Wenjing Su

Google

Position: Google Hardware Engineer
Rising Stars year of participation: 2018
Bio

Wenjing Su currently works at Google as a hardware engineer focusing on wearable antenna designs. She earned her PhD in Electrical and Computer Engineering from Georgia Institute of Technology where she is advised by Prof. Manos Tentzeris. Her research interface advance novel fabrication technique (e.g., inkjet-printing, 3D printing), special mechanical structures (e.g., microfluidics), and high-performance microwave components/antennas to solve existing problems and extend the application of smart health wearable electronics in Internet-of-Things (IoT) applications. Her research interests include applied electromagnetics, RFID, additively manufactured electronics, wearable antennas, reconfigurable antennas, wireless sensing, machine-learning aid sensing, flexible electronics, and green electronics.

Additively Manufactured Reconfigurable Microwave Components Based on Microfluidics for Wireless Sensing and Internet-of-Things Applications

Additively Manufactured Reconfigurable Microwave Components Based on Microfluidics for Wireless Sensing and Internet-of-things Applications
This research combines additive manufacturing and microfluidics with microwave and radio frequency (RF) electronics to provide a novel low-cost flexible and reconfigurable solution for the Internet-of-Things (IoT). Microfluidics, an emerging technology which allows the precise control of an extremely small amount of liquid within tiny channels can be used in IoT applications to achieve Lab-on-Chip (LoC) functionality and an extraordinary reconfigurability. Microwave structures are very sensitive to the surrounding environment and thus, excellent sensors while passive radio frequency identification (RFIDs) provide low-cost zero-power solutions for wireless liquid sensing. This work has developed various proof-of-concept disposable wireless liquid sensors and RFID-based sensing platforms for LoC applications. To realize excellent reconfigurability low-costly and compactly, this research also has studied new reconfigurable RF integration topologies by integrating microfluidic channels and dielectric or conducting liquids. In order to significantly decrease the production time and cost, and thus, to enhance the ubiquitous smart items, this research studied additive manufacturing (AM) in IoT applications. This research has been exploring the possibility of replacing the conventional electronics and microfluidics fabrication methods with cost-effective additive manufacturing methods such as inkjet-printing and 3D printing. This work presents first-of-its-kind, cost-effective, rapid, low-temperature, and environmental-friendly AM fabrication methods for various reconfigurable antennas or microwave components, wearable sensors, and sensing platforms. In summary, this research focuses on utilizing new AM fabrication techniques and novel microfluidics topologies to provide a low-cost, flexible, and scalable solution for wireless sensing and IoT applications.