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1. Modified Early Warning Score (MEWS) Visualization and Pattern Matching Imputation in Remote Patient Monitoring

Author

Teena Arora, Venki Balasubramanian, Andrew Stranieri, and Varun G. Menon

Subjects
Pattern imputation, data integrity, visualized remote patient monitoring (VRPM), clinical decision support, wearable technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Remote Patient Monitoring (RPM), which leverages the Internet of Medical Things (IoMT) and autonomous systems, has grown in popularity recently. In RPM, the IoMT sense a patient’s biophysical data and transmits it in real time while the autonomous system processes the data for clinical notifications and storage. However, RPM deployments face two diverse challenges: how to present continuous data so that healthcare professionals can quickly interpret data streams and how to manage a great deal of missing data that occurs in RPM. Several studies suggested techniques for imputing missing data in static databases, which are unsuitable for RPM. A method for constantly streaming healthcare data to medical experts involves summarizing vital signs information into a numerical score, such as the Modified Early Warning Score (MEWS), which may be visually displayed to highlight MEWS patterns over a certain period. However, a MEWS chart is simplistic and more sophisticated ways to present data visually for straightforward interpretation are needed. This research proposes a solution for the visualization and missing data challenges by identifying patterns in the RPM data. First, a pattern-matching technique is proposed to address the missing data by considering the correlation and variability of the vital signs, resulting in a comparable correct match rate. Second, we transform the observed raw physiological vital signs data into concepts we call trust, frequency, trend, and slope parameters for visualization and automated alerts. The proposed approach can better support clinical decision-making than the MEWS. Comprehensive visualization approaches and missing data solutions can improve the quality and dependability of patient risk assessments.

Published
2024
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2. DQN-based resource allocation for NOMA-MEC-aided multi-source data stream

Author

Jing Ling, Junjuan Xia, Fusheng Zhu, Chongzhi Gao, Shiwei Lai, and Venki Balasubramanian

Subjects
MEC, NOMA, Multi-source data stream, DQN, Telecommunication, TK5101-6720, Electronics, TK7800-8360
Abstract

Abstract This paper investigates a non-orthogonal multiple access (NOMA)-aided mobile edge computing (MEC) network with multiple sources and one computing access point (CAP), in which NOMA technology is applied to transmit multi-source data streams to CAP for computing. To measure the performance of the considered NOMA-aided MEC network, we first design the system cost as a linear weighting function of energy consumption and delay under the NOMA-aided MEC network. Moreover, we propose a deep Q network (DQN)-based offloading strategy to minimize the system cost by jointly optimizing the offloading ratio and transmission power allocation. Finally, we design experiments to demonstrate the effectiveness of the proposed strategy. Specifically, the designed strategy can decrease the system cost by about 15% compared with local computing when the number of sources is 5.

Published
2023
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3. A Temporal Deep Q Learning for Optimal Load Balancing in Software-Defined Networks

Author

Aakanksha Sharma, Venki Balasubramanian, and Joarder Kamruzzaman

Subjects
SDN, flow fluctuation, deep temporal reinforcement learning, latency minimization, packet delivery ratio, Chemical technology, TP1-1185
Abstract

With the rapid advancement of the Internet of Things (IoT), there is a global surge in network traffic. Software-Defined Networks (SDNs) provide a holistic network perspective, facilitating software-based traffic analysis, and are more suitable to handle dynamic loads than a traditional network. The standard SDN architecture control plane has been designed for a single controller or multiple distributed controllers; however, a logically centralized single controller faces severe bottleneck issues. Most proposed solutions in the literature are based on the static deployment of multiple controllers without the consideration of flow fluctuations and traffic bursts, which ultimately leads to a lack of load balancing among controllers in real time, resulting in increased network latency. Moreover, some methods addressing dynamic controller mapping in multi-controller SDNs consider load fluctuation and latency but face controller placement problems. Earlier, we proposed priority scheduling and congestion control algorithm (eSDN) and dynamic mapping of controllers for dynamic SDN (dSDN) to address this issue. However, the future growth of IoT is unpredictable and potentially exponential; to accommodate this futuristic trend, we need an intelligent solution to handle the complexity of growing heterogeneous devices and minimize network latency. Therefore, this paper continues our previous research and proposes temporal deep Q learning in the dSDN controller. A Temporal Deep Q learning Network (tDQN) serves as a self-learning reinforcement-based model. The agent in the tDQN learns to improve decision-making for switch-controller mapping through a reward–punish scheme, maximizing the goal of reducing network latency during the iterative learning process. Our approach—tDQN—effectively addresses dynamic flow mapping and latency optimization without increasing the number of optimally placed controllers. A multi-objective optimization problem for flow fluctuation is formulated to divert the traffic to the best-suited controller dynamically. Extensive simulation results with varied network scenarios and traffic show that the tDQN outperforms traditional networks, eSDNs, and dSDNs in terms of throughput, delay, jitter, packet delivery ratio, and packet loss.

