An improved Savitzky–Golay filtering algorithm for measuring pharmaceutical vial’s oxygen content based on wavelength modulation spectroscopy
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Gao Feng Zhu, Hong Qiu Zhu, Chun Hua Yang, Wei Hua Gui An improved Savitzky–Golay filtering algorithm for measuring pharmaceutical vial’s oxygen content based on wavelength modulation spectroscopy (Улучшенный алгоритм Савицкого–Голея для измерений содержания кислорода в фармацевтических пробах на основе волновой модуляционной спектроскопии) [на англ. яз.] // Оптический журнал. 2017. Т. 84. № 5. С. 86–91.
Gao Feng Zhu, Hong Qiu Zhu, Chun Hua Yang, Wei Hua Gui An improved Savitzky–Golay filtering algorithm for measuring pharmaceutical vial’s oxygen content based on wavelength modulation spectroscopy (Улучшенный алгоритм Савицкого–Голея для измерений содержания кислорода в фармацевтических пробах на основе волновой модуляционной спектроскопии) [in English] // Opticheskii Zhurnal. 2017. V. 84. № 5. P. 86–91.
Gao Feng Zhu, Hong Qiu Zhu, Chun Hua Yang, and Wei Hua Gui, "Improved Savitzky-Golay filtering algorithm for measuring a pharmaceutical vial’s oxygen content based on wavelength modulation spectroscopy," Journal of Optical Technology. 84(5), 355-359 (2017). https://doi.org/10.1364/JOT.84.000355
An improved Savitzky-Golay filtering algorithm was adopted to denoise the on-line measurement of a pharmaceutical vial’s oxygen content based on wavelength modulation spectroscopy. This algorithm was created to feed second harmonic signals containing noise into a sliding window and to reduce, or eliminate, pulse interference. Then, the data containing no singular values were processed by weighted moving average filter. The second harmonic signals were simulated and the experiments performed to measure a pharmaceutical vial’s oxygen concentration by using the improved Savitzky-Golay filtering algorithm: results were compared with those from a traditional algorithm, and a wavelet transform filter. The results indicated that the improved Savitzky-Golay filtering algorithm can match the efficacy of the wavelet analysis, but the former ran much faster than the latter, and the system response time was about 300 ms. The improved Savitzky-Golay filtering algorithm was suitable for on-line measurement of gas concentration.
improved Savitzky-Golay filtering algorithm, wavelength modulation spectroscopy, second harmonic signal, wavelet transform, least squares method
Acknowledgements:This work is partially supported by the State Key Program of National Natural Science of China Grant No. 61533021 and the Foundation for Innovative Research Groups of the National Natural Science Foundation of China (Grant No.61321003).
OCIS codes: 300.6360
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