Search

Your search keyword '"Jidong Lv"' showing total 29 results
Start Over Author "Jidong Lv" Publication Year Range Last 3 years
29 results on '"Jidong Lv"'

1. A Study of Unilateral Upper Limb Fine Motor Imagery Decoding Using Frequency-Band Attention Network

Author

Tianyu Shi, Xiang Gu, Hui Bi, Jidong Lv, Yan Liu, Yakang Dai, and Ling Zou

Subjects
Brain–computer interface, upper limb rehabilitation, EEG, fine motor imagery, deep learning, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Brain-computer interface (BCI) based motor imagery (MI) can assist stroke patients in upper limb rehabilitation and help restore motor function to a certain extent. However, the classical MI paradigm distinguishes different limbs and cannot effectively meet the needs of upper limb rehabilitation training for patients. Therefore, this paper designed a new paradigm for three motor imagery actions targeting different joints of the unilateral upper limb, and electroencephalogram (EEG) data from 20 healthy participants were collected for research analysis. A deep neural network model combining an attention mechanism for multiple frequency bands and a deep convolutional network were proposed to adaptively assign weight to the EEG data in different frequency bands. Then feature extraction was performed for each frequency band to learn further and to classify features. This model can obtain an average accuracy of 69.2% for the subject-independent case with the triple classification in the designed fine motor imagery (FMI) dataset, which is better than other controlled methods. Furthermore, ablation experiments were conducted for each module, demonstrating the effectiveness of each module. These results manifest the feasibility of our proposed method and the potential of FMI paradigm for BCI, providing a new training tool for upper limb rehabilitation after stroke.

Published
2024
Full Text
View/download PDF

2. A multi-feature fusion decoding study for unilateral upper-limb fine motor imagery

Author

Liangyu Yang, Tianyu Shi, Jidong Lv, Yan Liu, Yakang Dai, and Ling Zou

Subjects
brain-computer interface, upper limb rehabilitation, unilateral fine motor imagery, multi-domain fusion, Biotechnology, TP248.13-248.65, Mathematics, QA1-939
Abstract

To address the fact that the classical motor imagination paradigm has no noticeable effect on the rehabilitation training of upper limbs in patients after stroke and the corresponding feature extraction algorithm is limited to a single domain, this paper describes the design of a unilateral upper-limb fine motor imagination paradigm and the collection of data from 20 healthy people. It presents a feature extraction algorithm for multi-domain fusion and compares the common spatial pattern (CSP), improved multiscale permutation entropy (IMPE) and multi-domain fusion features of all participants through the use of decision tree, linear discriminant analysis, naive Bayes, a support vector machine, k-nearest neighbor and ensemble classification precision algorithms in the ensemble classifier. For the same subject, the average classification accuracy improvement of the same classifier for multi-domain feature extraction relative to CSP feature results went up by 1.52%. The average classification accuracy improvement of the same classifier went up by 32.87% relative to the IMPE feature classification results. This study's unilateral fine motor imagery paradigm and multi-domain feature fusion algorithm provide new ideas for upper limb rehabilitation after stroke.

Published
2023
Full Text
View/download PDF

3. DM-DQN: Dueling Munchausen deep Q network for robot path planning

Author

Yuwan Gu, Zhitao Zhu, Jidong Lv, Lin Shi, Zhenjie Hou, and Shoukun Xu

Subjects
Deep reinforcement learning, DM-DQN, Path planning, Dueling network, Electronic computers. Computer science, QA75.5-76.95, Information technology, T58.5-58.64
Abstract

Abstract In order to achieve collision-free path planning in complex environment, Munchausen deep Q-learning network (M-DQN) is applied to mobile robot to learn the best decision. On the basis of Soft-DQN, M-DQN adds the scaled log-policy to the immediate reward. The method allows agent to do more exploration. However, the M-DQN algorithm has the problem of slow convergence. A new and improved M-DQN algorithm (DM-DQN) is proposed in the paper to address the problem. First, its network structure was improved on the basis of M-DQN by decomposing the network structure into a value function and an advantage function, thus decoupling action selection and action evaluation and speeding up its convergence, giving it better generalization performance and enabling it to learn the best decision faster. Second, to address the problem of the robot’s trajectory being too close to the edge of the obstacle, a method of using an artificial potential field to set a reward function is proposed to drive the robot’s trajectory away from the vicinity of the obstacle. The result of simulation experiment shows that the method learns more efficiently and converges faster than DQN, Dueling DQN and M-DQN in both static and dynamic environments, and is able to plan collision-free paths away from obstacles.

