Experience

nView medical

• United States
• Medical Equipment Manufacturing
• 1 - 100 Employee

• Systems Engineer

  • May 2018 - Present

  Development of image quality metrics, optimization of image quality, development of protocols for verification. Recently achieved 510K compliance from the FDA for the product. Development of image quality metrics, optimization of image quality, development of protocols for verification. Recently achieved 510K compliance from the FDA for the product.



Centro de Imágenes Biomédicas, Pontificia Universidad Católica de Chile

• Intern

  • Jan 2018 - Apr 2018

  Development of a desktop Magnetic Resonance Imaging (MRI) system. Current work includes development of magnetics system, RF hardware, and data acquisition and processing. The final system will be used for research in low-cost MRI as well as classroom instruction of MR physics. Development of a desktop Magnetic Resonance Imaging (MRI) system. Current work includes development of magnetics system, RF hardware, and data acquisition and processing. The final system will be used for research in low-cost MRI as well as classroom instruction of MR physics.



Configurable Computing Lab, Brigham Young University

• Research Assistant

  • Aug 2013 - Dec 2017

  Research in light-weight, low-power computing for small radar. Implemented real-time FMCW radar processing algorithms on Zynq 7000 Field Programmable Gate Array. Resulting radar system weighs only 120 g and is 2.25 x 4 x 1.5 in³ in size. See publication for more detail. Research in light-weight, low-power computing for small radar. Implemented real-time FMCW radar processing algorithms on Zynq 7000 Field Programmable Gate Array. Resulting radar system weighs only 120 g and is 2.25 x 4 x 1.5 in³ in size. See publication for more detail.



Passive Inspection CubeSat Program, Brigham Young University

• Processing and Power Systems Team Lead

  • Apr 2016 - Sep 2016

  Led the design of the processing and power systems for the BYU Passive Inspection CubeSat Mission. The processing system uses an FPGA SoC to integrate 6 cameras and downlink image data to a ground station. Responsibilities included the design of the processing system architecture and instruction of student researchers. CubeSat will launch on the Virgin Galactic LauncherOne in June 2018 Led the design of the processing and power systems for the BYU Passive Inspection CubeSat Mission. The processing system uses an FPGA SoC to integrate 6 cameras and downlink image data to a ground station. Responsibilities included the design of the processing system architecture and instruction of student researchers. CubeSat will launch on the Virgin Galactic LauncherOne in June 2018