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1. Research on deep reinforcement learning in Internet of vehicles edge computing based on Quasi-Newton method

Author

ZHANG Jianwu, LU Zetao, ZHANG Qianhua, and ZHAN Ming

Subjects
Internet of vehicles, task offloading, deep reinforcement learning, Quasi-Newton method, Telecommunication, TK5101-6720
Abstract

To address the issues of ineffective task offloading decisions caused by multitasking and resource constraints in vehicular networks, the Quasi-Newton method deep reinforcement learning dual-phase online offloading (QNRLO) algorithm was proposed. The algorithm was designed by initially incorporating batch normalization techniques to optimize the training process of deep neural networks. Subsequently, optimization was performed using the Quasi-Newton method to effectively approximate the optimal solution. Through this dual-stage optimization, performance was significantly enhanced under conditions of multitasking and dynamic wireless channels, improving computational efficiency. By introducing Lagrange multipliers and a reconstructed dual function, the non-convex optimization problem was transformed into a convex optimization problem of the dual function, ensuring the global optimality of the algorithm. Additionally, system transmission time allocation in the vehicular network model was considered, enhancing the practicality of the algorithm. Compared to existing algorithms, the proposed algorithm improves the convergence and stability of task offloading significantly, addresses task offloading issues in vehicular networks effectively, and offers high practicality and reliability.

Published
2024
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2. Determination of eight volatile halogenated hydrocarbons in drinking water by headspace thermal desorption⁃gas mass spectrometry

Author

YU Juan, ZHENG Lei, XI Ye, and ZHAN Ming

Subjects
headspace, thermal desorption, vinyl chloride, volatile halogenated hydrocarbons, drinking water, Medicine
Abstract

ObjectiveTo establish a method for the determination of 8 volatile halogenated hydrocarbons in drinking water, including vinyl chloride, trichloroethylene, tetrachloroethylene, tetrachloromethane, chloroform, dichlorobromomethane, dichlorodibromomethane, and tribromomethane by headspace thermal desorption-gas mass spectrometry.MethodsThe water sample was kept in the headspace bottle at 60 ℃ for 40 min, and the volatile matter was transferred to the cold trap,subjected to thermal desorption, then analyzed by gas chromatography-mass spectrometry.ResultsThe linear ranges were 0.2‒20.0 μg·L-1 for vinyl chloride, 0.1‒20.0 μg·L-1 for chloroform, 0.02‒20.00 μg·L-1 for tetrachloromethane, 0.2‒20.0 μg·L-1 for trichloroethylene, 0.3‒20.0 μg·L-1 for dichlorobromomethane, 0.1‒20.0 μg·L-1 for tetrachloroethylene, 0.4‒20.0 μg·L-1 for dichlorodibromomethane, and 1.0‒20.0 μg·L-1 for tribromomethane. All the correlation coefficients were more than 0.997. The respective quantitative limits were 0.162, 0.073, 0.016, 0.184, 0.270, 0.071, 0.356 and 0.813 μg·L-1, and the respective recoveries were 98.0%‒101.0%, 102.0%‒110.0%, 99.2%‒101.0%, 95.5%‒96.2%, 96.0%‒102.0%, 100.0%‒102.0%, 99.0%‒105.0%, and 94.0%‒103.0%.ConclusionThe method is simple, sensitive, rapid, accurate and reliable, so it is applicable for the determination of 8 kinds of volatile halogenated hydrocarbons in drinking water.

