Abstract: The present disclosure relates to semiconductor structures and, more particularly, to dummy fill structures and methods of manufacture. The structure includes: a passive device formed in interlevel dielectric material; and a plurality of metal dummy fill structures composed of at least one main branch and two extending legs from at least one side of the main branch, the at least two extending legs being positioned and structured to suppress eddy currents of the passive device.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to dummy fill structures and methods of manufacture. The structure includes: a passive device formed in interlevel dielectric material; and a plurality of metal dummy fill structures composed of at least one main branch and two extending legs from at least one side of the main branch, the at least two extending legs being positioned and structured to suppress eddy currents of the passive device.

Abstract: Methods of fabricating an on-chip capacitor with a variable capacitance, as well as methods of adjusting the capacitance of an on-chip capacitor and design structures for an on-chip capacitor. The method includes forming first and second ports configured to be powered with opposite polarities, first and second electrodes, and first and second voltage-controlled units. The method includes configuring the first voltage-controlled unit to selectively couple the first electrode with the first port, and the second voltage-controlled unit to selectively couple the second electrode with the second port. When the first electrode is coupled by the first voltage-controlled unit with the first port and the second electrode is coupled by the second voltage-controlled unit with the second port, the capacitance of the on-chip capacitor increases.

Abstract: Methods of fabricating an on-chip capacitor with a variable capacitance, as well as methods of adjusting the capacitance of an on-chip capacitor and design structures for an on-chip capacitor. The method includes forming first and second ports configured to be powered with opposite polarities, first and second electrodes, and first and second voltage-controlled units. The method includes configuring the first voltage-controlled unit to selectively couple the first electrode with the first port, and the second voltage-controlled unit to selectively couple the second electrode with the second port. When the first electrode is coupled by the first voltage-controlled unit with the first port and the second electrode is coupled by the second voltage-controlled unit with the second port, the capacitance of the on-chip capacitor increases.

Abstract: Methods of fabricating an on-chip capacitor with a variable capacitance, as well as methods of adjusting the capacitance of an on-chip capacitor and design structures for an on-chip capacitor. The method includes forming first and second ports configured to be powered with opposite polarities, first and second electrodes, and first and second voltage-controlled units. The method includes configuring the first voltage-controlled unit to selectively couple the first electrode with the first port, and the second voltage-controlled unit to selectively couple the second electrode with the second port. When the first electrode is coupled by the first voltage-controlled unit with the first port and the second electrode is coupled by the second voltage-controlled unit with the second port, the capacitance of the on-chip capacitor increases.

Abstract: The specification discloses a method and a coupler for joining polymeric tubular objects, such as pipe. The coupler includes (a) a rigid, electromagnetically inductive carrier, (b) a temperature-responsive expandable material on the carrier, and (c) a polymeric material on the expandable material. The method includes the steps of (a) inserting the coupler into the ends of two adjacent polymeric tubular objects, (b) creating an electromagnetic field about the coupler causing the carrier to heat, in turn causing the expandable material to expand and force the polymeric material against the tubular objects, and further in turn causing the polymeric material to melt, soften, or liquefy, and (c) terminating the electromagnetic field allowing the polymeric material to cure or solidify to bond to the tubular objects.

Abstract: The specification discloses a method and a coupler for joining polymeric tubular objects, such as pipe. The coupler includes (a) a rigid, electromagnetically inductive carrier, (b) a temperature-responsive expandable material on the carrier, and (c) a polymeric material on the expandable material. The method includes the steps of (a) inserting the coupler into the ends of two adjacent polymeric tubular objects, (b) creating an electromagnetic field about the coupler causing the carrier to heat, in turn causing the expandable material to expand and force the polymeric material against the tubular objects, and further in turn causing the polymeric material to melt, soften, or liquefy, and (c) terminating the electromagnetic field allowing the polymeric material to cure or solidify to bond to the tubular objects.

