Mar 3 2016

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Machines That Tell You When They're Sick

In the future, machines will monitor their own health and request help, themselves, when something’s wrong, predicts David Cirulli, engineering vice president and cofounder of CEMSol LLC.

“There’s going to be an integrated system-health engine as part of every system out there, and it will be able to interface with other systems and components,” says Cirulli. “That’s what’s missing today.” He compares the capability to how sick human patients can verbalize symptoms to a doctor, giving them the crucial information they need to diagnose a problem.

The first version of what would become CEMSol’s Integrated System Health Management software was developed at NASA’s Ames Research Center in 2003 as a way to monitor an experimental hybrid rocket engine test bed that used both gas and solid fuel.

Traditionally, this would have been accomplished by building models and running simulations, but an engineer at Ames instead developed the Inductive Monitoring System (IMS) to gather and interpret real data automatically. Hundreds of Systems Seen at a Glance

It’s a pretty straightforward concept: IMS collects data from sensors that measure temperature, pressure, fuel flow, voltage, and other vital signs from within a system, then mines those results to establish a baseline for normal behavior. Any future data that don’t fit the baseline could indicate a problem or impending failure. And whereas human engineers or operators can understand the interactions between five to seven entities at most, says Cirulli, data-mining software such as IMS can see how hundreds of systems relate to each other at a glance.

By 2012, the software had been applied to a dozen programs at NASA Mission Control, and now it’s being integrated into launch control systems at Kennedy Space Center and monitoring the carbon analyzer that ensures drinking-water safety on the International Space Station. When the Orion capsule went on its inaugural test flight in December 2014, the software monitored the new vehicle’s electrical systems.

CEMSol, which stands for Comprehensive Engineering Management Solutions, licensed the program from NASA in 2012 and used it to develop its IMS-derived Integrated System Health Management software in two packages — one as a desktop application and another as a software developer’s kit. The desktop version imports recorded datasets and analyzes them, highlighting any deviations from normal. The software developer’s kit can monitor systems in real time. “It’s a library of functions the programmers can choose from to perform whatever system-detection analysis functions they want,” Cirulli says.

Good News: It’s Going to Fail!

Also in 2012, CEMSol teamed up with Ames and Lockheed Martin to try the system-health monitoring software on the Lockheed C-130 Hercules military transport plane. The aircraft has had a history of problems with a bleed valve that switches air flow between engines during start-up. Four years’ worth of datasets from 16 planes, including starter-system failures, were fed into the program, which was then able to predict a start-up failure three starts before a problem occurred.

The successful detection eliminated the need for a manufacturer to redesign the part or introduce a new computer system, and the advance warning meant there was no need to schedule a backup plane or wait for repairs to be made. An initial $70,000 investment by Lockheed Martin into the test was quickly recouped 10 times over in reduced delays and maintenance costs.

Such drastic results on one of the program’s first test drives show that it could have a big impact in the years ahead, when self-monitoring comes to everything from cell phones to medical devices, and from refrigerators to automobiles.

“Historically, system-health management has been an afterthought,” Cirulli says. “In the future, things will be much more reliable, durable, and dependable, because they’ll have a much better understanding of their own behavior.”

Release M16-019 NASA Extends Media Credentials Deadlines for Commercial Cargo Mission

NASA has extended media accreditation deadlines for the next launch of a commercial resupply services mission to the International Space Station, now targeted for Tuesday, March 22, during a 30-minute launch window that opens at approximately 11 p.m. EDT.

Orbital ATK’s Cygnus spacecraft will launch on a United Launch Alliance Atlas V rocket from Space Launch Complex 41 at Cape Canaveral Air Force Station (CCAFS) in Florida. The spacecraft will carry crew supplies and hardware to the orbital laboratory to support the Expedition 47 and 48 crews.

Media prelaunch and launch activities will take place at CCAFS and at nearby NASA Kennedy Space Center. The deadline to apply for media access to CCAFS is 5 p.m. Monday, March 14 for U.S. citizens. International media access to CCAFS is closed. The deadline to apply for media access to Kennedy is 5 p.m., March 8 for non-citizens and 5 p.m. March 14 for U.S. citizens. International media are required to upload a scanned copy of their visa and passport or green card when submitting their online accreditation request.

All media accreditation requests must be submitted online at:

https://media.ksc.nasa.gov

All media representatives must present two forms of unexpired legal, government identification to access Kennedy. One form must include a photo, such as a passport or driver’s license. Questions about accreditation should be directed to Jennifer Horner at jennifer.p.horner@nasa.gov or 321-867-6598. For other questions or additional information, contact the Kennedy newsroom at 321-867-2468.

This launch is the fifth contracted mission by Orbital ATK under NASA’s Commercial Resupply Services contract and will be followed later this year by an Orbital ATK resupply mission launching from NASA’s Wallops Flight Facility in Wallops Island, Virginia.