Published
2022
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3. A memory reduced Turbo code decoding architecture design and FPGA implementation

Author

Zeng Jie, Zhan Ming, Luo Xiaohong, Yang Chao, Deng Yi, and Wang Meng

Subjects
low-power dissipation, wireless communication, turbo code, fpga implementation, log-map algorithm, Electronics, TK7800-8360
Abstract

In order to satisfy the high-performance and low-power dissipation requirement in wireless communication, this paper proposes a low storage capacity and low-power dissipation Turbo decoder architecture based on the reverse recalculation and linear estimation by changing the storage method of the forward state metric, while the FPGA implementation structure is given. The results show that compared with the existing Turbo code decoder, the decoding structure designed in this paper reduces the storage capacity to 65%, and the decoding performance is close to the Log-MAP algorithm. In particular, compared with the traditional decoder architecture, dynamic storage capacity power dissipation is reduced by about 50%, and the overall power dissipation of the decoder architecture is decreased by 4.97%, 8.78%, 11.93%, 14.18% and 14.65% at the frequency of 25 MHz,50 MHz,75 MHz,100 MHz and 125 MHz, respectively.

Published
2019
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4. Evaluation of the systematic error induced by quadratic Zeeman effect using hyperfine ground state exchange method in a long-baseline dual-species atom interferometer

Author

Ji, Yu-Hang, He, Chuan, Yan, Si-Tong, Jiang, Jun-Jie, Lei, Jia-Qi, Zhou, Lu, Zhou, Lin, Chen, Xi, Wang, Jin, and Zhan, Ming-Sheng

Subjects
Physics - Atomic Physics, Quantum Physics
Abstract

The systematic error induced by the quadratic Zeeman effect is non-negligible in atom interferometers and must be precisely evaluated. We theoretically analyze the phase shift induced by the Zeeman effect, and use a hyperfine ground state exchange (HGSE) method to evaluate the systematic error in the long-baseline $^{85}$Rb-$^{87}$Rb dual-species atom interferometer due to the quadratic Zeeman effect. Compared to the two evaluation methods, mapping the absolute magnetic field in the interference region and performing phase measurements at different bias fields, the HGSE method could obtain the systematic error in real time in case of slow drifts of either the ambient magnetic field or other systematic effects irrelevant to the hyperfine ground states. To validate the effectiveness of the HGSE method, we also employ the mapping magnetic field method and modulating bias field method independently to cross-check and yield consistent results of three methods within an accuracy of $10^{-11}$ level. The HGSE method is helpful in evaluating and suppressing the quadratic Zeeman-effect-induced systematic error in long-baseline atom interferometer-based precision measurements, such as equivalence principle tests.

Published
2024

5. Probing the interaction energy of two $^{85}$Rb atoms in an optical tweezer via spin-motion coupling

Author

Zhuang, Jun, Wang, Kun-Peng, Wang, Peng-Xiang, Wei, Ming-Rui, Mamat, Bahtiyar, Sheng, Cheng, Xu, Peng, Liu, Min, Wang, Jin, He, Xiao-Dong, and Zhan, Ming-Sheng

Subjects
Physics - Atomic Physics
Abstract

The inherent polarization gradients in tight optical tweezers can be used to couple the atomic spins to the two-body motion under the action of a microwave spin-flip transition, so that such a spin-motion coupling offers an important control knob on the motional states of optically trapped two colliding atoms. Here, after preparing two elastically scattering $^{85}$Rb atoms in the three-dimensional ground-state in the optical tweezer, we employed this control in order to probe the colliding energies of elastic and inelastic channels. The combination of microwave spectra and corresponding s-wave pseudopotential model allows us to infer the effect of the state-dependent trapping potentials on the elastic colliding energies, as well as to reveal how the presence of inelastic interactions affects elastic part of the relative potential. Our work shows that the spin-motion coupling in a tight optical tweezer expand the experimental toolbox for fundamental studies of ultracold collisions in the two body systems with reactive collisions, and potentially for that of more complex interactions, such as optically trapped atom-molecule and molecule-molecule interactions., Comment: 8 pages, 5 figures

Published
2024
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7. Review of Ship Surveillance Technologies Based on High-Resolution Wide-Swath Synthetic Aperture Radar Imaging

Author

Xing Xiang-wei, Ji Ke-feng, Kang Li-hong, and Zhan Ming

Subjects
Synthetic Aperture Radar (SAR), High Resolution Wide Swath (HRWS), Ship surveillance, Electricity and magnetism, QC501-766
Abstract

Synthetic Aperture Radar (SAR) is widely used in ship surveillance. High-Resolution Wide-Swath (HRWS) SAR data are simultaneously collected, which introduces challenges and offers new research opportunities. SAR-based ship-surveillance technologies and the performance requirements of SAR systems are reviewed and summarized. Furthermore, the characteristics of HRWS SAR imaging and ship surveillance technologies are considered in tandem, and preliminary research results on ship detection, feature extraction, and classification are discussed. Finally, we point out issues to be addressed in future work.

