Abstract: A connector for electrically connecting to conductive structures formed on a semiconductor device includes a core including an isolation layer and signal vias and ground vias formed in the isolation layer; a first ground plane formed on a surface of or in the core and electrically connected to the ground vias; a first set of contact elements formed on a first surface of the core and electrically connected to the signal vias to form signal pins; a second set of contact elements formed on the first surface and electrically connected to a subset of the ground vias to form ground pins. The remaining ground vias without contact elements form buried ground vias. The first and second sets of contact elements are arranged on the first surface of the core to surround each signal pin by at least one adjacent ground pin and one or more adjacent buried ground vias.

Abstract: Disclosed is an electrical connector having a substrate and movable electrical contacts which are mounted to the substrate and extend a distance D from the substrate. A layer of compressible material (such as a foam or elastomeric material) is positioned on the substrate adjacent at least some of the electrical contacts and ideally has an uncompressed thickness slightly greater than the distance D to provide for protection of the electrical contacts. When a mating electrical device such as an electrical connector or other circuit member is mated to the electrical connector with its electrical contacts and its layer of compressible material, the layer of compressible material is compressed to a thickness less than the distance D, allowing the contacts to make a suitable electrical interconnection to the mating electrical device.

Abstract: Disclosed is an electrical connector having a substrate and movable electrical contacts which are mounted to the substrate and extend a distance D from the substrate. A layer of compressible material (such as a foam or elastomeric material) is positioned on the substrate adjacent at least some of the electrical contacts and ideally has an uncompressed thickness slightly greater than the distance D to provide for protection of the electrical contacts. When a mating electrical device such as an electrical connector or other circuit member is mated to the electrical connector with its electrical contacts and its layer of compressible material, the layer of compressible material is compressed to a thickness less than the distance D, allowing the contacts to make a suitable electrical interconnection to the mating electrical device.

Abstract: Disclosed is an electrical connector having a substrate and movable electrical contacts which are mounted to the substrate and extend a distance D from the substrate. A layer of compressible material (such as a foam or elastomeric material) is positioned on the substrate adjacent at least some of the electrical contacts and ideally has an uncompressed thickness slightly greater than the distance D to provide for protection of the electrical contacts. When a mating electrical device such as an electrical connector or other circuit member is mated to the electrical connector with its electrical contacts and its layer of compressible material, the layer of compressible material is compressed to a thickness less than the distance D, allowing the contacts to make a suitable electrical interconnection to the mating electrical device.

Abstract: The present invention is an electrical connector in which a substrate (such as a printed circuit board or PCB) includes a plurality of apertures (or vias) and some of those apertures are filled with two materials to improve the characteristics of the electrical interconnection. The preferred process of crating the filled vias includes the steps of plating the vias with an electrically-conductive material to create an electrically-conductive path between portions of the substrate and components associated with the substrate and partially filling the apertures, then filling at least a portion of the apertures or vias with a second or different filling material to seal at least apart of the electrically conductive path through the plating. The second filling material may be chosen to provide thermal compensation for the connection.

Abstract: The present invention is an electrical connector in which a substrate (such as a printed circuit board or PCB) includes a plurality of apertures (or vias) and some of those apertures are filled with two materials to improve the characteristics of the electrical interconnection. The preferred process of crating the filled vias includes the steps of plating the vias with an electrically-conductive material to create an electrically-conductive path between portions of the substrate and components associated with the substrate and partially filling the apertures, then filling at least a portion of the apertures or vias with a second or different filling material to seal at least apart of the electrically conductive path through the plating. The second filling material may be chosen to provide thermal compensation for the connection.

Abstract: A method for producing scalable, low cost, reliable, compliant, low profile, low insertion force, high-density, separable and reconnectable interposer for high speed, high performance electronic circuitry and semiconductors. The method can be used to make, for example, electrical connections from components such as a Printed Circuit Board (PCB) to another PCB, MPU, NPU, or other semiconductor device. A normalized working range for an array of elastic contacts of the interposer can be about 0.2 to 1.0. A reversible normalized working range is maintained through multiple connections and reconnections using a highly elastic material for the contact arms. In one aspect, a first electrical component having a first array pitch can be connected to a second electrical component having a second array pitch.

Abstract: A connector for electrically connecting to pads formed on a semiconductor device includes a substrate and an array of contact elements of conductive material formed on the substrate. Each contact element includes a base portion attached to the top surface of the substrate and a curved spring portion extending from the base portion and having a distal end projecting above the substrate. The curved spring portion is formed to curve away from a plane of contact and has a curvature disposed to provide a controlled wiping action when engaging a respective pad of the semiconductor device.

Abstract: A Flat Flex Connector (FFC) has connector flanges embedded in its insulated electrical traces. The flanges engage electrical circuits in a camera module such as a CMOS or CCD and are clamped into electrical engagement. The opposite end of the FFC makes electrical contact with another electrical device such as a semiconductor circuit. The assembly allows electrical connection of two or more devices in a confined space in which the electrical device are not easily aligned for electrical contact.

Abstract: A system for batch forming a sheet of spring elements in three dimensions is described. A spring element sheet containing spring elements defined in two dimensions is arranged between two mating die press plates. A force is applied to the mating die press plates to form the two-dimensional spring contact elements into three dimensions. Alternatively, configurable die press plates are used to selectively form a two-dimensional spring element sheet into three-dimensional spring contacts.

