Yuxi Sun scite author profile

Automatically extracting useful information from electronic medical records along with conducting disease diagnoses is a promising task for both clinical decision support(CDS) and neural language processing(NLP). Most of the existing systems are based on artificially constructed knowledge bases, and then auxiliary diagnosis is done by rule matching. In this study, we present a clinical intelligent decision approach based on Convolutional Neural Networks(CNN), which can automatically extract high-level semantic information of electronic medical records and then perform automatic diagnosis without artificial construction of rules or knowledge bases. We use collected 18,590 copies of the real-world clinical electronic medical records to train and test the proposed model. Experimental results show that the proposed model can achieve 98.67% accuracy and 96.02% recall, which strongly supports that using convolutional neural network to automatically learn high-level semantic features of electronic medical records and then conduct assist diagnosis is feasible and effective.

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Unsupervised deep hashing through learning soft pseudo label for remote sensing image retrieval

Sun

et al. 2022

Knowledge-Based Systems

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Multisensor Fusion and Explicit Semantic Preserving-Based Deep Hashing for Cross-Modal Remote Sensing Image Retrieval

Sun

Feng

et al. 2022

IEEE Trans. Geosci. Remote Sensing

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FiC-RNN: A Multi-FPGA Acceleration Framework for Deep Recurrent Neural Networks

Sun

Amano

2020

IEICE Trans. Inf. & Syst.

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Recurrent neural networks (RNNs) have been proven effective for sequence-based tasks thanks to their capability to process temporal information. In real-world systems, deep RNNs are more widely used to solve complicated tasks such as large-scale speech recognition and machine translation. However, the implementation of deep RNNs on traditional hardware platforms is inefficient due to long-range temporal dependence and irregular computation patterns within RNNs. This inefficiency manifests itself in the proportional increase in the latency of RNN inference with respect to the number of layers of deep RNNs on CPUs and GPUs. Previous work has focused mostly on optimizing and accelerating individual RNN cells. To make deep RNN inference fast and efficient, we propose an accelerator based on a multi-FPGA platform called Flow-in-Cloud (FiC). In this work, we show that the parallelism provided by the multi-FPGA system can be taken advantage of to scale up the inference of deep RNNs, by partitioning a large model onto several FPGAs, so that the latency stays close to constant with respect to increasing number of RNN layers. For single-layer and four-layer RNNs, our implementation achieves 31x and 61x speedup compared with an Intel CPU.

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Estimating energy consumption of residential buildings at scale with drive-by image capture

Ward

Sun

et al. 2023

Building and Environment

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Yuxi Sun

Clinical Assistant Diagnosis for Electronic Medical Record Based on Convolutional Neural Network

Unsupervised deep hashing through learning soft pseudo label for remote sensing image retrieval

Multisensor Fusion and Explicit Semantic Preserving-Based Deep Hashing for Cross-Modal Remote Sensing Image Retrieval

FiC-RNN: A Multi-FPGA Acceleration Framework for Deep Recurrent Neural Networks

Estimating energy consumption of residential buildings at scale with drive-by image capture

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