DONG Feng
School
School of Electrical and Information Engineering
Professional Title
Professor
Discipline
Control Science and Engineering
Contact Information
mtad@tju.edu.cn
School of Electrical and Information Engineering, Tianjin University. 26 Teaching Building - Area E, Weijin Road 92#, Nankai District, Tianjin, China
300072
Education Background
- Ph.D.| Tianjin University| Measurement Technology and Automatic Equipment| 2002
- M.Sc.| Tianjin University| Automatic Instrumentation and Equipment| 1996
- Second B.Sc. | Tianjin University| Education Science| 1992
- B.Sc.| Tianjin University| Industrial Automation and Instrumentation| 1988
Research Interests
- Complex Process Measuring, Modeling and Diagnosing
- Process Online Measurement and Visualization
- Biological Information Detecting, Processing and Imaging
- Industrial Automation Instrumentation and Process Control
Courses
Professional Membership
- Vice President of the International Society for Industrial Process Tomography (ISIPT)
- Regional Representative (Asia & Pacific) of the International Society for Industrial Process Tomography (ISIPT)
- IEEE Senior Member
- Committeeman of the National Technical Committee of Standardization for Industrial Process Measurement and Control (SAC/TC124), China
- Committeeman of the National Technical Committee of Standardization for Education about Standardization (SAC/SWG27), China.
- Member of the Council of Chinese Society for Measurement
- Vice President of the Multiphase Flow Measurement Committee, Chinese Society for Measurement
- Committeeman of the Multiphase Flow Measurement Committee, Chinese Society for Measurement
- Member of the Council of China Instrument and Control Society
- Member of Expert Committee, China Instrument and Control Society
- Vice President of the Energy Saving Applied Technology Committee, China Instrument and Control Society
- Member of the Energy Saving Applied Technology Committee, China Instrument and Control Society
- Counselor of the Product Information Working Committee, China Instrument and Control Society
- Vice President of the Product Information Working Committee, China Instrument and Control Society
- Committeeman of the Multiphase Flow Committee, Chinese Society of Engineering Thermophysics
- Executive Member of the Council Tianjin Automation Society
- Member of the Council Tianjin Instrument and Control Society
- Member of the Discipline Evaluation Group of Subject (Control Science and Engineering), Academic Degrees Committee of the State Council, China
- Member of the Discipline Evaluation Group (Electronic and Information Engineering), Academic Degree Committee of Tianjin Municipal Government, China
- Committeeman of the Academic Ethics Committee of Tianjin University.
- Member of Academic Committee of Tianjin University
- Committeeman of the Degree Committee of Tianjin University
- Committeeman of Degree Committee (Science and Engineering) in Tianjin University
- Member of the "Flow Measurement AND Instrumentation" Editorial Advisory Board
- Associate Editor-in-Chief of "Encyclopedia of China (Volume of Control Science and Engineering), 3th Edition", Beijing: Encyclopedia of China Publishing House
- Member of the "ACTA Automatica Sinica" Editorial Board
- Director of the "Electronic Instrumentation Customer" Editorial Board
- Vice Director of the "Electronic Instrumentation Customer" Editorial Board
Positions & Employments
-
2017.1-Now
School of Electrical and Information Engineering | Tianjin University | Professor -
2010.3-2019.12
Tianjin Key Laboratory of Process Measurement and Control | Tianjin University | Director | Professor -
2014.6-2016.12
School of Electrical Engineering and Automation | Tianjin University | Professor -
2005.7-2014.5
School of Electrical Engineering and Automation | Tianjin University | Vice Dean | Professor -
2001.7-2005.6
School of Electrical Automation and Energy Engineering | Tianjin University | Deputy Secretary | Associate Professor -
1994.7-2001.6
Department of Electrical and Automation Engineering | Tianjin University | Lecturer -
1988.7-1994.6
Department of Electrical and Automation Engineering | Tianjin University | Research Assistant
Academic Achievements
- Papers
- [1] An inclusion boundary and conductivity simultaneous estimation method for ultrasound reflection guided electrical impedance tomography, IEEE Sensors Journal, 2020(OCT), Vol.20, No.19, pp. 11578-11587. (DOI: 10.1109/JSEN.2020.2998852)
- [2] A fast inclusion boundary reconstruction framework for electrical impedance tomography with parametric snake model, IEEE Transactions on Instrumentation and Measurement, I2020(OCT), Vol.69, No.10, pp. 7606-7616. (DOI: 10.1109/TIM.2020.2983620)
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- [3] Yu Han, Tan Chao*, Dong Feng, Measurement of oil fraction in oil-water dispersed flow with swept-frequency ultrasound attenuation method, International Journal of Multiphase Flow, 2020(DEC), Vol.133, 103444. (DOI: 10.1016/j.ijmultiphaseflow.2020.103444)
- [4] Zhang Wei, Tan Chao*, Dong Feng, Wide angle ultrasonic transmission tomography by sparse pre-imaged OMP algorithm, IEEE Transactions on Instrumentation and Measurement, 2020(SEP), Vol.69, No.9, pp. 6262-6270. (DOI: 10.1109/TIM.2020.2967116)
- [5] Ren Shangjie, Sun Kai, Tan Chao, Dong Feng*, A two-stage deep learning method for robust shape reconstruction with electrical impedance tomography, IEEE Transactions on Instrumentation and Measurement, 2020(JUL), Vol.69, No.7, pp.4887-4897. (DOI: 10.1109/TIM.2019.2954722)
- [6] Liu Hao, Tan Chao*, Zhao Shu, Dong Feng, Nonlinear ultrasonic transmissive tomography for low contrast biphasic medium imaging using continuous-wave excitation, IEEE Transactions on Industrial Electronics, 2020(OCT), Vol.67, No.10, pp. 8878-8888. (DOI: 10.1109/TIE.2019.2949531)
- [7] Li Feng, Tan Chao*, Dong Feng, Jia Jiabin, V-Net deep imaging method for electrical resistance tomography, IEEE Sensors Journal, 2020(JUN), Vol.20, No.12, pp.1558-1748. (DOI: 10.1109/JSEN.2020.2973337)
- [8] Zhang Wei, Tan Chao*, Dong Feng, Dual-modality tomography by ERT and UTT projection sorting algorithm, IEEE Sensors Journal, 2020(MAY), Vol.20, No.10, pp. 5415-5423. (DOI: 10.1109/JSEN.2020.2969529)
- [9] Xu Yanbin, Zhang Shengnan, Bao Xuyang, Zheng Dongdong, Dong Feng*, Amplitude modulation method for acoustic radiation force impulse excitation, IEEE Transactions on Instrumentation and Measurement, 2020(MAY), Vol.69, No.5, pp. 2429-2438. (DOI: 10.1109/TIM.2020.2966309)
- [10] Liu Hao, Tan Chao, Ren Shangjie, Dong Feng*, Real-time reconstruction of ultrasonic tomography for two-phase flow imaging using continuous-wave excitation, IEEE Transactions on Instrumentation and Measurement, 2020(APR), Vol.69, No.4, pp. 1632-1642. (DOI: 10.1109/TIM.2019.2917736)
