Arjuna Veera SE
@pes.edu
Student, PES University
PES University
I am a recent graduate with a Bachelor of Technology (BTech) degree from PES University, where I pursued a comprehensive course of study in [Your Specific Major or Program]. During my academic journey, I had the privilege of participating in a transformative research internship at PES University, contributing to a year-long capstone project.
EDUCATION
I am a recent graduate with a Bachelor of Technology (BTech) degree from PES University, where I pursued a comprehensive course of study in [Your Specific Major or Program]. During my academic journey, I had the privilege of participating in a transformative research internship at PES University, contributing to a year-long capstone project.
As part of this internship, I had the opportunity to present my research findings at the CSITSS Conference in November 2023, showcasing my commitment to merging theoretical knowledge with real-world applications in the field of antenna design. Throughout this period, I acquired proficiency in utilizing CST Microwave Studio Suite and CAD tools for visualization, further enhancing my technical skill set.
Key highlights of my achievements include spearheading the design of a high-performance conformal antenna featuring a 1x4 array and corporate feeding techniques. Emphasizing its application in high-velocity aircraft and UAVs.
RESEARCH, TEACHING, or OTHER INTERESTS
Engineering, Electrical and Electronic Engineering, Oceanography, Radiation
FUTURE PROJECTS
Design of CSRR and Toothed SRR-Based Metamaterial Antenna
This research presents a novel antenna design tailored for satellite applications, incorporating a hybrid configuration comprising one Complementary Split Ring Resonator (CSRR) and nine Toothed Split Ring Resonators (TSRRs) on a defected grounded plane. The proposed antenna leverages metamaterials, characterized by unique properties like negative permeability and negative permittivity. The entire structure is implemented on an FR4 substrate with a height of 1.53 mm. The introduction of a slots enhances the antenna's versatility, enabling operation across multiple frequency bands i.e, 4.5 GHz, 5.05 GHz, and 5.55 GHz, resulting in notable improvements in gain, bandwidth, and return loss. Further refinement involves the truncation of antenna corners, resulting in circular polarization and enhanced impedance matching. Simulation tools such as CST, HFSS, and FEKO were employed to analyze and validate the proposed antenna design. Experimental testing in an anechoic chamber yielded a return l
Applications Invited