Showing total 8,341 results

1. Coplanar Waveguide Based Sensor Using Paper Superstrate for Non-Invasive Sweat Monitoring

Author

Michael M. Y. R. Riad and A. R. Eldamak

Subjects

Materials science, General Computer Science, 02 engineering and technology, 01 natural sciences, re-useable sensor, Transmission line, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Sensitivity (control systems), Transmission coefficient, hydration sensor, Filter paper, business.industry, Coplanar waveguide, 010401 analytical chemistry, Non invasive, General Engineering, Microwave bio-sensing, 020206 networking & telecommunications, 0104 chemical sciences, liquid characterization, cystic fibrosis diagnosis, Lookup table, Optoelectronics, lcsh:Electrical engineering. Electronics. Nuclear engineering, business, paper superstrate, lcsh:TK1-9971, Microwave

Abstract

This paper presents a broadband, simple, re-useable and low-cost approach for noninvasive sweat monitoring using a passive microwave circuit and a cellulose filter paper as a superstrate. The proposed sensor is composed of filter paper with the ability to absorb the sample liquid under test (LUT) placed on top of a coplanar waveguide (CPW) transmission line. Various samples of sodium chloride (NaCl) solutions with concentrations in the range of 0.01-2 mol/L and models of artificial sweat are used to test the proposed sensor. The difference in transmission coefficient (S21) between dry and wet states is used to determine the concentrations of tested solutions in the band of 1-6 GHz. The sensor detects concentrations as low as 0.01 mol/L (0.58 g/L) and quantities as low as 137 μL with a maximum sensitivity of 46.7 dB/g/L. The proposed sensor presents a simple approach to sample and characterize liquids with enhanced sensitivity and consistent performance using microwave signals.

Published

2020

2. A New Technique to Estimate the Degree of Polymerization of Insulation Paper Using Multiple Aging Parameters of Transformer Oil

Author

Kiyoshi Wakimoto, Liuqing Yang, Zhao Ge, Shijun Li, Ahmed Abu-Siada, and Shengtao Li

Subjects

General Computer Science, Transformer oil, 020209 energy, 02 engineering and technology, Degree of polymerization, 01 natural sciences, Fuzzy logic, oil aging parameters, law.invention, law, 0103 physical sciences, Linear regression, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, paper insulation, Process engineering, Transformer, 010302 applied physics, Data processing, Moisture, business.industry, General Engineering, Single parameter, power transformers, Environmental science, lcsh:Electrical engineering. Electronics. Nuclear engineering, business, lcsh:TK1-9971

Abstract

Transformer insulation paper is a key indicator for transformer remaining operational life. Paper decomposition is evaluated using the degree of polymerization (DP) which calls for samples of insulation paper from operating transformers. Since collecting such paper samples is extremely difficult, other indicators have been used to indirectly reveal the DP value of insulation paper. This includes dissolved gases in transformer oil such as carbon oxides and hydrocarbon gases, furan compounds, methanol, ethanol, and moisture along with some oil characteristics such as interfacial tension. However, for the same oil sample, these individual parameters lead to different DP values. This is attributed to the lack of accuracy of the established mathematical and artificial intelligence models correlating DP with each of the above mentioned individual parameters. This paper presents a self-learning method to estimate the DP value of transformer insulation paper based on multiple transformer oil aging parameters. The proposed method comprises data processing, fuzzy c-means and linear regression. Results reveal that estimating the DP value based on multiple aging parameters is more accurate than estimating it using one single parameter as per the current practice. The proposed method not only helps to understand the correlation between multiple oil aging parameters and the DP value of paper insulation, but also promotes the establishment of more accurate life assessment models for power transformers based on these oil aging parameters.

Published

2019

3. A Comprehensive Evaluation of Metadata-Based Features to Classify Research Paper’s Topics

Author

Muhammad Usman, Ghulam Mustafa, Muhammad Afzal, Anis Koubaa, and Abdul Shahid

Subjects

Root (linguistics), Hierarchy, Information retrieval, General Computer Science, Exploit, business.industry, Computer science, Document classification, Deep learning, General Engineering, Decision tree, computer.software_genre, Random forest, Metadata, General Materials Science, Artificial intelligence, Electrical and Electronic Engineering, business, computer

Abstract

The existing plethora of document classification techniques exploits different data sources either from the content or metadata of research articles. Various journal publishers like Springer, Elsevier, IEEE, etc., do not provide open access to the content of research articles, whereas metadata is freely available there. Metadata like title, keyword, and abstract can serve as a better alternative to the content in various scenarios. In the current literature, researchers have assessed the role of some of the metadata individually. We believe that the collective contribution of metadata parameters can play a significant role in classifying research papers. This paper presents a comprehensive evaluation of the role of metadata, individually as well as in combinations to achieve the objective of research paper classification. Moreover, we have classified the research articles into ACM hierarchy root categories (e.g. general literature, hardware, software, etc.). In this comprehensive evaluation, we have assessed all the possible combinations of metadata features against different classifiers such as Random Forest, K Nearest Neighbor, and Decision Tree. The results of this research reveal that the title & keywords combination outperforms other combinations with an F-measure score of 0.88.

Published

2021

4. Wireless IoT Motion-Recognition Rings and a Paper Keyboard

Author

Wen J. Li, Chao Lian, Guangyi Shi, Xiaopeng Sha, Yuliang Zhao, and Xueliang Zhang

Subjects

micro IMU, General Computer Science, Computer science, 02 engineering and technology, Keystroke logging, 01 natural sciences, Software portability, Acceleration, Inertial measurement unit, 0202 electrical engineering, electronic engineering, information engineering, Wireless, General Materials Science, Desk, business.industry, 010401 analytical chemistry, General Engineering, keystroke recognition, 0104 chemical sciences, wireless IoT ring, Key (cryptography), Wearable sensors, virtual keyboard, 020201 artificial intelligence & image processing, lcsh:Electrical engineering. Electronics. Nuclear engineering, business, lcsh:TK1-9971, Computer hardware, Gesture

Abstract

In this paper, we present a new scheme for implementing virtual keyboards, which uses only two to four motion-recognition rings per hand and a two-dimensional keyboard template (e.g., an A4 size paper with printed key positions). It has the benefit of portability, customizability, and low-cost when compared with existing approaches. Essentially, we have shown that wearing two wireless IoT rings on the middle phalanges of two fingers of each hand, users can input the alphabetic characters into a computing device by typing on a flat paper on a desk, and potentially in mid-air. We have demonstrated that two rings are sufficient in capturing the gestures and motions of all fingers in a typing hand for keystrokes recognition. A single wireless IoT ring, which weighs 7.8 grams, consists of a Bluetooth low energy (BLE) unit, a micro inertial measurement unit (mIMU), and a cell battery. The 3-axes attitude angles and the Z-axis acceleration of each ring are adopted as the features for keystroke recognition. The overall keystroke recognition accuracy rate can reach as high as 94.8% when two IoT rings are worn by a user on each hand; this accuracy rate increases to 98.6%, when four rings are worn on each typing hand.

Published

2019

5. Recognition of Aging Stage of Oil–Paper Insulation Based on Surface Enhanced Raman Scattering and Kernel Entropy Component Analysis

Author

Jingxin Zou, Dingkun Yang, Zhou Fan, Weiran Zhou, and Weigen Chen

Subjects

010302 applied physics, Materials science, General Computer Science, business.industry, Transformer oil, General Engineering, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Accelerated aging, Support vector machine, symbols.namesake, Electrical equipment, 0103 physical sciences, symbols, Optoelectronics, General Materials Science, Stage (hydrology), 0210 nano-technology, Spectral method, business, Raman spectroscopy, Raman scattering

Abstract

This study explores the method of applying surface enhanced Raman scattering (SERS) in diagnosing the aging stage of oil-paper insulation equipment in the power system, which provides access to the on-line mornitoring of electrical equipment. Oil-paper samples in different aging stages were obtained by accelerated aging experiments. Effective Raman signals of insulating oil were collected by using the self-made hexagonal sliver nano-plates SERS substrates and the self-assembled Raman detection platform. For the SERS data of oil-paper insulation samples, kernel entropy component analysis (KECA) was applied to extract the Raman spectral features and support vector machine (SVM) was used to recognize the the aging stage of oil-paper insulation. The results demonstrate that the KECA-SVM method exhibits a good diagnostic capacity and the recognition accuracy of the propsed method reached 81.43 % (57/70). In summary, a new spectral method is proposed to diagnose the aging stage of oil-paper insulation, which lays a foundation for the actual diagnosis of the aging condition in running oil-paper insulation equipment by Raman spectroscopy.

Published

2019

6. Steganalysis of Content-Adaptive Steganography Based on Massive Datasets Pre-Classification and Feature Selection

Author

Jicang Lu, Gang Zhou, Chunfang Yang, Lan Mingjing, and Zhenyu Li

Subjects

Steganalysis, Dependency (UML), General Computer Science, Steganography, information security, Computer science, business.industry, feature extraction, data analysis, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, General Engineering, multimedia communication, Pattern recognition, Feature selection, Content adaptive, Paper based, Texture (music), Image (mathematics), General Materials Science, Computer applications, lcsh:Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, business, lcsh:TK1-9971, computer security

Abstract

For current steganalysis of the image content-adaptive steganography, there are multiple problems to be improved, such as high difficulty and low accuracy, when detecting images with various contents and textures. For this problem, an improved steganalytic method is proposed in this paper based on the pre-classification and feature selection. First, using the features extracted based on the dependency analysis of image adjacent data, the images with various content and texture complexities are pre-classified as multiple clusters by the K-means algorithms. Then, the performance of existing various steganalytic features are analyzed for different clusters of images, and the optimal features for each cluster are selected for final classification. The experimental results show that the detection accuracy could be improved by the proposed method, and the rationality and availability are also verified. At the same time, the analysis and experimental results in this paper also show that the images with rich content and complex texture should be paid more attention both in steganography and in steganalysis.

Published

2019

7. The Expansive (Dis)Integration of Electrical Engineering Education

Author

Leah H. Jamieson and Brent K. Jesiek

Subjects

General Computer Science, Computer science, media_common.quotation_subject, engineering education, electrical engineering, 050905 science studies, Computer engineering, Paper report, General Materials Science, Relevance (information retrieval), Electrical and Electronic Engineering, media_common, education, business.industry, Field (Bourdieu), 05 social sciences, General Engineering, Electrical engineering, 050301 education, Variety (cybernetics), Market research, history, lcsh:Electrical engineering. Electronics. Nuclear engineering, 0509 other social sciences, business, lcsh:TK1-9971, 0503 education, Discipline, Expansive, Diversity (politics)

Abstract

This paper examines the history of electrical engineering education, leveraging the concept of “expansive (dis)integration” to frame a number of key trends and challenges in the field. Our account is organized historically, starting with the origins and early development of electrical engineering education beginning in the late 1800s, and then tracing out the rise of new subfields and specialties during the inter-war and post-WWII periods. The development of computer engineering as a field is given special attention as a case study in disciplinary (dis)integration, while setting the stage for a discussion of broader trends associated with the rising influence of digital techniques and technologies across electrical engineering. The final sections of this paper report on some contemporary challenges and opportunities that may further transform the field in upcoming years and decades, with particular emphasis on issues of demographic diversity and perceptions of broader relevance and impact. The approach of this paper is largely historical, drawing on a wide variety of primary and secondary source materials. It is expected that this paper will be of interest to anyone who would like to know more about the historical development of electrical engineering education, including in relation to more contemporary currents in the field.