Abstract: An elastic contact array circuitized substrate includes a circuitized substrate provided with circuit traces, and an array of three dimensional contact elements joined to the circuitized substrate and electrically coupled to the circuit traces. In one configuration, the array of three dimensional contacts are formed in a spring sheet material having anisotropic grains whose long direction is selected with respect to the longitudinal direction of elastic contact arms, in accordance with desired properties. In another configuration of the invention, the circuit traces are formed integrally within the spring sheet material.

Abstract: An electrical connector made up of an array of metallic contacts that act as conductive carriers, each attached to a flexible insulating sheet in one of an array of openings provided in the flexible sheet. The metallic contacts have portions disposed on opposite sides of the flexible insulating sheet that form a contact channel region that retains a rim portion surrounding an opening. The electrical connector provides a flexible carrier for the contacts to conform to irregular mating surfaces of components to be joined. For a given contact height, the electrical connector further provides a minimum electrical path length for components connected by the contacts board. In one aspect, the metallic contacts including at least one side containing elastic portions are formed from sheets of conductive material. In one aspect, circular shaped contacts are singulated after opposing conductive sheets are joined in regions within the openings of the flexible insulating sheet.

Abstract: An elastic contact array circuitized substrate includes a circuitized substrate provided with circuit traces, and an array of three dimensional contact elements joined to the circuitized substrate and electrically coupled to the circuit traces. In one configuration, the array of three dimensional contacts are formed in a spring sheet material having anisotropic grains whose long direction is selected with respect to the longitudinal direction of elastic contact arms, in accordance with desired properties. In another configuration of the invention, the circuit traces are formed integrally within the spring sheet material.

Abstract: A method for making a contact begins by providing a sheet of material. A portion of the sheet is deep drawn to form a cavity having at least one side wall, the cavity extending away from a rim formed by a non-drawn portion of the sheet. At least one spring member is defined from the at least one side wall and is bent such that at least a portion of the at least one spring member extends beyond the rim.

Abstract: A system for batch forming a sheet of spring elements in three dimensions includes a top spacer layer. A plurality of ball bearings is arranged in a predetermined pattern on the top spacer layer. A spring element sheet containing the spring elements defined in two dimensions is positioned on the top spacer layer and the plurality of ball bearings. A top spacer layer is positioned on the spring element sheet. The top spacer layer and the bottom support layer are adapted to have a force applied thereto to push the plurality of ball bearings against the spring element sheet, such that the spring elements extend above the plane of the spring element sheet, thereby forming the spring elements in three dimensions.

Abstract: A compliant, scalable, thermal-electrical-mechanical, flexible electrical connector. In one configuration, the flexible electrical connector comprises a flexible substrate, a first and second conductive layer, and a plating contiguously applied over the conductive layers and holes through the substrate. The first and second conductive layers are adhered to opposite sides of the flexible substrate and have a plurality of raised contact elements in registration with at least a subset of the holes. At least some contact elements on the first and second conductive layers that oppose each other are in electrical communication with one another by way of the plating.

Abstract: A method for fabricating an electrical connector made up of an array of metallic contacts that act as conductive carriers, each attached to a flexible insulating sheet in one of an array of openings provided in the flexible sheet. The metallic contacts have portions disposed on opposite sides of the flexible insulating sheet that form a contact channel region that retains a rim portion surrounding an opening. The electrical connector provides a flexible carrier for the contacts to conform to irregular mating surfaces of components to be joined. For a given contact height, the electrical connector further provides a minimum electrical path length for components connected by the contacts board. In one aspect, the metallic contacts including at least one side containing elastic portions are formed from sheets of conductive material. In one aspect, circular shaped contacts are singulated after opposing conductive sheets are joined in regions within the openings of the flexible insulating sheet.

Abstract: A scalable, low cost, reliable, compliant, low profile, low insertion force, high-density, separable and reconnectable connector for high speed, high performance electronic circuitry and semiconductors. The electrical connector can be used to make, for example, electrical connections from components such as a Printed Circuit Board (PCB) to another PCB, MPU, NPU, or other semiconductor device. A normalized working range for an array of elastic contacts of the interposer can be about 0.2 to 1.0. A reversible normalized working range is maintained through multiple connections and reconnections using a highly elastic material for the contact arms. In one aspect, a first electrical component having a first array pitch can be connected to a second electrical component having a second array pitch.

Abstract: An architecture for increasing the normalized working range of connectors having arrays of small contacts. One configuration includes a plurality of pairs of opposed contacts that are arranged in a staggered fashion. The opposed contacts are configured to engage an external contact array in a staggered fashion. The contact arm length of elastic contacts can be substantially greater than the effective array pitch of the plurality of pairs of opposed contacts. Accordingly, the vertical displacement range of three dimensional contacts formed in the connector can be much greater than for in-line contact arrangements.

Abstract: An electrical interposer including first and second surfaces is provided. A plurality of compliant pins are connected to the first surface of the substrate, each of the compliant pins having a drawn body with at least one side wall extending along a longitudinal axis thereof substantially perpendicular to the substrate. A plurality of contact elements are connected to the substrate for making electrical contact with a device facing the second surface of the substrate. Electrical paths connect the compliant pins to the contact elements.