Your search keyword '"Fu, Yong-Qing"' showing total 3 results

1. Refocusing with Time Reversal Mirror in Random Medium.

Author

Xia, Yun long and Fu, Yong qing

Abstract

Abstract: The use of time reversal mirror (TRM) to refocus a target through random medium is presented. A signal that is recorded and then retransmitted by an array of transducer, propagates back through the medium, and refocus approximately on the source y that emitted it. Refocusing resolution with a TRM through random medium is shown much better than that obtained in random medium. Here the phenomenon of refocusing through random medium in time-reversal acoustics is analyzed theoretically and with the results of numerical simulations. [Copyright &y& Elsevier]

Published

2012

2. Combination of WHT with TRM on Detection of LFM Signal in Inhomogeneous Medium.

Author

Xia, Yun long and Fu, Yong qing

Abstract

Abstract: T On the basis of time-reversal focusing theory, time frequency analysis combining with time reversal mirror (TRM) on detection of linear frequency modulation (LFM) signal in inhomogeneous medium is studied. The experiment on time frequency analysis is carried out in a lab water tank. A signal is received passively by a TRM, time-reversed and then re-transmitted into the same medium. The re-transmitted signal is received at the source and Wigner-Hough transform (WHT) analysis is performed. The time varying spectrum of time frequency analysis gives more useful information to recognize different types of target signals. The experiment results show that the new method can reduce cross-term and suppress multi-scattering. The approach is effective and feasible. [Copyright &y& Elsevier]

Published

2012

3. Record-Breaking Frequency of 44 GHz Based on the Higher Order Mode of Surface Acoustic Waves with LiNbO3/SiO2/SiC Heterostructures

Author

Zhou, Jian, Zhang, Dinghong, Liu, Yanghui, Zhuo, Fengling, Qian, Lirong, Li, Honglang, Fu, Yong-Qing, and Duan, Huigao

Abstract

Surface acoustic wave (SAW) technology has been extensively explored for wireless communication, sensors, microfluidics, photonics, and quantum information processing. However, due to fabrication issues, the frequencies of SAW devices are typically limited to within a few gigahertz, which severely restricts their applications in 5G communication, precision sensing, photonics, and quantum control. To solve this critical problem, we propose a hybrid strategy that integrates a nanomanufacturing process (i.e., nanolithography) with a LiNbO3/SiO2/SiC heterostructure and successfully achieve a record-breaking frequency of about 44 GHz for SAW devices, in addition to large electromechanical coupling coefficients of up to 15.7%. We perform a theoretical analysis and identify the guided higher order wave modes generated on these slow-on-fast SAW platforms. To demonstrate the superior sensing performance of the proposed ultra-high-frequency SAW platforms, we perform micro-mass sensing and obtain an extremely high sensitivity of approximately 33151.9 MHz·mm2·μg−1, which is about 1011times higher than that of a conventional quartz crystal microbalance (QCM) and about 4000 times higher than that of a conventional SAW device with a frequency of 978 MHz.

Published

2022