Wavelength division multiplexing and demultiplexing transistor outline (TO)-can assemblies for use in optical communications, and methods

What is claimed is: 1. A wavelength division demultiplexing (WDM) receiver optical subassembly (ROSA) transistor-outline (TO)-can assembly comprising: an assembly body having a forward end, a rearward end opposite the forward end, and an optical receptacle on the forward end that is adapted to hold an end of an optical fiber that is capable of carrying an optical signal having at least N wavelengths of light, where N is a positive integer that is equal to or greater than four, the assembly body having a main optical axis that extends from the forward end to the rearward end; at least N TO-can devices disposed on or formed in the assembly body, a first of the N TO-can devices being located in the rearward end of the assembly body and having an optical axis that is coaxial with main optical axis, wherein second through an Nth TO-can devices of the N TO-can devices are located in a side wall of the assembly body and have respective optical axes that are at a non-zero-degree angle to the main optical axis, wherein each of the N TO-can devices has an optoelectronic device therein that operates at a different wavelength of the N wavelengths; and an optics system disposed in the assembly body, the optics system coupling light between the optoelectronic devices of the N TO-can devices and the end of the optical fiber, the optics system including an optical wavelength division demultiplexing (WDM) arrangement comprising N−1 WDM filters disposed along the main optical axis and N−1 mirrors associated with the N−1 WDM filters, respectively, the N−1 mirrors being disposed at respective positions that are aligned with the respective optical axes of the second through Nth T-O can devices, wherein each WDM filter directs one of the light beams of one of the second through Nth wavelengths onto the associated mirror and wherein the associated mirror directs the respective light beam along the optical axis of the respective TO-can device toward the respective TO-can device, and wherein the light beam of the first wavelength of the N wavelengths passes through the N WDM filters and propagates toward the first TO-can device. 2. The WDM ROSA TO-can assembly of claim 1 , wherein the optics system further includes: N half-ball lenses, each half-ball lens coupling a respective one of the N light beams onto the respective optoelectronic device of the respective TO-can device. 3. The WDM ROSA TO-can assembly of claim 2 , further comprising: a collimating lens located at the forward end of the assembly body, the collimating lens collimating the optical signal of the N wavelengths of light as the optical signal passes out of the end of optical fiber, wherein each of the WDM filters operates on a collimated light beam. 4. The WDM ROSA TO-can assembly of claim 1 , wherein each of the WDM filters is at a non-zero-degree angle, α, relative to the main optical axis, wherein the non-zero-degree angle of the WDM filters relative to the main optical axis is less than 45 degrees. 5. The WDM ROSA TO-can assembly of claim 4 , wherein each of the mirrors is at an angle, β, relative to the main optical axis, wherein β is equal to 45 degrees minus α. 6. The WDM ROSA TO-can assembly of claim 1 , wherein the optical axes of the second through Nth T-O-can devices are at 90° angles relative to the main optical axis. 7. The WDM ROSA TO-can assembly of claim 1 , wherein a distance from back sides of respective headers of the second through Nth TO-can devices to the main optical axis is about three millimeters (mm). 8. The WDM ROSA TO-can assembly of claim 1 , wherein each of the optoelectronic devices operates at a data rate of at least 10.3125 Gigabits per second (Gbps) such that the TO-can assembly operates at a data rate of at least about 40 Gbps. 9. The WDM ROSA TO-can assembly of claim 1 , wherein each of the optoelectronic devices operates at a data rate of at least 25 Gigabits per second (Gbps) such that the TO-can assembly operates at a data rate of at least about 100 Gbps. 10. A quad small form factor pluggable (QSFP) optical transceiver module comprising: a QSFP module housing; a wavelength division multiplexing transmitter optical subassembly (TOSA) disposed in the QSFP module housing; and a wavelength division demultiplexing receiver optical subassembly (ROSA) disposed in the QSFP module housing, the TOSA and ROSA each comprising a transistor-outline (TO)-can assembly comprising: an assembly body having a forward end, a rearward end opposite the forward end, and an optical receptacle on the forward end that is adapted to hold an end of an optical fiber that is capable of carrying an optical signal having at least N wavelengths of light, where N is a positive integer that is equal to or greater than four, the assembly body having a main optical axis that extends from the forward end to the rearward end; at least N TO-can devices disposed on or formed in the assembly body, a first of the N TO-can devices being located in the rearward end of the assembly body and having an optical axis that is coaxial with a main optical axis, wherein second through an Nth TO-can devices of the N TO-can devices are located in a side wall of the assembly body and have respective optical axes that are at a non-zero-degree angle to the main optical axis, wherein each of the N TO-can devices has an optoelectronic device therein that operates at a different wavelength of the N wavelengths; and an optics system disposed in the assembly body, the optics system coupling light between the optoelectronic devices of the N TO-can devices and the end of the optical fiber. 11. A wavelength division multiplexing (WDM) transmitter optical subassembly (TOSA) transistor-outline (TO)-can assembly comprising: an assembly body having a forward end, a rearward end opposite the forward end, and an optical receptacle on the forward end that is adapted to hold an end of an optical fiber that is capable of carrying an optical signal having at least N wavelengths of light, where N is a positive integer that is equal to or greater than four, the assembly body having a main optical axis that extends from the forward end to the rearward end; at least N TO-can devices disposed on or formed in the assembly body, a first of the N TO-can devices being located in the rearward end of the assembly body and having an optical axis that is coaxial with the main optical axis, wherein second through an Nth TO-can devices of the N TO-can devices are located in a side wall of the assembly body and have respective optical axes that are at a non-zero-degree angle to the main optical axis, wherein each of the N TO-can devices has an optoelectronic device therein that operates at a different wavelength of the N wavelengths; and an optics system disposed in the assembly body, the optics system including N half-ball lenses and an optical wavelength division multiplexing (WDM) arrangement, the WDM arrangement performing WDM to combine N light beams of first through Nth respective wavelengths of light produced by N optoelectronic devices of the N TO-can devices, respectively, into a combined optical signal having at least the N wavelengths of light, the WDM arrangement comprising N-1 WDM filters disposed along the main optical axis, wherein the N half-ball lenses collimate the N light beams and couple the N collimated light beams onto a respective WDM filter, wherein each WDM filter reflects one of the collimated light beams of the second through an Nth wavelengths toward the forward end of the assembly body, and wherein each WDM filter passes any of the collimated light beams that are incident thereon except for the collimated light beam that is reflected by the respective WDM filter.