Two beam small arms transmitter

What is claimed is: 1. A Small Arms Transmitter (SAT) configured to be weapon mounted for use in a combat force training system at various temperatures, the SAT comprising: a first optical source having: a first collimating lens; and a first beam at a non-visible wavelength configured to provide signaling in the combat force training system; a second optical source having: a second collimating lens; and a second beam in a visible wavelength; and an optical combiner configured to combine the first beam with the second beam to generate a combined beam having a common optical axis; wherein both the first collimating lens and the second collimating lens have an F number greater than 2. 2. The SAT of claim 1 , wherein a laser source size of the either or both of the first optical source or the second optical source is between 40 and 60 microns. 3. The SAT of claim 1 , further comprising a beam alignment module configured to steer the combined beam. 4. The SAT of claim 1 , wherein the first optical source comprises an InfraRed (IR) laser. 5. The SAT of claim 1 , wherein the second optical source comprises a laser having a visible wavelength output. 6. The SAT of claim 1 , wherein the optical combiner comprises a cold mirror. 7. The SAT of claim 1 , further comprising a controller configured to selectively enable the second optical source in response to an alignment activation command. 8. The SAT of claim 1 , further comprising a housing configured to house either or both the first optical source or the second optical source comprises a nickel-cobalt ferrous alloy. 9. The SAT of claim 1 , wherein either or both the first collimating lens or the second collimating lens comprise Borosilicate Crown Glass. 10. A Small Arms Transmitter (SAT) configured to be weapon mounted for use in a combat force training system, the SAT comprising: an Infrared (IR) laser having: a first collimating lens having an F number greater than 2; and an IR output beam; wherein the IR laser is configured to provide signaling in the combat force training system; a visible wavelength laser having: a second collimating lens having an F number greater than 2; and a visible wavelength output beam; an optical combiner configured to combine the IR output beam with the visible wavelength output beam to generate a combined beam; a beam alignment module configured to steer the combined beam; and a controller configured to selectively enable the visible wavelength laser. 11. The SAT of claim 10 , wherein a laser source size of the either or both of the first optical source or the second optical source is between 40 and 60 microns. 12. The SAT of claim 10 , wherein: the IR laser is positioned with the IR output beam along a first axis; the visible wavelength laser is positioned with the visible wavelength output beam along a second axis perpendicular to the first axis; and wherein the optical combiner comprises a mirror positioned at an intersection of the first axis with the second axis. 13. The SAT of claim 10 , wherein the optical combiner comprises at least one of a dichroic, a cold mirror, or a hot mirror. 14. The SAT of claim 10 , wherein the beam alignment module comprises: a first beam steering module configured to steer the combined beam along a first axis; and a second beam steering module configured to steer the combined beam along a second axis perpendicular the first axis. 15. A method of manufacturing an athermal Small Arms Transmitter (SAT) configured to be weapon mounted for use in a combat force training system, the method comprising: providing a first optical source capable of emitting a first beam at a non-visible wavelength, the first optical source having a collimating lens with an F number greater than 2; providing a second optical source capable of emitting a second beam in a visible wavelength, the second optical source having a collimating lens with an F number greater than 2; and positioning an optical combiner in relation to the first optical source and the second optical source so as to combine the first beam with the second beam. 16. The method of manufacturing an athermal SAT of claim 15 , further comprising providing the first optical source or the second optical source in a housing that comprises a nickel-cobalt ferrous alloy. 17. The method of manufacturing an athermal SAT of claim 15 , further comprising situating a beam alignment module relative to the optical combiner such that the alignment module can steer the combined beam. 18. The method of manufacturing an athermal SAT of claim 15 , further comprising bonding a laser tube assembly of either or both the first optical source or the second optical source while the laser tube assembly is heated to a temperature of greater than 125° C. and less than 300° C. 19. The method of manufacturing an athermal SAT of claim 18 , further wherein a material used to bond the laser tube assembly does not flow below 300° C. during use of the athermal SAT.