Published
2022
Full Text
View/download PDF

4. Multi-Region and Multi-Band Electroencephalogram Emotion Recognition Based on Self-Attention and Capsule Network

Author

Sheng Ke, Chaoran Ma, Wenjie Li, Jidong Lv, and Ling Zou

Subjects
EEG, emotion recognition, Transformer, capsule network, brain region, frequency band, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999
Abstract

Research on emotion recognition based on electroencephalogram (EEG) signals is important for human emotion detection and improvements in mental health. However, the importance of EEG signals from different brain regions and frequency bands for emotion recognition is different. For this problem, this paper proposes the Capsule–Transformer method for multi-region and multi-band EEG emotion recognition. First, the EEG features are extracted from different brain regions and frequency bands and combined into feature vectors which are input into the fully connected network for feature dimension alignment. Then, the feature vectors are inputted into the Transformer for calculating the self-attention of EEG features among different brain regions and frequency bands to obtain contextual information. Finally, utilizing capsule networks captures the intrinsic relationship between local and global features. It merges features from different brain regions and frequency bands, adaptively computing weights for each brain region and frequency band. Based on the DEAP dataset, experiments show that the Capsule–Transformer method achieves average classification accuracies of 96.75%, 96.88%, and 96.25% on the valence, arousal, and dominance dimensions, respectively. Furthermore, in emotion recognition experiments conducted on individual brain regions or frequency bands, it was observed that the frontal lobe exhibits the highest average classification accuracy, followed by the parietal, temporal, and occipital lobes. Additionally, emotion recognition performance is superior for high-frequency band EEG signals compared to low-frequency band signals.

Published
2024
Full Text
View/download PDF

5. Prediction of hand grip strength based on surface electromyographic signals

Author

Jidong Lv, Yang Yang, Liangliang Niu, XiaoQin Sun, Lingyun Wang, Wei Lin, Hailong Rong, and Ling Zou

Subjects
sEMG, Prediction of hand grip strength, Sparrow search algorithm, Support vector regression, Electronic computers. Computer science, QA75.5-76.95
Abstract

The activity status of muscles in real-time should be obtained in hand rehabilitation training to adjust the auxiliary grip-strength value with a good hand grip-strength prediction model. Surface electromyography (sEMG) has great advantages in reflecting human hand motions noninvasively. Therefore, based on sEMG, the work proposed a hand grip-strength prediction method optimizing the support vector regression (SVR) model through Sparrow Search Algorithm (SSA). First, the time domain characteristics were extracted from sEMG signals, and grip-strength signals were interpolated by the cubic spline function to extract the average value of grip-strength signals. Then Pearson’s correlation coefficient was used to select appropriate feature combinations to enter the SSA-SVR model for grip-strength prediction. Finally, particle swarm optimization (PSO) and genetic algorithm (GA) were used to optimize the SVR model, and the effectiveness of the SSA-SVR model was verified by comparison. Random forest (RF) with SSA algorithm and BP neural network models was optimized to test the effect of SSA on improving the performance of the SVR model. The performance of the SSA-SVR model was better than that of other regression prediction models, with a root mean square error (RMSE) of 0.5054, an average absolute error (MAE) of 0.3242, an average absolute percentage error (MAPE) of 0.0864, and an accuracy (R2) of 93.2%. It can accurately predict the hand grip-strength value, which is suitable for hand rehabilitation training.

