Your search keyword '"Li, Fali"' showing total 5 results

1. Ultra-conformable Liquid Metal Particle Monolayer on Air/water Interface for Substrate-free E-tattoo

Author

Li, Fali, Lei, Wenjuan, Wang, Yuwei, Lu, Xingjian, Li, Shengbin, Xu, Feng, He, Zidong, Liu, Jinyun, Yang, Huali, Wu, Yuanzhao, Shang, Jie, Liu, Yiwei, and Li, Run-Wei

Subjects

FOS: Computer and information sciences, Computer Science - Human-Computer Interaction, FOS: Physical sciences, Physics - Applied Physics, Applied Physics (physics.app-ph), Human-Computer Interaction (cs.HC)

Abstract

Gallium-based liquid metal is getting increased attention in conformal flexible electronics for its high electrical conductivity, intrinsic deformability and biocompatibility. A series of flexible devices are developed based on the micro-particles of liquid metal. But it is still challenging to fabricate conformal liquid metal film with a large area and high uniformity. Interfacial self-assembly is a competitive candidate method. Traditional interfacial self-assembly methods have difficulties assembling liquid metal particles because the floating state of the high-density microparticles could be easily disturbed by gravity. Here, we realized the multi-size universal self-assembly (MUS) for liquid metal particles with various diameters (0~500{\mu}m). By introducing a simple z-axis undisturbed interfacial material releasing strategy, the interference of gravitational energy on the stability of floating particles is avoided. Benefits from this, the ultra-conformable monolayer film, with large area (>100 cm2) and high floating yield (50%~90%), can be fabricated by liquid metal particles. Furthermore, the monolayer can be conformally transferred to any interesting complex surface such as human skin and plant leaf, to fabricate substrate-free flexible devices. Without interference from the mechanical response of traditional substrate, the liquid metal e-tattoo is more user-friendly and can realize feel-less continuous monitoring.

Published

2023

2. PR-PL: A Novel Transfer Learning Framework with Prototypical Representation based Pairwise Learning for EEG-Based Emotion Recognition

Author

Zhou, Rushuang, Zhang, Zhiguo, Fu, Hong, Zhang, Li, Li, Linling, Huang, Gan, Dong, Yining, Li, Fali, Yang, Xin, and Liang, Zhen

Subjects

FOS: Computer and information sciences, ComputingMethodologies_PATTERNRECOGNITION, Computer Science - Human-Computer Interaction, Human-Computer Interaction (cs.HC)

Abstract

Affective brain-computer interfaces based on electroencephalography (EEG) is an important branch in the field of affective computing. However, individual differences and noisy labels seriously limit the effectiveness and generalizability of EEG-based emotion recognition models. In this paper, we propose a novel transfer learning framework with Prototypical Representation based Pairwise Learning (PR-PL) to learn discriminative and generalized prototypical representations for emotion revealing across individuals and formulate emotion recognition as pairwise learning for alleviating the reliance on precise label information. Extensive experiments are conducted on two benchmark databases under four cross-validation evaluation protocols (cross-subject cross-session, cross-subject within-session, within-subject cross-session, and within-subject within-session). The experimental results demonstrate the superiority of the proposed PR-PL against the state-of-the-arts under all four evaluation protocols, which shows the effectiveness and generalizability of PR-PL in dealing with the ambiguity of EEG responses in affective studies. The source code is available at https://github.com/KAZABANA/PR-PL.

Published

2022

3. The different brain areas occupied for integrating information of hierarchical linguistic units: a study based on EEG and TMS

Author

Y. Li, Y. Si, C. Chen, X. Huang, Q. Liu, D. Yao, Kimmo Alho, Y. Qiu, X. Zhang, Z. Cao, S. Gao, C. Pei, F. Li, N. Ding, P. Xu, Pei, Changfu, Qiu, Yuan, Li, Fali, Huang, Xunan, Si, Yajing, Li, Yuqin, Zhang, Xiabing, Chen, Chunli, Liu, Qiang, Cao, Zehong, Ding, Nai, Gao, Shan, Alho, Kimmo, Yao, Dezhong, and Xu, Peng

Subjects

Modality (human–computer interaction), Modalities, Chinese, medicine.diagnostic_test, Computer science, Cognitive Neuroscience, CTBS, Information processing, linguistic hierarchy, Experimental Psychology, Electroencephalography, Signal, Linguistics, Comprehension, Cellular and Molecular Neuroscience, transcranial magnetic stimulation, medicine, EEG, audio-visual integration, Sentence, 1109 Neurosciences, 1701 Psychology, 1702 Cognitive Sciences

Abstract

Human linguistic units are hierarchical, and our brain responds differently when processing linguistic units during sentence comprehension, especially when the modality of the received signal is different (auditory, visual, or audio-visual). However, it is unclear how the brain processes and integrates language information at different linguistic units (words, phrases, and sentences) provided simultaneously in audio and visual modalities. To address the issue, we presented participants with sequences of short Chinese sentences through auditory or visual or combined audio- visual modalities, while electroencephalographic responses were recorded. With a frequency tagging approach, we analyzed the neural representations of basic linguistic units (i.e., characters/monosyllabic words) and higher-level linguistic structures (i.e., phrases and sentences) across the three modalities separately. We found that audio-visual integration occurs at all linguistic units, and the brain areas involved in the integration varied across different linguistic levels. In particular, the integration of sentences activated the local left prefrontal area. Therefore, we used continuous theta-burst stimulation (cTBS) to verify that the left prefrontal cortex plays a vital role in the audio-visual integration of sentence information. Our findings suggest the advantage of bimodal language comprehension at hierarchical stages in language-related information processing and provide evidence for the causal role of the left prefrontal regions in processing information of audio-visual sentences.

