Brillouin and rayleigh distributed sensor

What is claimed is: 1. A Brillouin and Rayleigh distributed sensor comprising: a first laser source to emit a first laser beam; a second laser source to emit a second laser beam; a photodiode to acquire a beat frequency between the first laser beam and the second laser beam, wherein the beat frequency is used to maintain a predetermined offset frequency shift between the first laser beam and the second laser beam, wherein the predetermined offset frequency shift is relative to a predetermined frequency of either the first laser beam or the second laser beam; a modulator to modulate the first laser beam, wherein the modulated first laser beam is to be injected into a device under test (DUT); a coherent receiver, disposed separately from the photodiode, to acquire a backscattered signal from the DUT, wherein the backscattered signal results from the modulated first laser beam injected into the DUT, and wherein the coherent receiver is to use the second laser beam as a local oscillator to determine, based on the acquired backscattered signal, Brillouin and Rayleigh traces with respect to the DUT based on the predetermined offset frequency shift between the first laser beam and the second laser beam by further using a polarization beam splitter (PBS) of the coherent receiver to receive the backscattered signal, and divide the backscattered signal into two different polarization states including a first polar state and a second polar state that are the same as first and second polar states of the second laser beam, wherein a divided portion of the backscattered signal corresponding to the first polar state is to be mixed with the second laser beam at the first polar state, and a divided portion of the backscattered signal corresponding to the second polar state is to be mixed with the second laser beam at the second polar state to determine the Brillouin and Rayleigh traces with respect to the DUT; a processor; and a non-transitory computer readable medium storing machine readable instructions that when executed by the processor cause the processor to: determine, based on the Brillouin and Rayleigh traces, temperature and strain associated with the DUT. 2. The Brillouin and Rayleigh distributed sensor of claim 1 , wherein the predetermined offset frequency shift for determination of the Brillouin trace is approximately 10.8 GHz. 3. The Brillouin and Rayleigh distributed sensor of claim 1 , wherein the predetermined offset frequency shift for determination of the Brillouin trace is selected from a range of approximately 10.0 GHz to approximately 13.0 GHz. 4. The Brillouin and Rayleigh distributed sensor of claim 1 , wherein the predetermined offset frequency shift for determination of the Rayleigh trace is selected from a range of approximately 100.0 KHz to approximately 1.0 GHz. 5. The Brillouin and Rayleigh distributed sensor of claim 1 , wherein the DUT is an optical fiber. 6. A method for Brillouin trace and Rayleigh trace determination, the method comprising: maintaining, based on a beat frequency acquired by a photodiode and between a first laser beam and a second laser beam, a predetermined offset frequency shift between the first laser beam and the second laser beam, wherein the predetermined offset frequency shift is relative to a predetermined frequency of either the first laser beam or the second laser beam; modulating the first laser beam, wherein the modulated first laser beam is to be injected into a device under test (DUT); acquiring, by a coherent receiver disposed separately from the photodiode, a backscattered signal from the DUT, wherein the backscattered signal results from the modulated first laser beam injected into the DUT, and wherein the second laser beam is to be used as a local oscillator; determining, based on the acquired backscattered signal from the DUT, a Brillouin trace for the DUT; repeating the acquisition of the backscattered signal from the DUT for a plurality of frequency shifts; sampling, based on the repeated acquisitions corresponding to the plurality of frequency shifts and the acquisition of the backscattered signal from the DUT, a distributed Brillouin spectra; determining, based on the sampling of the distributed Brillouin spectra, a resonant Brillouin frequency shift along the DUT; and determining, based on the sampling of the distributed Brillouin spectra, integrated Brillouin power by performing an integration operation with respect to the resonant Brillouin frequency shift. 7. The method for Brillouin trace and Rayleigh trace determination according to claim 6 , further comprising: determining, based on the integrated Brillouin power, Rayleigh power, and the resonant Brillouin frequency shift along the DUT, temperature and strain associated with the DUT. 8. The method for Brillouin trace and Rayleigh trace determination according to claim 6 , wherein the DUT is an optical fiber. 9. The method for Brillouin trace and Rayleigh trace determination according to claim 6 , wherein the predetermined offset frequency shift for determination of the Brillouin trace is approximately 10.8 GHz. 10. The method for Brillouin trace and Rayleigh trace determination according to claim 6 , wherein the predetermined offset frequency shift for determination of the Brillouin trace is selected from a range of approximately 10.0 GHz to approximately 13.0 GHz. 11. A method for Brillouin trace and Rayleigh trace determination, the method comprising: scanning a first laser beam and a second laser beam over a wavelength range with a predetermined offset frequency shift between the two laser beams, wherein the predetermined offset frequency shift is relative to a predetermined frequency of either the first laser beam or the second laser beam, and wherein the predetermined offset frequency shift between the two laser beams is based on a beat frequency acquired by a photodiode; modulating the first laser beam, wherein the modulated first laser beam is to be injected into a device under test (DUT); acquiring, by a coherent receiver disposed separately from the photodiode, a backscattered signal from the DUT, wherein the backscattered signal results from the modulated first laser beam injected into the DUT, and wherein the second laser beam is to be used as a local oscillator; determining, based on the acquired backscattered signal from the DUT, a Rayleigh trace for the DUT; determining a Brillouin trace for the DUT; determining, based on the Rayleigh trace and the Brillouin trace, Rayleigh power and Brillouin power; normalizing the Brillouin power with respect to the Rayleigh power to remove power variations associated with the DUT; and determining, based on the normalized Brillouin power and a resonant Brillouin frequency shift along the DUT, temperature and strain associated with the DUT. 12. The method for Brillouin trace and Rayleigh trace determination according to claim 11 , further comprising: repeating the acquisition of the backscattered signal from the DUT for the predetermined offset frequency shift; and averaging, during scanning of the first laser beam and the second laser beam over the wavelength range with the predetermined offset frequency shift between the two laser beams, the repeated acquisitions of the backscattered signal from the DUT for the predetermined offset frequency shift to reduce coherent fading noises. 13. The method for Brillouin trace and Rayleigh trace determination according to claim 11 , wherein the predetermined offset frequency shift is selected from a range of approximately 100.0 KHz to approximately 1.0 GHz. 14. The method for Brillouin trace and Raylei