Showing total 3 results

1. The choice of the shape parameter–A friendly approach.

Author

Luh, Lin-Tian

Subjects

*MATHEMATICAL models, *COMPUTER simulation, *PARAMETERS (Statistics), *INVERSE problems, *MATHEMATICS

Abstract

Abstract In this paper we continue our study of the shape parameter c contained in the famous multiquadrics (− 1) ⌈ β ⌉ (c 2 + ∥ x ∥ 2) β , β > 0 , and the inverse multiquadrics (c 2 + ∥ x ∥ 2) β , β < 0. The theoretical ground is akin to our previous papers. However, we remove some unnecessary restrictions, making it much more accessible and useful, especially for nonmathematicians [ABSTRACT FROM AUTHOR]

Published

2019

2. Fine-granularity inference and estimations to network traffic for SDN.

Author

Jiang, Dingde, Huo, Liuwei, and Li, Ya

Subjects

*COMPUTER networks, *COMPUTER simulation, *PHYSICAL sciences, *INTERPOLATION

Abstract

An end-to-end network traffic matrix is significantly helpful for network management and for Software Defined Networks (SDN). However, the end-to-end network traffic matrix's inferences and estimations are a challenging problem. Moreover, attaining the traffic matrix in high-speed networks for SDN is a prohibitive challenge. This paper investigates how to estimate and recover the end-to-end network traffic matrix in fine time granularity from the sampled traffic traces, which is a hard inverse problem. Different from previous methods, the fractal interpolation is used to reconstruct the finer-granularity network traffic. Then, the cubic spline interpolation method is used to obtain the smooth reconstruction values. To attain an accurate the end-to-end network traffic in fine time granularity, we perform a weighted-geometric-average process for two interpolation results that are obtained. The simulation results show that our approaches are feasible and effective. [ABSTRACT FROM AUTHOR]

Published

2018

3. A Novel Multi-Receiver Signcryption Scheme with Complete Anonymity.

Author

Pang, Liaojun, Yan, Xuxia, Zhao, Huiyang, Hu, Yufei, and Li, Huixian

Subjects

*LAGRANGE equations, *POLYNOMIALS, *APPLIED mathematics, *COMPUTER simulation, *NUMERICAL analysis

Abstract

Anonymity, which is more and more important to multi-receiver schemes, has been taken into consideration by many researchers recently. To protect the receiver anonymity, in 2010, the first multi-receiver scheme based on the Lagrange interpolating polynomial was proposed. To ensure the sender’s anonymity, the concept of the ring signature was proposed in 2005, but afterwards, this scheme was proven to has some weakness and at the same time, a completely anonymous multi-receiver signcryption scheme is proposed. In this completely anonymous scheme, the sender anonymity is achieved by improving the ring signature, and the receiver anonymity is achieved by also using the Lagrange interpolating polynomial. Unfortunately, the Lagrange interpolation method was proven a failure to protect the anonymity of receivers, because each authorized receiver could judge whether anyone else is authorized or not. Therefore, the completely anonymous multi-receiver signcryption mentioned above can only protect the sender anonymity. In this paper, we propose a new completely anonymous multi-receiver signcryption scheme with a new polynomial technology used to replace the Lagrange interpolating polynomial, which can mix the identity information of receivers to save it as a ciphertext element and prevent the authorized receivers from verifying others. With the receiver anonymity, the proposed scheme also owns the anonymity of the sender at the same time. Meanwhile, the decryption fairness and public verification are also provided. [ABSTRACT FROM AUTHOR]

Published

2016