Search

Your search keyword '"Xue, Shibei"' showing total 134 results
Start Over Author "Xue, Shibei"
134 results on '"Xue, Shibei"'

1. Arbitrary State Transition of Open Qubit System Based on Switching Control

Author

Wu, Guangpu, Xue, Shibei, Ma, Shan, Kuang, Sen, Dong, Daoyi, and Petersen, Ian R.

Subjects
Quantum Physics, Electrical Engineering and Systems Science - Systems and Control
Abstract

We present a switching control strategy based on Lyapunov control for arbitrary state transitions in open qubit systems. With coherent vector representation, we propose a switching control strategy, which can prevent the state of the qubit from entering invariant sets and singular value sets, effectively driving the system ultimately to a sufficiently small neighborhood of target states. In comparison to existing works, this control strategy relaxes the strict constraints on system models imposed by special target states. Furthermore, we identify conditions under which the open qubit system achieves finite-time stability (FTS) and finite-time contractive stability (FTCS), respectively. This represents a critical improvement in quantum state transitions, especially considering the asymptotic stability of arbitrary target states is unattainable in open quantum systems. The effectiveness of our proposed method is convincingly demonstrated through its application in a qubit system affected by various types of decoherence, including amplitude, dephasing and polarization decoherence., Comment: 12 pages, 7 figures

Published
2024

2. Quantum gyroscopes based on double-mode surface-acoustic-wave cavities

Author

Zhu, Yuting, Xue, Shibei, Ju, Fangfang, and Yuan, Haidong

Subjects
Quantum Physics
Abstract

Recent progress shows that a surface-acoustic-wave (SAW) cavity can not only induce quantum acoustic dynamics but also can form optomechanical-like systems. Its operating frequencies in the microwave band make it resistant to the thermal noise of surrounding environments, while its radiation-pressure couplings make it susceptible to weak forces. Based on these advantages, we propose a gyroscope comprising coupled microwave-SAW cavities. In this paper, we systematically consider the three indices including range, signal-to-noise ratio, and sensitivity, which are the most important to gyroscopes but only partially considered in existing works. Additionally, we establish the fundamental limits of sensitivity when the quantum input is in the vacuum state and the squeezed vacuum state. We find that squeezing improves sensitivity and can surpass the standard quantum limit. However, this improvement can only reach up to $\sqrt{2}/2$ even as the squeezed parameter approaches infinity, which is rarely noted in recent works. Finally, we also offer analytical constraints for cooperativity and squeezed parameters. These constraints can be utilized to design gyroscopes based on coupled cavities in experiments., Comment: 12 pages, 5 figures

Published
2024

3. Robust quantum teleportation via a non-Markovian channel

Author

Wang, Yanfang, Xue, Shibei, Song, Hongbin, and Jiang, Min

Subjects
Quantum Physics
Abstract

In this paper, we propose a non-Markovian quantum channel approach to mitigating the degradation of the average fidelity in continuous-variable quantum teleportation. The non-Markovian quantum channel is modeled by an augmented system, where ancillary systems are introduced to represent the internal modes of non-Markovian environments. With a proper non-Markovianity, enhanced effects of the channels on continuous-variable quantum teleportation are observed. Also, the logarithmic negativity of entangled states can be effectively maintained so that the decay of the average fidelity of quantum teleportation is mitigated. In addition, the analysis on different teleported quantum states shows that coherent states exhibit stronger robustness than those of squeezed states and cat states in quantum teleportation with a non-Markovian channel., Comment: 16 pages, 16 figures

