Abstract: An apparatus for detecting radiation is provided. In embodiments, at least one sensor is disposed on a surface of a wafer-like substrate. At least one sensor medium is fixed relative to the substrate, optically or electrically coupled to the sensor, and separated from the sensor by no more than the substrate thickness. An electronic signal-processing circuit is connected to the sensor and configured to produce an output when the sensor is stimulated by a product of an interaction between the sensor medium and impinging radiation. The sensor is configured to collect, from the sensor medium, charge and/or light produced within the sensor medium by interactions with impinging radiation.

Abstract: A 3D stacked sASIC is provided that includes a plurality of 2D reconfigurable structured structured ASIC (sASIC) levels interconnected through hard-wired arrays of 3D vias. The 2D sASIC levels may contain logic, memory, analog functions, and device input/output pad circuitry. During fabrication, these 2D sASIC levels are stacked on top of each other and fused together with 3D metal vias. Such 3D vias may be fabricated as through-silicon vias (TSVs). They may connect to the back-side of the 2D sASIC level, or they may be connected to top metal pads on the front-side of the 2D sASIC level.

Abstract: A set of interlocking modules supports and connects a die containing lasers, a set of precision molded lenses and a set of beam switching elements. Another embodiment of the invention is a structure for mounting a logic chip and an optical chip on a chip carrier, with the optical chip being mounted on the side of the carrier facing the system board on which the carrier is mounted, so that radiation travels in a straight path from optical sources on the optical chip into optical transmission guides on the board.

Abstract: A modular, scalable focal plane array is provided as an array of integrated circuit dice, wherein each die includes a given amount of modular pixel array circuitry. The array of dice effectively multiplies the amount of modular pixel array circuitry to produce a larger pixel array without increasing die size. Desired pixel pitch across the enlarged pixel array is preserved by forming die stacks with each pixel array circuitry die stacked on a separate die that contains the corresponding signal processing circuitry. Techniques for die stack interconnections and die stack placement are implemented to ensure that the desired pixel pitch is preserved across the enlarged pixel array.

Abstract: Optical cubes and optical cube assemblies for directing optical beams are provided. The optical cubes are optically transparent modules that can be adapted to reflect, transmit, and/or partially reflect and transmit optical beams. The optical cubes may include bi-direction or multi-direction beam directing elements for directing optical beams. The optical cube assemblies may include flexible chip assemblies attached to optical cubes. The chip assemblies may include vertical cavity surface-emitting lasers for emitting optical beams or receivers for receiving optical beams mounted on a flexible and electrical interconnect mounting assembly.

Abstract: A method for forming an interconnect structure for a semiconductor device includes defining a via in a passivation layer so as expose a top metal layer in the semiconductor device. A seed layer is formed over the passivation layer, sidewalls of the via, and the top metal layer. A barrier layer is formed over an exposed portion of the seed layer, the exposed portion defined by a first patterned opening of a first diameter, and a solder material is formed over the barrier layer using a second patterned opening of a second diameter. The second patterned opening is configured such that the second diameter is larger than the first diameter.

Abstract: A method for forming an interconnect structure for a semiconductor device includes defining a via in a passivation layer so as expose a top metal layer in the semiconductor device. A seed layer is formed over the passivation layer, sidewalls of the via, and the top metal layer. A barrier layer is formed over an exposed portion of the seed layer, the exposed portion defined by a first patterned opening of a first diameter, and a solder material is formed over the barrier layer using a second patterned opening of a second diameter. The second patterned opening is configured such that the second diameter is larger than the first diameter.

Abstract: An optoelectronic assembly for an electronic system includes a thermally conductive, metallized transparent substrate having a first surface and an opposite second surface. A support chip set is bonded to the transparent substrate. A first substrate is in communication with the transparent substrate via the second surface and support chip set therebetween. A second substrate is in communication with the second surface of the first substrate and is configured for mounting at least one of data processing, data switching and data storage chips. An optoelectronic transducer is in signal communication with the support chip set, and an optical signaling medium having one end with an optical fiber array aligned with the transducer is substantially normal to the first surface of the transparent substrate. The support chip set and the transducer share a common thermal path for cooling.

Abstract: A method for forming an interconnect structure for a semiconductor device includes defining a via in a passivation layer so as expose a top metal layer in the semiconductor device. A seed layer is formed over the passivation layer, sidewalls of the via, and the top metal layer. A barrier layer is formed over an exposed portion of the seed layer, the exposed portion defined by a first patterned opening. The semiconductor device is annealed so as to cause atoms from the barrier layer to diffuse into the seed layer thereunderneath, wherein the annealing causes diffused regions of the seed layer to have an altered electrical resistivity and electrode potential with respect to undiffused regions of the seed layer.

Abstract: Under the present invention, a semiconductor chip is electrically connected to a substrate (e.g., organic, ceramic, etc.) by an interposer structure. The interposer structure comprises an elastomeric, compliant material that includes metallurgic through connections having a predetermined shape. In a typical embodiment, the metallurgical through connections electrically connect an under bump metallization of the semiconductor chip to a top surface metallization of the substrate. By utilizing the interposer structure in accordance with the present invention, the problems associated with previous semiconductor module designs are alleviated.

