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Your search keyword '"Tian, Kailun"' showing total 14 results
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14 results on '"Tian, Kailun"'

1. A Fast Power Spectrum Sensing Solution for Generalized Coprime Sampling

Author

Jiang, Kaili, Wang, Dechang, Tian, Kailun, Feng, Hancong, Zhao, Yuxin, Yuan, Junyu, and Tang, Bin

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

The growing scarcity of spectrum resources, wideband spectrum sensing is required to process a prohibitive volume of data at a high sampling rate. For some applications, spectrum estimation only requires second-order statistics. In this case, a fast power spectrum sensing solution is proposed based on the generalized coprime sampling. By exploring the sensing vector inherent structure, the autocorrelation sequence of inputs can be reconstructed from sub-Nyquist samples by only utilizing the parallel Fourier transform and simple multiplication operations. Thus, it takes less time than the state-of-the-art methods while maintaining the same performance, and it achieves higher performance than the existing methods within the same execution time, without the need for pre-estimating the number of inputs. Furthermore, the influence of the model mismatch has only a minor impact on the estimation performance, which allows for more efficient use of the spectrum resource in a distributed swarm scenario. Simulation results demonstrate the low complexity in sampling and computation, making it a more practical solution for real-time and distributed wideband spectrum sensing applications.

Published
2023

2. Wideband Spectrum Acquisition for UAV Swarm Using the Sparse Coding Fourier Transform

Author

Jiang, Kaili, Tian, Kailun, Feng, Hancong, Yuan, Junyu, and Tang, Bin

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

As the trend towards small, safe, smart, speedy and swarm development grows, unmanned aerial vehicles (UAVs) are becoming increasingly popular for a wide range of applications. In this letter, the challenge of wideband spectrum acquisition for the UAV swarms is studied by proposing a processing method that features lower power consumption, higher compression rates, and a lower signal-to-noise ratio. Our system is equipped with multiple UAVs, each with a different sub-sampling rate. That allows for frequency backetization and estimation based on sparse Fourier transform theory. Unlike other techniques, the collisions and iterations caused by non-sparsity environ-ments are considered. We introduce sparse coding Fourier transform to address these issues. The key is to code the entire spectrum and decode it through spectrum correlation in the code. Simulation results show that our proposed method performs well in acquiring both narrowband and wideband signals simultaneously, compared to the other methods.

Published
2023

3. Distributed UAV Swarm Augmented Wideband Spectrum Sensing Using Nyquist Folding Receiver

Author

Jiang, Kaili, Tian, Kailun, Feng, Hancong, Zhao, Yuxin, Wang, Dechang, Cao, Sen, Gao, Jian, Zhang, Xuying, Li, Yanfei, Yuan, Junyu, Xiong, Ying, and Tang, Bin

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

Distributed unmanned aerial vehicle (UAV) swarms are formed by multiple UAVs with increased portability, higher levels of sensing capabilities, and more powerful autonomy. These features make them attractive for many recent applica-tions, potentially increasing the shortage of spectrum resources. In this paper, wideband spectrum sensing augmented technology is discussed for distributed UAV swarms to improve the utilization of spectrum. However, the sub-Nyquist sampling applied in existing schemes has high hardware complexity, power consumption, and low recovery efficiency for non-strictly sparse conditions. Thus, the Nyquist folding receiver (NYFR) is considered for the distributed UAV swarms, which can theoretically achieve full-band spectrum detection and reception using a single analog-to-digital converter (ADC) at low speed for all circuit components. There is a focus on the sensing model of two multichannel scenarios for the distributed UAV swarms, one with a complete functional receiver for the UAV swarm with RIS, and another with a decentralized UAV swarm equipped with a complete functional receiver for each UAV element. The key issue is to consider whether the application of RIS technology will bring advantages to spectrum sensing and the data fusion problem of decentralized UAV swarms based on the NYFR architecture. Therefore, the property for multiple pulse reconstruction is analyzed through the Gershgorin circle theorem, especially for very short pulses. Further, the block sparse recovery property is analyzed for wide bandwidth signals. The proposed technology can improve the processing capability for multiple signals and wide bandwidth signals while reducing interference from folded noise and subsampled harmonics. Experiment results show augmented spectrum sensing efficiency under non-strictly sparse conditions.

Published
2023

4. Wideband Power Spectrum Sensing: a Fast Practical Solution for Nyquist Folding Receiver

Author

Jiang, Kaili, Wang, Dechang, Tian, Kailun, Feng, Hancong, Zhao, Yuxin, Cao, Sen, Gao, Jian, Zhang, Xuying, Li, Yanfei, Yuan, Junyu, Xiong, Ying, and Tang, Bin

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

The limited availability of spectrum resources has been growing into a critical problem in wireless communications, remote sensing, and electronic surveillance, etc. To address the high-speed sampling bottleneck of wideband spectrum sensing, a fast and practical solution of power spectrum estimation for Nyquist folding receiver (NYFR) is proposed in this paper. The NYFR architectures is can theoretically achieve the full-band signal sensing with a hundred percent of probability of intercept. But the existing algorithm is difficult to realize in real-time due to its high complexity and complicated calculations. By exploring the sub-sampling principle inherent in NYFR, a computationally efficient method is introduced with compressive covariance sensing. That can be efficient implemented via only the non-uniform fast Fourier transform, fast Fourier transform, and some simple multiplication operations. Meanwhile, the state-of-the-art power spectrum reconstruction model for NYFR of time-domain and frequency-domain is constructed in this paper as a comparison. Furthermore, the computational complexity of the proposed method scales linearly with the Nyquist-rate sampled number of samples and the sparsity of spectrum occupancy. Simulation results and discussion demonstrate that the low complexity in sampling and computation is a more practical solution to meet the real-time wideband spectrum sensing applications.