Published
2015
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12. Compact multi-channel radio frequency pulse sequence generator with fast switching capability for cold atom interferometers

Author

Jiang, Min, Lu, Si-Bin, Li, Yang, Sun, Chuan, Yao, Zhan-Wei, Li, Shao-Kang, Chen, Hong-Hui, Chen, Xiao-Li, Lu, Ze-Xi, Mao, Yin-Fei, Li, Run-Bing, Wang, Jin, and Zhan, Ming-Sheng

Subjects
Physics - Atomic Physics, Physics - Instrumentation and Detectors
Abstract

Cold atom interferometers have matured to a powerful tool in fundamental physics research, and they are currently on their way from realizations in the laboratory to applications in the real world. The radio frequency (RF) generator is an indispensable component to control lasers and then manipulate atoms. We developed a highly compact RF generator for fast switching and sweeping frequencies/amplitudes of atomic interference pulse sequences. Multi-channel RF signals are generated by using a field-programmable gate array (FPGA) to control eight direct digital synthesizers (DDSs). We further proposed and demonstrated a method of preloading the parameters of all RF pulse sequences to the DDS registers before the execution of the pulse sequences, which eliminates the data transfer between the FPGA and DDSs to change RF signals and thus sharply shortens the delay of frequency switching when the pulse sequences are running. The characterized performance shows the generated RF signals achieve 119 ns frequency switching delay, and 40 dB harmonic rejection ratio. The generated RF pulse sequences are applied to a cold atom-interferometer gyroscope, and the contrast of atomic interference fringes reaches 38%. This compact multi-channel generator with the fast frequency/amplitude switching or/and sweeping capability has beneficial applications for the real-world atom interferometers.

Published
2023

13. Self-Calibrated Atom-Interferometer Gyroscope by Modulating Atomic Velocities

Author

Chen, Hong-Hui, Yao, Zhan-Wei, Lu, Ze-Xi, Lu, Si-Bin, Jiang, Min, Li, Shao-Kang, Chen, Xiao-Li, Sun, Chuan, Mao, Yin-Fei, Li, Yang, Li, Run-Bing, Wang, Jin, and Zhan, Ming-Sheng

Subjects
Physics - Atomic Physics
Abstract

Atom-interferometer gyroscopes have attracted much attention for their potential superior long-term stability and extremely low drift. For such high precision instrument, a self-calibration to achieve an absolute rotation measurement is highly demanded. Here we propose and demonstrate a self-calibration of the atomic gyroscope. The calibration is realized by using the detuning of laser frequency to control the atomic velocity thus to modulate the scale factor of the gyroscope. The modulation determines the order and the initial phase of the interference stripe, thus eliminates the ambiguity caused by the periodicity of the interferometric signal. The calibration method is verified by measuring the Earth's rotation. Long-term stable and self-calibrated atom-interferometer gyros can find important applications in the fields of fundamental physics and long-time navigation., Comment: 10 pages, 5 figures

Published
2023

17. Experimental Quantum Simulation of Dynamic Localization on Curved Photonic Lattices

Author

Tang, Hao, Wang, Tian-Yu, Shi, Zi-Yu, Feng, Zhen, Wang, Yao, Shang, Xiao-Wen, Gao, Jun, Jiao, Zhi-Qiang, Li, Zhan-Ming, Chang, Yi-Jun, Zhou, Wen-Hao, Lu, Yong-Heng, Yang, Yi-Lin, Ren, Ruo-Jing, Qiao, Lu-Feng, and Jin, Xian-Min

