The 2 International Conference on Applicationsveh2019.shanghaitech.edu.cn/VEH2019_program.pdf ·...

The 2nd International Conference on Vibration and Energy Harvesting

Applications

ShanghaiTech University

Shanghai, China

July 13-15, 2019

Hosts

Sponsors

The 2nd International Conference on Vibration and Energy Harvesting Applications, July 13-15, 2019, Shanghai, China

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Program at A Glance

Start End Activities Presenter Venue

Day 0

(Jul. 13) 17:00 20:00 Registration -- SIST Lobby

Day 1

(Jul. 14)

8:00 8:30 Registration -- SIST Lobby

8:30 9:00 Opening Remark

& Group Photo Provost Jie Yin

SIST

Auditorium

9:00 9:30 Keynote Talk I Eric Yeatman SIST

Auditorium 9:30 10:00 Keynote Talk II Chengkuo Lee

10:00 10:20 Coffee Break -- SIST Lobby

10:20 11:35 Oral Session A

(MEMS) 5 speakers

SIST

Auditorium

11:35 13:00 Lunch break / TPC meeting -- Western-Style

Dining Hall

13:00 13:30 Keynote Talk III Muhammad Hajj

SIST

Auditorium

13:30 14:00 Keynote Talk IV Liqun Chen

14:00 15:15 Oral Session B

(Structures: nonlinearity) 5 speakers

15:15 15:30 IEEE IES Shanghai

Chapter Outreaching Chengbin Ma

15:30 16:45 Poster Session

& Coffee Break 40 speakers SIST Lobby

16:45 18:30 Oral Session C (Circuits) 7 speakers SIST

Auditorium

18:30 20:30 Conference Banquet

& Award Ceremony --

Staff

Dining Hall

Day 2

(Jul. 15)

8:30 9:00 Keynote Talk V Elie Lefeuvre SIST

Auditorium 9:00 9:30 Keynote Talk VI Wen-Jong Wu

9:30 9:50 Coffee Break -- SIST Lobby

9:50 11:05 Oral Session D

(Applications) 5 speakers

SIST

Auditorium 11:05 11:50

Oral Session E

(Structure: EH from fluids) 3 speakers

11:50 13:10 Lunch Break -- Western-Style

Dining Hall

13:10 14:25 Oral Session F

(Structure: EH from winds) 5 speakers

SIST

Auditorium 14:25 15:10

Oral Session G

(Structure: meta-materials) 3 speakers

15:10 16:10 Panel Discussion Keynote guests

& audiences

16:10 16:40 Coffee Break & Farewell -- SIST Lobby

(Date of revision: July 7, 2019)


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Table of Contents

Program at A Glance .......................................................................................... 2

Table of Contents ............................................................................................... 2

1. Conference Info ................................................................................................4

1.1 VEH 2019 .................................................................................................... 4

1.2 Organizers .................................................................................................. 5

1.3 Maps and WiFi ........................................................................................... 6

2. ShanghaiTech University ................................................................................8

2.1 Overview ..................................................................................................... 8

2.2 School of Information Science and Technology ................................. 10

3. Academic Activities .......................................................................................11

3.1 Keynote Talks .......................................................................................... 11

3.2 Invited Talks ............................................................................................. 17

3.3 Technical Program .................................................................................. 23

4. Poster Papers List ..........................................................................................28

5. Contacts ..........................................................................................................32


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1. Conference Info

1.1 VEH 2019

Vibration energy harvesting is an interdisciplinary research area, which requires substantial

synergy among very diverse expertise from both the academic and industrial communities. In

2018, a group of researchers who share the same particular interest in vibration and energy

harvesting had set up a WeChat group for making a better connection and brainstorming on

the related research topics. The 1st International Conference on Vibration and Energy

Harvesting Applications (VEH 2018) was initiated by Prof. Fei Wang from Southern University

of Science and Technology, Prof. Junyi Cao from Xi’an Jiaotong University, and Prof.

Wenming Zhang from Shanghai Jiao Tong University. It was held in the Southern University

of Science and Technology, Shenzhen, China, during Nov. 2-4, 2018.

The 2nd International Conference on Vibration and Energy Harvesting Applications (VEH 2019)

is held in another young and vibrant university in China, ShanghaiTech University. It aims to

create an effective platform for both the domestic and global researchers, on which they can

share the latest information on the development of the related technologies, have in-depth

discussions, and build up friendships and collaborations across the disciplinary boundaries.

VEH 2019 is well received. As of July 1st, 2019, we have received over 70 paper submissions

and over 100 registrations. The paper topics range from mechanical design and dynamics,

power management circuits and systems, MEMS technology, and self-powered IoT

applications, etc. Besides the participation of academic people, this year we have also

attracted people from industry to join the event. We got some sponsorships from the academic

organization (IEEE Industrial Electronic Society) as well as three companies from the related

industries.

VEH 2019 will be carried out in a single session style for effective information sharing and

discussions among experts from different disciplines. It has 6 Keynote Talks, 32 Oral

Presentations, including 11 Invited Talks, and more than 40 Poster presentations. Besides the

regular sessions, the VEH 2019 has also held a Student Poster Competition to encourage the

participation of more students, as well as a Panel Discussion for making an in-depth idea

exchange towards the future of the energy harvesting technologies.


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1.2 Organizers

Honorary Chairs

• Wei-Hsin Liao, The Chinese University of Hong Kong, Hong Kong, China

• Xinxin Li, Shanghai Institute of Microsystem and Information Technology,

Chinese Academy of Sciences, China

General Co-chairs

• Junrui Liang, ShanghaiTech University, China

• Huicong Liu, Soochow University, China

• Zhengbao Yang, City University of Hong Kong, China

Local Organizing Chairs

• Haoyu Wang, ShanghaiTech University, China

• Tao Wu, ShanghaiTech University, China

• Xiaoqing Zhang, Tongji University, China

Technical Program Committee

• Junyi Cao, Xi’an Jiao Tong University, China

• Liqun Chen, Shanghai University, China

• Zhongsheng Chen, Hunan University of Technology, China

• Kangqi Fan, Xidian University, China

• Junrui Liang, ShanghaiTech University, China

• Huicong Liu, Soochow University, China

• Yan Lu, University of Macau, Macau, China

• Lifeng Qin, Xiamen University, China

• Weiyang Qin, Northwestern Polytechnical University, China

• Giuseppe Quaranta, University of Rome, Italy

• Lihua Tang, University of Auckland, New Zealand

• Lin Wang, Huazhong University of Science and Technology, China

• Fei Wang, Southern University of Science and Technology, China

• Bin Yang, Shanghai Jiao Tong University, China

• Yaowen Yang, Nanyang Technological University, Singapore

• Zhengbao Yang, City University of Hong Kong, Hong Kong SAR, China

• Minghui Yao, Beijing University of Technology, China

• Wenming Zhang, Shanghai Jiao Tong University, China

• Xiaoqing Zhang, Tongji University, China

Conference Secretariat

• Jingying Chen (Chinese contact), ShanghaiTech University, China

• Yiming Gao (English contact), ShanghaiTech University, China

• Xin Li (Publicity), ShanghaiTech University, China

• Li Teng (Registration), ShanghaiTech University, China


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1.3 Maps and WiFi

The full map of ShanghaiTech University and the nearby facilit ies.


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Map of the conference venue:

Building 1, School of Information Science and Technology (SIST)

WiFi is available in Building 1, SIST

- SSID: veh2019

- SSID PWD: energyharvesting

“eduroam” also works in most places on the campus.

SIST auditorium SIST Lobby To the dining halls


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2. ShanghaiTech University

2.1 Overview


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ShanghaiTech University (ShanghaiTech in short, Chinese: 上海科技大学 ) is a young

resource-rich public university with a modern residential campus in the heart of Shanghai

Pudong’s Zhangjiang Hi-Tech Park. With an academic focus on STEAM research,

ShanghaiTech is committed to carrying out China’s national development strategy and

nurturing the next generation of innovative scientists, inventors, and entrepreneurs. By the

end of 2018, ShanghaiTech had 1433 undergraduates, 1788 graduate students (Master &

Ph.D.), and 485 faculty members.

The university has five schools in operation:

- School of Physical Science and Technology

- School of Information Science and Technology

- School of Life Science and Technology

- School of Entrepreneurship and Management

- School of Art and Creativity

In addition, ShanghaiTech has three research institutes:

- Shanghai Institute for Advanced Immunochemical Studies

- iHuman Institute

- Institute of Mathematical Sciences

With the backing and support of the Shanghai Municipal Government and China Academy of

Science, ShanghaiTech’s five schools and three research institutes seek cutting-edge

solutions to address the challenges that China and the world are facing in the fields of energy,

material, environment, human health, and artificial intelligence.

ShanghaiTech believes innovation comes from collaboration. Interdisciplinary research is

highly valued, and ShanghaiTech faculty are encouraged to collaborate across disciplines and

schools. Our location stone's throw distance from the high-tech R&D labs and national

research facilities of Zhangjiang Hi-Tech Park naturally fosters a collaborative relationship

between the university, national research facilities, and multi-national industry partners.