- [11] Liu Hao, Tan Chao, Ren Shangjie, Dong Feng*, Continuous-wave ultrasonic tomography for oil/water two-phase flow imaging using regularized weighted least square framework, Transactions of the Institute of Measurement and Control, 2020(APR), Vol.42, No.4, pp.666-679. (DOI: 10.1177/0142331219853073)
- [12] Liang Guanghui, Ren Shangjie*, Dong Feng, A Shape-based statistical inversion method for EIT/URT dual-modality imaging, IEEE Transactions on Image Processing, 2020(JAN), Vol29, No.1, pp.4099-4113. (DOI: 10.1109/TIP.2020.2969077)
- [13] Tan Chao*, Liu Shiwei, Jia Jiabin, Dong Feng, A wideband electrical impedance tomography system based on bioimpedance spectrum analysis, IEEE Transactions on Instrumentation and Measurement, 2020(JAN), Vol.69, No.1, pp. 144-154. (DOI: 10.1109/TIM.2019.2895929)
- [14] Tan Chao*, Li Xiao, Liu Hao, Dong Feng, An ultrasonic transmission/reflection tomography system for industrial multiphase flow imaging, IEEE Transactions on Industrial Electronics, 2019(DEC), Vol.66, No.12, pp. 9539-9548. (DOI: 10.1109/TIE.2019.2891455)
- [15] Liu Hao, Zhao Shu*, Tan Chao*, Dong Feng, A bilateral constrained image reconstruction method using electrical impedance tomography and ultrasonic measurement, IEEE Sensors Journal, 2019(NOV), Vol.19, No.21, pp. 9883-9895. (DOI: 10.1109/JSEN.2019.2928022)
- [16] Ren Shangjie, Sun Kai, Liu Dong*, Dong Feng*, A Statistical Shape Constrained Reconstruction Framework for Electrical Impedance Tomography, IEEE Transactions on Medical Imaging, 2019(OCT), Vol.38, No.10, pp. 2400-2410. (DOI: 10.1109/TMI.2019.2900031)
- [17] Wang Hongyi*, Dong Feng, Zhou Xinxiu, Wang Hongyu, Zhu Xinjun, Song Limei, Guo Qinhua, Fault diagnosis of reciprocating compressor using component estimating empirical mode decomposition and de-dimension template with double-loop correction algorithm, IEEE Access, 2019(JUL), Vol.7, pp.90630-90639. (DOI: 10.1109/ACCESS.2019.2925836)
- [18] Xiao Zhili, Tan Chao*, Dong Feng, Three-dimensional hemorrhage imaging by cambered magnetic induction tomography, IEEE Transactions on Instrumentation and Measurement, 2019(JUL), Vol.68, No.7, pp.2460-2468. (DOI: 10.1109/TIM.2019.2900779)
- [19] Zhang Wei, Tan Chao*, Xu Yanbin, Dong Feng, Electrical resistance tomography image reconstruction based on modified OMP algorithm, IEEE Sensors Journal, 2019(JUL), Vol.19, No.4, pp.5723-5731. (DOI: 10.1109/JSEN.2019.2906264)
- [20] Xu Yanbin, Zhang Shengnan, Wang Zheng, Dong Feng*, A fast iterative updated thresholding algorithm with sparsity constrains for electrical resistance tomography, Measurement Science and Technology, 2019(JUL), Vol.30, No.7, pp.074001(14pp.). (DOI: 10.1088/1361-6501/ab16aa)
- [21] Wang Yu, Ren Shangjie*, Dong Feng, Focusing sensor design for open electrical impedance tomography based on shape conformal transformation, Sensors, 2019(MAY), Vol.19, No.9, pp.2060(22p). (DOI: 10.3390/s19092060)
- [22] Liang Guanghui, Ren Shangjie*, Zhao Shu*, Dong Feng, A Lagrange-Newton method for EIT/UT dual-modality image reconstruction, Sensors, 2019(MAY), Vol.19, No.9, pp.1966(18p). (DOI: 10.3390/s19091966)
- [23] Tan Chao*, Shen Ying, Smith Keith, Dong Feng, Escudero Javier, Gas-liquid flow pattern analysis based on graph connectivity and graph-variate dynamic connectivity of ERT, IEEE Transactions on Instrumentation and Measurement, 2019(MAY), Vol.68, No.5, pp.1590-1601. (DOI: 10.1109/TIM.2018.2884548)
- [24] Dong Feng, Gao Huan, Liu Weiling, Tan Chao*, Horizontal oil-water two-phase dispersed flow velocity profile study by ultrasonic Doppler method, Experimental Thermal and Fluid Science, 2019(APR), Vol.102, pp. 357-367. (DOI: 10.1016/j.expthermflusci.2018.12.017)
- [25] Wang Yu, Ren Shangjie*, Dong Feng, A transformation-domain image reconstruction method for open electrical impedance tomography based on conformal mapping, IEEE Sensors Journal, 2019(MAR), Vol.19, No.5, pp.1873-1883. (DOI: 10.1109/JSEN.2018.2884760)
- [26] Ren Shangjie, Wang Yu, Liang Guanghui, Dong Feng*, A robust inclusion boundary reconstructor for electrical impedance tomography with geometric constraints, IEEE Transactions on Instrumentation and Measurement, 2019(MAR), Vol.68, No.3, pp.762-773. (DOI: 10.1109/TIM.2018.2853358)
- [27] Shi Xuewei, Tan Chao*, Dong Feng, Murai Yuichi, Oil-gas-water three-phase flow characterization and velocity measurement based on time-frequency decomposition, International Journal of Multiphase Flow, 2019(FEB), Vol.111, pp. 219-231. (DOI: 10.1016/j.ijmultiphaseflow.2018.11.006)
- [28] Tan Chao*, Lv Shuhua, Dong Feng, Takei Masahiro, Image reconstruction based on convolutional neural network for electrical resistance tomography, IEEE Sensors Journal, 2019(JAN), Vol. 19, No.1, pp.196-204. (DOI: 10.1109/JSEN.2018.2876411)
- [29] Shi Xuewei, Tan Chao*, Dong Xiaoxiao, Dong Feng, Structural velocity measurement of gas–liquid slug flow based on EMD of continuous wave ultrasonic Doppler, IEEE Transactions on Instrumentation and Measurement, 2018(NOV), Vol.67, No.11, pp. 2662-2675. (DOI: 10.1109/TIM.2018.2826858)
- [30] Zhang Shengnan, Xu Yanbin*, Dong Feng, Difference sensitivity matrix constructed for ultrasound modulated electrical resistance tomography, Measurement Science and Technology, 2018(OCT), Vol.29, No.10, pp.104005 (15pp). (DOI: 10.1088/1361-6501/aad733)
- [31] Liu Weiling, Tan Chao*, Dong Xiaoxiao, Dong Feng, Murai Yuichi, Dispersed oil-water two-phase flow measurement based on pulse-wave ultrasonic Doppler coupled with electrical sensors, IEEE Transactions on Instrumentation and Measurement, 2018(SEP), Vol.67, No.9, pp. 2129-2142. (DOI: 10.1109/TIM.2018.2814069)
- [32] Xu Yanbin, Han Bing, Dong Feng*, A new regularization algorithm based on neighborhood method for electrical impedance tomography, Measurement Science and Technology, 2018(AUG), Vol.29, No.8, pp. 085401 (13pp). (DOI: 10.1088/1361-6501/aac8b6)
- [33] Liang Guanghui, Ren Shangjie*, Dong Feng, An augmented Lagrangian trust region method for inclusion boundary reconstruction using ultrasound/electrical dual-modality tomography, Measurement Science and Technology, 2018(JUL), Vol.29, No.7, pp.074008(12pp). (DOI: 10.1088/1361-6501/aac160)
- [34] Ren Shangjie, Soleimani Manuchehr, Xu Yaoyuan, Dong Feng*, Inclusion boundary reconstruction and sensitivity analysis in Electrical Impedance Tomography, Inverse Problems in Science & Engineering, 2018(JUL), Vol.26, No.7, pp.1037-1061. (DOI: 10.1080/17415977.2017.1378195)
