Single-wavelength bidirectional transceiver with integrated optical fiber coupler

The invention claimed is: 1. An apparatus comprising: a 2×1 fusion coupler; an input/output optical fiber connected to the 2×1 fusion coupler; a detector optical subassembly fiber connected to the 2×1 fusion coupler; a laser optical subassembly fiber connected to the 2×1 fusion coupler; a transceiver comprising a transceiver electronic circuit printed wiring board, a laser optical subassembly electrically coupled to the transceiver electronic circuit printed wiring board and a detector optical subassembly electrically coupled to the transceiver electronic circuit printed wiring board, wherein the laser optical subassembly comprises a laser that is situated to transmit light to the laser optical subassembly fiber, and the detector optical subassembly comprises a photodetector that is situated to receive light from the detector optical subassembly fiber; and a metal base, wherein the transceiver electronic circuit printed wiring board and the 2×1 fusion coupler are attached to the metal base, and the 2×1 fusion coupler is disposed between the metal base and the transceiver electronic circuit printed wiring board. 2. The apparatus as recited in claim 1 , wherein the transceiver electronic circuit printed wiring board comprises a multiplicity of transceiver input/output metal contacts arranged at one end of the transceiver electronic circuit printed wiring board. 3. The apparatus as recited in claim 2 , further comprising a metal cover, wherein the transceiver electronic circuit printed wiring board and the metal cover are attached to the metal base, and the metal cover is open at one end to expose the transceiver input/output metal contacts, thereby enabling the corresponding metal contacts on an application hardware to be in contact with the transceiver input/output metal contacts when the one end of the transceiver electronic circuit printed wiring board is plugged into that application hardware. 4. The apparatus as recited in claim 1 , wherein the laser and detector optical subassemblies and the transceiver electronic circuit printed wiring board are attached to the metal base. 5. The apparatus as recited in claim 4 , further comprising a pair of flex circuits that respectively electrically connect the laser and detector optical subassemblies to the transceiver electronic circuit printed wiring board. 6. The apparatus as recited in claim 1 , wherein the metal base comprises a fiber nose tube projecting from one end of the metal base, and the input/output optical fiber passes through the fiber nose tube. 7. The apparatus as recited in claim 6 , further comprising a fiber boot that surrounds the fiber nose tube and a portion of the input/output optical fiber that projects beyond a distal end of the fiber nose tube. 8. The apparatus as recited in claim 1 , wherein the 2×1 fusion coupler, the input/output optical fiber, the detector optical subassembly fiber and the laser optical subassembly fiber are made of glass. 9. The apparatus as recited in claim 1 , wherein the 2×1 fusion coupler has a length of about 25 mm and a diameter of about 1.5 mm. 10. A data transmission system comprising: an optical cable comprising an optical fiber capable of carrying bits of data at a bit rate of at least one gigabit; a 2×1 fusion coupler optically coupled to one end of the optical cable; a transceiver comprising a transceiver electronic circuit printed wiring board, a detector optical subassembly optically coupled to the 2×1 fusion coupler and electrically coupled to the transceiver electronic circuit printed wiring board, and a laser optical subassembly optically coupled to the 2×1 fusion coupler and electrically coupled to the transceiver electronic circuit printed wiring board, wherein the laser optical subassembly comprises a laser that is situated to transmit light to the 2×1 fusion coupler, and the detector optical subassembly comprises a photodetector that is situated to receive light from the 2×1 fusion coupler; and a metal base, wherein the transceiver electronic circuit printed wiring board and the 2×1 fusion coupler are attached to the metal base, and the 2×1 fusion coupler is disposed between the metal base and the transceiver electronic circuit printed wiring board. 11. The data transmission system as recited in claim 10 , wherein the optical fiber is made of plastic. 12. The data transmission system as recited in claim 10 , wherein the 2×1 fusion coupler is made of glass and has a length of about 25 mm and a diameter of about 1.5 mm. 13. The data transmission system as recited in claim 10 , further comprising: a switch connected to the transceiver; and a line replaceable unit connected to the switch. 14. The data transmission system as recited in claim 10 , wherein the transceiver electronic circuit printed wiring board comprises a multiplicity of transceiver input/output metal contacts arranged at one end of the transceiver electronic circuit printed wiring board, further comprising a metal cover, wherein the transceiver electronic circuit printed wiring board and the metal cover are attached to the metal base, and the metal cover is open at one end to expose the transceiver input/output metal contacts, thereby enabling the corresponding metal contacts on an application hardware to be in contact with the transceiver input/output metal contacts when the one end of the transceiver electronic circuit printed wiring board is plugged into that application hardware. 15. The data transmission system as recited in claim 10 , wherein the laser and detector optical subassemblies are attached to the metal base. 16. The data transmission system as recited in claim 15 , further comprising a pair of flex circuits that respectively electrically connect the laser and detector optical subassemblies to the transceiver electronic circuit printed wiring board. 17. A method for assembling a pluggable transceiver package, comprising: connecting an input/output optical fiber, a detector optical subassembly fiber and a laser optical subassembly fiber to a 2×1 fusion coupler; inserting the input/output optical fiber into a fiber nose tube projecting from one end of a metal base; attaching the 2×1 fusion coupler to the metal base; connecting laser and detector optical subassemblies to a transceiver electronic circuit printed wiring board by way of respective flex circuits; inserting one end of the detector optical subassembly fiber inside a detector optical subassembly; inserting one end of the laser optical subassembly fiber inside a laser optical subassembly; attaching the laser and detector optical subassemblies to the metal base; positioning the transceiver electronic circuit printed wiring board so that the 2×1 fusion coupler is between the transceiver electronic circuit printed wiring board and metal base; and attaching the transceiver electronic circuit printed wiring board to the metal base. 18. The method as recited in claim 17 , further comprising: sliding a fiber boot onto the fiber nose tube; and attaching the fiber boot to the fiber nose tube on the metal base. 19. The method as recited in claim 17 , further comprising: placing a metal cover over the laser and detector optical subassemblies and the transceiver electronic circuit printed wiring board; and attaching the metal cover to the metal base, wherein the metal cover is open at one end to expose a multiplicity of transceiver input/output metal contacts on the transceiver electronic circuit printed wiring board, thereby enabling the corresponding metal contacts on an application