Published
2023

4. Local to Global: A Distributed Quantum Approximate Optimization Algorithm for Pseudo-Boolean Optimization Problems

Author

Yue, Bo, Xue, Shibei, Pan, Yu, Jiang, Min, and Dong, Daoyi

Subjects
Quantum Physics
Abstract

With the rapid advancement of quantum computing, Quantum Approximate Optimization Algorithm (QAOA) is considered as a promising candidate to demonstrate quantum supremacy, which exponentially solves a class of Quadratic Unconstrained Binary Optimization (QUBO) problems. However, limited qubit availability and restricted coherence time challenge QAOA to solve large-scale pseudo-Boolean problems on currently available Near-term Intermediate Scale Quantum (NISQ) devices. In this paper, we propose a distributed QAOA which can solve a general pseudo-Boolean problem by converting it to a simplified Ising model. Different from existing distributed QAOAs' assuming that local solutions are part of a global one, which is not often the case, we introduce community detection using Louvian algorithm to partition the graph where subgraphs are further compressed by community representation and merged into a higher level subgraph. Recursively and backwards, local solutions of lower level subgraphs are updated by heuristics from solutions of higher level subgraphs. Compared with existing methods, our algorithm incorporates global heuristics into local solutions such that our algorithm is proven to achieve a higher approximation ratio and outperforms across different graph configurations. Also, ablation studies validate the effectiveness of each component in our method., Comment: 12 pages, 6 figures

Published
2023

5. Quantum Approximate Optimization Algorithm in Non-Markovian Quantum Systems

Author

Yue, Bo, Xue, Shibei, Pan, Yu, and Jiang, Min

Subjects
Quantum Physics
Abstract

Although quantum approximate optimization algorithm (QAOA) has demonstrated its quantum supremacy, its performance on Noisy Intermediate-Scale Quantum (NISQ) devices would be influenced by complicated noises, e.g., quantum colored noises. To evaluate the performance of QAOA under these noises, this paper presents a framework for running QAOA on non-Markovian quantum systems which are represented by an augmented system model. In this model, a non-Markovian environment carrying quantum colored noises is modelled as an ancillary system driven by quantum white noises which is directly coupled to the corresponding principal system; i.e., the computational unit for the algorithm. With this model, we mathematically formulate QAOA as piecewise Hamiltonian control of the augmented system, where we also optimize the control depth to fit into the circuit depth of current quantum devices. For efficient simulation of QAOA in non-Markovian quantum systems, a boosted algorithm using quantum trajectory is further presented. Finally, we show that non-Markovianity can be utilized as a quantum resource to achieve a relatively good performance of QAOA, which is characterized by our proposed exploration rate., Comment: 27 pages, 8 figures, accepted by Physica Scripta

Published
2022

6. Efficient Depth Selection for the Implementation of Noisy Quantum Approximate Optimization Algorithm

Author

Pan, Yu, Tong, Yifan, Xue, Shibei, and Zhang, Guofeng

Subjects
Quantum Physics
Abstract

Noise on near-term quantum devices will inevitably limit the performance of Quantum Approximate Optimization Algorithm (QAOA). One significant consequence is that the performance of QAOA may fail to monotonically improve with depth. In particular, optimal depth can be found at a certain point where the noise effects just outweigh the benefits brought by increasing the depth. In this work, we propose to use the model selection algorithm to identify the optimal depth with a few iterations of regularization parameters. Numerical experiments show that the algorithm can efficiently locate the optimal depth under relaxation and dephasing noises., Comment: Submitted. Comments welcome!

Published
2022

7. HRPose: Real-Time High-Resolution 6D Pose Estimation Network Using Knowledge Distillation

Author

Guan, Qi, Sheng, Zihao, and Xue, Shibei

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning, Computer Science - Robotics
Abstract

Real-time 6D object pose estimation is essential for many real-world applications, such as robotic grasping and augmented reality. To achieve an accurate object pose estimation from RGB images in real-time, we propose an effective and lightweight model, namely High-Resolution 6D Pose Estimation Network (HRPose). We adopt the efficient and small HRNetV2-W18 as a feature extractor to reduce computational burdens while generating accurate 6D poses. With only 33\% of the model size and lower computational costs, our HRPose achieves comparable performance compared with state-of-the-art models. Moreover, by transferring knowledge from a large model to our proposed HRPose through output and feature-similarity distillations, the performance of our HRPose is improved in effectiveness and efficiency. Numerical experiments on the widely-used benchmark LINEMOD demonstrate the superiority of our proposed HRPose against state-of-the-art methods., Comment: 8 pages, 4 figures, and 5 tables, accepted by Chinese Journal of Electronics

Published
2022
Full Text
View/download PDF

8. Global Update Guided Federated Learning

Author

Wu, Qilong, Liu, Lin, and Xue, Shibei

Subjects
Computer Science - Machine Learning, Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