Subjects
Quantum Physics, Physics - Optics
Abstract

Dynamic localization, which originates from the phenomena of particle evolution suppression under an externally applied AC electric field, has been simulated by suppressed light evolution in periodically-curved photonic arrays. However, experimental studies on their quantitative dynamic transport properties and application for quantum information processing are rare. Here we fabricate one-dimensional and hexagonal two-dimensional arrays, both with sinusoidal curvature. We successfully observe the suppressed single-photon evolution patterns, and for the first time measure the variances to study their transport properties. For one-dimensional arrays, the measured variances match both the analytical electric field calculation and the quantum walk Hamiltonian engineering approach. For hexagonal arrays, as anisotropic effective couplings in four directions are mutually dependent, the analytical approach suffers, while quantum walk conveniently incorporates all anisotropic coupling coefficients in the Hamiltonian and solves its exponential as a whole, yielding consistent variances with our experimental results. Furthermore, we implement a nearly complete localization to show that it can preserve both the initial injection and the wave-packet after some evolution, acting as a memory of a flexible time scale in integrated photonics. We demonstrate a useful quantum simulation of dynamic localization for studying their anisotropic transport properties, and a promising application of dynamic localization as a building block for quantum information processing in integrated photonics., Comment: 4 figures

Published
2022
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18. Efficient two-dimensional defect-free dual-species atom arrays rearrangement algorithm with near-fewest atom moves

Author

Tao, Zhi-Jin, Yu, Li-Geng, Peng-Xu, Hou, Jia-Yi, He, Xiao-Dong, and Zhan, Ming-Sheng

Subjects
Quantum Physics
Abstract

Dual-species single-atom array in optical tweezers has several advantages over the single-species atom array as a platform for quantum computing and quantum simulation. Thus, creating the defect-free dual-species single-atom array with atom numbers over hundreds is essential. As recent experiments demonstrated, one of the main difficulties lies in designing an efficient algorithm to rearrange the stochastically loaded dual-species atoms arrays into arbitrary demanded configurations. We propose a heuristic connectivity optimization algorithm (HCOA) to provide the near-fewest number of atom moves. Our algorithm introduces the concept of using articulation points in an undirected graph to optimize connectivity as a critical consideration for arranging the atom moving paths. Tested in array size of hundreds atoms and various configurations, our algorithm shows a high success rate (> 97%), low extra atom moves ratio, good scalability, and flexibility. Furthermore, we proposed a complementary step to solve the problem of atom loss during the rearrangement.

Published
2022
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19. Short-Packet Interleaver against Impulse Interference in Practical Industrial Environments

Author

Zhan, Ming, Pang, Zhibo, Dzung, Dacfey, Yu, Kan, and Xiao, Ming

Subjects
Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing
Abstract

The most common cause of transmission failure in Wireless High Performance (WirelessHP) target industry environments is impulse interference. As interleavers are commonly used to improve the reliability on the Orthogonal Frequency Division Multiplexing (OFDM) symbol level for long packet transmission, this paper considers the feasibility of applying short-packet bit interleaving to enhance the impulse/burst interference resisting capability on both OFDM symbol and frame level. Using the Universal Software Radio Peripherals (USRP) and PC hardware platform, the Packet Error Rate (PER) performance of interleaved coded short-packet transmission with Convolutional Codes (CC), Reed-Solomon codes (RS) and RS+CC concatenated codes are tested and analyzed. Applying the IEEE 1613 standard for impulse interference generation, extensive PER tests of CC(1=2) and RS(31; 21)+CC(1=2) concatenated codes are performed. With practical experiments, we prove the effectiveness of bit in terleaved coded short-packet transmission in real factory environments. We also investigate how PER performance depends on the interleavers, codes and impulse interference power and frequency., Comment: 14 pages, 12 figures, submitted to IEEE Transactions on Wireless Communications

