Jinhao Qiu scite author profile

Jinhao Qiu

5Publications

372Citation Statements Received

94Citation Statements Given

How they've been cited

692

366

How they cite others

144

Affiliations

Nanjing University of Aeronautics and Astronautics, Tohoku University, Nanjing Library

Publications

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Application of a Negative Capacitance Circuit in Synchronized Switch Damping Techniques for Vibration Suppression

Qiu

Cheng

et al. 2011

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In the synchronized switching damping (SSD) techniques, the voltage on the piezoelectric element is switched synchronously with the vibration to be controlled using an inductive shunt circuit (SSDI). The inherent capacitance and the inductance in the shunt circuit comprise an electrically resonant circuit. In this study, a negative capacitance is used in the shunt circuit instead of an inductance in the traditional SSD technique. The voltage on the piezoelectric element can be effectively inverted although the equivalent circuit is capacitive and no resonance occurs. In order to investigate the principle of the new SSD method based on a negative capacitance (SSDNC), the variation of the voltage on the piezoelectric element and the current in the circuit are analyzed. Furthermore, the damping effect using the SSDNC is deduced, and the energy balance and stability of the new system are investigated analytically. The method is applied to the single-mode control and two-mode control of a composite beam, and its control performance was confirmed by the experimental results. For the first mode in single-mode control, the SSDNC is much more effective than SSDI. In other cases, the SSDNC is also more effective than the SSDI, although not significantly.

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Characterization of acoustic black hole effect using a one-dimensional fully-coupled and wavelet-decomposed semi-analytical model

Tang

et al. 2016

Journal of Sound and Vibration

189

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A piezoelectric spring pendulum oscillator used for multi-directional and ultra-low frequency vibration energy harvesting

et al. 2018

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Enhanced synchronized switch harvesting: a new energy harvesting scheme for efficient energy extraction

Shen

Qiu

et al. 2010

Smart Mater. Struct.

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This paper presents a new technique for optimized energy harvesting using piezoelectric microgenerators called enhanced synchronized switch harvesting (ESSH). This technique is based on the concept of synchronized switch harvesting (SSH), a nonlinear technique developed for energy harvesting from structural vibration. Compared with the standard technique of energy harvesting, the new technique dramatically increases the harvested power by almost 300% at resonance frequencies in the same vibration conditions, and also ensures an optimal harvested power whatever the load connected to the microgenerator. Furthermore, the new technique (ESSH) in this paper can be truly self-powered; a self-powered circuit which implements the technique is proposed. In addition, the overall power dissipation for the control circuitry is relatively constant (only about 121 μW), which is more attractive especially at high excitation. Because the new technique (ESSH) in this paper can be truly self-powered, no external power supply is needed, making the system suitable for more application fields, especially in remote operation.

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A modified prandtl-ishlinskii model for modeling asymmetric hysteresis of piezoelectric actuators

Hong-wei

Qiu

et al. 2010

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

133

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Piezoelectric actuators can offer high resolution of displacement and this makes them suitable for precise driving tasks. However, most piezoelectric actuators are made of piezoceramics which have a major drawback related to their natural hysteresis nonlinearity. To compensate the hysteresis nonlinearity of piezoelectric actuators, many hysteresis models have been proposed such as the Preisach model, the classical Prandtl-Ishlinskii model, and so on. This paper provides a new approach to model the asymmetric hysteresis nonlinearity of piezoelectric actuators. Unlike the classical Prandtl-Ishlinskii model, the proposed model is based on a combination of two asymmetric operators which can independently simulate the ascending branch and descending branch of hysteresis. Moreover, the proposed model can be calculated using the recursive least-squares method and this makes the model easy and convenient to be calculated. The validity of the proposed model is demonstrated by comparing its simulation results with experimental measurements. The results show that the proposed model is capable of modeling asymmetric hysteresis of piezoelectric actuators with very high accuracy.

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Jinhao Qiu

Application of a Negative Capacitance Circuit in Synchronized Switch Damping Techniques for Vibration Suppression

Characterization of acoustic black hole effect using a one-dimensional fully-coupled and wavelet-decomposed semi-analytical model

A piezoelectric spring pendulum oscillator used for multi-directional and ultra-low frequency vibration energy harvesting

Enhanced synchronized switch harvesting: a new energy harvesting scheme for efficient energy extraction

A modified prandtl-ishlinskii model for modeling asymmetric hysteresis of piezoelectric actuators

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