Published

2017

8. Aerial Image Color Balancing Based on Rank-Deficient Free Network

Author

Minglu Wei, Manzhu Yu, Li Zheng, Wenjie Jian, and Zongqian Zhan

Subjects

General Computer Science, Rank (linear algebra), business.industry, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, General Engineering, Orthophoto, Equalization (audio), Digital imaging, Process (computing), Color balance, General Materials Science, Computer vision, Artificial intelligence, Electrical and Electronic Engineering, business, Aerial image, Block (data storage)

Abstract

In the process of digital image acquisition, color inconsistency is a common issue due to the influence of photographic conditions. The inconsistency of color affects the quality of digital orthophoto products and subsequent applications significantly, and this issue remains challenging both in the academia and industry. This paper proposes a color equalization method for aerial image based on block adjustment and an improved color balance model based on the analysis of causes for color deviation. Two nonlinear functions are used to simulate the process of color deviation and correct the color of images. Due to the existence of error, the color corrected images still have minor deviations in the color of the overlapped regions. Therefore, this research introduces an error equation to address this issue and uses the least square principle to calculate the adjustment. The simulation experiments and real experiments are carried out on several groups of aerial image data respectively. The results show that the method not only achieves better visual effect but also has a higher adjustment precision. Finally, the rationality and parameters of the model proposed in this paper are discussed.

Published

2023

9. Research on Vehicle-to-Road Collaboration and End-to-End Collaboration for Multimedia Services in the Internet of Vehicles

Author

Songlin Sun and Zhi Ma

Subjects

General Computer Science, business.industry, computer.internet_protocol, Computer science, General Engineering, Service-oriented architecture, Telecommunications network, End-to-end principle, Resource allocation, General Materials Science, The Internet, Telematics, business, Intelligent transportation system, computer, Edge computing, Computer network

Abstract

With the development of mature communication network technologies such as 5G, edge computing and slicing, business applications in areas such as Telematics and intelligent transportation also need the support of vehicle-road collaboration technologies. Due to the mobility of vehicles and the heterogeneity of communication interfaces, it brings many challenges for data transmission and processing of Telematics. Therefore, network resources, roadside unit devices and sunken edge nodes need to work together to guarantee real-time network communication. Thus, they can jointly help improve the quality of network services and user experience, and show the level of vehicle-road collaboration wisdom in terms of safety, efficiency and service. In view of the future 5G network-related technologies and C-V2X development trend, this paper provides a comprehensive technical solution framework for Telematics based on end-edge collaboration, combining network resource deployment optimization and edge caching technologies for video transmission tasks in Telematics application scenarios. By adding 5G base station type RSU and UAV mobile base station to work jointly, network resources are better allocated for scalable coded video, and a relatively better edge caching strategy is obtained based on user mobility analysis. Aiming to improve the network system performance, the vehicle-side, road-side and edge-side are jointly considered to improve the utilization efficiency of limited network resources. In this paper, we hope to provide a practical and effective service architecture for Telematics video application scenarios through a convergence scheme of network resource allocation and edge caching configuration.

Published

2022

10. Interactive Analysis of Epidemic Situations Based on a Spatiotemporal Information Knowledge Graph of COVID-19

Author

Xiaojun Zhou, Tingting Li, Xiong You, Bingchuan Jiang, Ke Li, and Liheng Tan

Subjects

Information retrieval, General Computer Science, Knowledge representation and reasoning, Computer science, business.industry, Node (networking), Big data, General Engineering, Knowledge graph, Entity–relationship model, Similarity (psychology), General Materials Science, business, Semantic Web, Spatial analysis

Abstract

In view of the lack of data association in spatiotemporal information analysis and the lack of spatiotemporal situation analysis in knowledge graphs, this paper combines the semantic web of the geographic knowledge graph with the visual analysis model of spatial information and puts forward the comprehensive utilization of the related technologies of the geographic knowledge graph and big data visual analysis. Then, it realizes the situational analysis of COVID-19 (Coronavirus Disease 2019) and the exploration of patient relationships through interactive collaborative analysis. The main contributions of the paper are as follows. (1) Based on the characteristics of the geographic knowledge graph, a patient entity model and an entity relationship type and knowledge representation method are proposed, and a knowledge graph of the spatiotemporal information of COVID-19 is constructed. (2) To analyse the COVID-19 patients’ situations and explore their relationships, an analytical framework is designed. The framework, combining the semantic web of the geographic knowledge graph and the visual analysis model of geographic information, allows one to analyse the semantic web by using the node attribute similarity calculation, key stage mining, community prediction and other methods. (3) An efficient epidemic prevention and anti-epidemic method, which is of referential significance, is proposed. It is based on experiments and the collaborative analysis of the semantic web and spatial information, allowing for real-time situational understanding, the discovery of patients’ relationships, the analysis of the spatiotemporal distribution of patients, super spreader mining, key node analysis, and the prevention and control of high-risk groups.

Published

2022

11. Fault Reconfiguration Strategies of Active Distribution Network With Uncertain Factors for Maximum Supply Capacity Enhancement

Author

Xiaoqin Wang, Jiabin Jv, Yang Xin, Weixing Qiu, Jing Xu, Xudan Sheng, and Wanli He

Subjects

Wind power, General Computer Science, Computer science, business.industry, Stochastic modelling, General Engineering, Control reconfiguration, Fault (power engineering), Power (physics), Reliability engineering, Latin hypercube sampling, Distributed generation, General Materials Science, Electrical and Electronic Engineering, business, Random variable

Abstract

With a large number of distributed generation connected to the distribution network, the total supply capacity of the distribution network has been improved to a certain extent. However, due to the randomness of its output, it also brings some challenges to the reliable operation of the distribution network and the restoration of power supply after failure. Based on this, this paper proposes an active distribution network reconfiguration strategy with uncertain factors for maximum total supply capacity improvement. Firstly, the evaluation index of the maximum total supply capacity of distribution network is constructed, and the maximum total supply capacity index under the current operation mode is evaluated online through the calculation model of maximum total supply capacity based on N-1 security criterion. Then, the uncertainty of wind power, photovoltaic and electric vehicle DG and the stochastic model of prosumer load are considered, random variables are generated by Latin hypercube sampling (LHS) and their correlation is considered. Then, it introduces that the position of sectionalizing switch and tie switch can be adjusted according to the dispatching demand. Based on the evaluation index of maximum total supply capacity and DG output of uncertain factors, the active reconfiguration model of distribution network after fault is proposed. Finally, a calculation example illustrates the effectiveness and correctness of the model in this paper. It is demonstrated that the model can optimize the selection strategy of section switch and tie switch after the fault of distribution network, improve the utilization rate of distributed energy, and give full play to the power supply recovery potential of distribution network and reduce the outage time of prosumer groups.

Published

2022

12. Cloud-Native Network Slicing Using Software Defined Networking Based Multi-Access Edge Computing: A Survey

Author

Syed Danial Ali Shah, Mark A. Gregory, and Shuo Li

Subjects

Service (systems architecture), General Computer Science, Computer science, Distributed computing, Cloud computing, 02 engineering and technology, Microservices, multi-access edge computing, Server, software defined networking, ultra-reliable, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Network slicing, Edge computing, business.industry, General Engineering, 020206 networking & telecommunications, low latency communication, TK1-9971, Elasticity (cloud computing), cloud native, Scalability, Cellular network, Resource allocation, 020201 artificial intelligence & image processing, Electrical engineering. Electronics. Nuclear engineering, Software-defined networking, business

Abstract

Fifth-Generation (5G) mobile cellular networks provide a promising platform for new, innovative and diverse IoT applications, such as ultra-reliable and low latency communication, real-time and dynamic data processing, intensive computation, and massive device connectivity. End-to-End (E2E) network slicing candidates present a promising approach to resource allocation and distribution that permit operators to flexibly provide scalable virtualized and dedicated logical networks over common physical infrastructure. Though network slicing promises the provision of services on demand, many of its use cases, such as self-driving cars and Google's Stadia, would require the integration of a Multi-Access Edge Computing (MEC) platform in 5G networks. Edge Computing is envisioned as one of the key drivers for 5G and Sixth-Generation (6G) mobile cellular networks, but its role in network slicing remains to be fully explored. We investigate MEC and network slicing for the provision of 5G service focused use cases. Recently, changes to the cloud-native 5G core are a focus with MEC use cases providing network scalability, elasticity, flexibility, and automation. A cloud-native microservices architecture, along with its potential use cases for 5G network slicing, is envisioned. This paper also elaborates on the recent advances made in enabling E2E network slicing, its enabling technologies, solutions, and current standardization efforts. Finally, this paper identifies open research issues and challenges and provides possible solutions and recommendations.

Published

2021

13. A Survey on Beyond 5G Network With the Advent of 6G: Architecture and Emerging Technologies

Author

Anutusha Dogra, Rakesh Kumar Jha, and Shubha Jain

Subjects

General Computer Science, Computer science, 02 engineering and technology, Radio spectrum, eMBB, 0203 mechanical engineering, Next-generation network, 0202 electrical engineering, electronic engineering, information engineering, Wireless, General Materials Science, Edge computing, Wireless network, business.industry, Mobile broadband, General Engineering, 020206 networking & telecommunications, 020302 automobile design & engineering, TK1-9971, 5G NR, Handover, EVM, Optical wireless, uRLLC, Electrical engineering. Electronics. Nuclear engineering, mMTC, business, 5G, Computer network

Abstract

Nowadays, 5G is in its initial phase of commercialization. The 5G network will revolutionize the existing wireless network with its enhanced capabilities and novel features. 5G New Radio (5G NR), referred to as the global standardization of 5G, is presently under the $3^{\mathrm {rd}}$ Generation Partnership Project (3GPP) and can be operable over the wide range of frequency bands from less than 6GHz to mmWave (100GHz). 3GPP mainly focuses on the three major use cases of 5G NR that are comprised of Ultra-Reliable and Low Latency Communication (uRLLC), Massive Machine Type Communication (mMTC), Enhanced Mobile Broadband (eMBB). For meeting the targets of 5G NR, multiple features like scalable numerology, flexible spectrum, forward compatibility, and ultra-lean design are added as compared to the LTE systems. This paper presents a brief overview of the added features and key performance indicators of 5G NR. The issues related to the adaptation of higher modulation schemes and inter-RAT handover synchronization are well addressed in this paper. With the consideration of these challenges, a next-generation wireless communication architecture is proposed. The architecture acts as the platform for migration towards beyond 5G/6G networks. Along with this, various technologies and applications of 6G networks are also overviewed in this paper. 6G network will incorporate Artificial intelligence (AI) based services, edge computing, quantum computing, optical wireless communication, hybrid access, and tactile services. For enabling these diverse services, a virtualized network slicing based architecture of 6G is proposed. Various ongoing projects on 6G and its technologies are also listed in this paper.

Published

2021

14. Block Cipher Nonlinear Confusion Components Based on New 5-D Hyperchaotic System

Author

Nestor Tsafack, Ahmed Alkhayyat, Rafeeq Ahmed, Adi Alhudhaif, Alaa Kadhim Farhan, and Musheer Ahmad

Subjects

substitution-box, General Computer Science, Computer science, business.industry, General Engineering, Chaotic, Cryptography, security, Dynamical system, Encryption, TK1-9971, Nonlinear system, Dimension (vector space), Block ciphers, Attractor, General Materials Science, Electrical engineering. Electronics. Nuclear engineering, Electrical and Electronic Engineering, business, Algorithm, hyperchaotic system, Block cipher

Abstract

The security strengths of block ciphers greatly rely on the confusion components which have the tendency to transform the data nonlinearly into the perplexed form. This paper proposes to put forward a novel scheme of generating cryptographically strong nonlinear confusion components of block ciphers, usually termed as substitution-boxes (S-boxes). The anticipated S-box design scheme is based on a novel five-dimensional (5-D) chaotic system analyzed in this paper. The proposed 5-D dynamical system consists of hyperchaotic phenomenon, KY dimension, conservativity, unstable equilibrium point, and complex phase attractors which are suited for cryptographic applications. The S-box based on hyperchaotic system is made to evolve in order to generate an optimized S-box for high nonlinearity score to make it robust against many linear attacks. The performance analysis of proposed S-box demonstrates that it has bijectivity, high nonlinearity; satisfied strict avalanche criterion and bits independent criterion; low differential and linear probabilities. Moreover, performance appraisal of proposed S-box justifies its better strength and features over many recently investigated S-boxes.

