Search-tree Based SDN Candidate Selection in Hybrid IP/SDN Network

<p>Increase in globalization of the industry of software requires an exploration of requirements engineering (RE) in software development institutes at multiple locations. Requirements engineering task is very complicated when it is performed at single site, but it becomes too much complex when stakeholder groups define well-designed requirements under language, time zone and cultural limits. Requirements prioritization (RP) is considered as an imperative part of software requirements engineering in which requirements are ranked to develop best-quality software. In this research, a comparative study of the requirements prioritization techniques was done to overcome the challenges initiated by the corporal distribution of stakeholders within the organization at multiple locations. The objective of this study was to make a comparison between five techniques for prioritizing software requirements and to discuss the results for global software engineering. The selected techniques were Analytic Hierarchy Process (AHP), Cumulative Voting (CV), Value Oriented Prioritization (VOP), Binary Search Tree (BST), and Numerical Assignment Technique (NAT). At the end of the research a framework for Global Software Engineering (GSE) was proposed to prioritize the requirements for stakeholders at distributed locations.<strong></strong></p>

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Bloom Filter-Based Parallel Architecture for Accelerating Equi-Join Operation on FPGA

Electronics ◽

10.3390/electronics10151778 ◽

2021 ◽

Vol 10 (15) ◽

pp. 1778

Author(s):

Binhao He ◽

Meiting Xue ◽

Shubiao Liu ◽

Wei Luo

Keyword(s):

Relational Databases ◽

Parallel Architecture ◽

Operation Time ◽

Bloom Filter ◽

Search Tree ◽

Binary Search Tree ◽

Maximum Acceleration ◽

Data Intensive ◽

Match Rate ◽

Field Programmable

As one of the most important operations in relational databases, the join is data-intensive and time-consuming. Thus, offloading this operation using field-programmable gate arrays (FPGAs) has attracted much interest and has been broadly researched in recent years. However, the available SRAM-based join architectures are often resource-intensive, power-consuming, or low-throughput. Besides, a lower match rate does not lead to a shorter operation time. To address these issues, a Bloom filter (BF)-based parallel join architecture is presented in this paper. This architecture first leverages the BF to discard the tuples that are not in the join result and classifies the remaining tuples into different channels. Second, a binary search tree is used to reduce the number of comparisons. The proposed method was implemented on a Xilinx FPGA, and the experimental results show that under a match rate of 50%, our architecture achieved a high join throughput of 145.8 million tuples per second and a maximum acceleration factor of 2.3 compared to the existing SRAM-based join architectures.

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Beyond Binary Search: Parallel In-place Construction of Implicit Search Tree Layouts

IEEE Transactions on Computers ◽

10.1109/tc.2021.3075392 ◽

2021 ◽

pp. 1-1

Author(s):

Kyle Berney ◽

Henri Casanova ◽

Ben Karsin ◽

Nodari Sitchinava

Keyword(s):

Search Tree ◽

Binary Search

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Transition to Intra-Party Democracy: The Korean Presidential Candidate Selection System

Asian Perspective ◽

10.1353/apr.2002.0026 ◽

2002 ◽

Vol 26 (2) ◽

pp. 131-155

Author(s):

Hyun-Chool Lee

Keyword(s):

Candidate Selection ◽

Presidential Candidate ◽

Selection System

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E-ART: A New Encryption Algorithm Based on the Reflection of Binary Search Tree

Cryptography ◽

10.3390/cryptography5010004 ◽

2021 ◽

Vol 5 (1) ◽

pp. 4

Author(s):

Bayan Alabdullah ◽

Natalia Beloff ◽

Martin White

Keyword(s):

Data Storage ◽

Statistical Tests ◽

Data Encryption ◽

Search Tree ◽

Binary Search ◽

Binary Search Tree ◽

Security Level ◽

Avalanche Effect ◽

High Security Level ◽

Tree Data Structure

Data security has become crucial to most enterprise and government applications due to the increasing amount of data generated, collected, and analyzed. Many algorithms have been developed to secure data storage and transmission. However, most existing solutions require multi-round functions to prevent differential and linear attacks. This results in longer execution times and greater memory consumption, which are not suitable for large datasets or delay-sensitive systems. To address these issues, this work proposes a novel algorithm that uses, on one hand, the reflection property of a balanced binary search tree data structure to minimize the overhead, and on the other hand, a dynamic offset to achieve a high security level. The performance and security of the proposed algorithm were compared to Advanced Encryption Standard and Data Encryption Standard symmetric encryption algorithms. The proposed algorithm achieved the lowest running time with comparable memory usage and satisfied the avalanche effect criterion with 50.1%. Furthermore, the randomness of the dynamic offset passed a series of National Institute of Standards and Technology (NIST) statistical tests.

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