The Matrix of Illusion
Reality is a holographic Illusion and consciousness is the substance of the universe
(10 minutes 10 seconds) from http://www.youtube.com/watch?v=ziQcxabRfv4
Time-warped Fields use energy within curvatures of spacetime surrounding a rotating mass or energy field to generate containable and controllable fields of closed-timelike curves that can move matter and information forward or backward in time.
As general relativity predicts, rotating bodies drag spacetime around themselves in a phenomenon referred to as frame-dragging. This rotational frame-dragging effect is also known as the Lense-Thirring effect. The rotation of an object alters space and time, dragging a nearby object out of position compared to the predictions of Newtonian physics. The predicted effect is small—about one part in a few trillion.
However, as Dr. David Lewis Anderson proposed in 1987 with his announcement of time-warped field theory, the difference in potential energy between two different areas of twisted spacetime due to frame-dragging is significantly large. Even the smallest twist in spacetime contains enormous energy potential and can be used to create containable and controllable fields of close-timelike curves without the need for significant input power. This makes both forward and reverse time control possible within the limits of technology today.
The key characteristics of the application of time-warped fields for time control and time travel are presented in the picture below. This is followed by more detail describing the science below.
Frame Dragging Effect Basics
Rotational frame-dragging appears in the general principle of relativity and similar theories in the vicinity of rotating massive objects. Under this effect, the frame of reference in which a clock ticks the fastest is one which is rotating around the object as viewed by a distant observer. This also means that light traveling in the direction of rotation of the object will move around the object faster than light moving against the rotation as seen by a distant observer. It is now the best-known effect, partly thanks to the Gravity Probe B experiment.
Linear frame dragging is the similarly inevitable result of the general principle of relativity, applied to linear momentum. Although it arguably has equal theoretical legitimacy to the "rotational" effect, the difficulty of obtaining an experimental verification of the effect means that it receives much less discussion and is often omitted from articles on frame-dragging
Static mass increase is another effect. The effect is an increase in inertia of a body when other masses are placed nearby. While not strictly a frame dragging effect, it is also derived from the same equation of general relativity. It is a tiny effect that is difficult to confirm experimentally.
Mathematical Derivation of Frame Dragging
Frame-dragging may be illustrated most readily using the Kerr metric, which describes the geometry of spacetime in the vicinity of a mass M rotating with angular momentum J
where rs is the Schwarzschild radius
and where the following shorthand variables have been introduced for brevity
In the non-relativistic limit where M (or, equivalently, rs) goes to zero, the Kerr metric becomes the orthogonal metric for the oblate spheroidal coordinates
We may re-write the Kerr metric in the following form
This metric is equivalent to a co-rotating reference frame that is rotating with angular speed Ω that depends on both the radius r and the colatitude θ
In the plane of the equator this simplifies to:
Thus, an inertial reference frame is entrained by the rotating central mass to participate in the latter's rotation; this is frame-dragging. Frame-dragging occurs about every rotating mass and at every radius r and colatitude θ.
The Anderson Time Reactor
Time-warped field theory shows how a properly configured energy beam can be used to initiate and maintain the coupling of two different areas of slightly twisted spacetime. This enables the discharge of significantly greater levels of stored potential energy and generates controllable fields of closed-timelike curves. The system that couples these two regions of different spacetime potential is common referred to as an Anderson Time Reactor or spacetime battery.
The Anderson Time Reactor is a system that couples two different areas of twisted spacetime, with two different spacetime tensions. The system can access and create a conduit to harvest that stored energy and through the coupling process create dense fields of Closed Timelike Curves (CTCs).
A reactor consists of a region of spacetime, large or small, surrounding a rotating mass, where inertial frame dragging effects are present twisting spacetime between two regions of space.
A specialized beam emitter, with a localized source nearer to the rotating mass, is directed toward a more distant region of space, across the region of twisted spacetime created by inertial frame-dragging.
A series of power collectors near and surrounding the beam emitter provide a conduit to then channel and control the received power. The resulting effect is that the potential energy in the twisted fabric of spacetime is coupled or bridged from the distant point to the local power collector array. The entire process is initiated and controlled by the system.
The Anderson Time Reactor system achieves this by using the application of Time-warped Field theory to create the ability to leak, tap into and control the greater energy stored in this spacetime tension (or energy potential difference), in between the distant point and the localized point in spacetime.
In the most basic terms, the Time Reactor can be looked at as a simple spacetime battery, accessing the significant potential energy that existing around any rotating body anywhere in spacetime.
The coupling of these two points accesses what Dr. Anderson labeled a "spacetime-motive force" with the ability to produce high energy and time-warped fields allowing the containment and controlling of fields of closed-timelike curves.
The force between the localized and distant point is called the open spacetime-motive force. The open spacetime-motive force, even in the minimal effects of inertial frame-dragging, can be extremely large by present-day power generation standard standards. It is estimated that a single next-generation time reactor may have the ability to produce more than all of the worlds combined power generation capabilities today.
The amount of spacetime motive force depends on several factors. These include the mass of the rotating body, its rotation speed, relative orientation of the two point to the axis of rotation, and the medium and distance between the localized and distant points in space. More simply, it is a function of the degree of inertial frame-dragging and the characteristics of the medium through which the Time Reactor must operate between the two regions to open a "discharge path." Also, the amount of energy that is accessed, or time-warped fields generated, can be controlled in several ways through phasing and other characteristics of the emitter and power collector array.
A Practical Approach to Achieving Time Control
Practical time control and time travel requires significantly large energy levels, from some source, to operate effectively. To achieve time control we can attempt to generate this large energy level or, as an alternative, access and channel the energy already existing and inherent in natural processes and the basic makeup or fabric of spacetime surrounding our planet.
As stated above, it is estimated that a single next-generation time reactor may have the ability to produce more than all of the world's combined power generation capabilities today.
The fabric of spacetime is elastic and very powerful. It takes a tremendous amount of power to create even the slightest twist in spacetime. One can think of the fabric of spacetime surrounding a rotating mass, like the Earth, to be a spring or a battery.
The rotating mass creates a twist in the fabric of spacetime who's natural state and desire is to unwind, just like a spring, or to discharge, just like a battery. Time-warped field technology uses relatively low input power to open a discharge path for this spacetime battery. This technology itself does not create the energy levels required for time control and time travel. Instead, it relies on and operates using the energy stored within twisted spacetime around a rotating body that is created by the inertial frame-dragging effect. With only a small amount of system input power, time-warped field theory shows how enormous power levels can be accessed.
The coupling and discharge process, initiated and also defined by time-warped field theory and technology, generates significant levels of spacetime-motive force that can be used to generate very concentrated fields of closed-timelike curves near the Time Reactor's emitter and power collector array. These fields of closed-timelike curves are concentrated and controllable and can permit both forward and backwards time control.