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386 results on '"Zhang, Fangzheng"'

1. Microwave photonic frequency measurement and time-frequency analysis: Unlocking bandwidths over hundreds of GHz with a 10-nanosecond temporal resolution

Author

Shi, Taixia, Jiang, Chi, Lin, Chulun, Yang, Fangyi, Liu, Yiqing, Zhang, Fangzheng, and Chen, Yang

Subjects
Physics - Optics, Electrical Engineering and Systems Science - Signal Processing, Physics - Applied Physics
Abstract

Fast and broadband spectrum sensing is an essential component in cognitive radio systems, intelligent transportation systems, electronic warfare systems, etc. However, traditional electronic-based solutions have a trade-off among the analysis bandwidth, temporal resolution, and real-time performance. In comparison, microwave photonic solutions can overcome the trade-off at the cost of frequency accuracy and resolution. Nevertheless, the reported microwave photonic solutions suffer from a very poor frequency resolution and impose extremely high requirements on hardware when the analysis bandwidth is close to or greater than 100 GHz. Here, we show a microwave photonic frequency measurement and time-frequency analysis method, which is implemented by dispersion-based frequency-to-time mapping and assisted by a specially designed V-shape linearly frequency-modulated signal and a duty-cycle-enabling technique. Compared with the reported microwave photonic solutions, the hardware requirements are greatly reduced when achieving similar performance conditions. Using a total dispersion of -6817 ps/nm and a V-shape linearly frequency-modulated signal with a bandwidth of 31.6 GHz and a duty cycle of 1/4, we achieve an ambiguity-free analysis bandwidth of 252.8 GHz, a corresponding temporal resolution of 13.75 ns and a frequency resolution of 1.1 GHz. The temporal resolution can be improved to 6.875 ns when the duty cycle is changed to 1/2, while the analysis bandwidth in this case is 126.4 GHz., Comment: 21 pages, 10 figures, 1 table

Published
2024

2. Principle Driven Parameterized Fiber Model based on GPT-PINN Neural Network

Author

Zang, Yubin, Hua, Boyu, Tang, Zhenzhou, Lin, Zhipeng, Zhang, Fangzheng, Li, Simin, Zhang, Zuxing, and Chen, Hongwei

Subjects
Computer Science - Artificial Intelligence, Electrical Engineering and Systems Science - Signal Processing
Abstract

In cater the need of Beyond 5G communications, large numbers of data driven artificial intelligence based fiber models has been put forward as to utilize artificial intelligence's regression ability to predict pulse evolution in fiber transmission at a much faster speed compared with the traditional split step Fourier method. In order to increase the physical interpretabiliy, principle driven fiber models have been proposed which inserts the Nonlinear Schodinger Equation into their loss functions. However, regardless of either principle driven or data driven models, they need to be re-trained the whole model under different transmission conditions. Unfortunately, this situation can be unavoidable when conducting the fiber communication optimization work. If the scale of different transmission conditions is large, then the whole model needs to be retrained large numbers of time with relatively large scale of parameters which may consume higher time costs. Computing efficiency will be dragged down as well. In order to address this problem, we propose the principle driven parameterized fiber model in this manuscript. This model breaks down the predicted NLSE solution with respect to one set of transmission condition into the linear combination of several eigen solutions which were outputted by each pre-trained principle driven fiber model via the reduced basis method. Therefore, the model can greatly alleviate the heavy burden of re-training since only the linear combination coefficients need to be found when changing the transmission condition. Not only strong physical interpretability can the model posses, but also higher computing efficiency can be obtained. Under the demonstration, the model's computational complexity is 0.0113% of split step Fourier method and 1% of the previously proposed principle driven fiber model.

Published
2024

3. Fiber Transmission Model with Parameterized Inputs based on GPT-PINN Neural Network

Author

Zang, Yubin, Hua, Boyu, Lin, Zhipeng, Zhang, Fangzheng, Li, Simin, Zhang, Zuxing, and Chen, Hongwei

Subjects
Computer Science - Artificial Intelligence, Electrical Engineering and Systems Science - Signal Processing
Abstract

In this manuscript, a novelty principle driven fiber transmission model for short-distance transmission with parameterized inputs is put forward. By taking into the account of the previously proposed principle driven fiber model, the reduced basis expansion method and transforming the parameterized inputs into parameterized coefficients of the Nonlinear Schrodinger Equations, universal solutions with respect to inputs corresponding to different bit rates can all be obtained without the need of re-training the whole model. This model, once adopted, can have prominent advantages in both computation efficiency and physical background. Besides, this model can still be effectively trained without the needs of transmitted signals collected in advance. Tasks of on-off keying signals with bit rates ranging from 2Gbps to 50Gbps are adopted to demonstrate the fidelity of the model.

