1998.09-2002.12清華大學(xué)精密儀器與機(jī)械學(xué)系(碩博)博士
1998.09-2002.12清華大學(xué)精密儀器與機(jī)械學(xué)系(碩博)碩士
1993.09-1998.07清華大學(xué)精密儀器與機(jī)械學(xué)系學(xué)士

2019.07 - 2021.09 上海交通大學(xué)機(jī)械與動(dòng)力工程學(xué)院，院長(zhǎng)
2017.06 - 2019.07 上海交通大學(xué)機(jī)械與動(dòng)力工程學(xué)院，常務(wù)副院長(zhǎng)
2015.01 - 2017.06 上海交通大學(xué)致遠(yuǎn)工科榮譽(yù)計(jì)劃，項(xiàng)目主任
2015.01 - 2017.06 上海交通大學(xué)學(xué)生處副處長(zhǎng)
2013.01 - 機(jī)械系統(tǒng)與振動(dòng)國(guó)家重點(diǎn)實(shí)驗(yàn)室，副主任
2012.01 - 上海交通大學(xué)機(jī)械與動(dòng)力工程學(xué)院，特聘教授
2009.03 - 2011.12 上海交通大學(xué)機(jī)械與動(dòng)力工程學(xué)院，特別研究員
2008.07 - 2009.02 英國(guó)Sheffield大學(xué)自動(dòng)控制系，Research Fellow
2007.10 - 2008.06 英國(guó)Loughborough大學(xué)機(jī)械電子研究中心，Research Fellow
2005.04 - 2007.09 英國(guó)Sheffield大學(xué)自動(dòng)控制系，Research Fellow
2004.06 - 2005.04 英國(guó)Cranfield大學(xué)過(guò)程與系統(tǒng)工程系，Research Fellow
2003.03 - 2004.03 香港城市大學(xué)工業(yè)工程系，Research Associate

1) 信號(hào)分析與智能運(yùn)維
2) 振動(dòng)分析與控制
3) 微波感知技術(shù)
4) 海上浮式風(fēng)力發(fā)電
5) 超材料設(shè)計(jì)與動(dòng)力學(xué)

畢業(yè)博士生：
1) 楊 揚(yáng), 2010 - 2013, 牛津大學(xué)
2) 程長(zhǎng)明，2012 - 2015， 上海交通大學(xué)
3) 李星占，2012 - 2016， 中國(guó)工程物理研究院
4) 王新寬，2014 - 2017， 中國(guó)工程物理研究院
5) 張明威, 2013 - 2017, 百度 (上海)
6) 熊玉勇, 2015 - 2018, 上海交通大學(xué)
7) 陳是扦, 2014 - 2019, 西南交通大學(xué)
8) 溫斌榮，2015 - 2020， 上海交通大學(xué)
9) 衛(wèi)一民, 2013 - 2019,
10) 蘭錦春，2012 - 2020
11) 李占偉，2018 - 2021, 南京航空航天大學(xué)

博士后
1）楊 揚(yáng) - 牛津大學(xué)工作
2) 程長(zhǎng)明 - 上海交通大學(xué)副教授
3) 魏 莎 - 上海大學(xué)副教授
4）胡松濤- 上海交通大學(xué)副教授
5) 王增偉
6) 熊玉勇- 上海交通大學(xué)副教授

1) 機(jī)械系統(tǒng)與振動(dòng)國(guó)家重點(diǎn)實(shí)驗(yàn)室副主任
2) 上海市閔行區(qū)第六屆人大代表 (2017-2021)
3) 上海市青年科技人才協(xié)會(huì)副會(huì)長(zhǎng)(發(fā)起人之一)
4) 全國(guó)科技創(chuàng)新領(lǐng)軍人才聯(lián)盟理事
5) 中國(guó)振動(dòng)工程學(xué)會(huì)理事
6) 上海力學(xué)學(xué)會(huì)理事
7) 上海力學(xué)學(xué)會(huì)動(dòng)力學(xué)與控制專(zhuān)委會(huì)主任委員
8) 中國(guó)力學(xué)學(xué)會(huì)動(dòng)力學(xué)與控制專(zhuān)業(yè)委員會(huì)委員
9) 中國(guó)振動(dòng)工程學(xué)會(huì)非線性振動(dòng)專(zhuān)業(yè)委員會(huì)副主任委員
10) 中國(guó)振動(dòng)工程學(xué)會(huì)設(shè)備故障診斷專(zhuān)業(yè)委員會(huì)副理事長(zhǎng)
11) 中國(guó)振動(dòng)工程學(xué)會(huì)學(xué)術(shù)工作委員會(huì)委員
12) 中國(guó)振動(dòng)工程學(xué)會(huì)科技咨詢工作委員會(huì)委員
13) 《Frontiers of Mechanical Engineering 》編委
14) 《Chinese Journal of Mechanical Engineering》編委
15) 《計(jì)算力學(xué)學(xué)報(bào)》編委
16) 《噪聲與振動(dòng)控制》編委
17) 《振動(dòng)與沖擊》編委
18) 《動(dòng)力學(xué)與控制學(xué)報(bào)》編委
19) 天津市非線性動(dòng)力學(xué)與控制重點(diǎn)實(shí)驗(yàn)室學(xué)術(shù)委員會(huì)委員
20) 上海市能源工程力學(xué)重點(diǎn)實(shí)驗(yàn)室學(xué)術(shù)委員會(huì)委員
21) 華東交通大學(xué)載運(yùn)工具與裝備教育部重點(diǎn)實(shí)驗(yàn)室學(xué)術(shù)委員會(huì)委員
22) 湖南科技大學(xué)機(jī)械設(shè)備健康維護(hù)湖南省重點(diǎn)實(shí)驗(yàn)室學(xué)術(shù)委員會(huì)主任委員

19) 科技部重大專(zhuān)項(xiàng)子課題，核電廠關(guān)鍵設(shè)備和管道振動(dòng)控制設(shè)計(jì)技術(shù)研究，2019.01-2020.12
18) 企業(yè)委托，螺旋盤(pán)管在鉛錨流體作用下的流致振動(dòng)機(jī)理研究，2020.01-2021.08
17) 企業(yè)委托，典型核島主設(shè)備故障診斷及健康管理系統(tǒng)軟件開(kāi)發(fā)，2020.03-2020.12
16) 企業(yè)委托，發(fā)電機(jī)遠(yuǎn)程智能監(jiān)測(cè)與診斷專(zhuān)項(xiàng)技術(shù)開(kāi)發(fā)，2020.04-2020.09
15) 企業(yè)委托，核電廠主設(shè)備缺陷監(jiān)測(cè)及診斷系統(tǒng)瞬態(tài)識(shí)別模塊開(kāi)發(fā)和樣機(jī)集成，2020.07-2021.01
14) 企業(yè)委托，大型液壓阻尼器典型故障診斷系統(tǒng)，2020.10-2021.04
13) 企業(yè)委托，氣動(dòng)調(diào)節(jié)閥在線監(jiān)測(cè)軟件開(kāi)發(fā)與測(cè)試，2020.10-2021.01
12) 企業(yè)委托，先進(jìn)封裝過(guò)程監(jiān)測(cè)研究，2018.06-2018.12
11) 國(guó)家自然科學(xué)基金重點(diǎn)項(xiàng)目：中近海域大型海上浮式風(fēng)機(jī)耦合動(dòng)力學(xué)與穩(wěn)定性機(jī)理研究 (2017.01-2021.12, 300萬(wàn)，項(xiàng)目批準(zhǔn)編號(hào)：11632011)
10) 上海思瑞在線監(jiān)測(cè)技術(shù)有限公司委托項(xiàng)目：發(fā)電機(jī)轉(zhuǎn)子匝間短路在線監(jiān)測(cè)設(shè)備研究開(kāi)發(fā)(2015.12-2016.06)
9) 上海市科委國(guó)際合作重點(diǎn)項(xiàng)目：薄壁件銑削過(guò)程穩(wěn)定性分析、監(jiān)測(cè)與控制(2014.07-2017.06, 50萬(wàn)， 項(xiàng)目批準(zhǔn)編號(hào)：14140711100)
8) 國(guó)家自然科學(xué)基金面上項(xiàng)目：基于廣義多項(xiàng)式混沌展開(kāi)理論的振動(dòng)系統(tǒng)不確定性問(wèn)題研究 (2015.01-2018.12，90萬(wàn)， 項(xiàng)目批準(zhǔn)編號(hào)：11472170)
7) 上海電氣電站設(shè)備有限公司委托項(xiàng)目: 600MW發(fā)電機(jī)機(jī)座模態(tài)和動(dòng)力特性測(cè)試研究(2013.04-2014.3)
