LEON: The space chip that Europe built

January 8th, 2013 in Astronomy & Space / Space Exploration
Boasting a fivefold performance improvement on the ERC32, ESA’s LEON2-FT is once more manufactured by Atmel, marketed as the AT697. Features are etched onto its underlying semiconductor at 180 nanometre scale, compared to the single-chip ERC32’s 500 nm. The smaller the scale of course, the more computing power can be crammed onto an individual chip. Credit: Atmel


Boasting a fivefold performance improvement on the ERC32, ESA’s LEON2-FT is once more manufactured by Atmel, marketed as the AT697. Features are etched onto its underlying semiconductor at 180 nanometre scale, compared to the single-chip ERC32’s 500 nm. The smaller the scale of course, the more computing power can be crammed onto an individual chip. Credit: Atmel

(Phys.org)—Just like home computers, the sophisticated capabilities of today's space missions are made possible by the power of their processor chips. ESA's coming Alphasat telecom satellite, the Proba-V microsatellite, the Earth-monitoring Sentinel family and the BepiColombo mission to Mercury are among the first missions to use an advanced 32-bit microprocessor – engineered and built in Europe.

All of them incorporate the new LEON2-FT chip, commercially known as the AT697. Engineered to operate within spacecraft computers, this microprocessor is manufactured by Atmel in France but originally designed by ESA.

To give an idea of the kind of complex factors involved in its design, the 'FT' in its name stands for 'fault tolerant', meaning it can withstand the random memory 'bit flips' due to (for more information, see the link: LEON: The making of a microprocessor for space).

This year's Proba-V microsatellite – surveying daily on a daily basis for a community of scientists previously served by the Spot satellites – will use the AT697 processor in its main flight computer.

And while Alphasat employs an older ERC32 chip in its main flight computer, LEON2-FT will be operating an experimental star tracker aboard the satellite as well as the payload computer.

Alphasat I-XL, launching in 2013: this new class of 6-tonne telecommunications satellite is the result of a public– private partnership between ESA and Inmarsat, providing high data rate services to mobile users around the globe as well as carrying experimental technology payloads. Its large size gives it 12 kilowatts of power and signal processing capacity and a longer lifetime, attractive to the telecom market. Credit: Atmel

Also with ERC32-based flight computers, ESA's Sentinels, the first of which will also be launched in the coming year, will similarly harness LEON2-FT chips in their and startrackers for navigation. 

ESA's 2014 IXV Intermediate eXperimental Vehicle for testing atmospheric reentry will control its avionics with a LEON2-FT chip. And 2015's BepiColombo mission to Mercury and 2018's Gaia star-mapper are both using the same design.

The underlying LEON design has also been made available to Europe's industry as the basis for company-owned 'system-on-chip' microprocessors optimised for dedicated tasks. For instance, Astrium is using it to create a space-based GPS/Galileo satnav receiver.

How did ESA end up designing computer chips in the first place? As one of the only bodies worldwide to deal with the entire range of space activities, the Agency is as concerned with the internal components used to put together missions as the design of the missions themselves.

"One of the main reasons for ESA to exist is to ensure the independence of Europe's space industry," said Roland Weigand of ESA's microelectronics section.

Processor board for Qinetiq Space Belgium's Advanced Data & Power Management System (ADPMS) to run small satellites or payloads, first flown on ESA's Proba-2 mission in 2009. The ADPMS runs on an ESA-developed LEON2-FT chip, seen towards bottom left. Credit: Qinetiq Space Belgium

"If we are too dependent on parts from outside Europe whose supply could be restricted at any time then the competitiveness, even the long-term viability, of our space sector comes into question. That's become a real concern with foreign export controls and related regulations.

"ESA first became motivated to get involved with microprocessor development back in the 1990s as they became more central to the performance of .

"Independence from non-European parts is also a driver of our European Components Initiative, in place for the last decade, which is working with European industry to bring new components to market."

Provided by European Space Agency

"LEON: The space chip that Europe built." January 8th, 2013. http://phys.org/news/2013-01-leon-space-chip-europe-built.html