Abstract: A connection component for use in making microelectronic element assemblies which has peelable leads that are formed on a dielectric support structure. One end of each lead is permanently connected to the support structure and the opposite end of the lead is releasably connected to the support structure. When the releasable end of the lead is bonded to a contact on a semiconductor chip, the releasable end of the lead can be peeled from the support structure such that the chip may be moved away from the support structure. A compliant layer may be disposed between the chip and the support structure. If a compliant material is injected between the chip and the support structure to form the compliant layer, the compliant material will lift the chip away from the support structure and facilitate the peeling of the leads from the support structure.

Abstract: One embodiment of the present invention is a structure useful for testing circuits that includes: (a) a substrate having contactors on a first side and pads on a second side; (b) a card having pads on a first side; and (c) interconnectors that electrically connect the pads on the second side of the substrate with the pads on the card; wherein at least one of the interconnectors includes at least a portion that does not melt at temperatures in a range from about 183° C. to about 230° C., and the distance between the substrate and the card is determined by a dimension of the at least a portion.

Abstract: One embodiment of the present invention is a structure useful for testing circuits that includes: (a) a flexible substrate having contactors on a first side and pads on a second side; (b) a rigid substrate having vias aligned with the pads on the second side of the flexible substrate; (c) an adhesive layer comprised of a compliant adhesive material having vias aligned with the pads on the second side of the flexible substrate; the adhesive layer being affixed to the flexible substrate and the rigid substrate; (d) a card; (e) electrical connectors that are retained in the vias of the rigid substrate and the adhesive layer, which electrical connectors have first and second retractable ends, wherein the first retractable ends contact pads on the substrate, and the second retractable ends contact pads on the card; and (f) a clamp that is adapted to fit over the substrate and the adhesive layer, the clamp having an opening to provide access to the contactors, wherein the clamp is connected to the card.

Abstract: A component incorporating a dielectric element such as a polymeric film with leads and terminals thereon is assembled with a semiconductor chip and bond regions of the leads are connected to contacts of the chip. At least one lead incorporates a plural set of connecting regions connecting the bond region of that lead to a plurality of terminals. One or more of the connecting regions in each such plural set are severed so as to leave less than all of the terminals associated with each such plural set connected to the contacts of the chip.

Abstract: By causing the movement of charge from a toner to a latent image carrier, the amount of charge of the toner is lowered to an amount of charge suitable for facilitating the transfer of toner so as to improve the transfer efficiency. For this, an image forming apparatus includes a latent image carrier and a developing means for forming a negatively chargeable toner layer composed of two stories or less on a toner carrier by a toner layer thickness regulating member. An electrostatic latent image on the latent image carrier is developed with the toner to form a visible image and the visible image is transferred to a transfer medium. Further, the work function (?opc) of the surface of the latent image carrier is set to be larger than the work function (?t) of the toner.

Abstract: A microelectronic assembly includes a microelectronic element having a first surface with a plurality of contacts accessible at the first surface, and a compliant layer over the first surface of the microelectronic element, the compliant layer including a plurality of bumped protrusions and openings adjacent the bumped protrusions for providing access to the contacts, wherein each bumped protrusion includes a top surface and at least one sloping edge. The microelectronic assembly also includes conductive terminals over the top surfaces of the bumped protrusions, and a plurality of conductive bond ribbons having first ends in engagement with the contacts, second ends in engagement with the terminals and intermediate sections extending along the sloping edges for electrically interconnecting the contacts and the terminals.

Abstract: A microelectronic package includes a microelectronic element having contacts accessible at a surface thereof, a layer overlying the microelectronic element, the layer having a first surface and a sloping peripheral edge extending away from the first surface of the layer, and conductive terminals overlying the microelectronic element, wherein the layer supports the conductive terminals over the microelectronic element. The package also includes conductive traces having first ends electrically connected with the contacts of the microelectronic element and second ends electrically connected with the conductive terminals, with at least one of the conductive traces having a section that is in contact with and extends along the sloping peripheral edge of the layer, and a compliant material disposed between the conductive terminals and the microelectronic element so that the conductive terminals are movable relative to the microelectronic element.

