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Time Reactor Overview

An article by Dr. David Lewis Anderson

Description

The Anderson Spacetime Battery
Twisted spacetime around the earth, or
any rotating body, contains enormous
levels of potential energy. This is due
to the tension in the fabric of spacetime
caused by inertial frame-dragging.
A time reactor (patent pending) is a system accessing and applying the stored potential energy within regions of curved spacetime or hyperspace.

This world lacks an abundant source of plentiful and clean energy. Present power generation systems are inefficient, expensive and create dangerous or harmful byproducts of operation. Also, there is not presently a reliable source of time-warped fields, including closed time-like curves, for use in spacetime research, development and real-world applications.

A time reactor generates both high levels of clean power and containable and controllable time-warped fields and closed time-like curves.

Solution

A time reactor operates to access and to harvest the potential energy between points separated by regions of twisted or curved spacetime or hyperspace.
Two Separated Points Across Curved Spacetime in a Time Reactor
Illustration showing two points, A and B,
separated across a distance of curved spacetime.
This can include curved spacetime that is caused by inertial frame dragging around the earth, any rotating body, or other natural or artificially created effect on a large or micro scale.

When the time reactor is activated the spacetime-motive force stored in the tension of curved spacetime or across hyperspace is coupled and discharged providing an abundant source of clean energy. The effect of the coupling and discharge of spacetime-motive force also produces concentrated time-warped fields and closed time-like curves that can be contained and controlled for use in research, development and real-world applications.

A time reactor is the only system of its kind to generate power and time-warped fields, including closed time-like curves, using the stored potential energy across any region of curved spacetime or hyperspace. This includes any area of curved spacetime whether naturally or artificially created.


System Components (reference diagram to right and below)

Time Reactor - Component Connectivity Diagram
Component connectivity diagram of a time reactor
(patent pending). Diagram not to scale.
The Environment 1 is any region between and including two or more separated points in between which is a region of manmade or naturally-occurring curved spacetime or hyperspace.

The Reactor Emitter 2 is an assembly, located at any of a set of multiple points in space that are separated across a region of curved spacetime or hyperspace, which produces an information and energy beam when activated. The form of the beam may include but is not limited to thermal, chemical, electrical, radiant, nuclear, magnetic, elastic, sound, mechanical, spacetime-generated or any other form of information and energy known in the art that has the ability to enable the coupling and discharge of the spacetime-motive force stored within regions of curved spacetime or hyperspace.

The Reactor Power Collector 3 is an assembly, located at any of a set of multiple points that are separated across a region of curved spacetime or hyperspace, which captures the energy within the spacetime-motive force when it is coupled and discharged between the points.
Emitter Collector Pair
A basic time reactor may include just
one emitter and collector or arrays of
each. System physical size may range
from the micro level to systems that
cover large surface areas of a planet.
The form of the energy captured by a reactor power collector 3 may include but is not limited to thermal, chemical, electrical, radiant, nuclear, magnetic, elastic, sound, mechanical, spacetime-generated or any other form of energy known in the art that may be generated when spacetime-motive force is coupled and discharged across regions of curved spacetime or through hyperspace.

The Energy Storage Device 4 is an assembly that receives, stores, and releases energy created by the operation of the time reactor. The forms of the energy stored, processed and released by the energy storage device 4 may include but are not limited to thermal, chemical, electrical, radiant, nuclear, magnetic, elastic, sound, mechanical and spacetime-generated energy. The energy storage device 4 may consist of other types of energy storage devices know in the art, including but not limited to batteries and fuel cells.

The Power Conduit 5 comprises an energy conducting pathway connecting a reactor power collector 3 to the energy storage device 4. It may be of any material or structure known in the art with the ability to conduct forms of energy including but not limited to thermal, chemical, electrical, radiant, nuclear, magnetic, elastic, sound, mechanical and spacetime-generated energy.

The Reactor Control System 6 comprises feedback, monitoring and control of all parts, components, and operation of the time reactor. This includes all devices and communications necessary to sense, manage, command, direct or regulate the behavior of all time reactor parts and components.
Devices may include, but are not limited to, sensors, controllers, actuators, computer systems, communications, software algorithms and the operator human-machine interfaces needed to successfully operate the time reactor.

The Reactor Field Chamber 7 is an assembly with a volumetric area located near a reactor power collector 3 and the energy storage device 4 of the time reactor. The reactor field chamber 7 is positioned near and within the effects of fields generated by the operation of the time reactor. The reactor field chamber 7 creates an environment for monitoring, study, experimentation, and application of the fields generated by operation of the time reactor. This applies to many types of fields dependent on the type of energy being accessed, channeled or generated by operation of the reactor. This includes the fields generated by spacetime-motive forces within the reactor field chamber 7 that include, but are not limited to, time-warped fields, fields of closed time-like curves, and any fields producing variations of special spacetime geometries.