Published
2024
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4. A Novel Dynamic Software-Defined Networking Approach to Neutralize Traffic Burst

Author

Aakanksha Sharma, Venki Balasubramanian, and Joarder Kamruzzaman

Subjects
static and dynamic controller mapping, flow fluctuation, latency minimization, load balancing, Electronic computers. Computer science, QA75.5-76.95
Abstract

Software-defined networks (SDN) has a holistic view of the network. It is highly suitable for handling dynamic loads in the traditional network with a minimal update in the network infrastructure. However, the standard SDN architecture control plane has been designed for single or multiple distributed SDN controllers facing severe bottleneck issues. Our initial research created a reference model for the traditional network, using the standard SDN (referred to as SDN hereafter) in a network simulator called NetSim. Based on the network traffic, the reference models consisted of light, modest and heavy networks depending on the number of connected IoT devices. Furthermore, a priority scheduling and congestion control algorithm is proposed in the standard SDN, named extended SDN (eSDN), which minimises congestion and performs better than the standard SDN. However, the enhancement was suitable only for the small-scale network because, in a large-scale network, the eSDN does not support dynamic SDN controller mapping. Often, the same SDN controller gets overloaded, leading to a single point of failure. Our literature review shows that most proposed solutions are based on static SDN controller deployment without considering flow fluctuations and traffic bursts that lead to a lack of load balancing among the SDN controllers in real-time, eventually increasing the network latency. Therefore, to maintain the Quality of Service (QoS) in the network, it becomes imperative for the static SDN controller to neutralise the on-the-fly traffic burst. Thus, our novel dynamic controller mapping algorithm with multiple-controller placement in the SDN is critical to solving the identified issues. In dSDN, the SDN controllers are mapped dynamically with the load fluctuation. If any SDN controller reaches its maximum threshold, the rest of the traffic will be diverted to another controller, significantly reducing delay and enhancing the overall performance. Our technique considers the latency and load fluctuation in the network and manages the situations where static mapping is ineffective in dealing with the dynamic flow variation.

Published
2023
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5. AI and IoT-Enabled Smart Exoskeleton System for Rehabilitation of Paralyzed People in Connected Communities

Author

Sunil Jacob, Mukil Alagirisamy, Chen Xi, Venki Balasubramanian, Ram Srinivasan, Parvathi R., N. Z. Jhanjhi, and Sardar M. N. Islam

Subjects
Assistive technology, artificial intelligence, deep learning, exoskeleton, Internet of Things, smart connected community, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

In recent years, the number of cases of spinal cord injuries, stroke and other nervous impairments have led to an increase in the number of paralyzed patients worldwide. Rehabilitation that can aid and enhance the lives of such patients is the need of the hour. Exoskeletons have been found as one of the popular means of rehabilitation. The existing exoskeletons use techniques that impose limitations on adaptability, instant response and continuous control. Also most of them are expensive, bulky, and requires high level of training. To overcome all the above limitations, this paper introduces an Artificial Intelligence (AI) powered Smart and light weight Exoskeleton System (AI-IoT-SES) which receives data from various sensors, classifies them intelligently and generates the desired commands via Internet of Things (IoT) for rendering rehabilitation and support with the help of caretakers for paralyzed patients in smart and connected communities. In the proposed system, the signals collected from the exoskeleton sensors are processed using AI-assisted navigation module, and helps the caretakers in guiding, communicating and controlling the movements of the exoskeleton integrated to the patients. The navigation module uses AI and IoT enabled Simultaneous Localization and Mapping (SLAM). The casualties of a paralyzed person are reduced by commissioning the IoT platform to exchange data from the intelligent sensors with the remote location of the caretaker to monitor the real time movement and navigation of the exoskeleton. The automated exoskeleton detects and take decisions on navigation thereby improving the life conditions of such patients. The experimental results simulated using MATLAB shows that the proposed system is the ideal method for rendering rehabilitation and support for paralyzed patients in smart communities.