Abstract: Methods of fabricating an on-chip capacitor with a variable capacitance, as well as methods of adjusting the capacitance of an on-chip capacitor and design structures for an on-chip capacitor. The method includes forming first and second ports configured to be powered with opposite polarities, first and second electrodes, and first and second voltage-controlled units. The method includes configuring the first voltage-controlled unit to selectively couple the first electrode with the first port, and the second voltage-controlled unit to selectively couple the second electrode with the second port. When the first electrode is coupled by the first voltage-controlled unit with the first port and the second electrode is coupled by the second voltage-controlled unit with the second port, the capacitance of the on-chip capacitor increases.

Abstract: On-chip capacitors with a variable capacitance, as well as design structures for a radio frequency integrated circuit, and method of fabricating and method of tuning on-chip capacitors. The on-chip capacitor includes first and second ports powered with opposite polarities, first and second electrodes, and first and second voltage-controlled units. Each of the first and second voltage-controlled units is switched between a first state in which the first and second electrodes are electrically isolated from the first and second ports and a second state. When the first voltage-controlled unit is switched to the second state, the first electrode is electrically connected with the first port. When the second voltage-controlled unit is switched to the second state the second electrode is electrically connected with the second port. The on-chip capacitor has a larger capacitance value when the first and second voltage-controlled units are in the second state.

Abstract: Back-end-of-line (BEOL) wiring structures that include an on-chip inductor and an on-chip capacitor, as well as design structures for a radiofrequency integrated circuit. The on-chip inductor and an on-chip capacitor, which are fabricated as conductive features in different metallization levels, are vertically aligned with each other. The on-chip capacitor, which is located between the on-chip inductor and the substrate, may serve as a Faraday shield for the on-chip inductor. Optionally, the BEOL wiring structure may include an optional Faraday shield located vertically either between the on-chip capacitor and the on-chip inductor, or between the on-chip capacitor and the top surface of the substrate. The BEOL wiring structure may include at least one floating electrode capable of being selectively coupled with the electrodes of the on-chip capacitor to permit tuning, during circuit operation, of a resonance frequency of an LC resonator that further includes the on-chip inductor.

Abstract: Methods for fabricating a back-end-of-line (BEOL) wiring structure that includes an on-chip inductor and an on-chip capacitor, as well as methods for tuning and fabricating a resonator that includes the on-chip inductor and on-chip capacitor. The fabrication methods generally include forming the on-chip capacitor and on-chip inductor in different metallization levels of the BEOL wiring structure and laterally positioned to be substantially vertical alignment. The on-chip capacitor may serve as a Faraday shield for the on-chip inductor. Optionally, a Faraday shield may be fabricated either between the on-chip capacitor and the on-chip inductor, or between the on-chip capacitor and the substrate. The BEOL wiring structure may include at least one floating electrode capable of being selectively coupled with the directly-connected electrodes of the on-chip capacitor for tuning, during circuit operation, a resonance frequency of an LC resonator that further includes the on-chip inductor.

Abstract: On-chip capacitors with a variable capacitance, as well as design structures for a radio frequency integrated circuit, and method of fabricating and method of tuning on-chip capacitors. The on-chip capacitor includes first and second ports powered with opposite polarities, first and second electrodes, and first and second voltage-controlled units. Each of the first and second voltage-controlled units is switched between a first state in which the first and second electrodes are electrically isolated from the first and second ports and a second state. When the first voltage-controlled unit is switched to the second state, the first electrode is electrically connected with the first port. When the second voltage-controlled unit is switched to the second state the second electrode is electrically connected with the second port. The on-chip capacitor has a larger capacitance value when the first and second voltage-controlled units are in the second state.

Abstract: Design structure embodied in a machine readable medium for designing, manufacturing, or testing a design. The design structure includes active circuitry on a substrate, a bond pad carried by the substrate, and a shielding structure disposed between the substrate and the bond pad. The shielding structure includes a plurality of electrically characterized devices configured to reduce noise transmission from the active circuitry to the bond pad.

