Past Projects


Previous Projects

  • Machine-to-Machine Communication System, Hankuk University of Foreign Studies Research Funding, Seoul, South Korea. [2012- 2022 and Budget 30,000 $/Year]

  • Connected Vehicle for Driver Safety and Services, MtoV, Inc. South Korea, [2015- 2017 and Budget 30,000 $/Year]

  • Development of Intelligent Smart Phone Apps to strengthen Digital India Initiatives, Ministry of Human Resource and Dept. Delhi, India. 2016 [30 Lacs Indian rupees]

  • SAFESENS: Smart Town, ENIAC Joint Undertaking with the Grant Agreement no: 621272. [2015 - 2017]

  • Smart Town and PoT, EU Horizon 2020 projects ENTROPY with the Grant Agreement no: 649849. [2014 -2016 and Budget 200,000eu/Y]

  • Development of Smart City Applications, INPUT with the Grant Agreement no: 644672. [2014 - 2016]

  • NovaGenesis Architecture, Finep, with resources from Funttel, Grant No. 01.14.0231.00, Brazil. [2014 - 2018]

  • NovaGenesis based Services IoT Technology funded by The Radio communication Reference Center (Centro de Referência em Radicomunicações — CRR) of the National Institute of Telecommunications (Instituto Nacional de Telecomunicações - Inatel), Brazil. [2013 -2017]

  • Development of Future Internet Services, FCNPq, CAPES, and FAPEMIG, Brazil. 2012

  • Elastic of Energy Efficient IoT networks, CNPq (Grant# 305531/2015-8 & 457501/2014-6), Brazil.

  • Future Internet Architecture Research funded by Korea Comm. Comm. (KCC), Seoul, Korea. 2011

  • DEFINE: Developing Future Internet Network Model., funded by NAP (National Agenda Program) of Korea Research Council of Fundamental (KRCF) Science & Technology, Seoul, South Korea. Cost: 8.5 billion US-Dollars. [2009- 2012]

  • Spline-approximation of smooth surfaces funded by Techo. Innovation Center, DSU, Busan, Korea. [2007 - 2010]

  • uHealtcare: Ubiquitous Healthcare System funded by Brain Korea 2021 (BK21)-2nd Stage, Korea, [2007 -2010 and Budge 1.8 billion USD]

  • Assessment of Land use, Land Cover Pattern, Crop, Vegetation Classification, Water Area funded by Ministry of Human Resource and Development (MHRD), New Delhi, India, [2003 -2004 and Budget 5.0 Lakhs/ years]


Detailed Description

1. Machine-to-Machine Communication System fundend by HUFS from 2012-2022

This project focuses on the design and development of real-time software and embedded systems for the implementation of concept-proving prototypes in a timely manner. The project approach is also extended to cover end-to-end user applications, including Internet connectivity over small embedded devices for global communication between machine-to-machine, user-to-user, and user-to-machine. The project covers three major topics: architectural design, embedded systems design, and real-time software design at the systems level. The project aims to address issues related to the sensor-oriented Future Internet, including routing, mobility, MAC super frames, IPv6, ROLL, 6lowpan, energy consumption, security, and uHealthcare systems. My responsibility is to conduct research in computer networking and related areas, such as future internet architecture, wireless communication, cloud computing, the Internet of Things, M2M communication, and distributed systems.


2. Future Internet Architecture Research funded by Korea Communication Communications (KCC), Seoul, Korea, 2011

To address the limitations of the current Internet, we need to redesign the future Internet Architecture on a "clean slate" basis. To do this, we have defined a hierarchical architectural model that groups communicating entities based on their topological, administrative, or operational characteristics. The focus of this model is on the maintenance/query optimization mechanism during the ID and Locator separation system.

In this project, we aim to:

  • Understand the fundamental principles of future internet architecture and the current issues.

  • Implement algorithms for parameter estimation in linear and non-linear models.

  • Implement algorithms for ID detection and the estimation of the position of a target in a hierarchical network.

  • Apply the Bloom filter to linear state space models over an ID-mapping Server.

  • Understand the interplay of these elements in a few concrete real-world applications.


3. DEFINE: Developing Future Internet Network Model funded by National Agenda Program, KRCF, Korea, 2010

As a postdoctoral researcher in the DEFINE: Developing Future Internet Network Model project, you worked with the Future Internet Team in the Division of Fusion Convergence of Mathematical Sciences at the National Institute of Mathematical Sciences in Daejeon, South Korea. This project was funded by the National Agenda Program (NAP) of the Korea Research Council of Fundamental Science & Technology, and had a budget of 8.5 billion US dollars per year from November 2009 to October 2011.

My roal was in this project was to support the development of appropriate services in physical environments that provide global access to society. To do this, you focused on Sensor Oriented Future Internet (SOFI) schemes to support Internet connectivity over machine devices for various applications. Specifically, you worked on a machine-to-machine communication scheme, and described a work plan for this aspect of the project from March 2010 to August 2011.

  • Identifying suitable techniques for the collection and analysis of data.

  • Assisting in the development & preparation of continuing funding opportunities.

  • Travelling to international conferences and research visits in other institutions.

  • Contributing to team decisions about research directions.

  • Ensuring the validity and reliability of data at all times.


