Research Areas of Departement of Electronics and Communication Engineering
|
| Major Research Areas |
Number of Members Involved |
Name of the Faculty |
Core Specialization |
Interdisciplinary Areas |
| VLSI and Devices |
12 |
Prof. S. Baishya |
Solid-State Device Modeling and Simulation, Electronic Circuits, VLSI, and MEMS |
– – – - |
| Dr. P. K. Paul |
Fiber Optic Sensor, Optical interconnects, Analog VLSI Circuit |
– – – - |
| Dr. K.L. Baishnab |
Analog and RF VLSI Design, Algorithms to VLSI architectures, Device modeling, Biosensor Modelling and Optimization of VLSI Circuits and Communication system |
VLSI Design for Communication Systems, Modeling, and Optimization in 5G communication |
| Dr. M. Choudhury |
Microprocessor & Microcontroller, Electronic circuits, Digital circuits, Electronic measurements & Instrumentation, Bio-medical Instrumentation |
– – – - |
| Dr. B. Bhowmick (Shome) |
Semiconductor Devices, Modeling, and Simulation of low power and high power semiconductor devices, analog circuits, application of semiconductor devices as Biosensor and Light sensor |
Application of Semiconductor Devices as Sensors |
| Dr. Koushik Guha |
MEMS, NEMS, Microfluidics, Lab on Chip, VLSI, Semiconductor Devices |
MEMS/NEMS |
| Dr. T. R. Lenka |
Nanoelectronics, Nanotechnology, VLSI Design, MEMS Energy Harvesting, Solar Photovoltaics |
Solar Photovoltaics, Energy harvesting |
| Dr. S. K. Tripathy |
Electronic structure calculations, Nanoscience and Nanotechnology, Solar Cells, Storage Battery, Device Modelling and simulations, Sensors, VLSI system, and Testing |
Sensor for various applications, Lithium-Ion Battery, Perovskite solar cell, Machine Learning |
| Dr. Robin Khosla |
Nanoelectronics, Micro/Nanofabrication, VLSI Design and Technology, Semiconductor Materials and Devices fabrication and characterization, Embedded systems, and FPGA-based system design. |
Optoelectronics, Sensors and Actuators, MEMS, Group-IV based devices, Advanced Lithography |
| Dr. M. Kavicharan |
VLSI interconnects, Signal Integrity, Power Integrity, Advanced Devices, and Their Modeling, Analysis. Modeling of Carbon Nanotube Interconnects and stretchable interconnects, Embedded system design. |
Microelectronic devices for sensing applications. Stretchable electronics for wearable biomedical applications. Development of FPGA-based applications. Machine learning for VLSI physical design |
| Mr. Anupal Deka |
Nanoscale Devices, Molecular Dynamics Simulation |
– – – - |
| Dr. Bijit Choudhuri |
Microelectronic devices simulation, optoelectronic device fabrication, and characterization |
Optoelectronics material and device, Fabrication of Novel Nanostructures and their optical and electrical properties, Glancing angle deposition, Flexible health monitoring device |
| Communication Engineering |
8 |
Prof. Fazal A. Talukdar |
Communications and Signal Processing |
– – – - |
| Dr. Madhumita Banerjee |
Optical Communication |
Image processing |
| Dr. Wasim Arif |
Communications and Signal Processing |
– – – - |
| Dr. Ashraf Hossain |
Wireless Sensor Networks, Wireless Communications, Satellite Communications, Communication Systems, Wireless communications for 5G and 6G, Millimeter-wave communications |
– – – - |
| Dr. Ganesh Prasad |
Satellite Communication, Cooperative Wireless Communications, Underwater Networks, Free-Space Optical Communications, and Green Communications, Massive MIMO, Cooperative MIMO, NOMA, Wireless Sensor Networks, Power Line Communications, Smart Grid, Cognitive Radios, Next Generation Wireless Networks, UAV-assisted Networks, OFTS |
Machine Learning, Deep Machine Learning, Artificial Intelligence, Convex Optimization, 5G Networks, Signal Processing for Communication |
| Dr. Prabina Pattanayak |
