Guanhua Ye scite author profile

Guanhua Ye

5Publications

32Citation Statements Received

51Citation Statements Given

How they've been cited

139

How they cite others

112

Affiliations

University of Queensland, City University of New York, City College of New York

Publications

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FENet: A Frequency Extraction Network for Obstructive Sleep Apnea Detection

Yin

Tong

et al. 2021

IEEE J. Biomed. Health Inform.

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Streszczenie-Obstructive Sleep Apnea (OSA) is a highly prevalent but inconspicuous disease that seriously jeopardizes the health of human beings. Polysomnography (PSG), the gold standard of detecting OSA, requires multiple specialized sensors for signal collection, hence patients have to physically visit hospitals and bear the costly treatment for a single detection. Recently, many single-sensor alternatives have been proposed to improve the cost efficiency and convenience. Among these methods, solutions based on RR-interval (i.e., the interval between two consecutive pulses) signals reach a satisfactory balance among comfort, portability and detection accuracy.In this paper, we advance RR-interval based OSA detection by considering its real-world practicality from energy perspectives. As photoplethysmogram (PPG) pulse sensors are commonly equipped on smart wrist-worn wearable devices (e.g., smart watches and wristbands), the energy efficiency of the detection model is crucial to fully support an overnight observation on patients. This creates challenges as the PPG sensors are unable to keep collecting continuous signals due to the limited battery capacity on smart wrist-worn devices. Therefore, we propose a novel Frequency Extraction Network (FENet), which can extract features from different frequency bands of the input RRinterval signals and generate continuous detection results with downsampled, discontinuous RR-interval signals. With the help of the one-to-multiple structure, FENet requires only one-third of the operation time of the PPG sensor, thus sharply cutting down the energy consumption and enabling overnight diagnosis. Experimental results on real OSA datasets reveal the state-ofthe-art performance of FENet.

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Personalized On-Device E-Health Analytics With Decentralized Block Coordinate Descent

Yin

Chen

et al. 2022

IEEE J. Biomed. Health Inform.

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Actuated by the growing attention to personal healthcare and the pandemic, the popularity of E-health is proliferating. Nowadays, enhancement on medical diagnosis via machine learning models has been highly effective in many aspects of e-health analytics. Nevertheless, in the classic cloudbased/centralized e-health paradigms, all the data will be centrally stored on the server to facilitate model training, which inevitably incurs privacy concerns and high time delay. Distributed solutions like Decentralized Stochastic Gradient Descent (D-SGD) are proposed to provide safe and timely diagnostic results based on personal devices. However, methods like D-SGD are subject to the gradient vanishing issue and usually proceed slowly at the early training stage, thereby impeding the effectiveness and efficiency of training. In addition, existing methods are prone to learning models that are biased towards users with dense data, compromising the fairness when providing E-health analytics for minority groups.In this paper, we propose a Decentralized Block Coordinate Descent (D-BCD) learning framework that can better optimize deep neural network-based models distributed on decentralized devices for E-health analytics. As a gradient-free optimization method, Block Coordinate Descent (BCD) mitigates the gradient vanishing issue and converges faster at the early stage compared with the conventional gradient-based optimization. To overcome the potential data scarcity issues for users' local data, we propose similarity-based model aggregation that allows each on-device model to leverage knowledge from similar neighbor models, so as to achieve both personalization and high accuracy for the learned models. Benchmarking experiments on three real-world datasets illustrate the effectiveness and practicality of our proposed D-BCD, where additional simulation study showcases the strong applicability of D-BCD in real-life E-health scenarios.

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IPCC-SCTP: An enhancement to the standard SCTP to support multi-homing efficiently

Ye¹,

Saadawi²,

Lee³

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Video Face Swap Based on Autoencoder Generation Network

Yan

He²,

Xue

et al. 2018

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Try This Instead

Chen

Yin

et al. 2020

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Guanhua Ye

FENet: A Frequency Extraction Network for Obstructive Sleep Apnea Detection

Personalized On-Device E-Health Analytics With Decentralized Block Coordinate Descent

IPCC-SCTP: An enhancement to the standard SCTP to support multi-homing efficiently

Video Face Swap Based on Autoencoder Generation Network

Try This Instead

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