endtimetuber's video: AIRBORNE LASER OF UNITED STATES THE LITTLE HORN NEW ROMAN EMPIRE TO TARGET JESUS CHRIST Pt 2

http://www.usaisthenewromanempire.org official website of endtimetuber (under construction) AIRBORNE LASER OF UNITED STATES, THE LITTLE HORN, NEW ROMAN EMPIRE TO TARGET JESUS CHRIST Part 1 of 2 ================== PART 1 http://www.youtube.com/watch?v=vESvTKmlRLA Pentagon: Airborne Laser Downs Test Missile Ian Sample, science correspondent Guardian.co.uk, Friday 12 February 2010 23.50 GMT An infrared image released by the US department of defence shows the Missile Defence Agency's airborne laser destroying its target. Photograph: AFP/Getty Images The airborne laser test-bed (ALTB) on a flying modified Boeing 747-400F jumbo jet equipped with a massive laser gun shot down a Scud-like missile over the Pacific Ocean on a test range near Point Mugu on Thursday night, marking what analysts said was a milestone in the development of the U.S. missile defense system. (what is good for defense can also be good for offense). It uses more than one laser to bring down a missile. When infrared sensors on the plane detect a missile's exhaust plume, the first laser is used to track its trajectory. A second laser is then used to measure atmospheric effects between the plane and the missile. These are fed into a computer that adjusts the optics of the main laser. The giant 18 tonne infra­red laser then fires a single shot from the nose ­turret on the plane, lasting three to five seconds, which is targeted at the ­pressurised part of the missile. The intense concentration of heat on the missile's skin weakens it enough for aerodynamic stresses to tear the missile apart. The whole process takes less than 12 seconds. The main laser, a powerful $4bn (£2.55bn) chemical oxygen iodine laser, can fire 20 shots before the plane needs to land and fill up on fuel for the weapon. If it is used at lower power, it could muster 40 shots in one flight. Although the airborne laser was designed to destroy short-range tactical missiles, defence analysts believe it may be effective against intercontinental ballistic missiles, hostile aircraft and even satellites. The laser shot is a super-heated, basketball size invisible light beam that travel at the speed of light in air or 670 million mph capable to incinerate a missile moving at 4,000 mph. The lasers and missile detection sensors are built into a modified ­Boeing 747 freighter plane that cruises at an altitude of 40,000 feet and has a kill range of around 190 miles. The plane would be deployed over war zones or missile silos and fly in a figure of eight overhead to act as a deterrent. The airborne laser is a big part of the US missile defence agency's reincarnation of the strategic defence initiative, a constellation of laser-toting satellites proposed by the Reagan administration in the 1980s. That project hit insurmountable technical difficulties with putting powerful lasers in orbit and being able to track missiles quickly and accurately. Capabilities: Operates autonomously, above the clouds, outside the range of threat weapons but sufficiently close to enemy territory Engages early, destroying ballistic missiles in their boost phase of flight over launch area Cues and tracks targets, communicating with other joint theater assets for layered defense system Unique Technology: Nose-mounted turret with 1.5m telescope that focuses beams on missile and collects return image and signals Beam Control System to acquire and track targets with precision accuracy Elements The Airborne Laser Testbed (ALTB) is being developed as an advanced platform for MDAs directed energy research program. Using two solid state lasers and a megawatt-class Chemical Oxygen Iodine Laser housed aboard a modified Boeing 747-400 Freighter, the ALTB uses directed energy to demonstrate the potential of using directed energy as a viable technology against ballistic missiles. Firing Sequence The Airborne Laser Testbed uses six infrared sensors to detect the exhaust plume of a boosting missile. Once a target is detected, a kilowatt-class solid state laser, the Track Illuminator, tracks the missile and determines a precise aim point. The Beacon Illuminator, a second kilowatt-class solid state laser, then measures disturbances in the atmosphere, which are corrected by the adaptive optics system to accurately point and focus the high energy laser at its intended target. Using a very large telescope located in the nose turret, the beam control/fire control system focuses the megawatt-class COIL beam onto a pressurized area of the boosting missile, holding it there until the concentrated energy compromises the structural integrity of the threat missile causing it to fail.