat sink is positioned at least partially within the package body so a surface of a first portion of the heat sink faces the lead frame in close proximity to a substantial part, such as at least eighty percent, of the area of the enclosed portion of the lead frame to thereby substantially reduce an inductance associated with each of the leads.

Abstract: A substrate includes first and second regions over which first and second semiconductor devices are to be respectively positioned. The first region is located at least partially within the second region. Contact areas are located external to the first region but within the second region. In one embodiment, in which semiconductor devices are to be stacked over and secured to the substrate in a flip-chip type arrangement, the contact areas correspond to bond pads of an upper, second semiconductor device, while other contact areas located within the first region correspond to bond pads of a lower, first semiconductor device. In another embodiment, the contact areas correspond to bond pads of the first semiconductor device, which are electrically connected thereto by way of laterally extending discrete conductive elements, while other contact areas that are located external to the second region correspond to bond pads of the upper, second semiconductor device.

Abstract: A stacked assembly of integrated circuit semiconductor devices includes a stack of integrated circuit semiconductor devices supported by a printed circuit board (PCB). One or more multiconductor insulating assemblies provide an interface between terminals of the integrated circuit semiconductor devices and external circuitry.

Abstract: A method for a low profile multi-IC chip package for high-speed applications comprises a connector for electrically connecting the equivalent outer leads of a set of stacked primary semiconductor packages. In one embodiment, the connector comprises a two-part sheet of flexible insulative polymer with buses formed on one side. In another embodiment, the connector comprises multiple buses formed from conductive polymer. In further embodiments, the primary packages are stacked within a cage and have their outer leads in unattached contact with buses within the cage or, alternatively, are directly fixed to leads or pads on the host circuit board.

Abstract: A rerouting element for a semiconductor device includes a substantially planar member that carries at least one contact location, at least one conductive, at least one rerouted bond pad. The contact location is positioned adjacent to a first periphered edge of the substantially planar member and at a location that corresponds to the location of a bond pad of a semiconductor device with which the rerouting element is to be used. The at least one conductive element, which communicates with the at least one contact location, reroutes the bond pad location of the semiconductor device to a corresponding rerouted bond pad location adjacent to a second one peripheral edge of the rerouted substantially planar member which is opposite the first periphered edge. In addition, assemblies including rerouting elements and methods for designing and using rerouting elements are disclosed.

Abstract: A multi-part lead frame semiconductor device assembly is disclosed including a die bonded to a die paddle. A second lead frame including leads is superimposed and bonded onto the first lead frame. Also disclosed is a method for fabricating the multi-part lead frame semiconductor device assembly which utilizes equipment designed for single lead frame processing. If desired, the materials for the multi-part lead frame may be dissimilar.

Abstract: A rerouting element for a semiconductor device includes a dielectric film that carries conductive vias, conductive elements, and contact pads. The conductive vias are positioned at locations that correspond to the locations of bond pads of a semiconductor device with which the rerouting element is to be used. The conductive elements, which communicate with corresponding conductive vias, reroute the bond pad locations to corresponding contact pad locations adjacent to one peripheral edge or two adjacent peripheral edges of the rerouted semiconductor device. The rerouting element is particularly useful for rerouting centrally located bond pads of a semiconductor device, as well as for rerouting the peripheral locations of bond pads of a semiconductor device to one or two adjacent peripheral edges thereof. In addition, methods for designing and using rerouting elements are disclosed.

Abstract: A ball grid array (BGA) package that includes a central cavity for receiving a semiconductor die therein is disclosed. The die rests on a base laminate, the die side of which includes traces therein extending into the cavity, which is framed at least by an anisotropically conductive adhesive layer. Bond pads on the die are electrically connected, as by wire bonds or, in the case of a flip-chip configured die, solder balls or conductive adhesive elements, to the traces. The traces are, in turn, electrically connected through conductive vias to conductive element sites on the opposite side of the base laminate through a dielectric layer, the conductive element sites carrying solder balls or other discrete conductive bonding elements for connection to higher-level packaging.

Abstract: A technique for making an integrated circuit package. Specifically, a stacked memory device is provided with minimal interconnects. Memory die are stacked on top of each other and electrically coupled to a substrate. Thru vias are provided in the substrate and/or memory die to facilitate the electrical connects without necessitating a complex interconnect technology between each of the interfaces. Wire bonds are used to complete the circuit package.

Abstract: Methods of manufacturing a semiconductor structure are provided. The method comprises the steps of providing a first substrate having a first surface, providing a semiconductor device, electrically and physically coupling the semiconductor device to the first surface of said first substrate, providing a second substrate having a first surface, a second surface, and a cavity formed in said first surface, positioning the second substrate over said first substrate, and coupling the second substrate to the first substrate such that the semiconductor device is positioned at least partially within the cavity.

Abstract: A multi-part lead frame semiconductor device assembly is disclosed including a die bonded to a die paddle. A second lead frame including leads is superimposed and bonded onto the first lead frame. Also disclosed is a method for fabricating the multi-part lead frame semiconductor device assembly which utilizes equipment designed for single lead frame processing. If desired, the materials for the multi-part lead frame may be dissimilar.

Abstract: A multichip semiconductor package and method of making is provided that has a plurality of semiconductor chips fabricated in electrical isolation one from another integrally on a singular coextensive substrate useful for numerous and varied semiconductor chip applications. The semiconductor chips, instead of being singulated into a plurality of single-chip packages, are kept as integrally formed together and are thereafter electrically connected together so as to form a larger circuit. Encapsulation follows so as to form a single, multichip package. Common signals of the plurality of semiconductor chips are bussed together in electrical common across the substrate to a common electrode suitable for electrically providing the signal to another, external circuit, such as a PWB. The common bussing is achieved by conductive leads disposed across the substrate in pair sets having an extended portion that accommodates the common electrode in contact therewith.