Published
2022

22. Development of a compact high-resolution absolute gravity gradiometer based on atom interferometers

Author

Lyu, Wei, Zhong, Jia-Qi, Zhang, Xiao-Wei, Liu, Wu, Zhu, Lei, Xu, Wei-Hao, Chen, Xi, Tang, Biao, Wang, Jin, and Zhan, Ming-Sheng

Subjects
Physics - Atomic Physics, Quantum Physics
Abstract

We present a compact high-resolution gravity gradiometer based on dual Rb-85 atom interferometers using stimulated Raman transitions. A baseline L=44.5 cm and an interrogation time T=130 ms are realized in a sensor head with volume of less than 100 liters. Experimental parameters are optimized to improve the short-term sensitivity while a rejection algorithm relying on inversion of the Raman wave vector is implemented to improve the long-term stability. After an averaging time of 17000 s, a phase resolution of 104 {\mu}rad is achieved, which corresponds to a gravity gradient resolution of 0.86 E. As far as we know, this is the sub-E atom gravity gradiometer with the highest level of compactness to date. After the evaluation and correction of system errors induced by light shift, residual Zeeman shift, Coriolis effect and self-attraction effect, the instrument serves as an absolute gravity gradiometer and with it the local gravity gradient is measured to be 3114 (53) E., Comment: 10 pages, 11 figures

Published
2022

23. Self-Alignment of a Large-Area Dual-Atom-Interferometer Gyroscope Using Parameter Decoupled Phase Seeking Calibrations

Author

Yao, Zhan-Wei, Chen, Hong-Hui, Lu, Si-Bin, Li, Run-Bing, Lu, Ze-Xi, Chen, Xiao-Li, Yu, Geng-Hua, Jiang, Min, Sun, Chuan, Ni, Wei-Tou, Wang, Jin, and Zhan, Ming-Sheng

Subjects
Physics - Atomic Physics
Abstract

We realize a Mach-Zehnder-type dual-atom-interferometer gyroscope with an interrogation arm of 40 cm length and the interference area up to 1.2 cm$^2$. The precise angular alignment of the large-scale separated Raman lasers is demonstrated by seeking the phase intersection of Ramsey-Bord$\acute{e}$ interferometers after the gravity effect is compensated and by decoupling the velocity dependent crosstalk phase shifts, and applied to build the Mach-Zehnder atom interferometer. Then a compact inertial rotation sensor is realized based on dual large-area Mach-Zehnder atom interferometers by precisely aligning the large-scale separated Raman lasers, in which the coherence is well preserved and the common noise is differentially suppressed. The sensor presents a sensitivity of $1.5\times10^{-7}$ rad/s/Hz$^{1/2}$, and a stability of $9.5\times10^{-10}$ rad/s at 23000 s. The absolute rotation measurement is carried out by adjusting the atomic velocity which corresponds to modulating the scale factor., Comment: 6 pages, 4 figures

Published
2022

29. Mid-Frequency Gravitational Waves (0.1-10 Hz): Sources and Detection Methods Summary of the parallel session GW2 of MG16 Meeting

Author

Gao, Dongfeng, Ni, Wei-Tou, Wang, Jin, Zhan, Ming-Sheng, and Zhou, Lin

Subjects
General Relativity and Quantum Cosmology, Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

This article summarizes the talks in the session GW2 of the Sixteenth Marcel Grossmann Meeting on Recent Developments in Theoretical and Experimental General Relativity, Gravitation, and Relativistic Field Theories, 5-10 July, 2021, on Mid-frequency (0.1-10 Hz) gravitational waves: Sources and detection methods with a review on strain power spectral density amplitude of various mid-frequency gravitational wave projects/concepts and with extended summaries on the progress of ZAIGA project and on the conceptual study of AMIGO., Comment: 16 pages, 3 figures, 1 table

