An optical interconnect computing module having free space optical interconnects that form communication links with other systems with like optical interconnects and with computer blades contained within the computing module. The computing module adapts to changes in the position and orientation and other factors of the optical interconnects. The optical interconnects utilize solid-state electronic and optoelectronic components and optical components. The ability to adapt is controlled by an algorithm implemented in software, firmware and logic circuits. Computing modules within an equipment rack and between equipment racks as well as blades contained within a computing module may experience changes in position and orientation due to installation misalignment, servicing of equipment, vibrations, floor sagging, thermal expansion and contraction, earthquakes, line-of-sight obstructions, manufacturing imperfections and other sources.

A probe device is configured to insert optical fiber probes directly into a v-groove coupler on an optical integrated circuit (IC) device. The probe device may include a probe holder comprising with a slot. A fiber holder may insert into the slot. The fiber holder may comprise a body with a first portion and second portion disposed at an angle relative to one another so that the first portion is shorter than the second portion. The body may have a bottom with grooves disposed therein, the grooves having dimensions to receive part of an optical fiber probes therein. In use, the fiber holder can arrange the optical fiber probes to extend into the v-grooves of the v-groove coupler of an optical IC on a wafer. The device may incorporate an alignment mechanism that permits the fiber holder to move or self-align in response to contact between the optical fiber probes and structure of the v-groove coupler of an optical IC on a wafer.

A fiber optic tamper switch is disclosed, wherein a moveable member is moved to actuate the switch. The switch includes a component subassembly block and a cover. The switch includes a toggle arm extending through the cover, contacting the moveable member and configured to rotate when the moveable member is moved. The switch includes a fiber capture bar configured to receive a fiber optic cable and a fiber press bar coupled to the fiber capture bar configured to actuate upon the movement of the toggle arm and translate the fiber capture bar in a first direction, effecting a bend in the fiber optic cable. The fiber optic cable is configured to attenuate a light signal when bent. The switch includes a locking mechanism preventing the unbending of the fiber optic cable.

Photonic integrated circuits including controllable cantilevers are described. Such photonic integrated circuits may be used in connection with other optical devices, in which light is transferred between the photonic integrated circuit and one of these optical device. The photonic integrated circuit may comprise an optical waveguide having an end disposed proximate to a facet of the cantilever. The orientation of the cantilever may be actively controlled in one or two dimensions, thus adjusting the orientation of the optical waveguide. Actuation of the cantilever may be performed, for example, thermally and/or electrostatically. Orientation of the cantilever may be performed in such a way to align the optical waveguide with an optical device.

This invention discloses highly scalable and modular automated optical cross connect switch devices which exhibit low loss and scalability to high port counts. In particular, a device for the programmable interconnection of large numbers of optical fibers (100s-1000s) is provided, whereby a two-dimensional array of fiber optic connections is mapped in an ordered and rule-based fashion into a one-dimensional array with tensioned fiber optic circuit elements tracing substantially straight lines there between. Fiber optic elements are terminated in a stacked arrangement of flexible fiber optic circuit elements with a capacity to retain excess fiber lengths while maintaining an adequate bend radius. The combination of these elements partitions the switch volume into multiple independent, non-interfering zones, which retain their independence for arbitrary and unlimited numbers of reconfigurations. The separation into spaced-apart zones provides clearance for one or more robotic actuators to enter the free volume substantially adjacent to the two-dimensional array of connectors and mechanically reconfigure connectors without interrupting other circuits.

An apparatus includes a plurality of connector track elements, each extending substantially perpendicularly from a coupling plane, wherein a particular connector track element of the plurality of connector track elements includes a distribution of at least two magnets adjacent unattached end thereof, a polarity of the magnets on the particular connector track element being selected to provide magnetic repulsion as to at least one adjacent connector track element.

An optical interconnect computing module having free space optical interconnects that form communication links with other systems with like optical interconnects and with computer blades contained within the computing module. The computing module adapts to changes in the position and orientation and other factors of the optical interconnects. The optical interconnects utilize solid-state electronic and optoelectronic components and optical components. The ability to adapt is controlled by an algorithm implemented in software, firmware and logic circuits. Computing modules within an equipment rack and between equipment racks as well as blades contained within a computing module may experience changes in position and orientation due to installation misalignment, servicing of equipment, vibrations, floor sagging, thermal expansion and contraction, earthquakes, line-of-sight obstructions, manufacturing imperfections and other sources.

A multi-port aggregated cable includes: a plurality of duplex optical fibers, each duplex optical fiber having a first end and a second end; a first optical interface attached to each of the duplex optical fibers at the first end thereof and defining multiple ports, one for each of the duplex optical fibers, the first optical interface aggregating the duplex optical fibers at the first end thereof; and a second optical interface attached to each of the duplex optical fibers at the second end thereof and defining multiple ports, one for each of the duplex optical fibers, the second optical interface aggregating the duplex optical fibers at the second end thereof.

A polarization-independent optical switching system capable of rerouting light signals is disclosed. The system includes a plurality of switching cells, each including a pair of bus waveguides that are formed in different planes above a substrate. Each bus waveguide supports low-loss propagation of both the TE- and TM-polarization modes and are optically decoupled when the switch is in an unswitched state. In its switched state, a shunt waveguide that also supports low-loss propagation of both polarization modes is moved into proximity with both bus waveguides to form a pair of adiabatic directional couplers that enable the light signal to evanescently couple between each bus waveguide and the shunt waveguide. As a result, the path of a light signal through the switching cell is reconfigured.

A probe device is configured to insert optical fiber probes directly into a v-groove coupler on an optical integrated circuit (IC) device. The probe device may include a probe holder comprising with a slot. A fiber holder may insert into the slot. The fiber holder may comprise a body with a first portion and second portion disposed at an angle relative to one another so that the first portion is shorter than the second portion. The body may have a bottom with grooves disposed therein, the grooves having dimensions to receive part of an optical fiber probes therein. In use, the fiber holder can arrange the optical fiber probes to extend into the v-grooves of the v-groove coupler of an optical IC on a wafer. The device may incorporate an alignment mechanism that permits the fiber holder to move or self-align in response to contact between the optical fiber probes and structure of the v-groove coupler of an optical IC on a wafer.