OpenVPX design standards represent the backbone of today’s aerospace and defense embedded computing. This family of open-systems standards offers access to the highest-performing commercially developed processing technologies, promises interoperability, mixes RF and optical interconnects in the same system, and is helping bring the data center into ruggedized deployed applications.
Despite its advantages, however, there’s a consistent rap against OpenVPX; critics say it’s essentially a collection of proprietary embedded computing technologies masquerading as open-systems standards. The structure of OpenVPX allows a staggeringly wide variety of company-specific technologies, which can make interoperability among products from different suppliers difficult at best, and at worst can lock companies in to long-term supplier agreements — just like the bad old days of proprietary architectures that a quarter-century ago gave rise to commercial off-the-shelf (COTS) designs in the first place.
That all may be changing, however, as an emerging industry standard called Sensor Open Systems Architecture (SOSA) catches on. SOSA, administered by The Open Group in San Francisco, revolves around OpenVPX, and focuses on single-board computers and how they can be integrated into sensor platforms. It involves a standardized approach on how embedded systems interrogate sensor data to distill actionable information.
More to the point, however, experts in the embedded computing industry say SOSA functionally is winnowing-down cumbersome OpenVPX standards into a useful subset for aerospace and defense applications. SOSA’s potential to tame the OpenVPX monster could make interoperability of third-party embedded computing modules a reality, which could save costs and enhance competition in the embedded computing industry.
SOSA falls under an umbrella of emerging standards called Modular Open Systems Approach (MOSA). In addition to SOSA includes Future Airborne Capability Environment (FACE); Vehicular Integration for C4ISR/EW Interoperability (VICTORY); and Open Mission Systems/Universal Command and Control Interface (OMS/UCI).
One of the big difference between the MOSA standards and OpenVPX is serious participation of the U.S. military services on the standards committees; it’s not just private companies formulating standards in hopes that will adhere to them. Ensuring that embedded computing modules from many different vendors will work and play well together in a variety of backplane databus architectures perhaps offers the biggest payoff of SOSA.
“Before, VPX was so loose that it was difficult to do interoperability,” says Steve Gudknecht, product marketing manager at Elma Electronic Inc. in Fremont, Calif. “So then OpenVPX came out, and the user community did address some interoperability. Now, sitting on the standards boards are not just suppliers, but the Army, Navy, and Air Force. SOSA takes that OpenVPX standard and boils it down even further for interoperability and tri-branch convergence.”
Military involvement in setting the MOSA and SOSA standards helps keep OpenVPX in a shape that’s attractive to the military. “One of the objectives of SOSA and many other standards is to have complete interoperability of as many vendors possible in plug-and-play architectures — to define the standards narrowly enough so that is possible, yet to have advanced functions available,” explains Rodger Hosking vice president of Pentek Inc. in Upper Saddle River, N.J. “If the standard is too open, the interoperability suffers.”
SOSA may be the best thing in long time to enable the U.S. military to specify embedded computing systems that are economical, powerful, upgradable, and competitive, says Mark Littlefield, defense vertical product manager at Kontron America in San Diego.
The result of the SOSA effort will be “an open-systems architecture for defense that works,” Littlefield said last month in a presentation at the 2019 VITA Embedded Tech Trends (ETT) conference in San Diego