Published
2021
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6. An Adaptive and Flexible Brain Energized Full Body Exoskeleton With IoT Edge for Assisting the Paralyzed Patients

Author

Sunil Jacob, Mukil Alagirisamy, Varun G. Menon, B. Manoj Kumar, N. Z. Jhanjhi, Vasaki Ponnusamy, P. G. Shynu, and Venki Balasubramanian

Subjects
Artificial intelligence, assistive technologies, brain-computer interface, edge computing, Internet of Things (IoT), rehabilitation, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The paralyzed population is increasing worldwide due to stroke, spinal code injury, post-polio, and other related diseases. Different assistive technologies are used to improve the physical and mental health of the affected patients. Exoskeletons have emerged as one of the most promising technology to provide movement and rehabilitation for the paralyzed. But exoskeletons are limited by the constraints of weight, flexibility, and adaptability. To resolve these issues, we propose an adaptive and flexible Brain Energized Full Body Exoskeleton (BFBE) for assisting the paralyzed people. This paper describes the design, control, and testing of BFBE with 15 degrees of freedom (DoF) for assisting the users in their daily activities. The flexibility is incorporated into the system by a modular design approach. The brain signals captured by the Electroencephalogram (EEG) sensors are used for controlling the movements of BFBE. The processing happens at the edge, reducing delay in decision making and the system is further integrated with an IoT module that helps to send an alert message to multiple caregivers in case of an emergency. The potential energy harvesting is used in the system to solve the power issues related to the exoskeleton. The stability in the gait cycle is ensured by using adaptive sensory feedback. The system validation is done by using six natural movements on ten different paralyzed persons. The system recognizes human intensions with an accuracy of 85%. The result shows that BFBE can be an efficient method for providing assistance and rehabilitation for paralyzed patients.

Published
2020
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7. A Low-Complexity Equalizer for Video Broadcasting in Cyber-Physical Social Systems Through Handheld Mobile Devices

Author

Ahmad A. A. Solyman, Hani Attar, Mohammad R. Khosravi, Varun G. Menon, Alireza Jolfaei, Venki Balasubramanian, Buvana Selvaraj, and Pooya Tavallali

Subjects
Least-squares minimal residual (LSMR), digital video broadcasting-handheld (DVB-H), orthogonal frequency division multiplexing (OFDM), zero-forcing (ZF) and cyber-physical social systems, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

In Digital Video Broadcasting-Handheld (DVB-H) devices for cyber-physical social systems, the Discrete Fractional Fourier Transform-Orthogonal Chirp Division Multiplexing (DFrFT-OCDM) has been suggested to enhance the performance over Orthogonal Frequency Division Multiplexing (OFDM) systems under time and frequency-selective fading channels. In this case, the need for equalizers like the Minimum Mean Square Error (MMSE) and Zero-Forcing (ZF) arises, though it is excessively complex due to the need for a matrix inversion, especially for DVB-H extensive symbol lengths. In this work, a low complexity equalizer, Least-Squares Minimal Residual (LSMR) algorithm, is used to solve the matrix inversion iteratively. The paper proposes the LSMR algorithm for linear and nonlinear equalizers with the simulation results, which indicate that the proposed equalizer has significant performance and reduced complexity over the classical MMSE equalizer and other low complexity equalizers, in time and frequency-selective fading channels.

Published
2020
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8. Privacy Protection and Energy Optimization for 5G-Aided Industrial Internet of Things

Author

Mamoona Humayun, Nz Jhanjhi, Madallah Alruwaili, Sagaya Sabestinal Amalathas, Venki Balasubramanian, and Buvana Selvaraj

Subjects
5G, energy optimization, industrial Internet of Things, privacy, security, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The 5G is expected to revolutionize every sector of life by providing interconnectivity of everything everywhere at high speed. However, massively interconnected devices and fast data transmission will bring the challenge of privacy as well as energy deficiency. In today's fast-paced economy, almost every sector of the economy is dependent on energy resources. On the other hand, the energy sector is mainly dependent on fossil fuels and is constituting about 80% of energy globally. This massive extraction and combustion of fossil fuels lead to a lot of adverse impacts on health, environment, and economy. The newly emerging 5G technology has changed the existing phenomenon of life by connecting everything everywhere using IoT devices. 5G enabled IIoT devices has transformed everything from traditional to smart, e.g. smart city, smart healthcare, smart industry, smart manufacturing etc. However, massive I/O technologies for providing D2D connection has also created the issue of privacy that need to be addressed. Privacy is the fundamental right of every individual. 5G industries and organizations need to preserve it for their stability and competency. Therefore, privacy at all three levels (data, identity and location) need to be maintained. Further, energy optimization is a big challenge that needs to be addressed for leveraging the potential benefits of 5G and 5G aided IIoT. Billions of IIoT devices that are expected to communicate using the 5G network will consume a considerable amount of energy while energy resources are limited. Therefore, energy optimization is a future challenge faced by 5G industries that need to be addressed. To fill these gaps, we have provided a comprehensive framework that will help energy researchers and practitioners in better understanding of 5G aided industry 4.0 infrastructure and energy resource optimization by improving privacy. The proposed framework is evaluated using case studies and mathematical modelling.