Federated learning protects data privacy and security by exchanging models instead of data. However, unbalanced data distributions among participating clients compromise the accuracy and convergence speed of federated learning algorithms. To alleviate this problem, unlike previous studies that limit the distance of updates for local models, we propose global-update-guided federated learning (FedGG), which introduces a model-cosine loss into local objective functions, so that local models can fit local data distributions under the guidance of update directions of global models. Furthermore, considering that the update direction of a global model is informative in the early stage of training, we propose adaptive loss weights based on the update distances of local models. Numerical simulations show that, compared with other advanced algorithms, FedGG has a significant improvement on model convergence accuracies and speeds. Additionally, compared with traditional fixed loss weights, adaptive loss weights enable our algorithm to be more stable and easier to implement in practice., Comment: 6 pages, 3 figures, and 4 tables. Accepted by Chinese Control Conference 2022, Hefei, P. R. China

Published
2022

9. Giant-cavity-based quantum sensors with enhanced performance

Author

Zhu, Yu Ting, Wu, Rebing, Peng, Zhihui, and Xue, Shibei

Subjects
Quantum Physics, Physics - Optics
Abstract

Recent progresses have revealed that quantum systems with multiple position-dependent couplings, e.g., giant atoms, can exhibit some unconventional phenomena, such as non-exponential decay etc. However, their potential applications are still open questions. In this paper, we propose a giant-cavity-based quantum sensor for the first time, whose performance can be greatly enhanced compared to traditional cavity-based sensors. In our proposal, two cavities couple to a dissipative reservoir at multiple points while they couple to a gain reservoir in a single-point way. To detecting a unknown parameter using this sensor, a waveguide is coupled to one of the cavities where detecting fields can pass through for homodyne detection. We find that multiple position-dependent couplings can induce an inherent non-reciprocal coupling between the cavities, which can enhance the performance of sensors. Output noise in our scheme can be reduced to the shot noise level, which is about one order magnitude lower than the results in Ref. [Nature Communications, 2018, 9, 4320.]. Besides, the signal-to-noise ratio per photon is also enhanced by about one order of magnitude. These results show that the multiple-point-coupling structure is beneficial to nowadays quantum devices., Comment: 15 pages, 6 figures, submitted to Frontiers in Physics ( Research Topic on Quantum Optics with Giant Atoms: Theory, Experiment and Application)

Published
2022
Full Text
View/download PDF

10. A Cooperation-Aware Lane Change Method for Autonomous Vehicles

Author

Sheng, Zihao, Liu, Lin, Xue, Shibei, Zhao, Dezong, Jiang, Min, and Li, Dewei

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence
Abstract

Lane change for autonomous vehicles (AVs) is an important but challenging task in complex dynamic traffic environments. Due to difficulties in guarantee safety as well as a high efficiency, AVs are inclined to choose relatively conservative strategies for lane change. To avoid the conservatism, this paper presents a cooperation-aware lane change method utilizing interactions between vehicles. We first propose an interactive trajectory prediction method to explore possible cooperations between an AV and the others. Further, an evaluation is designed to make a decision on lane change, in which safety, efficiency and comfort are taken into consideration. Thereafter, we propose a motion planning algorithm based on model predictive control (MPC), which incorporates AV's decision and surrounding vehicles' interactive behaviors into constraints so as to avoid collisions during lane change. Quantitative testing results show that compared with the methods without an interactive prediction, our method enhances driving efficiencies of the AV and other vehicles by 14.8$\%$ and 2.6$\%$ respectively, which indicates that a proper utilization of vehicle interactions can effectively reduce the conservatism of the AV and promote the cooperation between the AV and others., Comment: 13 pages, 14 figures, 2 tables, submitted to IEEE Transactions on Vehicular Technology

Published
2022

11. Graph-Based Spatial-Temporal Convolutional Network for Vehicle Trajectory Prediction in Autonomous Driving

Author

Sheng, Zihao, Xu, Yunwen, Xue, Shibei, and Li, Dewei

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence, Computer Science - Robotics
Abstract