6) 國(guó)家杰出青年科學(xué)基金：復(fù)雜機(jī)電系統(tǒng)非線性動(dòng)力學(xué)頻域辨識(shí)方法(2012.01-2015.12， 240萬(wàn)，項(xiàng)目批準(zhǔn)編號(hào)：11125209)
5) 國(guó)家自然科學(xué)基金國(guó)際(地區(qū))合作交流項(xiàng)目(NSFC-RS:中英)：基于非線性Lamb 波及頻域分析的結(jié)構(gòu)損傷定位及評(píng)估方法研究 (2013.04–2015.03，中方主持，12.7萬(wàn)，項(xiàng)目批準(zhǔn)編號(hào)：11311130116)
4) 英國(guó)EPSRC資助項(xiàng)目：新一代阻尼技術(shù) (2008.3-2011.3，35萬(wàn)英鎊，英國(guó)Sheffield 大學(xué))
3) 國(guó)家自然科學(xué)基金青年基金：基于Volterra級(jí)數(shù)理論的多自由度非線性振動(dòng)系統(tǒng)的頻率響應(yīng)特性研究 (2010.1-2012.12， 24萬(wàn)，項(xiàng)目批準(zhǔn)編號(hào)：10902068)
2) 教育部新世紀(jì)優(yōu)秀人才支持計(jì)劃 (2010.01-2012.12，50萬(wàn)，項(xiàng)目批準(zhǔn)編號(hào)：NCET-09-0548)
1) 上海市浦江人才支持計(jì)劃(2010.06-2012.06，20萬(wàn)，項(xiàng)目批準(zhǔn)編號(hào)：10PJ1406000)

發(fā)表SCI收錄論文121篇(第1作者39篇)，SCI他引2150余次(按Google Scholar，論文引用5000余次)，4篇入選本領(lǐng)域近十年ESI TOP 1%高被引論文，2014~2018年連續(xù)入選愛(ài)思唯爾“中國(guó)高被引學(xué)者榜單”。
http://scholar.google.co.uk/citations?user=Qv9wI8YAAAAJ

[1] P Zhou, X Dong, S Chen, Z Peng, W Zhang, Parameterized model based Short-time chirp component decomposition, Signal Processing 145(2018), 146-154
[2] Y Yang, Z Peng, X Dong, W Zhang, DA Clifton, Component isolation for multi-component signal analysis using a non-parametric gaussian latent feature model, Mechanical Systems and Signal Processing 103(2018), 368-380
[3] J Zhong, S Zhong, Q Zhang, Z Peng, Measurement of instantaneous rotational speed using double-sine-varying-density fringe pattern, Mechanical Systems and Signal Processing 103(2018), 117-130
[4] HX Zou, WM Zhang, WB Li, KX Wei, KM Hu, ZK Peng, G Meng, Magnetically coupled flextensional transducer for wideband vibration energy harvesting: Design, modeling and experiments, Journal of Sound and Vibration 416(2018), 55-79
[5] S Hu, W Huang, X Shi, Z Peng, X Liu, Y Wang, Bi-Gaussian stratified effect of rough surfaces on acoustic emission under a dry sliding friction, Tribology International 119(2018), 308-315
[6] Y Xiong, Z Peng, G Xing, W Zhang, G Meng, Accurate and Robust Displacement Measurement for FMCW Radar Vibration Monitoring, IEEE Sensors Journal 18 (2018) , 1131-1139
[7] S Wei, ZK Peng, XJ Dong, WM Zhang, A nonlinear subspace-prediction error method for identification of nonlinear vibrating structures, Nonlinear Dynamics 91 (2018) , 1605-1617
[8] S Hu, W Huang, X Shi, Z Peng, X Liu, Y Wang, Evolution of bi-Gaussian surface parameters and sealing performance for a gas face seal under a low-speed condition, Tribology International (2018)
[9] S Chen, X Dong, Y Xiong, Z Peng, WM Zhang, Non-Stationary Signal De-noising Using an Envelope-Tracking Filter, IEEE/ASME Transactions on Mechatronics (2018)
[10] B Wen, X Tian, X Dong, Z Peng, W Zhang, Influences of surge motion on the power and thrust characteristics of an offshore floating wind turbine, Energy 141(2017), 2054-2068
[11] S Chen, X Dong, Z Peng, W Zhang, G Meng, Nonlinear chirp mode decomposition: A variational method, IEEE Transactions on Signal Processing 65 (2017), 6024-6037
[12] Y Xiong, S Chen, X Dong, Z Peng, W Zhang, Accurate measurement in Doppler radar vital sign detection based on parameterized demodulation, IEEE Transactions on Microwave Theory and Techniques 65 (2017), 4483-4492
[13] HX Zou, WM Zhang, WB Li, QH Gao, KX Wei, ZK Peng, G Meng, Design, modeling and experimental investigation of a magnetically coupled flextensional rotation energy harvester, Smart Materials and Structures 26 (2017), 115023
[14] QH Gao, WM Zhang, HX Zou, WB Li, ZK Peng, G Meng, Design and Analysis of a Bistable Vibration Energy Harvester Using Diamagnetic Levitation Mechanism, IEEE Transactions on Magnetics 53 (2017), 1-9
[15] Y Xiong, S Chen, G Xing, Z Peng, W Zhang, Static clutter elimination for frequency-modulated continuous-wave radar displacement measurement based on phasor offset compensation, Electronics Letters 53(2017), 1491-1493