Published
2024

4. Fiber neural networks for the intelligent optical fiber communications

Author

Zang, Yubin, Zhang, Zuxing, Li, Simin, Zhang, Fangzheng, and Chen, Hongwei

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Artificial Intelligence, Computer Science - Networking and Internet Architecture
Abstract

Optical neural networks have long cast attention nowadays. Like other optical structured neural networks, fiber neural networks which utilize the mechanism of light transmission to compute can take great advantages in both computing efficiency and power cost. Though the potential ability of optical fiber was demonstrated via the establishing of fiber neural networks, it will be of great significance of combining both fiber transmission and computing functions so as to cater the needs of future beyond 5G intelligent communication signal processing. Thus, in this letter, the fiber neural networks and their related optical signal processing methods will be both developed. In this way, information derived from the transmitted signals can be directly processed in the optical domain rather than being converted to the electronic domain. As a result, both prominent gains in processing efficiency and power cost can be further obtained. The fidelity of the whole structure and related methods is demonstrated by the task of modulation format recognition which plays important role in fiber optical communications without losing the generality., Comment: 5 pages, 4 figures

Published
2024

8. Chip-based photonic radar for high-resolution imaging

Author

Cui, Simin Li Zhengze, Ye, Xingwei, Feng, Jing, Yang, Yue, He, Zhengqian, Cong, Rong, Zhu, Dan, Zhang, Fangzheng, and Pan, Shilong

Subjects
Electrical Engineering and Systems Science - Signal Processing, Physics - Instrumentation and Detectors, Physics - Optics
Abstract

Radar is the only sensor that can realize target imaging at all time and all weather, which would be a key technical enabler for future intelligent society. Poor resolution and large size are two critical issues for radars to gain ground in civil applications. Conventional electronic radars are difficult to address both issues especially in the relatively low-frequency band. In this work, we propose and experimentally demonstrate, for the first time to the best of our knowledge, a chip-based photonic radar based on silicon photonic platform, which can implement high resolution imaging with very small footprint. Both the wideband signal generator and the de-chirp receiver are integrated on the chip. A broadband photonic imaging radar occupying the full Ku band is experimentally established. A high precision range measurement with a resolution of 2.7 cm and an error of less than 2.75 mm is obtained. Inverse synthetic aperture (ISAR) imaging of multiple targets with complex profiles are also implemented., Comment: 4 pages, 6figures

Published
2019

18. Optical All-Pass Filter Based on Dual-Injection MRR With Arbitrary Coupling Coefficients

Author

Cao, Kaixiang, Yu, Yuan, Chen, Yu, Cui, Shuai, Jiang, Weijun, Xu, Lu, Zhang, Fangzheng, and Zhang, Xinliang

Abstract

An optical all-pass filter (APF) has unified amplitude response and varied phase response, enabling phase manipulation without causing amplitude degradation. Therefore, the APF is significantly important to phase manipulation occasions. However, the implementation of optical APFs requires extremely stringent coupling coefficients matching between different couplers of the microring resonator (MRR). In actual fact, the matching of coupling coefficients is difficult due to the thermal crosstalk and adjusting accuracy of coupling coefficients. Here, we proposed and demonstrated an optical APF that can be realized under arbitrary coupling coefficients of the MRR by interfering the output lights from the MRR and a straight waveguide. We designed and fabricated the chip based on the silicon-on-insulator (SOI) platform. Experimental results show that the implemented optical APF has a phase change of 1.85π while the amplitude variation is within 1.3 dB from 5 to 40 GHz. Meanwhile, tunable time delay and microwave photonic phase shift based on the optical APF are also demonstrated.

Published
2024
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19. Implicit Adaptive Moment Estimation Method for On-Chip Metasurface Design and Optimization

Author

Zang, Yubin, Li, Simin, Zhang, Fangzheng, Zhang, Zuxing, and Chen, Hongwei

Abstract

In this letter, we present a new implicit optimizing method for optical device’s or system’s design and optimization. This method, derived from the traditional adaptive moment estimation algorithm which has been more and more frequently adopted in disciplinary fields of artificially intelligence, provides one potential feasible way of directly optimizing photonic systems or device without the help of extra AI or mathematical models which need to be established and trained in most cases of AI photonics. Moreover, optimizing efficiency are prominently promoted since this method takes gradient information into consideration to guide the optimization. This method’s fidelity and performance is demonstrated under the case of designing on-chip metasurface structured photonic logic gates.

