3 research outputs found
AUTOMATIC ARRHYTHMIAS DETECTION USING VARIOUS TYPES OF ARTIFICIAL NEURAL NETWORK BASED LEARNING VECTOR QUANTIZATION (LVQ)
Abstract
An automatic Arrythmias detection system is urgently required due to small number of cardiologits in Indonesia. This paper discusses only about the study and implementation of the system. We use several kinds of signal processing methods to recognize arrythmias from ecg signal. The core of the system is classification. Our LVQ based artificial neural network classifiers based on LVQ, which includes LVQ1, LVQ2, LVQ2.1, FNLVQ, FNLVQ MSA, FNLVQ-PSO, GLVQ and FNGLVQ. Experiment result show that for non round robin dataset, the system could reach accuracy of 94.07%, 92.54%, 88.09% , 86.55% , 83.66%, 82.29 %, 82.25%, and 74.62% respectively for FNGLVQ, FNLVQ-PSO, GLVQ, LVQ2.1, FNLVQ-MSA, LVQ2, FNLVQ and LVQ1. Whereas for round robin dataset, system reached accuracy of 98.12%, 98.04%, 94.31%, 90.43%, 86.75%, 86.12 %, 84.50%, and 74.78% respectively for GLVQ, LVQ2.1, FNGLVQ, FNLVQ-PSO, LVQ2, FNLVQ-MSA, FNLVQ and LVQ1
Robust Classification with Convolutional Prototype Learning
Convolutional neural networks (CNNs) have been widely used for image
classification. Despite its high accuracies, CNN has been shown to be easily
fooled by some adversarial examples, indicating that CNN is not robust enough
for pattern classification. In this paper, we argue that the lack of robustness
for CNN is caused by the softmax layer, which is a totally discriminative model
and based on the assumption of closed world (i.e., with a fixed number of
categories). To improve the robustness, we propose a novel learning framework
called convolutional prototype learning (CPL). The advantage of using
prototypes is that it can well handle the open world recognition problem and
therefore improve the robustness. Under the framework of CPL, we design
multiple classification criteria to train the network. Moreover, a prototype
loss (PL) is proposed as a regularization to improve the intra-class
compactness of the feature representation, which can be viewed as a generative
model based on the Gaussian assumption of different classes. Experiments on
several datasets demonstrate that CPL can achieve comparable or even better
results than traditional CNN, and from the robustness perspective, CPL shows
great advantages for both the rejection and incremental category learning
tasks