Synopsys Collaborates with Ema and Cesium to Support Nasa Artemis Program with Spacesuit Analysis and Communication System Development
SNPS
Published on 04/14/2026 at 12:50 pm EDT
NASA selected Synopsys, Inc. and EMA to verify spacesuit compatibility with the lunar environment. This work advances Synopsys' ongoing support of future Artemis missions, which also includes a collaborative effort with Cesium, part of Bentley Systems, and NASA'sGlenn Research Center in Cleveland to validate cellular system performance on the lunar surface using digital twin technology. The joint effort by EMA and Synopsys focuses on reducing risks to extravehicular activity (EVA) systems, specifically spacesuits, caused by both triboelectrification from lunar regolith interactions, and electrical charging and electrostatic discharge (ESD) from the space plasma environment.
Analyzing charging levels that the complex, multi-layer Artemis spacesuits may experience on the moon is a key consideration for sustained lunar surface operations, because ESD events can damage mission-critical electronics needed for communications and life support.Under the planned approach, EMA and Synopsys will apply and develop physics-based analysis workflows using Ansys Charge Plus?, a software simulation tool for electromagnetic charging and discharging, to evaluate spacesuit materials, layered stack-ups, and representative suit features across relevant lunar plasma conditions. Charge Plus is currently the only commercially available software capable of computing these types of space-charging problems in full 3D due to its ability to model the coupled physics governing plasma interaction, surface charging, charge transport, and ESD in complex, multi-material systems.These simulation efforts are paired with test and validation activities conducted at EMA's Space Environment and Radiation Effects (SERE) Laboratory in Pittsfield, Mass., one of the few facilities capable of replicating key aspects of the space plasma environment on the ground. This integrated simulation-and-test workflow allows teams to identify charging drivers, evaluate design tradeoffs, and focus validation where it matters most for astronaut safety and mission success.
In addition to spacesuit validation, Cesium integrated 3D spatial and true-to-reality Moon topography data into Synopsys'digital mission engineering environment, where radio frequency (RF) signal propagation performance is analyzed using Ansys RF Channel Modeler? software. Ansys HFSS?
simulation software is also included in the technology stack for high-fidelity antenna models installed on spacesuits and rovers, providing insight into end-to-end connectivity across the lunar surface. The Lunar 3GPP team at NASA'sGlenn Research Center leverages this solution to visualize and validate RF coverage in the context of realistic operating scenarios. The insights can help inform radio placement that will enable connectivity outside of a future Moon Base.
It will also support mission planning by identifying potential "shadow zones" caused by geographical elements on the Moon, like craters and rock formations that astronauts and rovers should avoid.