Published
2021

30. Noise Error Pattern Generation Based on Successive Addition-Subtraction for Guessing Decoding

Author

Zhan, Ming, Pang, Zhibo, Yu, Kan, Xu, Jing, and Wu, Fang

Subjects
Computer Science - Information Theory
Abstract

Guessing random additive noise decoding (GRAND) algorithm has emerged as an excellent decoding strategy that can meet both the high reliability and low latency constraints. This paper proposes a successive addition-subtraction algorithm to generate noise error permutations. A noise error patterns generation scheme is presented by embedding the "1" and "0" bursts alternately. Then detailed procedures of the proposed algorithm are presented, and its correctness is also demonstrated through theoretical derivations. The aim of this work is to provide a preliminary paradigm and reference for future research on GRAND algorithm and hardware implementation., Comment: 6 pages, 7 figures, submitted to IEEE Communications Letters

Published
2021

34. MHD analysis on the physical designs of CFETR and HFRC

Author

Zhu, Ping, Li, Li, Fang, Yu, He, Yuling, Wang, Shuo, Han, Rui, Liu, Yue, Wang, Xiaojing, Zhang, Yang, Zhang, Xiaodong, Yu, Qingquan, Hu, Liqun, Wang, Huihui, Sun, Youwen, Wei, Lai, Tang, Weikang, Liu, Tong, Wang, Zhengxiong, Yan, Xingting, Huang, Wenlong, Hou, Yawei, Ji, Xiaoquan, Zeng, Shiyong, Abdullah, Zafar, Chen, Zhongyong, Zeng, Long, Li, Haolong, Chen, Zhipeng, Wang, Zhijiang, Rao, Bo, Zhan, Ming, Ding, Yonghua, Pan, Yuan, Team, the CFETR Physics, and Team, the HFRC Physics

Subjects
Physics - Plasma Physics
Abstract

The China Fusion Engineering Test Reactor (CFETR) and the Huazhong Field Reversed Configuration (HFRC), currently both under intensive physical and engineering designs in China, are the two major projects representative of the low-density steady-state and high-density pulsed pathways to fusion. One of the primary tasks of the physics designs for both CFETR and HFRC is the assessment and analysis of the magnetohydrodynamic (MHD) stability of the proposed design schemes. Comprehensive efforts on the assessment of MHD stability of CFETR and HFRC baseline scenarios have led to preliminary progresses that may further benefit engineering designs., Comment: 48 pages, 26 figures

Published
2021

41. Photon-Inter-Correlation Optical Communication

Author

Yan, Zeng-Quan, Hu, Cheng-Qiu, Li, Zhan-Ming, Li, Zhong-Yuan, Zheng, Hang, and Jin, Xian-Min

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Physics - Optics, Quantum Physics
Abstract

The development of modern technology extends human presence beyond cislunar space and onto other planets, which presents an urgent need for high-capacity, long-distance and interplanetary communication. Communication using photons as carriers has a high channel capacity, but the optical diffraction limit in deep space leads to inevitable huge geometric loss, setting an insurmountable transmission distance for existing optical communication technologies. Here, we propose and experimentally demonstrate a photon-inter-correlation optical communication (PICOC) against an ultra-high channel loss. We treat light as a stream of photons, and retrieve the additional information of internal correlation and photon statistics globally from extremely weak pulse sequences. We successfully manage to build high-fidelity communication channel with a loss up to 160dB by separating a single-photon signal embedded in a noise ten times higher. With only commercially available telescopes, PICOC allows establishment of communication links from Mars to Earth communication using a milliwatt laser, and from the edge of the solar system to Earth using a few watts laser., Comment: Main Text: 19 pages, 5 figures, 1 table; Supplemental Material: 15 pages, 10 figures

Published
2021

42. Probing Multiple Electric Dipole Forbidden Optical Transitions in Highly Charged Nickel Ions

Author

Liang, Shi-Yong, Zhang, Ting-Xian, Guan, Hua, Lu, Qi-Feng, Xiao, Jun, Chen, Shao-Long, Huang, Yao, Zhang, Yong-Hui, Li, Cheng-Bin, Zou, Ya-Ming, Li, Ji-Guang, Yan, Zong-Chao, Derevianko, Andrei, Zhan, Ming-Sheng, Shi, Ting-Yun, and Gao, Ke-Lin