- [35] Wu Hao, Buschle Bill, Yang Yunjie, Tan Chao, Dong Feng, Jia Jiabin*, Lucquiaud Mathieu, Liquid distribution and fraction measurement in counter current flow packed column by electrical capacitance tomography, Chemical Engineering Journal, 2018(JUL), Vol.353, pp.519-532. (DOI: 10.1016/j.cej.2018.07.016)
- [36] Tan Chao*, Wu Yiran, Xiao Zhili, Dong Feng, Optimization of dual frequency-difference MIT sensor array based on sensitivity and resolution analysis, IEEE Access, 2018(JUN), Vol.6, pp.34911-34920. (DOI: 10.1109/ACCESS.2018.2849412)
- [37] Xiao Zhili, Tan Chao* Dong Feng, Multi-frequency dierence method for intracranial hemorrhage detection by magnetic induction tomography, Physiological Measurement, 2018(MAY), Vol.39, No.5, pp.055006(14pp). (DOI: 10.1088/1361-6579/aac09c)
- [38] Tan Chao, Dong Xiaoxiao, Dong Feng*, Continuous wave ultrasonic Doppler modeling for oil-gas-water three-phase flow velocity measurement, IEEE Sensors Journal, 2018(MAY), Vol.18, No.9, pp.3703-3713. (DOI: 10.1109/JSEN.2018.2812834)
- [39] Liu Weiling, Tan Chao*, Dong Feng, Local characteristic of horizontal air-water two-phase flow by wire-mesh sensor, Transactions of the Institute of Measurement and Control, 2018(FEB), Vol.40, No.3, pp.746-761. (DOI: 10.1177/0142331216665689)
- [40] Su Qian, Tan Chao, and Dong Feng*, Measurement of oil-water two-phase flow phase fraction with ultrasound attenuation, IEEE Sensors Journal, 2018(FEB), Vol.18, No.3, pp.1150-1159. (DOI: 10.1109/JSEN.2017.2779868)
- [41] Song Xizi, Xu Yanbin*, Dong Feng, and Witte Russell S., An instrumental electrode configuration for 3D ultrasound modulated electrical impedance tomography, IEEE Sensors Journal, 2017(DEC), Vol.17, No.24, pp.8206-8214. (DOI: 10.1109/JSEN.2017.2706758)
- [42] Ren Shangjie, Liu Hongcheng, Tan Chao*, and Dong Feng, Tomographic wire-mesh imaging based on sparse minimization, IEEE Sensors Journal, 2017(DEC), Vol.17, No.24, pp. 8187-8195. (DOI: DOI: 10.1109/JSEN.2017.2752226)
- [43] Dong Xiaoxiao, Tan Chao*, and Dong Feng, Gas-liquid two-phase flow velocity measurement with continuous wave ultrasonic Doppler and conductance sensor, IEEE Transactions on Instrumentation and Measurement, 2017(NOV), Vol.66, No.11. pp. 3064-3076. (DOI: 10.1109/TIM.2017.2717218)
- [44] Song Xizi, Qin Yexian, Xu Yanbin*, Ingram Pier, Witte Russell S., and Dong Feng, Tissue acousto-electric effect modeling from solid mechanics theory, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 2017(OCT), Vol.64, No.10, pp. 1583-1590. (DOI: 10.1109/TUFFC.2017.2724066)
- [45] Han Bing, Xu Yanbin* and Dong Feng, Design of current source for multi-frequency simultaneous electrical impedance tomography, Review of Scientific Instruments, 2017(SEP), Vol.88, No.9, pp.094709(7pp.) (DOI: 10.1063/1.5004185)
- [46] Xiao Zhili, Tan Chao*, Dong Feng, Effect of inter-tissue inductive coupling on multi-frequency imaging of intracranial hemorrhage by MIT, Measurement Science and Technology, 2017(AUG), Vol.28, No.8, pp.084001 (11pp). (DOI: 10.1088/1361-6501/aa7504)
- [47] Wang Hongyi*, Dong Feng, Song Limei, Bubble-forming regime identification based on image textural features and the MCWA feature selection method, IEEE Access, 2017(JUN), Vol.5, pp.15820-15830. (DOI: 10.1109/ACCESS.2017.2716783)
- [48] Liang Guanghui, Ren Shangjie*, Dong Feng, Ultrasound guided electrical impedance tomography for 2D free-interface reconstruction, Measurement Science and Technology, 2017(JUL), Vol.28, No.7, pp. 074003 (12pp). (DOI: 10.1088/1361-6501/aa6e23)
- [49] Song Xizi, Xu Yanbin*, Dong Feng, Linearized image reconstruction method for ultrasound modulated electrical impedance tomography based on power density distribution, Measurement Science and Technology, 2017(APR), Vol.28, No.4, pp. 045404 (14pp.). (DOI: 10.1088/1361-6501/aa5aed)
- [50] Su Qian, Tan Chao*, Dong Feng, Mechanism modeling for phase fraction measurement with ultrasound attenuation in oil-water two-phase flow, Measurement Science and Technology, 2017(FEB), Vol.28, No.3, pp. 035304 (17pp). (DOI: 10.1088/1361-6501/aa58dc)
- [51] Fu Guangzhi, Tan Chao*, Wu Hao and Dong Feng, Adaptive estimation of phase holdup of water-continuous oil-water two-phase flow, IEEE Access, 2017(FEB), Vol.5, pp. 3569-3579. (DOI: 10.1109/ACCESS.2017.2670549)
- [52] Tan Chao*, Yuan Ye, Dong Xiaoxiao and Dong Feng, Oil–water two-phase flow measurement with combined ultrasonic transducer and electrical sensors, Measurement Science and Technology, 2016(DEC), Vol.27, No.12, pp.125307 (11pp). (DOI: 10.1088/0957-0233/27/12/125307)
- [53] Song Xizi, Xu Yanbin* and Dong Feng, An image reconstruction framework based on boundary voltages for ultrasound modulated electrical impedance tomography, Measurement Science and Technology, 2016(NOV), Vol.27, No.11, pp.114003 (13pp). (DOI: 10.1088/0957-0233/27/11/114003)
- [54] Xu Yanbin*, Pei Yang and Dong Feng, An extended L-curve method for choosing a regularization parameter in electrical resistance tomography, Measurement Science and Technology, 2016(NOV), Vol.27, No.11, pp.114002(11pp.). (DOI: 10.1088/0957-0233/27/11/114002)
- [55] Xu Yanbin*, Pei Yang and Dong Feng, An adaptive Tikhonov regularization parameter choice method for electrical resistance tomography, Flow Measurement and Instrumentation, 2016(AUG), Vol.50, pp. 1-12. (DOI: 10.1016/j.flowmeasinst.2016.05.004)
- [56] Wu Hao, Tan Chao* and Dong Feng, An on-line adaptive estimation method for water holdup measurement in oil-water two-phase flow with conductance/capacitance sensor, Measurement Science and Technology, 2016(JULY), Vol.27, No.7, pp. 074001 (13pp.). (DOI: 10.1088/0957-0233/27/7/074001)
- [57] Ren Shangjie and Dong Feng*, Interface and permittivity simultaneous reconstruction in ECT based on boundary and finite elements coupling method, Philosophical Transactions A, 2016(JUNE), Vol.374, No.2070, pp. 20150333. (15pp.). (DOI: 10.1098/rsta.2015.0333)
- [58] Tan Chao, Liu Weling and Dong Feng*, Characterizing the correlations between local phase fractions of gas-liquid two-phase flow with wire-mesh sensor, Philosophical Transactions A, 2016(JUNE), Vol.374 , No.2070, pp. 20150335. (19pp.). (DOI: 10.1098/rsta.2015.0335)
- [59] Dong Xiaoxiao, Tan Chao*, Yuan Ye and Dong Feng, Measuring oil-water two-phase flow velocity with continuous wave ultrasound Doppler sensor and drift-flux model, IEEE Transactions on Instrumentation and Measurement, 2016, Vol.65, No.5, pp. 1098-1107. (DOI: 10.1109/TIM.2015.2507740)
- [60] Tan Chao, Wang Nana and Dong Feng*, Oil-water two-phase flow pattern analysis with the ERT based measurement and multivariate maximum Lyapunov exponent, Journal of Central South University, 2016, Vol.23, No.1, pp.240-248. (DOI: 10.1007/s11771-016-3067-3)