Through linking innovative research to development and commercialization, ShanghaiTech

hopes to play an important role in finding innovative solutions to address China’s most

pressing challenges.

ShanghaiTech University is playing an essential role in the construction of national facilities in

Zhangjiang Hi-Tech Park, such as the Free Electron Laser Facility, the Live Cell Imagining

Facility and the Ultra-Intense and Ultrashort Pulse Laser Facility initiated by the Zhangjiang

National Science Center.

ShanghaiTech University has actively participated in the global education program and carries

out several educational cooperation with some top international universities in student training,

teacher training, curriculum sharing, academic exchanges, cooperative scientific research, etc.

It also actively expands the exchange and cooperation relationship with domestic first-class

universities. At present, the university has established good cooperative relations with famous

universities in Europe and America, such as The University of Chicago, Massachusetts

Institute of Technology, University of California, Berkeley, Yale University, Cornell University,

University of Pennsylvania, University of Padua, Oxford University, Drexel University, etc.


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2.2 School of Information Science and Technology

The School of Information Science and Technology (SIST) is one of the four inaugural schools

of ShanghaiTech University. Since established, SIST has a mission to nurture, educate, and

train future technology innovators, enterprise leaders, R&D specialists, and entrepreneurs in

information science and technology. The SIST integrates world-leading scientific research

environment with life-enriching and transformative educational experience for our students.

SIST is committed to undertake and support national key R&D projects, with a strong

aspiration for scientific and technological breakthroughs. SIST has the clear objective of

becoming a regional, national, and international development workhorse by directly

contributing to global technological advances with creative ideas and disruptive innovations.

The main research areas of SIST includes:

Electrical Engineering

- Analog and digital circuits, power electronics, and systems.

- Signal processing, information theory, communications networks, control theory,

and systems

Computer Engineering

- Architecture, compiler, operating systems, software engineering

- Multi-core and parallel computing, computer networks, high-performance

computing

Computer Science

- Computation theory, algorithms, database

- Machine learning, artificial intelligence, big data, cloud computing, intelligent

machines, and robotics

Computing and Mathematical Science

- Optimization, numerical analysis, applied statistics, distributed and parallel

computing

Interdisciplinary Information Technology

- Bioinformatics, bioengineering, and biomedical engineering (with SLST)

- Microelectronics, devices, and optics (with SPST)

- Sensor networks and cyber-physical systems (with SPST, SEM)

- Renewable energy technology (with SPST)

- Social networks and applications (with SEM)

- Quantum computing and next-generation computing (with SPST, SLST)


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3. Academic Activities

3.1 Keynote Talks

- Keynote talk I (9:00-9:30, July 14)

Eric M. Yeatman

Professor

Department of Electrical and Electronic Engineering

Imperial College London, UK

Fellow of the Royal Academy of Engineering

IEEE Fellow

Title: Broadband Energy Harvesting and Generation with Piezoelectric Transduction

Abstract: Piezoelectric transduction is highly attractive in miniature energy harvesters

because of its simplicity, compatibility with micro-scale integration, and ability to provide

high voltages even at low frequencies. However, because of the low electromechanical

coupling coefficient of practical piezoelectric materials, these devices are usually

incorporated in mechanically resonant structures to enhance power density, and this results

in narrowband operation. This presentation will discuss methods to achieve broadband

performance, and present recent results including frequency up-conversion devices based

on magnetically plucked resonators. Advanced power processing circuits will be reviewed,

and results presented to show the high suitability of plucked piezoelectric devices for power

enhancing active switched circuits. The use of piezoelectrics in continuously rotating micro-

generators will be discussed, and modeling will be presented to show their advantage over

electromagnetic generators below the cm size scale.

Biography: Eric M. Yeatman has been a member of academic staff in Imperial College

London since 1989, and Professor of Micro-Engineering since 2005. He was appointed

Head of the Department of Electrical and Electronic Engineering in Sept. 2015. He has

published more than 250 papers and patents on optical devices and materials, micro-

electro-mechanical systems (MEMS), and other topics. Prof. Yeatman was awarded the

Royal Academy of Engineering Silver Medal in 2011 and was made a Fellow of the

Academy in 2012. He also holds Fellowships of the IEEE, the IET, IOM3, and the City and

Guilds Institute.


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- Keynote talk II (9:30-10:00, July 14)

Chengkuo Lee

Associate Professor

Department of Electrical and Computer Engineering

National University of Singapore, Singapore

Title: Progress and Applications of Energy Harvesting Technology

Abstract: In the past decade, significant growth in energy harvesting technology, which

scavenges the wasted energy available in the ambient environment such as vibrations,

heat, light, radiation, wind, water etc., and converts it into electrical energy, as a potential

inexhaustible source for low-power devices. When the advanced CMOS technology

migrates to 7nm scale, the availability of ultra-low-power integrated circuits (ICs) and MEMS

sensors of 1 µW (or less) power consumption make the sensor nodes in the coming era of

Internet-of-Things (IoT) become feasible to be operated by using the energy harvested from

ambient environment. Considering the same dimension of chip-scale sensor nodes, micro

energy harvesters, or microelectromechanical systems (MEMS) based energy harvesters

(EHs), becomes a promising component for realization of self-sustained miniaturized IoT

Sensor nodes. Although the MEMS EHs normally could not provide large output power, they

remain as good alternatives of power supply for IoT sensor nodes. On the other hand, Z. L.

Wang reports the triboelectric nanogenerator (TENG) in 2012. Various micro-/nano-

systems enabled by the integration of triboelectric nanogenerators and flexible electronics

technology are presented in this talk to show the feasibility of achieving "all-in-one" multi-

functional self-sustained system.

Biography: Dr. Chengkuo Lee received his Ph.D. degree in precision engineering from The

University of Tokyo, Tokyo, Japan, in 1996. Currently, he is the director of Center for

Intelligent Sensors and MEMS at National University of Singapore, Singapore. He

cofounded Asia Pacific Microsystems, Inc. (APM) in 2001, where he was Vice President of

R&D from 2001 to 2005. His research interests include MEMS, NEMS and flexible devices

for IoT, energy harvesting, metamaterials and biomedical applications. He has trained 20+

PhD students graduated from ECE Dept., NUS. He has co-authored 295+ journal articles

and 300+ conference papers. He holds 10 US patents. He is in the Executive Editor Board

of J Micromechanics and Microeng. (IOP, UK). He is the Associate editor of Journal of

Micro/Nanolithography, MEMS and MOEMS (JM3; SPIE). He serves on steering committee

and technical program committee for various conferences such as Transducers 2015, IEEE

MEMS 2015, IEEE NEMS 2015, IEEE SENSORS 2018, IEEE MEMS 2019 and

Transducers 2019, etc.


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- Keynote talk III (13:00-13:30, July 14)

Muhammad Hajj

George Meade Bond Professor and Chair

Department of Civil, Environmental and Ocean Engineering

Stevens Institute of Technology, USA

Fellow of the Engineering Mechanics Institute

Title: Vibration-based Energy Harvesting: Challenges, Solutions and Opportunities

Abstract: Transforming ambient energy that is otherwise wasted to electric power has evolved into an applied research field that aims at developing technologies to power electronic devices, circuits and wireless networks. Because semiconductors consume milliwatts (mW) in run operation mode and nanowatts (nW) in standby mode, energy harvesting of few mW is considered as an enabling technology that can be used to design self-powered sensors capable of monitoring and controlling a system’s performance, wirelessly transmitting and receiving data, and initiating decision making. A widely available and viable energy source is vibration with the common energy harvester consisting of a structure, transduction element and an electric load. Different aspects of vibration energy harvesters need to be addressed in order to increase their efficiency and power or energy density and implement them to support monitoring devices. Towards achieving that objective, we will discuss the exploitation of nonlinear phenomena to broaden the bandwidth of vibration energy harvesters and their use to support autonomous monitoring. We will present examples to show how such phenomena can be realized through simple variations of the harvesting structure along with examples of effective fluidic energy harvesting from aeroelastic vibrations. We will also discuss challenges and recent advances in the development of wireless ultrasonic vibration energy transmission as an approach to power sensors and devices. Particularly, we present patterning and focusing of the transmitted acoustic energy in space as an approach to simultaneously power distributed sensors or devices.

Biography: Professor Muhammad R. Hajj is the George Meade Bond Professor, Chair of the Department of Civil, Environmental and Ocean Engineering and the Director of the Davidson Laboratory at Stevens Institute of Technology. Dr. Hajj is a renowned scholar in the fields of nonlinear dynamics, fluid mechanics, structural dynamics and fluid-structure interactions with applications in aero- and hydro-elasticity, ships hydrodynamics, biomimetically-inspired air and underwater vehicles, and energy harvesting. To date, he has advised and directed research programs of 26 PhD students who hold prestigious academic and industry positions. He is the author/co-author of over 150 journal publications. Before joining Stevens Institute of Technology in July 2018, Dr. Hajj was the J. Byron Maupin Professor of Engineering and Director of the NSF funded I/UCRC Center for Energy Harvesting Materials and Systems at Virginia Tech where he oversaw the development of industry-directed energy-related science and technology research programs. Dr. Hajj is a Fellow of the Engineering Mechanics Institute and has served as an elected member of its Board of Governors.