Published
2020
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9. A survey on the adoption of blockchain in IoT: challenges and solutions

Author

Md Ashraf Uddin, Andrew Stranieri, Iqbal Gondal, and Venki Balasubramanian

Subjects
Blockchain technology, Consensus mechanism, Blockchain cryptographic primitives, healthcare, Patient monitoring, Cloud of Things, Information technology, T58.5-58.64
Abstract

Conventional Internet of Things (IoT) ecosystems involve data streaming from sensors, through Fog devices to a centralized Cloud server. Issues that arise include privacy concerns due to third party management of Cloud servers, single points of failure, a bottleneck in data flows and difficulties in regularly updating firmware for millions of smart devices from a point of security and maintenance perspective. Blockchain technologies avoid trusted third parties and safeguard against a single point of failure and other issues. This has inspired researchers to investigate blockchain’s adoption into IoT ecosystem. In this paper, recent state-of-the-arts advances in blockchain for IoT, blockchain for Cloud IoT and blockchain for Fog IoT in the context of eHealth, smart cities, intelligent transport and other applications are analyzed. Obstacles, research gaps and potential solutions are also presented.

Published
2021
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10. Continuous Patient Monitoring With a Patient Centric Agent: A Block Architecture

Author

Md. Ashraf Uddin, Andrew Stranieri, Iqbal Gondal, and Venki Balasubramanian

Subjects
Blockchain, body area sensor network, healthcare, remote patient monitoring, patient centric agent, proof of work, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The Internet of Things (IoT) has facilitated services without human intervention for a wide range of applications, including continuous remote patient monitoring (RPM). However, the complexity of RPM architectures, the size of data sets generated and limited power capacity of devices make RPM challenging. In this paper, we propose a tier-based End to End architecture for continuous patient monitoring that has a patient centric agent (PCA) as its center piece. The PCA manages a blockchain component to preserve privacy when data streaming from body area sensors needs to be stored securely. The PCA based architecture includes a lightweight communication protocol to enforce security of data through different segments of a continuous, real time patient monitoring architecture. The architecture includes the insertion of data into a personal blockchain to facilitate data sharing amongst healthcare professionals and integration into electronic health records while ensuring privacy is maintained. The blockchain is customized for RPM with modifications that include having the PCA select a Miner to reduce computational effort, enabling the PCA to manage multiple blockchains for the same patient, and the modification of each block with a prefix tree to minimize energy consumption and incorporate secure transaction payments. Simulation results demonstrate that security and privacy can be enhanced in RPM with the PCA based End to End architecture.

Published
2018
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22. Service Deployment Strategy for Predictive Analysis of FinTech IoT Applications in Edge Networks

Author

Mohammad Ayoub Khan, Mainak Adhikari, Venki Balasubramanian, Ambigavathi Munusamy, Varun G. Menon, Satish Narayana Srirama, and Danda B. Rawat

Subjects
Service (systems architecture), Computer Networks and Communications, business.industry, Computer science, Distributed computing, Computer Science Applications, FinTech, Support vector machine, Task (computing), Hardware and Architecture, Software deployment, Signal Processing, Customer satisfaction, Enhanced Data Rates for GSM Evolution, business, Baseline (configuration management), Information Systems
Abstract

The seamless integration of sensors and smart communication technologies has led to the development of various supporting systems for Financial Technology (FinTech). The emergence of the Next-Generation Internet of Things (Nx-IoT) for FinTech applications enhances the customer satisfaction ratio. The main research challenge for FinTech applications is to analyse the incoming tasks at the edge of the networks with minimum delay and power consumption while increasing the prediction accuracy. Motivated by the above-mentioned challenge, in this paper, we develop a ranked-based service deployment strategy and an Artificial Intelligence technique for financial data analysis at edge networks. Initially, a risk-based task classification strategy has been developed for classifying the incoming financial tasks and providing the importance to the risk-based task for meeting users’ satisfaction ratio. Besides that, an efficient service deployment strategy is developed using Hall’s theorem to assign the ranked-based financial data to the suitable edge or cloud servers with minimum delay and power consumption. Finally, the standard support vector machines (SVM) algorithm is used at edge networks for analysing the financial data with higher accuracy. The experimental results demonstrate the effectiveness of the proposed strategy and SVM model at edge networks over the baseline algorithms and classification models, respectively.