Forecasting the trajectories of neighbor vehicles is a crucial step for decision making and motion planning of autonomous vehicles. This paper proposes a graph-based spatial-temporal convolutional network (GSTCN) to predict future trajectory distributions of all neighbor vehicles using past trajectories. This network tackles the spatial interactions using a graph convolutional network (GCN), and captures the temporal features with a convolutional neural network (CNN). The spatial-temporal features are encoded and decoded by a gated recurrent unit (GRU) network to generate future trajectory distributions. Besides, we propose a weighted adjacency matrix to describe the intensities of mutual influence between vehicles, and the ablation study demonstrates the effectiveness of our proposed scheme. Our network is evaluated on two real-world freeway trajectory datasets: I-80 and US-101 in the Next Generation Simulation (NGSIM).Comparisons in three aspects, including prediction errors, model sizes, and inference speeds, show that our network can achieve state-of-the-art performance., Comment: 11 pages, 9 figures, 8 tables, submitted to IEEE Trans. Intelligent Transportation Systems

Published
2021
Full Text
View/download PDF

12. Spatial Non-Locality Induced Non-Markovian EIT in a Single Giant Atom

Author

Zhu, Yuting, Wu, Rebing, and Xue, Shibei

Subjects
Quantum Physics
Abstract

In recent experiments, electromagnetically induced transparency (EIT) were observed with giant atoms, but nothing unconventional were found from the transmission spectra. In this letter, we show that unconventional EIT does exist in giant atoms, and indicate why it has not been observed so far. Different from these existing works, this letter presents a consistent theory including a real space method and a time delayed master equation for observing unconventional EIT. We discover that this phenomenon is a quantum effect which cannot be correctly described in a semi-classical way as those in recent works. Our theory shows that it can be observed when the time delay between two neighboring coupling points is comparable to the relaxation time of the atom, which is crucial for a future experimental observation. This new phenomenon results from inherent non-locality of the giant atom, which physically forces propagating fields to be standing waves in space and the atom exhibiting retardations in time. Our theory establishes a framework for application of nonlocal systems to quantum information processing., Comment: 6 pages, 3 figures, Comments are welcome

Published
2021
Full Text
View/download PDF

13. Numerical detection of Gaussian entanglement and its application to the identification of bound entangled Gaussian states

Author

Ma, Shan, Xue, Shibei, Guo, Yu, and Shu, Chuan-Cun

Subjects
Quantum Physics, Mathematics - Optimization and Control
Abstract

We present a numerical method for solving the separability problem of Gaussian quantum states in continuous-variable quantum systems. We show that the separability problem can be cast as an equivalent problem of determining the feasibility of a set of linear matrix inequalities. Thus, it can be efficiently solved using existent numerical solvers. We apply this method to the identification of bound entangled Gaussian states. We show that the proposed method can be used to identify bound entangled Gaussian states that could be simple enough to be producible in quantum optics., Comment: 14 pages

Published
2020
Full Text
View/download PDF

14. An inverse-system method for identification of damping rate functions in non-Markovian quantum systems

Author

Xue, Shibei, Tan, Lingyu, Wu, Rebing, Jiang, Min, and Petersen, Ian R.

Subjects
Quantum Physics, Electrical Engineering and Systems Science - Systems and Control
Abstract

Identification of complicated quantum environments lies in the core of quantum engineering, which systematically constructs an environment model with the aim of accurate control of quantum systems. In this paper, we present an inverse-system method to identify damping rate functions which describe non-Markovian environments in time-convolution-less master equations. To access information on the environment, we couple a finite-level quantum system to the environment and measure time traces of local observables of the system. By using sufficient measurement results, an algorithm is designed, which can simultaneously estimate multiple damping rate functions for different dissipative channels. Further, we show that identifiability for the damping rate functions corresponds to the invertibility of the system and a necessary condition for identifiability is also given. The effectiveness of our method is shown in examples of an atom and three-spin-chain non-Markovian systems., Comment: 9 pages, 10 figures

Published
2020
Full Text
View/download PDF

15. Towards Distributed Privacy-Preserving Prediction

Author

Lyu, Lingjuan, Law, Yee Wei, Ng, Kee Siong, Xue, Shibei, Zhao, Jun, Yang, Mengmeng, and Liu, Lei