Subjects
Physics - Atomic Physics
Abstract

Highly charged ions (HCIs) are promising candidates for the next generation of atomic clocks, owing to their tightly bound electron cloud, which significantly suppresses the common environmental disturbances to the quantum oscillator. Here we propose and pursue an experimental strategy that, while focusing on various HCIs of a single atomic element, keeps the number of candidate clock transitions as large as possible. Following this strategy, we identify four adjacent charge states of nickel HCIs that offer as many as six optical transitions. Experimentally, we demonstrated the essential capability of producing these ions in the low-energy compact Shanghai-Wuhan Electron Beam Ion Trap. We measured the wavelengths of four magnetic-dipole ($M$1) and one electric-quadrupole ($E$2) clock transitions with an accuracy of several ppm with a novel calibration method; two of these lines were observed and characterized for the first time in controlled laboratory settings. Compared to the earlier determinations, our measurements improved wavelength accuracy by an order of magnitude. Such measurements are crucial for constraining the range of laser wavelengths for finding the "needle in a haystack" narrow lines. In addition, we calculated frequencies and quality factors, evaluated sensitivity of these six transitions to the hypothetical variation of the electromagnetic fine structure constant $\alpha$ needed for fundamental physics applications. We argue that all the six transitions in nickel HCIs offer intrinsic immunity to all common perturbations of quantum oscillators, and one of them has the projected fractional frequency uncertainty down to the remarkable level of 10$^{-19}$., Comment: To be published in Physical Review A

Published
2021
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47. Fast Correlated-Photon Imaging Enhanced by Deep Learning

Author

Li, Zhan-Ming, Wu, Shi-Bao, Gao, Jun, Zhou, Heng, Yan, Zeng-Quan, Ren, Ruo-Jing, Yin, Si-Yuan, and Jin, Xian-Min

Subjects
Quantum Physics, Electrical Engineering and Systems Science - Image and Video Processing, Physics - Applied Physics, Physics - Optics
Abstract

Correlated photon pairs, carrying strong quantum correlations, have been harnessed to bring quantum advantages to various fields from biological imaging to range finding. Such inherent non-classical properties support extracting more valid signals to build photon-limited images even in low flux-level, where the shot noise becomes dominant as light source decreases to single-photon level. Optimization by numerical reconstruction algorithms is possible but require thousands of photon-sparse frames, thus unavailable in real time. Here, we present an experimental fast correlated-photon imaging enhanced by deep learning, showing an intelligent computational strategy to discover deeper structure in big data. Convolutional neural network is found being able to efficiently solve image inverse problems associated with strong shot noise and background noise (electronic noise, scattered light). Our results fill the key gap in incompatibility between imaging speed and image quality by pushing low-light imaging technique to the regime of real-time and single-photon level, opening up an avenue to deep leaning-enhanced quantum imaging for real-life applications., Comment: 17 pages, 5 figures

Published
2020

48. Repurposing drugs for COVID-19 based on transcriptional response of host cells to SARS-CoV-2

Author

Li, Fuhai, Michelson, Andrew P., Foraker, Randi, Zhan, Ming, and Payne, Philip R. O.

Subjects
Quantitative Biology - Molecular Networks, Quantitative Biology - Quantitative Methods
Abstract