- [61] Chen Xuejun* and Dong Feng, A dual-band flame detector based on video, Optik (International Journal for Light and Electron Optics), 2016(JAN), Vol.127, No.1, pp.478-483. (DOI: 10.1016/j.ijleo.2015.09.238)
- [62] Fu Yan, Tan Chao* and Dong Feng, Analysis of response for magnetic induction tomography with internal source, Measurement, 2016(JAN), Vol.78, pp. 260-277. (DOI: 10.1016/j.measurement.2015.10.019)
- [63] Ren Shangjie, Zhao Jia and Dong Feng*, Dimensionality reduced simultaneous iterative reconstruction technique for electrical resistance tomography, Flow Measurement and Instrumentation, 2015(DEC), Vol.46(B), pp. 284-291. (DOI: 10.1016/j.flowmeasinst.2015.07.004)
- [64] Song Xizi, Xu Yanbin* and Dong Feng, A hybrid regularization method combining Tikhonov with total variation for electrical resistance tomography, Flow Measurement and Instrumentation, 2015(DEC), Vol.46(B), pp. 268-275. (DOI: 10.1016/j.flowmeasinst.2015.07.001)
- [65] Wu Hao, Tan Chao*, Dong Xiaoxiao and Dong Feng, Design of a conductance and capacitance combination sensor for water holdup measurement in oil-water two-phase flow, Flow Measurement and Instrumentation, 2015(DEC), Vol.46(B), pp. 218-229. (DOI: 10.1016/j.flowmeasinst.2015.06.026)
- [66] Song Xizi, Xu Yanbin* and Dong Feng, A spatially adaptive total variation regularization method for electrical resistance tomography, Measurement Science and Technology, 2015(DEC), Vol.26, No.12, pp. 125401 (15 pp.). (DOI: 10.1088/0957-0233/26/12/125401)
- [67] Dong Xiaoxiao, Tan Chao*, Yuan Ye and Dong Feng, Oil-water two-phase flow velocity measurement with continuous wave ultrasound Doppler and flow profile modeling, Chemical Engineering Science, 2015(OCT), Vol.135, pp.155-165. (DOI: 10.1016/j.ces.2015.05.011)
- [68] Tan Chao, Li Pengfei, Dai Wei and Dong Feng*, Characterization of oil-water two-phase ow with a combined conductance/capacitance sensor and wavelet analysis, Chemical Engineering Science, 2015(SEP), Vol.134, pp. 153–168. (DOI: 10.1016/j.ces.2015.04.046)
- [69] Tan Chao, Dai Wei, Yeung Hoi and Dong Feng*, A Kalman estimation based oil-water two-phase flow measurement with CRCC, International Journal of Multiphase Flow, 2015(JUNE), Vol.72, pp. 306–317. (DOI: 10.1016/j.ijmultiphaseflow.2014.06.014)
- [70] Tan Chao, Zhao Jia and Dong Feng*, Gas-water two-phase flow characterization with electrical resistance tomography and multivariate multiscale entropy analysis, ISA Transactions, 2015(March), Vol.55, pp.241-249. (DOI: 10.1016/j.isatra.2014.09.010)
- [71] Tan Chao, Ren Shang-Jie* and Dong Feng, Reconstruct the phase distribution within an annular channel by electrical resistance tomography, Heat Transfer Engineering, 2015(JAN), Vol.36, No.12, pp.1053-1064. (DOI: 10.1080/01457632.2015.981087)
- [72] Zhao Jia, Xu Yanbin* and Dong Feng, An Lq–Lp optimization framework for image reconstruction of electrical resistance tomography, Measurement Science and Technology, 2014(DEC), Vol.25, No.12, pp.125402 (15pp). (DOI:10.1088/0957-0233/25/12/125402)
- [73] Zhao Jia, Xu Yanbin, Tan Chao* and Dong Feng, A fast sparse reconstruction algorithm for electrical tomography, Measurement Science and Technology, 2014(AUG), Vol.25, No.8, pp.085401 (14pp). (DOI: 10.1088/0957-0233/25/8/085401)
- [74] Tan Chao, Dai Wei, Wu Hao, and Dong Feng, A conductance ring coupled cone meter for oil-water two-phase flow measurement, IEEE Sensors Journal, 2014(APR), Vol.14, No.4, pp.1244-1252. (DOI: 10.1109/JSEN.2013.2294629)
- [75] Ren Shangjie, Dong Feng, Xu Yaoyuan and Tan Chao, Reconstruction of the three-dimensional inclusion shapes using electrical capacitance tomography, Measurement Science and Technology, 2014(FEB), Vol.25, No.2, pp. 025403 (16pp). (DOI: 10.1088/0957-0233/25/2/025403)
- [76] Tan Chao, Wu Hao, Dong Feng*, Horizontal oil-water two-phase flow measurement with information fusion of conductance ring sensor and cone meter, Flow Measurement and Instrumentation, 2013(DEC), Vol.34, pp.83-90. (DOI: 10.1016/j.flowmeasinst.2013.08.006)
- [77] Ren Shangjie, Xu Yaoyuan, Tan Chao and Dong Feng*, Reconstructing the geometric configuration of three dimensional interface using electrical capacitance tomography, International Journal for Numerical Methods in Engineering, 2013(DEC), Vol.96, No.10, pp.628-644. (DOI: 10.1002/nme.4574)
- [78] Tan Chao*, Wu Hao, Dong Feng, Mass flow rate measurement of oil-water two-phase flow by a long-waist cone meter, IEEE Transactions on Instrumentation and Measurement, 2013(OCT), Vol.62, No.10, pp.2795-2804. (DOI: 10.1109/TIM.2013.2263660)
- [79] Tan Chao, Wu Hao, Wei Can, Dong Feng*, Experimental and numerical design of a long-waist cone flow meter, Sensors and Actuators A: Physical, 2013(SEP), Vol.199, pp.9-17. (DOI: 10.1016/j.sna.2013.04.039)
- [80] Fu Yan, Dong Feng*, Tan Chao, Response of Excitation Condition on Electromagnetic Tomography, Flow Measurement and Instrumentation, 2013(JUN), Vol.31, pp.10-18. (DOI: 10.1016/j.flowmeasinst.2012.10.002)
- [81] Bian Yuchen, Dong Feng*, Zhang Weida, Wang Hongyi, Tan Chao, Zhiqiang Zhang, 3D Reconstruction of Single Rising Bubble in Water Using Digital Image Processing and Characteristic Matrix, Particuology, 2013(APR), Vol.11, No.2, pp. 170-183. (DOI: 10.1016/j.partic.2012.07.005)
- [82] Cai Xiaoshu*, Huang Zhiyao, Dong Feng, Murai Yuichi, Preface, Particuology, 2013(APR), Vol.11, No.2, pp. 134. (DOI: 10.1016/j.partic.2012.12.003)
- [83] Ren Shangjie, Dong Feng* Tan Chao and Xu Yaoyuan, A boundary element approach to estimate the free-surface in stratified two-phase flow, Measurement Science and Technology, 2012(OCT), Vol.23, No.10, pp.10541(10pp). (DOI: 10.1088/0957-0233/23/10/105401)
- [84] Dong Feng*, Xu Cong, Zhang Zhiqiang, Ren Shangjie, Design of parallel electrical resistance tomography system for measuring multiphase flow, Chinese Journal of Chemical Engineering, 2012(APR), Vol.20, No. 2, pp.368-379. (DOI: 10.1016/S1004-9541(12)60400-5)
- [85] Tan Chao, Xu Yaoyuan, Dong Feng*, Determining the boundary of inclusions with known conductivities using a Levenberg–Marquardt algorithm by electrical resistance tomography, Measurement Science and Technology, 2011(OCT), Vol.22, No.10, pp. 104005 (13pp). (DOI:10.1088/0957-0233/22/10/104005)
- [86] Wang Hongyi, Dong Feng*, Bian Yuchen, Tan Chao, Improved Correlation for the Volume of Bubble Formed in Air-Water System, Chinese Journal of Chemical Engineering, 2011(JUN), Vol.19, No.3, pp529-532. (DOI: 10.1016/S1004-9541(11)60017-7)
- [87] Xu Yaoyuan, Dong Feng* Tan Chao, Electrical resistance tomography for locating inclusions using analytical boundary element integrals and their partial derivatives, Engineering Analysis with Boundary Elements, 2010(OCT), Vol.34, No.10, pp. 876-883. (DOI:10.1016/j.enganabound.2010.05.008)