Published
2023

25. A Novel Dynamic Software-Defined Networking Approach to Neutralize Traffic Burst

Author

Kamruzzaman, Aakanksha Sharma, Venki Balasubramanian, and Joarder

Subjects
static and dynamic controller mapping, flow fluctuation, latency minimization, load balancing
Abstract

Software-defined networks (SDN) has a holistic view of the network. It is highly suitable for handling dynamic loads in the traditional network with a minimal update in the network infrastructure. However, the standard SDN architecture control plane has been designed for single or multiple distributed SDN controllers facing severe bottleneck issues. Our initial research created a reference model for the traditional network, using the standard SDN (referred to as SDN hereafter) in a network simulator called NetSim. Based on the network traffic, the reference models consisted of light, modest and heavy networks depending on the number of connected IoT devices. Furthermore, a priority scheduling and congestion control algorithm is proposed in the standard SDN, named extended SDN (eSDN), which minimises congestion and performs better than the standard SDN. However, the enhancement was suitable only for the small-scale network because, in a large-scale network, the eSDN does not support dynamic SDN controller mapping. Often, the same SDN controller gets overloaded, leading to a single point of failure. Our literature review shows that most proposed solutions are based on static SDN controller deployment without considering flow fluctuations and traffic bursts that lead to a lack of load balancing among the SDN controllers in real-time, eventually increasing the network latency. Therefore, to maintain the Quality of Service (QoS) in the network, it becomes imperative for the static SDN controller to neutralise the on-the-fly traffic burst. Thus, our novel dynamic controller mapping algorithm with multiple-controller placement in the SDN is critical to solving the identified issues. In dSDN, the SDN controllers are mapped dynamically with the load fluctuation. If any SDN controller reaches its maximum threshold, the rest of the traffic will be diverted to another controller, significantly reducing delay and enhancing the overall performance. Our technique considers the latency and load fluctuation in the network and manages the situations where static mapping is ineffective in dealing with the dynamic flow variation.

Published
2023
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33. An AI-enabled lightweight data fusion and load optimization approach for Internet of Things

Author

Spyridon Mastorakis, Mian Ahmad Jan, Muhammad Khan, Muhammad Zakarya, Venki Balasubramanian, Varun G. Menon, and Ateeq Ur Rehman

Subjects
Computer Networks and Communications, Computer science, business.industry, Node (networking), Quality of service, Control reconfiguration, 020206 networking & telecommunications, 02 engineering and technology, Sensor fusion, Article, Hardware and Architecture, Packet loss, Server, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Upstream (networking), Enhanced Data Rates for GSM Evolution, business, Software, Computer network
Abstract

In the densely populated Internet of Things (IoT) applications, sensing range of the nodes might overlap frequently. In these applications, the nodes gather highly correlated and redundant data in their vicinity. Processing these data depletes the energy of nodes and their upstream transmission towards remote datacentres, in the fog infrastructure, may result in an unbalanced load at the network gateways and edge servers. Due to heterogeneity of edge servers, few of them might be overwhelmed while others may remain less-utilized. As a result, time-critical and delay-sensitive applications may experience excessive delays, packet loss, and degradation in their Quality of Service (QoS). To ensure QoS of IoT applications, in this paper, we eliminate correlation in the gathered data via a lightweight data fusion approach. The buffer of each node is partitioned into strata that broadcast only non-correlated data to edge servers via the network gateways. Furthermore, we propose a dynamic service migration technique to reconfigure the load across various edge servers. We assume this as an optimization problem and use two meta-heuristic algorithms, along with a migration approach, to maintain an optimal Gateway-Edge configuration in the network. These algorithms monitor the load at each server, and once it surpasses a threshold value (which is dynamically computed with a simple machine learning method), an exhaustive search is performed for an optimal and balanced periodic reconfiguration. The experimental results of our approach justify its efficiency for large-scale and densely populated IoT applications.