[16] S Chen, X Dong, G Xing, Z Peng, W Zhang, G Meng, Separation of overlapped non-stationary signals by ridge path regrouping and intrinsic chirp component decomposition, IEEE Sensors Journal 17(2017), 5994-6005
[17] HX Zou, W Zhang, WB Li, KX Wei, QH Gao, ZK Peng, G Meng, Design and experimental investigation of a magnetically coupled vibration energy harvester using two inverted piezoelectric cantilever beams for rotational motion, Energy Conversion and Management 148(2017), 1391-1398
[18] XQ Li, WB Li, WM Zhang, HX Zou, ZK Peng, G Meng, Magnetic force induced tristability for dielectric elastomer actuators, Smart Materials and Structures 26 (2017), 105007
[19] H Yan, WM Zhang, HM Jiang, KM Hu, FJ Hong, ZK Peng, G Meng, A measurement criterion for accurate mass detection using vibrating suspended microchannel resonators, Journal of Sound and Vibration 403(2017), 1-20
[20] B Wen, S Wei, K Wei, W Yang, Z Peng, F Chu, Power fluctuation and power loss of wind turbines due to wind shear and tower shadow, Frontiers of Mechanical Engineering 12 (2017), 321-332
[21] X Wang, Q Xu, M Huang, L Zhang, Z Peng, Effects of journal rotation and surface waviness on the dynamic performance of aerostatic journal bearings, Tribology International 112(2017), 1-9
[22] S Chen, Z Peng, Y Yang, X Dong, W Zhang, Intrinsic chirp component decomposition by using Fourier Series representation, Signal Processing 137(2017), 319-327
[23] XZ Li, XJ Dong, ZK Peng, WM Zhang, G Meng, Local variation detection in MDOF system using wavelet based transmissibility and its application in cracked beam, Journal of Vibration and control 23(2017), 2307-2327
[24] WB Li, WM Zhang, HX Zou, ZK Peng, G Meng, A novel variable stiffness mechanism for dielectric elastomer actuators, Smart Materials and Structures 26 (2017), 085033
[25] P Zhou, Z Peng, S Chen, Y Yang, W Zhang, Non-stationary signal analysis based on general parameterized time–frequency transform and its application in the feature extraction of a rotary machine, Frontiers of Mechanical Engineering, (2017), 1-9
[26] S Wei, QK Han, XJ Dong, ZK Peng, FL Chu, Dynamic response of a single-mesh gear system with periodic mesh stiffness and backlash nonlinearity under uncertainty, Nonlinear Dynamics 89(2017), 49-60
[27] HX Zou, WM Zhang, WB Li, KM Hu, KX Wei, ZK Peng, G Meng, A broadband compressive-mode vibration energy harvester enhanced by magnetic force intervention approach, Applied Physics Letters 110 (2017), 163904
[28] WM ZHANG, H YAN, ZK PENG, G MENG, Research progress on energy dissipation mechanisms in micro-and nano-mechanical resonators, Chinese Science Bulletin 62 (2017), 2077-2093
[29] CM Cheng, ZK Peng, WM Zhang, G Meng, Volterra-series-based nonlinear system modeling and its engineering applications: A state-of-the-art review, Mechanical Systems and Signal Processing 87(2017), 340-364
[30] X Wang, Q Xu, B Wang, L Zhang, H Yang, Z Peng, Numerical Calculation of Rotation Effects on Hybrid Air Journal Bearings, Tribology Transactions 60 (2017), 195-207
[31] S Chen, X Dong, Y Yang, W Zhang, Z Peng, G Meng, Chirplet path fusion for the analysis of time-varying frequency-modulated signals, IEEE Transactions on Industrial Electronics 64 (2017), 1370-1380
[32] MW Zhang, S Wei, ZK Peng, XJ Dong, WM Zhang, A two-stage time domain subspace method for identification of nonlinear vibrating structures, International Journal of Mechanical Sciences 120(2017), 81-90
[33] YM Wei, ZK Peng, XJ Dong, WM Zhang, G Meng, Mechanism of Optimal Targeted Energy Transfer, Journal of Applied Mechanics 84 (2017), 011007
[34] HX Zou, WM Zhang, KX Wei, WB Li, ZK Peng, G Meng, A compressive-mode wideband vibration energy harvester using a combination of bistable and flextensional mechanisms, Journal of Applied Mechanics 83 (2016), 121005
[35] X Wang, Q Xu, B Wang, L Zhang, H Yang, Z Peng, Effect of surface waviness on the static performance of aerostatic journal bearings, Tribology International 103(2016), 394-405

