Abstract
Due to its importance in clinical science, the estimation of physiological states (e.g., the severity of pathological tremor) has aroused growing interest in machine learning community. While the physiological state is a continuous variable, its continuity is lost when the physiological state is quantized into a few discrete classes during recording and labeling. The discreteness introduces misalignment between the true value and its label, meaning that these labels are unfortunately imprecise and coarse-grained. Most previous work did not consider the inaccuracy and directly utilized the coarse labels to train the machine learning algorithms, whose predictions are also coarse-grained. In this work, we propose to learn a precise, fine-grained estimation of physiological states using these coarse-grained ground truths. Established on mathematical rigorous proof, we utilize imprecise labels to restore the probabilistic distribution of precise labels in an approximate order-preserving fashion, then the deep neural network learns from this distribution and offers fine-grained estimation. We demonstrate the effectiveness of our approach in assessing the pathological tremor in Parkinson’s Disease and estimating the systolic blood pressure from bioelectrical signals.
Highlights
Due to its importance in clinical science, the estimation of physiological states has aroused growing interest in machine learning community
According to the universally accepted MDS-UPDRS19, the tremor severity is divided into 5 escalating levels, normal, slight, mild, moderate, severe, which we represent with integers {1, 2, 3, 4, 5} respectively
The main evaluation is done on Parkinson’s Disease (PD)-sEMG9 dataset containing 10K sequences of single-channel surface electromyography (sEMG) collected from the upper limbs of 147 individuals at a sampling rate of 1 KHz
Summary
Due to its importance in clinical science, the estimation of physiological states (e.g., the severity of pathological tremor) has aroused growing interest in machine learning community. In various scenarios the labels are provided as classification labels By learning from such labels, the machine learning model takes the raw medical data as input and classifies the physiological state into discrete classes. Consider the simplest case where we classify the severity of a certain disease on a patient into two levels, slight and severe In this sense, the annotators are required to provide binary labels by quantizing their judgments into two discrete categories. These Gaussian Process based methods are targeted at a task intrinsically different from ours and cannot be used to directly solve our task
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