|#1632||2243||September 10, 2016||By Sanatan Kulshrestha|
“…[t]he main advantage of using drones is precisely that they are unmanned. With the operators safely tucked in air-conditioned rooms far away, there’s no pilot at risk of being killed or maimed in a crash. No pilot to be taken captive by enemy forces. No pilot to cause a diplomatic crisis if shot down in a “friendly country” while bombing or spying without official permission”  Medea Benjamin, 2013
The aim of this article is to look at some of the developments and the technological spinoffs that are likely to have a profound impact upon uninterrupted 24/7 gathering of real time strategic intelligence, surveillance, and reconnaissance data.
X-37 B. The X-37 B or the Orbital Test Vehicle mystery aircraft of the US Air Force has nearly completed one year in orbit and it is not known when it will land. The X-37 B programme has been shrouded in mystery since its inception some time in 1999 as a NASA programme. The X-37 B has a wingspan of 4.5m, a length of 8.9 m, a height of 2.9m [VG1] and a launch weight of 4990 kg. It is powered by GaAs solar cells and lithium-ion batteries after it is boosted into space. It can remain in orbit for periods of over one year. As per US Air Force fact sheet the mission of the X-37B Orbital Test Vehicle, or OTV, is “an experimental test programme to demonstrate technologies for a reliable, reusable, unmanned space test platform for the U.S. Air Force. The primary objectives of the X-37B are twofold: reusable spacecraft technologies for America's future in space and operating experiments which can be returned to, and examined, on Earth”. It states further that OTV missions till now have spent a total of 1,367 days in orbit, "successfully checking out the X-37B's reusable flight, re-entry and landing technologies." As per US Air Force fact sheet some of the technologies being tested include advanced guidance, navigation and control, thermal protection systems, avionics, high temperature structures and seals, conformal reusable insulation, lightweight electromechanical flight systems, advanced propulsion systems & autonomous orbital flight, reentry and landing. It is said that X-37 B has a XR-5A Hall Thruster made by Aerojet Rocketdyne and that it carries an experimental propulsion system developed by the US Air Force.
High Altitude Airship. The Lockheed Martin High Altitude Airship (HAA™) is an un-tethered, unmanned lighter-than-air vehicle that is being designed to operate above the jet stream in a geostationary position to deliver persistent station keeping as a surveillance platform, telecommunications relay, or a weather observer. It will provide the military with, ever-present ISR, and rapid communications connectivity over the entire battle space. The airship is estimated to survey a 600-mile diameter area and millions of cubic miles of airspace.
Global Hawk. Global Hawk is the long-range, high-altitude ISR UAV of the US Air Force. It can fly for up to 32 hours at altitudes as high as 60,000 feet, with a range of 12,300 nautical miles, providing imaging and signals intelligence, as well as communications support, to troops around the world. It is battle proven and gives near-real-time, day and night, all weather high-resolution imagery of large geographical areas. The US Air Force plans to spend $4Bn on upgrading the Global Hawk drone programme.
Triton MQ 4C. The US Navy will continue with Triton MQ-4C that can stay aloft for over 24 hours at 17,000 m. It has speeds of up to 610 km/h. Its surveillance sensor is the AN/ZPY-3 Multi-Function Active Sensor (MFAS) X-band AESA radar with a 360-degree field-of-regard, capable of surveying 7,000,000 sq km of sea. It utilizes the radar in inverse synthetic aperture mode to identify a target in any weather condition and take high definition radar pictures, then use the advanced image and radar return recognition software of the onboard automatic identification system (AIS) for classification.
Gorgon Stare. In December 2015, the US DOD confirmed that the Gorgon Stare wide-area airborne surveillance (WAAS) system had been incorporated in the Reaper MQ-9 UAV of the US Air Force missions flying over Afghanistan. The basic configuration of Gorgon Stare consists of five monochrome charge-coupled device (CCD) daylight cameras and four thermal cameras built into a 25-inch EO/IR turret with a separate pod for data links. The advanced version of the above is the Autonomous Real-Time Ground Ubiquitous Surveillance Imaging System, (ARGUS-IS).
ARGUS. The ARGUS-IS, is a DARPA project contracted to BAE Systems and is a type of of wide-area persistent surveillance system. It is a camera system that utilizes hundreds of mobile phone cameras in a mosaic to video and auto-track every moving object within a 36 square mile area. ARGUS-IS provides military users an "eyes-on" persistent wide area surveillance capability to support tactical users in a dynamic battle space or urban environment. The sensor uses four lenses and 368 cell phone cameras of five megapixels each. The major components of the system are a 1.8 Gigapixels video system and its processing subsystems, in the air and on the ground. In early 2014, ARGUS-IS achieved initial operating capability (IOC) with the U.S. Air Force as part of Gorgon Stare Increment 2. The system streams a million terabytes of HD video per day. The enormous amount of data can be stored indefinitely and subjected to review as and when required. It is understood that ARGUS can be easily deployed on UAVs like Predator and HALE. The software utilized by ARGUS-IS is Persistics.
Software Persistics. The brain for handling of the immense amount of data gathered by the advanced surveillance cameras is a software programme called Persistics developed by Lawrence Livermore National Laboratories. Fundamentally, it is a data compression programme, which can compress the raw wide area video data from aircraft and UAVs 1000 times and achieve a reduction of pre-processed images by a factor of ten. Persistics compresses data that are essentially background data like jitter, static images of the background etc while retaining the images of military interest. The system functions by; carrying out video stabilization using ‘pixel-level dense image correspondence’; background image compression; aligning image positions obtained from different cameras, and output images of moving objects with sub-pixel resolution.
The military is moving rapidly towards gathering of strategic intelligence, surveillance, and reconnaissance data. The processing of such voluminous data is also being undertaken by advanced techniques utilizing artificial intelligence to a large extent. Nevertheless, the kill loop still takes considerable time from detection by the unmanned vehicles in the sky to activation of the armed response. Time is therefore ripe for the long endurance UAVs to start deploying armament on their pods. However, the automation of the drones to execute the kills on their own, without a human in the loop, is still some years away.
The Author is Senior Fellow at New Westminster College, Vancouver, Canada. Views expressed are personal.
 Benjamin, Medea. 2013. Drone Warfare: Killing by Remote Control. New York, NY: Verso.
[VG1]Amdt to tech data. Source: http://www.universetoday.com/128879/super-secret-x-37b-nears-one-year-orbit/#