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- Keynote talk IV (13:30-14:00, July 14)

Liqun Chen

Professor

Department of Mechanics

Harbin Institute of Technology (Shenzhen), China

Title: Analysis on Vibratory Energy Harvesters via Harmonic Balance

Abstract: The idea of harmonic balance is implemented to analyze nonlinear vibrations of

energy harvester systems. The resulting algebraic equations are numerically solved by the

Newton–Raphson method with the help of the arc-length continuation technique. Both a

traditional harmonic balance approach and an incremental harmonic balance approach are

developed for vibratory energy harvester systems. The two approaches yield the same

results. To handle complicated non-polynomial nonlinearities, an approach based on

harmonic balance with the help of alternating frequency/time domain technique is proposed

for strongly nonlinear vibration energy harvester systems. The proposed approaches are

successfully implemented a nonlinear piezoelectric energy harvester with a magnetic

oscillator and a Duffing type energy harvester with strong nonlinear electric terms. The

harmonic balance solutions are well supported by numerical simulation results. The

approaches are applied to a 1.5 degree-of-freedom model of an energy harvester based on

a piezoelectric circular composite clamped with a proof mass on the plate. System

identifications demonstrate strongly nonlinearities in the model. The experimental results

validate the amplitude-frequency responses predicted by the proposed harmonic balance

approaches, even in the case that there coexist hardening and softening characteristics

under sufficiently large excitations.

Biography: Li-Qun Chen began his university faculty career in Liaoning University of

Science and Technology after receiving his B Sc degree there in 1984. After he obtained

his PhD degree from Shanghai Jiaotong University in 1997, he worked as a postdoc in

Shanghai University. Since 1999, he serves as a full professor there. In 2017, Professor Li-

Qun Chen joined Harbin Institute of Technology (Shenzhen). He is an internationally

recognized researcher in the field of axially moving structures. He is recently interested in

vibratory energy harvesting, vibration reductions, and vibration isolations. He is one of Most

Cited Chinese Researchers since 2014. His honors and awards include National

Outstanding Young Scientist Fund of China (2007), Changjiang Distinguished Professor

(2008), and National Award of Natural Science (2017). He served as Associate Editor-in-

Chief of Chinese Journal of Theoretical and Applied Mechanics, Acta Mechanica Sinica,

and Applied Mathematics and Mechanics (English Edition), and Associate Editor of

Nonlinear Dynamics.


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- Keynote talk V (8:30-9:00 am, July 15)

Elie Lefeuvre

Professor

Center for Nanoscience and Nanotechnology

University of Paris-Sud, France

Title: Biomechanical Energy Harvesting for Medical Implant Applications

Abstract: Active implantable medical devices (AIMD) play an important role in

monitoring, diagnosing and treating patients. In-body medical device development has

been facing an increasingly stronger demand with increases at a pace of 6% yearly.

The current technical challenge in this field is creating smart, small and long-term use

implants that improve the patients’ health and life quality. In this context, while

implanted power sources have been almost exclusively based on traditional batteries,

mechanical energy-harvesting devices exhibit clear advantages and could be used in

many AIMD in the near future. Using the example of the pacemaker, this talk presents

technologies and strategies to efficiently convert mechanical energy into electricity,

highlighting the main challenges that need to be addressed in the particular context of

the human body (low vibration frequency, extreme miniaturization, high reliability) as

well as the technological and methodological evolutions required to move towards

industrialization of implanted biomechanical energy harvesters.

Biography: Elie Lefeuvre has been a Professor with the University of Paris -Sud since

2010. From 2001 to 2007, he was an Associate Professor with the National Institute for

Applied Sciences (Lyon, France), where he conducted research on energy harvesting,

vibration control, and structural health monitoring systems for aerospace applications.

Then, he oriented his work in the field of MEMS, when he was hired by University of

Paris-Sud in 2007. He currently heads the Energy Harvesting research team at the

Center for Nanoscience and Nanotechnology, a joint research unit of the CNRS and

University of Paris-Sud. He has authored more than 160 research papers and patents

on piezoelectric and electrostatic transducers, MEMS and interface circuits for energy

harvesting. His current research focuses in particular on the topic of biomechanical

energy harvesting for pacemaker applications.


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- Keynote talk VI (9:00-9:30 am, July 15)

Wen-Jong WU

Professor

Department of Engineering Science and Ocean Engineering

National Taiwan University, Taiwan

Title: Toward Fully Integrated Self-Power IoT Wireless Sensors in A Package with

Piezoelectric Vibration Energy Harvesting

Abstract: The output power and power density of piezoelectric micro energy harvesters

(PMEH) or so-called MEMS generators have been boosted for around two orders of

magnitude in the past decade. While the power consumption of wireless transceiver and

MEMS sensors getting lower and lower thanks to the advancement of semiconductor

fabrication technologies, the fully integrated self-powered wireless sensors in a package are

not far away from us with upcoming great demand from IoT (internet of things) applications.

The first part of this talk will cover the state-of-the-art piezoelectric energy harvester

technologies from the materials, transducer and packaging perspectives. The second part

of this talk will cover the interfacing and power conversion circuits for piezoelectric vibration

energy harvesters which are also crucial for real applications. The advancement of

interfacing circuits of the past decade and state-of-the-art technologies will be introduced. I

will also highlight the research activities and results of my team in NTU (National Taiwan

University) in recent years. At the end of this talk, the unsolved issues and challenges in the

field toward fully integrated system in a package will also be discussed.

Biography: Wen-Jong Wu is currently Professor of Department of Engineering Science and

Ocean Engineering, National Taiwan University. Wen-Jong Wu got his Ph.D. degree in

Institute of Applied Mechanics from National Taiwan University. He joined Department of

Engineering Science and Ocean Engineering, National Taiwan University as Assistant

Professor since 2003, has been Associate Professor since 2010, and has been Professor

since 2014. From 2007 to 2008, he was with Department of Mechanical and Aerospace

Engineering, Cornell University, NY USA as a visiting assistant professor. He is currently

associate editor of Smart Materials and Structures. His research interests are in

piezoelectric power transducer, vibration energy harvesting, wireless sensor networks, and

flexible electronics.


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3.2 Invited Talks

Fei Wang Associate Professor School of MicroElectronics Southern University of Science and Technology, China

Title: Vibration Energy Harvester with Linear Driven Rotor

Abstract: Recently, rotation kinetic energy has been harvested by electrostatic, piezoelectric and electromagnetic methods. In our daily life, however, linear movement is more popular than the rotational motion. In this presentation, we have demonstrated a new structure based on a linear driven rotor design. This structure could be used efficiently for energy harvesting from low frequency human motion, which could be applicable for both electrostatic and electromagnetic methods.

Lifeng Qin Associate Professor Mechanical and Electrical Engineering Xiamen University, China

Title: A Tunable Wideband Piezoelectric Vibration Energy Harvester for Low-Frequency Environment Using a Novel Impact- and Rope-Driven Hybrid Mechanism

Abstract: Piezoelectric vibration energy harvester (PVEH) transforming vibration energy into electrical power has increasingly been attracting research interest in the recent years. For the real applications, most environmental vibrations occur at a low frequency range (normally below 100 Hz). Hence, the frequency up-conversion (FUC) technique, which can convert low frequency vibrations to high frequency oscillations, is widely used in PVEH. While environmental vibrations are usually variable, and sometimes it may be impossible to achieve a harvester with enough bandwidth to enable practical applications. In addition, owing to the fabrication error, the conventional impact-based FUC PVEH may not have the exact performance as that expected/designed. Thus, a method to conveniently adjust the working frequency of a wideband energy harvester without re-fabrication or damage to the original structure is desirable. In this talk, a tunable FUC wideband PVEH is proposed, which is developed by adopting a novel impact- and rope-driven hybrid mechanism. For the proposed PVEH, the desired performance can be achieved by adding the rope and controlling the rope length without any structure re-fabrication. Thus, this tunable device affords a promising means of working effectively in a variable and complicated low-frequency environment.


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Xiaojing Mu Professor College of Optoelectronic Engineering Chongqing University, China

Title: “Micro” & “Macro” Vibration Energy Harvesters

Abstract: Energy harvesting has been demonstrated as an effective way to harvest vibrational energy to drive wireless electronic devices. There are many forms of vibrational energy in the natural world, such as wind, ocean wave and mechanical vibration. Our group has done some research about mechanism, materials and devices according to the characteristics of the vibration source, utilizing a variety of energy harvesters. We designed the piezoelectric harvester to gather the wind energy on the theory of flow flutter, also extended the method to the triboelectric generator, and achieved the transformation from “Micro” to “Macro”. Recently, we have presented a hybrid nano-generator in according to Bernoulli phenomenon, and make a breakthrough on accomplishing the couple of two thin films. Also, we designed several structures to assemble the wave power successfully. Furthermore, we also did the research of basic theory on materials, utilized the method of plasma and the properties of ferroelectric materials to increase the output power of the triboelectric nano-generator. In summary, these fundamental studies are the cornerstone of the development of energy harvesting technology.

