Abstract: An electrostatic discharge (ESD) protection circuit for providing ESD protection to an ESD protected circuit. The protection circuit comprises a signal pad and a crossover network for separating wanted electrical data signals and ESD signals according to their frequency. The protection circuit further comprises a first branch configured to transmit at least a spectral part of the wanted electrical data signals between the signal pad and the ESD protected circuit and a second branch configured to receive the ESD signals from the signal pad. Additionally there is provided a corresponding method, a corresponding integrated circuit chip and a corresponding design structure.

Abstract: The invention relates to a wafer prober including an optical waveguide, the optical waveguide having a first optical coupling end segment with a first optical coupling surface being devoid of cladding. The first optical coupling end segment being configured to provide an adiabatic optical coupling to a second optical coupling end segment of a second optical waveguide of a photonic integrated circuit on a semiconductor wafer when the optical waveguide is aligned with respect to the semiconductor wafer according to a set of alignment requirements. The second optical coupling end segment having a second optical coupling surface that is devoid of cladding. The second optical coupling surface is parallel to a wafer surface of the semiconductor wafer. An alignment system configured to align the optical waveguide with respect to the semiconductor wafer according to the set of alignment requirements.

Abstract: An electrostatic discharge (ESD) protection circuit for providing ESD protection to an ESD protected circuit. The protection circuit comprises a signal pad and a crossover network for separating wanted electrical data signals and ESD signals according to their frequency. The protection circuit further comprises a first branch configured to transmit at least a spectral part of the wanted electrical data signals between the signal pad and the ESD protected circuit and a second branch configured to receive the ESD signals from the signal pad. Additionally there is provided a corresponding method, a corresponding integrated circuit chip and a corresponding design structure.

Abstract: The invention relates to a wafer prober including an optical waveguide, the optical waveguide having a first optical coupling end segment with a first optical coupling surface being devoid of cladding. The first optical coupling end segment being configured to provide an adiabatic optical coupling to a second optical coupling end segment of a second optical waveguide of a photonic integrated circuit on a semiconductor wafer when the optical waveguide is aligned with respect to the semiconductor wafer according to a set of alignment requirements. The second optical coupling end segment having a second optical coupling surface that is devoid of cladding. The second optical coupling surface is parallel to a wafer surface of the semiconductor wafer. An alignment system configured to align the optical waveguide with respect to the semiconductor wafer according to the set of alignment requirements.

Abstract: The invention relates to a wafer prober including an optical waveguide, the optical waveguide having a first optical coupling end segment with a first optical coupling surface being devoid of cladding. The first optical coupling end segment being configured to provide an adiabatic optical coupling to a second optical coupling end segment of a second optical waveguide of a photonic integrated circuit on a semiconductor wafer when the optical waveguide is aligned with respect to the semiconductor wafer according to a set of alignment requirements. The second optical coupling end segment having a second optical coupling surface that is devoid of cladding. The second optical coupling surface is parallel to a wafer surface of the semiconductor wafer. An alignment system configured to align the optical waveguide with respect to the semiconductor wafer according to the set of alignment requirements.

Abstract: The invention relates to a wafer prober including an optical waveguide, the optical waveguide having a first optical coupling end segment with a first optical coupling surface being devoid of cladding. The first optical coupling end segment being configured to provide an adiabatic optical coupling to a second optical coupling end segment of a second optical waveguide of a photonic integrated circuit on a semiconductor wafer when the optical waveguide is aligned with respect to the semiconductor wafer according to a set of alignment requirements. The second optical coupling end segment having a second optical coupling surface that is devoid of cladding. The second optical coupling surface is parallel to a wafer surface of the semiconductor wafer. An alignment system configured to align the optical waveguide with respect to the semiconductor wafer according to the set of alignment requirements.

Abstract: A distributed electrostatic discharge protection circuit includes a plurality of electrostatic discharge protection elements and a current balancing network connecting the plurality of electrostatic discharge protection elements. The current balancing network is configured in a return path of the distributed electrostatic discharge protection circuit such that during an electrostatic discharge (ESD) event, the circuit provides predefined current density within each of the electrostatic discharge protection elements.

Abstract: Embodiments include a method for interconnecting components of an optical circuit. The method includes arranging the components on a support layer and embedding them within a material, such that portions of the material that is between the components contact the support layer. The obtained components are positioned with a certain inaccuracy with respect to ideal nominal positions thereof. Next, the support layer is removed to reveal one side of the components, on which side the components are level with said portions of said material. Positions of the components are identified and a set of optical polymer waveguides are adaptively fabricated, on the one side, so as for each of the fabricated polymer waveguides to optically connect subsets of two or more of the components, according to the identified positions of the components. The present invention is further directed to related optical circuits or electro-optical circuits of interconnected components.

Abstract: A computer program product or hardware description language (“HDL”) design structure in a computer-aided design system for generating a functional design model of an integrated circuitry structure including generating a functional representation of at least first and second regions of the integrated circuitry structure, generating a functional representation of an optical layer comprising optical waveguides, and generating a functional representation of a heat-conductive material for transferring heat from at least the second region through the optical layer to a heat sink.