Published

2021

15. Dynamic Hot Data Identification Using a Stack Distance Approximation

Author

Hyeonji Ha, Daeun Shim, Hyeyin Lee, and Dongchul Park

Subjects

General Computer Science, Computational complexity theory, Computer science, hot data, Computation, Big data, Hash function, Word error rate, 02 engineering and technology, Bloom filter, flash memory, stack distance, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, SSD, business.industry, hot data identification, Search engine indexing, General Engineering, Approximation algorithm, 020207 software engineering, TK1-9971, Computer engineering, Electrical engineering. Electronics. Nuclear engineering, Cache, business

Abstract

Though various applications such as flash memory, cache, storage systems, and even indexing for enterprise big data search, adopt hot data identification schemes, relatively little research has been expended into holistically examining alternative strategies. Rather, researchers tend to classify hot data simplistically by considering one or more frequency metrics, thereby disregarding recency, which is also an important consideration. In practice, different workloads mandate different treatment to achieve effective hot data decisions. This paper proposes a dynamic hot data identification scheme that adopts a workload stack distance approximation. Stack distance is a good recency measure, but it traditionally requires high computational complexity as well as additional space. Since stack distance calculation efficiency is a core component for our dynamic feature design, this paper additionally proposes a stack distance approximation algorithm that significantly reduces both computation and space requirements. To our knowledge, the proposed scheme is the first dynamic hot data identification scheme which judiciously assigns more weight to either recency or frequency based on workload characteristics. Our experiments with diverse realistic workloads demonstrate that our stack distance approximation achieves excellent accuracy (up to a 0.1% error rate) and our dynamic scheme improves performance by as much as 49.8%.

Published

2021

16. Enhancing a 5G Network Slicing Management Model to Improve the Support of Mobile Virtual Network Operators

Author

Andres Cardenas, David Fernandez, Carlos M. Lentisco, Ricardo Flores Moyano, and Luis Bellido

Subjects

Flexibility (engineering), Service (systems architecture), network slicing, General Computer Science, business.industry, Computer science, General Engineering, software-defined networks, multiaccess edge computing, TK1-9971, Management system, network function virtualization, General Materials Science, Electrical engineering. Electronics. Nuclear engineering, Isolation (database systems), Orchestration (computing), virtualized network function orchestration, business, Virtual network, 5G, Mobile network operator, Computer network

Abstract

Network slicing is a key element in 5G networks. It allows a mobile network operator (MNO) to offer multiple logical networks tailored to the requirements of different industry verticals over a shared infrastructure. From the point of view of an MNO, a mobile virtual network operator (MVNO) is a particular type of vertical network requiring not only the provision of logical networks with specific infrastructure resources but also customized management capabilities to allow the MVNO to offer network slice-based services to its clients over the infrastructure of multiple MNOs. However, the lack of flexibility to provide a customized and efficient network slice management system per tenant under the current proposals of the 3rd Generation Partnership Project (3GPP) and European Telecommunications Standards Institute (ETSI) limits the possibilities of MVNOs. This paper addresses this requirement by proposing a novel virtualized multidomain and multiclient orchestration system aligned with the functionalities of the network slicing management framework proposed by the 3GPP and ETSI. In particular, there are three contributions of this paper: (i) an extended service-based architecture is designed to provide an isolated management system to different MVNOs; (ii) a novel high-level slice instance template is defined to specify management and isolation requirements supporting network slicing as a service model; and (iii) finally, a teleoperated driving use case is described to showcase how our proposal provides an MVNO with an independent management system to orchestrate several network slices in cross-domain environments.

Published

2021

17. S&I Reader: Multi-Granularity Gated Multi-Hop Skimming and Intensive Reading Model for Machine Reading Comprehension

Author

Duoqian Miao, Yong Wang, and Chong Lei

Subjects

General Computer Science, Computer science, media_common.quotation_subject, Natural language understanding, Context (language use), 02 engineering and technology, 010501 environmental sciences, computer.software_genre, 01 natural sciences, Reading (process), 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, 0105 earth and related environmental sciences, media_common, Context model, business.industry, Granular computing, General Engineering, Task analysis, 020201 artificial intelligence & image processing, Granularity, Artificial intelligence, Language model, business, computer, Natural language processing

Abstract

Machine reading comprehension is a very challenging task, which aims to determine the answer span based on the given context and question. The newly developed pre-training language model has achieved a series of successes in various natural language understanding tasks with its powerful contextual representation ability. However, these pre-training language models generally lack the downstream processing structure for specific tasks, which limits further performance improvement. In order to solve this problem and deepen the model’s understanding of the question and context, this paper proposes S&I Reader. On the basis of the pre-training model, skimming, intensive reading, and gated mechanism modules are added to simulate the behavior of humans reading text and filtering information. Based on the idea of granular computing, a multi-granularity module for computing context granularity and sequence granularity is added to the model to simulate the behavior of human beings to understand the text from words to sentences, from parts to the whole. Compared with the previous machine reading comprehension model, our model structure is novel. The skimming module and multi-granularity module proposed in this paper are used to solve the problem that the previous model ignores the key information of the text and cannot understand the text with multi granularity. Experiments show that the model proposed in this paper is effective for both Chinese and English datasets. It can better understand the question and context and give a more accurate answer. The performance has made new progress on the basis of the baseline model.

Published

2021

18. Segmentation of the Airway Tree From Chest CT Using Tiny Atrous Convolutional Network

Author

Xiaoming Wu, Guohua Cheng, Chuan Guo, He Linyang, Wending Xiang, and Hongli Ji

Subjects

General Computer Science, Computer science, convolutional neural network, Convolutional neural network, 030218 nuclear medicine & medical imaging, Convolution, 03 medical and health sciences, 0302 clinical medicine, Robustness (computer science), General Materials Science, Segmentation, Ground truth, business.industry, Deep learning, General Engineering, deep learning, Pattern recognition, Image segmentation, Airway classification, respiratory system, semantic segmentation, respiratory tract diseases, medical image, lcsh:Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, business, Airway, lcsh:TK1-9971, 030217 neurology & neurosurgery, CT

Abstract

The airway tree is one of the most important part in human respiratory system. Airway segmentation plays a crucial role in pulmonary disease diagnosis, localization and surgical navigation. We propose a novel method to improve airway segmentation in thoracic computed tomography(CT) using deep learning. In order to take into account the multi-scale changes of the airway and achieve accurate airway segmentation, we design an end-to-end Tiny Atrous Convolutional Network (TACNet) based on 3D convolution neural network. In view of the difficulty of classification due to the numerous branches of airway, two evaluation factors, namely, the angle of airway bifurcation and the buffer length of airway bifurcation are designed, which are used for airway classification by combining the centerline extraction. We train TACNet on the inspirator thoracic CT scans with ground truth, which are generated by clinicians and evaluate on our own clinical data sets and EXACT’09 data sets. Compared with state-of-the-art airway segmentation algorithms, proposed algorithm in this paper achieve very competitive results in 20 test datasets of the EXACT’09 challenge. The experimental results show that the algorithm proposed in this paper has high robustness and advantages regardless of airway segmentation or airway classification. In 20 test datasets of the EXACT’09 challenge, the average airway tree length detection rate is the best in the public literatures.

Published

2021

19. Learning to Detect Incongruence in News Headline and Body Text via a Graph Neural Network

Author

Seunghyun Yoon, Kyomin Jung, Minwoo Lee, Meeyoung Cha, Taegyun Kim, and Kunwoo Park

Subjects

General Computer Science, Computer science, 050801 communication & media studies, 02 engineering and technology, computer.software_genre, 0508 media and communications, Margin (machine learning), 020204 information systems, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Electrical and Electronic Engineering, Artificial neural network, business.industry, Deep learning, 05 social sciences, General Engineering, Headline, Graph neural network, headline incongruity, Body text, Recurrent neural network, Graph (abstract data type), online misinformation, lcsh:Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, business, lcsh:TK1-9971, computer, Encoder, Natural language processing

Abstract

This paper tackles the problem of detecting incongruities between headlines and body text, where a news headline is irrelevant or even in opposition to the information in its body. Our model, called the graph-based hierarchical dual encoder (GHDE), utilizes a graph neural network to efficiently learn the content similarity between news headlines and long body paragraphs. This paper also releases a million-item-scale dataset of incongruity labels that can be used for training. The experimental results show that the proposed graph-based neural network model outperforms previous state-of-the-art models by a substantial margin (5.3%) on the area under the receiver operating characteristic (AUROC) curve. Real-world experiments on recent news articles confirm that the trained model successfully detects headline incongruities. We discuss the implications of these findings for combating infodemics and news fatigue.

Published

2021

20. Security Verification for Cyber-Physical Systems Using Model Checking

Author

Ching-Chieh Chan, Cheng-Zen Yang, and Chin-Feng Fan

Subjects

Model checking, 0209 industrial biotechnology, Security analysis, General Computer Science, Computer science, security constraint, 0211 other engineering and technologies, 02 engineering and technology, Computer security, computer.software_genre, 020901 industrial engineering & automation, General Materials Science, 021110 strategic, defence & security studies, business.industry, Cyber-physical systems, General Engineering, Cyber-physical system, Information technology, Safety constraints, Systems modeling, model checking, UPPAAL, TK1-9971, security verification, Domain knowledge, Electrical engineering. Electronics. Nuclear engineering, State (computer science), business, computer, operation technology

Abstract

A malicious attack may endanger human life or pollute environment on a cyber-physical system (CPS). However, successfully attacking a CPS needs not only the knowledge of information technology (IT) but also the domain knowledge of the system’s operation technology (OT). Therefore, it is critical to identify the vulnerabilities of a CPS. This paper proposes a systematic method for the security verification of a CPS, focusing on OT by using model checking with UPPAAL, so as to enhance cyber security. In our security analysis, we considered unsafe situations to be the result of a potentially effective security attack. Thus, we suggested a systematic method to generate security constraints based on the safety constraints (or safety checks) of the CPS and then enhance these security constraints by security verification using model checking with UPPAAL. UPPAAL’s simulation tool can perform a detailed search for each state in various possible model combinations and can explore human-computer interactions more deeply. The contributions of our method are as follows: First, a systematic method is proposed to generate security constraints based on the overall safety requirements at the OT level. Second, the security constraints thus generated can be used for run-time monitoring to identify the possible security attacks when they are violated. Third, this paper proposes to augment normal system modeling with a suggested Attack Module to simulate the potential OT attacks. Finally, the verification results may be used in the following twofold directions: to identify the vulnerabilities for possible design improvements and to suggest the further additions of security constraints.