4. uHealtcare: Ubiquitous Healthcare Monitoring System funded by Brain Korea 2021 (BK21)- 2nd Stage, Korea, 2007

During my PhD studies, I have worked on the BK-21 (Brain Korea 2021, 2nd stage) "Ubiquitous Healthcare System" project in the laboratory of USN at Dongseo University in Busan, South Korea. This project was funded by the Ministry of Human Resource and Education in Seoul and had a budget of 1.8 billion US dollars.

My contribution in this project was to research and work on wireless sensor networks in the context of a ubiquitous healthcare system. You decided to focus on IPv6-based wireless sensor networks (6lowpan) for healthcare applications, and worked on several issues related to protocols such as routing, mobility, MAC, and security for an IP-WSN-based uHealthcare system using the NS-2 simulator and Sensinode, and TinyOS-based testbed. This work took place from March 2007 to February 2010.

  • To publish regularly in leading publications

  • To attend and present papers at relevant international conferences and workshops

  • Data coding, data entry, transcribing, data analysis & assistance with writing up.

  • Responsible for some administrative tasks, such as webpage maintenance.

  • Producing regular reports for senior management and specialists in different areas.


5. Spline-approximation of smooth surfaces funded by Techo Innovation Center, DSU, Busan, Korea,2008

During my PhD studies, I have worked on the "Spline-approximation of smooth surfaces" project with Professor Hakimjon at Dongseo University in Busan, South Korea. This project was funded by the RIC/TIC Project (UCGA-TIC; Techo Innovation Center) at Dongseo University. As a research scholar, I was responsible for implementing algorithms for specialized processors of piecewise-polynomial bases using Java and Matlab programming. I have covered a range of topics in this work, including piecewise-polynomial bases based on the orthogonal Haar and Harmut functions, two-dimensional piecewise-polynomial bases, piecewise-polynomial bases based on splines, two-dimensional piecewise-polynomial bases based on splines, Walsh-wavelet, and inverse piecewise methods for signal processing. This work took place from March 2009 to February 2010.

  • To publish regularly in leading publications

  • To attend and present papers at relevant international conferences and workshops

  • To create value by developing transferable IPR

  • To prepare and submit patent applications

  • To supervise research assistants in their Ph.D. program


6. Assessment of Land use, Land Cover Pattern, Crop, Vegetation Classification, Water Area funded by Ministry of Human Resource and Development (MHRD), New Delhi, India, 2003

During my research assistant position in the Department of Computer Science and Engineering at the MN National Institute of Technology in Allahabad, I have worked on the "Assessment of Land use, Land Cover Pattern, Crop, Vegetation Classification, Water Area" project. This project was funded by the Ministry of Human Resource and Development in New Delhi, and the budget was 6.0 lakh Indian rupees. My role was in this project, to study land data data using Earth-Resource (E-R Mapper) simulator to analyze the MNNIT campus area and assist with the installation of a water pipeline for future water resources. I also performed a range of tasks such as data coding, data entry, transcribing, data analysis, and assisting with writing up reports for senior management and specialists in different areas. I was also responsible for some administrative tasks, such as webpage maintenance. This work took place from August 2003 to July 2004.


7. Ph.D. Thesis Title: IP-Based Wireless Sensor Network for Global Healthcare Monitoring Applications

The continuous advancement of wireless sensor networks (WSN) has led to the improvement of existing wireless patient health-monitoring systems. The IP-based Wireless Sensor Networks (IP-WSN) have become a popular topic for researchers. The Internet Engineering Task Force (IETF) working group has been designing a new IPv6 over Low-Power Wireless Personal Area Networks (6lowpan) stack, which refers to an IPv6 integration with a Lowpan device, known as an IP-WSN node. The IEEE 802.15.4 standard defines two types of nodes: reduced-function devices (RFD) and full-function devices (FFD). In this project, RFD nodes are used as Biomedical Sensors (BMS) nodes, while FFD nodes are used as IP-WSN nodes. While BMS nodes are used for sensing and transmitting MAC layer beacons to IP-WSN nodes in Body Area Networks (BAN), they can only interact with IP-WSN nodes, while IP-WSN nodes can connect with other IP-WSN nodes due to their full-function capabilities, which include IPv6 compression, neighbor discovery, mesh routing, and BMS packet binding techniques.

This project involves simulating and realtime testing the performance of IP-WSN networks. In the simulation part, we have bound the patient's biomedical data on the MAC layer into the 6lowpan stack and assumed that a wearable IP-WSN device has been embedded in the patient's BAN. The IP-WSN node has limited power and memory, and is unable to carry large energy resources. Therefore, the IP-WSN node acquires BMS packets from the patient's BAN and subsequently transmits them to the gateway operated by the forwarder over IPv6 networks.



8. M. Tech. Thesis Title: Connectivity of Ad-hoc Sensor Network with Fixed Networks

Ad-hoc sensor networking allows portable devices to establish communication without relying on a central infrastructure. However, the lack of a central infrastructure and the ability of devices to move randomly can lead to various problems, such as routing and security. This thesis focuses on the problem of routing in ad-hoc sensor networks. There are several ad-hoc routing protocols, such as AODV, DSR, DSDV, OLSR, and ZRP, that offer solutions for routing within a fixed network. However, there is also a need for communication between not only wireless devices within an ad-hoc network, but also between a wireless device in an ad-hoc network and a fixed device in a fixed network (e.g., the Internet). To address this need, the ad-hoc routing protocol AODV is modified to examine the connection between a wireless ad-hoc sensor network and a fixed network. To do this, Network Simulator-2 is used, and three proposed approaches for gateway discovery are implemented and investigated.