Subjects
Computer Science - Cryptography and Security
Abstract

In privacy-preserving machine learning, individual parties are reluctant to share their sensitive training data due to privacy concerns. Even the trained model parameters or prediction can pose serious privacy leakage. To address these problems, we demonstrate a generally applicable Distributed Privacy-Preserving Prediction (DPPP) framework, in which instead of sharing more sensitive data or model parameters, an untrusted aggregator combines only multiple models' predictions under provable privacy guarantee. Our framework integrates two main techniques to guarantee individual privacy. First, we introduce the improved Binomial Mechanism and Discrete Gaussian Mechanism to achieve distributed differential privacy. Second, we utilize homomorphic encryption to ensure that the aggregator learns nothing but the noisy aggregated prediction. Experimental results demonstrate that our framework has comparable performance to the non-private frameworks and delivers better results than the local differentially private framework and standalone framework., Comment: To appear at SMC'20

Published
2019

16. A gradient algorithm for Hamiltonian identification of open quantum systems

Author

Xue, Shibei, Wu, Rebing, Li, Dewei, and Jiang, Min

Subjects
Quantum Physics, Electrical Engineering and Systems Science - Systems and Control
Abstract

In this paper, we present a gradient algorithm for identifying unknown parameters in an open quantum system from the measurements of time traces of local observables. The open system dynamics is described by a general Markovian master equation based on which the Hamiltonian identification problem can be formulated as minimizing the distance between the real time traces of the observables and those predicted by the master equation. The unknown parameters can then be learned with a gradient descent algorithm from the measurement data. We verify the effectiveness of our algorithm in a circuit QED system described by a Jaynes-Cumming model whose Hamiltonian identification has been rarely considered. We also show that our gradient algorithm can learn the spectrum of a non-Markovian environment based on an augmented system model., Comment: 9 pages, 7 figures, Comments are welcome

Published
2019
Full Text
View/download PDF

17. Quantum Hamiltonian Identification with Classical Colored Measurement Noise

Author

Tan, Lingyu, Dong, Daoyi, Li, Dewei, and Xue, Shibei

Subjects
Electrical Engineering and Systems Science - Systems and Control, Quantum Physics
Abstract

In this paper, we present a Hamiltonian identification method for a closed quantum system whose time trace observables are measured with colored measurement noise. The dynamics of the quantum system are described by a Liouville equation which can be converted to a coherence vector representation. Since the measurement process is disturbed by classical colored noise, we introduce an augmented system model to describe the total dynamics, where the classical colored noise is parameterized. Based on the augmented system model as well as the measurement data, we can find a realization of the quantum system with unknown parameters by employing an Eigenstate Realization Algorithm. The unknown parameters can be identified using a transfer-function-based technique. An example of a two-qubit system with colored measurement noise is demonstrated to verify the effectiveness of our method., Comment: 8 pages, 5 figures

Published
2019
Full Text
View/download PDF

19. Optimal identification of non-Markovian environments for spin chains

Author

Xue, Shibei, Zhang, Jun, and Petersen, Ian R.

Subjects
Quantum Physics
Abstract

Correlations of an environment are crucial for the dynamics of non-Markovian quantum systems, which may not be known in advance. In this paper, we propose a gradient algorithm for identifying the correlations in terms of time-varying damping rate functions in a time-convolution-less master equation for spin chains. By measuring time trace observables of the system, the identification procedure can be formulated as an optimization problem. The gradient algorithm is designed based on a calculation of the derivative of an objective function with respect to the damping rate functions, whose effectiveness is shown in a comparison to a differential approach for a two-qubit spin chain., Comment: 6 pages, 4 figures, accepted by IEEE Trans. on Control Systems Technology

Published
2018
Full Text
View/download PDF

20. Modelling and Filtering for Non-Markovian Quantum Systems

Author

Xue, Shibei, Nguyen, Thien, James, Matthew R., Shabani, Alireza, Ugrinovskii, Valery, and Petersen, Ian R.

