Abstract
Supervised learning technologies have been used in medical-data classification to improve diagnosis efficiency and reduce human diagnosis errors. A large amount of manually annotated data are required for the fully supervised learning process. However, annotating data information will consume a large amount of manpower and resources. Self-supervised learning has great advantages in solving this problem. Self-supervised learning mainly uses pretext tasks to mine its own supervised information from large-scale unsupervised data. And this constructed supervised information is used to train the network to learn valuable representations for downstream tasks. This study designs a general and efficient model for the diagnosis and classification of medical sensor data based on contrastive predictive coding (CPC) in self-supervised learning, called TCC, which consists of two steps. The first step is to design a pretext task based on the idea of CPC, which aims to extract effective features between different categories using its encoder. The second step designs a downstream classification task with lower time and space complexity to perform a supervised type of training using the features extracted by the encoder of the pretext task. Finally, to demonstrate the performance of the proposed framework in this paper, we compare the proposed framework with recent state-of-the-art works. Experiments comparing the proposed framework with supervised learning are also set up under the condition of different proportions of labeled data.
Highlights
Healthcare as an important part of smart cities directly affects the quality of smart city construction
The rapid growth of urban population density, population aging, and various chronic diseases have brought challenges to the development of smart healthcare [1]. is no longer meets the requirements of sustainable urban development, prompting a shift from hospital-centered to family-centered healthcare [2]. e application of various deep learning algorithms has made it less difficult to automatically classify diseases and has greatly improved the accuracy of disease classification [3, 4]. e classification model can be paired with various IoT devices for real-time diagnosis [5], and patients can grasp their health status at home without having to go to the hospital for checkups every time, which will ease the tension on medical resources and help the construction of smart medical care to achieve sustainable urban development
We propose a two-step two-step CPC-based classification framework (TCC) model according to the architecture and ideas of contrastive predictive coding in self-supervised learning
Summary
Healthcare as an important part of smart cities directly affects the quality of smart city construction. Is no longer meets the requirements of sustainable urban development, prompting a shift from hospital-centered to family-centered healthcare [2]. E classification model can be paired with various IoT devices for real-time diagnosis [5], and patients can grasp their health status at home without having to go to the hospital for checkups every time, which will ease the tension on medical resources and help the construction of smart medical care to achieve sustainable urban development. Traditional supervised learning training requires a large amount of labeled data to achieve good results. For medical data with few labels and a high labeling threshold [6], traditional supervised training is no longer suitable [7]. Self-supervised learning can well solve the problem of unlabeled medical data by creating pseudolabels [8]. Self-supervised learning methods learn more general features rather than task-specific features, so models using self-supervised learning can be reused for different tasks in the same domain and can better perform the task of classifying medical sensor data [9]
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