About
I recently completed my Bachelor’s degree in Electrical Engineering and am seeking a role that allows me to work hands-on with hardware and embedded systems. I’m especially interested in understanding electronic systems at a fundamental level and enjoy applying that knowledge through practical projects. Currently, I’m designing and building a custom smartwatch as a personal hardware project, focusing on embedded firmware, low-power design, and system integration. Outside of engineering, I enjoy playing video games, snowboarding, and staying active through regular workouts.
Projects
Overwatch Pinball Machine
Created an Overwatch inspired pinball with character selection, voicelines, ultimate abilities, and more
Two-Stage Folded-Cascode Operational Amplifier
Designed and implemented a two-stage folded-cascode + common-source operational amplifier to achieve specifications of 80MHz unity-gain bandwidth, 65° phase margin, 70dB DC gain, and minimial power dissipation through device-level sizing and compensation design.
Line Following Robot
Made a line following robot using PID contols, Arduino, photoresistors, and custom 3D printed part. Competed against other in various tracks and got the most laps for one of the tracks.
IOT AI Wardrobe
Created a secure and personal IoT wardrobe management app where users can create an account, log into an existing account, and maintain secure sessions. Upon authentication users are directed to their personalized profile where they can register new sensor devices to their account, monitor real-time environmental data, and view temperature trends in their city. Authorized users are also given access to their personal wardrobe and dashboard, where they can keep track of all of their clothes by adding/removing items from their closet, or even chat with their AI-powered assistant!
SolarPunk WebGame
Designed and implemented a two-stage folded-cascode + common-source operational amplifier to achieve specifications of 80MHz unity-gain bandwidth, 65° phase margin, 70dB DC gain, and minimial power dissipation through device-level sizing and compensation design.