Subjects
Quantum Physics, Mathematics - Optimization and Control
Abstract

This paper presents an augmented Markovian system model for non-Markovian quantum systems. In this augmented system model, ancillary systems are introduced to play the role of internal modes of the non-Markovian environment converting white noise to colored noise. Consequently, non-Markovian dynamics are represented as resulting from direct interaction of the principal system with the ancillary system. To demonstrate the utility of the proposed augmented system model, it is applied to design whitening quantum filters for non-Markovian quantum systems. Examples are presented to illustrate how whitening quantum filters can be utilized for estimating non-Markovian linear quantum systems and qubit systems. In particular, we showed that the augmented Markovian formulation can be used to theoretically model the environment for an observed non-Markovian behavior in a recent experiment on quantum dots [ Phys. Rev. Lett., 108:046807, 2012], Comment: 20 pages, 10 figures. Comments are welcome

Published
2017
Full Text
View/download PDF

22. Non-Markovian coherent feedback control of quantum dot systems

Author

Xue, Shibei, Wu, Re-Bing, Hush, Michael R., and Tarn, Tzyh-Jong

Subjects
Quantum Physics
Abstract

This paper presents a non-Markovian coherent feedback scheme to control single quantum dot systems. The feedback loop is closed via a quantum tunneling junction between the natural source and drain baths of the quantum dot. The exact feedback-controlled non-Markovian Langevin equation is derived for describing the dynamics of the quantum dot. To deal with the nonlinear memory function in the Langevin equation, we analyze the Green's function-based root locus, from which we show that the decoherence of the quantum dot can be suppressed via increasing the feedback coupling strength. This effectiveness of decoherence suppression induced by non-Markovian coherent feedback is verified by an example of single quantum dot systems., Comment: 9 pages, 5 figures

Published
2015
Full Text
View/download PDF

24. LQG feedback control of a class of linear non-Markovian quantum systems

Author

Xue, Shibei, James, Matthew R., Ugrinovskii, Valery, and Petersen, Ian R.

Subjects
Quantum Physics
Abstract

In this paper we present a linear quadratic Gaussian (LQG) feedback control strategy for a class of linear non-Markovian quantum systems. The feedback control law is designed based on the estimated states of a whitening quantum filter for an augmented Markovian model of the non-Markovian open quantum systems. In this augmented Markovian model, an ancillary system plays the role of internal modes of the environment converting white noise into Lorentzian noise and a principal system obeys non-Markovian dynamics due to the direct interaction with the ancillary system. The simulation results show the LQG controller with the whitening filter obtains a better control performance than that with a Markovian filter in the problem of minimizing the photon numbers of the principal system when the ancillary system is disturbed by thermal noise., Comment: 7 pages, 4 figures. arXiv admin note: text overlap with arXiv:1503.07999

Published
2015
Full Text
View/download PDF

25. Quantum filter for a non-Markovian single qubit system

Author

Xue, Shibei, James, Matthew R., Shabani, Alireza, Ugrinovskii, Valery, and Petersen, Ian R.

Subjects
Quantum Physics
Abstract

In this paper, a quantum filter for estimating the states of a non-Markovian qubit system is presented in an augmented Markovian system framework including both the qubit system of interest and multi-ancillary systems for representing the internal modes of the non-Markovian environment. The colored noise generated by the multi-ancillary systems disturbs the qubit system via a direct interaction. The resulting non-Markovian dynamics of the qubit is determined by a memory kernel function arising from the dynamics of the ancillary system. In principle, colored noise with arbitrary power spectrum can be generated by a combination of Lorentzian noises. Hence, the quantum filter can be constructed for the qubit disturbed by arbitrary colored noise and the conditional state of the qubit system can be obtained by tracing out the multi-ancillary systems. An illustrative example is given to show the non-Markovian dynamics of the qubit system with Lorentzian noise., Comment: arXiv admin note: text overlap with arXiv:1503.07999

Published
2015
Full Text
View/download PDF

26. Quantum filter for a class of non-Markovian quantum systems

Author

Xue, Shibei, James, Matthew R., Shabani, Alireza, Ugrinovskii, Valery, and Petersen, Ian R.

