Abstract: An optical block includes a first surface that receives light entering the optical block, a second surface through which the light exits the optical block, and a reflector that reflects light from the first surface towards the second surface. The reflector includes a textured surface that scatters or absorbs some of the light received from the first surface to attenuate the light exiting the optical block through the second surface.

Abstract: An interconnect system includes various anti-backout latches that are movable between an engaged position and a disengaged position. When in the engaged position, the anti-backout latches can be configured to prevent an interconnect module, such as an optical transceiver, from becoming unmated from a host module. When in the disengaged position, the anti-backout latches permit the interconnect module to become unmated from a host module. Securement members are also disclosed that secure a heat sink to a module housing of the interconnect module.

Abstract: An optical block includes a first surface that receives light entering the optical block, a second surface through which the light exits the optical block, and a reflector that reflects light from the first surface towards the second surface. The reflector includes a textured surface that scatters or absorbs some of the light received from the first surface to attenuate the light exiting the optical block through the second surface.

Abstract: An optical block includes a first surface that receives light entering the optical block, a second surface through which the light exits the optical block, and a reflector that reflects light from the first surface towards the second surface. The reflector includes a textured surface that scatters or absorbs some of the light received from the first surface to attenuate the light exiting the optical block through the second surface.

Abstract: This present disclosure seals the light propagation path in an optical interconnection element from external contaminants. The optical interconnection element includes a reflective surface, which can also be sealed from external contaminants Additional novel concepts include all enclosed sealed regions of the optical interconnection element being fluidly connected and making the final seal of the optical interconnection element with a thin plate, which can bend reducing the pressure differential between the ambient environment and the sealed internal volume of the optical interconnection element.

Abstract: An interconnect system includes various anti-backout latches that are movable between an engaged position and a disengaged position. When in the engaged position, the anti-backout latches can be configured to prevent an interconnect module, such as an optical transceiver, from becoming unmated from a host module. When in the disengaged position, the anti-backout latches permit the interconnect module to become unmated from a host module. Securement members are also disclosed that secure a heat sink to a module housing of the interconnect module.

Abstract: Interconnect systems having anti-backout latches and securement members are disclosed.

Abstract: An interconnect system includes various anti-backout latches that are movable between an engaged position and a disengaged position. When in the engaged position, the anti-backout latches can be configured to prevent an interconnect module, such as an optical transceiver, from becoming unmated from a host module. When in the disengaged position, the anti-backout latches permit the interconnect module to become unmated from a host module. Securement members are also disclosed that secure a heat sink to a module housing of the interconnect module.

Abstract: A variety of methods and arrangements for latching a transceiver to a host printed circuit board (PCB) are described. The transceiver is secured to its electrical sockets by a latch that does not extend or only minimally extends beyond the transceiver footprint and height. In some embodiments the latch includes a thermal bridge that provides a heat transfer path between the transceiver and host substrate.

Abstract: An optical block includes a first surface that receives light entering the optical block, a second surface through which the light exits the optical block, and a reflector that reflects light from the first surface towards the second surface. The reflector includes a textured surface that scatters or absorbs some of the light received from the first surface to attenuate the light exiting the optical block through the second surface.

Abstract: An optical block includes a first surface that receives light entering the optical block, a second surface through which the light exits the optical block, and a reflector that reflects light from the first surface towards the second surface. The reflector includes a textured surface that scatters or absorbs some of the light received from the first surface to attenuate the light exiting the optical block through the second surface.

Abstract: An interconnect system includes various anti-backout latches that are movable between an engaged position and a disengaged position. When in the engaged position, the anti-backout latches can be configured to prevent an interconnect module, such as an optical transceiver, from becoming unmated from a host module. When in the disengaged position, the anti-backout latches permit the interconnect module to become unmated from a host module. Securement members are also disclosed that secure a heat sink to a module housing of the interconnect module.

Abstract: Interconnect systems having anti-backout latches and securement members are disclosed.

Abstract: An optical transceiver provides substantial thermal isolation between an IC die and an optical element that is in electrical communication with the IC die. The IC die is further in electrical communication with a substrate that supports the optical element and the IC die. The transceiver includes an IC heat spreader that is configured to dissipate heat generated from the IC die. The IC die and the optical element can be substantially thermally isolated from each other so as to prevent the heat generated from the IC die from causing the optical elements to overheat.

Abstract: An optical block includes a first surface that receives light entering the optical block, a second surface through which the light exits the optical block, and a reflector that reflects light from the first surface towards the second surface. The reflector includes a textured surface that scatters or absorbs some of the light received from the first surface to attenuate the light exiting the optical block through the second surface.

Abstract: An optical device that can be used in a range of telecommunications applications including optical multiplexers/demultiplexers and optical routers. The optical device includes an optical processing loop which allows multi-stage performance characteristics to be achieved with a single physical filtration stage. Optical processing on the first leg and second legs of the loop is asymmetrical thereby improving the integrity of the optical signals by effecting complementary chromatic dispersion on the first and second legs. In an embodiment of the invention the optical device includes a fundamental filter cell, a retro reflector and a splitter/combiner. The fundamental filter cell filters optical signals propagating on each of two legs of an optical loop which intersects the fundamental filter cell.

Abstract: Methods for combining or splitting optical signals that include an odd channel set an even channel set. The methods of combining or splitting are performed by subjecting the odd and even channel sets to a first filter that applies phase retardations corresponding with odd integer multiples of half a wavelength for each center wavelength associated with a selected one of the odd and even set of channels and with integer multiples of a full wavelength of each center wavelength associated with a remaining one of the odd set and the even set. The channel sets are then subjected to a second filter that applies phase retardations that are complementary to those experienced by the odd and even set of channels in the first filter. This complementary filtration has the effect of reducing dispersion. These methods may be used in optical devices applicable to a range of telecommunications applications, including optical multiplexers/demultiplexers and optical routers.

Abstract: An optical device that can be used in a range of telecommunications applications including optical multiplexers/demultiplexers and optical routers. The optical device splits and combines optical signals of frequency division multiplexed optical communication channels that are evenly spaced apart in frequency from one another. The optical device includes a first filter and a second filter. The first filter splits and combines odd and even channels depending on the propagation direction of the optical signal. The first filter exhibits complementary phase retardations corresponding with odd integer multiples of half a wavelength for each center wavelength associated with a selected one of the odd and even set of channels and with integer multiples of a full wavelength of each center wavelength associated with a remaining one of the odd set and the even set.

Abstract: The present invention provides optical filters that can be used in a range of telecommunications applications including optical multiplexers/demultiplexers, optical routers, and optical gain scalers. The optical filter is modular, using two or more couplers with a pair of delay paths between each pair of couplers in a sequence to generate a range of optical filter functions. The desired filter profile/function is obtained by proper selection of the coupling ratio for each coupler and by the length of each pair of delay paths. The couplers may be implemented as polarization or intensity beam splitters positioned along the optical path. Each coupler couples in controllable amounts, one or two inputs with the corresponding pair of delay paths.