Published

2021

21. Multi-Task Learning for Efficient Management of Beyond 5G Radio Access Network Architectures

Author

Zoraze Ali, Lorenza Giupponi, Marco Miozzo, and Paolo Dini

Subjects

mobile networks, General Computer Science, Computer science, Linearization, Multi-task learning, RNN, ARPU, Hand over, 5G mobile communication systems, Quality of service, Deep neural networks, Long short-term memory, 3GPP, General Materials Science, Computer architecture, UE, next generation self-organizing networks, 6G, Radio access network, business.industry, UL, Network architecture, General Engineering, deep learning, AE, Deep learning, Radio access networks, 3rd generation partnership project, Radio, TK1-9971, Self-organising, Next generation networks, 3rd generation, Mobile network, machine learning, Next generation self-organizing network, AI, Task analysis, V2X, Job analysis, Electrical engineering. Electronics. Nuclear engineering, LSTM, business, 5G, Computer network

Abstract

Automation of Radio Access Network (RAN) operation is a fundamental feature to manage sustainable and efficient Beyond Fifth-generation wireless (5G) networks, in the context of the Next Generation Self-Organizing Network (NG-SON) vision. Machine Learning (ML) is already identified as the key ingredient of this vision, with new standardized and open architectures, like Open-RAN (O-RAN), taking momentum. In this paper, we propose models based on single-task and Multi-Task Learning (MTL) paradigms to address two RAN use cases, handover management and initial Modulation and Coding Scheme (MCS) selection. Traditional handover schemes have the drawback of taking into account the quality of the signals from the serving, and the target cell, before the handover. Also, initial MCS at the start of the session and after a handover usually is handled conservatively. The proposed ML solutions allow to address these drawbacks by 1) considering the expected Quality of Experience (QoE) resulting from the decision of a target cell to handover, as the driving principle of the handover decision and 2) using the experience extracted from network data to make smarter initial MCS allocations. In this line, we implement a realistic cellular simulation scenario by incorporating coverage holes to build an extensive database to train and test the proposed models. The results show that the ML-based models outperform the 3rd Generation Partnership Project (3GPP) standardized handover and initial MCS selection approaches by improving the QoE of users resulting from a handover and the throughput obtained upon establishing a new connection with a network. Besides that, using the obtained results, this paper extensively discusses the merits of leveraging the MTL model to address different, but related multiple RAN functions because it allows reusing a common learning architecture for multiple RAN use cases, which provides significant implementation advantages., This work was supported in part by under Grant PID2020-113832RB-C22 (ORIGIN)/AEI/10.13039/501100011033, and in part by Huawei Technologies, Sweden AB.

Published

2021

22. Using Overhearing and Rateless Coding in Disseminating Various Messages in Vehicular AdHoc Networks

Author

Nadia H. Khiadani, Maryam Ataei Kachooei, Mostafa Nozari, and Faramarz Hendessi

Subjects

Vehicular ad hoc network, General Computer Science, Handshake, business.industry, Network packet, Computer science, Wireless ad hoc network, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, General Engineering, rateless coding, data dissemination, TK1-9971, Overhead (computing), General Materials Science, Network performance, VANETs, overhearing, Electrical engineering. Electronics. Nuclear engineering, Latency (engineering), business, Dissemination, Computer network

Abstract

Vehicular Ad hoc Networks (VANETs) are emerging technologies with the primary purpose of establishing Vehicular communications. Available protocols for data dissemination in VANETs are faced with issues like discontinuous connections, uncertainty about receiving messages, collisions, and latency. In this paper, a new method is presented for the dissemination of advertising and infotainment messages. The proposed method has used store carry and forward (SCF), rateless coding, and a new handshake mechanism to solve discontinuous connections, uncertainty about receiving messages, and collision problems, respectively. In this paper, changing the Road Side Unit (RSU) message over time and its impact on the network is proposed as a new step in evaluating data dissemination methods. Our results showed that if changing the RSU message happened very rapidly, the network performance will almost be eliminated; to address this problem and due to the advertising nature of messages, the use of overhearing has been suggested. To the best of our knowledge, this is the first time that message overhearing has been used in VANET. Extensive and accurate simulations results show that the proposed method for 2, 3, 5, and 10 messages: (i) reduces the overhead of handshake on average 70% 63%, 48%, and 3%, (ii) increases the number of delivered packets on average 5%, 22%, 75%, and 84%, and (iii) increases the range of data dissemination on average 47%, 187%, 661%, and 2962%, respectively. With the mentioned improvements, the proposed method can also significantly reduce the latency of disseminating messages between vehicles.

Published

2021

23. Random Differential Fault Attacks on the Lightweight Authenticated Encryption Stream Cipher Grain-128AEAD

Author

Wei-Chuen Yau, Luxin Xue, Iftekhar Salam, Thian Hooi Ooi, Josef Pieprzyk, and Raphael C.-W. Phan

Subjects

Authenticated encryption, General Computer Science, Computer science, Hardware_PERFORMANCEANDRELIABILITY, 02 engineering and technology, Encryption, Fault (power engineering), NIST, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Side channel attack, Stream cipher, random fault, business.industry, General Engineering, Probabilistic logic, Fault injection, Grain-128AEAD, TK1-9971, 020202 computer hardware & architecture, differential fault attack, lightweight cryptography, 020201 artificial intelligence & image processing, Electrical engineering. Electronics. Nuclear engineering, business, Algorithm

Abstract

Grain-128AEAD is a lightweight authenticated encryption stream cipher and one of the finalists in the National Institute of Standards and Technology (NIST) Lightweight Cryptography (LWC) project. This paper provides an independent third-party analysis of Grain-128AEAD against fault attacks. We investigate the application of three differential fault attack models on Grain-128AEAD. All these attacks can recover the initial state of Grain-128AEAD. First, we demonstrate an attack using a bit-flipping fault that requires access to 27.80 faulty outputs to recover the initial state. Then, we demonstrate an attack with a more relaxed assumption of a random fault with a probabilistic approach. Our probabilistic random fault attack requires access to 211.60 faulty outputs and 210.45 fault injections to recover the initial state with a success rate over 99%. Both of the above two attacks are based on precise control on the fault target. Finally, we apply a random fault attack with a deterministic approach (can conclusively determine the random fault value) and using different precision controls. For the precise control, we use existing approaches that have been applied to other ciphers, such as Tiaoxin-346. We also propose a technique for less stringent precision models, such as moderate control and no control, which are more practical than the precise control. Our result indicates that the deterministic random fault attack with a precise control requires an average of 27.64 fault injections and a data complexity of 28.80. The deterministic random fault attack with moderate control requires a weak assumption on the fault injection and hence, is the best attack presented in this paper; and is expected to require about 29.39 fault injections with a data complexity of about 212.98. All the attacks discussed in this paper are verified experimentally.

Published

2021

24. Detection of Historical Alarm Subsequences Using Alarm Events and a Coactivation Constraint

Author

Gianluca Manca and Alexander Fay

Subjects

alarm systems, Normalization (statistics), 0209 industrial biotechnology, General Computer Science, Computer science, alarm management, 02 engineering and technology, computer.software_genre, ALARM, 020901 industrial engineering & automation, Robustness (computer science), Alarm management, 0202 electrical engineering, electronic engineering, information engineering, alarm analysis, General Materials Science, business.industry, General Engineering, alarm floods, Automation, TK1-9971, Abnormal situations, Constraint (information theory), Benchmark (computing), 020201 artificial intelligence & image processing, Anomaly detection, Electrical engineering. Electronics. Nuclear engineering, Data mining, business, computer

Abstract

This paper aims to provide an in-depth study of the detection of historical alarm subsequences, which are frequently used as an initial step for alarm flood analysis methods. Therefore, state-of-the-art approaches are comprehensively examined, evaluated, and compared. To overcome the limitations of these methods, a novel approach is presented, which uses outlier detection in time distances between alarm events (activation and return to normal) and an alarm coactivation constraint. The effectiveness and performance of the examined methods are illustrated by means of an openly accessible dataset, which is introduced in this paper. It is based on the “Tennessee-Eastman-Process”, a benchmark in process automation. The intent is to provide a suitable dataset for the development and evaluation of alarm management methods in complex industrial processes using both quantitative and qualitative information from different sources. It is shown that the integration of supplementary information is beneficial for the overall performance and robustness of the detection method proposed here. This method allows for a more accurate detection of coherent historical abnormal situations, including phases with active root-cause disturbances and the normalization phases that follow their termination. Furthermore, the proposed method has the advantage that the detection results are less influenced by the alarm count, the propagation velocity, the duration of the situation, and the time distance between two causally independent situations in comparison to state-of-the-art approaches.

Published

2021

25. Reduction of Torque Ripples in Multi-Stack Slotless Axial Flux Machine by Using Right Angled Trapezoidal Permanent Magnet

Author

Muhammad Yousuf, Faisal Khan, Junaid Ikram, Rabiah Badar, Syed Sabir Hussain Bukhari, and Jong-Suk Ro

Subjects

torque ripples, General Computer Science, Computer science, Stator, 020209 energy, finite element analysis, 02 engineering and technology, law.invention, cogging torque, law, 0202 electrical engineering, electronic engineering, information engineering, Torque, General Materials Science, Torque ripple, Saturation (magnetic), business.industry, 020208 electrical & electronic engineering, slotless stator, General Engineering, Cogging torque, Structural engineering, Finite element method, Vibration, Axial flux machine, Magnet, lcsh:Electrical engineering. Electronics. Nuclear engineering, Reduction (mathematics), business, lcsh:TK1-9971, Axial flux

Abstract

The aim of this paper is to design, analyze and optimize the “Multi-Stack Slotless Axial Flux Switching Permanent Magnet Machine”. In the design process, mathematical models are implemented, and the Finite Element Method (FEM) is performed to analyze the machine performances. The paper aims to minimize the occurrence of cogging torque and torque ripple in the multi-stack slotless stator AFPM machine. As a consequence, it reduces the vibrations in the machine and increases its life span. Multi-stack slotless stator AFPM machine with a right-angled trapezoid-shaped PM is proposed and comparison is done with conventional shape AFPM machine. In order to examine the performance of multi-stack slotless stator AFPM machine Finite Element Analysis (FEA) is used. To further enhance the characteristics of the designed machine with the proposed right-angled PM shape, optimization is done by considering inner and outer pole pitch as the design variables. In optimization process, krigging method assigned with Latin Hyper-cube Sampling and a genetic algorithm (GA) is performed due to suitability with non-linear data. Then, finite element analysis by JMAG-Designer is performed to verify the results. It is determined that optimized model has achieved 65% reduction in torque ripples as compared with the conventional design. Hence, this work attempts to optimize the performance of the AFPM machine.

Published

2021

26. Benchmarking of Machine Learning for Anomaly Based Intrusion Detection Systems in the CICIDS2017 Dataset

Author

Robiah Yusof, Nazrulazhar Bahaman, Cik Feresa Mohd Foozy, Salama A. Mostafa, and Ziadoon Kamil Maseer

Subjects

General Computer Science, Computer science, Feature extraction, Decision tree, supervised and unsupervised learning, 02 engineering and technology, Intrusion detection system, Machine learning, computer.software_genre, Convolutional neural network, Cyberattacks, Naive Bayes classifier, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Artificial neural network, business.industry, Deep learning, General Engineering, 020206 networking & telecommunications, Random forest, Support vector machine, Statistical classification, machine learning, intrusion detection system, 020201 artificial intelligence & image processing, lcsh:Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, business, lcsh:TK1-9971, computer

Abstract

An intrusion detection system (IDS) is an important protection instrument for detecting complex network attacks. Various machine learning (ML) or deep learning (DL) algorithms have been proposed for implementing anomaly-based IDS (AIDS). Our review of the AIDS literature identifies some issues in related work, including the randomness of the selected algorithms, parameters, and testing criteria, the application of old datasets, or shallow analyses and validation of the results. This paper comprehensively reviews previous studies on AIDS by using a set of criteria with different datasets and types of attacks to set benchmarking outcomes that can reveal the suitable AIDS algorithms, parameters, and testing criteria. Specifically, this paper applies 10 popular supervised and unsupervised ML algorithms for identifying effective and efficient ML-AIDS of networks and computers. These supervised ML algorithms include the artificial neural network (ANN), decision tree (DT), k-nearest neighbor (k-NN), naive Bayes (NB), random forest (RF), support vector machine (SVM), and convolutional neural network (CNN) algorithms, whereas the unsupervised ML algorithms include the expectation-maximization (EM), k-means, and self-organizing maps (SOM) algorithms. Several models of these algorithms are introduced, and the turning and training parameters of each algorithm are examined to achieve an optimal classifier evaluation. Unlike previous studies, this study evaluates the performance of AIDS by measuring the true positive and negative rates, accuracy, precision, recall, and F-Score of 31 ML-AIDS models. The training and testing time for ML-AIDS models are also considered in measuring their performance efficiency given that time complexity is an important factor in AIDSs. The ML-AIDS models are tested by using a recent and highly unbalanced multiclass CICIDS2017 dataset that involves real-world network attacks. In general, the k-NN-AIDS, DT-AIDS, and NB-AIDS models obtain the best results and show a greater capability in detecting web attacks compared with other models that demonstrate irregular and inferior results.

