Referencing insertion loss using back-facet monitor from lasers

What is claimed is: 1. A test instrument to test optical components, the test instrument comprising: a laser; a back-facet monitor including a back-facet monitor photodiode to measure optical power at the laser; a power meter including a photodiode to measure optical power at a port connectable to a device under test (DUT) that is being tested by the test instrument; and a processing circuit to: determine a first set of measurements performed by the back-facet monitor photodiode and the photodiode of the power meter; determine a reference power based on the measurements performed by the back-facet monitor photodiode and the photodiode of the power meter, wherein the reference power is determined as a difference between a power measurement, of the first set of the measurements, taken by the back-facet monitor photodiode and another power measurement, of the first set of the measurements, taken by the photodiode of the power meter; determine a DUT power based on a second set of the measurements performed by the back-facet monitor photodiode and the photodiode of the power meter when the DUT is connected to the test instrument; and determine a performance parameter of the DUT based on the reference power and the DUT power, wherein the performance parameter comprises at least one of insertion loss, return loss and polarization dependent loss. 2. The test instrument of claim 1 , wherein the reference power is determined based on the first set of the measurements measured when the DUT is not connected to the test instrument. 3. The test instrument of claim 2 , wherein the DUT power is determined based on the second set of the measurements measured when the DUT is connected to the test instrument. 4. The test instrument of claim 3 , wherein the first set of measurements are performed at a time t 1 and the second set of measurements are performed at a time t 2 that is subsequent to the time t 1 . 5. The test instrument of claim 4 , Wherein the processing circuit determines the performance parameter of the DUT based on the optical power of the laser measured at t 1 and an optical power measured by the photodiode of the power meter at t 2 . 6. The test instrument of claim 1 , wherein the processing circuit accounts for drift in optical power of the laser occurring during the measurements to determine the performance parameter. 7. The test instrument of claim 1 , wherein the DUT comprises a passive optical component. 8. The test instrument of claim 7 , wherein the photodiode of the power meter is operable to measure input optical power of light received at the port that was emitted by the laser. 9. A test instrument to test a device under test (DUT) comprising an optical component, the test instrument comprising: a laser; a back-facet monitor including a back-facet monitor photodiode to measure optical power at the laser; a first port and a second port connectable to at least one of an optical cable and the DUT, wherein the laser is operable to emit light into the optical cable when connected to the first port; a power meter including a photodiode to measure input optical power of light received at the second port; and a processing circuit to: determine measurements performed by the back-facet monitor photodiode and the photodiode of the power meter; determine a reference power based on a first set of the measurements performed by the back-facet monitor photodiode and the photodiode of the power meter when the DUT is not connected to the test instrument, wherein the reference power is determined as a difference between a power measurement, of the first set of the measurements, taken by the back-facet monitor photodiode and another power measurement, of the first set of the measurements, taken by the photodiode of the power meter; determine a DUT power based on a second set of the measurements performed by the back-facet monitor photodiode and the photodiode of the power meter when the DUT is connected to the test instrument; and determine a performance parameter of the DUT based on the reference power and the DUT power that accounts for drift of the optical power of the laser when the first and second sets of the measurements are measured. 10. The test instrument of claim 9 , wherein the first set of the measurements are performed at a time t 1 and the second set of the measurements are performed at a time t 2 that is subsequent to the time t 1 . 11. The test instrument of claim 9 , wherein the performance parameter comprises at least one of insertion loss, return loss and polarization dependent loss. 12. The test instrument of claim 9 , wherein the DUT comprises a passive optical component. 13. The test instrument of claim 9 , wherein the first set of the measurements to determine the reference power are measured at a time t 1 when an optical cable is connected between the first and second ports and the laser emits light into the optical cable, and the second set of the measurements to determine the DUT power are measured at a time t 2 that is subsequent to the time t 1 when the DUT is connected to the first and second ports via optical cables, wherein the DUT comprises a passive optical component, and wherein the performance parameter comprises at least one of insertion loss, return loss and polarization dependent loss. 14. A method executable by a test instrument to test an optical component of a fiber optic network, the method comprising: measuring optical power at a back-facet monitor of a laser operable to emit light via at least one port of the test instrument; measuring optical power of input light received at the at least one port by a photodiode of a power meter of the test instrument; determining a reference power from a difference of the measured optical power at the back-facet monitor and the measured optical power of the input light received at the at least one port and measured by the photodiode of the power meter; measuring a second set of the measurements performed by the back-facet monitor and the photodiode of the power meter when a device under test (DUT) is connected to the test instrument and determining a performance parameter of the optical component being tested based on the reference power and the second set of measurements. 15. The method of claim 14 , wherein the reference power is determined based on a first set of the measurements when the DUT is not connected to the test instrument. 16. The method of claim 14 , wherein the first set of the measurements are performed at a time t 1 and the second set of the measurements are performed at a time t 2 that is subsequent to the time t 1 . 17. The method of claim 14 , wherein the performance parameter comprises at least one of insertion loss, return loss and polarization dependent loss.