Widely tunable short cavity laser

What is claimed is: 1. A high speed swept source comprising: a first tunable laser; and a second tunable laser; wherein each of said first and second tunable lasers is configured to emit tunable radiation over an emission wavelength range having a center wavelength, with an output power spectrum over said emission wavelength range and an average emission power; wherein each of said first and second tunable lasers comprises: an optical cavity including a first and second mirror; a gain region interposed between said first and second mirrors; a tuning region; and means for adjusting an optical path length of said tuning region; wherein: a free spectral range (FSR) of said optical cavity exceeds 5% of said center wavelength; said tunable laser operates substantially in a single longitudinal and transverse mode over said emission wavelength range; and said means has a wavelength tuning frequency response with a 6-dB bandwidth greater than about 1 kHz; and wherein a first wavelength sweep of said first tunable laser and a second wavelength sweep of said second tunable laser are interleaved to produce an interleaved sweep. 2. The high speed swept source of claim 1 , wherein a high-extinction ratio optical amplifier is used to gate on and off each of said first and second tunable lasers. 3. The high-speed swept source of claim 1 , wherein a pump energy of each of said tunable lasers is used to gate on an off each of said first and second tunable lasers. 4. The high-speed swept source of claim 1 , wherein at least one of the first tunable laser or the second tunable laser or both have said FSR larger than the emission wavelength range. 5. The high-speed swept source of claim 1 , wherein said means for adjusting an optical path length is configured to adjust a physical length of an airgap; and a frequency response of said means for adjusting an optical path length has damping substantially increased by squeeze-film damping effects. 6. The high-speed swept source of claim 1 , wherein said means for adjusting an optical path length further comprises a suspended mirror having a first diameter disposed on a central plate having a second diameter, wherein said first diameter is less than about half of said second diameter. 7. The high-speed swept source of claim 1 , wherein the interleaved sweep has an increased sweep rate compared to the first wavelength sweep or the second wavelength sweep or both. 8. The high-speed swept source of claim 1 , wherein the interleaved sweep has an increased emission wavelength range compared to the first wavelength sweep or the second wavelength sweep or both. 9. The high-speed swept source of claim 1 , wherein the first wavelength sweep and the second wavelength sweep have different tuning ranges. 10. The high-speed swept source of claim 1 , wherein the first wavelength sweep and the second wavelength sweep have different tuning speeds. 11. The high-speed swept source of claim 1 , wherein the first wavelength sweep and the second wavelength sweep have different tuning trajectories. 12. A method for generating an interleaved sweep comprising: generating a first wavelength sweep with a first tunable laser; and generating a second wavelength sweep with a second tunable laser; wherein each of said first and second tunable lasers is configured to emit tunable radiation over an emission wavelength range having a center wavelength, with an output power spectrum over said emission wavelength range and an average emission power; wherein each of said first and second tunable lasers comprises: an optical cavity including a first and second mirror; a gain region interposed between said first and second mirrors; a tuning region; and means for adjusting an optical path length of said tuning region; wherein: a free spectral range (FSR) of said optical cavity exceeds 5% of said center wavelength; said tunable laser operates substantially in a single longitudinal and transverse mode over said emission wavelength range; and said means has a wavelength tuning frequency response with a 6-dB bandwidth greater than about 1 kHz; and interleaving the first wavelength sweep and the second wavelength sweep to generate an interleaved sweep. 13. The method of claim 12 , further comprising gating on and off each of said first and second tunable lasers with a high-extinction ratio optical amplifier. 14. The method of claim 12 , further comprising gating on and off each of said first and second tunable lasers with changes to a pump energy. 15. The method of claim 12 , wherein at least one of the first tunable laser or the second tunable laser or both have said FSR larger than the emission wavelength range. 16. The method of claim 12 , wherein said means for adjusting an optical path length is configured to adjust a physical length of an airgap; and a frequency response of said means for adjusting an optical path length has damping substantially increased by squeeze-film damping effects. 17. The method of claim 12 , wherein said means for adjusting an optical path length further comprises a suspended mirror having a first diameter disposed on a central plate having a second diameter, wherein said first diameter is less than about half of said second diameter. 18. The method of claim 12 , wherein the interleaved sweep has an increased sweep rate compared to the first wavelength sweep or the second wavelength sweep or both. 19. The method of claim 12 , wherein the interleaved sweep has an increased emission wavelength range compared to the first wavelength sweep or the second wavelength sweep or both. 20. The method of claim 12 , wherein the first wavelength sweep and the second wavelength sweep have different tuning ranges. 21. The method of claim 12 , wherein the first wavelength sweep and the second wavelength sweep have different tuning speeds. 22. The method of claim 12 , wherein the first wavelength sweep and the second wavelength sweep have different tuning trajectories.