代表性论文专著
[1] Hong Gao, et al. Capture mechanism of a multi-dimensional wave energy converter with a strong coupling parallel drive. Applied Energy, 2024, 361: 122828.
[2] L. M. Yang, et al. Design and control of a novel six-legged skating robot with skateboards. IEEE/ASME Transactions on Mechatronics, 2024, 29 (4): 2590-2601.
[3] L. M. Yang, et al. Obstacle avoidance strategy for a novel skiing robot in unknown snow environments. IEEE Robotics and Automation Letters. 2024, 9 (4): 3203-3210.
[4] Y. Wang,et al. Robust Kalman Filter Based Path-Tracking Control with Prescribed Performance for Autonomous Ground Vehicles under FDI Attack. 2024 IEEE International Conference on Systems, Man, and Cybernetics (IEEE SMC 2024), 2024, 10, 6-10, Sarawak, Malaysia.
[5] C. Hu, et al. Optimal Adaptive Cruise Control in Mixed Traffic with Communication Latence and Driver Reaction, IEEE Transactions on Intelligent Transportation Systems, 2024, 25(11): 18636-18647.
[6] L. M. Yang et.al. Design and control of a novel six-legged robot for flat, downhill, and uphill skiing. International Conference on Intelligent Robotics and Applications, 2023, 7, 5-7, Hangzhou.
[7] Hong Gao, Jie Xiao. Effects of power take-off parameters and harvester shape on wave energy extraction and output of a hydraulic conversion system. Applied Energy,2021,299:117278.
[8] 高红,肖杰等 液压系统参数和浮体形状对波浪能捕获的影响. 第十二届全国流体传动及控制学术会议, 厦门, 2023, 4.8-4.9.
[9] 高红,肖杰. 波浪能捕获浮体对能量转化系统特性的影响, 机械工程学报, 2022, 58(16):360-369.
[10] 高红,肖杰. 基于模糊 PI 的波浪能液压转化系统平稳控制研究,机械工程学报, 2021, 57(10): 267-276.
[11] 高红,梁睿智. 波浪能捕获液压系统的特性研究, 机械工程学报, 2020, 56(18): 180-187.
[12] Hong Gao, Jie Xiao. Effect of Accumulator on Dynamic Performance of a Hydraulic Wave Energy Conversion System, The 10th International Conference on Fluid Power Transmission and Control (ICFP 2021), 11-13, April, Hangzhou, 2021,148-152.
[13] 高红,肖杰,梁睿智. 浮体参数对波浪能液压转化系统动态特性的影响. 第十一届全国流体传动及控制学术会议, 上海, 2020, 10.31-11.2
[14] Hong Gao Ruizhi Liang. Performance analysis of axisymmetric floating energy harvesters and influences of parameters and shape variation. International Journal of Energy Research, 2019, 43(6):2057-2074.(Cover Paper)
[15] Hong Gao Ruizhi Liang. Performance investigation of a hydraulic power take-off system for wave energy conversion. 2019 IEEE 8th International Conference on Fluid Power and Mechatronics, April 10-13, 2019, Wuhan, FPM2019-094.
[16] Hong Gao, Ruizhi Liang. Hydraulic system characteristic and motor performance in a wave energy conversion system. July 20-21, 2019, Beijing, RMTC 2019.( Awarded Best Paper)
[17] 高红,梁睿智,築地徹浩. 波浪能转化液压系统动态特性及能量转化的研究. 液压与气动, 2019, (6):1-4.
[18] Hong Gao Yang Yu. The dynamics and power absorption of cone-cylinder wave energy converters with three degree of freedom in irregular waves, Energy, 2018,143: 833-845. (SCI 收录, WOS:000425565700069)
[19] Gao Hong, Ruizhi Liang, Tetsuhiro Tsukiji . Investigation of dynamic characteristics and wave energy conversion of a hydraulic system. 10thFPTC, 2018.7.23,Beijing.
