Abstract: Embodiments of a tri-stable flexure mechanism are described where a resilient component is present that serves as both a structural component in the kinematic chain of the mechanism and as energy storing component of the mechanism. The resilient component maintains a movable arm and an input link in either a first stable state or a second stable state when the ends of the resilient component are held in place so that the resilient component has a state of high elastic strain energy. In a third stable state, where the resilient component is in a relaxed state of lower elastic strain energy, the mechanism may be in a tripped state distinct from the closed and open states.

Abstract: Embodiments of a tri-stable flexure mechanism are described where a resilient component is present that serves as both a structural component in the kinematic chain of the mechanism and as energy storing component of the mechanism. The resilient component maintains a movable arm and an input link in either a first stable state or a second stable state when the ends of the resilient component are held in place so that the resilient component has a state of high elastic strain energy. In a third stable state, where the resilient component is in a relaxed state of lower elastic strain energy, the mechanism may be in a tripped state distinct from the closed and open states.

Abstract: A multi-layered interconnect structure and method of formation. In a first embodiment, first and second liquid crystal polymer (LCP) dielectric layers are directly bonded, respectively, to first and second opposing surface of a thermally conductive layer, with no extrinsic adhesive material bonding the thermally conductive layer with either the first or second LCP dielectric layer. In a second embodiment, first and second 2S1P substructures are directly bonded, respectively, to first and second opposing surfaces of a LCP dielectric joining layer, with no extrinsic adhesive material bonding the LCP dielectric joining layer with either the first or second 2S1P substructures.

Abstract: A multi-layered interconnect structure and method of formation. In a first embodiment, first and second liquid crystal polymer (LCP) dielectric layers are directly bonded, respectively, to first and second opposing surface of a thermally conductive layer, with no extrinsic adhesive material bonding the thermally conductive layer with either the first or second LCP dielectric layer. In a second embodiment, first and second 2S1P substructures are directly bonded, respectively, to first and second opposing surfaces of a LCP dielectric joining layer, with no extrinsic adhesive material bonding the LCP dielectric joining layer with either the first or second 2S1P substructures.

Abstract: A multi-layered interconnect structure and method of formation. In a first embodiment, first and second liquid crystal polymer (LCP) dielectric layers are directly bonded, respectively, to first and second opposing surface of a thermally conductive layer, with no extrinsic adhesive material bonding the thermally conductive layer with either the first or second LCP dielectric layer. In a second embodiment, first and second 2S1P substructures are directly bonded, respectively, to first and second opposing surfaces of a LCP dielectric joining layer, with no extrinsic adhesive material bonding the LCP dielectric joining layer with either the first or second 2S1P substructures.

Abstract: A security enclosure and method of forming the security enclosure. The security enclosure includes an electronic assembly, an extension, and a tamper respondent wrap. The extension has a first end inserted in the assembly and a second end having at least one bonding pad thereon. The tamper respondent wrap at least partially surrounds the assembly. The wrap has a bonding pad. The bonding pad of the extension is secured to the bonding pad of the wrap. The tamper respondent wrap includes a plurality of layers. A plurality of electrically conductive lines or a plurality of electrically conductive ink traces exist within each layer of the wrap.

Abstract: A multi-layered interconnect structure and method of formation. In a first embodiment, first and second liquid crystal polymer (LCP) dielectric layers are directly bonded, respectively, to first and second opposing surface of a thermally conductive layer, with no extrinsic adhesive material bonding the thermally conductive layer with either the first or second LCP dielectric layer. In a second embodiment, first and second 2S1P substructures are directly bonded, respectively, to first and second opposing surfaces of a LCP dielectric joining layer, with no extrinsic adhesive material bonding the LCP dielectric joining layer with either the first or second 2S1P substructures.

Abstract: A multi-layered interconnect structure and method of formation. In a first embodiment, first and second liquid crystal polymer (LCP) dielectric layers are directly bonded, respectively, to first and second opposing surface of a thermally conductive layer, with no extrinsic adhesive material bonding the thermally conductive layer with either the first or second LCP dielectric layer. In a second embodiment, first and second 2S1P substructures are directly bonded, respectively, to first and second opposing surfaces of a LCP dielectric joining layer, with no extrinsic adhesive material bonding the LCP dielectric joining layer with either the first or second 2S1P substructures.

Abstract: A method of forming a core for and forming a composite wiring board. The core has an electrically conductive coating on at least one face of a dielectric substrate. At least one opening is formed through the substrate extending from one face to the other and through each conductive coating. An electrically conductive material is dispensed in each of the openings extending through the conducting coating. At least a portion of the surface of the conductive coating on one face is removed to allow a nub of the conductive material to extend above the substrate face and any remaining conductive material to thereby form a core that can be electrically joined face-to-face with a second core member or other circuitized structure.

Abstract: An electronic package and method of formation. A thermally conductive layer having first and second opposing surfaces is provided. A first dielectric layer is laminated under pressurization to the first opposing surface of the thermally conductive layer, at a temperature between a minimum temperature T1MIN and a maximum temperature T1MAX. T1MAX constrains the ductility of the first dielectric layer to be at least D1 following the laminating. T1MAX depends on D1 and on a first dielectric material comprised by the first dielectric layer. A second dielectric layer is laminated under pressurization to the second opposing surface of the thermally conductive layer, at a temperature between a minimum temperature T2MIN and a maximum temperature T2MAX. T2MAX constrains the ductility of the second dielectric layer to be at least D2 following the laminating. T2MAX depends on D2 and on a second dielectric material comprised by the second dielectric layer.