Yunlong Zi

Assistant Professor, Department of Mechanical and Automation Engineering, The Chinese University of Hong Kong, Hong Kong, China

Title: Standardization of Triboelectric Nanogenerators Progress and Perspectives

Abstract: The rapid development of the Internet of Things (IoT) and the increasing energy crisis call for a new type of energy source. Triboelectric nanogenerators (TENGs), which can convert mechanical energies to electricity, develop quickly in recent years and catch more and more people's attention all over the world. Meanwhile, the importance of the standardization for TENG has been emphasized, thus developing standardized theoretical models and experimental methods to quantitatively evaluate the performance becomes more and more important for the commercialization and industrialization of the TENG technology. This presentation will systematically review the origin of the V-Q plot (the standardized characterization tool) and the figure-of-merits (FOM, the standard for quantitatively charactering the energy output per cycle for TENG). Several essential factors which are going to be potentially involved in the standardization for TENGs will also be discussed, including the input energy, efficiency, environmental factors, and life-time assessment. At the same time, the studies about standards may open new research topics in this field. The standardization of TENG will be extremely helpful to understand and improve further applications of this emerging energy harvester. We believe that the standardization of TENG will greatly facilitate the commercialization and industrialization of TENGs in the future.


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Ya Wang Associate Professor Morris E. Foster Faculty Fellow II J. Mike Walker ‘66 Department of Mechanical Engineering Texas A&M University, USA

Title: Nonlinear Resonator Arrays for Energy Harvesting and Earthquake Mitigation

Abstract: Millions of earthquakes occur every year worldwide, which usually throw off a vast amount of vibrational energy at frequencies of 1-20 Hz and weaken or even collapse buildings and other infrastructure that are not resistant to large vibration. Metamaterials, which are usually made from assemblies of multiple control units, have been developed and provided a new way to protect new and/or existing buildings by deviating or trapping the propagation of surface seismic waves away from the structure. However, the energy produced by earthquakes is rarely directly absorbed and harvested. Besides, most of recent researches on earthquake mitigation carried out by employing resonant metamaterials are confined to a narrow frequency. This contrasts the requirements to protect buildings from an earthquake with a rather broader frequency. Building off our previously developed dual function resonator, the proposed nonlinear resonator arrays consist of a set of rectilinear oscillators and rotary oscillators focused on not only mitigating vibrations but also converting the vibrational energy into electricity. Taking the advantage of the nonlinearity we show that by creating arrays of the resonators and burying them under the soil surface, vibrations with a broader bandwidth can be turned into electricity.

Zhiyuan Chen Research Fellow School of Microelectronics Fudan University, China

Title: Fully Integrated Inductor-Less Flipping-Capacitor Rectifiers for Piezoelectric Energy Harvesting

Abstract: Piezoelectric energy harvesting is demanded by the rising market of Internet-of-Everything (IoE) in order to achieve system autonomy or even battery replacement. The conventional synchronized-switch harvesting on-inductor (SSHI) approach relies on bulky external inductors with high quality factor to enhance the extractable AC-DC electrical power limited by the inherent capacitance of the piezoelectric energy harvester. As the new generation IoE continuous push toward miniaturization and higher levels of integration, alternative solutions using on-chip capacitor arrays to replace bulky off-chip inductors are emerging. This presentation discusses the fundamental theory and various capacitor array architectures, including three phase flipping-capacitor rectifier (FCR), seven phase FCR and 21-phase split-phase FCR, to enhance the extractable power from the piezoelectric energy harvester. We will also show how these architectures are evolved, and how their performance is improved step by step.


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Shiquan Fan

Associate Professor School of Microelectronics Xi’an Jiaotong University, China

Title: Vibration Energy Powered Wireless Temperature Sensors for in Power Generation Application

Abstract: We report on developing a low-cost, easy-to-deploy, self-powering wireless sensor node integrated with existing solutions into wireless sensor networks, to monitor the temperature of selected equipment in an industrial power plant (motor, pump, etc.). Each sensor node includes: (a) energy-harvesting device and transducer (made by piezoelectric material); (b) a power management ASIC with cold start function for AC to DC, MPPT, and voltage regulation; (c) temperature sensor; (d) an ultra-low power wireless communication unit using ZigBee protocol. The quiescent current consumption of the system is calibrated to be less than 15 µA (10 µA average current consumption for ZigBee). Multiple sensors in a network communicate with a powered hub unit intermittently while continuously harvesting and storing energy, maintaining always-on operation without external energy input. A robust packaging method is developed for easy installation and facile retrofitting in the relevant industry environment. The temperature information of the equipment is monitored for more than 1 month. We demonstrate that the self-powering wireless sensor node can be implemented in a generic industrial power plant equipment with minimal cost and effort while providing real-time temperature sensing and long-term, continuous monitoring.

Yan Lu Assistant Professor, State Key Laboratory of Analog and Mixed-Signal VLSI Institute of Microelectronics University of Macau, Macau, China

Title: Bi-Directional (Reverse) Wireless Charging

Abstract: Bidirectional (reverse) wireless charging has been adopted recently by major mobile phone makers like Huawei and Samsung. In this talk, two reconfigurable wireless power transceivers, which reuse almost all of the hardware, will be briefly discussed. In particular, a novel cross-connected structure for the differential Class-D power amplifier in the transmitter mode is proposed for reducing the switching losses. Fabricated in 0.35µm standard CMOS process with 5V devices, over 78% battery-to-battery charging total efficiency and over 0.6A wireless charging current are demonstrated with two identical transceiver chips with printed coupling coils on board.


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Chengbin Ma Associate Professor University of Michigan–Shanghai Jiao Tong University Joint Institute (UM-SJTU Joint Institute) Shanghai Jiao Tong University, China

Title: System-Level Design and Optimization of High Efficiency, Low-Noise and Robust MHz WPT Systems

Abstract: Our work on system-level approaches for high performance megahertz (MHz) wireless power transfer (WPT) systems will be described. Operation in the MHz frequency band presents technical challenges due to possible increased power losses, strong nonlinearities of devices, and electromagnetic interference (EMI) problem. Both feedback-based active control and passive design were developed to improve the robustness of the MHz WPT system when the coil relative position and final load changed, the two major sources of uncertainty. The Class E topologies were particularly applied to improve efficiency and facilitate optimization-based designs. Finally, recent efforts on multiple-receiver MHz WPT systems will be mentioned such as design of a current-mode Class E PA, analysis and compensation of cross coupling, and decoupled load power distribution with a scalable number of receivers.

Weiqun Liu Associate Professor School of Mechanical Engineering Southwest Jiaotong University, China

Title: Considerations on the Self-Powered Realization of the Synchronous Switching Circuits

Abstract: To increase the harvested power, many synchronous switching harvesting techniques were developed. For these synchronous switching circuits, the self-powered realization remains a hot topic. A variety of approaches have been studied, including electronic breakers, mechanical switches, velocity control or integrated circuits etc. In the self-powered switching circuits, the switches automatically take actions to invert the piezoelectric voltage based on the information from the peak detectors that the maxima or minima are attained. Therefore, the harvested power is strongly related to the available open-circuit voltage magnitude and the phase lag between the switching actions and the corresponding piezoelectric extrema in the self-powered circuits. Previous studies mainly concerned the phase lag induced by the diode and the transistor in the electronic breaker. However, the envelope resistor and capacitor’s influence are not well analyzed in existed models. In this paper, comprehensive modeling and analysis taking these two factors into consideration are proposed. Investigations show that, the envelope resistor and capacitance affect the switching phase delay and the generator’s open-circuit voltage while considerable additional phase lag is introduced for charging the switch’s parasitic capacitance to turn on the switch.


22

Guangzu Zhang

Associate Professor

School of Optical and Electronic Information

Huazhong University of Science and Technology, China

Title: Flexible Three-Dimensional Interconnected Piezoelectric Ceramic Foam Based Composites for Highly Efficient Concurrent Mechanical and Thermal Energy Harvesting

Abstract: Flexible piezoelectric materials are pivotal to a variety of emerging applications ranging from wearable electronic devices, sensors to biomedical devices. Current ceramic-polymer composites with embedded low-dimensional ceramic fillers, though mechanically flexible, suffer from low piezoelectricity owing to the poor load-transfer efficiency that typically scales with the stiffness ratio of the polymer matrix to the ceramic fillers. Herein we introduce the scalable ceramic-polymer composites based on three-dimensional (3-D) interconnected piezoelectric microfoams. Comprehensive mechanics analyses reveal that the 3-D interconnected architecture presents a continuous pathway for load transfer to break the load-transfer scaling law seen in the conventional composites with low-dimensional ceramic fillers. The 3-D composite exhibits exceptional piezoelectric characteristics under multiple loading conditions (i.e., compression, stretching, and bending) and high mechanical durability under thousands of cycles. It also has excellent pyroelectricity, thereby enabling concurrent thermal and mechanical energy scavenging. Our findings suggest an innovative material framework for high-performance energy harvesters and self-powered micromechanical devices.


