Supriyo Sinha

Joint venture between Verily Life Sciences and Santen pharmaceuticals. Help define and execute company's technical vision Manage an outstanding team of electrical, mechanical, software and optical engineers and managers. Working on products that integrate virtual reality, data analytics, implant technologies and optical sensing

Early employee of Google Life Sciences, which became Verily Life Sciences Key lead on driving several programs and strategic partnerships from concept to launch Developed illumination hardware and control system for surgical robotics platform in $700M joint venture with Johnson&Johnson (Verb Surgical) Key inventor of technology used as core of digital pathology collaboration with Allergan $xxM Founder of microfluidic platform used in $xxM collaboration with Gilead Developed three ophthalmic medical devices from concept to early prototype that are part of backbone of $xxxM joint venture between Santen and Verily Built and managed successful teams comprising of mechanical engineers, optical engineers, hardware engineers and system engineers

Provide design consultation of optical systems and their applications (especially towards clinical and medical uses)

Optics subject matter expert within company Built optical concept development lab Developed early concepts and prototypes for optical biometrics products

Technical lead building a massively parallel in vivo brain imaging system for fruit flies - managed team of half a dozen scientists and engineers - developed laser micro-dissection protocol to enable neural imaging of fruit flies - designing optical components for massively parallel brain imaging microscopy system - designing fiber optic arrayed two-photon microscope system - research has been featured on NBC News, The Scientist among others Helped engineer endoscope system for imaging human muscle in live subjects

- leading the development of optical fiber, integrated optics and other optical technologies in CPA systems - modeling of high-power ultrafast fiber amplifiers and designing next-generation systems - responsible for construction of lab facilities and lead experimentalist at site reporting directly to CTO - working with outside suppliers to design and package custom devices

Co-wrote several funding proposals to different funding agencies Continued work in high power fiber lasers and amplifiers

Conducted research in adaptive optics (2000-2001) - built and tested silicon micro-machined deformable mirrors for thermal aberration compensation - built the hardware and software for Hartmann wavefront sensors - wrote software code to control deformable mirrors in a closed feedback loop Conducted research in slab laser amplifiers (2001-2003) - built and characterized edge-pumped slab resonators - helped develop a 100-W single frequency slab MOPA source Conducted research in fiber lasers and amplifiers (2003-2007) - built a simulator to model the performance of rare-earth doped fiber lasers and amplifiers - designed and helped construct the fiber lasers lab working space - trained two junior students in the area of fiber lasers - modified the silicate bonding process to allow fiber end-capping with bulk windows - working in the area of high power cw fiber lasers, high pulse energy modelocked fiber lasers and novel wavelength fiber lasers

- helped design and implement the antenna for RIM’s next generation product - helped improve existing antenna designs for RIM’s older products

- designed an active wideband balun with HBTs (5 GHz – 30 GHz) - created cells to decrease time required to simulated designs with mixed signals

- designed two FPGAs and a CPLD for the VIVID M360 card

- aided in the board layout of the 3600+ power supply backplane

- introduced major enhancements and bug fixes to the generated parsers/scanners in our translator layer

- multithreaded the test driver so that performance would improve and debugging would become easier