Published

2021

27. Adversarial Training Time Attack Against Discriminative and Generative Convolutional Models

Author

Subhajit Chaudhury, Hiya Roy, Sourav Mishra, and Toshihiko Yamasaki

Subjects

General Computer Science, Artificial neural network, Computer science, Adaptive optimization, business.industry, General Engineering, Evolutionary algorithm, Overfitting, Machine learning, computer.software_genre, Convolutional neural network, variational information bottleneck, TK1-9971, data poisoning, adaptive optimization, Stochastic gradient descent, Discriminative model, Robustness (computer science), Generalization in deep learning, training time attack, General Materials Science, Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, business, computer

Abstract

In this paper, we show that adversarial training time attacks by a few pixel modifications can cause undesirable overfitting in neural networks for both discriminative and generative models. We propose an evolutionary algorithm to search for an optimal pixel attack using a novel cost function inspired by domain adaptation literature to design our training time attack. The proposed cost function explicitly maximizes the generalization gap and domain divergence between clean and corrupted images. Empirical evaluations demonstrate that our adversarial training attack can achieve significantly low testing accuracy (with high training accuracy) on multiple datasets by just perturbing a single pixel in the training images. Even under the use of popular regularization techniques, we identify a significant performance drop compared to clean data training. Our attack is more successful than previous pixel-based training time attacks on state-of-the-art Convolutional Neural Networks (CNNs) architectures, as evidenced by significantly lower testing accuracy. Interestingly, we find that the choice of optimization plays an essential role in robustness against our attack. We empirically observe that Stochastic Gradient Descent (SGD) is resilient to the proposed adversarial training attack, different from adaptive optimization techniques such as the popular Adam optimizer. We identify that such vulnerabilities are caused due to over-reliance on the cross-entropy (CE) loss on highly predictive features. Therefore, we propose a robust loss function that maximizes the mutual information between latent features and input images, in addition to optimizing the CE loss. Finally, we show that the discriminator in Generative Adversarial Networks (GANs) can also be attacked by our proposed training time attack resulting in poor generative performance. Our paper is one of the first works to design attacks for generative models.

Published

2021

28. Research on Deep Learning Individual Tree Segmentation Method Coupling RetinaNet and Point Cloud Clustering

Author

Weigang Zhu, Chao Zhu, and Yaqiu Zhang

Subjects

Watershed, General Computer Science, Computer science, business.industry, Deep learning, Feature extraction, General Engineering, Orthophoto, Point cloud, Digital Orthophoto Map, computer.software_genre, TK1-9971, Tree (data structure), Deep Learning, individual tree segmentation, computer graphics, airborne LiDAR, General Materials Science, Segmentation, Electrical engineering. Electronics. Nuclear engineering, Data mining, Artificial intelligence, business, Cluster analysis, computer

Abstract

Increasing human activities have caused serious disturbance to global forest resources, so how to accurately identify individual trees has become an important task of forest resources investigation. In order to get the accurate number of individual trees, this paper took coniferous forest and mixed coniferous and broad-leaved forest as experimental samples, as well as Digital Orthophoto Map and airborne LiDAR Point Cloud as research data. We propose a deep Learning individual tree segmentation method based on RetinaNet model and PCS algorithm by doing comparative analysis (classical Watershed Algorithm and Layer Stacking Algorithm) at the plots (with high, medium, and low densities). The experimental results show that the method proposed in this paper can solve the problem of individual tree segmentation in high density forest and improve its degree of automation. Compared with Watershed algorithm and Layer stacking algorithm, F-Measure is improved by 6%-29% and 7%-20%, respectively. In other words, the results of individual tree segmentation presented in this paper can not only improve the precision of individual tree segmentation, but also maintain a high detection rate, which can meet the accuracy and high efficiency of individual tree extraction, so as to meet the needs for modern forestry investigation.

Published

2021

29. A Cross Connected Asymmetrical Switched-Capacitor Multilevel Inverter

Author

Md. Reyaz Hussan, Adil Sarwar, Marif Daula Siddique, Atif Iqbal, and Basem Alamri

Subjects

Power loss, self- voltage balancing, General Computer Science, multilevel inverter, Computer science, business.industry, General Engineering, Topology (electrical circuits), Switched capacitor, Topology, Network topology, TK1-9971, law.invention, Maximum efficiency, Capacitor, Level-shifted PWM, Software, law, Multilevel inverter, General Materials Science, total harmonic distortion, Electrical engineering. Electronics. Nuclear engineering, business, switched-capacitor MLI

Abstract

A Switched-Capacitor Multilevel Inverter (SCMLI) topology is proposed here, which can generate up to fifteen levels with one unit and can be extended further for getting higher levels. The proposed SCMLI has a lesser number of switching devices with respect to other recently proposed structures presented in this paper. It also has the capacitor self-balancing property. Power loss analysis has also been done using PLECS software. Maximum efficiency of 96.33 % has been achieved. A generalized comparative study has also been carried out with the newly presented topologies in different research articles considering several parameters. In order to validate the structure presented in this paper, simulation is done in Matlab®2018a, and the simulation results obtained are verified using an experimental prototype.

Published

2021

30. IoT-Based Interdigital Capacitance Sensing System for Damage Detection in CFRP-Concrete Structures

Author

Mohamed Abdelraheem, Mahmoud Abdelhafeez, and Amr Nassr

Subjects

Structural health monitoring, General Computer Science, Computer science, business.industry, Capacitive sensing, Node (networking), Internet of Things, General Engineering, Process (computing), Capacitance, TK1-9971, Nondestructive testing, Electronic engineering, Systems design, General Materials Science, inter digital capacitance sensor, Electrical engineering. Electronics. Nuclear engineering, business, Graphical user interface

Abstract

In this paper, we present an Internet of Things framework for structural health monitoring. The proposed system detects the delimitation and debonding in composite concrete structures: more specifically, develop an IoT-Based Non-Destructive Test (NDT) to detect debonding between Carbon Fiber sheets and Concrete slabs. An Inter Digital Capacitance Sensor is designed and fabricated to function as the primary detection element. The sensor is embedded within an IoT node that manages the measurement process, captures the measurement location automatically, and performs essential data filtering operations with an attached graphical interface that allows basic control and early-access to the measured data. The IoT node integrates within the larger framework via wireless WiFi connection throughout which the data is transferred and control functions are administrated. The paper presents the system design details including mathematical modeling for the capacitance sensing element, finite element simulation results, and practical setup measured data.

Published

2021

31. Pixel-Level Prediction for Ocean Remote Sensing Image Features Fusion Based on Global and Local Semantic Relations

Author

Lin Cao, Gao Hao, Dingfeng Yu, Yang Lei, Guangbing Yang, and Xuejun Xiong

Subjects

features fusion, General Computer Science, Computer science, Feature extraction, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, 0211 other engineering and technologies, 02 engineering and technology, Image (mathematics), Convolution, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, 021101 geological & geomatics engineering, Fusion, Pixel, business.industry, General Engineering, deep learning, Pattern recognition, TK1-9971, Ocean remote sensing, Feature (computer vision), multi-scale convolutional, Imaging technology, 020201 artificial intelligence & image processing, Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, business

Abstract

With the rapid development of remote-sensing imaging technology, remote-sensing images have become increasingly diverse, and people are paying more attention to ocean remote-sensing research. Because ocean remote-sensing data are complex, and the ocean environment is diverse, results will differ, even if the same target is detected at different times in the same scene. To obtain more semantic features and better pixel-level prediction capabilities, this paper proposes a pixel-level ocean remote-sensing image algorithm (GLPO-Net) that combines local and global features. First, texture features, color features, and spatial relationship features are extracted. Second, the algorithm constructs a multiscale local cross-attention mechanism strategy to obtain feature weight information in different directions to fully mine the local features of ocean remote-sensing images. Concurrently, an algorithm constructs a multiscale global cross-attention mechanism strategy to obtain global features. Then, the fusion of global features and local features is described in each submodule to obtain more representative deep features. Finally, small-sample ocean remote-sensing is described via image pixel-level prediction. The algorithm proposed in this paper has been tested with three public ocean remote-sensing datasets. The experimental results show that the proposed GLPO-Net algorithm can learn features from small samples of ocean remote-sensing images. Compared to the prediction results of other remote-sensing image algorithms, GLPO-Net exhibits better prediction capabilities.

Published

2021

32. Corn Leaf Diseases Diagnosis Based on K-Means Clustering and Deep Learning

Author

Hamza Turabieh, Qian Zhang, Huiling Chen, Helong Yu, Ali Asghar Heidari, Jiawen Liu, Chengcheng Chen, and Majdi Mafarja

Subjects

General Computer Science, biology, business.industry, Deep learning, Corn leaf disease diagnosis, Feature extraction, General Engineering, k-means clustering, deep learning, K-means clustering, Diagnostic accuracy, biology.organism_classification, TK1-9971, transfer Learning, Statistics, Leaf spot, General Materials Science, Cluster sampling, Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, Medical diagnosis, Cluster analysis, business, Mathematics

Abstract

Accurate diagnosis of corn crop diseases is a complex challenge faced by farmers during the growth and production stages of corn. In order to address this problem, this paper proposes a method based on K-means clustering and an improved deep learning model for accurately diagnosing three common diseases of corn leaves: gray spot, leaf spot, and rust. First, to diagnose three diseases, use the K-means algorithm to cluster sample images and then feed them into the improved deep learning model. This paper investigates the impact of various k values (2, 4, 8, 16, 32, and 64) and models (VGG-16, ResNet18, Inception v3, VGG-19, and the improved deep learning model) on corn disease diagnosis. The experiment results indicate that the method has the most significant identification effect on 32-means samples, and the diagnostic recall of leaf spot, rust, and gray spot disease is 89.24 %, 100 %, and 90.95 %, respectively. Similarly, VGG-16 and ResNet18 also achieve the best diagnostic results on 32-means samples, and their average diagnostic accuracy is 84.42% and 83.75%. In addition, Inception v3 (83.05%) and VGG-19 (82.63%) perform best on the 64-means samples. For the three corn diseases, the approach cited in this paper has an average diagnostic accuracy of 93%. It has a more significant diagnostic effect than the other four approaches and can be applied to the agricultural field to protect crops.