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3.3 Technical Program

Day 1: July 14, 2019

8:30-9:00 Opening Remark & Group Photo

Jie Yin (Provost of ShanghaiTech University)

9:00-9:30 Keynote Talk I (Session Chairs: Fei Wang)

Broadband Energy Harvesting and Generation with Piezoelectric Transduction

Eric Yeatman (Imperial College London)

9:30-10:00 Keynote Talk II (Session Chairs: Huicong Liu)

Progress and Applications of Energy Harvesting Technology

Chengkuo Lee (National University of Singapore)

10:00-10:20 Coffee Break

10:20-11:35 Oral Session A: MEMS (Session Chairs: Kai Tao, Tao Wu)

- Invited Talk (10:20-10:35): Vibration Energy Harvester with Linear Driven

Rotor

Fei Wang (Southern University of Science and Technology)

- Invited Talk (10:35-10:50): A Tunable Wideband Piezoelectric Vibration

Energy Harvester for Low-Frequency Environment Using a Novel Impact- and

Rope-Driven Hybrid Mechanism

Lifeng Qin (Xiamen University)

- Invited Talk (10:50-11:05): “Micro” & “Macro” Vibration Energy Harvesters

Xiaojing Mu (Chongqing University)

- Invited Talk (11:05-11:20): Standardization of Triboelectric Nanogenerators:

Progress and Perspectives

Yunlong Zi (The Chinese University of Hong Kong)

- Oral Presentation (11:20-11:35): T06 A Rotational Electromagnetic-

Triboelectric Hybrid Generator for Harvesting Low-Frequency and Irregular

Ocean Wave Energy

Cheng Hou, Huicong Liu, Yunfei Li, Manjuan Huang, Tao Chen, and Lining

Sun (Soochow University)

11:35-13:00 Lunch Break (Western-Style Dining Hall) / TPC meeting (1A-200)

13:00-13:30 Keynote Talk III (Session Chair: Zhimiao Yan)

Vibration-based Energy Harvesting: Challenges, Solutions, and Opportunities

Muhammad Hajj (Stevens Institute of Technology)


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13:30-14:00 Keynote Talk IV (Session Chair: Zhengbao Yang)

Analysis on Vibratory Energy Harvesters via Harmonic Balance

Liqun Chen (National University of Singapore)

14:00-15:15 Oral Session B: Structures – Nonlinearity

(Session Chairs: Minghui Yao, Junyi Cao)

- Invited Talk (14:00-14:15): Nonlinear Resonator Arrays for Energy

Harvesting and Earthquake Mitigation

Ya Wang (Texas A&M University)

- Oral Presentation (14:15-14:30): Nonlinear Effects in Energy Harvesting

Systems

Zhengbao Yang (City University of Hong Kong)

- Oral Presentation (14:30-14:45): S08 A Twisting Vibration-Based Energy

Harvester for Ultra-Low Frequency Excitations

Kangqi Fan, Hengheng Qu, and Meiling Cai (Xidian University)

- Oral Presentation (14:45-15:00): C11 Impedance Modeling and

Applications of a Bidirectional Energy Conversion Circuit for Realizing the

Dual Tasks of Energy Harvesting and Vibration Exciting

Bao Zhao, Jiahua Wang, Junrui Liang, and Wei-Hsin Liao

(ShanghaiTech University & The Chinese University of Hong Kong)

- Oral Presentation (15:00-15:15): S07 An Internal Resonances Based

Piezoelectric Harvester with High-Frequency Up-Converting Factor

Chunbo Lan, Lihua Tang, Guobiao Hu, and Weiyang Qin

(Nanjing University of Aeronautics and Astronautics)

15:15-15:30 IEEE Industrial Electronics Society Shanghai Chapter

Outreaching

Chengbin Ma, IEEE IES Shanghai Chapter Chair

15:30-16:45 Poster Session & Coffee Break

(Session Chair: Xiaoqing Zhang, Hao Ren)

40 speakers will present their research papers during the poster session,

including those participating in the Student Poster Competition. The list of the

poster papers is provided in Session 4 (poster paper list).

16:45-18:30 Oral Session C: Circuits (Session Chairs: Haoyu Wang, Minfan Fu)

- Invited Talk (16:45-17:00): System-Level Design and Optimization of High

Efficiency, Low-Noise and Robust MHz WPT Systems

Weiqun Liu (Southwest Jiaotong University)

- Invited Talk (17:00-17:15): Fully Integrated Inductor-Less Flipping-

Capacitor Rectifiers for Piezoelectric Energy Harvesting

Zhiyuan Chen (Fudan University)


25

- Invited Talk (17:15-17:30): Vibration Energy Powered Wireless

Temperature Sensors for in Power Generation Application

Shiquan Fan (Xi’an Jiaotong University)

- Invited Talk (17:30-17:45): Considerations on the Self-Powered Realization

of the Synchronous Switching Circuits

Chengbin Ma (Shanghai Jiao Tong University)

- Invited Talk (17:45-18:00): Bidirectional (Reverse) Wireless Charging

Yan Lu (University of Macau)

- Oral Presentation (18:00-18:15): C05 Design of Energy Harvesting Circuit

for Self-Powered Multi-Channel Series and Parallel Dual-Synchronous

Switch

Zhou Tianshuo, Gong Lijiao, Zhao Chunming, and Li Yibo

(Shihezi University)

- Oral Presentation (18:15-18:30): C04 A Multi-Bias Parallel SSHI Rectifier

for Piezoelectric Energy Harvesting

Liao Wu (Changsha University)

18:30-20:30 Conference Dinner (Staff Dining Hall) & Award Ceremony

Day 2: July 15, 2019

8:30-9:00 Keynote Talk V (Session Chair: Weiqun Liu)

Biomechanical Energy Harvesting for Medical Implant Applications

Elie Lefeuvre (University of Paris-Sud)

9:00-9:30 Keynote Talk VI (Session Chair: Ya Wang)

Toward Fully Integrated Self-Power IoT Wireless Sensors in A Package with

Piezoelectric Vibration Energy Harvesting

Wen-Jong Wu (National Taiwan University)

9:30-9:50 Coffee Break

9:50-11:05 Oral Session D: Applications

(Session Chair: Kailiang Ren, Kangqi Fan)

- Invited Talk (9:50-10:05): Flexible Three-Dimensional Interconnected

Piezoelectric Ceramic Foam Based Composites for Highly Efficient

Concurrent Mechanical and Thermal Energy Harvesting

Guangzu Zhang (Huazhong University of Science and Technology)


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- Oral Presentation (10:05-10:20): A09 Energy Harvesting Applications

Using Piezoelectric Materials and Electret Based Nanogenerator

Shaobo Gong, Jinxi Zhang, Aochen Wang, and Kailiang Ren

(Beijing Institute of Nanoenergy and Nanosystems, Chinese Academy of

Sciences)

- Oral Presentation (10:20-10:35): A03 TENG Based Pressure Sensor for

Continuous Measurement of Human Arterial Pulse Wave

Keyu Meng and Jin Yang (Chongqing University)

- Oral Presentation (10:35-10:50): T02 Remarkable Merits of Triboelectric

Nanogenerator than Electromagnetic Generator for Harvesting Small-

Amplitude Mechanical Energy

Junqing Zhao, Gaowei Zhen, and Chi Zhang (Beijing Institute of

Nanoenergy and Nanosystems, Chinese Academy of Sciences)

- Oral Presentation (10:50-11:05): T04 Bipolar-Charged Micro Electret

Power Generator

Binqiao Wang, Kai Tao, Yixin Chen, and Honglong Chang

(Northwestern Polytechnical University)

11:05-11:50 Oral Session E: Structure – EH from Fluids

(Session Chairs: Shengxi Zhou)

- Oral Presentation (11:05-11:20): S18 Performance Analysis of

Piezoelectric-Electromagnetic Composite Energy Harvester with Vortex-

Induced Vibration

Chengwei Hou, Rujun Song, and Xiaohui Yang

(Shandong University of Technology)

- Oral presentation (11:20-11:35): S22 Low-Velocity Water Flow Energy

Harvesting Based on VIV and Galloping

Zhimiao Yan, Weipeng Sun, and Ting Tan (Shanghai Jiao Tong

University)

- Oral presentation (11:35-11:50): S25 Magnetically Coupled Flextensional

Transducer for Underwater Vibration Energy Harvesting

Hong-Xiang Zou, Lin-Chuan Zhao, Ke-Xiang Wei, and Wen-Ming Zhang

(Hunan Institute of Engineering)

11:50-13:10 Lunch Break (Western-Style Dining Hall)

13:10-14:25 Oral Session F: Structure – EH from Winds

(Session Chairs: Weiyang Qin, Chengliang Pan)

- Oral Presentation (13:10-13:25): Development of High-Performance Wind

Energy Harvesters for Self-Powered Wireless Sensor Nodes Application

Huicong Liu (Soochow University)


27

- Oral Presentation (13:25-13:40): S13 Scavenging Wind Energy by a

Dynamic-Stable Flutter Energy Harvester with Rectangular Wing

Zhiyong Zhou, Weiyang Qin, and Wangzheng Deng


- Oral Presentation (13:40-13:55): S20 A Novel Design of Electromagnetic

Wind Energy Harvesting from Galloping

Zhang Lan-Bin, Dai Hu-Liang, Wang Lin

(Huazhong University of Science and Technology)

