sábado, 5 de setembro de 2015

Fortifying computer chips for space travel

 

 

Dec. 4, 2014 — At Space Launch Complex 37 at Cape Canaveral Air Force Station in Florida, fueling of the Delta IV Heavy rocket has been completed. The countdown continues for launch of NASA’s Orion spacecraft.

Space is cold, dark, and lonely. Deadly, too, if any one of a million things goes wrong on your spaceship. It's certainly no place for a computer chip to fail, which can happen due to the abundance of radiation bombarding a craft. Worse, ever-shrinking components on microprocessors make computers more prone to damage from high-energy radiation like protons from the sun or cosmic rays from beyond our galaxy.

It's a good thing, then, that engineers know how to make a spaceship's microprocessors more robust. To start, they hit them with high-energy ions from particle accelerators here on Earth. It's a radiation-testing process that finds a chip's weak spots, highlighting when, where, and how engineers need to make the microprocessor tougher.

One of the most long-lived and active space-chip testing programs is at the U.S. Department of Energy's Lawrence Berkeley National Lab (Berkeley Lab). Sitting just up the hill from UC Berkeley, in Berkeley Lab's Building 88, is the 88-Inch Cyclotron, a machine that accelerates ions to high energies along a circular path.

Since 1979, most American satellites have had one or more electronic components go through Berkeley Lab's cyclotron, says Mike Johnson, research coordinator at the 88-Inch Cyclotron. Chips on the Mars rover Curiosity, chips on the Solar Dynamics Observatory, chips on the space shuttles, and chips on the International Space Station have all been put through the paces in the particle accelerator before launch. The goal is relatively simple, says Johnson: it's to "piece together a curve of the likelihood that there's going to be an error."

Mistake-free Mars

NASA has publicly announced that it plans to send astronauts to Mars by the 2030s. A Mars trip would be a multi-year mission that will expose the crew and vessel to more radiation than any other manned mission in history. Currently, Johnson says, some electronics destined for NASA's new Mars-bound space craft called Orion are being tested at the facility.

As with any chip under testing, the Orion processors are mounted in a vacuum chamber in the direct line of fire from a so-called cocktail beam. This beam, Johnson says, mimics protons from coronal mass ejections and cosmic rays, but at lower energies. Because it's actually a mixture of different ion energies, the cocktail beam lets scientists easily step the energy up or down, depending on the application. For instance, a satellite orbiting Earth feels a different kind of radiation--thanks to protection by Earth's magnetic field--than a capsule taking people to Mars where there's no magnetic field to deflect protons from the sun.

What happens when radiation hits a chip? "As an ion goes through a microprocessor, it leaves a destructive trail of charged particles that can cause temporary disruption or permanent damage," says Johnson. Bombarding a chip in a cyclotron is one of the best ways to see how it fails. "Once you know how the microprocessor is going to behave, you can make parts stronger, re-engineer it, add redundancy or shielding," Johnson says. "It can also help with designing software" that can, for example, automatically reboot a system or reroute certain functions.

In the case of Orion, which last December had its first (unmanned) test flight around Earth, a number of radiation safeguards have already been put in place. Specifically, the microprocessors are, by design, more than a decade old. This is because older electronics contain larger transistors, which means they're less sensitive to interaction with an ion.

And importantly, the chips themselves are housed within significant radiation shielding. Engineers think the processors in the flight computer won't be at great risk of radiation thanks to their well-tested design and shielding. But plenty of fail-safes have been included just in case. Orion has two backup flight computers that can go online if the main one needs to reboot, a process that takes about 20 seconds. Additionally, there are two other processors within the flight computers running error-checking software to make sure the outputs of the primary processors aren't off. Thus, radiation is unlikely to cause catastrophic electronic failures on Orion.

Cyclotron Past and Future

Berkeley Lab's cyclotron splits its time between chip radiation testing (40 percent) and conducting U.S. Department of Energy nuclear physics research on superheavy elements (60 percent). The elements 110 and 114 were verified at the facility, and numerous new isotopes have been discovered over the last decade. Other Berkeley Lab accelerators, under Glenn Seaborg, were responsible for the discovery of 16 new elements on the periodic table.

The 88-Inch cyclotron was built in the 1960s. The venerable machine is still competitive and relevant today, explains Johnson, because of its ion source, which inject particles into the accelerator. The VENUS Ion Source is currently the most powerful in the world with several world records in terms of its ability to remove electrons from atoms. "Since we can't change the cyclotron magnet, we have one of the most advanced ion sources in the world," Johnson says.

As well as keeping the ion source powerful, engineers at the cyclotron are also making improvements to the beam that blasts the microprocessors during testing. A current project aims to shape the particle beam to be much smaller and more focused. Right now, a microbeam is available that comes in at about 10 microns by 10 microns, but within a year, says Johnson, his team hopes to shrink the size to the sub-micron level to better pinpoint the radiation problems in chips.