Abstract: Back-end-of-line (BEOL) wiring structures that include an on-chip inductor and an on-chip capacitor, as well as design structures for a radiofrequency integrated circuit. The on-chip inductor and an on-chip capacitor, which are fabricated as conductive features in different metallization levels, are vertically aligned with each other. The on-chip capacitor, which is located between the on-chip inductor and the substrate, may serve as a Faraday shield for the on-chip inductor. Optionally, the BEOL wiring structure may include an optional Faraday shield located vertically either between the on-chip capacitor and the on-chip inductor, or between the on-chip capacitor and the top surface of the substrate. The BEOL wiring structure may include at least one floating electrode capable of being selectively coupled with the electrodes of the on-chip capacitor to permit tuning, during circuit operation, of a resonance frequency of an LC resonator that further includes the on-chip inductor.

Abstract: Methods for fabricating a back-end-of-line (BEOL) wiring structure that includes an on-chip inductor and an on-chip capacitor, as well as methods for tuning and fabricating a resonator that includes the on-chip inductor and on-chip capacitor. The fabrication methods generally include forming the on-chip capacitor and on-chip inductor in different metallization levels of the BEOL wiring structure and laterally positioned to be substantially vertical alignment. The on-chip capacitor may serve as a Faraday shield for the on-chip inductor. Optionally, a Faraday shield may be fabricated either between the on-chip capacitor and the on-chip inductor, or between the on-chip capacitor and the substrate. The BEOL wiring structure may include at least one floating electrode capable of being selectively coupled with the directly-connected electrodes of the on-chip capacitor for tuning, during circuit operation, a resonance frequency of an LC resonator that further includes the on-chip inductor.

Abstract: Design structure embodied in a machine readable medium for designing, manufacturing, or testing a design. The design structure includes active circuitry on a substrate, a bond pad carried by the substrate, and a shielding structure disposed between the substrate and the bond pad. The shielding structure includes a plurality of electrically characterized devices configured to reduce noise transmission from the active circuitry to the bond pad.

Abstract: Semiconductor device structures and methods for shielding a bond pad from electrical noise generated by active circuitry of an integrated circuit carried on a substrate. The structure includes electrically characterized devices placed in a pre-determined arrangement under the bond pad. The pre-determined arrangement of the electrically characterized devices provides for a consistent high frequency environment under the bond pad, which simplifies modeling of the bond pad by a circuit designer.

Abstract: A plug-in lamp socket assembly is provided that maintains connections sealed to the environment between the electrical lamp leads, electrical socket contacts and circuits of the circuit carrier. The assembly has a lamp socket member for receiving a lamp in an aligned manner. A cap plate connects to the lamp socket member and is non-removable therefrom. The lamp socket has tabs that require proper alignment of the tabs for insertion into a circuit carrier having circuits molded therein. An O-ring seals the removable connection between the lamp socket, cap plate, assembly and the circuit carrier. The circuit carrier is sealed to the lens housing.

Abstract: A plug-in lamp socket assembly is provided that maintains connections sealed to the environment between the electrical lamp leads, electrical socket contacts and circuits of the circuit carrier. The assembly has a lamp socket member for receiving a lamp in an aligned manner. A cap plate connects to the lamp socket member and is non-removable therefrom. The lamp socket has tabs that require proper alignment of the tabs for insertion into a circuit carrier having circuits molded therein. An O-ring seals the removable connection between the lamp socket, cap plate, assembly and the circuit carrier. The circuit carrier is sealed to the lens housing.

Abstract: Improved imide-containing copolymers comprising, in the aromatic diamine component, p-phenylene diamine and at least one additional aromatic diamine have increased rigidity and useful processability. The copolymers of this invention also may exhibit improved resistance to the detrimental effects of humid environments and retain mechanical properties at elevated temperatures after exposure to humid environments.