Abstract: An electro-optic unit that may include a substrate, multiple optical engines, multiple electro-optic sub-units and optical conduits. Each optical engine may include one or more mechanical housings, each mechanical housing may include a group of lenses. Each electro-optic sub-unit is selected out of (a) a transmit electro-optic sub-unit that may include a group of lasers and a group of at least one laser driver, (b) a receive electro-optic sub-unit that may include a group of detectors and a group of at least one reception circuits; and (c) a hybrid electro-optic sub-unit that may include a receive portion and a transmit portion; wherein the transmit portion may include a sub-group of lasers and a sub-group of at least one laser driver; wherein the receive portion may include a sub-group of detectors and a sub-group of at least one reception circuits.

Abstract: A method for passively coupling an optical fiber to an optoelectronic chip, the method may include connecting the optical fiber to an optical cable interface of a first portion of an optical coupler; wherein the optical coupler further comprises a second portion; wherein the first portion comprises first optics that comprises a first lens array, an optical cable interface and three contact elements, each contact element has a spherical surface; and wherein the second portion comprises second optics that comprise a second lens array, and three elongated grooves; connecting the optical coupler to a substrate that supports the optoelectronic chip; and mechanically coupling the first portion to the second portion by aligning the three contact elements of the first portion with the three elongated grooves of the second portion thereby an optical axis related to a first lens array of the first portion passes through a point of intersection between longitudinal axes of the three elongated grooves, and an optical axi

Abstract: A high-frequency optoelectronic module, that includes a first chip, a substrate and at least one optoelectronic unit. The first chip includes a set of high-frequency electrical IO interfaces. The at least one optoelectronic unit includes a group of high-frequency electrical IO interfaces and a group of high-frequency optical IO interfaces. The group of high-frequency optical IO interfaces is coupled to the group of high-frequency electrical IO interfaces. The substrate is coupled to the first chip and the at least one optoelectronic chip. The set of high-frequency electrical IO interfaces is coupled to the group of high-frequency electrical IO interfaces via a group of conductors. A length of each conductor of the group of conductors is of a scale that does not exceed a millimetric scale.

Abstract: A method for passively coupling an optical fiber to an optoelectronic chip, the method may include connecting the optical fiber to an optical cable interface of a first portion of an optical coupler; wherein the optical coupler further comprises a second portion; wherein the first portion comprises first optics that comprises a first lens array, an optical cable interface and three contact elements, each contact element has a spherical surface; and wherein the second portion comprises second optics that comprise a second lens array, and three elongated grooves; connecting the optical coupler to a substrate that supports the optoelectronic chip; and mechanically coupling the first portion to the second portion by aligning the three contact elements of the first portion with the three elongated grooves of the second portion thereby an optical axis related to a first lens array of the first portion passes through a point of intersection between longitudinal axes of the three elongated grooves, and an optical axi

Abstract: A high-frequency optoelectronic module, that includes a first chip, a substrate and at least one optoelectronic unit. The first chip includes a set of high-frequency electrical IO interfaces. The at least one optoelectronic unit includes a group of high-frequency electrical IO interfaces and a group of high-frequency optical IO interfaces. The group of high-frequency optical IO interfaces is coupled to the group of high-frequency electrical IO interfaces. The substrate is coupled to the first chip and the at least one optoelectronic chip. The set of high-frequency electrical IO interfaces is coupled to the group of high-frequency electrical IO interfaces via a group of conductors. A length of each conductor of the group of conductors is of a scale that does not exceed a millimetric scale.

Abstract: A method for assembling an optical interconnect apparatus is provided. The optical interconnect comprises an integrated circuit chip, and at least one optoelectronic chip positioned on the integrated circuit chip, each of the at least one optoelectronic chip including a 2-dimensional optoelectronic array. The optical interconnect further comprises a first and a second microlens array, a bundle of optical fibers coupled to each second microlens array and supported by a bundle housing, and a block structure supporting the bundle housing to a printed circuit board (PCB).

Abstract: An optical interconnect uses large 2-dimensional matrices of optoelectronic chips. The optoelectronic chips are placed directly above the analog circuitry required to drive them and with the microlens array placed on top of the optoelectronic chip. A single microlens array is assembled directly on top of the 2-dimensional optoelectronic chip. The optoelectronic chips may include vertical cavity surface emitting lasers (VCSEL) for signal generation and p-i-n photodiodes for signal detection. A bundle of optical fibers or waveguides with a layout identical to the optoelectronic chips is used for optical data transfer between constituents of the optical communication system.

Abstract: An interconnect system for coupling light from a laser light source to an optical fiber having a fiber aperture, the interconnect system including a 2-dimensional array of laser light sources, a 2-dimensional array of micro lenses disposed between 10-200 ?m distance from the laser light source, between the laser light source and the optical fiber and in registration therewith, each micro lens comprising a micro lens back surface, a micro lens body, a micro lens front surface, and a clear aperture, the micro lens front surface and back surface being shaped to provide a laser beam in the micro lens body of smaller diameter than the clear aperture for focusing the beam onto the fiber aperture.

Abstract: An optoelectronic chip assembly including a printed circuit board (PCB) coupled to a substrate, an aperture formed through the printed circuit board and through the substrate, a heat sink, an array of active electro-optical elements mounted in the aperture and connected to a driving chip controlled by the PCB, wherein the driving chip is coupled to the heat sink. Preferably, the assembly further includes a plurality of passive optical elements disposed for optical communication and data transfer with said active electro-optical elements, but thermally isolated therefrom.