Brief Description of Shockwave Deflection
Shockwave Deflection using the gravitational field of the object to assist the deflection of any object, using an energy shockwave this allows a much larger coverage of an object over 40% of the mass of the objects need to be deflected, but in saying that, we don’t need to actually hit the object but to detonate at a calculated distance. The object needs to deflected from the side and also at a calculated intercepted point side on, and not head on. By using the gravitational displacement of the object I believe an energy wave would create a wave motion which would travel around the gravitational surrounds of the object along with the shockwave, this would allow the maximum energy required to move and deflect the object. With my research, my findings have lead me to believe that we should be looking at placing probes on the bodies to track their position along with sensors that can measure the gravitational fields along with composition, but I am still of the opinion that platforms should be in place in orbit between the planet Mars and the moon with radar systems on board. As we know a large number of these objects there are still a large number that we don’t know about and these are the ones that will be the biggest problem to earth and the human race. The only problem that we are facing at this point is that all we have is theory about deflecting these objects and with the Technology that we have, I still believe that shockwave deflection is still the way forward. With 2012 DA 14 size approximately 45 metres, this would have been a great test subject for any method of deflection. As a body even of this size it could cause large destruction, and we have seen what even an object just 2 times this size can do.
For the past 12 years I have worked on shockwave deflection using the gravitational field of these objects to deflect them onto another trajectory (orbit) and now in talks with government bodies. We must understand that there are an endless number of these objects within our solar system and one of the problems that we have with such objects is that they are extremely hard to locate. If they are coming from the sun, by having platforms in the orbit as describe earlier, this will allow tracking of these objects that are coming from the other side of the sun. The platforms design are well underway; each platform would be armed with the latest 3 stage missiles, the number depending on weight to place these platforms into these orbits. The platform also will be fitted with object tracking systems which allows the object to be tracked along with an interception of missiles when required. Once the calculations for interception and yield required e.g. one off interception or a multiple inception, which would be required depending on the makeup of the object and size along with the gravitational field and kinetic energy of the object. The platforms would also be fitted with interception probes which would allow real time tracking of these objects and more accurate location and position also orbit path.
The location for these platforms and the number of platforms is still being calculated, but I believe that the closer to Mars orbit would be the best, because of the distance this would allow fewer yields for a larger number of objects less than 500 metres, the much large objects would require more yield and maybe a two stage detonation. The distance would be the key from such distance the deflection would only have to be 000.002% at that point to allow a much large trajectory change to take the object path away from Earth. If the calculation were made in a way that the object could be placed on a new trajectory with either the Sun or a planet like Jupiter hence removing the object for ever.
The Tunguska event was an enormously powerful explosion that occurred near (and later struck) the Podkamennaya Tunguska River in what is now Krasnoyarsk Krai, Russia, at about 7:14 a.m. KRAT (00:14 UT) on June 30 [O.S. June 17], 1908. The explosion, having the epicenter (60.886°N, 101.894°E), is believed to have been caused by the air burst of a large meteoroid or comet fragment at an altitude of 5–10 kilometres (3–6 mi) above the Earth's surface. Different studies have yielded widely varying estimates of the object's size, on the order of 100 metres (330 ft).\
OSIRIS-REx will travel to a near-Earth asteroid called Bennu and bring a small sample back to Earth for study. The mission is scheduled for launch in late 2016. As planned, the spacecraft will reach its asteroid target in 2018 and return a sample to Earth in 2023.
NASA’s Lunar Reconnaissance Orbiter (LRO) acquired images of the lunar surface before and after the largest recorded explosion occurred on the surface. On March 17th, 2013, an object the size of a small boulder hit the surface in Mare Imbrium and exploded in a flash of light nearly 10 times as bright as anything ever recorded before
Impacted July 2009
NASA Near Earth Object (NEO) Program Status; NASA FY11 Budget for NEO Research
Asteroid 2016 QA2
This object discovered only 14 hours before it passed earth at a distance of 50,000 miles from Earth, this object has a diameter of approximately 180 feet travelling at approximately 8 km a second. We need more focus on locating these objects before one is discovered one hour before impact.