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10 15 20 25 30 35 40 45 50 55 50 of induction field created by the original current, multiplication of power can be attained, where one or more different outputs from the source can be extracted, where the system become fully self-controlled (for example if the system needs to provide 40W or 400W the system will regulate itself when it is designed by use of single or multiple (353) setup of the same system to produce maximal 400W where the output current is always in phase with the original input, where each set of wire and associated winding sets can be placed in a casing, like a tube (362), made of any material for warranting the constant equal distance and positioning of the coils and the wire where the casing can be used as a earth; We claim a reactor, as described in claim 1 and 2, which it’s electric output can used as basic supply to be put through at least one system as described above, for the current to be enhanced by several times. We claim the power enhancer device, working after the methods described in claim 140, in which at least one additional mechanical, electrical and/or electronic component is placed, for example a diode, an IC, a microchip, a rectifier, to enhance or regulate the working; We claim the power enhancer device which works after the method as described in claim 140, which is equipped with at least one magnetic winding means to collect magnetic fields provoked by at least one current carrying means (like wire, cable, carbon nanotube(s), graphene band(s)) of the system; We claim the power enhancer device which works after the method as described in claim 140, which is equipped with at least one moving magnetic winding means to provoke — by induction — a flow of electrons in at least one conductive means (like wire, cable, carbon nanotube(s), graphene band(s)) of the system. A new method is disclosed to build a reactor (Fig. 38), working after the method as described in claim 2 and 14, which is able to create internally — within a smaller core (382A) embodiment and a larger core (381A) embodiment — in each a magnetic field, joined together to form a three-dimensional double magnetic field (381C and 382C) that may reach till the boundary of the reactor or outside the boundaries of it’s physical system, creates anti-gravity effects for the reactor (380A) itself, where the reactor can be attached to the outer embodiment (387) — like a craft - by holding means (387A, 387B) and shaft means (396), where the smaller core (382A) is connected to at least one extended bottom-plate (382B) in which solid magnetic means (382C) are placed and nuclear sources (like separate sources, screws coated with nuclear material) are positioned on said bottom-plate inside (382D) and outside (382E) the area covered by the smaller core, where the smaller core embodiment initially rest on bearing means (like bearing balls 384, magnetic bearings), and these bearing means — being either part of the bottom-plate of the smaller core embodiment, either are free independently moveable (like balls), either are incorporated in the bottom-plate (381D) of said larger core (381A) embodiment, or any combination of these three - where the total reactor (380A) rest in it’s starting position on an rotative engine (385) equipped with solid magnetic means (385B) which are in a magnetic relationship with the solid magnetic means (382C) of the bottom-plate of the smaller core embodiment, where when activating the rotation of said engine (385A) also the smaller core embodiment starts to rotate inside the larger core embodiment, whereby the enclosed materials (380B, 380C)(gasses, metallic