Adjustable Laser Beam Width Device Based on Spatial Light Modulator
MI Chenkun1,YANG Zhaohui1,2,LIU Hongxin1,WANG Fei2
1. Suzhou Institute of Metrology, Suzhou, Jiangsu 215000, China
2. School of Physical Science and Technology,Soochow University, Suzhou, Jiangsu 215000, China
Abstract:In order to meet the traceability requirements of the laser industry for the beam width measuring device and improve the laser beam width calibration capability, a device which the laser beam width is continuously adjustable based on spatial light modulator (SLM) has been designed for the calibration of different beam widths of lasers in the 400~700nm wavelength range, which is used for the calibration of beam quality analyzers or laser spot measurement instruments. The experimental results show that the device is continuously adjustable in the width range of 0.1~5.0mm. This device utilizes the strong ability of partially coherent beams to resist environmental disturbances, its short-term stability is 99.5% and long-term stability is 99.1%, better than the short-term stability and long-term stability of reference laser which is 96.8% and 96.3% respectively. In addition, based on the superior beam shaping ability of SLM, the device can output the irregular beam to Gaussian beam.
HUANG C, ZHANG S Z, WANG J, et al. Review of Laser Frequency Stabilization Technology in Atmospheric Detection Lidar[J]. Acta Metrologica Sinica, 2023, 44(2): 186-194.
[10]
GUZMAN C, FORBES A. How to Shape Light with Spatial Light Modulators[M]. Bellingham, Washington 98227-0010 USA, 2017.
[17]
SIEGMAN A, New developments in laser resonators[J]. Proc. SPIE, 1990, 1224.
[14]
KOROTKOVA O, Scintillation index of a stochastic electromagnetic beam propagating in random media[J]. Opt. Commun., 2008, 281(9): 2342-2348.
WANG F, YU J Y, LIU X L, et al. Research progress of partially coherent beams propagation in turbulent atmosphere[J]. Acta Physica Sinica, 2018, 67(18):9-22.
LIN S Q, CAI Y J, YU J Y. Research progress of propagation of beams with spatial correlation structure in turbulent atmosphere[J]. High Power Laser and Partical Beams, 2021, 33(8): 081006.
[5]
ISO 11146-1: 2004. Test Methods for Laser Beam Widths, Divergence Angles and Beam Propagation Ratios—Part l: Stigmatic and Simple Astigmatic Beams[S].
[8]
CHEN Y H, GU J, WANG F, et al. Self-splitting properties of a Hermite-Gaussian correlated Schell-model beam[J]. Physical Review A, 2015, 91: 013823.
[15]
GBUR G, WOLF E. Spreading of partially coherent beams in random media[J]. Journal of the Optical Society of America A, 2002, 19(8): 1592-1598.
[3]
PRERANA S, SHWETA J, SHARMA R. A comparison of paraxial and extended paraxial approach for laser beam propagation in plasma[J]. Journal of Physics: Conference Series, 2012, 365(1): 012054.
WANG Y P, WANG Q B, MA C. Factors Affecting the Accurate Measurement of Laser Beam Width with CCD Camera[J]. Chinese Journal of Lasers, 2014, 41(2): 1-6.
ZHU L H, NIE Y Y, L B D. The Concept of the Beam Width and Comparison of Its Different Definitions[J]. Acta Photonica Sinica, 2005, 34(10): 1476-1479.
[12]
WOLF E. Introduction to the Theory of Coherence and Polarization of Light[M]. 1st Edition (978-0-521-82211-4) by Emil Wolf first published by Cambridge University Press, 2007.
WU F B, HU Z X, DUAN L C, et al. Development of Key Parameter Metrology and Detection Equipment for Q-switched Nd: YAG Laser Therapy Apparatus[J]. Acta Metrologica Sinica, 2023, 44(2): 311-316.
[11]
SPANGENBERG D, DUDLEY A, NEETHLING P, et al. White light wavefront control with a spatial light modulators[J]. Optics Express, 2014, 22(11): 13870-13879.
2024, Vol. 45 