[36] WB Li, WM Zhang, HX Zou, ZK Peng, G Meng, Asymmetry bistability for a coupled dielectric elastomer minimum energy structure, Smart Materials and Structures 25 (2016), 115023
[37] H Yan, WM Zhang, HM Jiang, KM Hu, ZK Peng, G Meng, Dynamical characteristics of fluid-conveying microbeams actuated by electrostatic force, Microfluidics and Nanofluidics 20(2016), 137
[38] CM Cheng, ZK Peng, WM Zhang, G Meng, A novel approach for identification of cascade of Hammerstein model, Nonlinear Dynamics 86(2016), 513-522
[39] Y Deng, CM Cheng, Y Yang, ZK Peng, WX Yang, WM Zhang, Parametric Identification of Nonlinear Vibration Systems Via Polynomial Chirplet Transform, Journal of Vibration and Acoustics 138 (2016), 051014
[40] HX Zou, WM Zhang, KX Wei, WB Li, ZK Peng, G Meng, Design and Analysis of a Piezoelectric Vibration Energy Harvester Using Rolling Mechanism, Journal of Vibration and Acoustics 138 (2016), 051007
[41] KM Hu, WM Zhang, X Shi, H Yan, ZK Peng, G Meng, Adsorption-induced surface effects on the dynamical characteristics of micromechanical resonant sensors for in situ real-time detection, Journal of Applied Mechanics 83 (2016), 081009
[42] Y Yang, ZK Peng, XJ Dong, WM Zhang, G Meng, Nonlinear time-varying vibration system identification using parametric time–frequency transform with spline kernel, Nonlinear dynamics 85 (2016), 1679-1694
[43] S Wei, Q Han, Z Peng, F Chu, Dynamic analysis of wind turbine gearboxes with unknown-but-bounded parameters under random wind excitation, IET Renewable Power Generation 11 (2016), 433-442
[44] W Yang, Z Peng, K Wei, P Shi, W Tian, Superiorities of variational mode decomposition over empirical mode decomposition particularly in time–frequency feature extraction and wind turbine condition monitoring, IET Renewable Power Generation 11 (2016), 443-452
[45] W Yang, Z Peng, K Wei, W Tian, Structural health monitoring of composite wind turbine blades: challenges, issues and potential solutions, IET Renewable Power Generation 11 (2016), 411-416
[46] MW Zhang, ZK Peng, XJ Dong, WM Zhang, G Meng, Location identification of nonlinearities in MDOF systems through order deternation of state-space models, Nonlinear Dynamics 84 (2016), 1837-1852
[47] S Wei, Q Han, Z Peng, F Chu, Dynamic analysis of parametrically excited system under uncertainties and multi-frequency excitations, Mechanical Systems and Signal Processing 72(2016), 762-784
[48] WM Zhang, H Yan, HM Jiang, KM Hu, ZK Peng, G Meng, Dynamics of suspended microchannel resonators conveying opposite internal fluid flow: Stability, frequency shift and energy dissipation, Journal of Sound and Vibration 368(2016), 103-120
[49] Y Yang, ZK Peng, WM Zhang, G Meng, ZQ Lang, Dispersion analysis for broadband guided wave using generalized warblet transform, Journal of Sound and Vibration 367(2016), 22-36
[50] X Zhang, Q Han, Z Peng, F Chu, A comprehensive dynamic model to investigate the stability problems of the rotor–bearing system due to multiple excitations, Mechanical Systems and Signal Processing 70(2016), 1171-1192
[51] WM Zhang, KM Hu, B Yang, ZK Peng, G Meng, Effects of surface relaxation and reconstruction on the vibration characteristics of nanobeams, Journal of Physics D: Applied Physics 49 (2016), 165304
[52] S Chen, Y Yang, K Wei, X Dong, Z Peng, W Zhang, Time-varying frequency-modulated component extraction based on parameterized demodulation and singular value decomposition, IEEE Transactions on Instrumentation and Measurement 65 (2016), 276-285
[53] KM Hu, WM Zhang, ZK Peng, G Meng, Transverse vibrations of mixed-mode cracked nanobeams with surface effect, Journal of Vibration and Acoustics 138(2016), 011020
[54] WM Zhang, H Yan, Z Peng, G Meng, Finite volume modeling of gas flow in microbearings with rough surface topography, Tribology Transactions 59 (2016), 99-107
[55] J Lan, Z Peng, Interval uncertainty analysis using CANDECOMP/PARAFAC decomposition, Model Validation and Uncertainty Quantification, Volume 3(2016), 73-81