The Coronavirus Disease 2019 (COVID-19) pandemic has infected over 10 million people globally with a relatively high mortality rate. There are many therapeutics undergoing clinical trials, but there is no effective vaccine or therapy for treatment thus far. After affected by the Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), molecular signaling of host cells plays critical roles during the life cycle of SARS-CoV-2. Thus, it is significant to identify the involved molecular signaling pathways within the host cells, and drugs targeting these molecular signaling pathways could be potentially effective for COVID-19 treatment. In this study, we aimed to identify these potential molecular signaling pathways, and repurpose existing drugs as a potentially effective treatment of COVID-19 to facilitate the therapeutic discovery, based on the transcriptional response of host cells. We first identified dysfunctional signaling pathways associated with the infection caused SARS-CoV-2 in human lung epithelial cells through analysis of the altered gene expression profiles. In addition to the signaling pathway analysis, the activated gene ontologies (GOs) and super gene ontologies were identified. Signaling pathways and GOs such as MAPK, JNK, STAT, ERK, JAK-STAT, IRF7-NFkB signaling, and MYD88/CXCR6 immune signaling were particularly identified. Based on the identified signaling pathways and GOs, a set of potentially effective drugs were repurposed by integrating the drug-target and reverse gene expression data resources. The dexamethasone was top-ranked in the prediction, which was the first reported drug to be able to significantly reduce the death rate of COVID-19 patients receiving respiratory support. The results can be helpful to understand the associated molecular signaling pathways within host cells, and facilitate the discovery of effective drugs for COVID-19 treatment., Comment: 11 pages, 3 figures

Published
2020

49. Suppression of Coriolis error in weak equivalence principle test using ^[85]Rb-^[87]Rb dual-species atom interferometer

Author

Duan, Wei-Tao, He, Chuan, Yan, Si-Tong, Ji, Yu-Hang, Zhou, Lin, Chen, Xi, Wang, Jin, and Zhan, Ming-Sheng

Subjects
Physics - Atomic Physics
Abstract

Coriolis effect is an important error source in the weak equivalence principle (WEP) test using atom interferometer. In this paper, the problem of Coriolis error in WEP test is studied theoretically and experimentally. In theoretical simulation, Coriolis effect is analyzed by establishing an error model. The measurement errors of Eotvos coefficient (eta) in WEP test related to experimental parameters, such as horizontal-velocity difference and horizontal-position difference of atomic clouds, horizontal-position difference of detectors and rotation compensation of Raman laser's mirror are calculated. In experimental investigation, the position difference between Rb-85 and Rb-87 atomic clouds is reduced to 0.1 mm by optimizing the experimental parameters, an alternating detection method is used to suppress the error caused by detection position difference, thus the Coriolis error related to atomic clouds and detectors is eliminated to 1.1E-9. This Coriolis error is further corrected by compensating the rotation of Raman laser's mirror, and the total uncertainty of eta measurement related to Coriolis effect is reduced as 4.4E-11., Comment: 15 pages, 9 figures

Published
2020
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50. Decoy-State Quantum Key Distribution over a Long-Distance High-Loss Underwater Free-Space Channel

Author

Hu, Cheng-Qiu, Yan, Zeng-Quan, Gao, Jun, Li, Zhan-Ming, Zhou, Heng, Dou, Jian-Peng, and Jin, Xian-Min

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

Atmospheric free space and fiber have been widely exploited as the channels for quantum communication, and have enabled inter-continent and inter-city applications. Air-sea free-space channel, being capable of linking the satellite-based quantum resource and underwater vehicle, has now become the last piece of the puzzle in building global quantum communication network. However, long-distance quantum communication penetrating water up to tens to hundreds of meters is extremely challenging due to the inevitable high loss. Here, we present an experimental demonstration of underwater decoy-state quantum key distribution against high loss, meanwhile keep a low quantum bit error rate less than 2.5% for different distances. By directly modulating blue-green lasers at a high speed of 50MHz and decoy-state protocol, we are able to for the first time reach a long-distance quantum key distribution that is unconditionally secure and can enable real-life air-sea quantum communication tasks. The demonstrated distance, even in coastal water of Jerlov types 2C, is up to 30 meters, about one-order improvement over the proof-in-principle demonstrations in previous experiments, and the channel loss is equivalent to 345-meter-long clean seawater of Jerlov type I, representing a key step forward to practical air-sea quantum communication., Comment: 9 pages, 8 figures, 3 tables

Published
2020
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