- [88] Zhang Fusheng, Dong Feng*, Tan Chao, High GVF and low pressure gas-liquid two-phase flow measurement based on dual-cone flowmeter, Flow Measurement and Instrumentation, 2010(SEP), Vol.21, No.3, pp.410-417. (DOI: 10.1016/j.flowmeasinst.2010.06.004)
- [89] Xu Yaoyuan, Dong Feng* Galerkin boundary element method for the forward problem of ERT, Flow Measurement and Instrumentation, 2010(SEP), Vol.21, No.3, pp.172-177. (DOI: 10.1016/j.flowmeasinst.2009.12.004)
- [90] Xu Yanbin*, Wang Huaxiang, Cui, Ziqiang, Dong, Feng, Yan, Yong, Separation of gas-liquid two-phase flow through independent component analysis, IEEE Transactions on Instrumentation and Measurement, 2010(MAY), Vol.59, No.5(SI), pp.1294-1302. (DOI: 10.1109/TIM.2010.2044077)
- [91] Tan Chao*, Dong Feng, Modification to mass flow rate correlation in oil–water two-phase flow by a V-cone flow meter in consideration of the oil–water viscosity ratio, Measurement Science and Technology, 2010(APR), Vol.21, No.4, pp. 045403(12pp). (DOI:10.1088/0957-0233/21/4/045403)
- [92] Xu Yanbin*, Cui Ziqiang, Wang Huaxiang, Dong Feng, Chen, Xiaoyan, Yang, Wuqiang, Independent component analysis of interface fluctuation of gas/liquid two-phase flows - experimental study, Flow Measurement and Instrumentation, 2009(DEC), Vol.20, No.6, pp.220-229. (DOI:10.1016/j.flowmeasinst.2009.08.002)
- [93] Tan Chao, Dong Feng*, Wu Mengmeng, Identification of gas/liquid two-phase flow regime through ERT-based measurement and feature extraction, Flow Measurement and Instrumentation, 2007(OCT-DEC), Vol.18, No.5, pp.255-261. (DOI: 10.1016/j.flowmeasinst.2007.08.003)
- [94] Dong Feng*, Xu Yanbin, Hua Lei, Wang Huaxiang, Two methods for measurement of gas-liquid flows in vertical upward pipe using dual-plane ERT system, IEEE Transactions on Instrumentation and Measurement, 2006(OCT), Vol.55, No.5, pp.1576-1586. (DOI: 10.1109/TIM.2006.881564)
- [95] Dong Feng*, Tan Chao, Liu Junwen, Xu Yanbin, Wang Huaxiang, Development of single drive electrode electrical resistance tomography system, IEEE Transactions on Instrumentation and Measurement, 2006(AUG), Vol.55, No.4, pp.1208-1214. (DOI: 10.1109/TIM.2006.877751)
- [96] Dong Feng*, Xu Yanbin, Xu Lijun, Hua Lei, Qiao Xutong, Application of dual-plane ERT system and cross correlation technique to measure gas-liquid flows in vertical upward pipe, Flow Measurement and Instrumentation, 2005(APR-JUN), Vol.16, No.2-3, pp.191-197. (DOI:10.1016/j.flowmeasinst.2005.02.010)
- [97] Dong Feng*, Qiao Xutong, JiangZhixu and Xu Lingan, Application of electrical resistance tomography to two-phase flow and void fraction measurement, Canadian Journal of Chemical Engineering, 2005(FEB), Vol.83, No.1, pp.19-23. (DOI: 10.1002/cjce.5450830105)
- [98] Xu Lijun* Wang Ya, Dong Feng, On-line monitoring of nonaxisymmetric flow profile with a multielectrode inductance flowmeter, IEEE Transactions on Instrumentation and Measurement, 2004(AUG), Vol.53, No.4, pp.1321-1326. (DOI: 10.1109/TIM.2004.831451)
- [99] Xu Lijun*, Xu Jian, Dong Feng and Zhang Tao, On fluctuation of the dynamic differential pressure signal of venturi meter for wet gas metering, Flow Measurement and Instrumentation, 2003(AUG-OCT), Vol.14, No.4-5, pp.211-217. (DOI: 10.1016/S0955-5986(03)00027-X)
- [100] Dong Feng*, Jiang Zhixu, Qiao Xutong and Xu Lingan, Application of electrical resistance tomography to two-phase pipe flow parameters measurement, Flow Measurement and Instrumentation, 2003(AUG-OCT), Vol.14, No.4-5, pp.183-192. (DOI: 10.1016/S0955-5986(03)00024-4)
- [101] Xu Lijun*, Li Xiaomin, Dong Feng, Wang Ya and Xu Lingan, Optimum estimation of the mean flow velocity for the multi-electrode inductance flowmeter, Measurement Science and Technology, 2001(AUG), Vol12, No.8, pp.1139-1146. (DOI: 10.1088/0957-0233/12/8/321)
- [102] Deng Xiang*, Dong Feng, Xu Lijun, Liu Xiaoping, Xu Lingan, Design of a dual-plane ERT system for cross correlation measurement of bubbly gas/liquid pipe flow, Measurement Science and Technology, 2001(AUG), Vol12, No.8, pp.1024-1031. (DOI: 10.1088/0957-0233/12/8/306)
- [103] Identification of two-phase flow regimes in horizontal, inclined and vertical pipes, Measurement Science and Technology, 2001(AUG), Vol12, No.8, pp.1069-1075. (DOI: 10.1088/0957-0233/12/8/312)
- Books
- [1] Ultrasonic Measurement Technology for Multiphase Flow
- [2] Chapter 4 the New China Automation Instrumentation Discipline and Related Professional Construction, and the chief writer of Part Two: 1949 to 1978 Automation Instrumentation Related Disciplines Construction and Industrial Development, in the History of Instrument Science and Technology (Automation Instrumentation) in China
- Patents
- [1] Focusing type heart electrical impedance imaging method, CN 115736877-B
- [2] Method for detecting defect of metal pipeline based on time-frequency domain electromagnetic technique, CN 119804627-B
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- [3] Red pool information criterion transit time estimation method based on waveform similarity, CN 118981007-B
- [4] Method for identifying oil-gas-water three-phase flow pattern of horizontal pipeline based on multimode ultrasonic, CN 119757123-B
- [5] An ultrasonic imaging method for detecting droplets and bubbles in oil-gas-water three-phase medium, CN 119959343-B
- [6] Method of parallel transmitting/receiving and transit time demodulating for ultrasonic tomography, CN 116642943-B
- [7] A method for measuring the flow rate of liquid-solid two-phase flow using a combined acoustic-electric dual-mode, CN 114777864-B
- [8] A dynamic image reconstruction method for electrical tomography based on prior dimensionality reduction Kalman filtering, CN 114494477-B
- [9] A dynamic image reconstruction method for ultrasonic tomography based on Kalman filtering, CN 114494497-B
- [10] Method for evaluating health status bearing of satellite momentum wheel based on typical variable fluctuation analysis, CN 118171029-B
- [11] An amplitude extraction method for transmission attenuation ultrasonic tomography, CN 114820847-B
- [12] Method for measuring oil-water two-phase flow phase content based on nonlinear ultrasound, CN 114563470-B
- [13] Optical coherence tomography super-resolution imaging based on external attention mechanism, CN 113298710-B
- [14] Fast spatial self-adaptive deconvolution method for optical coherence tomography, CN 112927317-B
- [15] Spatial self-adaptive deconvolution method for optical coherence tomography, CN 112927316-B
- [16] A sweeping ultrasonic attenuation measurement method for dispersed phase holdup detection, CN 112129832-B