Abstract: A connection component for making connections to a microelectronic element is made by providing leads on a surface of a polymeric layer and etching the polymeric layer to partially detach the leads from the polymeric layer, leaving a portion of each lead releasably connected to the polymeric layer by a small polymeric connecting element which can be broken or peeled away from the lead. Leads in a connecting element may be covered by an insulating jacket applied by a coating process, and the insulating jacket may in turn be covered by a conductive layer so that each lead becomes a miniature coaxial cable. This arrangement provides immunity to interference and facilitates operation at high speeds.

Abstract: A connection component for making connections to a microelectronic element is made by providing leads on a surface of a polymeric layer and etching the polymeric layer to partially detach the leads from the polymeric layer, leaving a portion of each lead releasably connected to the polymeric layer by a small polymeric connecting element which can be broken or peeled away from the lead. Leads in a connecting element may be covered by an insulating jacket applied by a coating process, and the insulating jacket may in turn be covered by a conductive layer so that each lead becomes a miniature coaxial cable. This arrangement provides immunity to interference and facilitates operation at high speeds.

Abstract: A connection component for making connections to a microelectronic element is made by providing leads on a surface of a polymeric layer and etching the polymeric layer to partially detach the leads from the polymeric layer, leaving a portion of each lead releasably connected to the polymeric layer by a small polymeric connecting element which can be broken or peeled away from the lead. Leads in a connecting element may be covered by an insulating jacket applied by a coating process, and the insulating jacket may in turn be covered by a conductive layer so that each lead becomes a miniature coaxial cable. This arrangement provides immunity to interference and facilitates operation at high speeds.

Abstract: A component incorporating a dielectric element such as a polymeric film with leads and terminals thereon is assembled with a semiconductor chip and bond regions of the leads are connected to contacts of the chip. At least one lead incorporates a plural set of connecting regions connecting the bond region of that lead to a plurality of terminals. One or more of the connecting regions in each such plural set are severed so as to leave less than all of the terminals associated with each such plural set connected to the contacts of the chip.

Abstract: A connection component for making connections to a microelectronic element is made by providing leads on a surface of a polymeric layer and etching the polymeric layer to partially detach the leads from the polymeric layer, leaving a portion of each lead releasably connected to the polymeric layer by a small polymeric connecting element which can be broken or peeled away from the lead. Leads in a connecting element may be covered by an insulating jacket applied by a coating process, and the insulating jacket may in turn be covered by a conductive layer so that each lead becomes a miniature coaxial cable. This arrangement provides immunity to interference and facilitates operation at high speeds.

Abstract: A connection component for making microelectronic assemblies includes a dielectric structural layer having a first surface and a plurality of conductive leads having first and second ends overlying the first surface of the dielectric structural layer. An adhesive is provided between the second ends of the leads and the dielectric structural layer such that the adhesive forms connections between the second ends of the leads and the structural layer. The formed connections have areas smaller than the areas of the second ends. The second ends of the leads are releasably attached to the structural layer by the connections. Thus, the second ends of the leads may be engaged with features on a microelectronic device and the microelectronic elements may be moved away from the structural layer so as to bend the second ends of the leads away from the structural layer.

Abstract: The present invention provides a method for fabricating a compliant microelectronic device package and an associated apparatus for substantially obviating thermal, compliancy and interconnection problems. Flexible, dielectric layers are used having on a first surface a plurality conductive leads which are each electrically coupled at a first end to at least one conductive pad also coupled to the first surface of the dielectric layers. A second end of the conductive leads are further coupled between the dielectric layers across a bonding gap. A compliant layer is then coupled to the bottom surface of the dielectric layers. One of the dielectric layers is coupled to the surface of a die by one of the compliant layer such that the die bond pads are juxtaposed with respective leads in the bonding gap. This assembly is attached to a protective structure and is encapsulated. A solder mask may be placed over the exposed surface of the dielectric layers to cover the leads and prevent shoring.

