Application of hilbert-huang transform to denoising in vortex flowmeter

Zhi-qiang Sun; Jie-min Zhou; Ping Zhou

doi:10.1007/s11771-006-0076-7

Journal of Central South University ›› 2006, Vol. 13 ›› Issue (5) : 501 -505. DOI: 10.1007/s11771-006-0076-7

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Application of hilbert-huang transform to denoising in vortex flowmeter

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Abstract

Due to piping vibration, fluid pulsation and other environmental disturbances, variations of amplitude and frequency to the raw signals of vortex flowmeter are imposed. It is difficult to extract vortex frequencies which indicate volumetric flowrate from noisy data, especially at low flowrates. Hilbert-Huang transform was adopted to estimate vortex frequency. The noisy raw signal was decomposed into different intrinsic modes by empirical mode decomposition, the time-frequency characteristics of each mode were analyzed, and the vortex frequency was obtained by calculating partial mode’s instantaneous frequency. Experimental results show that the proposed method can estimate the vortex frequency with less than 2% relative error; and in the low flowrate range studied, the denoising ability of Hilbert-Huang transform is markedly better than Fourier based algorithms. These findings reveal that this method is accurate for vortex signal processing and at the same time has strong anti-disturbance ability.

Keywords

flow measurement / vortex flowmeter / denoising / Hilbert-Huang transform / signal processing

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Zhi-qiang Sun, Jie-min Zhou, Ping Zhou. Application of hilbert-huang transform to denoising in vortex flowmeter. Journal of Central South University, 2006, 13(5): 501-505 DOI:10.1007/s11771-006-0076-7

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	BogueR W. The confusing world of flow sensing[J]. Sensor Review, 2005, 25(1): 5-5

[2]	YoderJ. Flowmeters and their apps: an overview[J]. Sensors, 2003, 20(10): 23-29

[3]	PankaninG L. The vortex flowmeter: various methods of investigating phenomena[J]. Measurement Science and Technology, 2005, 16(3): R1-R16

[4]	ZhangTao, SunHong-jun, WuPeng. Wavelet denoising applied to vortex flowmeters [J]. Flow Measurement and Instrumentation, 2004, 15(5–6): 325-329

[5]	SunHong-jun, ZhangTao, WangHua-xiangAdamsJ. Wavelet denosing method used in the vortex flowmeter [C]. Proceedings of 2nd International Conference on Machine Learning and Cybernetics, 2003, Los Angeles, Institute of Electrical and Electronic Engineers Inc: 1109-1112

[6]	SunHong-jun, ZhangTaoAdamsJ. Digital signal processing based on wavelet and statistics method for vortex flowmeters[C]. Proceedings of 3rd International Conference on Machine Learning and Cybernetics, 2004, Los Angeles, Institute of Electrical and Electronics Engineers Inc: 3160-3163

[7]	PengJie-gang, FuXin, ChenYing. Flow measurement of by a new type vortex flowmeter of dual triangulate bluff body [J]. Sensors and Actuators A: Physical, 2004, 115(1): 53-59

[8]	JanY, SheuT W. A numerical confirmation of the dual body vortex flowmeter design[J]. Computers and Fluids, 2004, 33(9): 1157-1174

[9]	BeraS C, RayJ K, ChattopadhyayS. A modified inductive pick-up type technique of measurement in a vortex flowmeter[J]. Measurement, 2004, 35(1): 19-24

[10]	ClarkeD W. Designing phase-locked loops for instrumentation applications[J]. Measurement, 2002, 32(3): 205-227

[11]	GhaoudT, ClarkeD W. Modelling and tracking a vortex flow-meter signal[J]. Flow Measurement and Instrumentation, 2002, 13(3): 103-117

[12]	SunZhi-qiang, ZhangHong-jian, HuangYong-mei. Research on detection of vortex flowmeter signal with differential pressure[J]. Chinese Journal of Sensors and Actuators, 2004, 17(3): 420-423(in Chinese)

[13]	HuangYong-mei, ZhangHong-jian, SunZhi-qiangZhaoXiao-na. A study of differential pressure measurement in vortex flowmeter[C]. Proceedings of FLOMEKO 2004, 2004, Beijing, China Standard Press: 367-371

[14]	RossbergA G, RieglerP, BuhlF, et al.. Detection of improper installation from the sensor signal of vortex flowmeters[J]. Flow Measurement and Instrumentation, 2004, 15(1): 29-35

[15]	HuangN E, ShenZ, LongS R, et al.. The empirical mode decomposition and the Hilbert spectrum for nonlinear and non-stationary time series analysis[J]. Proceedings of the Royal Society of London, 1998, 454: 903-995

[16]	ZhangR R, VanD L, LiangJ W. On estimating site damping with soil non-linearity from earthquake recordings[J]. International Journal of Non-linear Mechanics, 2004, 39(9): 1501-1517

[17]	HwangP A, HuangN E, WangD W. A note analysing nonlinear and nonstationary ocean wave data[J]. Applied Ocean Research, 2003, 25(4): 187-193

[18]	PengZ K, TseP W, ChuF L. A comparison study of improved Hilbert-Huang transform and wavelet transform: application to fault diagnosis for rolling bearing[J]. Mechanical Systems and Signal Processing, 2004, 18(1): 1-15

[19]	PanJ Y, YanX H, ZhengQ N. Interpretation of scatterometer ocean surface wind vector EOFs over the Northwestern Pacific[J]. Remote Sensing of Environment, 2003, 84(1): 53-68

[20]	MontesinosaM E. Hilbert-Huang analysis of BWR neutron detector signals: application to DR calculation and to corrupted signal analysis[J]. Annals of Nuclear Energy, 2003, 30(6): 715-727

[21]	LeiskG G, HsuN N, HuangN EThompsonD O. Application of the Hilbert-Huang Transform to machine tool condition/health monitoring[C]. Proceedings of AIP Conference, 2002, Changsha, American Institute of Physics: 1711-1718