[20] Hong Gao, Zhiheng Wang. Hydrodynamic response analysis and wave energy absorption of wave energy converters in regular waves. Marine Technology Society Journal, 2017, 51(1):64-74.(SCI 收录, WOS:000396298100008)
[21] Hong Gao,Feng Gao.Non-dimensional analysis of the transient flow rate and the coolant temperature in a reactor coolant system under different pump failures. Journal of Nuclear Science and Technology, 2016, 53(12):1988-1998. (SCI 收录, WOS:000386383300009)
[22]Gao Hong,Yu Yang,et al. Hydrodynamic analysis of a halfsphere-cylinder wave energy converter,The 9th International Conference on Fluid Power Transmission and Control (ICFP2017),2017,4,11-13,Hangzhou.
[23] Gao Hong, Gao Feng. Hydrodynamic Characteristics of a Floating Cylinder and the Power Capture Of Wave Energy. 9th FPTC-2016, 11.17-18, Hangzhou.
[24] Hong Gao, Feng Gao, Xianchao ZHAO, Jie CHEN, Xuewu CAO,Analysis of reactor coolant pump transient performance in primary coolant system during start-up period.Annals of Nuclear Energy,2013,54:202–208.(SCI收录,WOS:000315612400026)
[25] Hong Gao, Feng Gao, Xianchao Zhao, Jie Chen, Xuewu Cao. Flow transient in primary coolant system during reactor coolant pump start-up period. Proceedings of the ASME 2013 Fluids Engineering Summer Meeting, 2013, July, Nevada, USA, FEDSM2013-16580. (EI: 20140517253419, CPCI-S 收录: 000359030900066)
[26] Hong Gao, Feng Gao, Xianchao ZHAO, Jie CHEN, Xuewu CAO, Transient Flow Analysis in Reactor Coolant Pump Systems during Flow Coastdown Period. Nuclear engineering and design 2011, 241(2): 509-514.(SCI收录,WOS: 000287438900009 )
[27] GAO Hong, GAO Feng, CHEN Jie, CAO Xue-wu,Investigation of Flywheel Response during Flow Coastdown in Reactor Coolant System,2010 International conference on mechanism and machine science,Shanghai, 2010,July 21-25, 135-137.
[28]Hong Gao, Wanlai Lin, Zhaohui Du, Numerical Flow and Performance Analysis of a Water-Jet Axial Flow Pump, Ocean Engineering, Vol.35, No.16, 2008: 1604-1614.(SCI收录,WOS:000261293900005)
[29]H. Gao, W. L. Lin, Z. H. Du, An Investigation of the Flow and Overall Performance in a Water-Jet Axial Flow Pump based on CFD and Inverse Design Method, Proceedings of the Institution of Mechanical Engineers, Part a, Journal of Power and Energy, Vol. 222, No.5, 2008: 517-527.(SCI收录,WOS:000258584700008)
[30]Hong Gao, Wanlai Lin, Tetsuhiro Tsukiji. Investigation of Cavitation near the Orifice of Hydraulic Valves, Proceedings of the Institution of Mechanical Engineers, Part G, Journal of Aerospace Engineering, Vol. 220, No.4, 2006: 253-265.(SCI收录,WOS:000239834200002)
[31]Gao Hong, Lin Wanlai, Fu Xin, Yang Huayong, Tsukiji Tetsuhiro, Suppression of a Cavitation near the Orifice of a Relief Valve, Chinese Journal of Mechanical Engineering (English Edition), Vol. 18, No.1, 2005: 149-155.(EI: 05199092669)
[32]Hong Gao, Wanlai Lin, Fangming Ye, An Investigation of the Flow and Global Performance in a Water-Jet Axial Flow Pump Based on CFD and Inverse Design Method, Proceedings of ASME Fluids Engineering Division Summer Conference, 2005 Symposia, FEDSM2005, v 1 PART B, 2005: 1193-1201.(EI: 05519594278,CPCI-S收录,WOS:000242485100129)
[33]Hong Gao, Wanlai Lin, Fangming Ye, CFD Investigation of Global Performance and Three Dimensional Flows in a Water-Jet Axial Flow Pump, Proceedings of ASME Fluids Engineering Division Summer Conference, 2005 Symposia, FEDSM2005, v 1 PART B, 2005: 1573-1581. (EI: 06219888512,CPCI-S收录,WOS:000242485100172)
[34]GAO Hong, FU Xin, YANG Hua-yong, Tetsuhiro TSUKIJI, Numerical Investigation of Cavitating Flow Behind the Cone of a Poppet Valve in Water Hydraulic Systerm, Journal of Zhejiang University SCIENCE, Vol.3, No.4, 2002: 395-400.(EI: 02487244417)
[35]GAO Hong, FU Xin, YANG Hua-yong, Tetsuhiro TSUKIJI. Numerical and Experimental Investigation of Cavitating Flow within Hydraulic Poppet Valve, Jixie Gongcheng Xuebao/Chinese Journal of Mechanical Engineering, Vol.38, No.8, 2002 27-30.(EI: 03097381737)
[36]Hong GAO, Xin FU, Huayong YANG and Tetsuhiro TSUKIJI, Numerical and Experimental Investigation of Cavitating Flow Within Hydraulic Poppet Valve. 3rd International Fluid Power Conference proceedings, Aachen, Germany, March 5-6, 2002: 331-339.