Published
2024
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26. Ultralow Phase Noise Optoelectronic Oscillator and Its Application to a Frequency Synthesizer

Author

LIU Shifeng, XU Xiaorui, ZHANG Fangzheng, LIU Peng, KANG Xiaochen, YANG Huashan, and PAN Shilong

Subjects
OptoElectronic Oscillator (OEO), Phase modulator, Frequency synthesizer, Phase noise, Electricity and magnetism, QC501-766
Abstract

We propose a novel injection-locked OptoElectronic Oscillator (OEO) with ultralow phase noise based on two cascaded phase modulators, which is further applied to construct a frequency synthesizer. Thanks to the phase modulation, the output optical spectrum expands and the optical power keeps constant while passing through the optical fiber, which dramatically reduces the intensity noise induced by the nonlinear effects of the optical fiber. A dual-output MZI together with a balanced optical detector realizes the phase modulation to intensity modulation conversion and improves the signal to noise ratio of the OEO. The output frequency of the proposed OEO is 9.9999914 GHz with its sidemode suppression ratio larger than 85 dB, and the phase noise reaches –153.1 dBc/Hz at 10 kHz frequency offset which is 38.7 dB lower than that of Keysight E8257D. Moreover, a broadband, high performance frequency synthesizer is established based on the proposed OEO. Combining the DDS and PLL technologies, the proposed frequency synthesizer can cover 5.9~12.9 GHz range. The phase noise is around –130 dBc/Hz@10 kHz, the spur suppression ratio is better than 65 dB, and the frequency hopping time is less than 1.48 μs.

Published
2019
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27. Broadband LFM Radar Imaging System Based on Microwave Photonic I/Q De-chirping

Author

YANG Yue, YE Xingwei, ZHANG Fangzheng, and PAN Shilong

Subjects
Microwave photonics, Microwave photonic radar, Linear frequency modulated signal, I/Q receiver, Electricity and magnetism, QC501-766
Abstract

We propose a novel scheme of broadband LFM radar imaging system based on microwave photonic I/Q de-chirping. In the transmitter, a broadband linear frequency modulated signal is generated by photonic frequency-doubling. In the receiver, echoes reflected from the target are simultaneously sent to a couple of modulators in two polarization states. After the bias voltage of the corresponding modulator is adjusted to introduce a 90° phase difference, photonic I/Q de-chirping reception of radar echoes is achieved. The proposed radar is capable of real-time high-resolution detection and can distinguish the target on both sides of a reference point. The range ambiguity problem caused by image interference in current radar with photonic de-chirping reception is solved. In this study, first, the necessity of I/Q de-chirping is demonstrated. Then, the structure and principle of the proposed photonic-based radar are introduced. A K-band radar with a bandwidth of 8 GHz is established, and an experiment on target detection and inverse synthetic aperture radar imaging is conducted. Results show that the system can effectively suppress the interference from image frequencies.

Published
2019
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34. Photonics-Based Broadband Vortex Electromagnetic Wave Generation for High-Resolution Imaging

Author

Sun, Guanqun, Zhang, Fangzheng, Zhao, Keyi, and Pan, Shilong

Abstract

Vortex electromagnetic (EM) radar is able to image the target with high azimuth resolution in forward-looking scenarios. In this paper, to enhance the range resolution, a photonics-based broadband vortex EM generation and imaging system is proposed using a multi-channel microwave photonic phase shifter to precisely control the phase of signals fed into a uniform circular array. Compared with electrical phase shifters, the microwave photonic phase shifter implements more accurate control of both the phase and amplitude over a large spectral range. In the experiment, broadband vortex EM waves with 8-GHz bandwidth (18–26 GHz) and seven orbital angular momentum (OAM) modes (l = 0, ±1, ±2, and ±3) are generated, of which the field patterns and frequency-dependent beam divergence properties are analyzed. A radar imaging experiment is also conducted to verify the feasibility of forward-looking imaging with remarkably enhanced range resolution. We believe the proposed method can provide effective solutions to constructing broadband vortex EM systems, which are expected to bring significant improvements compared with narrow-band systems.

Published
2024
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