光谱学与光谱分析 |
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Laser Tuning Performance Testing and Optimization in TDLAS Oxygen Measuring Systems |
HE Jun-feng1, HU Jun1, KAN Rui-feng2, XU Zhen-yu2, WANG Tao1 |
1. Army Officer Academy,Hefei 230031,China 2. Key Lab of Environmental Optics & Technology, Chinese Academy of Sciences,Heifei 230031, China |
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Abstract TDLAS (tunable diode laser absorption spectroscopy) technology, with its unmatched advantages such as high selectivity molecular spectra, fast response, highsensitivity, non-contact measuring, become the preferred scheme for combustion process diagnosis, and can be effectively used for oxygen measuring. DFB (distributed feedback) laser diode with its small size, low power consumption, long service life, narrow linewidth, tunable wavelength has become the main choice of the TDLAS system. Performance of laser tuning characteristics is a key factor restricting TDLAS’s measuring performance. According to TDLAS oxygen measuring system’s working requirements, a simple experimental method was used totest and analyze tuning characteristics such as wavelength current, power current and wavelength temperature of a 764 nm DFB laser diode in the system. Nonlinear distortion of tuning curves was obvious, which affects oxygen measuring accuracy. The laser spectra’s characteristics such as narrow linewidth, high side mode suppression ratio and wide wavelength tuning range are obvious, while its wavelength-current tuning curve with a tuning rate of about 0.023 nm·mA-1 is not strictly linear. The higher the temperature the greater the threshold current, the PI curve is not strictly linear either. Temperature tuning curve is of good linearity, temperature-wavelength tuning rate keeps constant of about 0.056 nm/DEG C. Temperature tuning nonlinearity can be improved by hightemperature control accuracy, and current power nonlinearity can be improved by setting the reference light path. In order to solve the wavelength current tuning nonlinear problems, the method of DA controlling injection current was considered to compensate for non-linear wavelength current tuning according to DFBlaser diode tuning mechanism and polynomial fitting of test results. In view of different type of lasers, this method needs only one polynomial fitting process before the system’s initial work. The compensation scheme is reasonable andthe realization is simple, what’s more, it does not affect the measuring process. The experiments prove that λI curve’s linear fit residuals are less than 1 pm after compensation, far less than those of before compensation 22 pm, the compensation effect is obvious, which provided a basis for various oxygen parameters’ TDLAS measuring and inversion.
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Received: 2013-10-31
Accepted: 2014-02-18
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Corresponding Authors:
HE Jun-feng
E-mail: ruwhat@163.com
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