- Oral Presentation (13:55-14:10): S09 Experimental Investigation on A

Novel Airfoil Wing-Based Piezoelectric Energy Harvester for Harvesting from

Aeroelastic Vibration

Xiaobiao Shan, Haigang Tian, Han Cao, and Tao Xie

(Harbin Institute of Technology)

- Oral Presentation (14:10-14:25): S01 Piezoelectric Wind Energy

Harvesting from Galloping Oscillation of Right-Angle Cantilever Beam

Cheng-Liang Pan, Jing Zhang, and Hong-Bin Wang

(Hefei University of Technology)

14:25-15:10 Oral Session G: Structure – Metamaterials

(Session Chairs: Jiawen Xu, Chunbo Lan)

- Oral Presentation (14:25-14:40): S11 Meta-Plate Structure for

Simultaneous Vibration Control and Acoustic Energy Harvesting

Ming Yuan, Ziping Cao, Xiao Sheng, and Jun Luo

(Nanjing University of Posts and Telecommunications)

- Oral Presentation (14:40-14:55): S12 Theoretical Modeling and

Experimental Verification of a Variable Reluctance Energy Harvester

Hongyu Zhu, Junyi Cao, and Ying Zhang (Xi’an Jiaotong University)

- Oral Presentation (14:55-15:10): S26 Enhanced Elastic Wave Energy

Harvesting by Piezoelectric Metamaterial

Jiawen Xu, Hongyan Wang, and Ruqiang Yan (Southeast University)

15:10-16:10 Panel Discussion (Session Chair: Wei-Hsin Liao)

The Keynote Speakers will share their ideas with the audiences towards the

future development of energy harvesting technologies.

16:10-16:40 Coffee Break & Farewell


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4. Poster Papers List

A01 Enhancing Vehicle Suspension Dynamics Using Semi-Active Energy-

Harvesting Shock Absorber

Qiuchi Xiong, Bonan Qin, Hongjip Kim, Yuzhe Chen, and Lei Zuo

(Virginia Tech)

A02 Research on Energy Recovery System of Lithium Lon Supercapacitor in Rail

Transit

Liwei Dong, Haiquan Liang, Jingtai Hu, Ting Wu, and Yufei Chen

(Tongji University)

A04 Triboelectric Vibration Sensor for a Human-Machine Interface Built on

Ubiquitous Surfaces

Qiang He and Jin Yang (Chongqing University)

A05 A Self-Powered Wireless Sensor Network for Security Fence Monitoring by A

High-Performance Wind Energy Harvester

Yan Fang, Jiankang Zhang, Huicong Liu, Tao Chen, and Lining Sun

(Soochow University)

A06 Study of a Piezoelectric Energy Harvesting Floor Structure with Force

Amplification Mechanism

He Ming, Wang Sheng, Zhong Xiang, Zheng Shuxian, and Mingjie Guan

(Xiamen University)

A07 Smart Energy Harvester for Capturing Ankle Negative Work

Mingjing Cai and Wei-Hsin Liao (The Chinese University of Hong Kong)

A08 Piezoelectric Energy Harvesting for Rotor Applications

Liufeng Zhang, Zhaoye Qin, and Fulei Chu (Tsinghua University)

A10 ViPSN: A Vibration-Powered Sensing Node

Xin Li, Li Teng, and Junrui Liang (ShanghaiTech University)

C03 Vibration Energy Harvesting Based PCB Integrated Micro-Electric Generator

Zhijie Feng, Jiahua Chen, and Han Peng


C06 A Portable Piezoelectric Energy Harvesting Self-Powered Design

Yibo Li, Lijiao Gong, Chunming Zhao, and Tianshuo Zhou (Shihezi University)

C07 Reconfigurable Synchronous Switching Interface Circuits for Piezoelectric

Energy Harvesting

Chun-Yu Chen, Wei-Ting Shih, and Wen-Jong Wu (National Taiwan University)

C08 A Simple Voltage Trigger Circuit for Vibration Energy Harvester

Zhao Xingqiang, Li Feng, Yu Hanfei, Cai Jun, and Ding Yu

(Nanjing University of Information and Science)


29

C09 Two Power Management Circuits to Supply Energy for an Electric Ink Screen

with Humid and Temperature Sensor

Gang Shi, Meihua Wang, and Fei Wang

(Southern University of Science and Technology)

C10 A Theoretical Model of Piezoelectric Energy Harvesting Plates with a RL

Resonant Circuit

Yu Chen, Zhichun Yang, and Shengxi Zhou


S03 Nonlinear Cantilever Generator with Stiffness Characteristics Customized by

Curve Fixtures

Zhongxin Yuan and Weiqun Liu (Southwest Jiaotong University)

S04 Acoustic Energy Harvesting with Irradiated Cross-Linked Polypropylene

Piezoelectret Films

Yuan Xue, Jinfeng Zhao, Xiaoqing Zhang, Gerhard M. Sessler, and Mario

Kupnik (Tongji University)

S10 System Identifications of Nonlinear Electromagnetic Vibration Energy

Harvesters

Tian-Chen Yuan, Jian Yang, and Rui-Gang Song

(Shanghai University of Engineering Science)

S14 Wind Energy Harvesting Using Macro Fiber Composites Based on Flutter Mode

JianJun Liu, Xianghua Chen, Wei Xia, and Qun Li (Xi’an Jiaotong University)

S16 A Two-Dimensional Vibration Energy Harvester with Radially Distributed PVDF

Piezoelectric Array

Xing Liu, Haibo Zhao, Xiaozhou Zhang, Yiming Zhong, Xiaoxiang Wei, and

Peihong Wang (Anhui University)

S17 A Nonlinear Piezoelectric Energy Harvester with Bidirectional Magnetic

Excitation

Man Wang, Rujun Song, and Xiaohui Yang

(Shandong University of Technology)

S21 A Piezoelectric-Electromagnetic Rotational Harvester for Wind Energy in Harsh

Environment

Lin-Chuan Zhao, Hong-Xiang Zou, and Wen-Ming Zhang

(Shanghai Jiao Tong University)

S23 Attaining the High-Energy Orbit of Nonlinear Energy Harvesters by Load

Perturbation

Jiahua Wang and Wei-Hsin Liao (The Chinese University of Hong Kong)

S24 High-Performance Flexible Piezoelectric Buckled-Bridge Rational Energy

Harvesting Strategy for Ultra-Low Frequency Ambient

Zhiran Yi, Lingchao Kong, Yingwei Tian, Xiaoxue Dong, and Bin Yang

(Shanghai Jiao Tong University)


30

S27 Investigation on Rotational Mechanical Plucking Energy Harvester

Fang Shitong, Fu Xinlei, and Wei-Hsin Liao

(The Chinese University of Hong Kong)

S28 A Four-Quadrant Semi-Active Energy Harvester

Chen Gen and Bai Xian-Xu (Hefei University of Technology)

S29 Piezoelectric Power Micro Power Supply for Laser Pen

Zhao Chunming, Gong Lijiao, Zhou Tianshuo, and Li Yibo (Shihezi University)

S30 Flexible Three-Dimensional Interconnected Piezoelectric Ceramic Foam Based

Composites for Highly Efficient Concurrent Mechanical and Thermal Energy

Harvesting

Guangzu Zhang, Shenglin Jiang, and Qing Wang


S31 Multi-Stable Vibration Energy Harvesters: Design, Analysis and Application

Shengxi Zhou (Northwestern Polytechnical University)

S33 Nonlinear Magnetic-Coupled Flutter-based Aeroelastic Energy Harvester

Kui Li, Zhichun Yang, Yingsong Gu, Shun He, and Shengxi Zhou


S34 Snap-Through Criterion for An Energy Harvester with An Asymmetric Triple

Potential Well

Hai-tao Li, Hu Ding, Li-Qun Chen, Wei-Yang Qin

(Shanghai University & North University of China)

S35 Extended Impedance Modeling of Piezoelectric Energy Harvesting System

under Various Excitations

Yiming Gao and Junrui Liang (ShanghaiTech University)

M02 Design and Process of Lithium Niobate Resonator

Jinbo Wu and Tao Wu (ShanghaiTech University)

M03 Two-Dimensional Couple Piezoelectric Mems Resonator Apply for 5G

Communication

Kangfu Liu, Tao Wu, and Junrui Liang (ShanghaiTech University)

M04 Piezoelectric ZnO Thin Films for Multimodal Mems Vibrational Energy

Harvesting

Kai Tao, Lihua Tang, and Honglong Chang


M05 The Fabrication of Si-Nanowires FET and its Application in the Sensors

Yipeng Liu and Tao Wu (ShanghaiTech university)

M06 Simulation And Experiment Of Magnetoelectric Gyration Effect in Tb1-

xDyxFe2-y /Pb(Zr,Ti)O3 Laminated Composites

Wangyuxi, Luozhifang, and Tao Wu (ShanghaiTech University)


31

M07 Pmuts FEM Simulation in Air Environment

Sheng Wu and Tao Wu (ShanghaiTech University)

M08 Electret based Vibration Energy Harvester with Integrated Silicon Tips Used for

Corona Charging

Yujiang Guan, Yulong Zhang, and Fei Wang (Southern University of Science)

