Critical Need
Mithril's ability to actively reshape the surface of satellite mesh reflector antennas on-orbit will enable a type of atmospheric radar instrument that currently does not exist. Atmospheric monitoring from space is limited–remote sensing from low-earth orbit cannot continuously monitor any one area, while instruments in geostationary orbit cannot be made large and precise enough to penetrate the atmosphere. Gaps in disaster tracking are patched by pilots flying decades-old aircraft into storms, even as storm impacts become more severe and less predictable. New instruments that enable continuous atmosphere-penetrating coverage will be critical to protect vulnerable communities and commercial shipping.

Technology Vision
Mithril's technology allows active shaping and correction of the reflecting surface of a reflector-type antenna for satellites in geostationary orbit (GEO). This capability breaks existing trade-offs that limit the precision of large high-gain reflectors and enables a new type of space-based atmospheric radar that requires a large, high-precision reflector. This will allow continuous monitoring of large-scan sectors of the atmosphere for better prediction of and resilience against natural disasters. The technology also allows flexibility in GEO satellite communications and applications in signal intelligence thanks to the ability to deform and steer the whole dished reflector surface. 

Potential for Impact
Mithril's technology will change the game in severe weather monitoring and forecasting from space by providing the missing piece to enable essential new radar instruments. As severe weather becomes less predictable and impacts more communities and industries, Mithril's ability to continuously monitor large areas will reduce insured risks, help protect shipping and transportation infrastructure, and protect vulnerable communities from harm.