Subjects
Quantum Physics
Abstract

In this paper we present a Markovian representation approach to constructing quantum filters for a class of non-Markovian quantum systems disturbed by Lorenztian noise. An ancillary system is introduced to convert white noise into Lorentzian noise which is injected into a principal system via a direct interaction. The resulting dynamics of the principal system are non-Markovian, which are driven by the Lorentzian noise. By probing the principal system, a quantum filter for the augmented system can be derived from standard theory, where the conditional state of the principal system can be obtained by tracing out the ancillary system. An example is provided to illustrate the non-Markovian dynamics of the principal system., Comment: 8 pages, 7 figures

Published
2015
Full Text
View/download PDF

31. Asymmetric acoustic splitting with the dual-layers of binary metagratings.

Author

Liu, Zhengang, Chang, Shuai, Xue, Shibei, Ju, Fangfang, and Qian, Shengyou

Abstract

Here, we exhibit the asymmetric acoustic splitting with the dual-layers of binary metagratings (BMs), i.e., BM1 and BM2. For the positive incidence (PI) normally from the BM1 side, acoustic waves are freely transmitted through the BM1 and split into two beams with the transmitted angles at and , then the two beams are freely transmitted through the BM2 with the transmitted angles at and . For the negative incidence (NI) normally from the BM2 side, acoustic waves are wholly reflected. Hence, the asymmetric acoustic splitting is observed. Here, the dual-layers of BMs are exemplified by the coating cells with different period lengths. Excellent agreement can be observed between the numerical simulations and the theoretical analysis. Our proposal may be applied in noise control and acoustic communication. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

49. Eco-Driving of General Mixed Platoons With CAVs and HDVs

Author

Yang, Jinsong, Zhao, Dezong, Lan, Jianglin, Xue, Shibei, Zhao, Wenjing, Tian, Daxin, Zhou, Quan, and Song, Kang

Abstract

Eco-driving has been widely investigated over the last decade, but most studies focused on an individual vehicle or a vehicle platoon consisting of pure connected and automated vehicles (CAVs). Recently, mixed vehicle platoons consisting of both CAVs and human-driven vehicles (HDVs) have attracted much interest, considering the fact that HDVs will mix with CAVs in the traffic system for a long period. This paper proposes an eco-driving strategy for mixed platoons, composing of both offline planning and online tracking. In offline planning, an energy-efficient speed reference and a gearshift reference are determined by using the characteristics of each vehicle and future traffic information through dynamic programming. Offline planning optimised the vehicle speed and gearshift to allow the vehicle powertrain working at a high efficiency region. In online tracking, two different types of model predictive controls (MPCs) are proposed to control the CAVs in real-time. The MPCs are designed to achieve precise speed reference tracking performance and guarantee platoon string stability, respectively. Meanwhile, HDVs within the mixed platoon can be located anywhere in the platoon except working as the first vehicle to improve flexibility. Therefore, the proposed eco-driving strategy is applicable to mixed platoons with more general structures in ordering. The key contribution of this study is that the proposed eco-driving strategy can optimise the total fuel consumption for general mixed platoons. Simulation results show that the proposed eco-driving strategy improves the fuel economy of a mixed platoon by up to 6.39% compared to the benchmark conventional-adaptive cruise control strategies.

Published
2023
Full Text
View/download PDF

50. A Cooperation-Aware Lane Change Method for Automated Vehicles

Author

Sheng, Zihao, Liu, Lin, Xue, Shibei, Zhao, Dezong, Jiang, Min, and Li, Dewei

Abstract

Lane change for automated vehicles (AVs) is an important but challenging task in complex dynamic traffic environments. Due to difficulties in guaranteeing safety as well as a high efficiency, AVs are inclined to choose relatively conservative strategies for lane change. To avoid the conservatism, this paper presents a cooperation-aware lane change method utilizing interactions between vehicles. We first propose an interactive trajectory prediction method to explore possible cooperations between an AV and the others. Further, an evaluation on safety, efficiency and comfort is designed to make a decision on lane change. Thereafter, we propose a motion planning algorithm based on model predictive control (MPC), which incorporates AV’s decision and surrounding vehicles’ interactive behaviors into constraints so as to avoid collisions during lane change. Quantitative testing results show that compared with the methods without an interactive prediction, our method enhances driving efficiencies of the AV and other vehicles by 14.8% and 2.6%, respectively, which indicates that a proper utilization of vehicle interactions can effectively reduce the conservatism of the AV and promote the cooperation between the AV and others.

Published
2023
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results