论文信息 - A two-mode interference measurement for nanometer accuracy absolute distance ranging

A two-mode interference measurement for nanometer accuracy absolute distance ranging

We present a laser ranging system, under development, that uses a high frequency modulated beam to achieve sub-nm resolution by the combined use of interferometric and time-of-flight measurements. We first describe how the absolute distance is extracted from a two-mode interference signal. In particular we show that the signal, which presents both optical and synthetic wavelength scales, is essential to achieve nm-scale accuracy, despite the significant long-term phase drifts in the 20 GHz detection chains. Then we present results obtained with the telemeter implemented on an optical table, for a distance of about four meters, implemented by folding the laser beam path to the target. The challenge here is to achieve a phase and amplitude measurement of two 20 GHz signals with a resolution well below 10-4 cycle and 10-4, respectively, despite the fact that the signal undergoes very strong (×3 ) amplitude changes.

[1] N. Schuhler,et al. High-accuracy absolute distance measurement using frequency comb referenced multiwavelength source. , 2008, Applied optics.

[2] L. Nenadovic,et al. Rapid and precise absolute distance measurements at long range , 2009 .

[3] S. Dubovitsky,et al. MSTAR: a submicrometer absolute metrology system. , 2003, Optics letters.

[4] Jack E. Volder. The CORDIC Trigonometric Computing Technique , 1959, IRE Trans. Electron. Comput..

[5] G. Raybon,et al. Linear optical sampling , 2003, IEEE Photonics Technology Letters.

[6] William T. Estler,et al. Large-Scale Metrology – An Update , 2002 .

[7] Etienne Samain,et al. Multiple four-wave mixing in optical fibers: 1.5-3.4-THz femtosecond pulse sources and real-time monitoring of a 20-GHz picosecond source , 2010 .

[8] M. Fridlund. Future Space Missions to Search for Terrestrial Planets , 2008 .

[9] A. Labeyrie,et al. Tests with a Carlina-type hypertelescope prototype I. Demonstration of star tracking and fringe acquisition with a balloon-suspended focal camera , 2004 .

[10] W. Chaibi,et al. Low noise amplification of an optically carried microwave signal: application to atom interferometry , 2010, 1003.0266.