Published

2021

33. Employing Blockchain Technology to Strengthen Security of Wireless Sensor Networks

Author

Sung-Jung Hsiao and Wen-Tsai Sung

Subjects

General Computer Science, Computer science, Big data, Hash function, Data security, 02 engineering and technology, 01 natural sciences, embedded system, Blockchain, sensor, 0202 electrical engineering, electronic engineering, information engineering, Mobile database, General Materials Science, Block (data storage), business.industry, Wireless network, Node (networking), 010401 analytical chemistry, General Engineering, mobile database, 020206 networking & telecommunications, mobile web server, TK1-9971, 0104 chemical sciences, big data analysis, Electrical engineering. Electronics. Nuclear engineering, business, Wireless sensor network, Computer network

Abstract

The proposed approach uses blockchain-based technology to strengthen the data security of wireless sensor networks (WSNs). This paper integrates blockchain-based technology with data transfer to establish an extremely secure WSNs structure. The present wireless network is built on the architecture of the Internet of Things (IoT) and employs a blockchain-based method to make the reliability of data transmission strong. In this proposed research, many small-area wireless sensor networks establish the entire WSNs structure, and every small-area wireless sensor network has a primary data collection node called a “mobile database.” The “mobile database” node of this study uses embedded microcontrollers with an operating system, such as Raspberry Pi and Arduino Yun. This block contains the sensor data collected by itself and the hash value of the previous block. Then the hash value of its own block, which is also part of the hash calculation of the next block, was calculated through the mining calculation program. Any block in the proposed method includes the encrypted hash-value of the previous block, the current timestamp, and the transaction data. In our research content, the transaction data is represented as wireless network sensing data. Basically, the system employs the hash function for calculation using the Merkel-tree algorithm. Such programming makes the block with blockchain-based technology difficult to tamper with content. This study approach revises the blockchain-based transaction ledger to become a sensor data record. Therefore, the proposed system gathers and analyzes sensor data for more reliability in the wireless sensing network structure. Furthermore, the innovative system with blockchain-based technology can treat a private cloud-end. This paper also carries on to visualize the uploaded sensing data by the sensors and draws corresponding charts based on big data analysis. The wireless network architecture proposed in this paper is built on embedded devices, making it easy for the system to build a web server. Using Python or JavaScript programming language in the web environment is relatively more convenient for data visualization and data analysis. Finally, this study uses traditional methods and innovative methods to compare data transmission. When the system uses innovative methods with blockchain-based technology, it is almost impossible for any operator to tamper with the data transmitted by the sensor.

Published

2021

34. On-Site Identification of Counterfeit Drugs Based on Near-Infrared Spectroscopy Siamese-Network Modeling

Author

Zheng An-Bing, Feng Yan-Chun, Yang Huihua, Yin Li-Hui, and Pan Xi-Peng

Subjects

General Computer Science, near-infrared spectroscopy, Computer science, 02 engineering and technology, Convolutional neural network, Siamese-network, Set (abstract data type), 0502 economics and business, General Materials Science, 1D CNN, 050210 logistics & transportation, business.industry, 05 social sciences, drug identification, General Engineering, Pattern recognition, 021001 nanoscience & nanotechnology, Support vector machine, Identification (information), Binary classification, Test set, lcsh:Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, 0210 nano-technology, business, lcsh:TK1-9971, Counterfeit Drugs

Abstract

Near-infrared spectroscopy (NIR) has become one of the most important methods for counterfeit drugs identification for its low cost, non-destructive, and on-site detection. However, it is often invalid for unknown samples beyond the scope of modeling samples, as well as it is not efficient in conditions of insufficient samples (insufficient number of samples within the class), unbalanced samples (large difference in the number of samples between classes), and sensitivity of identification results (different tolerance for different errors in application scenarios). To solve these problems, this paper proposes a general method for on-site identification of counterfeit drugs based on Siamese-network modeling with near-infrared spectroscopy, which especially constructs the train set and test set, learning the general knowledge of spectral differences to identify the different drugs by a costumed one-dimensional convolution neural network (1D-CNN), and finally answered the question of whether the on-site two spectra are pointed to the same drug. Based on experimental modeling samples of 1314 spectra, which are involved 9 drugs produced by 25 manufacturers, this paper has constructed and fully trained its model. Then, not known at the time of modeling, 4 drugs produced by 9 manufacturers are used for testing in the on-site application, and the accuracy rate amounts to 97.3%. For generalizing consideration, randomly divided into training and testing categories, the 32015 spectra of 135 drugs produced by 391 manufacturers in the spectral library are handled by the same processing. The generalization model is equally applicable, and the accuracy is above 97%. Compared with traditional binary classification identification methods such as SVM, PLS-DA, Auto-encoding, and one class (OC) threshold identification algorithms such as SVM-OC, SIMCA, conformity test (CT), the proposed method has the best identification ability for unknown samples in modeling.

Published

2021

35. Online Handwritten Mathematical Expression Recognition and Applications: A Survey

Author

Dmytro Zhelezniakov, Viktor Zaytsev, and Olga Radyvonenko

Subjects

General Computer Science, Distance education, 02 engineering and technology, Machine learning, computer.software_genre, human-computer interaction, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Electrical and Electronic Engineering, Architecture, Hidden Markov model, Sequence, business.industry, General Engineering, Deep learning, ubiquitous computing, 020207 software engineering, neural networks, ComputingMethodologies_PATTERNRECOGNITION, Handwriting recognition, Benchmark (computing), Task analysis, Deep neural networks, handwriting mathematical expressions recognition, 020201 artificial intelligence & image processing, lcsh:Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, LSTM, business, lcsh:TK1-9971, computer

Abstract

Handwritten mathematical expressions are an essential part of many domains, including education, engineering, and science. The pervasive availability of computationally powerful touch-screen devices, similar to the recent emergence of deep neural networks as high-quality sequence recognition models, result in the widespread adoption of online recognition of handwritten mathematical expressions. Also, a deeper study and improvement of such technologies is necessary to address the current challenges posed by the extensive usage of distance learning, and remote work due to the world pandemic. This paper delineates the state-of-the-art recognition methods along with the user's experience in pen-centric applications for operating with handwritten mathematical expressions. Recognition methods have been categorized into classes, with a description of their merits and limitations. Particular attention is paid to end-to-end approaches based on encoder-decoder architecture and multi-modal input. Evaluation protocols and open benchmark datasets are considered as well as the comparison of the recognition performance, based on open competition results. The use of handwritten math recognition is illustrated by examples of applications for various fields and platforms. A distinctive part of the survey is that we also considered how UI design relies on the use of different recognition approaches, which is aimed at helping potential researchers improve the performance of the introduced approaches toward the best responses in practical applications. Finally, this paper presents the prospective survey of future research directions in handwritten mathematical expression recognition and their applications.

Published

2021

36. Encoder-Decoder Structure With the Feature Pyramid for Depth Estimation From a Single Image

Author

Mengxia Tang, Songnan Chen, Ruifang Dong, and Jiangming Kan

Subjects

single image, General Computer Science, business.industry, Computer science, Feature extraction, encoder-decoder, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, General Engineering, Image (mathematics), Convolution, Depth prediction, Upsampling, feature pyramid, Feature (computer vision), Depth map, Pyramid, General Materials Science, Computer vision, lcsh:Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, Pyramid (image processing), business, lcsh:TK1-9971, Encoder

Abstract

We address the problem of depth estimation from a single monocular image in the paper. Depth estimation from a single image is an ill-posed and inherently ambiguous problem. In the paper, we propose an encoder-decoder structure with the feature pyramid to predict the depth map from a single RGB image. More specifically, the feature pyramid is used to detect objects of different scales in the image. The encoder structure aims to extract the most representative information from the original image through a series of convolution operations and to reduce the resolution of the input image. We adopt Res2-50 as the encoder to extract important features. The decoder section uses a novel upsampling structure to improve the output resolution. Then, we also propose a novel loss function that adds gradient loss and surface normal loss to the depth loss, which can predict not only the global depth but also the depth of fuzzy edges and small objects. Additionally, we use Adam as our optimization function to optimize our network and speed up convergence. Our extensive experimental evaluation proves the efficiency and effectiveness of the method, which is competitive with previous methods on the Make3D dataset and outperforms state-of-the-art methods on the NYU Depth v2 dataset.

Published

2021

37. Optimal Container Migration for Mobile Edge Computing: Algorithm, System Design and Implementation

Author

Taewoon Kim, Motassem Al-Tarazi, Jenn-Wei Lin, and Wooyeol Choi

Subjects

Downtime, live migration, Mobile edge computing, General Computer Science, business.industry, Computer science, Distributed computing, General Engineering, Response time, Cloud computing, docker, TK1-9971, edge computing, General Materials Science, Electrical engineering. Electronics. Nuclear engineering, Enhanced Data Rates for GSM Evolution, implementation, business, Selection algorithm, Container, optimal decision, Edge computing, Live migration

Abstract

Edge computing is a promising alternative to cloud computing for offloading computationally heavy tasks from resource-constrained mobile user devices. Placed at the edge of the network, edge computing is particularly advantageous to delay-limited applications for having a short distance to end-users. However, when a mobile user moves away from the service coverage of the associated edge server, the advantage gradually vanishes, increasing response time. Although service migration has been studied to address this problem focusing on minimizing the service downtime, both zero-downtime and the amount of traffic generated as a result of migration need further study. In this paper, an optimal live migration for containerized edge computing service is studied. This paper presents three zero-downtime migration techniques based on state duplication and state reproduction techniques, and then, proposes an optimal migration technique selection algorithm that jointly minimizes the response time and network traffic during migration. For validation and performance comparison, the proposed migration techniques are implemented on off-the-shelf hardware with Linux operating system. The evaluation results showed that compared with a naive migration, the optimal approach reduced the response time and network load by at least 74.75% and 94.79%, respectively, under considered scenarios.

Published

2021

38. Command Filter-Based Control for Spacecraft Attitude Tracking With Pre-Defined Maximum Settling Time Guaranteed

Author

Yufeng Gao, Chuanjiang Li, and Dongyu Li

Subjects

0209 industrial biotechnology, General Computer Science, Spacecraft, Computer science, Settling time, business.industry, Bandwidth (signal processing), General Engineering, 02 engineering and technology, backstepping method, TK1-9971, Attitude control, Constraint (information theory), 020901 industrial engineering & automation, Control theory, Filter (video), 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, General Materials Science, Electrical engineering. Electronics. Nuclear engineering, Spacecraft attitude tracking, business, Actuator, pre-defined maximum settling time control

Abstract

For the on-orbit service spacecraft attitude tracking task with external disturbances, considering the limited capacity of its actuators and high control performance required, an improved performance constraint control algorithm based on command filters is proposed in this paper. For the proposed control algorithm, before the theoretical control signal is transmitted to the actuator, it needs to be filtered by the command filter. This filter can constrain the rate, magnitude, and bandwidth of the signals, smooth the command signals and avoid peak interference. In terms of performance constraints, inspired by the performance constraint curve, this paper uses the determined points to re-design a new performance constraint function, which shows the maximum settling time parameters, allowing designers to pre-defined this limited time of the closed-loop system according to needs. Therefore, the maximum settling time of the actual closed-loop system will be less than the pre-defined maximum settling time. The controller based on the command filter is designed, and on this basis, the corresponding performance-constrained control algorithm with pre-defined maximum settling time guaranteed is proposed. Through the proof and simulation, the rationality and effectiveness of the proposed controller are further demonstrated.

