GPS World

Tag: launch

  • Global BeiDou grows to 21 with latest launch

    Global BeiDou grows to 21 with latest launch

    Seven-ninths of the way there! The 21st satellite of the BeiDou-3 global constellation, destined to number 27 upon completion, successfully launched from Xichang on June 24. Once in final orbit and commissioned, it will become the second of three planned inclined geosynchronous orbit (IGSO) satellites, traipsing in figure-eight loops across the skies above China and neighbors in the Asia-Pacific region.

    The IGSO trio will play a key role in the expansion of BeiDou-3 from a regional to a global system, in that they may afford the Asia-Pacific region greater BeiDou-derived accuracy and availability — the so-called “optimized coverage” — than will be accessible to users of the constellation in other areas of the world.

    The new satellite, like others of its latest generation, will establish inter-satellite ranging links, and carries new-gun rubidium atomic clocks and passive hydrogen maser clocks. It weighs 450 kg, a gain over previous generations, with a phased array antenna for navigation signals, a laser retroreflector and deployable S/L-band and C-band antennas.

    While BeiDou-3 has widespread applications in construction, transportation, fishing, power grid, disaster response, public security, smart cities and more, it will also bring increased capability — and independence from GPS — to the People’s Liberation Army. At 2 million strong with modernizing equipment, this is a force to be reckoned with in an increasingly unsettled region, with China actively pursuing numerous territorial disputes.

    BeiDou-3 is migrating its civil or B1 signal from 1561.098 MHz to 1575.42 MHz, the same as the GPS L1 and Galileo E1, and changing from a quadrature phase shift keying modulation to a multiplexed binary offset carrier modulation similar to Galileos E1 and the pending GPS L1C.

  • Russian Proton-M Crashes, Loses Another Payload

    In 2013, Russia lost three GLONASS satellites when their launch aboard a Proton-M rocket went awry, sending the satellites crashing into the Baikonur Cosmodrome in Kazakhstan instead of aloft into space. Before that, in 2010, three other GLONASS satellites ended up in the Pacific Ocean aboard a Proton-M rocket.

    This week, on  May 15, another Proton-M satellite crashed, this time with the Ekspress-AM4R telecommunications satellite aboard.

    Launch of the Proton-M rocket took place from Launch Pad 39 at the Baikonur Cosmodrome at 21:42 GMT. However, an unspecified failure was noted during third stage flight. The rocket and satellite are lost, according to a NASA Spaceflight article.

  • Delay in Setting Recently Launched Block IIF Satellite Healthy

    Delay in Setting Recently Launched Block IIF Satellite Healthy

    A United Launch Alliance Delta IV lifts off from Space Launch Complex-37 with the Air Force's Global Positioning System (GPS) IIF-5 satellite. This launch marked the 25th Delta IV flight since the first flight in 2002.
    A United Launch Alliance Delta IV lifts off from Space Launch Complex-37 with the Air Force’s Global Positioning System (GPS) IIF-5 satellite. This launch marked the 25th Delta IV flight since the first flight in 2002.

    The latest GPS Block IIF satellite, IIF-5 or SVN64 (operating as PRN30), was launched on February 21, 2014. Typically, GPS satellites are checked out and made operational within about a month following launch. SVN64 has yet to be set healthy.

    The delay is due to an extended navigation test being performed by the GPS master control station. A navigation upload for SVN64 was performed in March with ephemeris and clock data as usual streching weeks in advance. However, unlike with operational satellites, no further updated uploads have been performed. The aging ephermis and clock data gradually becomes less and less accurate as time goes by but should degrade gracefully.

    Inquisitive observers will have noticed that the received navigation data from SNV64 changes infrequently. Currently, the navigation data changes once per day with an epoch of 13:00 GPS Time unlike every two hours with operational satellites. And the data fit interval is 26 hours, compared to four hours.

    The test is scheduled to run until mid-May.

  • Launch of Two Beidou-2/Compass Satellites Could Be April 23

    News courtesy of CANSPACE listserv.

     

    Web chatter indicates that the launch of a pair of BeiDou-2/Compass medium Earth orbit (MEO) satellites from the Xichang Satellite Launch Center will take place around April 23. This will be the first time that a pair of BeiDou-2/Compass satellites is launched on a single rocket. The satellites are designated M3 and M4. M1 is already in orbit, and M2 and M5 are expected to be launched in June.

     

  • Fabric Engine Launches; Solves GIS Imaging Challenges with Dynamic Languages

    Fabric Engine Inc announced that it has officially launched v1.0 of its high-performance computing platform, Fabric Engine. Having recently earned Judge’s Choice at January 2012’s NodeJam, the server- and client-side Fabric Engine technology is now available to programmers under the AGPL license.

     

    According to the announcement, Fabric Engine taps into the power of modern, multi-core hardware to bring multi-threaded, compiled performance to dynamic languages such as JavaScript and Python. The benefits of dynamic languages are well-known – they’re easy to use and fast to work with. However, they are slow when compared to compiled languages. Until now, dynamic language applications have to be re-built using compiled languages in order to provide performance, which introduces significant costs. Fabric Engine gives the same performance as multi-threaded C++, yet retains the ease of use and speed of iteration of dynamic languages.

    “With Fabric Engine’s technology, it’s possible to take current backend infrastructure and redeploy it to scale and gain impressive performance increases,” said Guido Vieira, General Manager at Nexalogy Environics, a company focused on social media analytics and an early user of Fabric Engine. “Fabric Engine has other advantages too. In addition to using a language very similar to JavaScript for the high-performance operators (vanilla JavaScript/node.js for everything else), which reduces the need to use C++, you can avoid the whole code-compile-run cycle with its sometimes long delays, and use a more immediate execute model.”

    The company reported that on the desktop, Fabric Engine is ideal for high-performance applications, such as those used in game development, animation, film production, GIS, medicine, and other industries that are greedy for performance. Fabric Engine currently runs as a browser plug-in, and is currently in beta for a Python/QT desktop framework. On the server and in the cloud, Fabric Engine is ideal for addressing compute-bound problems that require raw execution performance. With node.js, Fabric Engine provides an asynchronous compute model that works well alongside the other services that node provides.

    The company listed proven uses of Fabric Engine include:

    –       3D animation

    –       Facial recognition

    –       Image/video processing

    –       Remote collaboration on 3D data

    –       GIS visualization

    –       Medical visualization

    –       Semantic analysis (Nexalogy Use Case)

    –       Statistical analysis

    –       And any other compute-bound challenge.

    “This launch marks the culmination of more than two years of hard work,” said Paul Doyle, CEO and co-founder of Fabric Engine. “We have many ideas of what can be achieved with our technology, but we also look forward to seeing all of the creative directions in which developers push Fabric. With our open-source licensing model, it is easy for developers to get started with Fabric Engine and start building high-performance applications.”