- [17] Multi-frequency ultrasonic tomography based on attenuation spectrum fusion in oil-gas-water three-phase medium CN 112067691-B
- [18] An electrical impedance image reconstruction method based on hollow convolutional network, CN 109859285-B
- [19] An electrical impedance image reconstruction method based on low-rank sparse decomposition, CN 109118554-B
- [20] A deep V-shaped dense network imaging method based on information flow and gradient flow enhancement, CN 110580727-B
- [21] An iterative method for simultaneous algebraic reconstruction of ultrasonic imaging with total variation regularization constraint, CN 109598769-B
- [22] Regularized weighted least square method for image reconstruction of transmission and reflection double mode ultrasonic tomography, CN 110706298-B
- [23] A reconstruction algorithm is used for electrical resistance tomography with contraction coefficient improved Tikhonov regularization parameter, CN 110176046-B
- [24] Ultrasonic elastography simulation method based on multi-physical field coupling, CN 110147633-B
- [25] A regularization reconstruction method based on sensitivity matrix optimization for electrical tomography, CN 110232720-B
- [26] V-net depth imaging method, CN 109712207-B
- [27] An image reconstruction method of electrical tomography based on convolutional neural network, CN 109598768-B
- [28] A regularization reconstruction method of the L1-L2space adaptive for electrical tomography, CN 109035352-B
- [29] An image reconstruction method of electrical impedance for abdominal lesions with information constraint of ultrasonic reflection, CN 109584323-B
- [30] A time delay control method of the acoustic beam deflection for ultrasonic phased array imaging in a pipeline, CN 111220709-B
- [31] A time delay control method of the acoustic beam focusing for ultrasonic phased array imaging in a pipeline, CN 111060600-B
- [32] An imaging reconstruction method for ultrasonic tomography using the non-uniform shape constrained pixel range filtering, CN 109102552-B
- [33] Multi-mode configurable broadband ultrasonic tomography system, CN 113030249-B
- [34] Method for segmenting blood vessel based on multi-view coronary angiography sequence image, CN 114862865-B
- [35] Vascular segmentation method based on self-attention mechanism and convolutional neural network hybrid model, CN 113902757-B
- [36] A method for monitoring and predicting the flow Status of the gas-liquid two-phase flow, CN 113341734-B
- [37] Gas-liquid two-phase flow state monitoring method based on the multi-modal dynamic kernel analysis, CN 113485307-B
- [38] Multi-media separation imaging method based on multi-frequency weighted frequency difference, CN 110988043-B
- [39] An IVOCT image guidewire artifact removal method based on grayscale weighting, CN 113470137-B
- [40] Gas-liquid two-phase flow state monitoring method based on the multi-sensor information core specification variable analysis, CN 113486607-B
- [41] An acoustic radiation force impulse elastography method based on displacement attenuation characteristics, CN 110927729-B
- [42] A two-stage catheter artifact removal method for intravascular optical coherence tomography, CN 113436099-B
- [43] Dual-mode tomography with electrical/ultrasonic information fusion, CN 110470743-B
- [44] n extensible multimodal tomography system based on CPCI bus, CN 109446118-B
- [45] Pulse excitation method of acoustic radiation force based on amplitude modulation, CN 110243950-B
- [46] An adaptive broadband impedance tomography method characterized by electrical spectrum, CN 108652623-B
- [47] Ultrasonic detection method of the different media interface using acoustic impedance variation information, CN 110108797-B
- [48] Ultrasonic tomography with mode fusion of transmission and reflection, CN 109884183 B
- [49] An elastic imaging method based on focusing ultrasonic acoustic signals, CN 109730722-B
- [50] An elastic characteristic detection method based on focusing ultrasonic acoustic signal, CN 109745077-B
- [51] A inclusions boundary reconstruction method of electrical/ultrasonic two-mode based on statistical inversion, CN 109946388-B
- [52] An image segmentation method for electrical impedance tomography based on minimum residual error is presented, CN 108830875-B
- [53] A reconstruction method of continuous wave ultrasound tomography using modified path tracing description, CN 110097608-B
- [54] An extensible multimodal tomography system, CN 109387605-B
- [55] A control method for multimodal tomography system, CN 109030750-B
- [56] A multiphase flow visualization measuring device using ultrasonic plane wave scanning, CN 108490068-B
- [57] Multi-frequency electromagnetic tomography method for the cerebral hemorrhage detection, CN 106725468-B
- [58] Ultrasonic transmission mode tomography based on mesh generation of propagation path, CN 108287199-B
- [59] An imaging method for biological tissue multi-characteristic based on acoustic effect and radiation force, CN 107550458-B
- [60] Ultrasonic transmission mode tomography based on mesh generation of propagation path, CN 108287199-B
- [61] A flow velocity measurement method for the oil-gas-water three phase flow by acoustic and electric dual modes, CN 109188016-B
- [62] A acoustic-electrical fusion measurement method for two-phase flow process parameters, CN 107153086-B
- [63] Multifrequency electromagnetic tomography for inhibiting mutual inductance coupling between tissues, CN 106901733-B
- [64] A two-phase flow velocity measurement method based on ultrasonic pulse Doppler and electrical multi-sensor, CN 107632167-B
- [65] A regularization reconstruction method for electrical tomography based on neighborhood variation sum, CN 107369187-B
- [66] A tomography reconstruction method using the matching tracing, CN 107133999-B
- [67] A two-phase flow pattern recognition method based on electrical resistance tomography and ultrasonic Doppler data fusion, CN 108038494-B
- [68] A super-resolution imaging method for wire mesh sensor, CN 107102031-B
- [69] A method for measuring the structural velocity of gas-liquid slug flow by acoustic and electric dual mode, CN 107389974-B
- [70] A flow velocity distribution detection equipment with ultrasonic Doppler, CN 107102166-B
- [71] Flow velocity measurement method for oil-gas-water three-phase plug type dispersed flow, CN 106996988-B
- [72] Acoustoelectric imaging method based on establishment of standard value, CN 106859600-B
- [73] A measurement method for flow velocity of the gas-liquid two-phase bubble flow using acoustic and electrical two-mode, CN 107024603-B
- [74] A measurement method for flow velocity of the gas-liquid two-phase slug and plug flow using acoustic and electrical two-mode, CN 106932606-B