Published

2021

39. Impact of EEG Parameters Detecting Dementia Diseases: A Systematic Review

Author

Luz-Maria Sanchez-Reyes, Jose-Billerman Robles-Ocampo, Maria-Luisa Garcia-Gomar, Juvenal Rodríguez-Reséndiz, and Gloria Avecilla-Ramírez

Subjects

biomedical applications, General Computer Science, detection reliability, Computer science, Feature extraction, Electroencephalography, Machine learning, computer.software_genre, World health, 03 medical and health sciences, 0302 clinical medicine, medicine, Dementia, neurodegenerative diseases, General Materials Science, Electrical and Electronic Engineering, Health sector, Reliability (statistics), 030304 developmental biology, 0303 health sciences, automatic/semi-automatic detection, medicine.diagnostic_test, business.industry, General Engineering, medicine.disease, Wide field, TK1-9971, EEG systems, Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, Sampling time, business, computer, 030217 neurology & neurosurgery

Abstract

Dementia diseases are increasing rapidly, according to the World Health Organization (WHO), becoming an alarming problem for the health sector. The electroencephalogram (EEG) is a non-invasive test that records brain electrical activity and has a wide field of applications in the medical area, one of which is the detection of neurodegenerative diseases. The aim of this work is to present the results of a thorough review of the use of EEG systems for the detection of dementia diseases. Around 82 papers published between 2009 and 2020 were reviewed and compared obtaining data such as sampling time, number of electrodes, the most popular processing, classification, and validation techniques, as well as an analysis of the reported results. The relationship of the selected parameters with the efficiency obtained is shown. Some more common combinations in the reviewed papers that demonstrated to have reliability levels greater than 90%, and details to be considered at each stage of the process. An overview of the most commonly used classification tools and processing techniques is also described.

Published

2021

40. A Review of Cybersecurity Guidelines for Manufacturing Factories in Industry 4.0

Author

Valentin Mullet, Eric Ramat, Patrick Sondi, Laboratoire d'Informatique Signal et Image de la Côte d'Opale (LISIC), and Université du Littoral Côte d'Opale (ULCO)

Subjects

Cybersecurity, Honeypot, General Computer Science, Standardization, Industry 4.0, Supply chain, Harmonization, 02 engineering and technology, cyber-physical systems, Computer security, computer.software_genre, 0202 electrical engineering, electronic engineering, information engineering, [INFO]Computer Science [cs], General Materials Science, ComputingMilieux_MISCELLANEOUS, business.industry, 020208 electrical & electronic engineering, General Engineering, intelligent manufacturing systems, 020206 networking & telecommunications, Automation, industrial control system, Industrial Internet of Things, Factory (object-oriented programming), manufacturing execution systems, The Internet, lcsh:Electrical engineering. Electronics. Nuclear engineering, business, lcsh:TK1-9971, computer

Abstract

Industry 4.0 is a revolution in manufacturing by introducing disruptive technologies such as Internet of Things (IoT) and cloud-computing into the heart of the factory. The resulting increased automation and the improved production synergy between stocks, supply chains and customer demands, come along with the threats and attacks from the Internet. Despite extensive literature on the cybersecurity topic, many actors in manufacturing factories are just realizing the impact of cybersecurity in the preservation of their business. This paper introduces step-by-step the concepts and practical aspects of an Industry 4.0 manufacturing factory that are related to cybersecurity. Based on a subdivision of a typical factory into several generic perimeters, we present the vulnerabilities and threats regarding the network and devices usually found in each perimeter. Therefore, it is more efficient to present the recent proposals of the literature regarding cybersecurity guidelines and solutions in Industry 4.0. Instead of spreading a lot of references regarding every aspect of cybersecurity, we focused on a limited number of papers among the recent references. However, for each paper, we provide the details about the purpose of the proposal, the methodology adopted, the technical solution developed and its evaluation by the authors. These solutions range from classical cybersecurity countermeasures to innovative ones, such as those based on honeypots and digital twins. In order to deliver a review also useful to non scientists, we present our guidelines along with those of some organizations involved in cybersecurity harmonization and standardization in the world.

Published

2021

41. Learning Without Forgetting: A New Framework for Network Cyber Security Threat Detection

Author

Rupesh Raj Karn, Prabhakar Kudva, and Ibrahim M. Elfadel

Subjects

Hessian matrix, Forgetting, General Computer Science, Artificial neural network, neural network, business.industry, Computer science, General Engineering, Cloud computing, Context (language use), synaptic intelligence, Computer security, computer.software_genre, Convolutional neural network, fisher information, TK1-9971, Domain (software engineering), Image (mathematics), Progressive learning, elastic weight consolidation, Task analysis, General Materials Science, Electrical engineering. Electronics. Nuclear engineering, business, computer

Abstract

Progressive learning addresses the problem of incrementally learning new tasks without compromising the prediction accuracy of previously learned tasks. In the context of artificial neural networks, several algorithms exist for achieving the progressive learning goal of learning without forgetting. However, these algorithms have traditionally been tested on the well-known and widely available datasets from the domain of image understanding and computer vision. Very little has been done on exploring the suitability of progressive learning algorithms in the important area of network threat detection. On a more fundamental level, progressive learning algorithms are still faced with the challenge of predicting the ultimate ability of a given neural network architecture to add more tasks to its repertoire without undergoing catastrophic forgetting. The goal of this paper is to address such a challenge in the context of cyber security threat detection. It does so by providing a unified conceptual and computational framework where progressive learning algorithms can be analyzed, compared, and contrasted in terms of their learning capacity and prediction accuracy for specific datasets from the cloud cyber security domain. In particular, this paper provides rigorous metrics for predicting the onset of catastrophic forgetting in the cyber security domain and contrasts them with their usage in the imaging domain. Our extensive numerical results show that progressive learning, along with the proposed criteria for catastrophic forgetting, provides a very structured framework for automating network threat detection as new threats emerge throughout network operation.

Published

2021

42. 5G Mobile Communication Applications: A Survey and Comparison of Use Cases

Author

Olaonipekun Oluwafemi Erunkulu, Caspar K. Lebekwe, Adamu Murtala Zungeru, Joseph Chuma, and Modisa Mosalaosi

Subjects

Radio access network, network slicing, General Computer Science, business.industry, Computer science, Use cases, General Engineering, Core network, key performance indicators, 5G core network, spectrum, TK1-9971, System requirements, Next-generation network, Wireless, General Materials Science, Electrical engineering. Electronics. Nuclear engineering, Mobile telephony, NG-RAN, business, Mobile device, 5G, Computer network

Abstract

The mobile demands and future business context are anticipated to be resolved by the fifth-generation (5G) of mobile communication systems. It is expected to provide an utterly mobile device, connected society, and support the demanding services of various use cases (UCs). This is intended to meet the demand requirement by providing services at tens of Gbps in terms of data rates, higher mobility range, lower latencies, and massive connectivity density devices per square kilometer. A comprehensive and up-to-date survey of the different developed and proposed use cases is presented in this paper. The first part of the paper presents the overview of the new 5G Architecture by introducing new features such as the new radio interface (New Radio), an overview of the 5G Core Network, minimum requirements, and the Radio Access Network, 5G spectrum requirements and other fundamentals of the network. Secondly, a detailed review of the developed and proposed use cases for 5G communications by the standards development organizations (SDO) and other key players in mobile communication is provided. Thirdly, we went ahead to propose spectrum bands for the deployment of the various use cases based on the low-, mid-, and high-band spectrum and further classified the use cases with respect to their relevance and family, identifying the IMT-2020 test environments and the usage scenarios derived by the 3GPP, fourthly, the channel capacity and the bandwidth of the spectrum was studied, simulated and compared to ascertain the spectrum proposed in this paper for each UC family. Hence, this paper serves as a guideline for understanding the future 5G deployment scenarios in various environments. This would allow system developers to design and implement 5G channel characterization models specific to the usage scenarios to meet the system requirements.

Published

2021

43. Multi-Regional Optimal Power Flow Using Marine Predators Algorithm Considering Load and Generation Variability

Author

R. A. Swief, Hany M. Hasanien, Almoataz Y. Abdelaziz, Nada Mamdouh Hassan, and M. Z. Kamh

Subjects

renewable energy resources, marine predator algorithm, General Computer Science, business.industry, Heuristic (computer science), Computer science, IEEE 48-Bus system, 020209 energy, Load modeling, 020208 electrical & electronic engineering, General Engineering, 02 engineering and technology, TK1-9971, Renewable energy, multi-regional systems, Power flow, Genetic algorithm, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, optimal power flow, Electrical engineering. Electronics. Nuclear engineering, business, Algorithm

Abstract

This paper introduces the application of a newly developed heuristic nature-inspired optimization technique, viz, tuned Marine Predator Algorithm (MPA), to solve the optimal power flow (OPF) problem of multi-regional systems. The paper proposes MPA parameters' tuning to enhance the algorithm performance. The paper takes into account the variability of different types of renewable energy resources (RERs) and loads. Two modeling approaches are presented: holistic (multi-regions are modeled as one large network) and inter-bounded (modeling the regional interfaces). The MPA is applied to the IEEE-48 bus connected system, and the results are compared with another well-established heuristic algorithm, namely the Genetic Algorithm (GA). The results demonstrate the validation, applicability and effectiveness of using the MPA for solving multi-region OPF problem considering renewable energy sources and load variability.

Published

2021

44. Impact of Industrial Agglomeration on Regional Economy in a Simulated Intelligent Environment Based on Machine Learning

Author

Lei Zhu, Hui Zhan, and Zhuo Yu

Subjects

Service (systems architecture), Index (economics), General Computer Science, Computer science, Internet of Things, regional economy, 02 engineering and technology, Machine learning, computer.software_genre, Manufacturing, 0202 electrical engineering, electronic engineering, information engineering, Intelligent environment, General Materials Science, Tertiary sector of the economy, industry agglomeration, business.industry, Economies of agglomeration, smart environment, 020208 electrical & electronic engineering, General Engineering, 020206 networking & telecommunications, machine learning, Economy, Smart environment, lcsh:Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, business, lcsh:TK1-9971, computer

Abstract

The Internet of Things is based on a communication network to automatically receive various information from the natural world. It uses intelligent objects with perception, communication and computers to automatically receive various information from nature. All independently managed physical objects are connected to each other to achieve integrated perception, reliable transmission and intelligent processing, and to establish intelligent information between people and objects, and objects and object service systems. This article mainly introduces the impact of industrial agglomeration on the regional economy in a simulated intelligent environment based on machine learning. This paper proposes a method to detect industrial agglomeration index to analyze industrial agglomeration. Through the establishment of the industrial agglomeration index system, the level of integration of the manufacturing industry in our city was objectively analyzed, and the impact of the integration of manufacturing industry on our city was tested empirically. Finally, the relationship between industrial integration and regional economic development was tested. The experimental results in this paper show that industrial integration in a smart environment based on simulation learning has a significant positive impact on regional economic development. Among them, the level of cooperation between the manufacturing service industry and the manufacturing industry increased by 1%, and the level of regional economic development increased by 0.025%.