M09 A High Sensitivity Piezoelectric MEMS Accelerometer Based on Aerosol

Deposition Method

Xuewen Gong, Chao-Ting Chen, Wen-Jong Wu, and Wei-Hsin Liao

(The Chinese University of Hong Kong)

T01 A Highly Thermostable Silicon Dioxide Composited BNT-BZT Lead-Free

Porous Ceramics for Pyroelectricl Energy Harvesting

Meng Shen, Mingyu Li, Guangzu Zhang, and Shenglin Jiang


T03 A Scalable Ultral-thin Paper-templated PZT Foam Composite

Ying Hong and Zhengbao Yang (City University of Hong Kong)

T05 Electrostatic Vibration Energy Harvester Based on Negatively Charged

Stretchable FEP Electret Films

Xingchen Ma, Xiaoqing Zhang, Gerhard M. Sessler, Li Chen, Xiaoya Yang,

Ying Dai, and Pengfei He (Tongji University)

T07 Improvement of Uneven Output Power Distribution in Piezoelectric Circular

Diaphragm for Vibration Energy Harvesting,

Yu Han, Liwei Chen, and Tongqing Yan (Tongji University)


32

5. Contacts

Name 姓名 Affiliation 单位 Email Role

Jie Yin 印杰 ShanghaiTech University 上海科技大学 -- ShanghaiTech Provost

Jinyi Yu 虞晶怡 ShanghaiTech University 上海科技大学 [email protected] SIST Vice Dean

Yu Zhou 周宇 ShanghaiTech University 上海科技大学 [email protected] SIST Vice Dean

Prof. Xinxin Li 李昕欣 Shanghai Institute of Microsystem and Information Technology, CAS 中科院上海微系统所 [email protected] Honorary Chair

Wei-Hsin Liao 廖维新 The Chinese University of Hong Kong 香港中文大学 [email protected] Honorary Chair

Junrui Liang 梁俊睿 ShanghaiTech University 上海科技大学 [email protected] General Chair

Huicong Liu 刘会聪 Soochow University 苏州大学 [email protected] General Co-Chair

Zhengbao Yang 杨征保 City University of Hong Kong 香港城市大学 [email protected] General Co-Chair

Haoyu Wang 王浩宇 ShanghaiTech University 上海科技大学 [email protected] Local Chair

Tao Wu 吴涛 ShanghaiTech University 上海科技大学 [email protected] Local Chair

Xiaoqing Zhang 张晓青 Tongji University 同济大学 [email protected] Local Chair

Liqun Chen 陈立群 Harbin Institute of Technology 哈尔滨工业大学（深圳） [email protected] Keynote Speaker

Chengkuo Lee 李成国 National University of Singapore 新加坡国立大学 [email protected] Keynote Speaker

Wen-Jong Wu 吴文中 National Taiwan University 国立台湾大学 [email protected] Keynote Speaker

Muhammad Hajj -- Stevens Institute of Technology 斯蒂文斯理工学院 [email protected] Keynote Speaker

Elie Lefeuvre -- University of Paris-Sud 巴黎第十一大学 [email protected] Keynote Speaker

Eric Yeatman -- Imperial College London 帝国理工学院 [email protected] Keynote Speaker

Zhiyuan Chen 陈之原 Fudan University 复旦大学 [email protected] Invited Speaker

Shiquan Fan 范世全 Xi'an Jiaotong University 西安交通大学 [email protected] Invited Speaker

Weiqun Liu 刘伟群 Southwest Jiaotong University 西南交通大学 [email protected] Invited Speaker

Xiaojing Mu 牟笑静 Chongqing University 重庆大学 [email protected] Invited Speaker

Lifeng Qin 秦利锋 Xiamen University 厦门大学 [email protected] Invited Speaker

Fei Wang 汪飞 Southern University of Science and Technology 南方科技大学 [email protected] Invited Speaker

Ya Wang 王娅 Texas A&M University 德克萨斯 A&M 大学 [email protected] Invited Speaker

Guangzu Zhang 张光祖 Huazhong University of Science and Technology 华中科技大学 [email protected] Invited Speaker

Yunlong Zi 訾云龙 Chinese University of Hong Kong 香港中文大学 [email protected] Invited Speaker

Zhongsheng Chen 陈仲生 Hunan University of Technology 湖南工业大学 [email protected] WeChat Group Founder

Junyi Cao 曹军义 Xi'an Jiaotong University 西安交通大学 [email protected] Committee

Kangqi Fan 樊康旗 Xidian University 西安电子科技大学 [email protected] Committee

Weiyang Qin 秦卫阳 Northwestern Polytechnical University 西北工业大学 [email protected] Committee

Lin Wang 王琳 Huazhong University of Science and Technology, China 华中科技大学 [email protected] Committee

Bin Yang 杨斌 Shanghai Jiao Tong University 上海交通大学 [email protected] Committee

Minghui Yao 姚明辉 Tianjin Polytechnic University, China 天津工业大学 [email protected] Committee

Wenming Zhang 张文明 Shanghai Jiao Tong University 上海交通大学 [email protected] Committee

Zhigang Shao 邵志刚 Cinv Optics Ltd. Co. 西努光学 [email protected] Sponsor

Huifeng Song 宋慧锋 Cinv Optics Ltd. Co. 西努光学 -- Sponsor

Shenqi Xie 谢申奇 Lyncée Tec -- [email protected] Sponsor

Xiang Yu 俞翔 Rotron Technology 欧创科技 [email protected] Sponsor

Junhua Zhang 张俊华 Cinv Optics Ltd. Co. 西努光学 -- Sponsor

Xianxu Bai 白先旭 Hefei University of Technology 合肥工业大学 [email protected] Participant

Mingjing Cai 蔡明京 Chinese University of Hong Kong 香港中文大学 [email protected] Participant

Gen Chen 陈根 Hefei University of Technology 合肥工业大学 [email protected] Participant

Jiahua Chen 陈佳桦 Huazhong University of Science and Technology 华中科技大学 [email protected] Participant

Nan Chen 陈楠 Northwestern Polytechnical University 西北工业大学 [email protected] Participant

Xianghua Chen 陈祥华 Xi'an Jiaotong University 西安交通大学 [email protected] Participant

Yu Chen 陈宇 Northwestern Polytechnical University 西北工业大学 [email protected] Participant

Junyu Chen 陳俊宇 National Taiwan University 国立台湾大学 [email protected] Participant

Yan Fang 房艳 Suzhou University 苏州大学 [email protected] Participant

Zhijie Feng 冯志杰 Huazhong University of Science and Technology 华中科技大学 [email protected] Participant

Xuewen Gong 龚雪文 Chinese University of Hong Kong 香港中文大学 [email protected] Participant

Mingjie Guan 关明杰 Xiamen University 厦门大学 [email protected] Participant

Yujiang Guan 管宇江 Southern University of Science and Technology 南方科技大学 [email protected] Participant

Jianping Guo 郭建平 Sun Yat-Sen University 中山大学 [email protected] Participant

Sizhen Guo 郭思婧 Wuhan University of Technology 武汉理工大学 [email protected] Participant

Yu Han 韩煜 Tongji University 同济大学 [email protected] Participant

Chaoping He 何超平 Guangdong Chlorop Technology Co., Ltd. 广东顺德智勤科技有限公司 [email protected] Participant

Ying Hong 洪颖 City University of Hong Kong 香港城市大学 [email protected] Participant

Chengwei Hou 侯成伟 Shandong University of Technology 山东理工大学 [email protected] Participant

Cheng Hou 侯诚 Suzhou University 苏州大学 [email protected] Participant

Wenbin Huang 黄文彬 Chongqing University 重庆大学 [email protected] Participant

Zhenyu Huang 黄震宇 Shanghai Jiao Tong University 上海交通大学 [email protected] Participant

Zhihui Lai 赖志慧 Shenzhen University 深圳大学 [email protected] Participant

Chunbo Lan 蓝春波 Nanjing University of Aeronautics and Astronautics 南京航空航天大学 [email protected] Participant

Haitao Li 李海涛 North University of China 中北大学 [email protected] Participant

Hongjun Li 李宏军 CETC No.13 Institute 中国电科第十三研究所 [email protected] Participant

Kui Li 李魁 Northwestern Polytechnical University 西北工业大学 [email protected] Participant

Ze Li 李泽 Northwestern Polytechnical University 西北工业大学 [email protected] Participant

Fengrui Liu 刘丰瑞 Shanghai Jiao Tong University 上海交通大学 [email protected] Participant

Jianjun Liu 刘建军 Xi'an Jiaotong University 西安交通大学 [email protected] Participant

Xing Liu 刘星 Anhui University 安徽大学 [email protected] Participant

Jianhua Lu 卢健华 Guangdong Chlorop Technology Co., Ltd. 广东顺德智勤科技有限公司 [email protected] Participant

Lijun Lu 路礼军 Shanghai Jiao Tong University 上海交通大学 [email protected] Participant

Kejing Ma 马珂婧 Shanghai Jiao Tong University 上海交通大学 [email protected] Participant

Xingchen Ma 马星晨 Tongji University 同济大学 [email protected] Participant

Fangyu Mao 毛方玉 University of Macau 澳门大学 [email protected] Participant

He Mao 毛贺 Shenzhen Institute of Advanced Technology, CAS 中科院深圳先进技术研究院 [email protected] Participant