Abstract: An optoelectronic assembly for a computer system includes an electronic chip(s), a substrate, an electrical signaling medium, an optoelectronic transducer, and an optical coupling guide. The electronic chip(s) is in communication with the substrate, which is in communication with a first end of the electrical signaling medium. A second end of the electrical signaling medium is in communication with the optoelectronic transducer, and includes the optical coupling guide for aligning an optical signaling medium with the optoelectronic transducer. An electrical signal from the electronic chip is communicated to the optoelectronic transducer via the substrate and the electrical signaling medium. The optical transducer and electronic chip(s) share a common heat spreader, and communication to other groups of electronic chip(s) is done without the need for communication via a second level electrical package.

Abstract: An optoelectronic assembly for an electronic system includes a transparent substrate having a first surface and an opposite second surface, the transparent substrate being thermally conductive and being metallized on the surface. A support electronic chip set is configured for at least one of providing multiplexing, demultiplexing, coding, decoding and optoelectronic transducer driving and receive functions and is bonded to the second surface of the transparent substrate. A first substrate having a first surface and an opposite second surface, is in communication with the transparent substrate via the metallized second surface and support chip set therebetween. A second substrate is in communication with the second surface of the first substrate and is configured for mounting at least one of data processing, data switching and data storage chips.

Abstract: A method for forming an interconnect structure for a semiconductor device includes defining a via in a passivation layer so as expose a top metal layer in the semiconductor device. A seed layer is formed over the passivation layer, sidewalls of the via, and the top metal layer. A barrier layer is formed over an exposed portion of the seed layer, the exposed portion defined by a first patterned opening. The semiconductor device is annealed so as to cause atoms from the barrier layer to diffuse into the seed layer thereunderneath, wherein the annealing causes diffused regions of the seed layer to have an altered electrical resistivity and electrode potential with respect to undiffused regions of the seed layer.

Abstract: Optical cubes and optical cube assemblies for directing optical beams are provided. The optical cubes are optically transparent modules that can be adapted to reflect, transmit, and/or partially reflect and transmit optical beams. The optical cubes may include bi-direction or multi-direction beam directing elements for directing optical beams. The optical cube assemblies may include flexible chip assemblies attached to optical cubes. The chip assemblies may include vertical cavity surface-emitting lasers for emitting optical beams or receivers for receiving optical beams mounted on a flexible and electrical interconnect mounting assembly.

Abstract: An optical-electronic package for an electronic device provides electrical connections to the electronic device and optical fiber connections to the electronic device. The package includes a high thermal conductivity base which has a pedestal to support and provide heat transfer connection to the electronic device. A seal band is formed on the base and a casing is bonded to the seal band. The casing has side feedthroughs for the electrical connections from the electronic device, and the casing has top feedthroughs or grooves for the optical fiber connections from the electronic device. A lid is hermetically sealed to the top of the casing. The lid has retractable means for forming a bend in the optical fibers to provide strain relief when the lid is placed on the casing. The retractable means for forming a bend in the optical fibers is retractable once the lid is sealed on the casing.

Abstract: A set of interlocking modules supports and connects a die containing lasers, a set of precision molded lenses and a set of beam switching elements. Another embodiment of the invention is a structure for mounting a logic chip and an optical chip on a chip carrier, with the optical chip being mounted on the side of the carrier facing the system board on which the carrier is mounted, so that radiation travels in a straight path from optical sources on the optical chip into optical transmission guides on the board.

Abstract: Optical cubes and optical cube assemblies for directing optical beams are provided. The optical cubes are optically transparent modules that can be adapted to reflect, transmit, and/or partially reflect and transmit optical beams. The optical cubes may include bi-direction or multi-direction beam directing elements for directing optical beams. The optical cube assemblies may include flexible chip assemblies attached to optical cubes. The chip assemblies may include vertical cavity surface-emitting lasers for emitting optical beams or receivers for receiving optical beams mounted on a flexible and electrical interconnect mounting assembly.

Abstract: A set of interlocking modules supports and connects a die containing lasers, a set of precision molded lenses and a set of beam switching elements. Another embodiment of the invention is a structure for mounting a logic chip and an optical chip on a chip carrier, with the optical chip being mounted on the side of the carrier facing the system board on which the carrier is mounted, so that radiation travels in a straight path from optical sources on the optical chip into optical transmission guides on the board.

Abstract: A process and structure for forming an optical subassembly in an integrated circuit, comprising: defining electrically conducting lines and bonding pads in a metallization layer on a substrate; depositing a passivation layer over the metallization layer; etching the passivation layer to remove the passivation layer from each of the bonding pads and a portion of the metallization layer associated with each of the bonding pads; diffusing Cr from the lines proximate said bonding pads to prevent solder wetting down lines; bonding an optical device to one of the bonding pads; and attaching the substrate to a carrier utilizing solder bond attachment.

Abstract: An optical-electronic package for an electronic device provides electrical connections to the electronic device and optical fiber connections to the electronic device. The package includes a high thermal conductivity base which has a pedestal to support and provide heat transfer connection to the electronic device. A seal band is formed on the base and a casing is bonded to the seal band. The casing has side feedthroughs for the electrical connections from the electronic device, and the casing has top feedthroughs or grooves for the optical fiber connections from the electronic device. A lid is hermetically sealed to the top of the casing. The lid has retractable means for forming a bend in the optical fibers to provide strain relief when the lid is placed on the casing. The retractable means for forming a bend in the optical fibers is retractable once the lid is sealed on the casing.