- [75] An adaptive series estimation method of the water holdup in the two phase flow, CN 106872530-B
- [76] Measurement method of two-phase flow velocity using continuous wave Doppler spectrum correction, CN 106443060-B
- [77] A sparse reconstruction method of the electrical tomography based on Firm threshold iterative, CN 106530367-B
- [78] Layered interface reconstruction method based on electrical/ultrasonic double modal fusion tomography, CN 106442631-B
- [79] An adaptive estimation method of the water holdup in the oil-water two phase flow, CN 106404846-B
- [80] The phase fraction measurement method of the two phase flows using the ultrasonic echo, CN 106153149-B
- [81] The phase fraction measurement method of the oil-water two phase flows based on the ultrasonic attenuation model, CN 106226392-B
- [82] An adaptive estimation method of the water holdup in the two phase flow, CN 105842298-B
- [83] An exciting current source for bioelectrical impedance tomography, CN 105656489-B
- [84] An acoustoelectric double modal measurement method of the two phase flow velocity, CN 105181996-B
- [85] An acoustoelectric double modal measurement method of the phase velocity in two phase flow, CN 104965104-B
- [86] A phase holdup measurement method of two-phase flow using the electromagnetic eddy current sensing, CN 104820013-B
- [87] A 3D power density imaging method based on the acoustoelectric effect, CN 104644170-B
- [88] A power density imaging method based on the acoustoelectric effect, CN 104644219A-B
- [89] Building method for sensitivity matrix using the ultrasonic focusing disturbance information, CN 104614010-B
- [90] Lp regularization reconstruction method of electrical tomography based on the p vector arithmetic of equal difference decline, CN 104614411-B
- [91] Lp regularization reconstruction method of electrical tomography based on the p vector arithmetic of equal ratio contraction, CN 104634829-B
- [92] Reconstruction method of electrical tomography based on the second order differential correction L curve, CN 104535294-B
- [93] An electrical tomography reconstruction method based on curvature calculation of improved L curve, CN 104574462-B
- [94] Measurement method for multiphase flow velocity using the ultrasonic and the electrical multi-sensor cross-correlation, CN 104155471-B
- [95] Visualization method of Multiphase flow using the ultrasonic Doppler and the electrical multi-sensor, CN 104101687-B
- [96] Visualization method of multi-phase flow based on the sensitive principle of electrical and ultrasonic, CN 104089985-B
- [97] An optical fiber data transmission method based on asynchronous communication mode, CN104022828-B
- [98] Beer production automation control system based on Ethernet and CC-Link, CN 202583856-U
- [99] An internal-external composite array sensor for measuring process parameters of fluid in pipelines, CN 102495107-B
- [100] A multiphase flow measurement method based on multi cross section impedance type long waist inner cone and correlate velocity measurement, CN 102116755-B
- [101] A multiphase flow measurement method based on the multi cross section impedance double differential pressure long waist inner cone sensor, CN 102147382-B
- [102] A multiphase flow measurement method based on the double cross section impedance long waist inner cone sensor, CN 102116754-B
- [103] A multiphase flow measurement method based on the single section impedance long waist inner cone sensor, CN 102147385-B
- [104] A multi-cross section data acquisition system based on industry standard, CN 101566659-B
- [105] Measuring method of gas-liquid two-phase flow based on cross-sectional measurement, CN 100437046-C
- [106] Identification method of gas-liquid two-phase flow pattern based on electrical resistance tomography, CN1216287-C
Team
Intelligent Measurement and Visualization for Complex Processes and Its Applications
The research group for Intelligent Measurement and Visualization for Complex Processes and Its Applications was formed in the mid-1980s. It is based on the discipline of Control Science and Engineering at Tianjin University, the interdiscipline of Low-altitude Technology and Engineering, the national Key discipline of Measurement Technology and Automatic Equipment, and the Tianjin Key Laboratory of Process Measurement and Control. Based on the team, the International Joint Research Center for Process Imaging and Measuring in Tianjin has been established. Currently, the research group has 3 professors, 6 associate professors (associate research fellow), the more trhen 10 doctoral students, and over 40 master's students.
The research team focuses on processes with typical complexity characteristics in nature, society's production, and daily life. Its goal is to solve key bottleneck technologies in practical engineering. It is based on exploratory frontier innovation research supported by National Natural Science Foundation of China, National Science and Technology Research, and also relies on technological innovation and application promotion carried out through cooperation with enterprises and institutions. The team is committed to achieving breakthroughs in innovative research at the scientific frontier and implementing practical engineering solutions.
The research team has ensured the cutting-edge nature, advancement and practicality of scientific research by conducting extensive exchanges and in-depth cooperation with top research institutions, universities and leading enterprises both domestically and internationally.
The research team focuses on processes with typical complexity characteristics in nature, society's production, and daily life. Its goal is to solve key bottleneck technologies in practical engineering. It is based on exploratory frontier innovation research supported by National Natural Science Foundation of China, National Science and Technology Research, and also relies on technological innovation and application promotion carried out through cooperation with enterprises and institutions. The team is committed to achieving breakthroughs in innovative research at the scientific frontier and implementing practical engineering solutions.
The research team has ensured the cutting-edge nature, advancement and practicality of scientific research by conducting extensive exchanges and in-depth cooperation with top research institutions, universities and leading enterprises both domestically and internationally.
- Honors & Awards
- [1] 12/2024: Top-ten Faculty Award in School of Electrical and Information Engineering, Tianjin University
- [2] 08/2023: Outstanding Editorial Board Member of Acta Automatica Sinica.
