Abstract: Integrated circuit chips may be optically interconnected using microLEDs. Some interconnections may be vertically-launched parallel optical links. Some interconnections may be planar-launched parallel optical links.

Abstract: An optical communication system may include microLEDs for use in communicating data between chips or multi-chip modules. The number of microLEDs may be greater than a number of electrical data lines for carrying data to be communicated. Signals on the electrical data lines may be inverse multiplexed, for example to allow for operation of the microLEDs at a rate slower than operation of electrical circuitry generating signals on the electrical data lines.

Abstract: Coupling of light from large angular distribution microLEDs into smaller angular acceptance distribution of transmission channels is performed using optical elements.

Abstract: A microLED may be used to generate light for intra-chip or inter-chip communications. The microLED, or an active layer of the microLED, may be embedded in a waveguide. The waveguide may include a lens.

Abstract: Optical interconnects for IC chips may include optical sources and receivers integrated with the IC chips. MicroLEDs may be mounted on an interconnect layer of the IC chip, and embedded within a waveguide. Photodetectors to receive light from the waveguide may be fabricated in a top surface of a semiconductor substrate, below a level of the interconnect layer, but with a passageway for light through the interconnect layer.

Abstract: An optical interconnect may provide for optical communications between two IC chips. The optical interconnect may include an array of optoelectronic elements, for example microLEDs and photodetectors, with the array including a plurality of sub-arrays. A fiber bundle of optical fibers may couple the optoelectronic elements, and the fiber bundle may include a plurality of sub-bundles, with for example one sub-bundle for coupling pairs of sub-arrays. Fibers of each sub-bundle may be accurately positioned with respect to one another.

Abstract: A multi-layer planar waveguide may be used in providing an interconnect for inter-chip and/or intra-chip signal transmission. Various embodiments to transmit optical signals are disclosed, along with designs of microLED optical assemblies, photodetector optical assemblies, waveguides, and multi-layer planar waveguides.

Abstract: A coherent fiber bundle may be used to optically connect an array of microLEDs to an array of photodetectors in an optical communication system.

Abstract: Light from one or more microLEDs may be coupled into multiple waveguide cores. Parabolic reflectors, truncated parabolic reflectors, and encapsulants may be used to increase fraction of emitted light coupled into the waveguide cores.

Abstract: Multi-chip modules in different semiconductor packages may be optically data coupled by way of LEDs and photodetectors linked by a multicore fiber. The multicore fiber may pass through apertures in the semiconductor packages, with an array of LEDs and photodetectors in the semiconductor package providing and receiving, respectively, optical signals comprised of data passed between the multi-chip modules.

Abstract: Optical interconnects for IC chips may include optical sources and receivers integrated with the IC chips. MicroLEDs may be mounted on an interconnect layer of the IC chip, and embedded within a waveguide. Photodetectors to receive light from the waveguide may be fabricated in a top surface of a semiconductor substrate, below a level of the interconnect layer, but with a passageway for light through the interconnect layer.

Abstract: An optical interconnect may provide for optical communications between two IC chips. The optical interconnect may include an array of optoelectronic elements, for example microLEDs and photodetectors, with the array including a plurality of sub-arrays. A fiber bundle of optical fibers may couple the optoelectronic elements, and the fiber bundle may include a plurality of sub-bundles, with for example one sub-bundle for coupling pairs of sub-arrays. Fibers of each sub-bundle may be accurately positioned with respect to one another.

Abstract: Integrated circuit chips may be optically interconnected using microLEDs. Some interconnections may be vertically-launched parallel optical links. Some interconnections may be planar-launched parallel optical links.

Abstract: A multi-layer planar waveguide may be used in providing an interconnect for inter-chip and/or intra-chip signal transmission. Various embodiments to transmit optical signals are disclosed, along with designs of microLED optical assemblies, photodetector optical assemblies, waveguides, and multi-layer planar waveguides.

Abstract: Optical chip-to-chip interconnects may use microLEDs as light sources. The interconnected chips may be on a same substrate. A pair of endpoint chips may each have associated optical transceiver subsystems, with transceiver circuitry in transceiver chips. Optical communications may be provided between the optical transceiver subsystems, with the optical transceiver subsystems in communication with their associated endpoint chips by way of metal layers in the substrate.

Abstract: A coherent fiber bundle may be used to optically connect an array of microLEDs to an array of photodetectors in an optical communication system.

Abstract: For optical communications between semiconductor ICs, optical transceiver assembly subsystems may be integrated with a processor. The optical transceiver assembly subsystems may be monolithically integrated with processor ICs or they may be provided in separate optical transceiver ICs coupled to or attached to the processor ICs.

Abstract: A microLED may be used to generate light for intra-chip or inter-chip communications. The microLED, or an active layer of the microLED, may be embedded in a waveguide. The waveguide may include a lens.

Abstract: Multi-chip modules in different semiconductor packages may be optically data coupled by way of LEDs and photodetectors linked by a multicore fiber. The multicore fiber may pass through apertures in the semiconductor packages, with an array of LEDs and photodetectors in the semiconductor package providing and receiving, respectively, optical signals comprised of data passed between the multi-chip modules.

Abstract: Optically coupling two or more optical transceiver integrated circuits (OTRIC) using OTRIC-on-substrate assemblies is disclosed. The optical transceiver integrated circuits may be attached to different substrates, where the substrates may allow the passage of optical signals to and from the optical transceiver integrated circuits. The OTRIC-on-substrate assemblies may comprise one or more optoelectronic device arrays, lenses and mirrors, mounts, and optical transmission medium. The optical transmission medium may be free space or and optical fiber. An optical coupling mechanism may be used in conjunction with the OTRIC-on-substrate assemblies to link optical signals between the optical transceiver integrated circuits.