Nano Dimension’s First AME Monolithic RF Communications Circuit Was Sent to ISS Flight Studies
Nano Dimension Ltd., an industry leading additively manufactured electronics (AME)/PE (Printed Electronics) provider, announced that the first ever integrated RF circuit fabricated by Nano Dimension and designed and integrated by L3Harris, has been flown to the International Space Station (ISS). This project, two years in the making, was selected by the ISS U.S. National Laboratory for space effects studies. The project will provide a systematic analysis of an additively manufactured single board for RF space systems, especially for nanosatellites and will communicate with a ground-based satellite tracking system at Embry Riddle Aeronautical University, Daytona Beach, Fla. The primary purpose of the project is to demonstrate the viability of using new technologies, such as multi-level/multi-material AMEs, which use 3D inkjet printer-based technologies to produce monolithic RF communication systems for use in space.
This project, part of the MISSE Flight Facility, is the first systematic experiment by L3Harris and Nano Dimension aiming to analyze the RF properties of additively manufactured High Performance Electronic Devices (Hi-PEDs™) in a space environment.
L3Harris is a leader in the development of RF circuits for satellites and communications systems. In recent years, research to develop these circuits and systems used for conveying information such as data, video and voice across long distances has focused on improving mobility and performance.
Nano Dimension fabricated the single RF board using its proprietary additively manufactured electronics process in the DragonFly LDM® system. The board includes the antenna, the electronic traces for mounting all the functional components, and the signal ground plane. The fabricated communications device was designed by L3Harris to operate at 2.4 Ghz and to be integrated into the MISSE module and launch. This device will be tested at three program points: pre-flight, in-flight and post-flight. In this first-of-its-kind space flight experiment, the hardware will fly in the low Earth orbit (LEO) environment for six months on the ISS, which will provide scientists with a better understanding of how AME technology endures in various space environments. LEO, a region some 1,200 miles (2,000 km) above the planet, is home to the ISS, as well as a large number of communications satellites, all of which utilize RF communications systems. The possibility of using AME technology for these RF systems had arisen in the past, as it offers several advantages, including the ability to produce low weight, high performance electronic devices, rapid development time and the ability to fabricate complex shapes and systems that traditional manufacturing cannot.
Dr. Arthur Paolella, senior scientist for the Space and Airborne Systems segment of L3Harris, commented, “Additive manufacturing, or 3D printing, is playing a critical role in advancing the development and applications of small and nano satellites and the overall LEO economy. The applications of 3D printing are broad, touching almost every aspect of research, design and manufacturing. The major objective of this project is to fly an experiment consisting of an integrated communications circuit fabricated by additive manufacturing and analyze the RF properties of those materials in a space environment. The communications system now on the ISS went through extensive testing in order to prepare it for the mission. Nano Dimension’s contribution to this project was extremely important, as their additively manufactured capability is technologically advanced and superior to existing technologies.”
“This project has been a significant opportunity to qualify our additive manufacturing technology for space applications by fabricating a fully integrated communications board enabled by the multi -material and multi-layer technology of our DragonFly LDM® system,” said Dr. Jaim Nulman, Nano Dimension’s chief technology officer. “The collaboration with L3Harris has increased the technological readiness of our system towards the TR-9 level, which is the highest technology readiness level that indicates the capability for volume deployment in a LEO environment,” added Dr. Nulman.