Abstract: A method of forming a member for joining to form a composite wiring board. The member includes a dielectric substrate. Adhesive tape is applied to at least one face of said substrate. At least one opening is formed through the substrate extending from one face to the other and through each adhesive tape. An electrically conductive material is dispensed in each of the openings and partially cured. The adhesive tape is removed to allow a nub of the conductive material to extend above the substrate face to form a wiring structure with other elements.

Abstract: A multi-layered interconnect structure and method of formation. In a first embodiment, first and second liquid crystal polymer (LCP) dielectric layers are directly bonded, respectively, to first and second opposing surface of a thermally conductive layer, with no extrinsic adhesive material bonding the thermally conductive layer with either the first or second LCP dielectric layer. In a second embodiment, first and second 2S1P substructures are directly bonded, respectively, to first and second opposing surfaces of a LCP dielectric joining layer, with no extrinsic adhesive material bonding the LCP dielectric joining layer with either the first or second 2S1P substructures.

Abstract: A multilayered stack and method of formation. First and second dielectric layers are formed, respectively including first and second liquid crystal polymer (LCP) dielectric materials, with an electrically conductive plug through the first dielectric layer. A first and second electrical circuitization is formed in direct mechanical contact with a surface of the first and second dielectric layer, respectively, wherein the second electrical circuitization mechanically and electrically contacts an end of the plug, and wherein the plug is fluxlessly soldered to the first electrical circuitization.

Abstract: The present invention relates to a method for providing an interconnect between layers of a multilayer circuit board. A first via extending through a total thickness of a first layer is formed. The first via is totally filled with a first solid conductive plug and an end of the first solid conductive plug includes a first contact pad that is in contact with a surface of the first layer. A second via extending through a total thickness of a second layer is formed. The second via totally filling with a second solid conductive plug and an end of the second solid conductive plug includes a second contact pad that is in contact with a surface of the second layer. The second layer is electrically and mechanically coupled to the first layer by an electrically conductive adhesive that is in electrical and mechanical contact with both the end of the first plug and the end of the second plug.

Abstract: An electronic package and method of formation. A thermally conductive layer having first and second opposing surfaces is provided. A first dielectric layer is laminated under pressurization to the first opposing surface of the thermally conductive layer, at a temperature between a minimum temperature T1MIN and a maximum temperature T1MAX. T1MAX constrains the ductility of the first dielectric layer to be at least D1 following the laminating. T1MAX depends on D1 and on a first dielectric material comprised by the first dielectric layer. A second dielectric layer is laminated under pressurization to the second opposing surface of the thermally conductive layer, at a temperature between a minimum temperature T2MIN and a maximum temperature T2MAX. T2MAX constrains the ductility of the second dielectric layer to be at least D2 following the laminating. T2MAX depends on D2 and on a second dielectric material comprised by the second dielectric layer.

Abstract: A semiconductor device having a thermoset-containing, dielectric material and methods for fabricating the same is provided. The device may take the form of a printed circuit board, an integrated circuit chip carrier, or the like. The dielectric material is a non-fibrillated, fluoropolymer matrix that has inorganic particles distributed therein and is impregnated with a thermoset material.

Abstract: A method and apparatus for forming a security enclosure having improved fold retention. In particular, the enclosure is formed by folding a flexible tamper respondent cloth around an electronic assembly. An adhesive on the inner folded surfaces of the cloth temporarily retains the folds. The enclosure is then exposed to heat and pressure to promote improved adhesion strength of the adhesive, thereby improving fold retention.

Abstract: A method and structure relating to multisegmented plated through holes. A substrate includes a dielectric layer sandwiched between a first laminate layer and a second laminate layer. A through hole is formed through the substrate. The through hole passes through nonplatable dielectric material within the dielectric layer. As a result, subsequent seeding and electroplating of the through hole results in a conductive metal plating forming at a wall of the through hole on a segment of the first laminate layer and on a segment of the second laminate layer, but not on the nonplatable dielectric material of the dielectric layer. Thus, the conductive metal plating is not continuous from the first laminate layer to the second laminate layer.

Abstract: The present invention provides a security enclosure having an electronic assembly, such as a cryptographic processor card enclosed within an enclosure, surrounded by a tamper respondent wrap. The enclosure further includes a flexible extension cable which electrically connects the wrap and the assembly. The extension cable includes a plurality of interconnections at a first end to form an electrical connection with the assembly, and a plurality of bonding pads at a second end to form an electrical connection with a plurality of corresponding bonding pads of the wrap.

Abstract: A method of forming a member for joining to form a composite wiring board. The member includes a dielectric substrate. Adhesive tape is applied to at least one face of said substrate. At least one opening is formed through the substrate extending from one face to the other and through each adhesive tape. An electrically conductive material is dispensed in each of the openings and partially cured. The adhesive tape is removed to allow a nub of the conductive material to extend above the substrate face to form a wiring structure with other elements.