Author Archives: monambigha

EASIS Summer Camp 2017


From June 12th to 16th, CIAN at the University of Arizona hosted 15 Native American high school students from Winslow Unified School District in Winslow, AZ. The annual Expect Academic Success in STEM (EASIS) Optical Engineering Summer Camp offers 8th-12th grade students the chance to learn more about optics and engineering through demonstrations, presentations by OSC graduate students and faculty, guided tours, and a college preparation talk. A great “thank you” to CIAN and UA College of Optical Science faculty, students, and staff for making the third year of EASIS another huge success!

Check out the slides below to see the fun we had and learning about optical engineering.

Interested in supporting EASIS 2018? Or interested in making a summer camp adventure for your students? Contact Us!


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The Summer 2017 EASIS program was supported in part by contributions from SPIE and the College of Optical Sciences. We’d like to give hearty thanks to these contributors for their essential part in the summer’s success!

IOU REU: 2017 Program Summary

Every summer, CIAN hosts undergraduate students for the Integrated Optics for Undergraduates (IOU) Research Experience for Undergraduates (REU) program. This summer CIAN hosted four talented and successful students to participate in innovative research across CIAN campuses nationwide. Following is a summary of these students’ experiences and more information about the program.

Learn more about and apply for the IOU REU program for Summer 2018 here.


Aneek James, an electrical engineering student from the University of Georgia performed research on Construction of a Fiber Array-Centered Silicon Photonic Chip Prober. His Mentor was Dr. Keren Bergman.

Aneek working on his research project.

Project Abstract:

Two-fiber stage probers are limited in stability, cost of required actuators, and inability to run parallel tests on the I/ O ports(e.g. cross talk experiments). In an effort to address these issues, a fiber array-based prober was developed to facilitate efficient testing of silicon photonic chips.


Jazz Pouls, an electrical engineering and computer science major from the University of California Berkeley performed research on Accelerated High Precision 3D Imaging with FMCW Lidar. His mentor was Dr. Ming Wu.


200 x 200 scan of human fingers

Project Abstract:

Frequency Modulated Continuous Wave Lidar (FMCW)

  • Galvo mirrors to scan laser across target
  • Interferometry to determine target’s distance
  • Applications: driverless cars, robotics, manufacturing
    • These applications need high resolution and speed
    • Current resolution is good: <1mm resolution at ~10m distance
    • Our current system is slow: a 100×100 point scan takes ~10 min
    • Goal: Increase speed, ideally to video frame rate (30 fps)


William (Trey) Rauh, an engineering major from the Tidewater Community College completed his project on Optical Triplexer Design. Dr. Demetris Geddis was his mentor.

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Project Abstract:

  • Optical Triplexers are utilized in the creation of optical networks. These devices are used to send and recieve multiple wavelengths of light in the same fiber optic cable.
  • Incoming optical pulses are converted to electric signals via photodetectors.
  • Outgoing electrical transmissions are emitted by VCSEL (Vertical Cavity Surface Emitting Laser).
  • Ultimately, the triplexer serves as a device for converting optical pulses to electrical signals, and vice versa.


Jeffrey Smith, an engineering student from Thomas Nelson Community College performed research on Design and Simulation of Reciever and Transmitter Circuits for Optical Triplexers. Dr. Demetris Geddis also mentored him.

Project Abstract:

The goal was to design and simulate receiver and transmitter circuits for optical triplexer. Fiber networks are so cost effective that this new triplexer build might be a more cost efficient way to open a catalyst of data centers.

I’m personally motivated by the children whom live in poverty stricken communities or those secluded rural areas where fiber coverage isn’t offered. Providers only render these resources to the more prominent economies. The motivation for this research for me is giving people the tools they need but were never offered, so that they may transform their minds.