Avionics pluggable active optical connector

The invention claimed is: 1. A pluggable active optical connector comprising: a connector housing; a first printed circuit board contained within the connector housing; a first multiplicity of electrical connectors electrically coupled to and supported by the first printed circuit board; a first bidirectional optical sub-assembly contained within the connector housing and comprising a first laser device and a first photodetector which are electrically coupled to the first printed circuit board and a first housing mounted to the first printed circuit board, the first housing being a single housing comprising a first receptacle that is configured to receive the first laser device and first photodetector and a second receptacle that is configured to receive one end of a first terminus that terminates a first optical cable, the first receptacle of the first housing being integrally formed or rigidly affixed to the second receptacle of the first housing; a second printed circuit board contained within the connector housing; a second multiplicity of electrical connectors electrically coupled to and supported by the second printed circuit board; a second bidirectional optical sub-assembly comprising a second laser device and a second photodetector which are electrically coupled to the second printed circuit board and a second housing mounted to the second printed circuit board, the second housing being a single housing comprising a first receptacle that is configured to contain the second laser device and second photodetector and a second receptacle that is configured to receive one end of a second terminus that terminates a second optical cable, the first receptacle of the second housing being integrally formed or rigidly affixed to the second receptacle of the second housing, wherein the first laser device is electrically coupled to a first pair of electrical connectors of the first multiplicity of electrical connectors and arranged to transmit light through the first housing to an end of a first optical fiber in response to electrical signals received via the first pair of electrical connectors of the first multiplicity of electrical connectors; wherein the first photodetector is electrically coupled to a second pair of electrical connectors of the first multiplicity of electrical connectors and arranged to send electrical signals to the second pair of electrical connectors of the first multiplicity of electrical connectors in response to receipt of light from the end of the first optical fiber; wherein the second laser device is electrically coupled to a first pair of electrical connectors of the second multiplicity of electrical connectors and arranged to transmit light through the second housing to an end of a second optical fiber in response to electrical signals received via the first pair of electrical connectors of the second multiplicity of electrical connectors; and wherein the second photodetector is electrically coupled to a second pair of electrical connectors of the second multiplicity of electrical connectors and arranged to send electrical signals to the second pair of electrical connectors of the second multiplicity of electrical connectors in response to receipt of light from the end of the second optical fiber. 2. The pluggable active optical connector as recited in claim 1 , wherein the first multiplicity of electrical connectors are electrical sockets. 3. The pluggable active optical connector as recited in claim 1 , wherein the first bidirectional optical sub-assembly further comprises a wavelength-division multiplexing filter which is optically coupled to the first laser device and first photodetector. 4. The pluggable active optical connector as recited in claim 1 , wherein the first bidirectional optical sub-assembly further comprises: a first wavelength-division multiplexing filter which is optically coupled to the first laser device and first photodetector; and a second wavelength-division multiplexing filter which is optically coupled to the second laser device and second photodetector. 5. The pluggable active optical connector as recited in claim 3 , wherein the first bidirectional optical sub-assembly further comprises: a can that is disposed inside the first receptacle, contains the first laser device, first photodetector, and wavelength-division multiplexing filter, and has a window; and a lens installed in the window. 6. A data transmission system comprising: a fiber optical network comprising a plurality of pairs of optical fiber cables and a plurality of pairs of termini, each terminus terminating an end of a respective optical fiber cable; a plurality of electronic devices; a plurality of mating connectors which are respectively attached and electrically coupled to the plurality of electronic devices, each mating connector having first and second multiplicities of electrical connectors; and a plurality of pluggable active optical connectors which are respectively attached and electrically coupled to the plurality of mating connectors, attached to the plurality of pairs of termini, and optically coupled to the plurality of pairs of optical fiber cables, wherein each of the plurality of pluggable active optical connectors comprises a respective connector housing, a respective pair of printed circuit boards contained within the respective connector housing, and a respective pair of optical-electrical bidirectional transceivers optically coupled to the respective pair of optical fiber cables, electrically coupled to the respective pair of printed circuit boards, and contained within the respective connector housing, and wherein each optical-electrical bidirectional transceiver comprises a respective laser device, a respective photodetector, and a respective single housing comprising a first receptacle that is configured to receive the respective laser device and respective photodetector and a second receptacle that is integrally formed with the first receptacle and configured to receive one end of the respective terminus of the respective pair of termini, the first receptacle of the respective single housing being integrally formed or rigidly affixed to the second receptacle of the respective single housing. 7. The data transmission system as recited in claim 6 , wherein each bidirectional optical sub-assembly further comprises: a can that is disposed inside the respective housing, contains the respective laser device and the respective photodetector, and has a window; and a lens installed in the window. 8. The data transmission system as recited in claim 6 , wherein the electronic devices are line replaceable units. 9. The data transmission system as recited in claim 8 , wherein the line replaceable units are installed on an aircraft. 10. The data transmission system as recited in claim 6 , wherein each optical-electrical bidirectional transceiver further comprises a respective wavelength-division multiplexing filter which is optically coupled to the respective laser device and the respective photodetector. 11. The data transmission system as recited in claim 10 , wherein each optical-electrical bidirectional transceiver further comprises: a pair of data input terminals electrically coupled to respective electrical connectors of one mating connector; and a laser driver electrically coupled to the pair of data input terminals and to the laser device. 12. The data transmission system as recited in claim 11 , wherein each optical-electrical bidirectional transceiver further comprises: a pair of data output terminals electrically coupled to respective electrical connectors of the one mating connector; and a transimpedance ampli