Published

2022

4. Identification of the General Anesthesia Induced Loss of Consciousness by Cross Fuzzy Entropy-Based Brain Network

Author

Tao Xu, Yueheng Peng, Dezhong Yao, Yuqin Li, Dongrui Gao, Peng Xu, Fali Li, Hui Zheng, Yangsong Zhang, Lin Jiang, Zehong Cao, Tifei Yuan, Cunbo Li, Li, Fali, Li, Yuqin, Zheng, Hui, Jiang, Lin, Gao, Dongrui, Li, Cunbo, Peng, Yueheng, Cao, Zehong, Zhang, Yangsong, Yao, Dezhong, Xu, Tao, Yuan, Ti Fei, and Xu, Peng

Subjects

Consciousness, Computer science, media_common.quotation_subject, Entropy, Biomedical Engineering, Unconsciousness, Electroencephalography, Anesthesia, General, Fuzzy logic, loss of consciousness, 0903 Biomedical Engineering, 0906 Electrical and Electronic Engineering, Internal Medicine, medicine, Humans, Entropy (energy dispersal), Time point, Cluster analysis, Propofol, media_common, Resting state fMRI, medicine.diagnostic_test, General Neuroscience, Rehabilitation, cross fuzzy entropy, Brain, general anesthesia, time-varying networks, Anesthesia, medicine.symptom

Abstract

Refereed/Peer-reviewed Although the spatiotemporal complexity and network connectivity are clarified to be disrupted during the general anesthesia (GA) induced unconsciousness, it remains to be difficult to exactly monitor the fluctuation of consciousness clinically. In this study, to track the loss of consciousness (LOC) induced by GA, we first developed the multi-channel cross fuzzy entropy method to construct the time-varying networks, whose temporal fluctuations were then explored and quantitatively evaluated. Thereafter, an algorithm was further proposed to detect the time onset at which patients lost their consciousness. The results clarified during the resting state, relatively stable fuzzy fluctuations in multi-channel network architectures and properties were found; by contrast, during the LOC period, the disrupted frontal-occipital connectivity occurred at the early stage, while at the later stage, the inner-frontal connectivity was identified. When specifically exploring the early LOC stage, the uphill of the clustering coefficients and the downhill of the characteristic path length were found, which might help resolve the propofol-induced consciousness fluctuation in patients. Moreover, the developed detection algorithm was validated to have great capacity in exactly capturing the time point (in seconds) at which patients lost consciousness. The findings demonstrated that the time-varying cross-fuzzy networks help decode the GA and are of great significance for developing anesthesia depth monitoring technology clinically.

Published

2021

5. Brain variability in dynamic resting-state networks identified by fuzzy entropy: a scalp EEG study

Author

Peng Xu, Xianjun Zhu, Yajing Si, Chanli Yi, Fali Li, Zehong Cao, Dezhong Yao, Zhenglin Yang, Yuanyuan Liao, Yangsong Zhang, Lin Jiang, Li, Fali, Jiang, Lin, Liao, Yuanyuan, Si, Yajing, Yi, Chanli, Zhang, Yangsong, Zhu, Xianjun, Yang, Zhenglin, Yao, Dezhong, Cao, Zehong, and Xu, Peng

Subjects

Property (programming), Computer science, Entropy, Biomedical Engineering, Electroencephalography, Temporal lobe, Cellular and Molecular Neuroscience, resting-state, medicine, Effects of sleep deprivation on cognitive performance, EEG, Cerebral Cortex, Network architecture, Scalp, Resting state fMRI, medicine.diagnostic_test, Quantitative Biology::Neurons and Cognition, network variability, business.industry, Brain, Pattern recognition, Cognition, decision-making, fuzzy entropy, Artificial intelligence, Occipital lobe, business

Abstract

Objective. Exploring the temporal variability in spatial topology during the resting state attracts growing interest and becomes increasingly useful to tackle the cognitive process of brain networks. In particular, the temporal brain dynamics during the resting state may be delineated and quantified aligning with cognitive performance, but few studies investigated the temporal variability in the electroencephalogram (EEG) network as well as its relationship with cognitive performance. Approach. In this study, we proposed an EEG-based protocol to measure the nonlinear complexity of the dynamic resting-state network by applying the fuzzy entropy. To further validate its applicability, the fuzzy entropy was applied into simulated and two independent datasets (i.e. decision-making and P300). Main results. The simulation study first proved that compared to the existing methods, this approach could not only exactly capture the pattern dynamics in time series but also overcame the magnitude effect of time series. Concerning the two EEG datasets, the flexible and robust network architectures of the brain cortex at rest were identified and distributed at the bilateral temporal lobe and frontal/occipital lobe, respectively, whose variability metrics were found to accurately classify different groups. Moreover, the temporal variability of resting-state network property was also either positively or negatively related to individual cognitive performance. Significance. This outcome suggested the potential of fuzzy entropy for evaluating the temporal variability of the dynamic resting-state brain networks, and the fuzzy entropy is also helpful for uncovering the fluctuating network variability that accounts for the individual decision differences.

Published

2021