Launching a satellite into space requires painstaking preparation, not only to make sure that a multitude of technologies are functioning, but also to ensure that critical components are working together in unison. One example is the communication systems on-board satellites and the rockets used to launch them.
A number of receivers and transmitters are installed into both satellites and rockets so that engineers on Earth can use radio signals to track and control their every movement, and function and troubleshoot problems that may arise during ascent. Once securely in orbit, satellites also send data back to Earth for telecommunications and scientific research.
But having multiple pieces of equipment sending and receiving radio signals within close proximity causes co-site interference: transmitters meddle with the signals being sent to receiving systems, preventing critical communications from reaching their desired targets. If the signal interference is severe enough, a launch could fail.
So before installing radio frequency (RF) systems, NASA engineers use simulation software to analyze and correct for any interference that would occur between a satellite and its launch rocket. They also analyze other RF systems near the launchpad, such as antenna towers and radar, which may also interfere with data transmission. If the simulator detects the potential for any interference, various measures can be implemented to correct for it. For example, technicians could move antennas to different areas of the spacecraft to reduce the inter-system coupling. Engineers can also engage in frequency planning, which means carefully coordinating when each system operates on specific channels, thereby lessening the chance of interference between devices.
Because there are many systems at play in any launch, and because they all need to be accounted for, staging a computer simulation can be tedious and time-consuming. In the past, it was even more painstaking because, in many cases, specifications for each RF system had to be manually inputted before running each individual analysis. That is, until engineers at the Launch Services Program at NASA’s Kennedy Space Center (KSC) collaborated with the private sector to customize software that would streamline the work.
In March 2012, KSC entered into a Small Business Innovation Research (SBIR) contract with Delcross Technologies LLC (Champaign, IL) to enhance the company’s EMIT interference simulation software by developing a more robust library of RF systems. The company had already created such a library for EMIT, which allows users to simply drag and drop whichever equipment is being considered for a rocket and satellite. Once all the prospective RF systems are in place, the software assesses whether there is any potential for interference between components. With the new contract, the goal was to increase the number of equipment items to choose from by adding a number of key systems of particular interest to NASA engineers, which would further lessen the amount of time needed to manually input specifications into the program.
Filling out the library was accomplished by tapping every publicly available source for all the data parameters needed, such as start and stop frequencies and channel spacing, to identify specific radios. By January 2013, Delcross completed the contract, having added hundreds of RF system specifications to the EMIT library. Having a more robust library will be an enormous help to KSC’s Launch Services Program.
For Delcross Technologies, the collaboration has been a success. Since the new library was introduced, sales to the US military, telecommunications companies, and other organizations whose success depends on clear radio transmission signals, have increased. Creating the RF system models is one of the biggest bottlenecks in using a simulation program like EMIT. The data- base developed under the project goes a long way to removing that bottleneck by providing ready-to-go models, which can shave days off the analysis time.