Published
2021

36. Smart Sensing-Enabled Decision Support System for Water Scheduling in Orange Orchard

Author

Muhammad Zakarya, Varun G. Menon, Mian Ahmad Jan, Rahim Khan, and Venki Balasubramanian

Subjects
Irrigation, Decision support system, Computer science, business.industry, media_common.quotation_subject, Reliability engineering, Scheduling (computing), Scarcity, Water resources, Wireless, Electrical and Electronic Engineering, Irrigation management, business, Instrumentation, Wireless sensor network, media_common
Abstract

The scarcity of water resources throughout the world demands its optimum utilization in various sectors. Smart Sensing-enabled irrigation management systems are the ideal solutions to ensure the optimum utilization of water resources in the agriculture sector. This paper presents a wireless sensor network-enabled Decision Support System (DSS) for developing a need-based irrigation schedule for the orange orchard. For efficient monitoring of various in-field parameters, our proposed approach uses the latest smart sensing technology such as soil moisture, leaf-wetness, temperature and humidity. The proposed smart sensing-enabled test-bed was deployed in the orange orchard of our institute for approximately one year and successfully adjusted its irrigation schedule according to the needs and demands of the plants. Moreover, a modified Longest Common SubSequence (LCSS) mechanism is integrated with the proposed DSS for distinguishing multi-valued noise from the abrupt changing scenarios. To resolve the concurrent communication problem of two or more wasp-mote sensor boards with a common receiver, an enhanced RTS/CTS handshake mechanism is presented. Our proposed DSS compares the most recently refined data with pre-defined threshold values for efficient water management in the orchard. Irrigation activity is scheduled if water deficit criterion is met and the farmer is informed accordingly. Both the experimental and simulation results show that the proposed scheme performs better in comparison to the existing schemes.

Published
2021

37. Multi-Variate Data Fusion Technique for Reducing Sensor Errors in Intelligent Transportation Systems

Author

Priyan Malarvizhi Kumar, Gunasekaran Manogaran, Vijayalakshmi Saravanan, Venki Balasubramanian, Bharat S. Rawal, Varatharajan Ramachandran, and Carlos Enrique Montenegro-Marin

Subjects
Computer science, Real-time computing, Process (computing), Kalman filter, computer.software_genre, Sensor fusion, Network simulation, Intelligent sensor, Asynchronous communication, Electrical and Electronic Engineering, Instrumentation, Intelligent transportation system, computer, Data integration
Abstract

Connected vehicles in intelligent transportation system (ITS) scenario rely on environmental data for supporting user-centric applications along the driving time. Sensors equipped in the vehicles are responsible for accumulating data from the environment, followed by the fusion process. Such fusion process provides accurate and stable data required for the applications in a recurrent manner. In order to enhance the data fusion of connected vehicles, this article introduces multi-variate data fusion (MVDF) technique. This technique is competent in handling asynchronous and discrete data from the environment and streamlining them into continuous and delay-less inputs for the applications. The process of data fusion is aided through least square regression learning to determine the errors in different time instances. The indefinite and definite data fusion instances are differentiated using this regression model to identify the errors in fore-hand. Besides, the differentiation relies on the application run-time interval to progress data fusion within the same or extended time instance and data slots. In this manner the differentiation along with the error identification is regular until the application required data is met. The performance of this technique is verified using network simulator experiments for the metrics error, data utilization ratio, and computation time. The results show that this technique improves data utilization under controlled time and fewer errors.

Published
2021

39. Adaptation of Blockchain in Internet of Medical Things for Remote Patient Monitoring

Author

Cinthia J. Godly, Venki Balasubramanian, Ram Srinivasan, and Bevish Y. Jinila

Abstract

IoT has been transforming the world of information significantly. It has allowed administration services without human interventions for a range of applications including healthcare with Remote Patient Monitoring (RPM). Blockchain is broadly utilized in IoT applications like smart health monitoring that provides privacy and security. Blockchain innovation presents freedom for the medical services industry, for example, reduced transaction costs, transparency for reporting regulatory entities, productive medical care information, privacy, confidentiality and universality of healthcare records. This chapter deals with the collaboration of blockchain innovation in IoT security in terms of the RPM framework. A Patient Centric Agent is used for end-to-end design for nonstop tolerant checking. The patient agent deals with a segment of blockchain to provide protection when streaming information from body area sensors that need to be securely stored and DQDO\]HG critical parts of blockchain to a wellbeing application network where patient's information can be utilized to make alarms that are essential to validate medical services suppliers in a protected way. This methodology is valuable as they assemble information for longer time frames. The access control manager stores and safely accesses information needed by the classifier during retraining progressively in realtime from an external data storage.

