Your search keyword '"Hanqing Qiao"' showing total 6 results

1. Monte Carlo Sampling of Inverse Problems Based on a Squeeze-and-Excitation Convolutional Neural Network Applied to Ground-Penetrating Radar Crosshole Traveltime: A Numerical Simulation Study

Author

Hanqing Qiao, Cai Liu, and Shengchao Wang

Subjects

crosshole ground-penetrating radar (GPR), MCMC, SE-CNN, travel time data inversion, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Monte Carlo-based sampling methods (MCMC) can be used to solve inverse problems affecting ground penetrating radar (GPR) data. However, due to their high computational complexity, they have not been widely used in practical applications. This article uses neural network methods to replace the computationally complex forward problem of Monte Carlo methods. However, the neural network method is an approximation of the accurate formula method, and this may introduce model errors. In order to reduce the impact of model errors, in this study, we incorporate the Squeeze-and-Excitation (SE) attention mechanism into Convolutional Neural Networks (CNN) to further improve the accuracy of the network. Moreover, with the statistical advantages of the MCMC method, model errors can be explained during the inversion process, further reducing their impact. We apply the proposed method to solve the inversion problem of crosshole ground-penetrating radar travel time data. Compared with commonly used approximate forward models, the method proposed in this paper has better accuracy. The results of data experiments indicate that this method can effectively invert the velocity of underground media.

Published

2024

2. Iterative Interferometric Denoising Filter for Traveltime Picking

Author

Hanqing Qiao, Yicheng Zhou, Sherif M. Hanafy, and Cai Liu

Subjects

random data noises, seismic interferometry, traveltime, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Traveltime picking accuracy is frequently affected by incoherent or random data noise. Within this context, we put forth a new denoising method called iterative interferometric denoising filtering. This method leverages the pseudo-Wigner distribution function to capture the offset and time-symmetric patterns of source wavelets convolved in seismic signals. Incoherent or random noises without this characteristic are eliminated via this approach. The processed data have waveform information distortion and more frequency components. However, the traveltime information can be considered correct, and the improved signal-to-noise ratio makes traveltime picking much more convenient. Our method’s practical applications in a synthetic and in two field datasets show that this technology can increase the signal-to-noise ratio, and the picked traveltime information can be used in traveltime tomography. These two field datasets were collected near the Aqaba Gulf and the Qademah fault, located in King Abdullah Economic City.

Published

2024

3. Research on Prediction Method of Volcanic Rock Shear Wave Velocity Based on Improved Xu–White Model

Author

Hanqing Qiao, Bing Zhang, and Cai Liu

Subjects

volcanic reservoir, conventional logging, shear wave velocity prediction, Xu–White model, statistical model, Bayesian inversion, Technology

Abstract

Volcanic rock reservoirs have received extensive attention from scholars all over the world because of their geothermal, mineral, and oil and gas resources. Shear wave velocity is the essential information for AVO (amplitude variation with offset) analysis and the reservoir description of volcanic rocks. However, due to factors such as cost, technical reasons, and so on, shear wave velocity is not provided in many logging data. This paper proposes a shear wave velocity prediction method suitable for the conventional logging of volcanic rocks. Firstly, the Xu–White model is improved. The probability distributions formed by the prior information of the logging area are used to initialize the key petrophysical parameters in the model instead of the fixed parameter value to establish the statistical petrophysical model between the logging curve and shear wave velocity. Then, based on the Bayesian inversion method, the simulated P-wave velocity is matched with the actual P-wave logging data to calculate the key petrophysical parameters, and is then used for S-wave velocity prediction. The method is applied to the actual logging data of the No. 5 structure in Nanpu Sag, eastern China. The prediction effect of shear wave velocity is better than that of the conventional method, indicating the feasibility and effectiveness of this method. This study will provide more accurate shear wave velocity data for the exploration and development of volcanic reservoirs.

Published

2022

4. Driving mechanism of drift-step-recovery diodes

Author

Yinghong Li, Yun Wu, Hanqing Qiao, Chaolong Yi, Fang Xu, Huimin Song, Xia Wenfeng, Xie Jialing, Hua Liang, and Yiping Shi

Subjects

Mechanism (engineering), Materials science, Pulse generator, Driving circuit, Electronic engineering, Instrumentation, Diode

Abstract

Parameters governing forward and reverse pumping of a device mechanism have an important influence on the cutoff and output characteristics of a drift-step-recovery diode (DSRD). Therefore, we analyzed the driving circuit for the DSRD that was used to adjust pumping parameter values. With multiple modules in parallel, a driving method exploiting narrow-pulse pumping is proposed in developing a high-repetition-frequency DSRD pulse generator. In experiments and simulations, one key factor affecting the working stability of this pulse generator operating at repetition frequencies in the megahertz range was found that helped in further optimizing the parameter settings of our 2 kV DSRD driving circuit. From this insight, a 2 kV–5 MHz all-solid-state high-repetition-frequency pulse generator based on the DSRD was developed.

Published

2021

5. An Ultra Wideband Vivaldi Antenna Array Based on Tightly Coupled Effect

Author

Xie Jialing, Fang Xu, Chaolong Yi, Hanqing Qiao, and Yiping Shi

Subjects

Physics, Acoustics, Capacitive sensing, 020208 electrical & electronic engineering, Bandwidth (signal processing), Impedance matching, Ultra-wideband, 020206 networking & telecommunications, 02 engineering and technology, Low frequency, law.invention, law, 0202 electrical engineering, electronic engineering, information engineering, Waveform, Vivaldi antenna

Abstract

An ultra wideband Vivaldi antenna array based on tightly coupled effect is proposed. The elements are arranged overlap to get an additional capacitive capacity to achieve impedance matching at low frequency. A sample of a 4× 4 Vivaldi array was simulated, fabricated, and tested. The measured farfield waveform is basically agreed with simulated one. The designed antenna gets a bandwidth of O.4GHz-4.2GHz.

Published

2019

6. An Ultra Wideband Antenna Based on Tightly Coupled Effect with Practical Compact Balun

Author

Yiping Shi, Lu Yanlei, Xie Jialing, Fan Yajun, Chaolong Yi, Zhang Xingjia, Shi Lei, Hanqing Qiao, Fang Xu, Zhu Yufeng, Xia Wenfeng, and Wang Xiangyu

Subjects

Antenna array, Physics, Resistive touchscreen, Optics, Balun, business.industry, Ultra-wideband, Standing wave ratio, Antenna (radio), business, Electrical impedance, Microstrip

Abstract

An ultra wideband low-profile antenna array based on tightly coupled effect is presented. The proposed antenna array consists of tightly coupled dipoles, the size of an element is $4\text{cm}\times 4\text{cm}\times 10\text{cm}$ . A compact balun of microstrip line gradual changing to parallel double-strip line at both sides is designed, providing unbalanced to balanced transformation and impedance transformation. With resistive frequency select surface, the proposed antenna achieves a wide operating bandwith of 0.5GHz∼11.5GHz with $\text{VSWR} . To avoid cutoff effect, extra no-feeding elements are added in each row of the array.

Published

2019