Your search keyword '"Kim, Moonseong"' showing total 2 results

1. Regional Correlation Aided Mobile Traffic Prediction with Spatiotemporal Deep Learning

Author

Park, JeongJun, Mwasinga, Lusungu J., Yang, Huigyu, Raza, Syed M., Le, Duc-Tai, Kim, Moonseong, Chung, Min Young, Choo, Hyunseung, Park, JeongJun, Mwasinga, Lusungu J., Yang, Huigyu, Raza, Syed M., Le, Duc-Tai, Kim, Moonseong, Chung, Min Young, and Choo, Hyunseung

Abstract

Mobile traffic data in urban regions shows differentiated patterns during different hours of the day. The exploitation of these patterns enables highly accurate mobile traffic prediction for proactive network management. However, recent Deep Learning (DL) driven studies have only exploited spatiotemporal features and have ignored the geographical correlations, causing high complexity and erroneous mobile traffic predictions. This paper addresses these limitations by proposing an enhanced mobile traffic prediction scheme that combines the clustering strategy of daily mobile traffic peak time and novel multi Temporal Convolutional Network with a Long Short Term Memory (multi TCN-LSTM) model. The mobile network cells that exhibit peak traffic during the same hour of the day are clustered together. Our experiments on large-scale real-world mobile traffic data show up to 28% performance improvement compared to state-of-the-art studies, which confirms the efficacy and viability of the proposed approach., Comment: 4 pages, 5 figures, 1 table. This paper is already accepted on IEEE Consumer Communications & Networking Conference(CCNC) 2024

Published

2023

2. Efficient and Anonymous Two-Factor User Authentication in Wireless Sensor Networks: Achieving User Anonymity with Lightweight Sensor Computation

Author

Nam, Junghyun, Choo, Kim-Kwang Raymond, Han, Sangchul, Kim, Moonseong, Paik, Juryon, Won, Dongho, Nam, Junghyun, Choo, Kim-Kwang Raymond, Han, Sangchul, Kim, Moonseong, Paik, Juryon, and Won, Dongho

Abstract

A smart-card-based user authentication scheme for wireless sensor networks (hereafter referred to as a SCA-WSN scheme) is designed to ensure that only users who possess both a smart card and the corresponding password are allowed to gain access to sensor data and their transmissions. Despite many research efforts in recent years, it remains a challenging task to design an efficient SCA-WSN scheme that achieves user anonymity. The majority of published SCA-WSN schemes use only lightweight cryptographic techniques (rather than public-key cryptographic techniques) for the sake of efficiency, and have been demonstrated to suffer from the inability to provide user anonymity. Some schemes employ elliptic curve cryptography for better security but require sensors with strict resource constraints to perform computationally expensive scalar-point multiplications; despite the increased computational requirements, these schemes do not provide user anonymity. In this paper, we present a new SCA-WSN scheme that not only achieves user anonymity but also is efficient in terms of the computation loads for sensors. Our scheme employs elliptic curve cryptography but restricts its use only to anonymous user-to-gateway authentication, thereby allowing sensors to perform only lightweight cryptographic operations. Our scheme also enjoys provable security in a formal model extended from the widely accepted Bellare-Pointcheval-Rogaway (2000) model to capture the user anonymity property and various SCA-WSN specific attacks (e.g., stolen smart card attacks, node capture attacks, privileged insider attacks, and stolen verifier attacks).

Published

2015