Published
2022

41. Innovative software systems for managing the impact of the COVID‐19 pandemic

Author

Soumya K. Ghosh, Venki Balasubramanian, S. Singh, and Ricardo Vinuesa

Subjects
2019-20 coronavirus outbreak, Editorial, Process management, Coronavirus disease 2019 (COVID-19), Computer science, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Pandemic, Software system, Software
Published
2021

42. AI and IoT-Enabled Smart Exoskeleton System for Rehabilitation of Paralyzed People in Connected Communities

Author

Mukil Alagirisamy, R Parvathi, Sunil Jacob, Venki Balasubramanian, Nz Jhanjhi, Chen Xi, Ram Srinivasan, and Sardar M. N. Islam

Subjects
General Computer Science, Computer science, medicine.medical_treatment, Internet of Things, 02 engineering and technology, Simultaneous localization and mapping, Rendering (computer graphics), 03 medical and health sciences, 0302 clinical medicine, Intelligent sensor, Human–computer interaction, 0202 electrical engineering, electronic engineering, information engineering, medicine, General Materials Science, Rehabilitation, business.industry, 020208 electrical & electronic engineering, exoskeleton, General Engineering, deep learning, artificial intelligence, Exoskeleton, TK1-9971, Medical services, Assistive technology, smart connected community, Electrical engineering. Electronics. Nuclear engineering, business, 030217 neurology & neurosurgery
Abstract

In recent years, the number of cases of spinal cord injuries, stroke and other nervous impairments have led to an increase in the number of paralyzed patients worldwide. Rehabilitation that can aid and enhance the lives of such patients is the need of the hour. Exoskeletons have been found as one of the popular means of rehabilitation. The existing exoskeletons use techniques that impose limitations on adaptability, instant response and continuous control. Also most of them are expensive, bulky, and requires high level of training. To overcome all the above limitations, this paper introduces an Artificial Intelligence (AI) powered Smart and light weight Exoskeleton System (AI-IoT-SES) which receives data from various sensors, classifies them intelligently and generates the desired commands via Internet of Things (IoT) for rendering rehabilitation and support with the help of caretakers for paralyzed patients in smart and connected communities. In the proposed system, the signals collected from the exoskeleton sensors are processed using AI-assisted navigation module, and helps the caretakers in guiding, communicating and controlling the movements of the exoskeleton integrated to the patients. The navigation module uses AI and IoT enabled Simultaneous Localization and Mapping (SLAM). The casualties of a paralyzed person are reduced by commissioning the IoT platform to exchange data from the intelligent sensors with the remote location of the caretaker to monitor the real time movement and navigation of the exoskeleton. The automated exoskeleton detects and take decisions on navigation thereby improving the life conditions of such patients. The experimental results simulated using MATLAB shows that the proposed system is the ideal method for rendering rehabilitation and support for paralyzed patients in smart communities.

Published
2021

44. Cognitive AmBC-NOMA IoV-MTS Networks With IQI: Reliability and Security Analysis

Author

Xingwang Li, Ming Zeng, Linpeng Hai, Yike Zheng, Mohammad Dahman Alshehri, Gaofeng Nie, and Venki Balasubramanian

Subjects
Security analysis, Series (mathematics), Computer science, Mechanical Engineering, Reliability (computer networking), Quality of service, Logistics & Transportation, Cognition, medicine.disease, 0801 Artificial Intelligence and Image Processing, 0905 Civil Engineering, 1507 Transportation and Freight Services, Computer Science Applications, Quadrature (mathematics), Noma, Automotive Engineering, medicine, Electronic engineering, Latency (engineering)
Abstract

Internet-of-Vehicle (IoV) enabled Maritime Transportation Systems (MTS) communication is anticipated to support ultra-reliable and low latency, diverse quality-of-service (QoS) and large-scale connectivities. To meet such stringent demands, a cognitive ambient backscatter non-orthogonal multiple access (C-AmBC-NOMA) IoV-MTS network is proposed. We explore the reliable and secure performance of the proposed C-AmBC-NOMA IoV-MTS network with in-phase and quadrature phase imbalance (IQI) at radio-frequency (RF) front-ends and the existence of an eavesdropper. In particular, the analytical expressions on the outage probability (OP) and intercept probability (IP) are obtained after a series of calculations. For a deeper understanding, we discuss the asymptotic behavior of OPs in the high signal-to-noise ratio (SNR) region, the diversity orders of OPs, and IPs in the high main-to-eavesdropper ratio (MER) regime. The results of Monte-Carlo simulation and a series of corresponding theoretical analysis show that: i) As the SNR approaches infinity, the OPs tend to be fixed non-negative values, indicating that the diversity orders of the OPs have error floors; ii) When the MER approaches infinity, the IPs of legitimate users decrease continuously, while the IP of backscatter device (BD) increases; iii) Compared with the system performance under ideal condition, the system performance is less reliable under IQI condition, but the security performance is enhanced; iv) By carefully selecting the system parameters, a trade-off can be achieved between reliability and security.