In the meantime, engineers come from all over the country to test electronics for a variety of space and terrestrial applications. High-energy particles aren't just in space, after all. A small number of these particles reach the surface of the planet too. Therefore, versions of next-generation chips for phones and computers are currently under evaluation at the cyclotron. More-reliable electronics in space and on Earth: brought to you by the 88-Inch Cyclotron.


Story Source:

The above post is reprinted from materials provided by Lawrence Berkeley National Laboratory. The original item was written by Kate Greene. Note: Materials may be edited for content and length.


http://www.sciencedaily.com/releases/2015/09/150904195347.htm

 

Videotaped interrogations: a matter of perspective

 

 

What if there were one simple trick to presenting a police interrogation video that would make people more likely to believe a confession was voluntary--or coerced? Research by Ohio University psychology professor G. Daniel Lassiter indicates that one actually exists. When the camera is focused on a suspect--the interrogator either is nowhere in sight, or only his back is visible--viewers are more likely to believe that any self-incriminating statement is voluntary. That perception persists even if the interrogator coerces or threatens the suspect.
But take the simple step of moving the camera, positioning it so that both the interrogator and suspect can be seen in profile, and the exact same interview can leave viewers with a much different impression. Using that alternate camera angle can eliminate the sort of bias that can lead to wrongful convictions. Lassiter provided NSF with more insight into his work.

Credit: NSF



International Year of Light comes to Washington D.C. Sept. 12

 


Two events to celebrate achievements in science and engineering of light and light-based technologies, and raise awareness of contributions to humanity

image of light orb

Nearly two dozen interactive exhibits will allow hands-on learning about light.
Credit and Larger Version

August 26, 2015

To promote the progress and promise of light research and education, leading U.S. science organizations will host two events on Saturday, Sept. 12, 2015, in Washington, D.C.

The events are organized by the National Science Foundation (NSF) in conjunction with the American Institute of Physics, the American Physical Society, the IEEE Photonics Society, the National Academy of Sciences, the Optical Society and the International Society for Optics and Photonics (SPIE).

The programs will mark the International Year of Light, a yearlong celebration of light science and its applications, as proclaimed by the United Nations.

These events will feature the latest in light-based technologies as well as leading scientists and educators to promote improved public understanding of the central role of light in the modern world.

Wonders of Light: Family Science Fun

What
An educational event for school-age children with activities demonstrating the science of light

When
10 a.m. - 3 p.m. E.T. on Sept. 12

Where
The Smithsonian National Museum of the American Indian

Who
Public and media are welcome; no RSVP required
The first 1,000 visitors will receive an International Year of Light tote bag.

Hands-on activities to include:

  • A LED-orb that changes color with music
  • Build-your-own kaleidoscope
  • An interactive video game
  • A green screen to be a reporter for a day

Light for a Better World: A Celebration of U.S. Innovation

What
A public symposium and invitation-only reception

When
6 - 9 p.m. E.T. on Sept. 12

Where
National Academy of Sciences

Who
Media and invited guests
Interested members of the media, please email pwimmer@osa.org.

This symposium will feature:

  • Eric Betzig, Howard Hughes Medical Institute, 2014 Nobel Prize Winner
  • France Córdova, National Science Foundation Director
  • Gerald Duffy, GE Lighting Manager
  • Michael Liehr, AIM Photonics CEO
  • Shuji Nakamura, University of California Santa Barbara, 2014 Nobel Prize Winner

About the International Year of Light

The International Year of Light and Light-Based Technologies (IYL 2015) is a global initiative adopted by the United Nations (A/RES/68/221) to raise awareness of how optical technologies promote sustainable development and provide solutions to worldwide challenges in energy, education, agriculture, communications and health. With UNESCO as lead agency, IYL 2015 programs will promote improved public and political understanding of the central role of light in the modern world while also celebrating noteworthy anniversaries in 2015--from the first studies of optics 1,000 years ago to discoveries in optical communications that power the Internet today.

For more information on the International Year of Light, please visitlight2015.org.

For more information about NSF-funded light research and education, visitnsf.gov/light.

-NSF-

Media Contacts
Sarah Bates, NSF, (703) 292-7738, sabates@nsf.gov

Related Websites
NSF.gov/light: www.nsf.gov/light

The National Science Foundation (NSF) is an independent federal agency that supports fundamental research and education across all fields of science and engineering. In fiscal year (FY) 2015, its budget is $7.3 billion. NSF funds reach all 50 states through grants to nearly 2,000 colleges, universities and other institutions. Each year, NSF receives about 48,000 competitive proposals for funding, and makes about 11,000 new funding awards. NSF also awards about $626 million in professional and service contracts yearly.

 

http://www.nsf.gov/news/news_summ.jsp?cntn_id=136072&WT.mc_id=USNSF_51&WT.mc_ev=click