[56] Y Yang, XJ Dong, ZK Peng*, WM Zhang, G Meng, Vibration signal analysis using parameterized time–frequency method for features extraction of varying-speed rotary machinery, Journal of Sound and Vibration 335(2015), 350-366
[57] CM Cheng, ZK Peng*, X.J Dong, WM Zhang, G Meng, A novel damage detection approach by using Volterra kernel functions based analysis, Journal of the Franklin Institute, 352(2015) 3098–3112
[58] Y Yang, X Dong, Z Peng*, W Zhang, G Meng, Component Extraction for Non-Stationary Multi-Component Signal Using Parameterized De-chirping and Band-Pass Filter, IEEE Signal Processing Letters, 22 (2015), 1373-1377
[59] Y Liu, E Pavlovskaia, M Wiercigroch, Z Peng, Forward and backward motion control of a vibro-impact capsule system, International Journal of Non-Linear Mechanics 70(2015), 30-46
[60] KM Hu, WM Zhang, XJ Dong, ZK Peng, G Meng, Scale Effect on Tension-Induced Intermodal Coupling in Nanomechanical Resonators, ASME-Journal of Vibration and Acoustics 137 (2015), 021008
[61] H Yan, WM Zhang, ZK Peng, G Meng, Effect of random surface topography on the gaseous flow in microtubes with an extended slip model, Microfluidics and Nanofluidics 18 (2015), 897-910
[62] H Yan, WM Zhang, ZK Peng, G Meng, Effect of Three-Dimensional Surface Topography on Gas Flow in Rough Micronozzles, Journal of Fluids Engineering 137 (2015), 051202
[63] X Zhang, Q Han, Z Peng, F Chu, A new nonlinear dynamic model of the rotor-bearing system considering preload and varying contact angle of the bearing, Communications in Nonlinear Science and Numerical Simulation 22 (2015), 821-841
[64] 彭志科*，程長(zhǎng)明，Volterra 級(jí)數(shù)理論研究進(jìn)展與展望, 科學(xué)通報(bào)，60(2015) 1874-1888
[65] Y. Yang, Z. K. Peng*, X. J. Dong, W. M. Zhang, and G.Meng，Application of Parameterized Time-FrequencyAnalysis on Multicomponent Frequency Modulated Signals，IEEE TRANSACTIONS ON INSTRUMENTATION AND MEASUREMENT，63 (2014), 3169-3180
[66] CM Cheng, ZK Peng*, XJ Dong, WM Zhang, G Meng, Locating non-linear components in two dimensional periodic structures based on NOFRFs, International Journal of Non-Linear Mechanics 67(2014), 198-208
[67] X.J Dong*, L Ye, Z.K Peng, H.X Hua, G. Meng.. Performance evaluation of vibration controller for piezoelectric smart structures in finite element environment. Journal of vibration and Control., 20 (2014), 2146-2161
[68] X.J Dong*, L Ye, Z.K Peng, H.X Hua, G. Meng. A study on controller structure interaction of piezoelectric smart structures based on finite element method. Journal of Intelligent Material Systems and Structures. 25 (2014), 1401-1413
[69] X.J Dong, Z.K Peng, W.M Zhang, G. Meng. Connection between Volterra Series and Perturbation Method in Nonlinear Systems Analysis. Acta Mechanica Sinica. 30 (2014), 600-606
[70] Y. Yang, Z. K. Peng*, X. J. Dong, W. M. Zhang, and G.Meng，General Parameterized Time-Frequency Transform, IEEE TRANSACTIONS ON SIGNAL PROCESSING, 62,(2014) 2751-2764
[71] WM Zhang, H Yan, ZK Peng, G Meng, Electrostatic pull-in instability in MEMS/NEMS: A review, Sensors and Actuators A: Physical 214(2014), 187-218
[72] Y Yang, ZK Peng*, WM Zhang, G Meng , Frequency-varying group delay estimation using frequency domain polynomial chirplet transform, Mechanical Systems and Signal Processing 46 (2014), 146-162
[73] Q.K Han, J.S Zhao, W.X Lu, Z.K Peng, F.L Chu*, Steady-state response of a geared rotor system with slant cracked shaft and time-varying mesh stiffness, Communications in Nonlinear Science and Numerical Simulation, 19(2014) 1156–1174
[74] CM Cheng, ZK Peng*, WM Zhang, G Meng , Wavelet basis expansion-based Volterra kernel function identification through multilevel excitations, Nonlinear Dynamics 76 (2014), 985-999
[75] CM Cheng, XJ Dong, ZK Peng*, WM Zhang, G Meng, Wavelet basis expansion-based spatio-temporal Volterra kernels identification for nonlinear distributed parameter systems, Nonlinear Dynamics 78 (2014), 1179-1192