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- [3] 01/2023: Excellent Editorial Board Member of Acta Automatica Sinica in 2022
- [4] 10/2022: Second-Class Prize for Scientific and Technological Progress
- [5] 08/2022: Supervisor of the Excellent Doctoral Dissertation of Tianjin University
- [6] 07/2021: Supervisor of the Excellent Doctoral Dissertation of Tianjin University
- [7] 2021 to Now: Top 2% of global scientists in the lifetime scientific influence ranking
- [8] 2020 to Now: Top 2% of global scientists in the annual scientific influence ranking
- [9] 06/2020: Top 70 Most Published Author of IEEE Transactions on Instrumentation and Measurement in the Past 7 Year
- [10] 12/2019: Excellent Advisor for Engineering Degrees of Tianjin
- [11] 12/2019: Excellent Teaching Achievement First-Class Award
- [12] 10/2019: Supervisor of the National Excellent Doctoral Dissertation in Measurement Control and Instrumentation of the China Instrument and Control Society
- [13] 11/2015: Supervisor of the Excellent Doctoral Dissertation of Tianjin University
- [14] 06/2015: Supervisor of the Excellent Master Dissertation in Tianjin
- [15] 03/2013: Supervisor of the Excellent Doctoral Dissertation in Tianjin
- [16] 12/2012: Advanced Teacher and Staff in Education
- [17] 09/2011: Supervisor of the Excellent Doctoral Dissertation of Tianjin University
- [18] 01/2010: Third-Class Prize for Natural Science of Tianjin
- [19] 02/2007: New Century Excellent Talents in University
- [20] 11/2003: Innovation Prize for Scientific and Technological Progress of China Instrument and Control Society
- [21] 11/2001: Second-Class Prize for Natural Science of Tianjin
- [22] 05/1995: Top-Ten Pioneer Young Award of Tianjin University
- Research Projects
- [1] National Science Foundation of China, Flow state analysis and on-line monitoring of oil-gas-water multiphase flow with multi-source information fusion (No. 51976137), 01/2020-12/2023. (Principal Investigator)
- [2] Natural Science Foundation of Tianjin, China (Key Projects), Visual monitoring of process state in oil-gas-water multiphase flow by multi-source information fusion (No. 19JCZDJC38900), 04/2019-03/2022. (Principal Investigator)
-
- [3] SMC Corporation of Japan, Pneumatic test method and control technology, 04/2018-03/2020. (Principal Investigator)
- [4] SMC Corporation of Japan (Beijing SMC Education Foundation), Financial Aids to Students, 11/2018-11/2020. (Coordinator)
- [5] Science and Technology Innovation Plan of Tianjin, China, Construction of new test instrument development and experimental test platform, (No.16PTSYJC00060), 10/2016-09/2018. (Principal Investigator)
- [6] National Science Foundation of China, Electrical/ultrasonic dual modality tomography fusion mechanism and method (No. 61571321), 01/2016–12/2019,. (Principal Investigator)
- [7] SMC Corporation of Japan, Pneumatic test method and control technology, 04/2015-03/2018. (Principal Investigator)
- [8] SMC Corporation of Japan (Donation Project), Construction of pneumatic measurement and control laboratory, 04/2015-03/2018. (Coordinator)
- [9] SMC Corporation of Japan (Beijing SMC Education Foundation), Financial Aids to Students, 11/2014-11/2017. (Coordinator)
- [10] Science and Technology Innovation Plan of Tianjin, China, Construction of complex flow and multimodality test experimental platform (No.13TXSYJC40200), 10/2013-03/2016. (Principal Investigator)
- [11] National Science Foundation of China (Scientific Instruments Basic Research Special), Oil-gas-water multiphase flow process parameters visualization measurement and test instrumentation (No. 61227006), 01/2013–12/2016. (Principal Investigator)
- [12] Baicheng Tianqi Equipment & Machinery Co., Ltd., Crosslinking cable production line intelligent control system, 01/2012–12/2014. (Principal Investigator)
- [13] Special-Funded Programme on National Key Scientific Instruments and Equipment Development of China, Undersea high efficiency oil-gas-water separator and metering mechanism(SSM) (No. 2011YQ120048); Task No.1: Multiphase flow visualization and parameters measurement system (No. 2011YQ12004801); 10/2011–10/2017. (Principal Investigator)
- [14] National Science Foundation of China, Methods of multiphase flow measurement based on coupled multi-sensitive field (No. 51176141), 01/2012–12/2015. (Principal Investigator)
- [15] Natural Science Foundation of Tianjin, China (Key Projects), Mechanisms, models and system optimization of multiphase flow measurement based on coupled multi-sensitive field (No. 11JCZDJC22500), 04/2011–03/2014. (Principal Investigator)
- [16] Chinese Academy of Medical Sciences & Peking Union Medical College Institute of Biomedical Engineering, EIT system all-digital processing and testing, 10/2009-09/2010. (Principal Investigator)
- [17] Chinese Academy of Medical Sciences & Peking Union Medical College Institute of Biomedical Engineering, Test and improve of EIT system, 12/2008-12/2009. (Principal Investigator)
- [18] Chinese Academy of Medical Sciences & Peking Union Medical College Institute of Biomedical Engineering, Electrical impedance tomography system for early diagnosis of breast cancer, 04/2008-12/2009. (Principal Investigator)
- [19] Natural Science Foundation of Tianjin, China (Key Projects), Measurement of oil/gas/water multi-phase flow based on multi-sensors fusion (No. 08JCZDJC17700), 04/2008–09/2010. (Principal Investigator)
- [20] National Science Foundation of China, Flow behaviors of oil/gas /water three-phase flow based on multiple source measured information fusion (No. 50776063), 01/2008–12/2010. (Principal Investigator)
- [21] Tianjin Pulait Technology Development Co., LTD (Patent Transfer), Identification method of gas-liquid two-phase flow pattern based on electrical resistance tomography, 11/2008. (Principal Investigator)
- [22] SMC Corporation of Japan, Development and test of pneumatic operated device and instrumentation, 04/2007-03/2015. (Principal Investigator)
- [23] The National High Technology Research and Development Program of China (863 Program), Measurement of oil/gas/water three-phase flow based on multi-sensor data fusion (No. 2006AA04Z167), 12/2006-12/2008. (Principal Investigator)
- [24] Program for New Century Excellent Talents in University (NCET), Ministry of Education of the People´s Republic of China, Flow mechanism of multi-phase flow based on cross section measurement (No.NCET-06-0230), 01/2006-12/2008. (Principal Investigator)
- [25] Natural Science Foundation of Tianjin, China, Two-phase flow measurement based on multi-sensor data fusion (No. 05YFJMJC11600), 04/2005-12/2007. (Principal Investigator)
- [26] Tianjin Henry Control System Company, Development of control system of auto parts production line, 09/2003-12/2005. (Principal Investigator)
- [27] National Science Foundation of China, New method for the measurement of two-phase pipe flow (No. 50276043), 01/2003-12/2005. (Principal Investigator)
- [28] Wuhan Petrochemical Industry Company of China, Control system for gasoline tank area, 07/2003-12/2003. (Principal Investigator)
- [29] Daqing Oil Company of China, A set of gas/liquid two-phase flow measurement installation, 01/2002-12/2004. (Principal Investigator)
- [30] Wuhan Petrochemical Industry Company of China, Monitoring and alarming system for flammable gas, 07/2002-12/2002. (Principal Investigator)
- [31] Daqing Oil Company of China, Signal collecting and processing system for resistance water cut meter and cross-correlation flowmeter, 01/1998-06/2001. (Principal Investigator)
- [32] Shenyang institute of computer technology, Chinese academy of sciences, Simulation graph plotter of the tape and thermal film using computer, 01/1998-12/2000. (Principal Investigator)
- [33] Wuhan Petrochemical Industry Company of China, Monitoring and detecting system for gasoline tank area, 09/1997-12/1999. (Principal Investigator)
- [34] Tianjin Gas Supply Company of China, Pulsatile gas flow measurement for the gas metering station, 05/1997-05/1998. (Principal Investigator)
- [35] Tianjin Gas Company of China, Pulsatile flow influence on orifice flowmeters in gas delivery line, 01/1995-10/1996. (Principal Investigator)
- Teacher Blog