Jiachen Wang scite author profile

Jiachen Wang

4Publications

26Citation Statements Received

88Citation Statements Given

How they've been cited

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110

Affiliations

Chinese People's Armed Police Force Engineering University, China Meteorological Administration

Publications

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Fully automatic liver attenuation estimation combing CNN segmentation and morphological operations

Huo¹,

Terry²,

Wang³

et al. 2019

Medical Physics

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Purpose Manually tracing regions of interest (ROIs) within the liver is the de facto standard method for measuring liver attenuation on computed tomography (CT) in diagnosing nonalcoholic fatty liver disease (NAFLD). However, manual tracing is resource intensive. To address these limitations and to expand the availability of a quantitative CT measure of hepatic steatosis, we propose the automatic liver attenuation ROI‐based measurement (ALARM) method for automated liver attenuation estimation. Methods The ALARM method consists of two major stages: (a) deep convolutional neural network (DCNN)‐based liver segmentation and (b) automated ROI extraction. First, liver segmentation was achieved using our previously developed SS‐Net. Then, a single central ROI (center‐ROI) and three circles ROI (periphery‐ROI) were computed based on liver segmentation and morphological operations. The ALARM method is available as an open source Docker container (https://github.com/MASILab/ALARM). Results Two hundred and forty‐six subjects with 738 abdomen CT scans from the African American‐Diabetes Heart Study (AA‐DHS) were used for external validation (testing), independent from the training and validation cohort (100 clinically acquired CT abdominal scans). From the correlation analyses, the proposed ALARM method achieved Pearson correlations = 0.94 with manual estimation on liver attenuation estimations. When evaluating the ALARM method for detection of nonalcoholic fatty liver disease (NAFLD) using the traditional cut point of < 40 HU, the center‐ROI achieved substantial agreements (Kappa = 0.79) with manual estimation, while the periphery‐ROI method achieved “excellent” agreement (Kappa = 0.88) with manual estimation. The automated ALARM method had reduced variability compared to manual measurements as indicated by a smaller standard deviation. Conclusions We propose a fully automated liver attenuation estimation method termed ALARM by combining DCNN and morphological operations, which achieved “excellent” agreement with manual estimation for fatty liver detection. The entire pipeline is implemented as a Docker container which enables users to achieve liver attenuation estimation in five minutes per CT exam.

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Load Forecasting Based on LVMD-DBFCM Load Curve Clustering and the CNN-IVIA-BLSTM Model

Wang

Guo

et al. 2023

Applied Sciences

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Power load forecasting plays an important role in power systems, and the accuracy of load forecasting is of vital importance to power system planning as well as economic efficiency. Power load data are nonsmooth, nonlinear time-series and “noisy” data. Traditional load forecasting has low accuracy and curves not fitting the load variation. It is not well predicted by a single forecasting model. In this paper, we propose a novel model based on the combination of data mining and deep learning to improve the prediction accuracy. First, data preprocessing is performed. Second, identification and correction of anomalous data, normalization of continuous sequences, and one-hot encoding of discrete sequences are performed. The load data are decomposed and denoised using the double decomposition modal (LVMD) strategy, the load curves are clustered using the double weighted fuzzy C-means (DBFCM) algorithm, and the typical curves obtained are used as load patterns. In addition, data feature analysis is performed. A convolutional neural network (CNN) is used to extract data features. A bidirectional long short-term memory (BLSTM) network is used for prediction, in which the number of hidden layer neurons, the number of training epochs, the learning rate, the regularization coefficient, and other relevant parameters in the BLSTM network are optimized using the influenza virus immunity optimization algorithm (IVIA). Finally, the historical data of City H from 1 January 2016 to 31 December 2018, are used for load forecasting. The experimental results show that the novel model based on LVMD-DBFCM load c1urve clustering combined with CNN-IVIA-BLSTM proposed in this paper has an error of only 2% for electric load forecasting.

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Data compression based on compressed sensing and wavelet transform

Weibing

Wang

2010

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Sparse representation of tropospheric grid data using compressed sensing

Xiao

Liu

et al. 2021

GPS Solut

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Jiachen Wang

Fully automatic liver attenuation estimation combing CNN segmentation and morphological operations

Load Forecasting Based on LVMD-DBFCM Load Curve Clustering and the CNN-IVIA-BLSTM Model

Data compression based on compressed sensing and wavelet transform

Sparse representation of tropospheric grid data using compressed sensing

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