NASA picks Ohio State engineer to help detect, discard manmade radio frequency interference
The cacophony of signals constantly at play on Earth—from radio traffic to cell phones and other communications systems—ultimately creates the white noise of human technology in action.
In space, however, this cacophony is getting in the way of some important Earth science research - and it's only getting worse as human technology advances.
Joel Johnson, chair and professor of the Department of Electrical and Computer Engineering at The Ohio State University, is now leading a NASA program to help navigate the noise. Since 2001, his team at Ohio State has focused on detecting and discarding manmade radio frequency interference (RFI) from the Earth’s naturally fluctuating microwave signals. The technology is imperative for future satellite missions using microwave radiometry to observe Earth's properties.
Johnson's project, “CubeRRT: CubeSat Radiometer RFI Technology Validation,” recently received $5.6 million from NASA’s Science Mission Directorate to advance RFI reduction technology.
“Successful RFI mitigation by CubeRRT will not only improve the possibility of microwave radiometry in an RFI intensive environment, but may also allow future systems to operate over a larger bandwidth resulting in lower measurement noise,” Johnson said.
CubeRRT is one of four projects selected for the In-Space Validation of Earth Science Technologies (InVEST) Program in support of the NASA’s Earth Science Division. Ohio State is the only national university leading one of the four selected projects, and is working in partnership with investigators from NASA Jet Propulsion Laboratory and NASA Goddard Space Flight Center. The team will ultimately demonstrate RFI technologies for Earth-sensing microwave radiometers, enabling scientists to remotely sense global properties such as soil moisture, atmospheric water vapor, sea surface temperature, sea surface winds, and more.
Johnson's team contributed similar technologies for NASA’s Soil Moisture Active Passive (SMAP) satellite, which launched in January. SMAP is now helping scientists create the most detailed global maps of soil moisture to date, improving understanding of Earth’s water and carbon cycles, as well as the ability to manage water resources.
Johnson said the team's RFI system will fly in space as part of a “6U” (20 cm x 30 cm x 10 cm, i.e. the size of a shoebox) CubeSat, with a potential launch date as early as 2018.
NASA’s InVEST program is targeted to small instruments and instrument subsystems that can advance the technology to enable relevant Earth science measurements in space. The first year funding for these investigations is approximately $9 million dollars.
written by Ryan Horns, Electrical and Computer Engineering; edited by college communications staff