Build-a-Satellite Program Could Fast Track National Security Space Missions

Customizing a satellite system to mission requirements
Designing a space system with Valhalla is similar to customizing a new car online. A project team member visits Sandia’s internal Valhalla website and selects the features and parts needed to execute the mission. The first step is to provide Valhalla with mission requirements that can be parsed into quantitative goals, including:

·  Determining the level of fidelity and detail needed by specifying if the satellite system will need to detect, identify, categorize or associate objects or events.

·  Selecting the class of object or event to search for, including vehicles, explosions, aircraft, boats, space debris or other satellites.

·  Selecting the frequency of data collection, or how often the system should revisit the target objects or events.

·  Selecting the target’s motion model. Will the system need to observe the trajectory of trucks traveling from one location to another, or will it need to observe a city, region or neighborhood of interest, or monitor objects or events across the globe?

·  Specifying any constraints. For example, the system may need to be compatible with a specific external network.

·  Selecting a mission operation center to feed the images and data captured by the satellite.

With the mission requirements clearly defined, Meub said the next step is to select parts such as onboard computers, radios, batteries, reaction wheels, sensors, propulsion tanks and thrusters, and GPS receivers from a component catalog with about 2,500 parts to choose from.

Valhalla takes all the selected parts and creates a baseline satellite design by using encoded interface control documents, engineering best practices and rules-based logic, he said. It sizes the payload, structure, solar arrays and batteries, optimizes the mass of the satellite and its compatibility with various launch vehicles and generates a notional layout of components internal to the satellite.

A Day-in-the-Life in Space
Valhalla then populates the baseline design into a group of satellites, often referred to as a constellation, and simulates the space system executing the mission by running a day-in-the-life power model simulation, Meub said. The simulation compares the mission performance metrics against space system goals and repeats that process thousands of times to find the best constellation design.

Valhalla also models the system’s orbital dynamics and the gravity harmonics of the earth, moon and sun to simulate the space environment each satellite will experience over the course of the day.

Meub said there are thousands of variables and relationships to consider when designing a space system for a specific national security mission, making the task well-suited for high-performance computing.

“Valhalla visualizes the relationship between variables so the user can see how the overall space system is affected when parameters that are relevant to each other change,” he said. “For example, the desired altitude of the spacecraft will affect the size of the telescope needed and vice versa. As the altitude of the satellite increases, the telescope also needs to become more powerful, but the system will need fewer satellites to provide enough sensing coverage to execute its mission.”

Creating Interactive Data Visualizations for Decision-Making
The simulation data is post-processed in a graphics processing unit cluster. The GPU takes all the data from the simulation and combs through it to correlate performance metrics across variable sets to produce an N-dimensional hypersurface that provides the user with hundreds of plots, including a 3D visualization of the constellation executing its mission, revisit and collection statistics, launch vehicle compatibility and simulated satellite telemetry feeds.

“This allows users to analyze the simulation data quickly,” Meub said. “All the data in a trusted, digestible format — you can see why certain simulation runs produce better performance metrics than others. This enables teams to deliver national security solutions for some projects in months rather than years.”

Valhalla has been funded through the Laboratory Directed Research and Development program, the New Mexico Small Business Assistance program, the National Nuclear Security Administration and other government organizations.