[37]Hong GAO, Xin FU, Huayong YANG and Tetsuhiro TSUKIJI,Numerical and Experimental of Investigation of Cavitating Flow in Oil Hydraulic Ball Valve. The Fifth JFPS International Symposium on Fluid Power, Nara, Japan, November 12-15, 2002: 923-928.
[38]Gao Hong, Fu Xin, Yang Huayong, Tetsuhiro Tsukiji, Flow Visualization and Noise Measurement in Hydraulic Relief Valve. The Fourth International Symposium on Fluid Power Transmission and Control, April 8-10, 2003, Wuhan, China, 574-577.
[39]Gao Hong, Fu Xin, Yang Huayong. Numerical Simulation of Cavitating Flow in Hydraulic Conical Valve. Proceedings of the fifth international conference on fluid Power Transmission and Control (ICFP-2001), Hangzhou, China, April 3-4, 2001: 485- 488.(CPCI-S:000176367500105)
[40] Tetsuhiro Tsukiji, Yohei Yamamoto, Hong Gao. Flow analysis inside the suction chamber of a compressor for automotive air-conditioner. The Fourth International Symposium on Fluid Power Transmission and Control,April 8-10, 2003, Wuhan, China, 554-559.
[41] 高红,傅新,杨华勇,築地徹浩.锥阀阀口气穴流场的数值模拟与试验研究.机械工程学报,2002,38(8):27-30.(EI: 03097381737)
[42] 高红,傅新,杨华勇,築地徹浩.球阀阀口气穴流场的模拟与可视化研究.农业机械学报,2003,34(3):45-48.(EI 03297554290)
[43] 高红,傅新,杨华勇,築地徹浩. 球阀阀口气穴流场的数值模拟与实验研究.中国机械工程,2003,14(4):338-340.
[44] 高红,傅新,築地徹浩.平衡阀内气穴现象的研究.液压与气动,2002,7:22-23.
[45] 高红,傅新,杨华勇,築地徹浩.球阀阀口气穴现象的研究.第5届海内外青年设计与制造科学会议,2002,7月10-12日,大连,520-522.
[46] 高红,叶方明,林万来.喷水推进泵的CFD研究.中国科协第五届青年学术年会文集,北京:中国科学技术出版社,主编:张玉台,2004,8-¬9.
[47] 叶方明,高红,林万来.后置导叶型喷水推进泵总特性及三维流场.上海交通大学学报,2005,39(9):1409-¬1412.(EI 05459460180)
[48] 黄欢明,高红,杜朝辉.轴流泵出口流场的实验研究与数值模拟.水泵技术,2008, (2): 6-8,31.
[49] 黄欢明,高红,沈枫,杜朝辉.轴流泵内流场的数值模拟与实验.农业机械学报,2008,39(8):66-69,148.(EI: 20083711541007)
[50] 黄欢明,高红,杜朝辉.轴流泵叶轮内部流动数值模拟与实验.上海交通大学学报,2009,43(1):124-128.