Abstract: A computer program product for fabricating an optical assembly having stored computer readable program code including a first program to place a flexible portion of a substrate including a waveguide, the waveguide exposed at one end edge of the substrate upon a horizontally movable stage of a flip-chip bonder, a second program to vertically move a clamp through the stage opening to place the waveguide exposed end in a vertical position, a third program to vertically downwardly move a bond head containing an optical component upon the waveguide exposed substrate edge to position the optical component with the exposed waveguide, a fourth program to fixably mount the optical component to the substrate edge, and a fifth program to release the optical component from the bond head while moving the clamp vertically downward through the stage opening unbending the flexible portion of the substrate with the optical component mounted thereon.

Abstract: A system comprises an interposer positioned between an integrated circuit and a system planar. An electrical/optical transceiver is coupled to the interposer, wherein the electrical/optical transceiver converts electrical signals into optical signals. The interposer comprises a first set of electrical conductors that is electrically coupled to non-Input/Output (I/O) electrical connectors on the integrated circuit, and wherein the first set of electrical conductors passes through the interposer to directly connect the non-I/O electrical connectors on the integrated circuit to the system planar. The interposer further comprises a second set of electrical conductors that is electrically coupled to input/output (I/O) electrical connectors on the integrated circuit, wherein the second set of electrical conductors traverses through the interposer to the electrical/optical transceiver to convert electrical I/O signals from the integrated circuit into optical I/O signals.

Abstract: Embodiments provide a horizontally movable stage, with an opening, of a flip-chip bonder, a substrate including at least one flexible portion and a waveguide, the waveguide exposed at one end edge of the substrate positioned upon the stage with the end edge over the opening, a vertically upwardly movable clamp sized to penetrate the stage opening and positioned underneath the stage, a vertically downwardly movable bond head above the stage opening, an optical component positioned in the head, a glue dispenser positioned to provide glue to either a mating surface of the substrate exposed end edge or a mating surface of the optical component, and a controller connected to the stage, clamp, head and dispenser, including a control circuit for positioning the substrate waveguide exposed end edge underneath the optical component while dispensing glue for fixably bonding the mating surfaces of the optical component and the substrate exposed end edge.

Abstract: A computer program product or hardware description language (“HDL”) design structure in a computer-aided design system for generating a functional design model of an integrated circuitry structure including generating a functional representation of at least first and second regions of the integrated circuitry structure, generating a functional representation of an optical layer comprising optical waveguides, and generating a functional representation of a heat-conductive material for transferring heat from at least the second region through the optical layer to a heat sink.

Abstract: An integrated circuitry structure includes at least first and second regions. An optical layer includes optical waveguides. A heat-conductive material transfers heat from at least the second region through the optical layer to a heat sink.

Abstract: A method in a computer-aided design system for generating a functional design model of an integrated circuitry structure including generating a functional representation of at least first and second regions of the integrated circuitry structure, generating a functional representation of an optical layer comprising optical waveguides, and generating a functional representation of a heat-conductive material for transferring heat from at least the second region through the optical layer to a heat sink.

Abstract: An integrated circuit coupling device includes an integrated circuit package; and an optical data transmission medium connected to the integrated circuit package, and comprising a movable coolant, adapted to remove heat from the integrated circuit package, in operation.

Abstract: A method for fabricating an optical assembly by placing a flexible portion of a substrate, including a waveguide, upon a horizontally movable stage of a flip-chip bonder. Then moving a clamp through an opening in the stage to bend the flexible portion of the substrate to place the waveguide exposed end in approximately a vertical position and vertically downwardly moving a bond head containing an optical component upon the waveguide exposed substrate edge to position the optical component with the exposed waveguide and mounting the optical component to the substrate edge. Then releasing the optical component from the bond head while moving the clamp downward through the stage opening and unbending the flexible portion of the substrate with the optical component mounted thereon.

Abstract: A computer program product for fabricating an optical assembly, having a computer readable storage medium having computer readable program code embodied therewith, the computer readable program code includes a first computer readable program code configured to horizontally position a flexible portion of a substrate including a waveguide, the waveguide exposed at one end edge of the substrate; a second computer readable program code configured to bend the flexible portion of the substrate to place the waveguide exposed end in approximately a vertical position; a third computer readable program code configured to vertically position a flip-chip bonder bond head containing an optical component upon the waveguide exposed substrate edge to optically mate the optical component with the exposed waveguide; and a fourth computer readable program code configured to fixably mount the optical component to the substrate edge.

Abstract: A polymer waveguide including a polymer matrix and particles, wherein the particles are embedded in the polymer matrix and have lower optical bulk losses than the polymer matrix.

Abstract: The invention is directed to a device (10, 10a-10d) comprising: a set of on-chip circuits (110-160, 170, 180), each of the circuits configured to generate a magnetic field (300) perpendicular to a planar surface of the set when energized; a ferrofluidic layer (40) interfaced to the planar surface; and a logic circuit (50) configured to selectively energize (200, 200a) one ore more circuits of the set such as to generate a magnetic field at the energized circuits and a deformation (41, 44, 45) of the ferrofluidic layer in response thereto and to modulate optical beams (IR1, IR2) directed to the ferrofluid layer. Preferably, an additional liquid layer (60) is interfaced to the ferrofluid layer, opposite to the on-chip circuits, which is not miscible with the ferrofluid layer. The invention can be applied to micro-display/projection devices, programmable optical reflecting lenses, or to micro-molding applications for surface replication.