Finger ECG-Based Authentication for Healthcare Data Security Using Artificial Neural Network
Title | Finger ECG-Based Authentication for Healthcare Data Security Using Artificial Neural Network |
Publication Type | Conference Paper |
Year of Publication | 2017 |
Authors | Chen, Y., Chen, W. |
Conference Name | 2017 IEEE 19th International Conference on E-Health Networking, Applications and Services (Healthcom) |
Date Published | oct |
ISBN Number | 978-1-5090-6704-6 |
Keywords | artificial neural network models, Artificial neural networks, authentication, Conferences, Data models, ECG data, ECG signal, electrocardiogram, Electrocardiography, feature extraction, finger ECG signals, finger ECG-based authentication, General NN model, Health Care, health monitoring, healthcare data security, Heart beat, human recognition, medical signal processing, Metrics, mobile medical devices, neural nets, policy-based governance, pubcrawl, resilience, Resiliency, security of data, stage Personal NN models, wearable devices |
Abstract | Wearable and mobile medical devices provide efficient, comfortable, and economic health monitoring, having a wide range of applications from daily to clinical scenarios. Health data security becomes a critically important issue. Electrocardiogram (ECG) has proven to be a potential biometric in human recognition over the past decade. Unlike conventional authentication methods using passwords, fingerprints, face, etc., ECG signal can not be simply intercepted, duplicated, and enables continuous identification. However, in many of the studies, algorithms developed are not suitable for practical application, which usually require long ECG data for authentication. In this work, we introduce a two-phase authentication using artificial neural network (NN) models. This algorithm enables fast authentication within only 3 seconds, meanwhile achieves reasonable performance in recognition. We test the proposed method in a controlled laboratory experiment with 50 subjects. Finger ECG signals are collected using a mobile device at different times and physical statues. At the first stage, a ``General'' NN model is constructed based on data from the cohort and used for preliminary screening, while at the second stage ``Personal'' NN models constructed from single individual's data are applied as fine-grained identification. The algorithm is tested on the whole data set, and on different sizes of subsets (5, 10, 20, 30, and 40). Results proved that the proposed method is feasible and reliable for individual authentication, having obtained average False Acceptance Rate (FAR) and False Rejection Rate (FRR) below 10% for the whole data set. |
URL | https://ieeexplore.ieee.org/document/8210804 |
DOI | 10.1109/HealthCom.2017.8210804 |
Citation Key | chen_finger_2017 |
- health monitoring
- Wearable devices
- stage Personal NN models
- security of data
- Resiliency
- resilience
- pubcrawl
- policy-based governance
- neural nets
- mobile medical devices
- Metrics
- medical signal processing
- human recognition
- Heart beat
- healthcare data security
- artificial neural network models
- health care
- General NN model
- finger ECG-based authentication
- finger ECG signals
- feature extraction
- Electrocardiography
- electrocardiogram
- ECG signal
- ECG data
- Data models
- Conferences
- authentication
- Artificial Neural Networks