[76] X Dong, Z Peng, H Hua, G Meng , Modeling of the Through-the-Thickness Electric Potentials of a Piezoelectric Bimorph Using the Spectral Element Method, Sensors 14 (2014), 3477-3492
[77] KM Hu, WM Zhang, ZY Zhong, ZK Peng, G Meng , Effect of surface layer thickness on buckling and vibration of nonlocal nanowires, Physics Letters A 378 (2014), 650-654
[78] Liu, Y, Zhang, WM , Zhong, ZY, Peng, ZK, Meng, G, Nonlinear dynamic analysis of nano-resonator driven by optical gradient force, ACTA PHYSICA SINICA , 63(2014) 26201
[79] X.J Dong, Z.K Peng, W.M Zhang, H.X Hua and G Meng, An Efficient Spectral Element Model with Electric DOFs for the Static and Dynamic Analysis of a Piezoelectric Bimorph, Mathematical Problems in Engineering, 2014 (2014), Article ID 425317, 9 pages
[80] X.J Dong, Z.K Peng, W.M Zhang, H.X Hua and G Meng,, Research on Spillover Effects for Vibration Control of Piezoelectric Smart Structures by ANSYS, Mathematical Problems in Engineering, 2014 (2014), Article ID 870940 , 8 pages
[81] W.M. Zhang*, G. Meng, Z. K. Peng, Gaseous slip flow in micro-bearings with random rough surface, International Journal of Mechanical Sciences, 68(2013) 105-113
[82] Z.K. Peng, W.M. Zhang, B.T. Yang, G. Meng, F.L. Chu*, The parametric characteristic of bispectrum for nonlinear systems subjected to Gaussian input, Mechanical Systems and Signal Processing, 36(2013) 456-470
[83] X.J. Dong*, Z.K. Peng, W.M. Zhang, G. Meng, F.L. Chu, Parametric characteristic of the random vibration response of nonlinear systems, Acta Mechanica Sinica/Lixue Xuebao, 29(2013) 267-283
[84] X.N Zhang , Q.K Han , Z.K Peng, F.L Chu*, Stability analysis of a rotor–bearing system with time-varying bearing stiffness due to finite number of balls and unbalanced force, Journal of Sound and Vibration, 332(2013)6768–6784
[85] 彭志科*, 孟光, 張文明, Volterra級(jí)數(shù)與攝動(dòng)法的內(nèi)在關(guān)系研究, 中國(guó)科學(xué):物理學(xué) 力學(xué) 天文學(xué), 第4期, 494-499頁(yè), 2013.
[86] 程長(zhǎng)明, 彭志科*, 孟光, 基于NARMAX模型和NOFRF結(jié)構(gòu)損傷檢測(cè)的實(shí)驗(yàn)研究, 動(dòng)力學(xué)與控制學(xué)報(bào), 第11卷, 第1期, 89-96頁(yè), 2013.
[87] 鄧楊, 彭志科*, 楊揚(yáng), 張文明, 孟光, 基于參數(shù)化時(shí)頻分析的非線性振動(dòng)系統(tǒng)參數(shù)辨識(shí), 力學(xué)學(xué)報(bào), 第45卷, 第6期, 992-996頁(yè), 2013.
[88] Z.K Peng, Z.Q Lang, G. Meng, S. A. Billings, Reducing force transmissibility in multiple degrees of freedom structures through anti-symmetric nonlinear viscous damping, Acta Mechanica Sinica, 28 (2012) 1436-1448
[89] Z.K. Peng, G. Meng, Z.Q Lang, W.M. Zhang, F.L. Chu, Study of the effects of cubic nonlinear damping on vibration isolations using Harmonic Balance Method, International Journal of Non-Linear Mechanics, 47 (2012) 1073–1080
[90] Z.K Peng, W.M Zhang, Z.Q. Lang, G Meng, F.L. Chu, Time-Frequency Data Fusion Technique with Application to Vibration Signal Analysis, Mechanical Systems and Signal Processing, 29 (2012) 164–173
[91] P.F Guo, Z.Q Lang, Z.K Peng, Analysis and design of the force and displacement transmissibility of nonlinear viscous damper based vibration isolation systems, Nonlinear Dynamics, 67(2012) 2671-2687
[92] Y Yang, Z.K Peng, G. Meng, W.M Zhang, A Novel Time Frequency Transform for the Analysis of Signals with Time-varying Frequency, IEEE Transactions on Industrial Electronics, 59(2012) 1612-1621
[93] Y Yang, Z.K Peng, G. Meng, W.M Zhang, Characterize highly oscillating frequency modulation using generalized Warblet transform, Mechanical Systems and Signal Processing, 26 (2012) 128-140
[94] W.M Zhang, G. Meng, Z.K Peng, Coupled Nonlinear Effects of Random Surface Roughness and Rarefaction on Slip Flow in Ultra-Thin Film Gas Bearing Lubrication, Journal of Tribology – Transactions of the ASME, 134(2012) 024502
[95] W.M Zhang, G. Meng, X.Y Wei, Z.K Peng, Effect of surface roughness on rarefied-gas heat transfer in microbearings, Physics Letters A, 376 (2012) 789-794
[96] W.M Zhang, G. Meng, X.Y Wei, Z.K Peng, Slip flow and heat transfer in microbearings with fractal surface topographies, International Journal of Heat and Mass Transfer, 55(2012) 7223-7233