Published
2023
Full Text
View/download PDF

6. Computational Efficient Motion Planning Method for Automated Vehicles Considering Dynamic Obstacle Avoidance and Traffic Interaction

Author

Yuxiang Zhang, Jiachen Wang, Jidong Lv, Bingzhao Gao, Hongqing Chu, and Xiaoxiang Na

Subjects
autonomous vehicles, trajectory planning, model predictive control, Chemical technology, TP1-1185
Abstract

In complex driving scenarios, automated vehicles should behave reasonably and respond adaptively with high computational efficiency. In this paper, a computational efficient motion planning method is proposed, which considers traffic interaction and accelerates calculation. Firstly, the behavior is decided by connecting the points on the unequally divided road segments and lane centerlines, which simplifies the decision-making process in both space and time span. Secondly, as the dynamic vehicle model with changeable longitudinal velocity is considered in the trajectory generation module, the C/GMRES algorithm is used to accelerate the calculation of trajectory generation and realize on-line solving in nonlinear model predictive control. Meanwhile, the motion of other traffic participants is more accurately predicted based on the driver’s intention and kinematics vehicle model, which enables the host vehicle to obtain a more reasonable behavior and trajectory. The simulation results verify the effectiveness of the proposed method.

Published
2022
Full Text
View/download PDF

7. Toward the Trajectory Predictor for Automatic Train Operation System Using CNN–LSTM Network

Author

Yijuan He, Jidong Lv, Hongjie Liu, and Tao Tang

Subjects
deep learning, CNN–LSTM model, virtual coupling, spatiotemporal data mining, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841
Abstract

The accurate trajectory of the train ahead with more dynamic behaviour, such as train position, speed, acceleration, etc., is the critical issue of virtual coupling for future railways, which can drastically reduce their headways and increase line capacity. This paper presents an integrated convolutional neural network (CNN) and long short-term memory (LSTM) hybrid model for the task of trajectory prediction. A CNN–LSTM hybrid algorithm has been proposed. The model employs CNN and LSTM to extract the spatial dimension feature of the trajectory and the long-term dependencies of train trajectory data, respectively. The proposed CNN–LSTM model has superiority in achieving collaborative data mining on spatiotemporal measurement data to simultaneously learn spatial and temporal features from phasor measurement unit data. Therefore, the high-precision prediction of the train trajectory prediction is achieved based on the sufficient fusion of the above features. We use real automatic train operation (ATO) collected data for experiments and compare the proposed method with recurrent neural networks (RNN), recurrent neural networks (GRU), LSTM, and stateful-LSTM models on the same data sets. Experimental results show that the prediction performance of long-term trajectories is satisfyingly accurate. The root mean square error (RMSE) error can be reduced to less than 0.21 m, and the hit rate achieves 93% when the time horizon increases to 4S, respectively.

Published
2022
Full Text
View/download PDF

8. Communication-Based Train Control with Dynamic Headway Based on Trajectory Prediction

Author

Yijuan He, Jidong Lv, and Tao Tang

Subjects
LSTM-KF model, relative moving block, dynamic headway, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841
Abstract

Rail transit plays a significant role in the operation of an efficient and effective urban public transportation system. Safety and capacity are some of the most crucial objectives in railway operations. The communication-based train control (CBTC) system is a continuous and automatic train control system that realizes constant and high-capacity train ground two-way communication. In this study, a dynamic headway model of the ‘softwall’ moving-block approach is proposed for CBTC to increase the track capacity and improve dispatching efficiency based on the train trajectory prediction. For this precise trajectory prediction task, we introduce a hybrid trajectory prediction model to combine Long Short-term memory (LSTM) and Kalman Filter (KF) to extract the train’s local data features and learn the long-term dependencies, respectively. Then we present a dynamic headway model to maximize the train headway and reduce the track distance. The leading trains’ information is used to construct the iterative learning control strategy, and the predicted trajectory is input into the algorithm of the headway model. We use a simulation model of the rail network in Chengdu to demonstrate the effectiveness of our proposed approach. The results show the Mean Absolute Error (MAE) of the predicted trajectory retreated to 93.97 cm and reductions in operation headway of at least 64.33% under the dynamic headway model versus the traditional moving-block model.