Abstract: A connection component for making connections to a microelectronic element is made by providing leads on a surface of a polymeric layer and etching the polymeric layer to partially detach the leads from the polymeric layer, leaving a portion of each lead releasably connected to the polymeric layer by a small polymeric connecting element which can be broken or peeled away from the lead. Leads in a connecting element may be covered by an insulating jacket applied by a coating process, and the insulating jacket may in turn be covered by a conductive layer so that each lead becomes a miniature coaxial cable. This arrangement provides immunity to interference and facilitates operation at high speeds.

Abstract: A connection component for making microelectronic assemblies includes a dielectric structural layer having a first surface and a plurality of conductive leads having first and second ends overlying the first surface of the dielectric structural layer. An adhesive is provided between the second ends of the leads and the dielectric structural layer such that the adhesive forms connections between the second ends of the leads and the structural layer. The formed connections have areas smaller than the areas of the second ends. The second ends of the leads are releasably attached to the structural layer by the connections. Thus, the second ends of the leads may be engaged with features on a microelectronic device and the microelectronic elements may be moved away from the structural layer so as to bend the second ends of the leads away from the structural layer.

Abstract: A connection component for making microelectronic assemblies includes a dielectric structural layer having a first surface and a plurality of conductive leads having first and second ends overlying the first surface of the dielectric structural layer. An adhesive is provided between the second ends of the leads and the dielectric structural layer such that the adhesive forms connections between the second ends of the leads and the structural layer. The formed connections have areas smaller than the areas of the second ends. The second ends of the leads are releasably attached to the structural layer by the connections. Thus, the second ends of the leads may be engaged with features on a microelectronic device and the microelectronic elements may be moved away from the structural layer so as to bend the second ends of the leads away from the structural layer.

Abstract: A microelectronic assembly includes a microelectronic element having a first surface including a central region and a peripheral region surrounding the central region, the microelectronic element including a plurality of contacts disposed in the central region. The microelectronic assembly also includes a compliant layer overlying the peripheral region of the first surface, the compliant layer having a bottom surface facing toward the first surface of the microelectronic element, a top surface facing upwardly away from the first surface of the microelectronic element and one or more edge surfaces extending between the top and bottom surfaces of the compliant layer. A plurality of flexible bond ribbons are disposed over the compliant layer so that the bond ribbons extend over the top surface and one or more of the edge surfaces and the bond ribbons electrically connect the contacts to conductive terminals overlying the top surface of the compliant layer.

Abstract: A microelectronic component is made by providing a starting structure having a dielectric layer and leads on a surface of the dielectric layer. Ends of the leads are connected to contacts on a microelectronic element, such as the contacts on a semiconductor chip or wafer. The dielectric layer is then etched to partially detach the leads from the dielectric layer, leaving at least one end of each lead permanently connected to the dielectric layer. The remainder of the lead may be fully or partially detached from the dielectric layer. If the remainder of the lead is only partially detached, the connecting elements that connects the leads to the polymeric layer can be broken or peeled away from the leads during the step of moving the microelectronic element and dielectric layer away from one another.

Abstract: Semiconductor chip packages and methods of fabricating the same. The package includes a thermally conductive protective structure having an indentation open to a front side and a flange surface at least partially surrounding the indentation and facing to the front of the structure. A chip is disposed in the indentation so that the front surface of the chip, with contacts thereon, faces toward the front of the structure. A flexible dielectric film having terminals thereon is placed on the flange surface, and a compliant material is disposed between the film and the flange surface. The terminals on the film are connected to the contacts on the chip. The individual terminals on the film are movable with respect to the protective structure, which facilitates mounting and compensation for thermal expansion.