[97] Z.K Peng, Z.Q Lang, L Zhao, S.A Billings, The force transmissibility of MDOF structures with a non-linear viscous damping device, International Journal of Non-linear Mechanics, 46(2012) 1305-1314
[98] Z. K. Peng, Z. Q. Lang, et al, Feasibility study of structural damage detection using NARMAX modelling and Nonlinear Output Frequency Response Function based analysis, Mechanical Systems and Signal Processing, 25 (2011) 1045–1061
[99] Z.K. Peng, Z.Q. Lang, G. Meng and F.L. Chu, The effects of crack on the transmission matrix of rotor systems, Shock and Vibration, 18 (2011) 91–103
[100]Z. K. Peng, G. Meng, F. L. Chu, Improved wavelet reassigned scalograms and application for modal parameter estimation, Shock and Vibration, 18 (2011) 299–316
[101]Z. K. Peng, Z.Q Lang, G. Meng and F. L. Chu, On the Distribution of Nonlinear Effects in Locally Nonlinear One-Dimensional Chain Type Structures, International Journal of Mechanical Sciences, 53 (2011) 226–235
[102]Z.K Peng, G. Meng, Z.Q. Lang, F.L Chu, W.M Zhang, Polynomial Chirplet Transform with Application to Instantaneous Frequency Estimation, IEEE Transactions on Measurement and Instrumentation 60(2011) 3222-3229
[103]R.J Hao, Z.K Peng, Z.P Feng, F.L Chu, Application of support vector machine based on pattern spectrum entropy in fault diagnostics of rolling element bearings, Measurement Science and Technology, 22 (2011) 045708 (13pp)
[104]W.M Zhang, G. Meng, Z.K Peng, Nonlinear Dynamic Analysis of Atomic Force Microscopy Under Bounded Noise Parametric Excitation, IEEE/ASME TRANSACTIONS ON MECHATRONICS, 16 (2011) 1063-1072
[105]Z.K Peng, Z.Q Lang, Effects of anti-symmetric nonlinear viscous damping on the force transmissibility of MDOF structures, Theoretical & Applied Mechanics Letters, 1(2011) 063004
[106]程長(zhǎng)明,彭志科,孟光,一類(lèi)非線性系統(tǒng)的隨機(jī)振動(dòng)頻域響應(yīng)分析研究,力學(xué)學(xué)報(bào), 43 (2011) 905-913
[107]彭志科,郎自強(qiáng),孟光,程長(zhǎng)明, 一類(lèi)非線性隔振器振動(dòng)傳遞特性分析,動(dòng)力學(xué)與控制學(xué)報(bào), 9(2011) 314-320
[108]Z. K. Peng, Z. Q. Lang, X. J. Jing, and S. A. Billings, The Transmissibility of Vibration Isolators With a Nonlinear Anti-symmetric Damping Characteristic, ASME- Journal of Vibration and Acoustics, 132(2010) 014501 (7 pages)
[109]Z.K Peng, Z.Q Lang, The Nonlinear Output Frequency Response Functions of One- Dimensional Chain Type Structures, ASME-Journal of Applied Mechanics, 77 (2010) 011007 (10 pages)
[110]Z. K. Peng, Z. Q. Lang, F. L. Chu and G. Meng, Locating Nonlinear Component in Periodic Structures Using the Nonlinear Effects, Structural Health Monitoring - An International Journal, 9 (2010) 401-411
[111]Z.K. Peng, M.R. Jackson, L.Z Guo, R.M. Parkin, G. Meng, Effects of bearing clearance on the chatter stability of milling process, Nonlinear Analysis: Real World Applications, 11 (2010) 3577-3589
[112]W.M Zhang, G Meng, Z.K Peng, Random surface roughness effect on slider micro bearing lubrication, Micro&Nano Letters, 5(2010) 347-350
[113]ZK Peng, ZQ Lang, SA Billings, Analysis of Locally Nonlinear MDOF Systems Using Nonlinear Output Frequency Response Functions, ASME- Journal of Vibration and Acoustics, 131(2009) 051007 (10 pages)
[114]Z. K Peng, Z.Q. Lang, C. Wolters, S.A. Billings, Feature Extraction for Damage Detection in Structures Based on Nonlinearity Analysis, Key Engineering Materials, 413-414 (2009) 627-634
[115]Z.K. Peng, M.R. Jackson, J.A. Rongong, F.L. Chu, R.M. Parkin, On the Energy Leakage of Discrete Wavelet Transform, Mechanical Systems and Signal Processing, 23(2009) 330-343
[116]Z.Q. Lang, X.J. Jing, S.A. Billings, G.R. Tomlinson, Z.K. Peng，Theoretical study of the effects of nonlinear viscous damping on vibration isolation of sdof systems, Journal of Sound and Vibration, 323 (2009) 352-365
[117]F.L Chu, S.F Yuan, Z.K Peng (2009). Machine Learning Techniques, in Encyclopedia of Structural Health Monitoring, Boller, C., Chang, F. and Fujino, Y. (eds). John Wiley & Sons Limited, Chichester, UK, pp597-610.