Published
2022
Full Text
View/download PDF

23. A multi-feature fusion decoding study for unilateral upper-limb fine motor imagery

Author

Liangyu Yang, Tianyu Shi, Jidong Lv, Yan Liu, Yakang Dai, and Ling Zou

Subjects
Computational Mathematics, Applied Mathematics, Modeling and Simulation, General Medicine, General Agricultural and Biological Sciences
Abstract

To address the fact that the classical motor imagination paradigm has no noticeable effect on the rehabilitation training of upper limbs in patients after stroke and the corresponding feature extraction algorithm is limited to a single domain, this paper describes the design of a unilateral upper-limb fine motor imagination paradigm and the collection of data from 20 healthy people. It presents a feature extraction algorithm for multi-domain fusion and compares the common spatial pattern (CSP), improved multiscale permutation entropy (IMPE) and multi-domain fusion features of all participants through the use of decision tree, linear discriminant analysis, naive Bayes, a support vector machine, k-nearest neighbor and ensemble classification precision algorithms in the ensemble classifier. For the same subject, the average classification accuracy improvement of the same classifier for multi-domain feature extraction relative to CSP feature results went up by 1.52%. The average classification accuracy improvement of the same classifier went up by 32.87% relative to the IMPE feature classification results. This study's unilateral fine motor imagery paradigm and multi-domain feature fusion algorithm provide new ideas for upper limb rehabilitation after stroke.

Published
2022

27. Dynamic functional connectivity changes of resting-state brain network in attention-deficit/hyperactivity disorder

Author

Zhihao Zhu, Hongwei Wang, Hui Bi, Jidong Lv, Xiaotong Zhang, Suhong Wang, and Ling Zou

Subjects
Behavioral Neuroscience, Brain Mapping, Attention Deficit Disorder with Hyperactivity, Neural Pathways, Humans, Brain, Child, Magnetic Resonance Imaging
Abstract

Patients with attention-deficit/hyperactivity disorder (ADHD) have shown abnormal functional connectivity and network disruptions at the whole-brain static level. However, the changes in brain networks in ADHD patients from dynamic functional connectivity (DFC) perspective have not been fully understood. Accordingly, we executed DFC analysis on resting-state fMRI data of 25 ADHD patients and 27 typically developing (TD) children. A sliding window and Pearson correlation were used to construct the dynamic brain network of all subjects. The k-means+ + clustering method was used to recognize three recurring DFC states, and finally, the mean dwell time, the fraction of time spent for each state, and graph theory metrics were quantified for further analysis. Our results showed that ADHD patients had abnormally increased mean dwell time and the fraction of time spent in state 2, which reached a significant level (p 0.05). In addition, a weak correlation between the default mode network was associated in three states, and the positive correlations between visual network and attention network were smaller than TD in three states. Finally, the integration of each network node of ADHD in state 2 is more potent than that of TD, and the degree of node segregation is smaller than that of TD. These findings provide new evidence for the DFC study of ADHD; dynamic changes may better explain the developmental delay of ADHD and have particular significance for studying neurological mechanisms and adjuvant therapy of ADHD.

Published
2022

28. A cooperative collision-avoidance control methodology for virtual coupling trains

Author

Shuai Su, Wentao Liu, Qingyang Zhu, Ruoqing Li, Tao Tang, and Jidong Lv

Subjects
Public Health, Environmental and Occupational Health, Accidents, Traffic, Humans, Human Factors and Ergonomics, Safety, Risk, Reliability and Quality, Algorithms
Abstract

To further improve the line transport capacity, virtual coupling has become a frontier hot topic in the field of rail transit. Specially, the safe and efficient following control strategy based on relative distance braking mode (RDBM) is one of the core technologies. This paper innovatively proposes a cooperative collision-avoidance control methodology, which can enhance the operation efficiency on the premise of ensuring the safety. Firstly, a novel framework for the RDBM based on the predicted trajectory of the preceding train is proposed for the train collision-avoidance control. To reduce the train following distance, a cooperative control model is further proposed and is formulated as a Markov decision process. Then, the Deep-Q-Network (DQN) algorithm is introduced to solve the efficient control problem by learning the safe and efficient control strategy for the following train where the critical elements of the reinforcement learning framework are designed. Finally, experimental simulations are conducted based on the simulated environment to illustrate the effectiveness of the proposed approach. Compared with the absolute distance braking mode (ADBM), the minimum following distance between the adjacent trains can be reduced by 70.23% on average via the proposed approach while the safety can be guaranteed.

Published
2021

Catalog

Books, media, physical & digital resources
See catalog results