Improving Prediction Efficacy through Abnormality Detection and Data Preprocessing.

Abnormal testing data can severely reduce model performance if not processed properly. In this work, we propose a preprocessing system to handle different types of commonly seen abnormal testing data. The system consists of an aberrant data detector and an aberrant data corrector. The aberrant data detector is responsible for classifying the type of incoming data. Based on the data type, the aberrant data corrector will take different actions to amend testing data. Users can then apply their preferred prediction methods on the corrected testing data. Specifically, corrupted and adversarial images are used as examples of abnormal data. We show that corrupted data can be reconstructed through a Gaussian Locally Linear Mappings method, and the prediction performance of adversarial samples can be improved by using the nearest neighbors as a surrogate. We compare the proposed aberrant data detector and corrector with existing and well-recognized alternatives. These approaches are published individually and do not put two components together as a pre-processing system. The numerical outcomes show that our proposed components, standing alone, are competitive. The proposed system is a generic method that can be applied to different downstream predictive models. We use three existing prediction methods to illustrate the general usage of the proposed system and its capability of improving prediction efficacy.

RACOON: a multiuser QoS design for mobile wireless body area networks.

In this study, Random Contention-based Resource Allocation (RACOON) medium access control (MAC) protocol is proposed to support the quality of service (QoS) for multi-user mobile wireless body area networks (WBANs). Different from existing QoS designs that focus on a single WBAN, a multiuser WBAN QoS should further consider both inter-WBAN interference and inter-WBAN priorities. Similar problems have been studied in both overlapped wireless local area networks (WLANs) and Bluetooth piconets that need QoS supports. However, these solutions are designed for non-medical transmissions that do not consider any priority scheme for medical applications. Most importantly, these studies focus on only static or low mobility networks. Network mobility of WBANs will introduce unnecessary inter-network collisions and energy waste, which are not considered by these solutions. The proposed multiuser-QoS protocol, RACOON, simultaneously satisfies the inter WBAN QoS requirements and overcomes the performance degradation caused by WBAN mobility. Simulation results verify that RACOON provides better latency and energy control, as compared with WBAN QoS protocols without considering the inter-WBAN requirements.