SBIR-STTR Award

Highly-integrated, reconfigurable radar antenna arrays fabricated on flexible substrates offer high functionality in a portable package that can be rolled up and transported on the ground, or deployed into space. High levels of integration allow for: reconfigurability of operating frequency and / or gain pattern; integration of control, information processing, and communications functions directly onto the antenna substrate; integration of MEMS sensors into the antenna substrate to monitor the system health during deployment and in service; and opto-electronic beam forming networks, providing immunity to electromagnetic interference. While the advantages of highly-integrated flexible antennas are significant, their fabrication is highly challenging due to the lack of manufacturing technologies that can meet all of the processing requirements on flexible substrates. In this program we will develop and demonstrate a lithography-based process technology that enables a variety of critical processes that cannot be carried out using existing patterning technologies, in particular: the fabrication of the radar elements and feed structures on very-large-area substrates; the reduction of manufacturing costs by using photoablation processes; high levels of integration by means of laser-crystallization, allowing for the integration of high-performance ICs; and a combination of processes to produce MEMS for on-board sensors and for reconfiguring the array.

As the important role of NASA "missions to earth" has been clearly demonstrated in recent years, the need for radar antenna systems that have large fields of coverage has gained increased emphasis. In order to achieve the desired performance from space, the antenna systems must have surface areas that are hundreds of square meters in size. However, to make it affordable to deploy such large-area antennas into space, it is necessary to fabricate these antennas on flexible substrates, which are lightweight, and can be rolled into small volumes. The fabrication of flexible antennas calls for new manufacturing techniques that are capable of addressing the challenges of patterning high-resolution features on very-large area flexible substrates, while achieving precise registration of the antenna features over the entire substrate area. In this Phase II proposal we will develop and demonstrate processes to fabricate large-area antennas on flexible substrates, focusing, in particular, on JPL's 2 x 3 m active membrane phased array radar; and we will fabricate the flexible panels required for JPL's antenna. The fabrication of the array antenna will be performed using Anvik's novel large-area roll-to-roll photolithography technology, which enables high-resolution and micron-level registration on large-area flexible substrates.