Su Ouyang 欧阳溯 Xiamen University 厦门大学 [email protected] Participant

Chengliang Pan 潘成亮 Hefei University of Technology 合肥工业大学 [email protected] Participant

Han Peng 彭晗 Huazhong University of Science and Technology 华中科技大学 [email protected] Participant

Kailiang Ren 任凯亮 Beijing Institute of Nanoenergy and Nanosystems, CAS 北京纳米能源与系统研究所 [email protected] Participant

XIAOBIAO Shan 单小彪 Harbin Institute of Technology 哈尔滨工业大学 [email protected] Participant


33

Name 姓名 Affiliation 单位 Email Role

Hui Shen 沈辉 Qingdao University 青岛大学 [email protected] Participant

Guangwei Shi 时光炜 Shanghai Jiao Tong University 上海交通大学 [email protected] Participant

Meng Su 苏萌 Northwestern Polytechnical University 西北工业大学 [email protected] Participant

Weipeng Sun 孙维鹏 Xi'an University of Technology 西安理工大学 [email protected] Participant

Ting Tan 谭婷 Shanghai Jiao Tong University 上海交通大学 [email protected] Participant

Kai Tao 陶凯 Northwestern Polytechnical University 西北工业大学 [email protected] Participant

Haigang Tian 田海港 Harbin Institute of Technology 哈尔滨工业大学 [email protected] Participant

Jiahua Wang 汪家华 Chinese University of Hong Kong 香港中文大学 [email protected] Participant

Guangqing Wang 王光庆 Zhejiang Gongshang University 浙江工商大学 [email protected] Participant

Junlei Wang 王军雷 Zhengzhou University 郑州大学 [email protected] Participant

Man Wang 王曼 Shandong University of Technology 山东理工大学 [email protected] Participant

Peihong Wang 王佩红 Anhui University 安徽大学 [email protected] Participant

Wei Wang 王炜 Tianjin University 天津大学 [email protected] Participant

Xiaoxiang Wei 魏孝祥 Anhui University 安徽大学 [email protected] Participant

Liao Wu 吴了 Changsha University 长沙学院 [email protected] Participant

Tao Xie 谢涛 Harbin Institute of Technology 哈尔滨工业大学 [email protected] Participant

Zhengqiu Xie 谢正邱 Chongqing University 重庆大学 [email protected] Participant

Jiawen Xu 徐佳文 Southeast University 东南大学 [email protected] Participant

Zhiwei Yan 颜志淼 Shanghai Jiao Tong University 上海交通大学 [email protected] Participant

Fan Yang 杨帆 Xiamen University 厦门大学 [email protected] Participant

Tongqing Yang 杨同青 Tongji University 同济大学 [email protected] Participant

Zhiran Yi 易志然 Shanghai Jiao Tong University 上海交通大学 [email protected] Participant

Weiwei Yu 于炜炜 Huada Semiconductor Co., LTD. 华大半导体 [email protected] Participant

Ming Yuan 袁明 Nanjing University of Posts and Telecommunications 南京邮电大学 [email protected] Participant

Tianchen Yuan 袁天辰 Shanghai University of Engineering Science 上海工程技术大学 [email protected] Participant

Zhongxin Yuan 袁忠鑫 Southwest Jiaotong University 西南交通大学 [email protected] Participant

Bin Zhang 张斌 Shandong University (Weihai) 山东大学(威海) [email protected] Participant

Jinhui Zhang 张金惠 Xiamen University 厦门大学 [email protected] Participant

Liufeng Zhang 张刘锋 Tsinghua University 清华大学 zhang [email protected] Participant

Zhonghua Zhang 张忠华 Zhejiang Normal University 浙江师范大学 [email protected] Participant

Chunming Zhao 赵春明 Shihezi University 石河子大学 [email protected] Participant

Junqing Zhao 赵俊青 Beijing Institute of Nanoenergy and Nanosystems, CAS 北京纳米能源与系统研究所 [email protected] Participant

Linchuan Zhao 赵林川 Shanghai Jiao Tong University 上海交通大学 [email protected] Participant

Xiang Zhao 赵翔 Southwest Petroleum University 西南石油大学 [email protected] Participant

Xingqiang Zhao 赵兴强 Nanjing University of Information Science and Technology 南京信息工程大学 [email protected] Participant

Shengxi Zhou 周生喜 Northwestern Polytechnical University 西北工业大学 [email protected] Participant

Tianshuo Zhou 周天烁 Shihezi University 石河子大学 [email protected] Participant

Zhenhua Zhou 周振华 Changsha University of Science and Technology 长沙理工大学 [email protected] Participant

Zhiyong Zhou 周志勇 Henan University 河南大学 [email protected] Participant

Hongyu Zhu 朱红宇 Xi'an Jiaotong University 西安交通大学 [email protected] Participant

Hongxiang Zou 邹鸿翔 Shanghai Jiao Tong University 上海交通大学 [email protected] Participant

Lei Zuo 左磊 Virginia Polytechnic Institute 弗吉尼亚理工大学 [email protected] Participant

Smita Sahu -- Shanghaitech University 上海科技大学 [email protected] Local Participant

Minfan Fu 傅旻帆 Shanghaitech University 上海科技大学 [email protected] Local Participant

Qingjie Guo 郭庆杰 Shanghaitech University 上海科技大学 [email protected] Local Participant

Peiqing Han 韩佩卿 Shanghaitech University 上海科技大学 [email protected] Local Participant

Xiaoyu Jiang 蒋晓宇 Shanghaitech University 上海科技大学 [email protected] Local Participant

Sijie Li 李思杰 Shanghaitech University 上海科技大学 [email protected] Local Participant

Baoying Liu 刘宝英 Shanghaitech University 上海科技大学 [email protected] Local Participant

Fang Liu 刘芳 Shanghaitech University 上海科技大学 [email protected] Local Participant

Kaiyan Liu 刘凯艳 Shanghaitech University 上海科技大学 [email protected] Local Participant

Yu Liu 刘宇 Shanghaitech University 上海科技大学 [email protected] Local Participant

Xiaolin Lu 鲁晓琳 Shanghaitech University 上海科技大学 [email protected] Local Participant

Kunyong Lu 吕坤勇 Shanghaitech University 上海科技大学 [email protected] Local Participant

Ke Ma 马可 Shanghaitech University 上海科技大学 [email protected] Local Participant

Hao Ren 任豪 Shanghaitech University 上海科技大学 [email protected] Local Participant

Shiying Wang 王世颖 Shanghaitech University 上海科技大学 [email protected] Local Participant

XinChen Wang 王鑫辰 Shanghaitech University 上海科技大学 [email protected] Local Participant

Wang Xuejun 王雪君 Shanghaitech University 上海科技大学 [email protected] Local Participant

Wang Yuetong 王月桐 Shanghaitech University 上海科技大学 [email protected] Local Participant

Shuai Wu 吴帅 Shanghaitech University 上海科技大学 [email protected] Local Participant

Jiangting Xia 夏江婷 Shanghaitech University 上海科技大学 [email protected] Local Participant

Qun Yang 杨群 Shanghaitech University 上海科技大学 [email protected] Local Participant

Jicong Zhang 张继聪 Shanghaitech University 上海科技大学 [email protected] Local Participant

Xiangyu Zhang 张湘煜 Shanghaitech University 上海科技大学 [email protected] Local Participant

Zepeng Zhang 张泽鹏 Shanghaitech University 上海科技大学 [email protected] Local Participant

Zehao Zhao 赵泽浩 Shanghaitech University 上海科技大学 [email protected] Local Participant

Hongtao Zhong 钟鸿涛 Shanghaitech University 上海科技大学 [email protected] Local Participant

Jingying Chen 陈晶莹 ShanghaiTech University 上海科技大学 [email protected] Staff

Linglong Gao 高玲珑 ShanghaiTech University 上海科技大学 [email protected] Staff

Yiming Gao 高一鸣 ShanghaiTech University 上海科技大学 [email protected] Staff

Yongji Gao 高永基 ShanghaiTech University 上海科技大学 [email protected] Staff

Xin Li 李鑫 ShanghaiTech University 上海科技大学 [email protected] Staff

Yichao Liu 刘义超 ShanghaiTech University 上海科技大学 [email protected] Staff

Hong Tang 汤鸿 ShanghaiTech University 上海科技大学 [email protected] Staff

Li Teng 滕雳 ShanghaiTech University 上海科技大学 [email protected]> Staff

Ying Xue 薛颖 ShanghaiTech University 上海科技大学 [email protected] Staff

Shuai Zhang 张帅 ShanghaiTech University 上海科技大学 [email protected] Staff

Yang Zhang 张杨 ShanghaiTech University 上海科技大学 [email protected] Staff

Bao Zhao 赵宝 ShanghaiTech University 上海科技大学 [email protected] Staff

The 2 International Conference on Applicationsveh2019.shanghaitech.edu.cn/VEH2019_program.pdf ·...

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