[118]褚福磊, 彭志科等, <機(jī)械故障診斷中的現(xiàn)代信號(hào)處理方法>, 科學(xué)出版社, 北京, 2009 (獲2007年度中國(guó)科學(xué)院科學(xué)出版基金資助)
[119]Z.K Peng, Z.Q Lang, S.A Billings, Nonlinear Parameter Estimation for Multi-Degree-of-Freedom Nonlinear Systems Using Nonlinear Output Frequency Response Functions, Mechanical Systems and Signal Processing, 22 (2008) 1582-1594
[120]Z.K. Peng, Z.Q. Lang, F. L. Chu, On the Nonlinear Effects Introduced by Crack Using Nonlinear Output Frequency Response Functions. Computers & Structure, 86 (2008) 1809-1818
[121]Z.K Peng, Z.Q. Lang, S.A Billings, A Novel Method for Detecting the Nonlinear Components in Periodic Structures, Institution of Mechanical Engineers, Part C, Journal of Mechanical Engineering Science, 222 (2008) 903-910
[122]Z.K Peng, Z.Q Lang, The Effects of System Nonlinearity on the Output Frequency Response of a Nonlinear Passive Engine Mount, Journal of Sound and Vibration, 318(2008) 313-328
[123]Z.Q Lang, Z.K Peng, A Novel Approach for Nonlinearity Detection in Vibrating Systems, Journal of Sound and Vibration 314 (2008) 603-615
[124]Z.K. Peng, Z.Q Lang, S.A Billings and GR Tomlinson, Comparisons between Harmonic Balance and Nonlinear Output Frequency Response Function in Nonlinear System Analysis, Journal of Sound and Vibration 311 (2008) 56-73
[125]F L Chu, Z K Peng and Z Q Lang, An effective method for locating nonlinear components in periodic structures, Journal of Physics: Conference Series 96 (2008) 012016
[126]Z.K Peng, Z.Q Lang, S.A Billings, Linear Parameter Estimation for Multi-Degree-of -Freedom Nonlinear Systems Using Nonlinear Output Frequency Response Functions, Mechanical Systems and Signal Processing, 21 (2007) 3108-3122
[127]Z.K Peng, Z.Q Lang, On the Convergence of the Volterra Series Representation of the Duffing’s Oscillators Subjected to Harmonic Excitations, Journal of Sound and Vibration, 305 (2007) 322-332
[128]Z.K Peng, Z.Q Lang, S.A Billings, Nonlinear Output Frequency Response Functions of MDOF Systems with Multiple Nonlinear Components, International Journal of Non-linear Mechanics, 42 (2007) 941-958
[129]Z.K Peng, Z.Q Lang, S.A Billings, Nonlinear Output Frequency Response Function under Harmonic Loadings and Its Application to Bilinear Oscillator Study, International Journal of Mechanical Sciences, 49 (2007) 1213-1225
[130]Z.K Peng, Z.Q Lang, S.A Billings, Resonances and resonant frequencies for a class of nonlinear systems. Journal of Sound and Vibration 300 (2007) 993-1014
[131]Z.K Peng, Z.Q Lang, S.A Billings, Crack detection using nonlinear output frequency response functions, Journal of Sound and Vibration, 301(2007) 777-788
[132]Z.K Peng, Z.Q Lang, S.A Billings, Nonlinear Output Frequency Response Functions for Multi-Input Nonlinear Volterra Systems, International Journal of Control, 80 (2007) 843-855
[133]Z.K Peng, Z.Q Lang, Detecting the Position of Nonlinear Component in Periodic Structures from the System Responses to Dual Sinusoidal Excitations. International Journal of Non-Linear Mechanics. 42 (2007) 1074-1083
[134]Z.K Peng, Z.Q Lang, The Relationship between Harmonic Balance Method and Nonlinear Output Frequency Response Function Approach, Proceedings of the Institution of Mechanical Engineers, Part C, Journal of Mechanical Engineering Science, 221 (2007) 1533-1543
[135]D. Guo, Z.K. Peng, Vibration analysis of a cracked rotor using Hilbert–Huang transform, Mechanical Systems and Signal Processing, 21(2007) 3030-3041
[136]Z.K. Peng, F.L. Chu and Peter W. Tse, Singularity Analysis of the Vibration Signals Using Wavelet Modulus Maxima Method. Mechanical Systems and Signal Processing, 21 (2007) 780-794
[137]Z.K. Peng, Z.Q Lang and S.A. Billings, (2006). The Nonlinear Output Frequency Response Function and Its Application to Fault Detection. 6th IFAC Symposium on Fault Detection, Supervision and Safety of technical Process, Beijing P. R China
[138]Z.K. Peng, Peter W. Tse and F.L. Chu, An Improved Hilbert - Huang Transform and Its Application for Vibration Signals Analysis. Journal of Sound and Vibration, 286 (2005) 187-205
[139]Z.K. Peng, Peter W. Tse and F.L. Chu, A Comparison Study of Improved Hilbert-Huang Transform and Wavelet Transform: Application to Fault Diagnosis for Rolling Bearing. Mechanical Systems and Signal Processing, 19 (2005) 974-988
[140]Z. K. Peng, F. L. Chu and Peter W. Tse, Detection of the Rubbing Caused Impacts for Rotor - Stator Fault Diagnosis Using Reassigned Scalogram. Mechanical Systems and Signal Processing, 19 (2005) 391-409
[141]Z. K. Peng, F. L. Chu, Application of the Wavelet Transform in Machine Condition Monitoring and Fault Diagnostics: A Review with Bibliography. Mechanical Systems and Signal Processing, 18(2004) 199-221
[142]Z. Peng, Y. He, Q Lu and F. Chu, Feature Extraction of the Rub-Impact Rotor System by Means of Wavelet. Journal of Sound and Vibration, 259 (2003) 1000-1010.
[143]Z. Peng, Y. He, Q Lu and F. Chu, Wavelet Multifractal Approaches for Singularity Analysis of the Vibration Signals. Key Engineering Materials, 245(2003) 565-570
[144]Q Lu, Z. Peng, F. Chu and J Huang, Design of Fuzzy Controller for Smart Structures Using Genetic Algorithms. Smart Materials and Structures. 12(2003) 979-986
[145]Z. Peng, F. Chu and Y. He, Vibration Signal Analysis and Feature Extraction Based On Reassigned Wavelet Scalogram. Journal of Sound and Vibration, 253 (2002)1087-1100
[146]Z. Peng, Y. He, Z. Chen and F. Chu, Identification of the Shaft Orbit for Rotating Machines Using Wavelet Modulus Maxima. Mechanical Systems and Signal Processing, 16(2002) 623-635

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