Time Reactor - Component Connectivity Diagram
Component connectivity diagram of a time reactor (patent pending). Diagram not to scale.

Relationship Between Components

The embodiment shown in the drawing example above includes a single reactor emitter 2 and two reactor power collectors 3 connected via power conduits 5 to an energy storage device 4 at a single location (A) in a curved spacetime environment 1. A control system 6 with bi-directional communication to each component is also shown in addition to a reactor field chamber 7 in close proximity to the reactor power collectors 3 and the energy storage device 4.

Further, the drawing is a diagram only, and one embodiment of the time reactor may include these components located differently with respect to each other. In one variation there may be just a single reactor emitter 2 and single reactor power collector 3. In another variation the reactor power collector 3 could instead be an array of reactor power collectors 3. In yet another variation there could be multiple reactor emitters 2 and reactor power collectors 3 at the same or at multiple different points that are separated from each other across curved spacetime or hyperspace. The time reactor system may be configured in many different ways and scales.

Operation

Visualization of energy pattern near time reactor
Spectral image of energy pattern
near time reactor emitter and power
collector array showing coupling
and discharge of spacetime-motive
force including energy drift in the
direction of inertial frame dragging
of the Earth, USA, 2008
In operation all components of the time reactor are in an off state in which no components are powered or activated. When all components are powered and the reactor emitter 2 is activated, a multi-path information and energy beam is directed between two points (A and B) separated across curved spacetime or hyperspace. The resulting effect of the multi-path beam is to couple and create a discharge path for the spacetime-motive force stored in the curved spacetime between the two points or across hyperspace. The discharge of the spacetime motive force is coupled into the reactor power collectors 3 then conducted through the power conduits 5 into the energy storage device 4. The reactor control system 6 manages the entire operation including the balancing and conditioning of the energy in the energy storage device 4 and controlling the fields in the reactor field chamber 7 that are created by the spacetime-motive force and energy delivered through the power conduits 5 into the energy storage device 4.

Necessary and Optional Components

Necessary elements of the time reactor include at least one reactor emitter 2, one reactor power collector 3, one power conduit 5 and a control system 6 operating in the aforementioned environment 1. If generated power is not immediately consumed then an energy storage device 4 may be included. If the application of generated fields is desired then a reactor field chamber 7 may be added. The system could include additional reactor emitters 2, reactor power collectors 3, and power conduits 5. (Not shown.) In addition, multiple complete time reactor systems of any size may be used to increase the total power generation capability or to create additional and different types generated fields, within or near the reactor location, for different applications. (Not shown.)

Design Considerations

The design of each component will vary significantly based upon application. The size of the time reactor could vary from a micro-level to a much larger application covering a large area on the surface of a planet, other surface, or may cover multiple surfaces at different points. The design characteristics of each individual component and part will vary greatly based upon many application design criteria. These design criteria include the time reactor operational environment, its physical size, the number of reactor emitters 2 and reactor power collectors 3, the paths and medium through which the coupling and discharge of spacetime-motive force occurs, the generated power levels, and the relative positioning of all components and parts.

Potential energy levels in curved spacetime
surrounding Earth are significant and an
abundant source of clean natural energy.
Configurations

The elements of the time reactor may be reconfigured in many different ways to produce the same results. A single time reactor may include some parts and components at a single point or at two or more points that are separated across a region of curved spacetime or hyperspace. Additionally, multiple complete time reactors may be used to increase power generation capacity or generate different formations of time-warped fields and closed time-like curves.

Primary Application

Because one benefit of this invention is power generation, and the physical scale of the invention can range from micro to large-scale applications, the applications are vast. In most applications to use the time reactor all components and parts would be activated and the control system 6 would be used to generate the conditions necessary to initiate the coupling, discharging and collecting of the energy in the space-time motive force stored in the curved spacetime or hyperspace in the time reactors operating environment 1. The control system 6 would manage all feedback and control, balancing and conditioning all individual parts, components and the overall system to ensure efficient and effective operation during activation, operation and shutdown. This includes all aspects of field generation, control and application in the reactor field chamber 7.

Alternative Application Considerations

Time Reactor - Alternative Application Considerations
Alternative applications of time reactor
technology may include long-range space
communications, force-at-a-distance,
and multi-dimensional computing.
The invention is not limited to power generation. For example the fields generated by the coupling of spacetime-motive force may be concentrated and controlled in or near the reactor field chamber 7 producing time-warped fields including closed time-like curves permitting relative time acceleration and deceleration within the reactor field chamber 7 that can be used for multiple applications. In addition, the operation of the time reactor may create carrier waveforms in the structure of spacetime that may permit modulation and accelerated long distance communication through spacetime or hyperspace. It may also be possible to use the characteristics of the coupled space-time motive force and the time reactor to create fields providing force-at-a-distance through spacetime. In addition, the invention creates conditions that may be valuable for multi-dimensional computing and many applications in research and development in the area of spacetime physics and high-energy systems.