Published
2023

7. Distributed UAV Swarm Augmented Wideband Spectrum Sensing Using Nyquist Folding Receiver

Author

Jiang, Kaili, Tian, Kailun, Feng, Hancong, Zhao, Yuxin, Wang, Dechang, Gao, Jian, Cao, Sen, Zhang, Xuying, Li, Yanfei, Yuan, Junyu, Xiong, Ying, and Tang, Bin

Abstract

Distributed unmanned aerial vehicle (UAV) swarms are formed by multiple UAVs with increased portability, higher levels of sensing capabilities, and more powerful autonomy. These features make them attractive for many applications, potentially increasing the shortage of spectrum resources. In this paper, wideband spectrum sensing augmented technology is discussed for distributed UAV swarms to improve the utilization of spectrum using Nyquist folding receiver (NYFR). Compared to the other sub-sampling schemes, the NYFR has low hardware complexity, power consumption, and high recovery efficiency for non-strictly sparse conditions. In particular, there is a focus discussion on the sensing model of two multichannel scenarios for the distributed UAV swarms, one with a complete functional receiver for the UAV swarm with reconfigurable intelligent surface (RIS), and another with a decentralized UAV swarm equipped with a complete functional receiver for each UAV element. Moreover, the property for multiple pulse reconstruction is analyzed through the Gershgorin circle theorem, especially for very short pulses. And the block sparse recovery property is analyzed for wide bandwidth signals. Experiment results show augmented spectrum sensing efficiency under non-strictly sparse conditions, and improve the processing capability for multiple signals and wide bandwidth signals while reducing interference from folded noise and subsampled harmonics.

Published
2024
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9. Syntactic Modeling and Neural-Based Parsing for Multifunction Radar Signal Interpretation

Author

Feng, Han Cong, Jiang, Kai Li, Zhou, Zhixin, Zhao, YuXin, Yan, Hai Xin, Tian, Kailun, and Tang, Bin

Abstract

The analysis of intercepted multifunction radar (MFR) signals and the assessment of potential threats are critical in the field of radar countermeasures. The complexity of MFR control mechanisms poses serious challenges in modeling and recognizing their internal states. MFRs, being discrete event systems, can be well described by formal languages. This article presents a generalized version of the previous syntactic modeling of MFRs, utilizing the proposed latent variable controlled stochastic context-free grammar (LVCSCFG). The enhanced model incorporates a mapping between the external environment and the production probabilities, offering a more effective representation of the resource management process. Additionally, we introduce a neural-based approach for maximum likelihood estimation of the MFRs internal states, which are represented by a grammar tree. LVCSCFG exhibits enhanced representation of MFR dynamic behaviors, and simulation results indicate that the neural network outperforms traditional statistical parsing algorithms in terms of speed and precision under various nonideal channel conditions.

Published
2024
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10. A Fast Power Spectrum Sensing Solution for Generalized Coprime Sampling.

Author

Jiang, Kaili, Wang, Dechang, Tian, Kailun, Zhao, Yuxin, Feng, Hancong, and Tang, Bin

Subjects
POWER spectra, FOURIER transforms, DISTRIBUTED algorithms, SENSES, ORDER statistics
Abstract

With the growing scarcity of spectrum resources, wideband spectrum sensing is necessary to process a large volume of data at a high sampling rate. For some applications, only second-order statistics are required for spectrum estimation. In this case, a fast power spectrum sensing solution is proposed based on the generalized coprime sampling. The solution involves the inherent structure of the sensing vector to reconstruct the autocorrelation sequence of inputs from sub-Nyquist samples, which requires only parallel Fourier transform and simple multiplication operations. Thus, it takes less time than the state-of-the-art methods while maintaining the same performance, and it achieves higher performance than the existing methods within the same execution time without the need to pre-estimate the number of inputs. Furthermore, the influence of the model mismatch has only a minor impact on the estimation performance, allowing for more efficient use of the spectrum resource in a distributed swarm scenario. Simulation results demonstrate the low complexity in sampling and computation, thus making it a more practical solution for real-time and distributed wideband spectrum sensing applications. [ABSTRACT FROM AUTHOR]

Published
2024
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14. Comparative Analysis of Buffer and Damper Positions for Increasing the Seismic Performance of Suspension Bridge.

Author

Pan, Shengshan, Wang, Jichong, Fan, Shuli, Tian, Kailun, and Zhu, Weizhi

Subjects
SUSPENSION bridges, CONCRETE beams, FINITE element method, COMPARATIVE studies, NONLINEAR analysis, EARTHQUAKE resistant design, SEISMIC response
Abstract

In this research, a finite element model is established to investigate effective seismic control schemes for a self-anchored suspension bridge (SASB) with three towers. Nonlinear dynamic analyses are conducted to evaluate the seismic performance of SASB with different layout schemes of viscous dampers and buffers, which were installed in longitudinal direction and transversal direction, respectively. The responses of the SASB designed with 10 seismic control schemes are compared to ascertain suitable seismic schemes for SASBs. The results show that the number and location of lateral buffers have an important impact on the dynamic characterization of the SASB, especially for the first lateral mode and lateral fundamental frequency. To effectively increase the seismic performance of SASBs with three towers, mounting buffers between the side towers and the main girder of SASBs is an appropriate scheme. The viscous dampers can effectively decrease the dynamic reaction of the towers and longitudinal deformation of the girder under earthquake excitations. The plan involves the installation of dampers between the main concrete stiffening girder and the side towers as the optimal longitudinal seismic scheme for the SASB. The study offers important insights into the seismic design of SASBs with three towers. [ABSTRACT FROM AUTHOR]

Published
2023
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