Abstract: An optical component comprising a plurality of optical input ports and a plurality of optical output ports. A polymer amplifying medium is provided within the component which is pumped by a pump source for exciting the polymer amplifying medium. Signals passing through the optical component are routed through the polymer amplifying medium. This, provides amplification using a polymer amplifying medium which is integrated into the structure of the component. This amplification can then compensate for the loss resulting from the other functions of the component.

Abstract: An anamorphic lens for correcting aberration of a highly divergent beam from a laser source has first and second cylindrical surfaces having mutually perpendicular planes of symmetry. Each surface is defined from a generator polynomial including cross terms in two variables so as to correct aberration of light from a widely divergent source.

Abstract: An optical component comprising a plurality of optical input ports and a plurality of optical output ports. A polymer amplifying medium is provided within the component which is pumped by a pump source for exciting the polymer amplifying medium. Signals passing through the optical component are routed through the polymer amplifying medium This, provides amplification using a polymer amplifying medium which is integrated into the structure of the component. This amplification can then compensate for the loss resulting from the other functions of the component.

Abstract: An optical switch has a plurality of input ports (2) and a plurality of output ports (4). Associated with each input port (2) there is an input path IP followed by a free space beam exiting that input port (2), and associated with each output port (4) there is an output path OP followed by a free space beam entering that output port (4). Located at each input path IP/output path OP intersection is mirror means If (12) comprising a main mirror (12a) actuatable to divert a beam from a corresponding input path IP to a corresponding output path OP and at least one back-up mirror (12b) for performing the same function as the main mirror (12a).

Abstract: Distortion compensation of an optical micro-electro-mechanical system (MEMS) device disposed on a substrate surface is effected by measuring degradation of an optical parameter of the device and applying a force to the substrate to reverse the degradation. The compensating force may be provided via a layer of piezo-electric material bonded to the opposite surface of the substrate and to which a control voltage is applied. The device distortion may arise from thermal mismatch effects in a package housing containing the device. Typically, the MEMS device comprises an optical crosspoint switch array.

Abstract: Distortion compensation of an optical micro-electro-mechanical system (MEMS) device disposed on a substrate surface is effected by measuring degradation of an optical parameter of the device and applying a force to the substrate to reverse the degradation. The compensating force may be provided via a layer of piezo-electric material bonded to the opposite surface of the substrate and to which a control voltage is applied. The device distortion may arise from thermal mismatch effects in a package housing containing the device. Typically, the MEMS device comprises an optical crosspoint switch array.

Abstract: The power handling capabilities and operational lifetime of a MEMS device, e.g., a MEMS mirror, operating in a high intensity optical beam environment are enhanced by packaging the device in an packaging atmosphere having a suitably high thermal conductivity, preferably exceeding that of air. The packaging atmosphere can be selected to provide a desired level of heat loss from the MEMS device.

Abstract: An integrated MEMS stabilizer comprises a MEMS platform connected to at least one submount and integrated support means for the MEMS platform including a vibration stabilization mechanism. The vibration stabilization mechanism provides at least one connection between the submount and the MEMS platform, and reduces the amplitude of any external vibration experienced by the MEMS platform. The stabilization mechanism provided by the stabilizer enables any MEMS device or component formed or attached to the MEMS platform to maintain its operational performance even when exposed to vibrational disturbance. The stabilization mechanism may further provide protection against shock for example, by monitoring the integrated MEMS stabilizer on a slab of suitable visco elastic material, e.g. Sorbothane™.