Published
2022

45. A supervised learning model to identify the star potential of a basketball player

Author

Venki Balasubramanian, Ram Srinivasan, and Abhishek Vidyasagar

Subjects
Basketball, Computer science, business.industry, Supervised learning, Star (graph theory), Machine learning, computer.software_genre, Theoretical Computer Science, Computational Theory and Mathematics, Artificial Intelligence, Control and Systems Engineering, Analytics, Artificial intelligence, business, computer
Published
2021

47. An intelligent heart disease prediction system based on swarm-artificial neural network

Author

Mainak Adhikari, Venki Balasubramanian, Varun G. Menon, Sudarshan Nandy, Xingwang Li, and Muhammad Zakarya

Subjects
0209 industrial biotechnology, Artificial neural network, Heart disease, Computer science, Heuristic (computer science), business.industry, Swarm behaviour, 02 engineering and technology, Prediction system, equipment and supplies, Machine learning, computer.software_genre, medicine.disease, Task (project management), Consistency (database systems), 020901 industrial engineering & automation, Artificial Intelligence, 0202 electrical engineering, electronic engineering, information engineering, Benchmark (computing), medicine, 020201 artificial intelligence & image processing, Artificial intelligence, business, computer, Software
Abstract

The accurate prediction of cardiovascular disease is an essential and challenging task to treat a patient efficiently before occurring a heart attack. In recent times, various intelligent healthcare frameworks have been designed with different machine learning and swarm optimization techniques for cardiovascular disease prediction. However, most of the existing strategies failed to achieve higher accuracy for cardiovascular disease prediction due to the lack of data-recognized techniques and proper prediction methodology. Motivated by the existing challenges, in this paper, we propose an intelligent healthcare framework for predicting cardiovascular heart disease based on Swarm-Artificial Neural Network (Swarm-ANN) strategy. Initially, the proposed Swarm-ANN strategy randomly generates predefined numbers of Neural Networks (NNs) for training and evaluating the framework based on their solution consistency. Additionally, the NN populations are trained by two stages of weight changes and their weight is adjusted by a newly designed heuristic formulation. Finally, the weight of the neurons is modified by sharing the global best weight with other neurons and predicts the accuracy of cardiovascular disease. The proposed Swarm-ANN strategy achieves 95.78% accuracy while predicting the cardiovascular disease of the patients from a benchmark dataset. The simulation results exhibit that the proposed Swarm-ANN strategy outperforms the standard learning techniques in terms of various performance matrices.

Published
2021

49. Towards Smart World

Author

Rinku Sharma Dixit, Dr. Lavanya Sharma, Shanu Sharma, and Venki Balasubramanian

Subjects
business.industry, Smart world, Internet privacy, business, Internet of Things
Published
2020

50. Rapid health data repository allocation using predictive machine learning

Author

Andrew Stranieri, Iqbal Gondal, Ashraf Uddin, and Venki Balasubramanian

Subjects
Technology, 020205 medical informatics, Computer science, business.industry, Deep learning, 020206 networking & telecommunications, Health Informatics, 02 engineering and technology, Health records, Machine learning, computer.software_genre, Health data, Machine Learning, Blockchain, Health Records, Personal, Electronic health record, 0202 electrical engineering, electronic engineering, information engineering, Electronic Health Records, Humans, Artificial intelligence, Stream data, business, computer, Classifier (UML)
Abstract

Health-related data is stored in a number of repositories that are managed and controlled by different entities. For instance, Electronic Health Records are usually administered by governments. Electronic Medical Records are typically controlled by health care providers, whereas Personal Health Records are managed directly by patients. Recently, Blockchain-based health record systems largely regulated by technology have emerged as another type of repository. Repositories for storing health data differ from one another based on cost, level of security and quality of performance. Not only has the type of repositories increased in recent years, but the quantum of health data to be stored has increased. For instance, the advent of wearable sensors that capture physiological signs has resulted in an exponential growth in digital health data. The increase in the types of repository and amount of data has driven a need for intelligent processes to select appropriate repositories as data is collected. However, the storage allocation decision is complex and nuanced. The challenges are exacerbated when health data are continuously streamed, as is the case with wearable sensors. Although patients are not always solely responsible for determining which repository should be used, they typically have some input into this decision. Patients can be expected to have idiosyncratic preferences regarding storage decisions depending on their unique contexts. In this paper, we propose a predictive model for the storage of health data that can meet patient needs and make storage decisions rapidly, in real-time, even with data streaming from wearable sensors. The model is built with a machine learning classifier that learns the mapping between characteristics of health data and features of storage repositories from a training set generated synthetically from correlations evident from small samples of experts. Results from the evaluation demonstrate the viability of the machine learning technique used.

Published
2020

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