Wireless Communication Systems, MIMO/massive MIMO Communication Systems, Applications of Soft Computing Techniques, Cross-Layer Communication Issues, Resource Allocation for Communications, Millimeter-Wave Communications, Machine Learning for Communications, Antenna Design, FPGA Prototyping for Communications |
Smart Grid Communications, Smart Transportation Systems, Optimization Techniques, Machine Learning, Deep Learning |
| Dr. P. Puspa Devi |
Optical Fiber Communication, Opto-Electronic Devices, III-V Semiconductors, Electronic Biosensors, and Photonic crystal Biosensors |
– – – - |
| Dr. Devendra S. Gurjar |
Wireless Sensor Networks, MIMO communication systems, cooperative relaying, device-to-device communications, smart grid communications, physical layer security, and simultaneous wireless information and power transfer |
Smart Transportation Systems, UAV Communications, V2X Communications |
| Signal/Image Processing |
5 |
Dr. R. H. Laskar |
Speech and Audio Processing, Image and Video processing, Bio-medical image processing, Communication system Engineering, Soft computing techniques, Machine Learning |
Speech and Audio Processing, Natural Language Processing, Medical Image Processing |
| Dr. R. K. Karsh |
Image Hashing, Dynamic Hand Gesture Recognition, Sign Language Recognition, Image Authentication, Multimedia Security, Computer vision using Deep Learning |
Medical Image Processing: Early detection of cancer disease using computer vision |
| Dr. Chandrajit Choudhury |
Light Field Imaging, Digital Image Processing, Computer Vision, Pattern Recognition, Compressive sensing |
– – – - |
| Dr. R. Murugan |
Bio-Medical Signal/Image Processing, Retinal Image Analysis, Digital Image Processing, Digital Signal Processing, Embedded systems, Machine Learning, and Deep Learning. |
Medical Image Processing, Medical Internet of Things, Automatic Driverless Assistance System, Design of exoskeleton, Multimedia Compression Techniques, Machine learning / Deep learning. VLSI / Embedded Signal Processing, and differential & integral equations for medical image segmentation/restoration. |
| Dr. Tripti Goel |
Medical Image Processing, Neuroimaging, Pattern Recognition, Digital Image Processing, Digital Signal Processing, Optimization techniques, Machine Learning, and Deep Learning. |
Medical Image Processing, Machine learning, Pattern Recognition, Deep learning, Optimization Techniques |
| RF and Microwave |
6 |
Dr. Banani Basu |
Antenna & Wave Propagation, Metamaterial Structures, Wireless Communication |
Machine Learning (ML) in Antenna Design, Application of ML in RF Imaging, Soft Computing for Radiation Pattern Synthesis |
| Dr. Taimoor Khan |
Printed Microwave and Millimeter-Wave Components, RF Energy Harvesting, EBG, and FSS Structures, Ultra-wideband Technology |
Computational Intelligence in Applied Electromagnetics, Bio-Electromagnetics |
| Dr. Arnab Nandi |
Resonators for RF Applications, Metamaterial-Inspired Structures for Antenna Application, Wireless Sensor Networks |
Deep Learning-Based Intelligent Receiver for Wireless Communications, Soft Computing Techniques in Wireless Sensor Networks, Machine Learning (ML) in Antenna Design |
| Dr. Ujjal Chakraborty |
Compact Multiband antennas, phased array antennas, Body wearable conformal antennas, and reconfigurable antennas |
– – – - |
| Dr. M. V. Swati |
High-frequency Active Devices; Antenna Design; Metamaterial based devices; Radio Frequency Integrated Circuits; Gyro-Devices |
– – – - |
| Dr. Gaurav S. Baghel |
High-frequency solid state devices; RFICs; Antennas; Metamaterial based devices; Millimeter-wave Devices; Gyrotron Oscillators; Gyro-Traveling Wave Tubes; Remote detection of radioactive materials using millimeter wave signal |
– – – - |