Published

2021

45. A Roadmap for Migration System-Architecture Decision by Neutrosophic-ANP and Benchmark for Enterprise Resource Planning Systems

Author

Amany A. Slamaa, Haitham A. El-Ghareeb, and Ahmed Aboelfetouh Saleh

Subjects

General Computer Science, computer.internet_protocol, Computer science, system architecture, 02 engineering and technology, Microservices, law.invention, law, 0202 electrical engineering, electronic engineering, information engineering, Information system, General Materials Science, benchmarking, Enterprise resource planning, Flowchart, business.industry, General Engineering, microservices architecture (MSA), 020207 software engineering, Service-oriented architecture, Industrial engineering, Performance testing, TK1-9971, monolith, Systems architecture, Benchmark (computing), 020201 artificial intelligence & image processing, Electrical engineering. Electronics. Nuclear engineering, business, computer, service-oriented architecture (SOA), Dependency (project management)

Abstract

The selection of the system-architecture is critical step in software-engineering lifecycle. Unfortunately, the selecting a suitable architecture is a hard mission. The difficulty of the adopting architecture increases in inconsistence case as in SOA and MSA. The paper answers “when architecture transform”, “to which architecture migrate” and “how”. The paper addresses the lack of evaluation ERPs in post-implementation phase. The paper provides static and dynamic analysis for monolith, SOA and MSA by numerical-comparison and Benchmark. This paper proposes a roadmap for migration-architecture. The roadmap consists of flowchart of migration and migration-decision model that is supported with criteria of evaluation form for assessing system’s baseline and making a consistence decision by Neutrosophic-ANP. Because of the dependency between factors of information system evolution, ANP is used. Furthermore, Neutrosophic set is selected because its accuracy in inconsistence. Benchmark assesses OpenBravoERP, Odoo12 and Metasfresh5.144 to represent monolith, SOA and MSA respectively. Benchmark assesses performance, time to the market, stability, future proof, network issue and cost. They are tested based on scenario tests which grantee that transactions are executed within more than one module of ERPS, simulates real business’s procedures, huge number of records and concurrent load by virtual users. The proposed model and benchmark help “Hitac’ enterprise in two decisions for its expansion-plan in COVID-19 crisis. The numerical steps of this case-study are provided. Most published papers and literatures about Microservices are not empirical. The main paper’s result is filling this gap by a one of the empirical aspects with an academic study support.

Published

2021

46. Safe Adaptive Deep Reinforcement Learning for Autonomous Driving in Urban Environments. Additional Filter? How and Where?

Author

Sina Alighanbari and Nasser L. Azad

Subjects

General Computer Science, Computer science, 020209 energy, safety filters, Context (language use), 02 engineering and technology, Machine learning, computer.software_genre, 0202 electrical engineering, electronic engineering, information engineering, Reinforcement learning, General Materials Science, safe exploration, Deep reinforcement learning, business.industry, Heuristic, General Engineering, adaptive learning, Constraint satisfaction, TK1-9971, Model predictive control, 13. Climate action, Filter (video), Bounded function, 020201 artificial intelligence & image processing, Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, Adaptive learning, autonomous vehicles, business, computer

Abstract

Autonomous driving (AD) provides a reliable solution for safe driving by replacing human drivers responsible for the majority of accidents. The emergence of Machine Learning, specifically Deep Reinforcement Learning (DRL), and its ability to solve complex games proved its potential to address AD challenges. However, model-free methods still suffer from safety-related issues that can be resolved using safe-DRL approaches. The addition of model-based safety filters to the learning-based algorithms provides safety bounds on their performance and constraint satisfaction. In this paper, we investigate the addition of a safety filter based on Model Predictive Control and show an increase in mean testing episode reward by 110% from −75 mean episode reward during testing for 50 episodes for Deep Deterministic Policy Gradient ( $DDPG$ ) to 7.758. We study the impacts of safety filters (7.758 mean reward), heuristic rules, bounded additive noises (0.49% performance increase comparing to noise-free case), and exploration (3.425 mean reward) on the learning algorithm. We compare the effects of filters in the context of simulated exploration and bounded exploration and prove that bounded exploration results in 9.86% increase in mean reward and 12.95% decrease in std comparing to the other method. Additionally, inspired by Deep Internal Learning and biological mechanisms like brain plasticity, we investigate the idea of using each sample for training only once instead of utilizing stochastic batches which increases the mean testing accumulated reward by 1.87% and leads to the best performance (7.942 mean reward and 0.048 std). Finally, the results demonstrate better automotive results for our proposed method than DDPG. Our proposed method, DDPG with safety filter in bounded exploration and adaptive learning under noisy input conditions, has a success rate of 100% under different traffic densities for the simulation environment used in this paper and our assumptions. The proposed method’s automotive results are shown for a braking scenario to avoid collision with other road users.

Published

2021

47. Study of Wind Turbine Fault Diagnosis and Early Warning Based on SCADA Data

Author

Yilong Shi, Yirong Liu, and Xiang Gao

Subjects

DBSCAN, Wind power, General Computer Science, fault warning, business.industry, Computer science, Real-time computing, General Engineering, Condition monitoring, ComputerApplications_COMPUTERSINOTHERSYSTEMS, fault diagnosis, Fault (power engineering), Turbine, TK1-9971, Data modeling, SCADA, General Materials Science, Electrical engineering. Electronics. Nuclear engineering, business, Cluster analysis, Wind turbine, XGBoost

Abstract

Wind turbine fault diagnosis and early warning are important to reduce wind farm operation and maintenance costs and improve power generation efficiency. In this paper, we take the Supervisory Control and Data Acquisition (SCADA) data as the research object and research wind turbine health data purification, fault diagnosis model building, and unit operation status monitoring from a completely data-driven perspective. Firstly, for the problem that Density-Based Spatial Clustering of Applications with Noise (DBSCAN) algorithm cannot identify high-density anomalous data. An anomaly data processing scheme combining a density clustering algorithm and normal power interval estimation is proposed. The accuracy of extracting health data from wind turbines is improved. Secondly, to address the problem that the eXtreme Gradient Boosting (XGBoost) algorithm has more hyperparameters, we propose an optimization scheme based on the Bayesian Optimization Algorithm (BOA) and tree model for feature weight measurement, which improves the efficiency and accuracy of intuitive mapping from SCADA system monitoring data to fault features. Finally, a wind turbine condition monitoring scheme based on the information fusion of multi-characteristic monitoring parameters is designed. The wind turbine condition monitoring scheme proposed in this paper can warn generator system failure 3.67 hours, gearbox system failure 5.17 hours in advance, and hydraulic system failure 2.33 hours in advance.

Published

2021

48. Data-Driven Intelligence System for General Recommendations of Deep Learning Architectures

Author

Gjorgji Noveski, Tome Eftimov, Kostadin Mishev, and Monika Simjanoska

Subjects

Flexibility (engineering), General Computer Science, hyperparameters selection, business.industry, Computer science, Process (engineering), Deep learning, DL architecture selection, General Engineering, Intelligent decision support system, Machine learning, computer.software_genre, TK1-9971, Data-driven, Data modeling, Scalability, General Materials Science, Electrical engineering. Electronics. Nuclear engineering, Artificial intelligence, Architecture, intelligent system, business, computer, multi-label classification

Abstract

Choosing optimal Deep Learning (DL) architecture and hyperparameters for a particular problem is still not a trivial task among researchers. The most common approach relies on popular architectures proven to work on specific problem domains led on the same experiment environment and setup. However, this limits the opportunity to choose or invent novel DL networks that could lead to better results. This paper proposes a novel approach for providing general recommendations of an appropriate DL architecture and its hyperparameters based on different configurations presented in thousands of published research papers that examine various problem domains. This architecture can further serve as a starting point of investigating DL architecture for a concrete data set. Natural language processing (NLP) methods are used to create structured data from unstructured scientific papers upon which intelligent models are learned to propose optimal DL architecture, layer type, and activation functions. The advantage of the proposed methodology is multifold. The first is the ability to eventually use the knowledge and experience from thousands of DL papers published through the years. The second is the contribution to the forthcoming novel researches by aiding the process of choosing optimal DL setup based on the particular problem to be analyzed. The third advantage is the scalability and flexibility of the model, meaning that it can be easily retrained as new papers are published in the future, and therefore to be constantly improved.

Published

2021

49. Introspection Into Reliability Aspects in AlGaN/GaN HEMTs With Gate Geometry Modification

Author

Gaurav Trivedi, Ashok Ray, and Sushanta Bordoloi

Subjects

leakage current, gate shape, Materials science, electron temperature, General Computer Science, business.industry, Transconductance, GaN HEMT, General Engineering, Wide-bandgap semiconductor, High-electron-mobility transistor, Capacitance, TK1-9971, Threshold voltage, Reliability (semiconductor), Electric field, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, Capacitance voltage (CV), Optoelectronics, Breakdown voltage, General Materials Science, Electrical engineering. Electronics. Nuclear engineering, business

Abstract

Reliability enhancement of AlGaN / GaN HEMT is a significant thrust area due to rapidly improving material and processing technology. In this paper, a detailed analysis of gate–shaped AlGaN / GaN HEMT with field plate is presented. Although AlGaN / GaN HEMT with field–plate is well known, its blending with gate–shaping leading to a more robust and reliable behaviour is described in this paper. It is observed that the threshold voltage and transconductance invariably remain constant for various combinations of gate–shaped and field plate placements. The threshold voltage for all the devices are found to be – 5.8 V. The peak transconductance for the devices without field plate and with field plate is $\sim ~0.16$ S/mm and $\sim ~0.15$ S/mm, respectively. Apart from leakage current, the electric field also gets mitigated for both gate–shaped and field–plated devices by $\sim ~45$ % and $\sim ~68$ %, respectively. The moderation in electric field further assists in the reduction of electron temperature for gate–shaped and field–plated structures by $\sim ~12$ % and $\sim ~85$ %, respectively. Additionally, breakdown voltage increases for the gate–shaped devices to 133 V as compared to 120 V of conventional devices without field plate. Significant reduction in leakage current, electric field, and electron temperature is accompanied by a minor increment in capacitance for the field–plated structure, hence, the proposed structure is expected to enhance reliability of the device. Thus, it is anticipated that the proposed devices with enhanced reliability would be a step ahead of conventional devices and would find major applications in high power domain.

Published

2021

50. Electricity Consumption Forecasting Using Gated-FCN With Ensemble Strategy

Author

Abrar Ahmed, Sardar Muhammad Gulfam, Aqdas Naz, Muhammad Asif, Muhammad Shafiq, Jin-Ghoo Choi, Nadeem Javaid, and Muhammad Umar Javed

Subjects

electricity consumption forecasting, General Computer Science, Mean squared error, Computer science, enhanced BiGRU, weighted averaging technique, Feature selection, computer.software_genre, General Materials Science, Time series, smart grid, business.industry, Deep learning, General Engineering, Deep learning forecasting technique, gated FCN, TK1-9971, Noise, Mean absolute percentage error, Benchmark (computing), Domain knowledge, Electrical engineering. Electronics. Nuclear engineering, Data mining, Artificial intelligence, business, computer

Abstract

Accurate electricity consumption forecasting in the power grids ensures efficient generation and distribution of electricity. Keeping this in mind, the paper introduces a novel deep learning model, termed Gated-FCN, for short-term load forecasting. The key idea is to introduce an automated feature selection and deep learning model for forecasting. The model includes an eight-layered Fully Convolutional Network (FCN-8) in which the hand-crafted feature selection that requires expert domain knowledge is avoided. Furthermore, the model also reduces noise as it learns internal dependencies and the correlation of the time series. Enhanced Bidirectional Gated Recurrent Unit (EBiGRU) is used in combination with FCN-8 to learn long-term temporal dependencies of the time series. Moreover, a weighted averaging mechanism of multiple snapshot models is adopted in the proposed model to assign optimized weights to BiGRU. At the end of FCN-8 and BiGRU, a fully connected dense layer is used that gives final prediction results. Gated-FCN is an end-to-end forecasting model that does not require any other model for enhancing its forecasting efficiency. Different activation functions are initially analyzed to determine how the proposed model learns complex patterns from the time series data. Later, the activation function having the best accuracy is used for forecasting. The proposed model extracts both spatial and temporal features from the data. Furthermore, this paper also provides predictive and exploratory data analyses to assist policymakers in making optimal decisions regarding power production and dispatch. In order to demonstrate the applicability of the proposed technique, the simulations are performed using nine years’ load consumption data taken from Independent System Operators New England (ISO-NE). The comparison with five state-of-the-art techniques is also provided to prove the fact that Gated-FCN gives the best forecasting accuracy as compared to other benchmark techniques in terms of two performance metrics: Mean Absolute Percentage Error (MAPE) and Root Mean Square Error (RMSE).

Published

2021