Embry-Riddle partners with private and public entities to assist in developing solutions to today's and tomorrow's aeronautical and aerospace problems. Here at the world's largest aviation-oriented university, our focus on applied research is unique.
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  • Effects of Institutional Responses to the COVID-19 Pandemic on Undergraduate Faculty and Students Across STEM Disciplines

    PI Chelsea LeNoble

    CO-I Allison Kwesell

    The project's specific aims are to: (1) examine teaching and learning experiences of undergraduate faculty and students in response to the COVID-19 pandemic; (2) examine the effects of faculty and student reactions on undergraduate STEM teaching and learning; and (3) leverage findings to develop actionable recommendations for colleges and universities to best prepare and protect their faculty, staff, and students and the integrity of undergraduate STEM education.

    View the project website here, and the NSF Award abstract here

    Tags: STEM college of arts and sciences multidisciplinary worldwide campus

    Categories: Faculty-Staff

  • Collaborative Research: Wideband Multi-Beam Antenna Arrays: Low-Complexity Algorithms and Analog-CMOS Implementations

    PI Sirani Mututhanthrige Perera

    PI Arjuna Habarakada Madanayake

    PI Soumyajit Mandal

    Explosion of millimeter-wave (mm-wave) bandwidth opens up applications in 5G wireless systems spanning communications, localization, imaging, and radar. This project addresses challenges in mathematics, engineering, and science in developing efficient wideband beamformers based on sparse factorizations of the matrix called-delay Vandermonde matrices (DVM). The proposed highly integrated approach is attractive for mobile applications including 5G smart devices, the internet of things, mobile robotics, unmanned aerial vehicles, and other emerging applications focused on mm-waves.



    A multi-beam array receiver is deeply difficult to realize in integrated circuit (IC) form due to the underlying complexity of its signal flow graph. Through the proposed work, mathematical methods based on the theories of i) sparse factorization and complexity of the structured complex DVM with the introduction of a super class for the discrete Fourier transform(which is DVM), and ii) approximation transforms are proved to solve this problem.

    The resulting matrices are realized with multi-GHz bandwidths using analog ICs. The novel DVM algorithm solves the longstanding "beam squint" problem, i.e., the fact that the beam direction changes with input frequency, making true wideband operation impossible. Moreover, the proposed multi-beamforming networks in analog IC form will be realized efficiently while addressing precision circuit design, digital calibration, built-in self-test, etc. Besides scientific merits, both minority students and female students will be mentored to pursue careers in the STEM disciplines through the proposed project.


    This project was funded by the National Science Foundation (the division of Electrical, Communications, and Cyber Systems) with award numbers 1711625 and 1711395. 

    Tags: mathematics computational mathematics Industrial Mathematics electrical and computer engineering college of arts and sciences STEM Women

    Categories: Faculty-Staff

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